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-<pre>
-
-The Project Gutenberg EBook of Industrial Poisoning, by Joseph Rambousek
-
-This eBook is for the use of anyone anywhere in the United States and most
-other parts of the world at no cost and with almost no restrictions
-whatsoever.  You may copy it, give it away or re-use it under the terms of
-the Project Gutenberg License included with this eBook or online at
-www.gutenberg.org.  If you are not located in the United States, you'll have
-to check the laws of the country where you are located before using this ebook.
-
-Title: Industrial Poisoning
-       From Fumes, Gases and Poisons of Manufacturing Processes
-
-Author: Joseph Rambousek
-
-Translator: Thomas M. Legge
-
-Release Date: November 1, 2019 [EBook #60605]
-
-Language: English
-
-Character set encoding: UTF-8
-
-*** START OF THIS PROJECT GUTENBERG EBOOK INDUSTRIAL POISONING ***
-
-
-
-
-Produced by Suzanne Lybarger, Brian Janes and the Online
-Distributed Proofreading Team at http://www.pgdp.net
-
-
-
-
-
-
-</pre>
-
-
-<p><span class="pagenum"><a name="Page_i" id="Page_i">[i]</a></span></p>
-
-<p class="titlepage larger">INDUSTRIAL POISONING</p>
-
-<p class="center">FROM FUMES, GASES AND POISONS<br />
-OF MANUFACTURING PROCESSES</p>
-
-<hr />
-
-<p><span class="pagenum"><a name="Page_ii" id="Page_ii">[ii]</a></span></p>
-
-<div class="bbox">
-
-<p class="center">BY THE SAME AUTHOR</p>
-
-<p class="center larger"><b>LEAD POISONING<br />
-AND LEAD ABSORPTION:</b></p>
-
-<p class="center">THE SYMPTOMS, PATHOLOGY AND
-PREVENTION, WITH SPECIAL REFERENCE
-TO THEIR INDUSTRIAL
-ORIGIN AND AN ACCOUNT OF THE
-PRINCIPAL PROCESSES INVOLVING
-RISK.</p>
-
-<p class="hanging">By THOMAS M. LEGGE M.D. (Oxon.), D.P.H.
-(Cantab.), H.M. Medical Inspector of Factories;
-Lecturer on Factory Hygiene, University of
-Manchester; and KENNETH W. GOADBY,
-D.P.H. (Cantab.), Pathologist and Lecturer
-on Bacteriology, National Dental Hospital.
-Illustrated. viii+308 pp. 12s. 6<i>d.</i> net.</p>
-
-<p class="center"><span class="smcap">London</span>: EDWARD ARNOLD.</p>
-
-</div>
-
-<hr />
-
-<p><span class="pagenum"><a name="Page_iii" id="Page_iii">[iii]</a></span></p>
-
-<p class="titlepage larger">INDUSTRIAL POISONING</p>
-
-<p class="center">FROM FUMES, GASES AND POISONS<br />
-OF MANUFACTURING PROCESSES</p>
-
-<p class="titlepage"><span class="smaller">BY</span><br />
-DR. J. RAMBOUSEK<br />
-<span class="smaller">PROFESSOR OF FACTORY HYGIENE,<br />
-AND CHIEF STATE HEALTH OFFICER, PRAGUE</span></p>
-
-<p class="titlepage"><span class="smaller">TRANSLATED AND EDITED BY</span><br />
-THOMAS M. LEGGE, M.D., D.P.H.<br />
-<span class="smaller">H.M. MEDICAL INSPECTOR OF FACTORIES<br />
-JOINT AUTHOR OF ‘LEAD POISONING AND LEAD ABSORPTION’</span></p>
-
-<p class="titlepage">WITH ILLUSTRATIONS</p>
-
-<p class="titlepage"><span class="smaller">LONDON</span><br />
-EDWARD ARNOLD<br />
-<span class="smaller">1913</span></p>
-
-<p><span class="pagenum"><a name="Page_iv" id="Page_iv">[iv]</a></span></p>
-
-<hr />
-
-<p><span class="pagenum"><a name="Page_v" id="Page_v">[v]</a></span></p>
-
-<h2>TRANSLATOR’S PREFACE</h2>
-
-<p>I undertook the translation of Dr. Rambousek’s book because
-it seemed to me to treat the subject of industrial poisons in
-as novel, comprehensive, and systematic a manner as was
-possible within the compass of a single volume. Having
-learnt much myself from Continental writings on industrial
-diseases and factory hygiene, I was anxious to let others also
-see how wide a field they had covered and how thorough
-were the regulations for dangerous trades abroad, especially
-in Germany. A praiseworthy feature of Dr. Rambousek’s
-book was the wealth of references to the work of foreign
-writers which is made on almost every page. To have left
-these names and references, however, in the text as he has
-done would have made the translation tedious reading, and
-therefore for the sake of those who desire to pursue inquiry
-further I have adopted the course of collecting the great
-majority and placing them all together in an appendix at
-the end of the volume.</p>
-
-<p>Dr. Rambousek as a medical man, a chemist, and
-a government official having control of industrial matters,
-is equipped with the very special knowledge required to
-describe the manufacturing processes giving rise to injurious
-effects, the pathology of the lesions set up, and the preventive
-measures necessary to combat them. In his references to
-work done in this country he has relied largely on abstracts
-which have appeared in medical and technical journals published
-on the Continent. I have only thought it necessary
-to amplify his statements when important work carried out
-here on industrial poisoning,—such as that on nickel carbonyl<span class="pagenum"><a name="Page_vi" id="Page_vi">[vi]</a></span>
-and on ferro-silicon—had been insufficiently noted. Such
-additions are introduced in square brackets or in footnotes.</p>
-
-<p>In his preface Dr. Rambousek says ‘the book is intended
-for all who are, or are obliged to be, or ought to be, interested
-in industrial poisoning.’ No words could better describe the
-scope of the book.</p>
-
-<p>The work of translation would never have been begun
-but for the assistance given me in Parts II and III by my
-sister, Miss H. Edith Legge. To her, and to Mr. H. E.
-Brothers, F.I.C., who has been to the trouble of reading the
-proofs and correcting many mistakes which my technical
-knowledge was insufficient to enable me to detect, my best
-thanks are due.</p>
-
-<p>I am indebted to Messrs. Davidson &amp; Co., Belfast, for
-permission to use figs. 46 and 48; to Messrs. Locke, Lancaster
-&amp; Co., Millwall, for fig. 27; to Mr. R. Jacobson, for
-figs. 30, 33, 37, 38, and 43; to Messrs. Siebe, Gorman &amp; Co.,
-for figs. 32, 39, and 40; to Messrs. Blackman &amp; Co. for fig. 47;
-to Messrs. Matthews &amp; Yates for fig. 54; to H.M. Controller
-of the Stationery Office for permission to reproduce figs. 52,
-53, and 54, and the diagrams on p. 284; and lastly to my
-publisher, for figs. 41, 42, 43, and 49, which are taken from
-the book by Dr. K. W. Goadby and myself on ‘Lead
-Poisoning and Lead Absorption.’</p>
-
-<p class="right">T. M. L.</p>
-
-<p><span class="smcap">Hampstead</span>, <i>May 1913</i>.</p>
-
-<hr />
-
-<p><span class="pagenum"><a name="Page_vii" id="Page_vii">[vii]</a></span></p>
-
-<h2>CONTENTS</h2>
-
-<table summary="Contents" class="contents">
-  <tr>
-    <td></td>
-    <td class="tdpg smaller">PAGE</td>
-  </tr>
-  <tr>
-    <td><span class="smcap">Introduction</span></td>
-    <td class="tdpg"><a href="#INTRODUCTION">xiii</a></td>
-  </tr>
-  <tr>
-    <td class="tdc" colspan="2">Part I.—Description of the industries and processes attended with risk of poisoning: incidence of such poisoning</td>
-  </tr>
-  <tr>
-    <td><span class="smcap">Chemical Industry</span></td>
-    <td class="tdpg"><a href="#I_THE_CHEMICAL_INDUSTRY">1</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Sulphuric acid industry (sulphur dioxide): use of sulphuric acid</td>
-    <td class="tdpg"><a href="#Page_4">4</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Its effects on health</td>
-    <td class="tdpg"><a href="#Page_9">9</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Hydrochloric acid, saltcake and soda industry</td>
-    <td class="tdpg"><a href="#Page_14">14</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Their effects on health</td>
-    <td class="tdpg"><a href="#Page_20">20</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Use of sulphate and sulphide of soda</td>
-    <td class="tdpg"><a href="#Page_22">22</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Ultramarine</td>
-    <td class="tdpg"><a href="#Page_22">22</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Sulphonal</td>
-    <td class="tdpg"><a href="#Page_22">22</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Diethyl sulphate</td>
-    <td class="tdpg"><a href="#Page_23">23</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Chlorine, chloride of lime and chlorates</td>
-    <td class="tdpg"><a href="#Page_23">23</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Their effect on health</td>
-    <td class="tdpg"><a href="#Page_26">26</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Other chlorine compounds and their use as well as bromine, iodine and fluorine</td>
-    <td class="tdpg"><a href="#Page_29">29</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Chlorides of phosphorus</td>
-    <td class="tdpg"><a href="#Page_30">30</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Chlorides of sulphur</td>
-    <td class="tdpg"><a href="#Page_31">31</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Zinc chloride</td>
-    <td class="tdpg"><a href="#Page_32">32</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Rock salt</td>
-    <td class="tdpg"><a href="#Page_32">32</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Organic chlorine compounds</td>
-    <td class="tdpg"><a href="#Page_32">32</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Carbon oxychloride (phosgene)</td>
-    <td class="tdpg"><a href="#Page_32">32</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Carbon chlorine compounds (aliphatic)</td>
-    <td class="tdpg"><a href="#Page_33">33</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Methyl chloride</td>
-    <td class="tdpg"><a href="#Page_33">33</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Methylene chloride</td>
-    <td class="tdpg"><a href="#Page_34">34</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Carbon tetrachloride</td>
-    <td class="tdpg"><a href="#Page_34">34</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Ethyl chloride</td>
-    <td class="tdpg"><a href="#Page_34">34</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Monochloracetic acid</td>
-    <td class="tdpg"><a href="#Page_34">34</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Chloral</td>
-    <td class="tdpg"><a href="#Page_34">34</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Chloroform</td>
-    <td class="tdpg"><a href="#Page_34">34</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Chloride of nitrogen</td>
-    <td class="tdpg"><a href="#Page_35">35</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Cyanogen chloride</td>
-    <td class="tdpg"><a href="#Page_35">35</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Chlorobenzene</td>
-    <td class="tdpg"><a href="#Page_35">35</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub3">Benzo trichloride, benzyl chloride</td>
-    <td class="tdpg"><a href="#Page_35">35</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub3"><span class="pagenum"><a name="Page_viii" id="Page_viii">[viii]</a></span>Nitro- and dinitro-chlorobenzene</td>
-    <td class="tdpg"><a href="#Page_35">35</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Iodine and iodine compounds</td>
-    <td class="tdpg"><a href="#Page_36">36</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Bromine and bromine compounds</td>
-    <td class="tdpg"><a href="#Page_36">36</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub3">Methyl iodide and methyl bromide</td>
-    <td class="tdpg"><a href="#Page_36">36</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Fluorine compounds</td>
-    <td class="tdpg"><a href="#Page_37">37</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub3">Hydrofluoric and silicofluoric acids</td>
-    <td class="tdpg"><a href="#Page_38">38</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Manufacture and uses of nitric acid</td>
-    <td class="tdpg"><a href="#Page_39">39</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Its effect on health</td>
-    <td class="tdpg"><a href="#Page_40">40</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Nitric and nitrous salts and compounds</td>
-    <td class="tdpg"><a href="#Page_44">44</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Barium nitrate</td>
-    <td class="tdpg"><a href="#Page_44">44</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Ammonium nitrate</td>
-    <td class="tdpg"><a href="#Page_44">44</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Lead nitrate</td>
-    <td class="tdpg"><a href="#Page_44">44</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Mercurous and mercuric nitrate</td>
-    <td class="tdpg"><a href="#Page_44">44</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Silver nitrate</td>
-    <td class="tdpg"><a href="#Page_45">45</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Sodium nitrite</td>
-    <td class="tdpg"><a href="#Page_45">45</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Amyl nitrite</td>
-    <td class="tdpg"><a href="#Page_45">45</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Manufacture of explosives and their effects</td>
-    <td class="tdpg"><a href="#Page_45">45</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Fulminate of mercury</td>
-    <td class="tdpg"><a href="#Page_46">46</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Nitro-glycerin</td>
-    <td class="tdpg"><a href="#Page_46">46</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Dynamite</td>
-    <td class="tdpg"><a href="#Page_47">47</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Gun cotton</td>
-    <td class="tdpg"><a href="#Page_48">48</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Collodion cotton, smokeless powder</td>
-    <td class="tdpg"><a href="#Page_48">48</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Manufacture of phosphorus and lucifer matches and their effects</td>
-    <td class="tdpg"><a href="#Page_49">49</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Other uses of phosphorus and compounds of phosphorus</td>
-    <td class="tdpg"><a href="#Page_52">52</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub3">Phosphor-bronze</td>
-    <td class="tdpg"><a href="#Page_52">52</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub3">Sulphide of phosphorus</td>
-    <td class="tdpg"><a href="#Page_52">52</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub3">Phosphoretted hydrogen</td>
-    <td class="tdpg"><a href="#Page_52">52</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Superphosphate and artificial manure</td>
-    <td class="tdpg"><a href="#Page_53">53</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Basic slag</td>
-    <td class="tdpg"><a href="#Page_54">54</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Chromium compounds and their uses</td>
-    <td class="tdpg"><a href="#Page_55">55</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Sodium and potassium bichromate</td>
-    <td class="tdpg"><a href="#Page_55">55</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Lead chromate and chrome colours</td>
-    <td class="tdpg"><a href="#Page_55">55</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Their effect on health</td>
-    <td class="tdpg"><a href="#Page_56">56</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Manganese compounds and their effects</td>
-    <td class="tdpg"><a href="#Page_58">58</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Mineral oil industry and the use of petroleum and benzine</td>
-    <td class="tdpg"><a href="#Page_59">59</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Chemical cleaning</td>
-    <td class="tdpg"><a href="#Page_61">61</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Their effect on health</td>
-    <td class="tdpg"><a href="#Page_61">61</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Recovery and use of sulphur</td>
-    <td class="tdpg"><a href="#Page_64">64</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Its effect on health</td>
-    <td class="tdpg"><a href="#Page_65">65</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Sulphuretted hydrogen and its effect</td>
-    <td class="tdpg"><a href="#Page_65">65</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Preparation and use of carbon bisulphide in vulcanising, &amp;c.</td>
-    <td class="tdpg"><a href="#Page_68">68</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Its effect on health</td>
-    <td class="tdpg"><a href="#Page_69">69</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Preparation of illuminating gas</td>
-    <td class="tdpg"><a href="#Page_71">71</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Its effect on health</td>
-    <td class="tdpg"><a href="#Page_74">74</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Coke ovens and risk from them</td>
-    <td class="tdpg"><a href="#Page_77">77</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Other kinds of power and illuminating gas</td>
-    <td class="tdpg"><a href="#Page_80">80</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Producer gas</td>
-    <td class="tdpg"><a href="#Page_80">80</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Blast furnace gas</td>
-    <td class="tdpg"><a href="#Page_82">82</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Water gas</td>
-    <td class="tdpg"><a href="#Page_82">82</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Dowson and Mond gas</td>
-    <td class="tdpg"><a href="#Page_82">82</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Suction gas</td>
-    <td class="tdpg"><a href="#Page_83">83</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Acetylene (calcium carbide)</td>
-    <td class="tdpg"><a href="#Page_85">85</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2"><span class="pagenum"><a name="Page_ix" id="Page_ix">[ix]</a></span>Their effect on health</td>
-    <td class="tdpg"><a href="#Page_87">87</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Ammonia and ammonium compounds</td>
-    <td class="tdpg"><a href="#Page_90">90</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Use of ammonia and its effects</td>
-    <td class="tdpg"><a href="#Page_92">92</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Cyanogen compounds</td>
-    <td class="tdpg"><a href="#Page_93">93</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Use of cyanide, and their effects</td>
-    <td class="tdpg"><a href="#Page_95">95</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Coal tar and tar products</td>
-    <td class="tdpg"><a href="#Page_96">96</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Their effects on health</td>
-    <td class="tdpg"><a href="#Page_101">101</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Artificial organic dye stuffs (coal tar colours)</td>
-    <td class="tdpg"><a href="#Page_107">107</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub3">Their effects on health</td>
-    <td class="tdpg"><a href="#Page_112">112</a></td>
-  </tr>
-  <tr>
-    <td><span class="smcap">Recovery and use of metals</span></td>
-    <td class="tdpg"><a href="#II_SMELTING_OF_METALS">120</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Lead poisoning in general</td>
-    <td class="tdpg"><a href="#Page_120">120</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Lead, silver and zinc smelting</td>
-    <td class="tdpg"><a href="#Page_122">122</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Spelter works</td>
-    <td class="tdpg"><a href="#Page_125">125</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Lead poisoning in lead smelting and spelter works</td>
-    <td class="tdpg"><a href="#Page_126">126</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">White lead and other use of lead colours</td>
-    <td class="tdpg"><a href="#Page_131">131</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Lead poisoning in the manufacture and use of white lead and lead paints</td>
-    <td class="tdpg"><a href="#Page_132">132</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Manufacture of electric accumulators</td>
-    <td class="tdpg"><a href="#Page_134">134</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">The ceramic industry</td>
-    <td class="tdpg"><a href="#Page_135">135</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Coarse ware pottery</td>
-    <td class="tdpg"><a href="#Page_136">136</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Manufacture of stove tiles</td>
-    <td class="tdpg"><a href="#Page_137">137</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Stoneware and porcelain</td>
-    <td class="tdpg"><a href="#Page_138">138</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Lead poisoning in letterpress printing</td>
-    <td class="tdpg"><a href="#Page_138">138</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Lead poisoning in filecutting, polishing precious stones, musical instrument making, &amp;c.</td>
-    <td class="tdpg"><a href="#Page_140">140</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Mercury (poisoning in its recovery and use)</td>
-    <td class="tdpg"><a href="#Page_141">141</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Mercurial poisoning in water-gilding, coating mirrors, in felt hat making, &amp;c.</td>
-    <td class="tdpg"><a href="#Page_142">142</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Arsenic (poisoning in its recovery and in use of arsenic and arsenic compounds)</td>
-    <td class="tdpg"><a href="#Page_143">143</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Recovery of arsenic and white arsenic</td>
-    <td class="tdpg"><a href="#Page_143">143</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Poisoning by arseniuretted hydrogen gas</td>
-    <td class="tdpg"><a href="#Page_145">145</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Antimony</td>
-    <td class="tdpg"><a href="#Page_146">146</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Extraction of iron</td>
-    <td class="tdpg"><a href="#Page_146">146</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Ferro-silicon</td>
-    <td class="tdpg"><a href="#Page_149">149</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Zinc</td>
-    <td class="tdpg"><a href="#Page_151">151</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Copper, brass (brassfounders’ ague)</td>
-    <td class="tdpg"><a href="#Page_151">151</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Metal pickling</td>
-    <td class="tdpg"><a href="#Page_152">152</a></td>
-  </tr>
-  <tr>
-    <td><span class="smcap">Other Industries</span></td>
-    <td class="tdpg"><a href="#III_OCCURRENCE_OF_INDUSTRIAL_POISONING">153</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Treatment of stone and earths; lime burning, glass</td>
-    <td class="tdpg"><a href="#Page_153">153</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Treatment of animal products</td>
-    <td class="tdpg"><a href="#Page_154">154</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Preparation of vegetable foodstuffs</td>
-    <td class="tdpg"><a href="#Page_154">154</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Poisonous woods</td>
-    <td class="tdpg"><a href="#Page_154">154</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Textile industry</td>
-    <td class="tdpg"><a href="#Page_156">156</a></td>
-  </tr>
-  <tr>
-    <td class="tdc" colspan="2">Part II.—Pathology and treatment of industrial poisoning</td>
-  </tr>
-  <tr>
-    <td><span class="smcap">Industrial poisons in general</span></td>
-    <td class="tdpg"><a href="#I_INTRODUCTORY">157</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Channels of absorption, classification, susceptibility, immunity</td>
-    <td class="tdpg"><a href="#Page_158">158</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Fate of poisons in the body—absorption, cumulative action, excretion</td>
-    <td class="tdpg"><a href="#Page_162">162</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">General remarks on treatment</td>
-    <td class="tdpg"><a href="#Page_163">163</a></td>
-  </tr>
-  <tr>
-    <td><span class="smcap">Industrial poisons in particular</span></td>
-    <td class="tdpg"><a href="#II_INDUSTRIAL_POISONING_IN_PARTICULAR_INDUSTRIES">169</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1"><span class="pagenum"><a name="Page_x" id="Page_x">[x]</a></span>Group: mineral acids, halogens, inorganic halogen compounds, alkalis</td>
-    <td class="tdpg"><a href="#Page_169">169</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Hydrochloric acid</td>
-    <td class="tdpg"><a href="#Page_170">170</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Hydrofluoric and silico-fluoric acids</td>
-    <td class="tdpg"><a href="#Page_171">171</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Sulphur dioxide and sulphuric acid</td>
-    <td class="tdpg"><a href="#Page_171">171</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Nitrous fumes, nitric acid</td>
-    <td class="tdpg"><a href="#Page_172">172</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Chlorine, bromine, iodine</td>
-    <td class="tdpg"><a href="#Page_173">173</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Chlorides of phosphorus, sulphur and zinc</td>
-    <td class="tdpg"><a href="#Page_174">174</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Ammonia</td>
-    <td class="tdpg"><a href="#Page_175">175</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Alkalis</td>
-    <td class="tdpg"><a href="#Page_176">176</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Group: Metals and metal-compounds</td>
-    <td class="tdpg"><a href="#Page_176">176</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Lead and its compounds</td>
-    <td class="tdpg"><a href="#Page_177">177</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Zinc and its alloys</td>
-    <td class="tdpg"><a href="#Page_182">182</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Mercury and its compounds</td>
-    <td class="tdpg"><a href="#Page_183">183</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Manganese and its compounds</td>
-    <td class="tdpg"><a href="#Page_184">184</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Chromium and its compounds</td>
-    <td class="tdpg"><a href="#Page_185">185</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Nickel salts (nickel carbonyl)</td>
-    <td class="tdpg"><a href="#Page_186">186</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Copper</td>
-    <td class="tdpg"><a href="#Page_188">188</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Silver and its compounds</td>
-    <td class="tdpg"><a href="#Page_188">188</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Group: Arsenic, Phosphorus</td>
-    <td class="tdpg"><a href="#Page_189">189</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Arsenic and its oxides</td>
-    <td class="tdpg"><a href="#Page_189">189</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Phosphorus</td>
-    <td class="tdpg"><a href="#Page_190">190</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Phosphoretted hydrogen</td>
-    <td class="tdpg"><a href="#Page_191">191</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Group: Sulphuretted hydrogen, carbon bisulphide, and cyanogen (nerve poisons)</td>
-    <td class="tdpg"><a href="#Page_192">192</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Sulphuretted hydrogen</td>
-    <td class="tdpg"><a href="#Page_192">192</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Carbon bisulphide</td>
-    <td class="tdpg"><a href="#Page_193">193</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Cyanogen compounds</td>
-    <td class="tdpg"><a href="#Page_195">195</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Group: Arseniuretted hydrogen and carbonic oxide (blood poisons)</td>
-    <td class="tdpg"><a href="#Page_197">197</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Group: Hydrocarbons of the aliphatic and aromatic series and their halogen and hydroxyl substitution products</td>
-    <td class="tdpg"><a href="#Page_202">202</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Sub-group: Hydrocarbons of mineral oils and their distillation products (benzine, paraffin, &amp;c.)</td>
-    <td class="tdpg"><a href="#Page_202">202</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Sub-group: Hydrocarbons of the aromatic series</td>
-    <td class="tdpg"><a href="#Page_204">204</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub3">Benzene and its homologues</td>
-    <td class="tdpg"><a href="#Page_204">204</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub3">Naphthalene</td>
-    <td class="tdpg"><a href="#Page_208">208</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Sub-group: Halogen substitution products of the aliphatic series (narcotic poisons)</td>
-    <td class="tdpg"><a href="#Page_208">208</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Sub-group: Halogen substitution products of the benzene series</td>
-    <td class="tdpg"><a href="#Page_209">209</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Sub-group: Hydroxyl substitution products of the fatty series</td>
-    <td class="tdpg"><a href="#Page_210">210</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Group: Nitro- and amido-derivatives of the aliphatic and aromatic series</td>
-    <td class="tdpg"><a href="#Page_211">211</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Sub-group: Nitro-derivatives of the aliphatic series</td>
-    <td class="tdpg"><a href="#Page_212">212</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Sub-group: Nitro- and amido-derivatives of the aromatic series</td>
-    <td class="tdpg"><a href="#Page_212">212</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Turpentine, pyridene, alkaloids, nicotine, poisonous woods</td>
-    <td class="tdpg"><a href="#Page_215">215</a></td>
-  </tr>
-  <tr>
-    <td class="tdc" colspan="2">Part III.—Preventive measures against industrial poisoning</td>
-  </tr>
-  <tr>
-    <td><span class="smcap">General preventive measures</span></td>
-    <td class="tdpg"><a href="#GENERAL_MEASURES">217</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">International action, notification of poisoning, schedules of poisons</td>
-    <td class="tdpg"><a href="#Page_218">218</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Special preventive measures for workers—selection, periodical medical examination, co-operation of workers, &amp;c.</td>
-    <td class="tdpg"><a href="#Page_226">226</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Rescue appliances</td>
-    <td class="tdpg"><a href="#Page_230">230</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Washing accommodation and baths</td>
-    <td class="tdpg"><a href="#Page_237">237</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1"><span class="pagenum"><a name="Page_xi" id="Page_xi">[xi]</a></span>Removal of dust and fumes by exhaust ventilation</td>
-    <td class="tdpg"><a href="#Page_242">242</a></td>
-  </tr>
-  <tr>
-    <td><span class="smcap">Preventive Measures in Particular Industries</span></td>
-    <td class="tdpg"><a href="#PARTICULAR_INDUSTRIES">256</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Sulphuric acid industry</td>
-    <td class="tdpg"><a href="#Page_256">256</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Hydrochloric acid and soda industries</td>
-    <td class="tdpg"><a href="#Page_257">257</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Chlorine, bleaching powder, chlorine compounds</td>
-    <td class="tdpg"><a href="#Page_259">259</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Manufacture of nitric acid and explosives</td>
-    <td class="tdpg"><a href="#Page_260">260</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Artificial manures, basic slag</td>
-    <td class="tdpg"><a href="#Page_261">261</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Chromium and its compounds</td>
-    <td class="tdpg"><a href="#Page_265">265</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Petroleum, benzine</td>
-    <td class="tdpg"><a href="#Page_267">267</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Phosphorus, lucifer matches</td>
-    <td class="tdpg"><a href="#Page_268">268</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Bisulphide of carbon</td>
-    <td class="tdpg"><a href="#Page_271">271</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Illuminating gas, tar production</td>
-    <td class="tdpg"><a href="#Page_275">275</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Gas power plant</td>
-    <td class="tdpg"><a href="#Page_276">276</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Acetylene gas installations</td>
-    <td class="tdpg"><a href="#Page_278">278</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Ammonia</td>
-    <td class="tdpg"><a href="#Page_279">279</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Cyanogen, cyanogen compounds</td>
-    <td class="tdpg"><a href="#Page_280">280</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Coal tar, tar products</td>
-    <td class="tdpg"><a href="#Page_280">280</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Organic dye-stuffs, coal tar colours</td>
-    <td class="tdpg"><a href="#Page_285">285</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Recovery and use of metals</td>
-    <td class="tdpg"><a href="#Page_288">288</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Iron</td>
-    <td class="tdpg"><a href="#Page_289">289</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Lead</td>
-    <td class="tdpg"><a href="#Page_292">292</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub3">Lead smelting</td>
-    <td class="tdpg"><a href="#Page_299">299</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub3">Electric accumulators</td>
-    <td class="tdpg"><a href="#Page_305">305</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub3">White lead and lead colours</td>
-    <td class="tdpg"><a href="#Page_310">310</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub3">Letterpress printing</td>
-    <td class="tdpg"><a href="#Page_316">316</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub3">Ceramic industry</td>
-    <td class="tdpg"><a href="#Page_319">319</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub3">File cutting</td>
-    <td class="tdpg"><a href="#Page_321">321</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub3">Other uses of lead</td>
-    <td class="tdpg"><a href="#Page_322">322</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Zinc smelting</td>
-    <td class="tdpg"><a href="#Page_323">323</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub3">Brass casting, metal pickling</td>
-    <td class="tdpg"><a href="#Page_325">325</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Recovery and use of mercury</td>
-    <td class="tdpg"><a href="#Page_326">326</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Arsenic and its compounds</td>
-    <td class="tdpg"><a href="#Page_328">328</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub2">Gold and silver</td>
-    <td class="tdpg"><a href="#Page_329">329</a></td>
-  </tr>
-  <tr>
-    <td><span class="smcap">Preventive Measures in other trades</span></td>
-    <td class="tdpg"><a href="#OTHER_TRADES">329</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Manufacture and use of varnishes</td>
-    <td class="tdpg"><a href="#Page_330">330</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Production of vegetable foods</td>
-    <td class="tdpg"><a href="#Page_332">332</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Wood working</td>
-    <td class="tdpg"><a href="#Page_335">335</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Paper manufacture</td>
-    <td class="tdpg"><a href="#Page_336">336</a></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">Textile industries</td>
-    <td class="tdpg"><a href="#Page_336">336</a></td>
-  </tr>
-  <tr>
-    <td><span class="smcap">Appendix</span></td>
-    <td class="tdpg"><a href="#APPENDIX">339</a></td>
-  </tr>
-  <tr>
-    <td><span class="smcap">Index</span></td>
-    <td class="tdpg"><a href="#INDEX">355</a></td>
-  </tr>
-</table>
-
-<p><span class="pagenum"><a name="Page_xii" id="Page_xii">[xii]</a></span></p>
-
-<hr />
-
-<p><span class="pagenum"><a name="Page_xiii" id="Page_xiii">[xiii]</a></span></p>
-
-<h2 id="INTRODUCTION">INTRODUCTION</h2>
-
-<p>The attempt to systematise from the scientific standpoint
-the mass of material that has been collected about poisons
-is a very heavy task, even for the toxicologist who desires to
-treat his subject comprehensively. How much greater is the
-difficulty of writing a systematic book on industrial poisoning
-keeping practical application in the forefront!</p>
-
-<p>Technical considerations which are decisive in the causation
-and prevention of industrial poisoning are here of especial
-moment, and must naturally influence classification of the
-subject-matter when the object is to assist those concerned in
-factory hygiene.</p>
-
-<p>Bearing this in mind, I have divided the subject into
-three parts. The arrangement of the first, which gives as
-complete a statement as possible of the occurrence of industrial
-poisoning, into industries and processes was determined on
-technical grounds. The second, which amplifies the first,
-attempts to summarise the pathology or symptoms of the
-various forms of poisoning. The references to the literature
-of the particular subjects—as exhaustive as I could make
-them—will lighten further study. To these two parts, following
-on knowledge of causation and symptoms, the third, in
-which preventive measures are outlined, is linked.</p>
-
-<p>The apparent drawback in use of the book is that one
-form of poisoning has often to be referred to in three places.
-But, I hope, this is more than counterbalanced by the completeness
-of the scheme which results from the subdivision of
-the subject.</p>
-
-<p>The pathology of industrial poisoning necessitates frequent
-repetition when describing the branches of industry giving<span class="pagenum"><a name="Page_xiv" id="Page_xiv">[xiv]</a></span>
-rise to the intoxication, as one and the same form can occur
-in the most varied processes. The numerous instances of
-actual cases of poisoning quoted must therefore be regarded
-as conforming to the same pathological type. Similarly,
-preventive measures require separate systematic treatment in
-order to avoid constant repetition which would otherwise
-obscure the general survey. Quite a number of means of
-prevention apply equally to several industries in which the
-same cause is at work. The success attained by thus simplifying
-the issues is the greater because such common measures
-are the easier to carry through and to supervise.</p>
-
-<p>The method therefore has been adopted only after serious
-reflection and has been directed mainly by practical considerations.</p>
-
-<p>Recent cases which have either been reported or come to
-the knowledge of the author have been given, with particulars
-as exact as possible. Cases dating back some time have been
-omitted intentionally so as to exclude everything which did
-not correspond with the present conditions of industry and
-trade. Historical facts only receive consideration in so far
-as they are fundamentally important and necessary for the
-sake of completeness.</p>
-
-<p>The details given in Part I of actual instances will supply
-material for fresh efforts, renewed investigation, and new points
-of attack.</p>
-
-<hr />
-
-<p><span class="pagenum"><a name="Page_1" id="Page_1">[1]</a></span></p>
-
-<h1>INDUSTRIAL POISONING</h1>
-
-<h2 id="PART_I">PART I<br />
-<span class="smaller"><i>DESCRIPTION OF THE INDUSTRIES AND
-PROCESSES ATTENDED WITH RISK
-OF POISONING; INCIDENCE OF SUCH
-POISONING</i></span></h2>
-
-<h3 id="I_THE_CHEMICAL_INDUSTRY">I. THE CHEMICAL INDUSTRY</h3>
-
-<h4>GENERAL CONSIDERATIONS AS TO INCIDENCE OF INDUSTRIAL
-POISONING</h4>
-
-<p>The chemical industry offers naturally a wide field for the
-occurrence of industrial poisoning. Daily contact with the
-actual poisonous substances to be prepared, used, stored, and
-despatched in large quantity gives opportunity for either
-acute or chronic poisoning—in the former case from sudden
-accidental entrance into the system of fairly large doses,
-as the result of defective or careless manipulation, and, in the
-latter, constant gradual absorption (often unsuspected) of
-the poison in small amount.</p>
-
-<p>The industry, however, can take credit for the way in
-which incidence of industrial poisoning has been kept down
-in view of the magnitude and variety of the risks which often
-threaten. This is attributable to the comprehensive hygienic
-measures enforced in large chemical works keeping abreast of
-modern advance in technical knowledge. A section of this
-book deals with the principles underlying these measures.
-Nevertheless, despite all regulations, risk of poisoning cannot<span class="pagenum"><a name="Page_2" id="Page_2">[2]</a></span>
-be wholly banished. Again and again accidents and illness
-occur for which industrial poisoning is responsible. Wholly
-to prevent this is as impossible as entirely to prevent accidents
-by mechanical guarding of machinery.</p>
-
-<p>Owing to the unknown sources of danger, successful
-measures to ward it off are often difficult. The rapid advance
-of this branch of industry, the constant development of new
-processes and reactions, the frequent discovery of new materials
-(with properties at first unknown, and for a long time insufficiently
-understood, but nevertheless indispensable), constantly
-give rise to new dangers and possibilities of danger, of which
-an accident or some disease with hitherto unknown symptoms
-is the first indication. Further, even when the dangerous
-effects are recognised, there may often be difficulty in devising
-appropriate precautions, as circumstances may prevent immediate
-recognition of the action of the poison. We cannot
-always tell, for instance, with the substances used or produced
-in the processes, which is responsible for the poisoning, because,
-not infrequently, the substances in question are not chemically
-pure, but may be either raw products, bye-products, &amp;c.,
-producing mixtures of different bodies or liberating different
-chemical compounds as impurities.</p>
-
-<p>Hence difficulty often arises in the strict scientific explanation
-of particular cases of poisoning, and, in a text-book such
-as this, difficulty also of description. A rather full treatment
-of the technical processes may make the task easier and help
-to give a connected picture of the risks of poisoning in the
-chemical industry. Such a procedure may be especially
-useful to readers insufficiently acquainted with chemical
-technology.</p>
-
-<p>We are indebted to Leymann<a href="#endnote1" id="endnote-ref1"><span class="endnote-marker">1</span></a> and Grandhomme<a href="#endnote2" id="endnote-ref2"><span class="endnote-marker">2</span></a> especially
-for knowledge of incidence of industrial poisoning in
-this industry. The statistical data furnished by them are the
-most important proof that poisoning, at any rate in large
-factories, is not of very frequent occurrence.</p>
-
-<p>Leymann’s statistics relate to a large modern works in
-which the number employed during the twenty-three years of
-observation increased from 640 in the year 1891 to 1562 in
-1904, giving an average of about 1000 yearly, one-half of whom
-might properly be defined as ‘chemical workers.’ The factory<span class="pagenum"><a name="Page_3" id="Page_3">[3]</a></span>
-is concerned in the manufacture of sulphuric, nitric, and hydrochloric
-acids, alkali, bichromates, aniline, trinitro-phenol,
-bleaching powder, organic chlorine compounds, and potassium
-permanganate.</p>
-
-<p>These statistics are usefully complemented by those of
-Grandhomme drawn from the colour works at Höchst a-M.
-This large aniline works employs from 2600 to 2700 workers;
-the raw materials are principally benzene and its homologues,
-naphthalene and anthracene. The manufacture includes the
-production of coal-tar colours, nitro- and dinitro-benzene,
-aniline, rosaniline, fuchsine, and other aniline colours, and
-finally such pharmaceutical preparations as antipyrin, dermatol,
-sanoform, &amp;c. Of the 2700 employed, 1400 are chemical
-workers and the remainder labourers.</p>
-
-<p>These two series of statistics based on exact observations
-and covering allied chemical manufacture are taken together.
-They seek to give the answer to the question—How many and
-what industrial poisonings are found?</p>
-
-<p>The figures of Leymann (on an average of 1000 workers
-employed per annum) show 285 cases of poisoning reported
-between the years 1881 and 1904. Of these 275 were caused
-by aniline, toluidine, nitro- and dinitro-benzene, nitrophenol,
-nitrochloro and dinitrochloro benzene. Three were fatal and
-several involved lengthy invalidity (from 30 to 134 days, owing
-to secondary pneumonia). Included further are one severe
-case of chrome (bichromate) poisoning (with nephritis as a
-sequela), five cases of lead poisoning, three of chlorine, and one
-of sulphuretted hydrogen gas. In the Höchst a-M. factory
-(employing about 2500 workers) there were, in the ten years
-1883-92, only 129 cases of poisoning, of which 109 were
-due to aniline. Later figures for the years 1893-5 showed
-122 cases, of which 43 were due to aniline and 76 to lead
-(contracted mostly in the nitrating house). Grandhomme
-mentions further hyperidrosis among persons employed on
-solutions of calcium chloride, injury to health from inhalation
-of methyl iodide vapour in the antipyrin department, a fatal
-case of benzene poisoning (entering an empty vessel in which
-materials had previously been extracted with benzene), and
-finally ulceration and perforation of the septum of the nose
-in several chrome workers.</p>
-
-<p><span class="pagenum"><a name="Page_4" id="Page_4">[4]</a></span></p>
-
-<p>The number of severe cases is not large, but it must be
-remembered that the factories to which the figures relate are
-in every respect models of their kind, amply provided with
-safety appliances and arrangements for the welfare of the
-workers. The relatively small amount of poisoning is to be
-attributed without doubt to the precautionary measures taken.
-Further, in the statistics referred to only those cases are
-included in which the symptoms were definite, or so severe as
-to necessitate medical treatment. Absorption of the poison
-in small amount without producing characteristic symptoms,
-as is often the case with irritating or corrosive fumes, and such
-as involve only temporary indisposition, are not included.
-Leymann himself refers to this when dealing with illness
-observed in the mineral acid department (especially sulphuric
-acid), and calls attention to the frequency of affections of the
-respiratory organs among the persons employed, attributing
-them rightly to the irritating and corrosive effect of the acid
-vapour. Elsewhere he refers to the frequency of digestive
-disturbance among persons coming into contact with sodium
-sulphide, and thinks that this may be due to the action of
-sulphuretted hydrogen gas.</p>
-
-<p>Nevertheless, the effect of industrial poisons on the health
-of workers in chemical factories ought on no account to be
-made light of. The admirable results cited are due to a proper
-recognition of the danger, with consequent care to guard
-against it. Not only have Grandhomme and Leymann<a name="FNanchor_1" id="FNanchor_1"></a><a href="#Footnote_1" class="fnanchor">[A]</a>
-rendered great services by their work, but the firms in question
-also, by allowing such full and careful inquiries to be undertaken
-and published.</p>
-
-<h4>SULPHURIC ACID (SULPHUR DIOXIDE)</h4>
-
-<p><span class="smcap">Manufacture.</span>—Sulphur dioxide, generally obtained by
-roasting pyrites in furnaces of various constructions, or, more
-rarely, by burning brimstone or sulphur from the spent oxide
-of gas-works, serves as the raw material for the manufacture
-of sulphuric acid. Before roasting the pyrites is crushed, the<span class="pagenum"><a name="Page_5" id="Page_5">[5]</a></span>
-‘lump ore’ then separated from the ‘smalls,’ the former
-roasted in ‘lump-burners’ or kilns (generally several roasting
-furnace hearths united into one system), and the latter
-preferably in Malétra and Malétra-Schaffner shelf-burners
-(<a href="#fig1">fig. 1</a>) composed of several superimposed firebrick shelves.
-The pyrites is charged on to the uppermost shelf and gradually
-worked downwards. Pyrites residues are not suitable for direct
-recovery of iron, but copper can be recovered from residues
-sufficiently rich in metal by the wet process; the residues
-thus freed of copper and sulphur are then smelted for
-recovery of iron.</p>
-
-<div class="figcenter" style="width: 400px;" id="fig1">
-
-<img src="images/fig1.jpg" width="400" height="350" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 1.</span>—Pyrites Burner for Smalls (<i>after Lueger</i>)</p>
-
-</div>
-
-<p>Utilisation for sulphuric acid manufacture of the sulphur
-dioxide given off in the calcining of zinc blende (see Spelter
-works), impracticable in reverberatory furnaces, has been
-made possible at the Rhenania factory by introduction of
-muffle furnaces (several superimposed), because by this means
-the gases led off are sufficiently concentrated, as they are not
-diluted with the gases and smoke from the heating fires.
-This method, like any other which utilises the gases from
-roasting furnaces, has great hygienic, in addition to economical,
-advantages, because escape of sulphur dioxide gas is avoided.
-Furnace gases, too poor in sulphur dioxide to serve for direct
-production of sulphuric acid, can with advantage be made to<span class="pagenum"><a name="Page_6" id="Page_6">[6]</a></span>
-produce liquid anhydrous sulphur dioxide. Thus, the sulphur
-dioxide gas from the furnaces is first absorbed by water, driven
-off again by boiling, cooled, dried, and liquefied by pressure.</p>
-
-<p>The gaseous sulphur dioxide obtained by any of the
-methods described is converted into sulphuric acid either by
-(<i>a</i>) the chamber process or (<i>b</i>) the contact process.</p>
-
-<p>In the <i>lead chamber process</i> the furnace gases pass through
-flues in which the flue dust and a portion of the arsenious acid
-are deposited into the Glover tower at a temperature of about
-300° C., and from there into the lead chambers where oxidation
-of the sulphur dioxide into sulphuric acid takes place, in the
-presence of sufficient water, by transference of the oxygen of
-the air through the intervention of the oxides of nitrogen.
-The gases containing oxides of nitrogen, &amp;c., which are drawn
-out of the lead chambers, have the nitrous fumes absorbed in
-the Gay-Lussac tower (of which there are one or two in series),
-by passage through sulphuric acid which is made to trickle
-down the tower. The sulphuric acid so obtained, rich in
-oxides of nitrogen, and the chamber acid are led to the Glover
-tower for the purpose of denitration and concentration, so
-that all the sulphuric acid leaves the Glover as Glover acid of
-about 136-144° Tw. Losses in nitrous fumes are best made
-up by addition of nitric acid at the Glover or introduction
-into the first chamber. The deficiency is also frequently made
-good from nitre-pots.</p>
-
-<p>The lead chambers (<a href="#fig2">fig. 2</a>) are usually constructed entirely—sides,
-roof, and floor—of lead sheets, which are joined together
-by means of a hydrogen blowpipe. The sheets forming the
-roof and walls are supported, independent of the bottom, on
-a framework of wood. The capacity varies from 35,000 to
-80,000 cubic feet. The floor forms a flat collecting surface for
-the chamber acid which lutes the chamber from the outer air.
-The necessary water is introduced into the chamber as steam
-or fine water spray.</p>
-
-<p>The Glover and Gay-Lussac towers are lead towers. The
-Glover is lined with acid-proof bricks and filled with acid-proof
-packing to increase the amount of contact. The Gay-Lussac
-is filled with coke over which the concentrated sulphuric
-acid referred to above flows, forming, after absorption
-of the nitrous fumes, nitro-sulphuric acid.</p>
-
-<p><span class="pagenum"><a name="Page_7" id="Page_7">[7]</a></span></p>
-
-<div class="figcenter" style="width: 500px;" id="fig2">
-
-<p class="caption"><span class="smcap">Fig. 2a.</span>—Lead Chamber System—Section through X X (<i>after Ost</i>)</p>
-
-<img src="images/fig2.jpg" width="500" height="700" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 2b.</span>—Lead Chamber System—Plan</p>
-
-<ul>
-<li>A Pyrites Burner</li>
-<li>B Glover Tower</li>
-<li>C Draft Regulator</li>
-<li>D, D´ Lead Chambers</li>
-<li>E Air Shaft</li>
-<li>F, F,´ F,´´ F´´´ Acid Reservoirs</li>
-<li>G Acid Egg</li>
-<li>H Cooler</li>
-<li>J Gay-Lussac Tower</li>
-</ul>
-
-</div>
-
-<p><span class="pagenum"><a name="Page_8" id="Page_8">[8]</a></span></p>
-
-<p>As already stated, two Gay-Lussac towers are usually
-connected together, or where there are several lead-chamber
-systems there is, apart from the Gay-Lussac attached to each,
-a central Gay-Lussac in addition, common to the whole series.
-The introduction of several Gay-Lussac towers has the advantage
-of preventing loss of the nitrous fumes as much as possible—mainly
-on economical grounds, as nitric acid is expensive.
-But this arrangement is at the same time advantageous on
-hygienic grounds, as escape of poisonous gases containing
-nitrous fumes, &amp;c., is effectually avoided. The acids are
-driven to the top of the towers by compressed air. The whole
-system—chambers and towers—is connected by means of
-wide lead conduits. Frequently, for the purpose of quickening
-the chamber process (by increasing the number of condensing
-surfaces) Lunge-Rohrmann plate towers are inserted in the
-system—tall towers lined with lead in which square perforated
-plates are hung horizontally, and down which diluted sulphuric
-acid trickles.</p>
-
-<p>To increase the draught in the whole system a chimney is
-usual at the end, and, in addition, a fan of hard lead or earthenware
-may be introduced in front of the first chamber or
-between the two Gay-Lussac towers. Maintenance of a
-constant uniform draught is not only necessary for technical
-reasons, but has hygienic interest, since escape of injurious
-gases is avoided (see also Part III).</p>
-
-<p>The chamber acid (of 110°-120° Tw. = 63-70 %) and the
-stronger Glover acid (of 136°-144° Tw. = 75-82 %) contain
-impurities. In order to obtain for certain purposes pure
-strong acid the chamber acid is purified and concentrated.
-The impurities are notably arsenious and nitrous acids (Glover
-acid is N free), lead, copper, and iron. Concentration (apart
-from that to Glover acid in the Glover tower) is effected by
-evaporation in lead pans to 140° Tw. and finally in glass balloons
-or platinum stills to 168° Tw. (= 97 %). The lead pans are
-generally heated by utilising the waste heat from the furnaces
-or by steam coils in the acid itself, or even by direct firing.</p>
-
-<p>Production of sulphuric acid by the <i>contact method</i> depends
-on the fact that a mixture of sulphur dioxide and excess of
-oxygen (air) combines to form sulphur trioxide at a moderate heat
-in presence of a contact substance such as platinised asbestos<span class="pagenum"><a name="Page_9" id="Page_9">[9]</a></span>
-or oxide of iron. The sulphur dioxide must be carefully
-cleaned and dried, and with the excess of air is passed through
-the contact substance. If asbestos carrying a small percentage
-of finely divided platinum is the contact substance, it is
-generally used in the form of pipes; oxide of iron (the residue
-of pyrites), if used, is charged into a furnace. Cooling by a
-coil of pipes and condensation in washing towers supplied with
-concentrated sulphuric acid always forms a part of the process.
-A fan draws the gases from the roasting furnaces and drives
-them through the system. The end product is a fuming
-sulphuric acid containing 20-30 per cent. SO₃. From this by
-distillation a concentrated acid and a pure anhydride are
-obtained. From a health point of view it is of importance
-to know that all sulphuric acid derived from this anhydride
-is pure and free from arsenic.</p>
-
-<p>The most important <i>uses</i> of sulphuric acid are the following:
-as chamber acid (110°-120° Tw.) in the superphosphate,
-ammonium sulphate, and alum industries; as Glover acid
-(140°-150° Tw.) in the Leblanc process, i.e. saltcake and
-manufacture of hydrochloric acid, and to etch metals; as
-sulphuric acid of 168° Tw. in colour and explosives manufacture
-(nitric acid, nitro-benzene, nitro-glycerine, gun-cotton,
-&amp;c.); as concentrated sulphuric acid and anhydride for the
-production of organic sulphonic acids (for the alizarin and
-naphthol industry) and in the refining of petroleum and
-other oils. Completely de-arsenicated sulphuric acid is used
-in making starch, sugar, pharmaceutical preparations, and
-in electrical accumulator manufacture.</p>
-
-<p><span class="smcap">Effects on Health.</span>—The health of sulphuric acid workers
-cannot in general be described as unfavourable.</p>
-
-<p>In comparison with chemical workers they have, it is said,
-relatively the lowest morbidity. Although in this industrial
-occupation no special factors are at work which injure in
-general the health of the workers, there is a characteristic
-effect, without doubt due to the occupation—namely, disease
-of the respiratory organs. Leymann’s figures are sufficiently
-large to show that the number of cases of diseases of the
-respiratory organs is decidedly greater in the sulphuric acid
-industry than among other chemical workers. He attributes
-this to the irritating and corrosive effect of sulphur dioxide<span class="pagenum"><a name="Page_10" id="Page_10">[10]</a></span>
-and sulphuric acid vapour on the mucous membrane of the
-respiratory tract, as inhalation of these gases can never be
-quite avoided, because the draught in the furnace and chamber
-system varies, and the working is not always uniform.
-Strongly irritating vapours escape again in making a high
-percentage acid in platinum vessels, which in consequence
-are difficult to keep air-tight. Of greater importance than
-these injurious effects from frequent inhalation of small
-quantities of acid vapours, or employment in workrooms
-in which the air is slightly charged with acid, is the accidental
-sudden inhalation of large quantities of acid gases, which
-may arise in the manufacture, especially by careless attendance.
-Formerly this was common in charging the roasting furnaces
-when the draught in the furnace, on addition of the pyrites,
-was not strengthened at the same time. This can be easily
-avoided by artificial regulation of the draught.</p>
-
-<p>Accidents through inhalation of acid gases occur further
-when entering the lead chambers or acid tanks, and in emptying
-the towers. Heinzerling relates several cases taken from
-factory inspectors’ reports. Thus, in a sulphuric acid factory
-the deposit (lead oxysulphate) which had collected on the
-floor of a chamber was being removed: to effect this the lead
-chambers were opened at the side. Two of the workers, who
-had probably been exposed too long to the acid vapours
-evolved in stirring up the deposit, died a short time after they
-had finished the work. A similar fatality occurred in cleaning
-out a nitro-sulphuric acid tank, the required neutralisation
-of the acid by lime before entering having been omitted. Of
-the two workers who entered, one died the next day; the other
-remained unaffected. The deceased had, as the post mortem
-showed, already suffered previously from pleurisy. A fatality
-from breathing nitrous fumes is described fully in the report
-of the Union of Chemical Industry for the year 1905. The
-worker was engaged with two others in fixing a fan to a lead
-chamber; the workers omitted to wait for the arrival of the
-foreman who was to have supervised the operation. Although
-the men used moist sponges as respirators, one of them inhaled
-nitrous fumes escaping from the chamber in such quantity
-that he died the following day.</p>
-
-<p>Similar accidents have occurred in cleaning out the Gay-Lussac<span class="pagenum"><a name="Page_11" id="Page_11">[11]</a></span>
-towers. Such poisonings have repeatedly occurred
-in Germany. Fatal poisoning is recorded in the report of
-the Union of Chemical Industry, in the emptying and cleaning
-of a Gay-Lussac tower despite careful precautions. The
-tower, filled with coke, had been previously well washed with
-water, and during the operation of emptying, air had been
-constantly blown through by means of a Körting’s injector.
-The affected worker had been in the tower about an hour;
-two hours later symptoms of poisoning set in which proved
-fatal in an hour despite immediate medical attention. As
-such accidents kept on recurring, the Union of Chemical
-Industry drew up special precautions to be adopted in the
-emptying of these towers, which are printed in Part III.</p>
-
-<p>Naturally, in all these cases it is difficult to say exactly
-which of the acid gases arising in the production of sulphuric
-acid was responsible for the poisoning. In the fatal cases
-cited, probably nitrous fumes played the more important part.</p>
-
-<p>Poisoning has occurred in the transport of sulphuric acid.
-In some of the cases, at all events, gaseous impurities, especially
-arseniuretted hydrogen, were present.</p>
-
-<p>Thus, in the reports of the German Union of Chemical
-Industry for the year 1901, a worker succumbed through
-inhalation of poisonous gases in cleaning out a tank waggon
-for the transport of sulphuric acid. The tank was cleaned of
-the adhering mud, as had been the custom for years, by a
-man who climbed into it. No injurious effects had been
-noted previously at the work, and no further precautions were
-taken than that one worker relieved another at short intervals,
-and the work was carried on under supervision. On the
-occasion in question, however, there was an unusually large
-quantity of deposit, although the quality of the sulphuric
-acid was the same, and work had to be continued longer.
-The worker who remained longest in the tank became ill on his
-way home and died in hospital the following day; the other
-workers were only slightly affected. The sulphuric acid used
-by the firm in question immediately before the accident came
-from a newly built factory in which anhydrous sulphuric
-acid had been prepared by a special process. The acid was
-Glover acid, and it is possible that selenium and arsenic
-compounds were present in the residues. Arseniuretted<span class="pagenum"><a name="Page_12" id="Page_12">[12]</a></span>
-hydrogen might have been generated in digging up the mud.
-Two similar fatalities are described in the report of the same
-Union for the year 1905. They happened similarly in cleaning
-out a sulphuric acid tank waggon, and in them the arsenic in
-the acid was the cause. Preliminary swilling out with water
-diluted the remainder of the sulphuric acid, but, nevertheless,
-it acted on the iron of the container. Generation of hydrogen
-gas is the condition for the reduction of the arsenious acid
-present in sulphuric acid with formation of arseniuretted
-hydrogen. In portions of the viscera arsenic was found.
-Lately in the annual reports of the Union of Chemical Industry
-for 1908 several cases of poisoning are described which were
-caused by sulphuric acid. A worker took a sample out of a
-vessel of sulphuric acid containing sulphuretted hydrogen gas.
-Instead of using the prescribed cock, he opened the man-hole
-and put his head inside, inhaling concentrated sulphuretted
-hydrogen gas. He became immediately unconscious and
-died. Through ignorance no use was made of the oxygen
-apparatus.</p>
-
-<p>Another fatality occurred through a foreman directing
-some workers, contrary to the regulations against accidents
-from nitrous gases, to clean a vessel containing nitric and
-sulphuric acids. They wore no air helmets: one died shortly
-after from inhalation of nitrous fumes. Under certain circumstances
-even the breaking of carboys filled with sulphuric acid
-may give rise to severe poisoning through inhalation of acid
-gases. Thus a fatality<a href="#endnote3" id="endnote-ref3"><span class="endnote-marker">1</span></a> occurred to the occupier of a workroom
-next some premises in which sulphuric acid carboys had been
-accidentally broken. Severe symptoms developed the same
-night, and he succumbed the next morning in spite of treatment
-with oxygen. A worker in the factory became seriously
-ill but recovered.</p>
-
-<p>A similar case is described<a href="#endnote4" id="endnote-ref4"><span class="endnote-marker">2</span></a> in a factory where concentrated
-sulphuric acid had been spilt. The workers covered the spot
-with shavings, which resulted in strong development of sulphur
-dioxide, leading to unconsciousness in one worker.</p>
-
-<p>The frequent observation of the injurious effect of acid
-gases on the teeth of workers requires mention; inflammation
-of the eyes of workers also is attributed to the effects of
-sulphuric acid.</p>
-
-<p><span class="pagenum"><a name="Page_13" id="Page_13">[13]</a></span></p>
-
-<p>Leymann’s statistics show <i>corrosions and burns</i> among
-sulphuric acid workers to be more than five times that among
-other classes. Such burns happen most frequently from
-carelessness. Thus, in the reports of the Union of Chemical
-Industry for 1901, three severe accidents are mentioned
-which occurred from use of compressed air. In two cases the
-acid had been introduced before the compressed air had been
-turned off; in the third the worker let the compressed air
-into the vessel and forgot to turn off the inlet valve. Although
-the valves were provided with lead guards, some of the acid
-squirted into the worker’s face. In one case complete blindness
-followed, in a second blindness in one eye, and in the third
-blindness in one eye and impaired vision of the other.</p>
-
-<p>Besides these dangers from the raw material, bye-products,
-and products of the manufacture, <i>lead poisoning</i> has been
-reported in the erection and repair of lead chambers. The
-lead burners generally use a hydrogen flame; the necessary
-hydrogen is usually made from zinc and sulphuric acid and
-is led to the iron by a tube. If the zinc and sulphuric acid
-contain arsenic, the very dangerous arseniuretted hydrogen is
-formed, which escapes through leakages in the piping, or is
-burnt in the flame to arsenious acid.</p>
-
-<p>Further, the lead burners and plumbers are exposed to the
-danger of chronic lead poisoning from insufficient observance
-of the personal precautionary measures necessary to guard
-against it (see Part III). Those who are constantly engaged
-in burning the lead sheets and pipes of the chambers suffer
-not infrequently from severe symptoms. Unfortunately, the
-work requires skill and experience, and hence alternation of
-employment is hardly possible.</p>
-
-<p>Finally, mention should be made of poisoning by <i>arseniuretted
-hydrogen gas</i> from vessels filled with sulphuric acid containing
-arsenic as an impurity, and by sulphuretted hydrogen
-gas in purifying the acid itself. In the manufacture of liquid
-<i>sulphur dioxide</i>, injury to health can arise from inhalation of
-the acid escaping from the apparatus. The most frequent
-cause for such escape of sulphur dioxide is erosion of the walls
-of the compressor pumps and of the transport vessels, in
-consequence of the gas being insufficiently dried, as, when
-moist, it attacks iron.</p>
-
-<p><span class="pagenum"><a name="Page_14" id="Page_14">[14]</a></span></p>
-
-<p>Sulphur dioxide will come up for further consideration
-when describing the industrial processes giving rise to it, or in
-which it is used.</p>
-
-<h4>HYDROCHLORIC ACID, SALTCAKE, AND SODA</h4>
-
-<p><span class="smcap">Manufacture.</span>—The production of hydrochloric acid
-(HCl), sodium sulphate (Na₂SO₄), and sodium sulphide (Na₂S)
-forms part of the manufacture of soda (Na₂CO₃) by the Leblanc
-process. The products first named increase in importance,
-while the Leblanc soda process is being replaced more and more
-by the manufacture of soda by the Solvay ammonia process,
-so much so that on the Continent the latter method predominates
-and only in England does the Leblanc process hold
-its ground.</p>
-
-<p>Health interests have exercised an important bearing on
-the development of the industries in question. At first, in the
-Leblanc process the hydrochloric acid gas was allowed to
-escape into the atmosphere, being regarded as a useless bye-product.
-Its destructive action on plant life and the inconvenience
-caused to the neighbourhood, in spite of erection of
-high chimneys, demanded intervention. In England the evils
-led to the enactment of the Alkali Acts—the oldest classical
-legislative measures bearing on factory hygiene—by which the
-Leblanc factories were required to condense the vapour by
-means of its absorption in water, and this solution of the acid
-is now a highly valued product. And, again, production of
-nuisance—inconvenience to the neighbourhood through the
-soda waste—was the main cause of ousting one of the oldest
-and most generally used methods of chemical industrial production.
-Although every effort was made to overcome the
-difficulties, the old classical Leblanc process is gradually but
-surely yielding place to the modern Solvay process, which
-has no drawback on grounds of health.</p>
-
-<p>We outline next the main features of the <i>Leblanc soda
-process</i>, which includes, as has been mentioned, also the manufacture
-of hydrochloric acid, sodium sulphate and sulphide.</p>
-
-<p>The first part of the process consists in the production of the
-sulphate from salt and sulphuric acid, during which hydrochloric
-acid is formed; this is carried out in two stages
-represented in the following formulæ:</p>
-
-<p><span class="pagenum"><a name="Page_15" id="Page_15">[15]</a></span></p>
-
-<ul>
-<li>1. NaCl + H₂SO₄ = NaHSO₄ + HCl.</li>
-<li>2. NaCl + NaHSO₄ = Na₂SO₄ + HCl.</li>
-</ul>
-
-<p>The first stage in which bisulphate is produced is carried
-out at a moderate heat, the second requires a red heat. The
-reactions, therefore, are made in a furnace combining a pan and
-muffle furnace.</p>
-
-<p>This saltcake muffle furnace is so arranged that the pan can
-be shut off from the muffle by a sliding-door (D). The pan
-(A) and muffle (E) have separate flues for carrying off the
-hydrochloric acid developed (B, F). First, common salt is
-treated with sulphuric (Glover) acid in the cast-iron pan. When
-generation of hydrochloric acid vapour has ceased, the sliding-door
-is raised and the partly decomposed mixture is pushed
-through into the muffle, constructed of fire-resisting bricks and
-tiles, and surrounded by the fire gases. While the muffle is
-being raised to red heat, the sulphate must be repeatedly
-stirred with a rake in order, finally, while still hot and giving off
-acid vapour, to be drawn out at the working doors into iron
-boxes provided with doors, where the material cools. The acid
-vapour given off when cooling is drawn through the top of the
-box into the furnace.</p>
-
-<div class="figcenter" style="width: 400px;" id="fig3">
-
-<img src="images/fig3.jpg" width="400" height="200" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 3.</span>—Saltcake Muffle Furnace—Section <i>(after Ost</i>)</p>
-
-<p class="caption">A Pan; B, F Pipes for hydrochloric acid vapour; D Shutter; E Muffle,
-O Coke fire.</p>
-
-</div>
-
-<p>Mechanical stirrers, despite their advantage from a health
-point of view, have not answered because of their short life.</p>
-
-<p>The valuable bye-product of the sulphate process, <i>hydrochloric
-acid</i>, is led away separately from the pan and the<span class="pagenum"><a name="Page_16" id="Page_16">[16]</a></span>
-muffle, as is seen, into one absorption system. The reason of
-the separation is that the gas from the pan is always the more
-concentrated. The arrangement of the absorbing apparatus
-is illustrated in <a href="#fig4">fig. 4</a>.</p>
-
-<div class="figcenter" style="width: 500px;" id="fig4">
-
-<p class="caption"><span class="smcap">Fig. 4a.</span>—Preparation of Hydrochloric Acid—Plan (<i>after Lueger</i>)</p>
-
-<ul>
-<li>A, A´ Earthenware pipes</li>
-<li>B, B´ Sandstone cooling towers</li>
-<li>C, C Series of Woulff’s bottles</li>
-<li>D, E Condenser wash towers</li>
-</ul>
-
-<img src="images/fig4.jpg" width="500" height="650" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 4b.</span>—Elevation</p>
-
-</div>
-
-<p>The gases are led each through earthenware pipes or<span class="pagenum"><a name="Page_17" id="Page_17">[17]</a></span>
-channels of stone pickled with tar (A´), first into small towers
-of Yorkshire flags (B), where they are cooled and freed from flue
-dust and impurities (sulphuric acid) by washing. They are
-next led through a series (over fifty) of Woulff bottles (bombonnes)
-one metre high, made of acid-resisting stoneware.
-The series is laid with a slight inclination towards the furnace,
-and water trickles through so that the gases coming from the
-wash towers are brought into contact with water in the one
-case already almost saturated, whilst the gas which is poorest
-in hydrochloric acid meets with fresh water. From the bombonne
-situated next to the wash tower the prepared acid is
-passed as a rule through another series. The last traces of
-hydrochloric acid are then removed by leading the gases from
-the Woulff bottles up two water towers of stoneware (D and E),
-which are filled partly with earthenware trays and partly with
-coke; above are tanks from which the water trickles down over
-the coke. The residual gases from both sets of absorbing
-apparatus now unite in a large Woulff bottle before finally
-being led away through a duct to the chimney stack.</p>
-
-<p>Less frequently absorption of hydrochloric acid is effected
-without use of Woulff bottles, principally in wash towers such
-as the Lunge-Rohrmann plate tower.</p>
-
-<p>In the purification of hydrochloric acid, de-arsenicating by
-sulphuretted hydrogen or by barium sulphide, &amp;c., and separation
-of sulphuric acid by addition of barium chloride, have to be
-considered.</p>
-
-<p>Another method for production of sulphate and hydrochloric
-acid, namely, the Hargreaves process, is referred to later.</p>
-
-<p>We return now to the further working up of the sodium
-sulphate into sulphide and soda. The conversion of the
-sulphate into soda by the Leblanc method is effected by
-heating with coal and calcium carbonate, whereby, through the
-action of the coal, sodium sulphide forms first, which next
-with the calcium carbonate becomes converted into sodium
-carbonate and calcium sulphide.</p>
-
-<p>The reactions are:</p>
-
-<ul>
-<li>Na₂SO₄ + 2C = Na₂S + 2CO₂</li>
-<li>Na₂S + CaCO₃ = Na₂CO₃ + CaS</li>
-<li>CaCO₃ + C = CaO + 2CO.</li>
-</ul>
-
-<p><span class="pagenum"><a name="Page_18" id="Page_18">[18]</a></span></p>
-
-<p>The reactions are carried out in small works in open
-reverberatory furnaces having two platforms on the hearth, and
-with continuous raking from one to the other which, as the
-equations show, cause escape of carbonic
-acid gas and carbonic oxide.</p>
-
-<p>Such handworked furnaces, apart
-from their drawbacks on health
-grounds, have only a small capacity,
-and in large works their place is
-taken by revolving furnaces—closed,
-movable cylindrical furnaces—in which
-handwork is replaced by the mechanical
-revolution of the furnace and from
-which a considerably larger output
-and a product throughout good in
-quality are obtained.</p>
-
-<p>The <i>raw soda</i> thus obtained in
-the black ash furnace is subjected to
-lixiviation by water in iron tanks in
-which the impurities or tank waste
-(see below) are deposited. The crude
-soda liquor so obtained is then further
-treated and converted into calcined
-soda, crystal soda, or caustic soda.
-In the production of calcined soda
-the crude soda liquor is first purified
-(‘oxidised’ and ‘carbonised’) by
-blowing through air and carbonic acid
-gas, pressed through a filter press, and
-crystallised by evaporation in pans
-and calcined, i.e. deprived of water by
-heat.</p>
-
-<div class="figcenter" style="width: 500px;" id="fig5">
-
-<img src="images/fig5.jpg" width="500" height="125" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 5.</span>—Revolving Black Ash Furnace—Elevation (<i>after Lueger</i>)</p>
-
-<p class="caption">A Firing hearth; B Furnace; C Dust box.</p>
-
-</div>
-
-<p><i>Crystal soda</i> is obtained from well-purified
-tank liquor by crystallising in
-cast-iron vessels.</p>
-
-<p>Caustic soda is obtained by introducing lime suspended in
-iron cages into the soda liquor in iron caustic pots, heating with
-steam, and agitating by blowing in air.</p>
-
-<p>The resulting clear solution is drawn off and evaporated in
-cast-iron pans.</p>
-
-<p><span class="pagenum"><a name="Page_19" id="Page_19">[19]</a></span></p>
-
-<p>As already mentioned, the <i>tank waste</i> in the Leblanc process,
-which remains behind—in amount about equal to the soda
-produced after lixiviation of the raw soda with water—constitutes
-a great nuisance. It forms mountains round the
-factories, and as it consists principally of calcium sulphide
-and calcium carbonate, it easily weathers under the influence
-of air and rain, forming soluble sulphur compounds and
-developing sulphuretted hydrogen gas—an intolerable source
-of annoyance to the district.</p>
-
-<p>At the same time all the sulphur introduced into the
-industry as sulphuric acid is lost in the tank waste. This loss
-of valuable material and the nuisance created led to attempts—partially
-successful—to recover the sulphur.</p>
-
-<p>The best results are obtained by the Chance-Claus method,
-in which the firebrick ‘Claus-kiln’ containing ferric oxide
-(previously heated to dull redness) is used. In this process
-calcium sulphide is acted on by carbonic acid with evolution of
-gas so rich in sulphuretted hydrogen that it can be burnt to
-sulphur dioxide and used in the lead chambers for making sulphuric
-acid. Sulphur also as such is obtained by the method.</p>
-
-<p>These sulphur-recovery processes which have hardly been
-tried on the Continent—only the United Alkali Company in
-England employs the Chance-Claus on a large scale—were, as
-has been said, not in a position to prevent the downfall of the
-Leblanc soda industry. Before describing briefly the Solvay
-method a word is needed as to other processes for manufacture
-of sulphate and hydrochloric acid.</p>
-
-<p><i>Hargreaves’ process</i> produces sodium sulphate (without
-previous conversion of sulphur dioxide into sulphuric acid)
-directly by the passage of gases from the pyrites burners, air
-and steam, through salt blocks placed in vertical cast-iron
-retorts, a number of which are connected in series. A fan draws
-the gases through the system and leads the hydrochloric acid
-fumes to the condenser.</p>
-
-<p>Sodium sulphate is used in the manufacture of glass,
-ultramarine, &amp;c. Further, the sulphate is converted into
-Glauber’s salts by dissolving the anhydrous sulphate obtained
-in the muffle furnace, purifying with lime, and allowing the
-clear salt solution to crystallise out in pans.</p>
-
-<p>A further use of the sulphate is the preparation of sodium<span class="pagenum"><a name="Page_20" id="Page_20">[20]</a></span>
-sulphide, which is effected (as in the first part of the Leblanc
-soda process) by melting together sulphate and coal in a
-reverberatory furnace. If the acid sulphate (bisulphate) or
-sulphate containing bisulphate is used much sulphur dioxide
-gas comes off.</p>
-
-<p>The mass is then lixiviated in the usual soda liquor vats
-and the lye either treated so as to obtain crystals or evaporated
-to strong sodium sulphide which is poured like caustic soda
-into metal drums where it solidifies.</p>
-
-<p>In <i>Solvay’s ammonia soda process</i> ammonia recovered from
-the waste produced in the industry is led into a solution of
-salt until saturation is complete. This is effected generally in
-column apparatus such as is used in distillation of spirit. The
-solution is then driven automatically by compressed air to
-the carbonising apparatus in which the solution is saturated
-with carbonic acid; this apparatus is a cylindrical tower
-somewhat similar to the series of vessels used for saturating
-purposes in sugar factories through which carbonic acid gas
-passes. In this process crystalline bi-carbonate of soda is
-first formed, which is separated from the ammoniacal mother
-liquor by filtration, centrifugalisation, and washing. The
-carbonate is then obtained by heating (calcining in pans),
-during which carbonic acid gas escapes, and this, together
-with the carbonic acid produced in the lime kilns, is utilised
-for further carbonisation again. The lime formed during
-the production of carbonic acid in the lime kilns serves to drive
-the ammonia out of the ammoniacal mother liquor, so that the
-ammonia necessary for the process is recovered and used over
-and over again. The waste which results from the action of
-the lime on the ammonium chloride liquor is harmless—calcium
-chloride liquor.</p>
-
-<p>The <i>electrolytic</i> manufacture of soda from salt requires
-mention, in which chlorine (at the anode) and caustic soda
-(at the cathode) are formed; the latter is treated with carbonic
-acid to make soda.</p>
-
-<p><span class="smcap">Effects on Health.</span>—Leymann’s observations show that
-in the department concerned with the Leblanc soda process
-and production of sodium sulphide, relatively more sickness
-is noted than, for example, in the manufacture of sulphuric
-and nitric acids.</p>
-
-<p><span class="pagenum"><a name="Page_21" id="Page_21">[21]</a></span></p>
-
-<p>In the preparation of the sulphate, possibility of injury to
-health or poisoning arises from the fumes containing hydrochloric
-or sulphuric acid in operations at the muffle furnace;
-in Hargreaves’ process there may be exposure to the effect
-of sulphur dioxide. Hydrochloric and sulphuric acid vapours
-can escape from the muffle furnace when charging, from
-leakages in it, and especially when withdrawing the still hot
-sulphate. Large quantities of acid vapours escape from the
-glowing mass, especially if coal is not added freely and if it
-is not strongly calcined. Persons employed at the saltcake
-furnaces suffer, according to Jurisch, apart from injury to
-the lungs, from defective teeth. The teeth of English workers
-especially, it is said, from the practice of holding flannel in
-their mouths with the idea of protecting themselves from the
-effect of the vapours, are almost entirely eroded by the action
-of the hydrochloric acid absorbed by the saliva. Hydrochloric
-acid vapour, further, can escape from the absorbing apparatus
-if this is not kept entirely sealed, and the hydrochloric acid
-altogether absorbed—a difficult matter. Nevertheless, definite
-acute industrial poisoning from gaseous hydrochloric acid is
-rare, no doubt because the workers do not inhale it in concentrated
-form.</p>
-
-<p>Injury to the skin from the acid absorbed in water may
-occur in filling, unloading, and transport, especially when in
-carboys, but the burns, if immediately washed, are very slight
-in comparison with those from sulphuric or nitric acids.
-Injury to health or inconvenience from sulphuretted hydrogen
-is at all events possible in the de-arsenicating process by means
-of sulphuretted hydrogen gas. At the saltcake furnace when
-worked by hand the fumes containing carbonic oxide gas may
-be troublesome. In the production of caustic soda severe
-corrosive action on the skin is frequent. Leymann found that
-13·8 per cent. of the persons employed in the caustic soda
-department were reported as suffering from burns, and calls
-attention to the fact that on introducing the lime into the hot
-soda lye the contents of the vessel may easily froth over.
-Heinzerling refers to the not infrequent occurrence of eye
-injuries in the preparation of caustic soda, due to the spurting
-of lye or of solid particles of caustic soda.</p>
-
-<p>The tank waste gives rise, as already stated, to inconvenience<span class="pagenum"><a name="Page_22" id="Page_22">[22]</a></span>
-from the presence of sulphuretted hydrogen. In the recovery
-of the sulphur and treatment of the tank waste, sulphuretted
-hydrogen and sulphur dioxide gases are evolved. According
-to Leymann, workers employed in removing the waste and
-at the lye vats frequently suffer from inflammation of the
-eyes. Further, disturbance of digestion has been noted in
-persons treating the tank waste, which Leymann attributes
-to the unavoidable development of sulphuretted hydrogen
-gas.</p>
-
-<p>In the manufacture of sodium sulphide similar conditions
-prevail. Leymann found in this branch relatively more
-cases of sickness than in any other; diseases of the digestive
-tract especially appeared to be more numerous. Leymann
-makes the suggestion that occurrence of disease of the digestive
-organs is either favoured by sodium sulphide when swallowed
-as dust, or that here again sulphuretted hydrogen gas plays a
-part. Further corrosive effect on the skin and burns may
-easily arise at work with the hot corrosive liquor.</p>
-
-<p>In the Solvay ammonia process ammonia and carbonic acid
-gas are present, but, so far as I know, neither injury to health
-nor poisoning have been described among persons employed
-in the process. Indeed, the view is unanimous that this method
-of manufacture with its technical advantages has the merit
-also of being quite harmless. As may be seen from the preceding
-description of the process there is no chance of the
-escape of the gases named into the workrooms.</p>
-
-<h4>USE OF SULPHATE AND SULPHIDE</h4>
-
-<p><i>Ultramarine</i> is made from a mixture of clay, sulphate
-(Glauber’s salts), and carbon—sulphate ultramarine; or clay,
-sulphur, and soda—soda ultramarine. These materials are
-crushed, ground, and burnt in muffle furnaces. On heating
-the mass in the furnace much sulphur dioxide escapes, which
-is a source of detriment to the workmen and the neighbourhood.</p>
-
-<p><i>Sulphonal</i> (CH₃)₂C(SO₂C₂H₅)₂, diethylsulphone dimethylmethane,
-used medically as a hypnotic, is obtained from
-mercaptan formed by distillation of ethyl sulphuric acid with
-sodium or potassium sulphide. The mercaptan is converted
-into mercaptol, and this by oxidation with potassium permanganate
-into sulphonal. The volatile mercaptan has a most<span class="pagenum"><a name="Page_23" id="Page_23">[23]</a></span>
-disgusting odour, and clings for a long time even to the clothes
-of those merely passing through the room.</p>
-
-<p><i>Diethyl sulphate</i> ((C₂H₅)₂SO₄).—Diethyl sulphate obtained
-by the action of sulphuric acid on alcohol has led to poisoning
-characterised by corrosive action on the respiratory tract.<a href="#endnote5" id="endnote-ref5"><span class="endnote-marker">1</span></a> As
-the substance in the presence of water splits up into sulphuric
-acid and alcohol, this corrosive action is probably due to the
-acid. It is possible, however, that the molecule of diethyl
-sulphate as such has corrosive action.</p>
-
-<p>Contact with diethyl sulphate is described as having led to
-fatal poisoning.<a href="#endnote6" id="endnote-ref6"><span class="endnote-marker">2</span></a> </p>
-
-<p>A chemist when conducting a laboratory experiment
-dropped a glass flask containing about 40 c.c. of diethyl
-sulphate, thereby spilling some over his clothes. He went on
-working, and noticed burns after some time, quickly followed
-by hoarseness and pain in the throat. He died of severe inflammation
-of the lungs. A worker in another factory was dropping
-diethyl sulphate and stirring it into an at first solid, and later
-semi-liquid, mass for the purpose of ethylating a dye stuff. In
-doing so he was exposed to fumes, and at the end of the work
-complained of hoarseness and smarting of the eyes. He died
-of double pneumonia two days later. Post mortem very
-severe corrosive action on the respiratory tract was found,
-showing that the diethyl sulphuric acid had decomposed
-inside the body and that nascent sulphuric acid had given
-rise to the severe burns. The principal chemist who had
-superintended the process suffered severely from hoarseness
-at night, but no serious consequences followed.</p>
-
-<p>It is stated also that workmen in chemical factories coming
-into contact with the fumes of diethyl sulphate ester suffer
-from eye affections.<a href="#endnote7" id="endnote-ref7"><span class="endnote-marker">3</span></a> </p>
-
-<h4>CHLORINE, CHLORIDE OF CALCIUM, AND CHLORATES</h4>
-
-<p><span class="smcap">Manufacture.</span>—The older processes depend on the preparation
-of chlorine and hydrochloric acid by an oxidation
-process in which the oxidising agent is either a compound rich
-in oxygen—usually common manganese dioxide (pyrolusite)—or
-the oxygen of the air in the presence of heated copper
-chloride (as catalytic agent). The former (Weldon process)<span class="pagenum"><a name="Page_24" id="Page_24">[24]</a></span>
-is less used now than either the latter (Deacon process) or the
-electrolytic manufacture of chlorine.</p>
-
-<p>In the <i>Weldon process</i> from the still liquors containing
-manganous chloride the manganese peroxide is regenerated,
-and this so regenerated Weldon mud, when mixed with fresh
-manganese dioxide, is used to initiate the process. This is
-carried out according to the equations:</p>
-
-<ul>
-<li>MnO₂ + 4HCl = MnCl₄ + 2H₂O</li>
-<li>MnCl₄ = MnCl₂ + Cl₂.</li>
-</ul>
-
-<div class="figcenter" style="width: 500px;" id="fig6">
-
-<img src="images/fig6.jpg" width="500" height="250" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 6.</span>—Preparation of Chlorine—Diaphragm Method (<i>after Ost</i>)</p>
-
-</div>
-
-<p>Hydrochloric acid is first introduced into the chlorine still
-(vessels about 3 m. in height, of Yorkshire flag or fireclay),
-next the Weldon mud gradually, and finally steam to bring the
-whole to boiling; chlorine comes off in a uniform stream.
-The manganous chloride still liquor is run into settling tanks.
-The regeneration of the manganous chloride liquor takes
-place in an oxidiser which consists of a vertical iron cylinder
-in which air is blown into the heated mixture of manganous
-chloride and milk of lime. The dark precipitate so formed,
-‘Weldon mud,’ as described, is used over again, while the
-calcium chloride liquor runs away.</p>
-
-<p>The <i>Deacon process</i> depends mainly on leading the stream
-of hydrochloric acid gas evolved from a saltcake pot mixed
-with air and heated into a tower containing broken bricks of<span class="pagenum"><a name="Page_25" id="Page_25">[25]</a></span>
-the size of a nut saturated with copper chloride. Chlorine is
-evolved according to the equation:</p>
-
-<ul>
-<li>2HCl + O = 2Cl + H₂O.</li>
-</ul>
-
-<div class="figcenter" style="width: 400px;" id="fig7">
-
-<img src="images/fig7.jpg" width="400" height="300" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 7.</span>—Preparation of Chlorine—Bell Method
-(<i>after Ost</i>)</p>
-
-</div>
-
-<p>The <i>electrolytic production</i> of chlorine with simultaneous
-production of <i>caustic alkali</i> is increasing and depends on the
-splitting up of alkaline chlorides by a current of electricity. The
-chlorine evolved at the anode and the alkaline liquor formed at
-the cathode must be kept apart to prevent secondary formation
-of hypochlorite and chlorate (see below). This separation is
-generally effected in one of three ways: (1) In the diaphragm
-process (Griesheim-Elektron
-chemical
-works) the anode
-and cathode are kept
-separate by porous
-earthenware diaphragms
-arranged as
-illustrated in <a href="#fig6">fig. 6</a>.
-The anode consists
-of gas carbon, or is
-made by pressing
-and firing a mixture
-of charcoal and tar;
-it lies inside the
-diaphragm. The
-chlorine developed
-in the anodal cell is carried away by a pipe. The metal
-vessel serves as the cathode. The alkali, which, since it contains
-chloride, is recovered as caustic soda after evaporation
-and crystallisation, collects in the cathodal space lying
-outside the diaphragm. (2) By the Bell method (chemical
-factory at Aussig) the anodal and cathodal fluids, which keep
-apart by their different specific weights, are separated by a
-stoneware bell; the poles consist of sheet iron and carbon.
-The containing vessel is of stoneware. (3) In the mercury
-process (England) sodium chloride is electrolysed without
-a diaphragm, mercury serving as the cathode. This takes
-up the sodium, which is afterwards recovered from the
-amalgam formed by means of water.</p>
-
-<p><span class="pagenum"><a name="Page_26" id="Page_26">[26]</a></span></p>
-
-<p>If <i>chlorate</i> or <i>hypochlorite</i> is to be obtained electrolytically,
-electrodes of the very resistant but expensive platinum iridium
-are used without a diaphragm. Chlorine is developed—not
-free, but combined with the caustic potash. The bleaching
-fluid obtained electrolytically in this way is a rival of bleaching
-powder.</p>
-
-<p><i>Bleaching powder</i> is made from chlorine obtained by the
-Weldon or Deacon process. Its preparation depends on the
-fact that calcium hydrate takes up chlorine in the cold with
-formation of calcium hypochlorite after the equation:</p>
-
-<ul>
-<li>2Ca(OH)₂ + 4Cl = Ca(ClO)₂ + CaCl₂ + 2H₂O.</li>
-</ul>
-
-<p>The resulting product contains from 35 to 36 per cent.
-chlorine, which is given off again when treated with acids.</p>
-
-<p>The preparation of chloride of lime takes place in bleaching
-powder chambers made of sheets of lead and Yorkshire flagstones.
-The lime is spread out on the floors of these and
-chlorine introduced. Before the process is complete the lime
-must be turned occasionally.</p>
-
-<p>In the manufacture of bleaching powder from Deacon
-chlorine, Hasenclever has constructed a special cylindrical
-apparatus (<a href="#fig8">fig. 8</a>), consisting of several superimposed cast-iron
-cylinders in which are worm arrangements carrying the lime
-along, while chlorine gas passes over in an opposite direction.
-This continuous process is, however, only possible for the
-Deacon chlorine strongly diluted with nitrogen and oxygen
-and not for undiluted Weldon gas.</p>
-
-<p><i>Liquid chlorine</i> can be obtained by pressure and cooling
-from concentrated almost pure Weldon chlorine gas.</p>
-
-<p><i>Potassium chlorate</i>, which, as has been said, is now mostly
-obtained electrolytically, was formerly obtained by passing
-Deacon chlorine into milk of lime and decomposing the calcium
-chlorate formed by potassium chloride.</p>
-
-<p>Chlorine and chloride of lime are used for bleaching;
-chlorine further is used in the manufacture of colours; chloride
-of lime as a mordant in cloth printing and in the preparation of
-chloroform; the chlorates are oxidising agents and used in
-making safety matches. The manufacture of organic chlorine
-products will be dealt with later.</p>
-
-<p><span class="pagenum"><a name="Page_27" id="Page_27">[27]</a></span></p>
-
-<div class="figcenter" style="width: 500px;" id="fig8">
-
-<img src="images/fig8.jpg" width="500" height="550" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 8.</span>—Preparation of Bleaching Powder. Apparatus of Hasenclever (<i>after Ost</i>)</p>
-
-<p class="caption">A Hopper for slaked lime; W Worm conveying lime; Z Toothed wheels;
-K Movable covers; C Entrance for chlorine gas; D Pipe for escape of
-chlorine-free gas; B Outlet shoot for bleaching powder</p>
-
-</div>
-
-<p><span class="smcap">Effects on Health.</span>—In these industries the possibility
-of injury to health and poisoning by inhalation of chlorine
-gas is prominent. Leymann has shown that persons employed
-in the manufacture of chlorine and bleaching powder suffer
-from diseases of the respiratory organs 17·8 per cent., as contrasted
-with 8·8 per cent. in other workers: and this is without
-doubt attributable to the injurious effect of chlorine gas, which
-it is hardly possible to avoid despite the fact that Leymann’s<span class="pagenum"><a name="Page_28" id="Page_28">[28]</a></span>
-figures refer to a model factory. But the figures show also
-that as the industry became perfected the number of cases of
-sickness steadily diminished.</p>
-
-<p>Most cases occur from unsatisfactory conditions in the
-production of chloride of lime, especially if the chloride of
-lime chambers leak, if the lime is turned over while the
-chlorine is being let in, by too early entrance into chambers
-insufficiently ventilated, and by careless and unsuitable
-methods of emptying the finished bleaching powder.</p>
-
-<p>The possibility of injury is naturally greater from the
-concentrated gas prepared by the Weldon process than from
-the diluted gas of the Deacon process—the more so as in the
-latter the bleaching powder is made in the Hasenclever closed-in
-cylindrical apparatus in which the chlorine is completely
-taken up by the lime. The safest process of all is the electrolytic,
-as, if properly arranged, there should be no escape of
-chlorine gas. The chlorine developed in the cells (when carried
-out on the large scale) is drawn away by fans and conducted in
-closed pipes to the place where it is used.</p>
-
-<p>Many researches have been published as to the character
-of the skin affection well known under the name of <i>chlorine
-rash</i> (chlorakne). Some maintain that it is not due to chlorine
-at all, but is an eczema set up by tar. Others maintain that
-it is due to a combined action of chlorine and tar. Support to
-this view is given by the observation that cases of chlorine rash,
-formerly of constant occurrence in a factory for electrolytic
-manufacture of chlorine, disappeared entirely on substitution
-of magnetite at the anode for carbon.<a href="#endnote8" id="endnote-ref8"><span class="endnote-marker">1</span></a> The conclusion
-seems justified that the constituents of the carbon or of the
-surrounding material set up the condition.</p>
-
-<p>Chlorine rash has been observed in an alkali works where
-chlorine was not produced electrolytically, and under conditions
-which suggested that compounds of tar and chlorine were the
-cause. In this factory for the production of salt cake by the
-Hargreaves’ process cakes of rock salt were prepared and, for
-the purpose of drying, conveyed on an endless metal band
-through a stove. To prevent formation of crusts the band
-was tarred. The salt blocks are decomposed in the usual
-way by sulphur dioxide, steam, and oxygen of the air, and
-the hydrochloric acid vapour led through Deacon towers in<span class="pagenum"><a name="Page_29" id="Page_29">[29]</a></span>
-which the decomposition of the hydrochloric acid into chlorine
-and water is effected by metal salts in the manner characteristic
-of the Deacon process. These salts are introduced in small
-earthenware trays which periodically have to be removed and
-renewed; the persons engaged in doing this were those affected.
-The explanation was probably that the tar sticking to the salt
-blocks distilled in the saltcake furnaces and formed a compound
-with the chlorine which condensed on the earthenware
-trays. When contact with these trays was recognised as the
-cause, the danger was met by observance of the greatest cleanliness
-in opening and emptying the Deacon towers.</p>
-
-<p>Leymann<a href="#endnote9" id="endnote-ref9"><span class="endnote-marker">2</span></a> is certain that the rash is due to chlorinated
-products which emanate from the tar used in the construction
-of the cells. And the affection has been found to be much
-more prevalent when the contents of the cells are emptied
-while the contents are still hot than when they are first
-allowed to get cold.</p>
-
-<p>Lehmann<a href="#endnote10" id="endnote-ref10"><span class="endnote-marker">3</span></a> has approached the subject on the experimental
-side, and is of opinion that probably chlorinated tar derivatives
-(chlorinated phenols) are the cause of the trouble. Both he and
-Roth think that the affection is due not to external irritation
-of the skin, but to absorption of the poisonous substances into
-the system and their elimination by way of the glands of the
-skin.</p>
-
-<p>In the section on manganese poisoning detailed reference
-is made to the form of illness recently described in persons
-employed in drying the regenerated Weldon mud.</p>
-
-<p>Mercurial poisoning is possible when mercury is used in
-the production of chlorine electrolytically.</p>
-
-<p>In the manufacture of chlorates and hypochlorite, bleaching
-fluids, &amp;c., injury to health from chlorine is possible in the
-same way as has been described above.</p>
-
-<h4>OTHER CHLORINE COMPOUNDS. BROMINE, IODINE, AND
-FLUORINE</h4>
-
-<p>Chlorine is used for the production of a number of organic
-chlorine compounds, and in the manufacture of bromine and
-iodine, processes which give rise to the possibility of injury
-to health and poisoning by chlorine; further, several of the<span class="pagenum"><a name="Page_30" id="Page_30">[30]</a></span>
-substances so prepared are themselves corrosive or irritating
-or otherwise poisonous. Nevertheless, severe poisoning and
-injurious effects can be almost entirely avoided by adoption
-of suitable precautions. In the factory to which Leymann’s
-figures refer, where daily several thousand kilos of chlorine
-and organic chlorine compounds are prepared, a relatively
-very favourable state of health of the persons employed was
-noted. At all events the preparation of chlorine by the electrolytic
-process takes place in closed vessels admirably adapted
-to avoid any escape of chlorine gas except as the result of
-breakage of the apparatus or pipes. When this happens,
-however, the pipes conducting the gas can be immediately
-disconnected and the chlorine led into other apparatus or
-into the bleaching powder factory.</p>
-
-<p>As such complete precautionary arrangements are not
-everywhere to be found, we describe briefly the most important
-of the industries in question and the poisoning recognised in
-them.</p>
-
-<p><i>Chlorides of phosphorus.</i>—By the action of dry chlorine
-on an excess of heated amorphous phosphorus, trichloride is
-formed (PCl₃), a liquid having a sharp smell and causing lachrymation,
-which fumes in the air, and in presence of water decomposes
-into phosphorous acid and hydrochloric acid. On heating
-with dry oxidising substances it forms phosphorus oxychloride
-(see below), which is used for the production of acid chlorides.
-By continuous treatment with chlorine it becomes converted
-into phosphorus pentachloride (PCl₅), which also is conveniently
-prepared by passing chlorine through a solution of phosphorus
-in carbon bisulphide, the solution being kept cold; it is crystalline,
-smells strongly, and attacks the eyes and lungs. With
-excess of water it decomposes into phosphoric acid and hydrochloric
-acid: with slight addition of water it forms phosphorus
-oxychloride (POCl₃). On the large scale this is prepared by
-reduction of phosphate of lime in the presence of chlorine with
-carbon or carbonic oxide. Phosphorus oxychloride, a colourless
-liquid, fumes in the air and is decomposed by water into
-phosphoric acid and hydrochloric acid.</p>
-
-<p>In the preparation of chlorides of phosphorus, apart
-from the danger of chlorine gas and hydrochloric acid, the
-poisonous effect of phosphorus and its compounds (see Phosphorus)<span class="pagenum"><a name="Page_31" id="Page_31">[31]</a></span>
-and even of carbon disulphide (as the solvent of
-phosphorus) and of carbonic oxide (in the preparation of
-phosphorus oxychloride) have to be taken into account.</p>
-
-<p>Further, the halogen compounds of phosphorus exert
-irritant action on the eyes and lungs similar to chloride of
-sulphur as a result of their splitting up on the moist mucous
-membranes into hydrochloric acid and an oxyacid of phosphorus.<a href="#endnote11" id="endnote-ref11"><span class="endnote-marker">4</span></a> </p>
-
-<p>Unless, therefore, special measures are taken, the persons
-employed in the manufacture of phosphorus chlorides suffer
-markedly from the injurious emanations given off.<a href="#endnote12" id="endnote-ref12"><span class="endnote-marker">5</span></a> </p>
-
-<p>Leymann<a href="#endnote13" id="endnote-ref13"><span class="endnote-marker">6</span></a> mentions one case of poisoning by phosphorus
-chloride as having occurred in the factory described by him.
-By a defect in the outlet arrangement phosphorus oxychloride
-flowed into a workroom. Symptoms of poisoning
-(sensation of suffocation, difficulty of breathing, lachrymation,
-&amp;c.) at once attacked the occupants; before much gas had
-escaped, the workers rushed out. Nevertheless, they suffered
-from severe illness of the respiratory organs (bronchial catarrh
-and inflammation of the lungs, with frothy, blood-stained
-expectoration, &amp;c.).<a href="#endnote14" id="endnote-ref14"><span class="endnote-marker">7</span></a> </p>
-
-<p><i>Chlorides of sulphur.</i>—Monochloride of sulphur (S₂Cl₂) is
-made by passing dried, washed chlorine gas into molten
-heated sulphur. The oily, brown, fuming liquid thus made
-is distilled over into a cooled condenser and by redistillation
-purified from the sulphur carried over with it. Sulphur monochloride
-can take up much sulphur, and when saturated is
-used in the vulcanisation of indiarubber, and, further, is used
-to convert linseed and beetroot oil into a rubber substitute.
-Monochloride of sulphur is decomposed by water into sulphur
-dioxide, hydrochloric acid, and sulphur. By further action
-of chlorine on the monochloride, sulphur dichloride (SCl₂) and
-the tetrachloride (SCl₄) are formed.</p>
-
-<p>In its preparation and use (see also Indiarubber Manufacture)
-the injurious action of chlorine, of hydrochloric acid,
-and of sulphur dioxide comes into play.</p>
-
-<p>The monochloride has very irritating effects. Leymann cites
-an industrial case of poisoning by it. In the German factory
-inspectors’ reports for 1897 a fatal case is recorded. The
-shirt of a worker became saturated with the material owing<span class="pagenum"><a name="Page_32" id="Page_32">[32]</a></span>
-to the bursting of a bottle. First aid was rendered by pouring
-water over him, thereby increasing the symptoms, which proved
-fatal the next day. Thus the decomposition brought about by
-water already referred to aggravated the symptoms.</p>
-
-<p><i>Zinc chloride</i> (ZnCl₂) is formed by heating zinc in presence of
-chlorine. It is obtained pure by dissolving pure zinc in hydrochloric
-acid and treating this solution with chlorine. Zinc
-chloride is obtained on the large scale by dissolving furnace
-calamine (zinc oxide) in hydrochloric acid. Zinc chloride is
-corrosive. It is used for impregnating wood and in weighting
-goods. Besides possible injury to health from chlorine and
-hydrogen chloride, risk of arseniuretted hydrogen poisoning
-is present in the manufacture if the raw materials contain
-arsenic. Eulenburg considers that in soldering oppressive
-zinc chloride fumes may come off if the metal to be soldered is
-first wiped with hydrochloric acid and then treated with the
-soldering iron.</p>
-
-<p><i>Rock salt.</i>—Mention may be made that even to salt in
-combination with other chlorides (calcium chloride, magnesium
-chloride, &amp;c.) injurious effects are ascribed. Ulcers
-and perforation of the septum of the nose in salt-grinders
-and packers who were working in a room charged with salt
-dust are described.<a href="#endnote15" id="endnote-ref15"><span class="endnote-marker">8</span></a> These effects are similar to those produced
-by the bichromates.</p>
-
-<h4>Organic Chlorine Compounds</h4>
-
-<p><i>Carbon oxychloride</i> (COCl₂, carbonyl dichloride, phosgene)
-is produced by direct combination of chlorine and carbonic
-oxide in presence of animal charcoal. Phosgene is itself a very
-poisonous gas which, in addition to the poisonous qualities of
-carbonic oxide (which have to be borne in mind in view of
-the method of manufacture), acts as an irritant of the mucous
-membranes. Commercially it is in solution in toluene and
-xylene, from which the gas is readily driven off by heating.
-It is used in the production of various colours, such as crystal
-violet, Victoria blue, auramine, &amp;c.</p>
-
-<p>A fatal case of phosgene gas poisoning in the report
-of the Union of Chemical Industry for 1905 deserves
-mention. The phosgene was kept in a liquefied state in iron<span class="pagenum"><a name="Page_33" id="Page_33">[33]</a></span>
-bottles provided with a valve under 2·3 atm. pressure. The
-valve of one of these bottles leaked, allowing large escape into
-the workroom. Two workers tried but failed to secure the
-valve. The cylinder was therefore removed by a worker, by
-order of the manager, and placed in a cooling mixture, as
-phosgene boils at 8° C. The man in question wore a helmet
-into which air was pumped from the compressed air supply in
-the factory. As the helmet became obscured through moisture
-after five minutes the worker took it off. A foreman next put
-on the cleaned mask, and kept the cylinder surrounded with
-ice and salt for three-quarters of an hour, thus stopping the
-escape of gas. Meanwhile, the first worker had again entered
-the room, wearing a cloth soaked in dilute alcohol before his
-mouth, in order to take a sack of salt to the foreman. An
-hour and a half later he complained of being very ill, became
-worse during the night, and died the following morning.
-Although the deceased may have been extremely susceptible,
-the case affords sufficient proof of the dangerous nature of
-the gas, which in presence of moisture had decomposed into
-carbonic acid and hydrochloric acid; the latter had acutely
-attacked the mucous membrane of the respiratory passages
-and set up fatal bronchitis. Further, it was found that
-the leaden plugs of the valves had been eroded by the
-phosgene.</p>
-
-<p>Three further cases of industrial phosgene poisoning have
-been reported,<a href="#endnote16" id="endnote-ref16"><span class="endnote-marker">9</span></a> one a severe case in which there was bronchitis
-with blood-stained expectoration, great dyspnœa, and weakness
-of the heart’s action. The affected person was successfully
-treated with ether and oxygen inhalations. Phosgene may
-act either as the whole molecule, or is inhaled to such degree
-that the carbonic oxide element plays a part.</p>
-
-<p>In another case of industrial phosgene poisoning the
-symptoms were those of severe irritation of the bronchial
-mucous membrane and difficulty of breathing.<a href="#endnote17" id="endnote-ref17"><span class="endnote-marker">10</span></a> The case
-recovered, although sensitiveness of the air passages lasted a
-long time.</p>
-
-<p><i>Carbon chlorine compounds</i> (<i>aliphatic series</i>).—<i>Methyl
-chloride</i> (CH₃Cl) or chlormethane is prepared from methyl
-alcohol and hydrochloric acid (with chloride of zinc) or methyl
-alcohol, salt, and sulphuric acid. It is prepared in France on a<span class="pagenum"><a name="Page_34" id="Page_34">[34]</a></span>
-large scale from beetroot <i>vinasse</i> by dry distillation of the
-evaporation residue. The distillate, which contains methyl
-alcohol, trimethylamine, and other methylated amines, is
-heated with hydrochloric acid; the methyl chloride so obtained
-is purified, dried and compressed. It is used in the preparation
-of pure chloroform, in the coal-tar dye industry, and in surgery
-(as a local anæsthetic). In the preparation of methyl chloride
-there is risk from methyl alcohol, trimethylamine, &amp;c. Methyl
-chloride itself is injurious to health.</p>
-
-<p><i>Methylene chloride</i> (CH₂Cl₂, dichlormethane) is prepared in
-a similar way. It is very poisonous.</p>
-
-<p><i>Carbon tetrachloride</i> (CCl₄, tetrachlormethane) is technically
-important. It is prepared by passing chlorine gas into carbon
-bisulphide with antimony or aluminium chloride. Carbon
-tetrachloride is a liquid suitable for the extraction of fat or
-grease (as in chemical cleaning), and has the advantage of being
-non-inflammable. Carbon tetrachloride, so far as its poisonous
-qualities are concerned, is to be preferred to other extractives
-(see Carbon Bisulphide, Benzine, &amp;c.); for the rest it causes
-unconsciousness similar to chloroform.</p>
-
-<p>When manufactured industrially, in addition to the poisonous
-effect of chlorine, the poisonous carbon bisulphide has also
-to be borne in mind.</p>
-
-<p><i>Ethyl chloride</i> (C₂H₅Cl) is made in a way analogous to
-methyl chloride by the action of hydrochloric acid on ethyl
-alcohol and chloride of zinc. It is used in medicine as a
-narcotic.</p>
-
-<p><i>Monochloracetic acid.</i>—In the preparation of monochloracetic
-acid hydrochloric acid is developed in large quantity.
-From it and anthranilic acid artificial indigo is prepared
-(according to Heuman) by means of caustic potash.</p>
-
-<p><i>Chloral</i> (CCl₃CHO, trichloracetaldehyde) is produced by
-chlorinating alcohol. Chloral is used in the preparation of
-pure chloroform and (by addition of water) of chloral hydrate
-(trichloracetaldehyde hydrate), the well-known soporific.</p>
-
-<p><i>Chloroform</i> (CHCl₃, trichlormethane).—Some methods for
-the preparation of chloroform have been already mentioned
-(Chloral, Methyl Chloride). Technically it is prepared by
-distillation of alcohol or acetone with bleaching powder. The
-workers employed are said to be affected by the stupefying<span class="pagenum"><a name="Page_35" id="Page_35">[35]</a></span>
-vapours. Further, there is the risk of chlorine gas from use of
-chloride of lime.</p>
-
-<p><i>Chloride of nitrogen</i> (NCl₃) is an oily, volatile, very explosive,
-strongly smelling substance, which irritates the eyes and nose
-violently and is in every respect dangerous; it is obtained
-from the action of chlorine or hypochlorous acid on sal-ammoniac.
-The poisonous nature of these substances may
-come into play. Risk of formation of chloride of nitrogen
-can arise in the production of gunpowder from nitre containing
-chlorine.</p>
-
-<p><i>Cyanogen chloride</i> (CNCl).—Cyanogen chloride is made
-from hydrocyanic acid or cyanide of mercury and chlorine.
-Cyanogen chloride itself is an extremely poisonous and irritating
-gas, and all the substances from which it is made are
-also poisonous. According to Albrecht cyanogen chloride
-can arise in the preparation of red prussiate of potash (by
-passage of chlorine gas into a solution of the yellow prussiate)
-if the solution is treated with chlorine in excess; the workers
-may thus be exposed to great danger.</p>
-
-<p><i>Chlorobenzene.</i>—In his paper referred to Leymann cites
-three cases of poisoning by chlorobenzene, one by dinitrochlorobenzene,
-and, further, three cases of burning by chlorobenzene
-and one by benzoyl chloride (C₆H₅COCl). The last
-named is made by treating benzaldehyde with chlorine, and
-irritates severely the mucous membranes, while decomposing
-into hydrochloric acid and benzoic acid.<a href="#endnote18" id="endnote-ref18"><span class="endnote-marker">11</span></a> Benzal chloride
-(C₆H₅CHCl₂), benzo trichloride (C₆H₅CCl₃), and benzyl chloride
-(C₆H₅CH₂Cl) are obtained by action of chlorine on boiling
-toluene. The vapours of these volatile products irritate the
-respiratory passages. In the manufacture there is risk from
-the effect of chlorine gas and toluene vapour (see Benzene,
-Toluene).</p>
-
-<p>Leymann<a href="#endnote19" id="endnote-ref19"><span class="endnote-marker">12</span></a> describes in detail six cases of poisoning in
-persons employed in a chlorobenzene industry, of which two
-were due to nitrochlorobenzene. Symptoms of poisoning—headache,
-cyanosis, fainting, &amp;c.—were noted in a person
-working for three weeks with chlorobenzene.<a href="#endnote20" id="endnote-ref20"><span class="endnote-marker">13</span></a> </p>
-
-<p>In Lehmann’s opinion chlorine rash, the well-recognised
-skin affection of chlorine workers, may be due to contact with
-substances of the chlorbenzol group.<a href="#endnote21" id="endnote-ref21"><span class="endnote-marker">14</span></a> </p>
-
-<p><span class="pagenum"><a name="Page_36" id="Page_36">[36]</a></span></p>
-
-<p><i>Iodine and iodine compounds.</i>—Formerly iodine was obtained
-almost exclusively from the liquor formed by lixiviation
-of the ash of seaweed (kelp, &amp;c.); now the principal sources are
-the mother liquors from Chili saltpetre and other salt industries.
-From the concentrated liquor the iodine is set free by means
-of chlorine or oxidising substances and purified by distillation
-and sublimation. Iodine is used for the preparation of photographic
-and pharmaceutical preparations, especially iodoform
-(tri-iodomethane, CHI₃), which is made by acting with iodine
-and caustic potash on alcohol, aldehyde, acetone, &amp;c.</p>
-
-<p>Apart from possible injurious action of chlorine when used
-in the preparation of iodine, workers are exposed to the possibility
-of chronic iodine poisoning. According to Ascher<a href="#endnote22" id="endnote-ref22"><span class="endnote-marker">15</span></a>
-irritation effects, nervous symptoms, and gastric ulceration
-occur in iodine manufacture and use. He considers that
-bromide of iodine used in photography produces these irritating
-effects most markedly. Layet and also Chevallier in older
-literature have made the same observations.</p>
-
-<p>The Swiss Factory Inspectors’ Report for 1890-1 describes
-two acute cases of iodine poisoning in a factory where organic
-iodine compounds were made; one terminated fatally (severe
-cerebral symptoms, giddiness, diplopia, and collapse).</p>
-
-<p><i>Bromine and bromine compounds.</i>—Bromine is obtained
-(as in the case of iodine) principally from the mother liquors of
-salt works (especially Stassfurt saline deposits) by the action
-of chlorine or nascent oxygen on the bromides of the alkalis
-and alkaline earths in the liquors. They are chiefly used in
-photography (silver bromide), in medicine (potassium bromide,
-&amp;c.), and in the coal-tar dye industry.</p>
-
-<p>The danger of bromine poisoning (especially of the chronic
-form) is present in its manufacture and use, but there is no
-positive evidence of the appearance of the bromine rash among
-the workers. On the other hand, instances are recorded of
-poisoning by methyl bromide, and the injurious effect of
-bromide of iodine has been referred to.</p>
-
-<p><i>Methyl iodide and methyl bromide.</i>—Methyl iodide (CH₃I),
-a volatile fluid, is obtained by distillation of wood spirit with
-amorphous phosphorus and iodine; it is used in the production
-of methylated tar colours and for the production of various
-methylene compounds. Grandhomme describes, in the paper<span class="pagenum"><a name="Page_37" id="Page_37">[37]</a></span>
-already referred to, six cases, some very severe, of poisoning
-by the vapour of methyl iodide among workers engaged in the
-preparation of antipyrin, which is obtained by the action of
-aceto-acetic ether on phenyl hydrazine, treatment of the pyrazolone
-so obtained with methyl iodide, and decomposition of the
-product with caustic soda. A case of methyl iodide poisoning
-is described in a factory operative, who showed symptoms
-similar to those described for methyl bromide except that the
-psychical disturbance was more marked.<a href="#endnote23" id="endnote-ref23"><span class="endnote-marker">16</span></a> </p>
-
-<p>Three cases of methyl bromide (CH₃Br) poisoning are
-described in persons preparing the compound.<a href="#endnote24" id="endnote-ref24"><span class="endnote-marker">17</span></a> One of these
-terminated fatally. There is some doubt as to whether
-these cases were really methyl bromide poisoning. But later
-cases of methyl bromide poisoning are known, and hence the
-dangerous nature of this chemical compound is undoubted.
-Thus the Report of the Union of Chemical Industry for
-1904 gives the following instance: Two workers who had to
-deal with an ethereal solution of methyl bromide became ill
-with symptoms of alcoholic intoxication. One suffered for a
-long time from nervous excitability, attacks of giddiness, and
-drowsiness. Other cases of poisoning from methyl bromide
-vapour are recorded with severe nervous symptoms and even
-collapse.</p>
-
-<p><i>Fluorine compounds.</i>—<i>Hydrogen fluoride</i> (HFl) commercially
-is a watery solution, which is prepared by decomposition
-of powdered fluorspar by sulphuric acid in cast-iron
-vessels with lead hoods. The escaping fumes are collected in
-leaden condensers surrounded with water; sometimes to get
-a very pure product it is redistilled in platinum vessels.</p>
-
-<p>Hydrogen fluoride is used in the preparation of the fluorides
-of antimony, of which antimony fluoride ammonium sulphate
-(SbFl₃(NH₄)₂SO₄) has wide use in dyeing as a substitute for
-tartar emetic. It is produced by dissolving oxide of antimony
-in hydrofluoric acid with addition of ammonium sulphate and
-subsequent concentration and crystallisation. Hydrofluoric
-acid is used for etching glass (see also Glass Industry).</p>
-
-<p>In brewing, an unpurified silico-fluoric acid mixed with
-silicic acid, clay, oxide of iron, and oxide of zinc called Salufer
-is used as a disinfectant and preservative.</p>
-
-<p><i>Hydrofluoric acid and silicofluoric acid</i> (H₂SiFl₆) arise<span class="pagenum"><a name="Page_38" id="Page_38">[38]</a></span>
-further in the superphosphate industry by the action of
-sulphuric acid on the phosphorites whereby silicofluoric acid
-is obtained as a bye-product (see also Manufacture of Artificial
-Manure). Hydrofluoric acid and its derivatives both in their
-manufacture and use and in the superphosphate industry
-affect the health of the workers.</p>
-
-<p>If hydrogen fluoride or its compounds escape into the
-atmosphere they attack the respiratory passages and set up
-inflammation of the eyes; further, workers handling the
-watery solutions are prone to skin affections (ulceration).</p>
-
-<p>The following are examples of the effects produced.<a href="#endnote25" id="endnote-ref25"><span class="endnote-marker">18</span></a> A
-worker in an art establishment upset a bottle of hydrofluoric
-acid and wetted the inner side of a finger of the right hand.
-Although he immediately washed his hands, a painful inflammation
-with formation of blisters similar to a burn of the second
-degree came on within a few hours. The blister became
-infected and suppurated.</p>
-
-<p>A man and his wife wished to obliterate the printing on the
-top of porcelain beer bottle stoppers with hydrofluoric acid.
-The man took a cloth, moistened a corner of it, and then rubbed
-the writing off. After a short time he noticed a slight burning
-sensation and stopped. His wife, who wore an old kid glove
-in doing the work, suffered from the same symptoms, the pain
-from which in the night became unbearable, and in spite of
-medical treatment gangrene of the finger-tips ensued. Healing
-took place with suppuration and loss of the finger-nails.</p>
-
-<p>Injury of the respiratory passages by hydrofluoric acid has
-often been reported. In one factory for its manufacture the
-hydrofluoric acid vapour was so great that all the windows to a
-height of 8 metres were etched dull.</p>
-
-<p>Several cases of poisoning by hydrofluoric acid were noted
-by me when examining the certificates of the Sick Insurance
-Society of Bohemia. In 1906 there were four due to inhalation
-of vapour of hydrofluoric acid in a hydrofluoric acid factory,
-with symptoms of corrosive action on the mucous membrane of
-the respiratory tract. In 1907 there was a severe case in the
-etching of glass.<a href="#endnote26" id="endnote-ref26"><span class="endnote-marker">19</span></a> </p>
-
-<p><span class="pagenum"><a name="Page_39" id="Page_39">[39]</a></span></p>
-
-<h4>NITRIC ACID.</h4>
-
-<p><span class="smcap">Manufacture and Uses.</span>—<i>Nitric acid</i> (HNO₃) is obtained
-by distillation when Chili saltpetre (sodium nitrate) is decomposed
-by sulphuric acid in cast-iron retorts according to the
-equation:</p>
-
-<ul>
-<li>NaNO₃ + H₂SO₄ = NaHSO₄ + HNO₃.</li>
-</ul>
-
-<p>Condensation takes place in fireclay Woulff bottles connected
-to a coke tower in the same way as has been described in
-the manufacture of hydrochloric acid.</p>
-
-<div class="figcenter" style="width: 500px;" id="fig9">
-
-<img src="images/fig9.jpg" width="500" height="325" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 9.</span>—Preparation of Nitric Acid (<i>after Ost</i>)</p>
-
-</div>
-
-<p>Lunge-Rohrmann plate towers are also used instead of the
-coke tower. Earthenware fans—as is the case with acid gases
-generally—serve to aspirate the nitrous fumes.</p>
-
-<p>To free the nitric acid of the accompanying lower oxides of
-nitrogen (as well as chlorine, compounds of chlorine and other
-impurities) air is blown into the hot acid. The mixture of
-sodium sulphate and sodium bisulphate remaining in the
-retorts is either converted into sulphate by addition of salt or
-used in the manufacture of glass.</p>
-
-<p>The nitric acid obtained is used either as such or mixed with
-sulphuric acid or with hydrochloric acid.</p>
-
-<p>Pure nitric acid cannot at ordinary atmospheric pressure<span class="pagenum"><a name="Page_40" id="Page_40">[40]</a></span>
-be distilled unaltered, becomes coloured on distillation, and
-turns red when exposed to light. It is extremely dangerous to
-handle, as it sets light to straw, for example, if long in contact
-with it. It must be packed, therefore, in kieselguhr earth,
-and when in glass carboys forwarded only in trains for transport
-of inflammable material.</p>
-
-<p>Red, <i>fuming nitric acid</i>, a crude nitric acid, contains much
-nitrous and nitric oxides. It is produced if in the distillation
-process less sulphuric acid and a higher temperature are
-employed or (by reduction) if starch meal is added.</p>
-
-<p>The successful production of nitric acid from the air must be
-referred to. It is effected by electric discharges in special
-furnaces from which the air charged with nitrous gas is led into
-towers where the nitric oxide is further oxidised (to tetroxide),
-and finally, by contact with water, converted into nitric acid.</p>
-
-<p>Nitric acid is used in the manufacture of phosphoric acid,
-arsenious acid, and sulphuric acid, nitro-glycerin and nitrocellulose,
-smokeless powder, &amp;c. (see the section on Explosives),
-in the preparation of nitrobenzenes, picric acid, and other
-nitro-compounds (see Tar Products, &amp;c.). The diluted acid
-serves for the solution and etching of metals, also for the preparation
-of nitrates, such as the nitrates of mercury, silver, &amp;c.</p>
-
-<p><span class="smcap">Effects on Health.</span>—Leymann considers that the average
-number of cases and duration of sickness among persons employed
-in the nitric acid industry are generally on the increase;
-the increase relates almost entirely to burns which can hardly
-be avoided with so strongly corrosive an acid. The number of
-burns amounts almost to 12 per cent. according to Leymann’s
-figures (i.e. on an average 12 burns per 100 workers), while
-among the packers, day labourers, &amp;c., in the same
-industry the proportion is only 1 per cent. Affections
-of the respiratory tract are fairly frequent (11·8 per cent.
-as compared with 8·8 per cent. of other workers), which is no
-doubt to be ascribed to the corrosive action of nitrous fumes
-on the mucous membranes. Escape of acid fumes can occur
-in the manufacture of nitric acid though leaky retorts, pipes,
-&amp;c., and injurious acid fumes may be developed in the workrooms
-from the bisulphate when withdrawn from the retorts,
-which is especially the case when excess of sulphuric acid
-is used. The poisonous nature of these fumes is very<span class="pagenum"><a name="Page_41" id="Page_41">[41]</a></span>
-great, as is shown by cases in which severe poisoning has
-been reported from merely carrying a vessel containing fuming
-nitric acid.<a href="#endnote27" id="endnote-ref27"><span class="endnote-marker">1</span></a> </p>
-
-<p>Frequent accidents occur through the corrosive action of
-the acid or from breathing the acid fumes—apart from the
-dangers mentioned in the manufacture—in filling, packing,
-and despatching the acid—especially if appropriate vessels
-are not used and they break. Of such accidents several are
-reported.</p>
-
-<p>Further, reports of severe poisoning from the use of nitric
-acid are numerous. Inhalation of nitrous fumes (nitrous
-and nitric oxides, &amp;c.) does not immediately cause severe
-symptoms or death; severe symptoms tend to come on some
-hours later, as the examples cited below show.</p>
-
-<p>Occurrence of such poisoning has already been referred to
-when describing the sulphuric acid industry. In the superphosphate
-industry also poisoning has occurred by accidental
-development of nitric oxide fumes on sodium nitrate mixing
-with very acid superphosphate.</p>
-
-<p>Not unfrequently poisoning arises in pickling metals
-(belt making, pickling brass; cf. the chapter on Treatment
-of Metals). Poisoning by nitrous fumes has frequently
-been reported from the action of nitric acid on organic substances
-whereby the lower oxides of nitrogen—nitrous
-and nitric oxides—are given off. Such action of nitric
-acid or of a mixture of nitric and sulphuric acid on organic
-substances is used for nitrating purposes (see Nitroglycerin;
-Explosives; Nitrobenzol).</p>
-
-<p>Through want of care, therefore, poisoning can arise in these
-industries. Again, this danger is present on accidental contact
-of escaping acid with organic substances (wood, paper, leather,
-&amp;c.), as shown especially by fires thus created.<a href="#endnote28" id="endnote-ref28"><span class="endnote-marker">2</span></a> </p>
-
-<p>Thus, in a cellar were five large iron vessels containing a
-mixture of sulphuric and nitric acids. One of the vessels was
-found one morning to be leaking. The manager directed that
-smoke helmets should be fetched, intending to pump out
-the acid, and two plumbers went into the cellar to fix
-the pump, staying there about twenty-five minutes. They
-used cotton waste and handkerchiefs as respirators, but
-did not put on the smoke helmets. One plumber suffered<span class="pagenum"><a name="Page_42" id="Page_42">[42]</a></span>
-only from cough, but the other died the same evening with
-symptoms of great dyspnœa. At the autopsy severe inflammation
-and swelling of the mucous membrane of the palate,
-pharynx and air passages, and congestion of the lungs were
-found.</p>
-
-<p>Two further fatal cases in the nitrating room are described
-by Holtzmann. One of the two complained only a few hours
-after entering the room of pains in the chest and giddiness.
-He died two days later. The other died the day after entering
-the factory, where he had only worked for three hours. In
-both cases intense swelling and inflammation of the mucous
-membrane was found.</p>
-
-<p>Holtzmann mentions cases of poisoning by nitrous fumes in
-the heating of an artificial manure consisting of a mixture of
-saltpetre, brown coal containing sulphur, and wool waste.
-Fatalities have been reported in workers who had tried to
-mop up the spilt nitric acid with shavings.<a href="#endnote29" id="endnote-ref29"><span class="endnote-marker">3</span></a> We quote the
-following other instances<a href="#endnote30" id="endnote-ref30"><span class="endnote-marker">4</span></a> :</p>
-
-<p>(1) Fatal poisoning of a fireman who had rescued several
-persons from a room filled with nitrous fumes the result of a
-fire occasioned by the upsetting of a carboy. The rescued
-suffered from bronchial catarrh, the rescuer dying from inflammation
-and congestion of the lungs twenty-nine hours after the
-inhalation of the gas.</p>
-
-<p>(2) At a fire in a chemical factory three officers and fifty-seven
-firemen became affected from inhalation of nitrous
-fumes, of whom one died.</p>
-
-<p>(3) In Elberfeld on an open piece of ground fifty carboys
-were stored. One burst and started a fire. As a strong wind
-was blowing the firemen were little affected by the volumes
-of reddish fumes. Soon afterwards at the same spot some
-fifty to sixty carboys were destroyed. Fifteen men successfully
-extinguished the fire in a relatively still atmosphere in less
-than half an hour. At first hardly any symptoms of discomfort
-were felt. Three hours later all were seized with violent
-suffocative attacks, which in one case proved fatal and in the
-rest entailed nine to ten days’ illness from affection of the
-respiratory organs.</p>
-
-<p>The Report of the Union for Chemical Industry for 1908
-describes a similar accident in a nitro-cellulose factory.</p>
-
-<p><span class="pagenum"><a name="Page_43" id="Page_43">[43]</a></span></p>
-
-<p>Of those engaged in extinguishing the fire twenty-two were
-affected, and in spite of medical treatment and use of the
-oxygen apparatus three died.</p>
-
-<p>From the same source we quote the following examples:</p>
-
-<p>In a denitrating installation (see Nitro-glycerin; Explosives)
-a man was engaged in blowing, by means of compressed air,
-weak nitric acid from a stoneware vessel sunk in the ground
-into a washing tower. As the whole system was already under
-high pressure the vessel suddenly exploded, and in doing so
-smashed a wooden vat containing similar acid, which spilt on
-the ground with sudden development of tetroxide vapours.
-The man inhaled much gas, but except for pains in the chest
-felt no serious symptoms at the time and continued to work
-the following day. Death occurred the next evening from
-severe dyspnœa.</p>
-
-<p>A somewhat similar case occurred in the nitrating room of
-a dynamite factory in connection with the cleaning of a waste
-acid egg; the vessel had for several days been repeatedly
-washed out with water made alkaline with unslaked lime.
-Two men then in turn got into the egg in order to remove
-the lime and lead deposit, compressed air being continuously
-blown in through the manhole. The foreman remained
-about a quarter of an hour and finished the cleaning
-without feeling unwell. Difficulty of breathing came on
-in the evening, and death ensued on the following day.</p>
-
-<p>In another case a worker was engaged in washing nitroxylene
-when, through a leak, a portion of the contents collected in
-a pit below. He then climbed into the pit and scooped the
-nitroxylene which had escaped into jars. This work took
-about three-quarters of an hour, and afterwards he complained
-of difficulty of breathing and died thirty-six hours later.<a href="#endnote31" id="endnote-ref31"><span class="endnote-marker">5</span></a> </p>
-
-<p>A worker again had to control a valve regulating the
-flow to two large vessels serving to heat or cool the nitrated
-liquid. Both vessels were provided with pressure gauges and
-open at the top. Through carelessness one of the vessels ran over,
-and instead of leaving the room after closing the valve, the
-man tried to get rid of the traces of his error, remaining in the
-atmosphere charged with the fumes,<a href="#endnote32" id="endnote-ref32"><span class="endnote-marker">6</span></a> and was poisoned.</p>
-
-<p><span class="pagenum"><a name="Page_44" id="Page_44">[44]</a></span></p>
-
-<h4>Nitric and Nitrous Salts and Compounds</h4>
-
-<p>When dissolving in nitric acid the substances necessary for
-making the various nitrates, nitric and nitrous oxides escape.
-In certain cases nitric and hydrochloric acids are used together
-to dissolve metals such as platinum and gold and ferric oxides,
-when chlorine as well as nitrous oxide escapes. Mention is
-necessary of the following:</p>
-
-<p><i>Barium nitrate</i> (Ba(NO₃)₂) is prepared as a colourless
-crystalline substance by acting on barium carbonate or barium
-sulphide with nitric acid. Use is made of it in fireworks
-(green fire) and explosives. In analogous way strontium
-nitrate (Sr(NO₃)₂) is made and used for red fire.</p>
-
-<p><i>Ammonium nitrate</i> (NH₄NO₃), a colourless crystalline substance,
-is obtained by neutralising nitric acid with ammonia
-or ammonium carbonate, and is also made by dissolving
-iron or tin in nitric acid. It is used in the manufacture of
-explosives.</p>
-
-<p><i>Lead nitrate</i> (Pb(NO₃)₂), a colourless crystalline substance,
-is made by dissolving lead oxide or carbonate in nitric acid.
-It is used in dyeing and calico printing, in the preparation
-of chrome yellow and other lead compounds, and mixed with
-lead peroxide (obtained by treatment of red lead with nitric
-acid) in the manufacture of lucifer matches. Apart from risk
-from nitrous fumes (common to all these salts) there is risk
-also of chronic lead poisoning.</p>
-
-<p><i>Nitrate of iron</i> (Fe(NO₃)₂), forming green crystals, is made
-by dissolving sulphide of iron or iron in cold dilute nitric acid.
-The so-called nitrate of iron commonly used in dyeing consists
-of basic sulphate of iron (used largely in the black dyeing of
-silk).</p>
-
-<p><i>Copper nitrate</i> (Cu(NO₃)₂), prepared in a similar way, is
-also used in dyeing.</p>
-
-<p><i>Mercurous nitrate</i> (Hg₂(NO₃)₂) is of great importance
-industrially, and is produced by the action of cold dilute
-nitric acid on an excess of mercury. It is used for ‘carotting’
-rabbit skins in felt hat making, for colouring horn, for
-etching, and for forming an amalgam with metals, in making
-a black bronze on brass (art metal), in painting on porcelain, &amp;c.</p>
-
-<p><i>Mercuric nitrate</i> (Hg(NO₃)₂) is made by dissolving mercury<span class="pagenum"><a name="Page_45" id="Page_45">[45]</a></span>
-in nitric acid or by treating mercury with excess of warm
-nitric acid. Both the mercurous and mercuric salts act as
-corrosives and are strongly poisonous (see also Mercury and
-Hat Manufacture).</p>
-
-<p><i>Nitrate of silver</i> (AgNO₃) is obtained by dissolving silver
-in nitric acid and is used commercially as a caustic in the well-known
-crystalline pencils (lunar caustic). Its absorption into
-the system leads to accumulation of silver in the skin—the
-so-called argyria (see Silver). Such cases of chronic poisoning
-are recorded by Lewin.<a href="#endnote33" id="endnote-ref33"><span class="endnote-marker">7</span></a> Argyria occurs among photographers
-and especially in the silvering of glass pearls owing to introduction
-of a silver nitrate solution into the string of pearls by
-suction. In northern Bohemia, where the glass pearl industry
-is carried on in the homes of the workers, I saw a typical case.
-The cases are now rare, as air pumps are used instead of the
-mouth.</p>
-
-<p><i>Sodium nitrite</i> (NaNO₂) is obtained by melting Chili saltpetre
-with metallic lead in cast-iron vessels. The mass is
-lixiviated and the crystals obtained on evaporation. The
-lead oxide produced is specially suitable for making red
-lead. Cases of lead poisoning are frequent and sometimes
-severe. Roth<a href="#endnote34" id="endnote-ref34"><span class="endnote-marker">8</span></a> mentions a factory where among 100 employed
-there were 211 attacks in a year.</p>
-
-<p><i>Amyl nitrite</i> (C₅H₁₁NO₂) is made by leading nitrous fumes
-into iso-amyl alcohol and distilling amyl alcohol with potassium
-nitrite and sulphuric acid. It is a yellowish fluid, the fumes
-of which when inhaled produce throbbing of the bloodvessels
-in the head and rapid pulse.</p>
-
-<p>For other nitric acid compounds see the following
-section on Explosives and the section on Manufacture of Tar
-Products (Nitro-benzene, &amp;c.).</p>
-
-<h4>Explosives</h4>
-
-<p>Numerous explosives are made with aid of nitric acid or a
-mixture of nitric and sulphuric acids. Injury to health and
-poisoning—especially through development of nitrous fumes—can
-be caused. Further, some explosives are themselves
-industrial poisons, especially those giving off volatile fumes
-or dust.</p>
-
-<p><span class="pagenum"><a name="Page_46" id="Page_46">[46]</a></span></p>
-
-<p>The most important are:</p>
-
-<p><i>Fulminate of mercury</i> (HgC₂N₂O₂) is probably to be
-regarded as the mercury salt of fulminic acid, an isomer
-of cyanic acid. It is used to make caps for detonating
-gunpowder and explosives, and is made by dissolving
-mercury in nitric acid and adding alcohol. The heavy white
-crystals of mercury fulminate are filtered off and dried.
-Very injurious fumes are produced in the reaction, containing
-ethyl acetate, acetic acid, ethyl nitrate, nitrous acid, volatile
-hydrocyanic acid compounds, hydrocyanic acid, ethyl cyanide,
-cyanic acid; death consequently can immediately ensue on
-inhalation of large quantities. The fulminate is itself poisonous,
-and risk is present in filtering, pressing, drying, and granulating
-it. Further, in filling the caps in the huts numerous cases of
-poisoning occur. Heinzerling thinks here that mercury fumes
-are developed by tiny explosions in the pressing and filling.
-In a factory in Nuremburg 40 per cent. of the women employed
-are said to have suffered from mercurial poisoning. Several
-cases in a factory at Marseilles are recorded by Neisser.<a href="#endnote35" id="endnote-ref35"><span class="endnote-marker">9</span></a>
-In addition to the risk from the salt there is even more
-from nitrous fumes, which are produced in large quantity in the
-fulminate department.</p>
-
-<p><i>Nitro-glycerin</i> (C₃H₅(O—NO₂)₃, dynamite, explosive gelatine).—Nitro-glycerin
-is made by action of a mixture of nitric
-and sulphuric acids on anhydrous glycerin. The method of
-manufacture is as follows (<a href="#fig10">see fig. 10</a>): glycerin is allowed
-to flow into the acid mixture in leaden vessels; it is agitated
-by compressed air and care taken that the temperature remains
-at about 22° C., as above 25° there may be risk. The liquid is
-then run off and separates into two layers, the lighter nitro-glycerin
-floating on the top of the acid. The process is watched
-through glass windows. The nitro-glycerin thus separated is run
-off, washed by agitation with compressed air, then neutralised
-(with soda solution) and again washed and lastly filtered. The
-acid mixture which was run off is carefully separated by standing,
-as any explosive oil contained in it will rise up. The waste
-acid freed from nitro-glycerin is recovered in special apparatus,
-being denitrified by hot air and steam blown through it.
-The nitrous fumes are condensed to nitric acid. The sulphuric
-acid is evaporated.</p>
-
-<p><span class="pagenum"><a name="Page_47" id="Page_47">[47]</a></span></p>
-
-<p><i>Dynamite</i> is made by mixing nitro-glycerin with infusorial
-earth previously heated to redness and purified.</p>
-
-<p><i>Blasting gelatine</i> is made by dissolving gun cotton (collodion
-wool, nitro-cellulose) in nitro-glycerin. Both are pressed into
-cartridge shape.</p>
-
-<p>Nitro-glycerin itself is a strong poison which can be
-absorbed both through the skin
-and from the alimentary canal.
-Kobert describes a case where
-the rubbing of a single drop
-into the skin caused symptoms
-lasting for ten hours. Workmen
-engaged in washing out
-nitro-glycerin from the kieselguhr
-earth, having in doing so
-their bare arms immersed in
-the liquid, suffered. Although
-it be granted that nitro-glycerin
-workers become to a large
-extent acclimatised, cases of
-poisoning constantly occur in
-explosives factories referable to
-the effect of nitro-glycerin.</p>
-
-<p>Persons mixing and sieving
-dynamite suffer from ulcers
-under the nails and at the
-finger-tips which are difficult to
-heal. Further, where the apparatus
-employed is not completely
-enclosed nitrous fumes
-escape and become a source of
-danger. Formerly this danger
-was constantly present in the
-nitrating house where nitration
-was effected in open vessels. Now that this is usually done
-in closed nitrating apparatus with glass covers the danger
-is mainly limited to the acid separating house, wash house,
-and especially the room in which denitration of the waste
-acids is effected.</p>
-
-<div class="figcenter" style="width: 275px;" id="fig10">
-
-<img src="images/fig10.jpg" width="275" height="500" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 10.</span>—Preparation of Nitro-glycerin.
-Nitrating Vessel (<i>after Guttmann</i>)</p>
-
-<p class="caption">A Glycerine reservoir; C Fume
-flue; D Acid supply pipe; E, G Compressed
-air supply; H, J Cooling coil.</p>
-
-</div>
-
-<p>A fatal case in a nitro-glycerin factory was reported in<span class="pagenum"><a name="Page_48" id="Page_48">[48]</a></span>
-1902 where, through carelessness, a separator had overflowed.
-The workman who tried to wash away the acid with water
-inhaled so much of the nitrous fumes that he succumbed
-sixteen hours later.</p>
-
-<p>Other cases of poisoning by nitrous fumes occurring in the
-denitrating department are described in detail in the section
-on the use of nitric acid.</p>
-
-<p>One of these occurred to a man forcing dilute nitric acid
-from an earthenware egg by means of compressed air into a
-washing tower. The egg burst and broke an acid tank. The
-workman died on the following day.</p>
-
-<p>A fatal case occurred in a dynamite factory in cleaning out a
-storage tank for waste acid in spite of previous swilling and
-ventilation.</p>
-
-<p><i>Gun cotton</i> (<i>pyroxyline</i>) and its use.—Pyroxyline is the
-collective name for all products of the action of nitric acid on
-cellulose (cotton wool and similar material); these products
-form nitric acid ester of cellulose (nitro-cellulose).</p>
-
-<p>Gun cotton is formed by the action of strong nitric acid on
-cellulose (cotton wool). A mixture of sulphuric and nitric
-acids is allowed to act on cotton wool (previously freed from
-grease, purified, and dried), with subsequent pressing and
-centrifugalising. In the nitrating centrifugal machine (in the
-Selvig-Lange method) both processes are effected at the same
-time.</p>
-
-<p>The interior of this apparatus is filled with nitric
-acid, cotton wool is introduced, the acid fumes exhausted
-through earthenware pipes, and the remainder of the acid
-removed by the centrifugal machine; the nitrated material is
-then washed, teazed in teazing machines, again washed,
-neutralised with calcium carbonate, again centrifugalised, and
-dried. Since drying in drying stoves is a great source of danger
-of explosion, dehydration is effected with alcohol, and the gun
-cotton intended for the production of smokeless powder carried
-directly to the gelatinising vessels (see Smokeless Powder).</p>
-
-<p>Gun cotton, apart from its use for smokeless powder, is
-pressed in prisms and used for charging torpedoes and sea
-mines.</p>
-
-<p><i>Collodion cotton</i> is a partially nitrated cellulose. It is
-prepared generally in the same way as gun cotton, except that<span class="pagenum"><a name="Page_49" id="Page_49">[49]</a></span>
-it is treated with a more dilute acid. It is soluble (in contradistinction
-to gun cotton) in alcohol-ether, and the solution
-is known as collodion (as used in surgery, photography, and to
-impregnate incandescent gas mantles). Mixed with camphor
-and heated collodion forms celluloid.</p>
-
-<p>In Chardonnet’s method for making artificial silk collodion
-is used by forcing it through fine glass tubes and drawing
-and spinning it. The alcohol-ether vapours are carried away
-by fans and the spun material is de-nitrated by ammonium
-sulphide.</p>
-
-<p><i>Smokeless powder</i> is a gun cotton powder—that is gun
-cotton the explosive power of which is utilised by bringing it
-into a gelatinous condition. This is effected by gelatinising
-the gun cotton with alcohol-ether or acetone (sometimes with
-addition of camphor, resin, &amp;c.). A doughy, pasty mass results,
-which is then rolled, washed, dried, and pressed into rods.
-Nobel’s nitroleum (artillery powder) consists half of nitro-glycerin
-and half of collodion cotton. In the production of
-gun cotton and collodion cotton the workers are affected and
-endangered by nitric and nitrous fumes unless the nitrating
-apparatus is completely airtight.</p>
-
-<p>Erosion of the incisor teeth is general, but use of the new
-nitrating apparatus, especially of the nitrating centrifugal
-machines already described, has greatly diminished the
-evil. In making collodion, celluloid and artificial silk, in addition
-to the risks referred to in the production of gun cotton,
-the vapour from the solvents, ether, alcohol, acetone, acetic-ether,
-and camphor, comes into consideration, but there is no
-account of such poisoning in the literature of the subject.</p>
-
-<p>Other explosives which belong to the aromatic series are
-described in the chapter on Tar Derivatives, especially picric
-acid.</p>
-
-<h4>PHOSPHORUS AND PHOSPHORUS MATCHES</h4>
-
-<p>The total production of <i>phosphorus</i> is not large. Formerly it
-was prepared from bone ash. Now it is made from phosphorite,
-which, as in the super-phosphate industry, is decomposed
-by means of sulphuric acid, soluble phosphate and calcium
-sulphate being formed; the latter is removed, the solution<span class="pagenum"><a name="Page_50" id="Page_50">[50]</a></span>
-evaporated, mixed with coal or coke powder, distilled in clay
-retorts, and received in water.</p>
-
-<p>Phosphorus is also obtained electro-chemically from a
-mixture of tricalcium phosphate, carbon, and silicic acid,
-re-distilled for further purification, and finally poured under
-water into stick form.</p>
-
-<p><i>Red phosphorus</i> (amorphous phosphorus) is obtained by
-heating yellow phosphorus in the absence of air and subsequently
-extracting with carbon bisulphide.</p>
-
-<p><i>Phosphorus matches</i> are made by first fixing the wooden
-splints in frames and then dipping the ends either into paraffin
-or sulphur which serve to carry the flame to the wood. Then
-follows dipping in the phosphorus paste proper, for which
-suitable dipping machines are now used. The phosphorus
-paste consists of yellow phosphorus, an oxidising agent (red
-lead, lead nitrate, nitre, or manganese dioxide) and a binding
-substance (dextrine, gum); finally the matches are dried and
-packed.</p>
-
-<p><i>Safety matches</i> are made in the same way, except that
-there is no phosphorus. The paste consists of potassium
-chlorate, sulphur, or antimony sulphide, potassium bichromate,
-solution of gum or dextrine, and different admixtures such as
-glass powder, &amp;c. These matches are saturated with paraffin
-or ammonium phosphate. To strike them a special friction
-surface is required containing red phosphorus, antimony
-sulphide, and dextrine. In the act of striking the heat
-generated converts a trace of the red phosphorus into the
-yellow variety which takes fire.</p>
-
-<p>Danger to health arises from the poisonous gases evolved
-in the decomposition of the calcined bones by sulphuric
-acid. When phosphorus is made from phosphorite the same
-dangers to health are present as in the production of super-phosphate
-artificial manure, which is characterised by the
-generation of hydrofluoric and fluosilicic acids. In the
-distillation of phosphorus phosphoretted hydrogen and phosphorus
-fumes may escape and prove dangerous.</p>
-
-<p>Industrial poisoning from the use of white phosphorus in
-the manufacture of matches has greater interest than its
-occurrence in the production of phosphorus itself. Already
-in 1845 chronic phosphorus poisoning (phosphorus necrosis)<span class="pagenum"><a name="Page_51" id="Page_51">[51]</a></span>
-had been observed by Lorinser, and carefully described by Bibra
-and Geist in 1847. In the early years of its use phosphorus
-necrosis must have been fairly frequent in lucifer match
-factories, and not infrequently have led to death. This
-necessitated preventive measures in various States (see Part III);
-cases became fewer, but did not disappear altogether.</p>
-
-<p>Especially dangerous is the preparation of the paste,
-dipping, and manipulations connected with drying and filling
-the matches into boxes. According to the reports of the
-Austrian factory inspectors there are about 4500 lucifer match
-workers in that country, among whom seventy-four cases of
-necrosis are known to have occurred between the years 1900
-and 1908 inclusive.</p>
-
-<p>Teleky<a href="#endnote36" id="endnote-ref36"><span class="endnote-marker">1</span></a> considers these figures much too small, and from
-inquiries undertaken himself ascertained that 156 cases
-occurred in Austria between 1896 and 1906, while factory
-inspectors’ reports dealt with only seventy-five. He was of
-opinion that his own figures were not complete, and thinks
-that in the ten years 1896 to 1905 there must have been from
-350 to 400 cases of phosphorus necrosis in the whole of Austria.
-Despite strict regulations, modern equipment of the factories,
-introduction of improved machinery, and limitation of the white
-phosphorus match industry to large factories, it has not been
-possible to banish the risk, and the same is true of Bohemia,
-where there is always a succession of cases. Valuable statistics
-of phosphorus necrosis in Hungary are available.<a href="#endnote37" id="endnote-ref37"><span class="endnote-marker">2</span></a> In 1908
-there were sixteen factories employing 1882 workers of whom
-30 per cent. were young—children even were employed. The
-industry is carried on in primitive fashion without hygienic
-arrangements anywhere. It is strange that, notwithstanding
-these bad conditions, among a large number of the workers
-examined only fourteen active cases were found, in addition
-to two commencing, and fifteen cured—altogether thirty-one
-cases (excluding fifty-five cases in which there was some
-other pathological change in the mouth). Altogether ninety-three
-cases since 1900 were traced in Hungary, and in view
-of the unsatisfactory situation preventive measures, short
-of prohibition of the use of white phosphorus, would be
-useless.</p>
-
-<p>In England among 4000 lucifer match workers there were<span class="pagenum"><a name="Page_52" id="Page_52">[52]</a></span>
-thirteen cases in the years 1900 to 1907 inclusive. Diminution
-in the number was due to improved methods of manufacture
-and periodical dental examination prescribed under Special
-Rules.</p>
-
-<p>Phosphorus necrosis is not the only sign of industrial
-phosphorus poisoning, as the condition of fragilitas ossium is
-recognised.<a href="#endnote38" id="endnote-ref38"><span class="endnote-marker">3</span></a> From what has been said it is evident that
-preventive measures against phosphorus poisoning, although
-they diminish the number, are not able to get rid of phosphorus
-necrosis, and so civilised States have gradually been driven to
-prohibit the use of white phosphorus (for the history of this
-see Part III).</p>
-
-<p>Use of chrome salts (especially potassium bichromate) in
-the preparation of the paste causes risk of poisoning in premises
-where ‘Swedish’ matches are made. Attention has been called
-to the frequency of chrome ulceration.<a href="#endnote39" id="endnote-ref39"><span class="endnote-marker">4</span></a> The paste used consists
-of 3-6 per cent. chrome salt, so that each match head contains
-about ½ mg. Wodtke found among eighty-four workers early
-perforation of the septum in thirteen. Severe eczema also
-has been noted.</p>
-
-<p>It is even alleged that red phosphorus is not entirely free
-from danger. Such cachexia as has been noted may be
-referable to the absorption of potassium chlorate.</p>
-
-<h5>Other Uses of Phosphorus and Compounds of Phosphorus</h5>
-
-<p>Isolated cases of phosphorus poisoning have been observed
-in the manufacture of phosphor-bronze. This consists of
-90 parts copper, 9 parts tin, and 0·5 to 0·75 phosphorus.</p>
-
-<p><i>Sulphides of phosphorus</i> (P₂S₅, P₄S₃, P₂S₃) are made by
-melting together red phosphorus and sulphur. They make a
-satisfactory substitute for the poisonous yellow phosphorus
-and are considered non-poisonous, but the fact remains that
-they give off annoying sulphuretted hydrogen gas.</p>
-
-<p><i>Phosphoretted hydrogen gas</i> (PH₃) rarely gives rise to
-industrial poisoning. It may come off in small amounts in
-the preparation of acetylene and in the preparation of, and
-manipulations with, white phosphorus. It is stated that in
-acetylene made of American calcium carbide 0·04 per cent. of
-phosphoretted hydrogen is present, and in acetylene from<span class="pagenum"><a name="Page_53" id="Page_53">[53]</a></span>
-Swedish calcium carbide 0·02 per cent.; Lunge and Cederkreutz
-found an acetylene containing 0·06 per cent. These
-amounts might cause poisoning if the gas were diffused in
-confined spaces. Poisoning, in part attributable to phosphoretted
-hydrogen gas, is brought about through ferro-silicon
-(see under Ferro-silicon).</p>
-
-<h5>Superphosphate and Artificial Manure</h5>
-
-<p><i>Superphosphate</i>, an artificial manure, is prepared from
-various raw materials having a high proportion of insoluble
-basic calcium phosphate (tricalcium phosphate), which by
-treatment with sulphuric acid are converted into the soluble
-acid calcium phosphate (monocalcium phosphate) and calcium
-sulphate. Mineral substances such as phosphorites, coprolites,
-guano, bone ash, &amp;c., serve as the starting-point. Chamber
-acid, or sometimes the waste acid from the preparation of
-nitro-benzene or purification of petroleum, are used in the
-conversion. The raw materials are ground in closed-in apparatus,
-under negative pressure, and mixed with the sulphuric
-acid in wooden lead-lined boxes or walled receptacles. The
-product is then stored until the completion of the reaction
-in ‘dens,’ dried, and pulverised in disintegrators.</p>
-
-<p>In the manufacture of bone meal extraction of the
-fat from the bones with benzine precedes treatment with
-acid.</p>
-
-<p>A further source of artificial manure is <i>basic slag</i>—the slag
-left in the manufacture of steel by the Gilchrist-Thomas
-method—which contains 10-25 per cent. of readily soluble
-phosphoric acid. It requires, therefore, only to be ground into
-a very fine powder to serve as a suitable manure.</p>
-
-<p>Owing to the considerable heat generated by the action
-of the sulphuric acid when mixed with the pulverised raw
-materials (especially in the conversion of the phosphorites)
-hydrofluoric and silicofluoric acid vapours are evolved in
-appreciable amount, and also carbonic and hydrochloric
-acid vapours, sulphur dioxide, and sulphuretted hydrogen gas.
-These gases—notably such as contain fluorine—if not effectually
-dealt with by air-tight apparatus and exhaust ventilation—may
-lead to serious annoyance and injury to the persons<span class="pagenum"><a name="Page_54" id="Page_54">[54]</a></span>
-employed. Further, there is risk of erosion of the skin from
-contact with the acid, &amp;c.</p>
-
-<p>A case is described of pustular eczema on the scrotum
-of a worker engaged in drying sodium silicofluoride, due
-probably to conveyance of irritating matter by the hands.
-After the precaution of wearing gloves was adopted the
-affection disappeared.</p>
-
-<p>A marked case of poisoning by nitrous fumes even is
-recorded in the manufacture of artificial manure from mixing
-Chili saltpetre with a very acid superphosphate.</p>
-
-<p>Injurious fumes can be given off in the rooms where
-bones are stored and, in the absence of efficient ventilation,
-carbonic acid gas can accumulate to an amount that may be
-dangerous.</p>
-
-<p>The fine dust produced in the grinding of <i>basic slag</i> has,
-if inhaled, a markedly corrosive action on the respiratory
-mucous membrane attributed by some to the high proportion
-(about 50 per cent.) in it of quicklime. As a matter of fact
-numerous small ulcers are found on the mucous membranes of
-basic slag grinders and ulceration of the lung tissue has been
-observed. The opinion is expressed that this is due to corrosive
-action of the dust itself, and not merely to the sharp, jagged
-edged particles of dust inhaled. And in support of this view is
-cited the frequency with which epidemics of pneumonia have
-been noted among persons employed in basic slag works.
-Thus in Nantes thirteen cases of severe pneumonia followed one
-another in quick succession. And similar association has been
-noted in Middlesbrough, where the action of the basic slag dust
-was believed to injure the lung tissue and therefore to provide
-a favourable soil for the development of the pneumonia
-bacillus. Statistics collected by the Imperial Health Office
-showed that in the three years 1892, 1893, and 1894, 91·1 per
-cent., 108·9 per cent., and 91·3 per cent. respectively of the
-workers became ill, the proportion of respiratory diseases
-being 56·4 per cent., 54·4 per cent., and 54·3 per cent. respectively.
-A case of severe inflammation of the lungs is described
-in a labourer scattering basic slag in a high wind which drove
-some of it back in his face.</p>
-
-<p>Lewin has described a case in which a worker scattering a
-mixture of basic slag and ammonium superphosphate suffered<span class="pagenum"><a name="Page_55" id="Page_55">[55]</a></span>
-from an eczematous ulceration which, on being scratched by
-the patient, became infected and led to death from general
-blood poisoning. Lewin regarded the fatal issue as the
-sequela of the scattering of the manure.</p>
-
-<p>Inflammation of the conjunctiva and of the eyelids has
-been recorded.</p>
-
-<h4>CHROMIUM COMPOUNDS AND THEIR USES</h4>
-
-<p>Chrome ironstone, lime, and soda are ground and intimately
-mixed. They are next roasted in reverberatory furnaces,
-neutral <i>sodium chromate</i> being formed. This is lixiviated and
-converted into sodium bichromate (Na₂Cr₂O₇) by treatment
-with sulphuric acid. Concentration by evaporation follows;
-the concentrated liquor is crystallised in cast-iron tanks.
-The crystals are centrifugalised, dried, and packed. <i>Potassium
-bichromate</i> may be made in the same way, or, as is
-usually the case, out of sodium bichromate and potassium
-chloride.</p>
-
-<p>The bichromates are used in the preparation and oxidation
-of chrome colours, but their principal use is in dyeing and
-calico printing, bleaching palm oil, purifying wood spirit and
-brandy, in the preparation of ‘Swedish’ matches, in the
-manufacture of glass, in photography, in dyeing, in tanning,
-and in oxidation of anthracene to anthraquinone.</p>
-
-<h5>Lead Chromate and Chrome Colours</h5>
-
-<p><i>Chrome yellow</i> is neutral lead chromate (PbCrO₄). It is
-obtained by precipitating a solution of potassium bichromate
-with lead acetate or lead nitrate, or by digesting the bichromate
-solution with lead sulphate, and is used as a paint and in
-calico and cloth printing. With Paris or Berlin blue it forms
-a <i>chrome green</i>. <i>Chrome orange</i>, i.e. basic lead chromate
-(PbCrO₄Pb(OH)₂) is made by adding milk of lime to lead
-chromate and boiling.</p>
-
-<p><i>Chromium</i> and <i>chromic acid salts</i> are widely used in dyeing
-and printing, both as mordants and oxidising agents and
-as dyes (chrome yellow, chrome orange). In mordanting
-wool with potassium chromate the wool is boiled in a<span class="pagenum"><a name="Page_56" id="Page_56">[56]</a></span>
-potassium chromate solution to which acids such as sulphuric,
-lactic, oxalic, or acetic are added.</p>
-
-<p>In dyeing with chrome yellow, for instance, the following
-is the process. Cotton wool is saturated with nitrate or
-acetate of lead and dried, passed through lime water, ammonia,
-or sodium sulphate, and soaked in a warm solution of potassium
-bichromate. The yellow is converted into the orange colour by
-subsequent passage through milk of lime.</p>
-
-<p><i>Chrome tanning.</i>—This method of producing chrome
-leather, first patented in America, is carried out by either the
-single or two bath process.</p>
-
-<p>In the two bath process the material is first soaked in a
-saturated solution of bichromate and then treated with an acid
-solution of thiosulphate (sodium hyposulphite) so as to reduce
-completely the chromic acid. The process is completed even
-with the hardest skins in from two to three days.</p>
-
-<p>In the single bath method basic chrome salts are used in
-highly concentrated form. The skins are passed from dilute
-into strong solutions. In this process also tanning is quickly
-effected.</p>
-
-<p><span class="smcap">Effects on Health.</span>—Among the persons employed in
-the bichromate factory of which Leymann has furnished
-detailed particulars, the number of sick days was greater
-than that among other workers.</p>
-
-<p>Further, <i>erosion of the skin</i> (<i>chrome holes</i>) is characteristic
-of the manufacture of bichromates. These are sluggish
-ulcers taking a long time to heal. This is the main cause of
-the increased general morbidity that has been observed. The
-well-known perforation of the septum of the nose without,
-however, causing ulterior effects, was observed by Leymann in
-all the workers in the factory. This coincides with the opinion
-of others who have found the occurrence of chrome holes, and
-especially perforation of the septum, as an extraordinarily
-frequent occurrence. Many such observations are recorded,<a href="#endnote40" id="endnote-ref40"><span class="endnote-marker">1</span></a>
-and also in workers manufacturing ‘Swedish’ matches. Thus
-of 237 bichromate workers, ulcers were present in 107 and
-perforation in 87. According to Lewin, who has paid special
-attention to the poisonous nature of chromium compounds, they
-can act in two ways: first, on the skin and mucous membrane,
-where the dust alights, on the alimentary tract by swallowing,<span class="pagenum"><a name="Page_57" id="Page_57">[57]</a></span>
-and on the pharynx by inhalation. Secondly, by absorption
-into the blood, kidney disease may result.</p>
-
-<p>The opinion that chromium, in addition to local, can have
-constitutional effect is supported by other authorities. Leymann
-describes a case of severe industrial chrome poisoning
-accompanied by nephritis in a worker who had inhaled and
-swallowed much chromate dust in cleaning out a vessel.
-Regulations for the manufacture of bichromates (see Part III)
-have no doubt improved the condition, but reports still show
-that perforation of the septum generally takes place.</p>
-
-<p>It must be borne in mind that practically all chromium
-compounds are not alike poisonous. Chrome ironstone is
-non-poisonous, and the potassium and sodium salts are by far
-the most poisonous, while the neutral chromate salts and
-chromic oxide are only slightly so. Pander found that
-bichromates were 100 times as poisonous as the soluble
-chromium oxide compounds, and Kunkel is of opinion that
-poisonous effect shown by the oxides is attributable to traces
-of oxidation into chromic acid.</p>
-
-<p>Lewin, on the other hand, declares in a cautionary notice
-for chrome workers generally that all chromium compounds
-are poisonous, and therefore all the dyes made from them.<a href="#endnote41" id="endnote-ref41"><span class="endnote-marker">2</span></a> </p>
-
-<p>In the manufacture of bichromates, chance of injury to
-health arises partly from the dust, and partly from the steam,
-generated in pouring water over the molten mass. The steam
-carries particles of chromium compounds with it into the air.
-In evaporating the chromate solutions, preparation of the
-bichromate, breaking the crystals, drying and packing, the
-workers come into contact with the substance and the liquors.
-Chrome ulceration is, therefore, most frequently found among
-those employed in the crystal room and less among the furnace
-hands.</p>
-
-<p>From 3·30 to 6·30 mg. of bichromate dust have been found
-in 1 c.m. of air at breathing level in the room where chromate
-was crushed, and 1·57 mg. where it was packed. Further,
-presence of chromium in the steam escaping from the hot
-chrome liquors has been proved.<a href="#endnote42" id="endnote-ref42"><span class="endnote-marker">3</span></a> </p>
-
-<p>Poisoning from use of chrome colours is partly attributable
-to lead, as, for example, in making yellow coloured tape
-measures, yellow stamps, and from the use of coloured<span class="pagenum"><a name="Page_58" id="Page_58">[58]</a></span>
-thread. Gazaneuve<a href="#endnote43" id="endnote-ref43"><span class="endnote-marker">4</span></a> found 10 per cent. of lead chromate
-in such thread, in wool 18 per cent., and in the dust of
-rooms where such yarn was worked up 44 per cent.</p>
-
-<p>Use of chrome colours and mordants is accompanied by
-illness which certainly is referable to the poisonous nature of
-the chrome. In France use of chromic and phosphoric acid in
-etching zinc plates has caused severe ulceration.</p>
-
-<p>Bichromate poisoning has been described among photographers
-in Edinburgh in the process of carbon printing, in
-which a bichromate developer is used.<a href="#endnote44" id="endnote-ref44"><span class="endnote-marker">5</span></a> </p>
-
-<p>There is much evidence as to occurrence of skin eruptions
-and development of pustular eczema of the hands and forearms
-of workers in chrome tanneries.<a href="#endnote45" id="endnote-ref45"><span class="endnote-marker">6</span></a> In a large leather factory
-where 300 workers were constantly employed in chrome
-tanning nineteen cases of chrome ulceration were noted within
-a year. Injury to health was noted in a chrome tannery in
-the district of Treves, where the two bath process was used,
-from steam developed in dissolving the chromate in hot
-water.</p>
-
-<p>Finally, I have found several records in 1907 and 1908 of
-perforation of the septum in Bohemian glass workers.</p>
-
-<h4>MANGANESE COMPOUNDS</h4>
-
-<p>The raw material of the manganese industry is <i>hausmannite</i>
-(manganese dioxide, MnO₂). This is subjected to a crushing
-process, sorted, sieved, finely ground, washed, and dried.
-The pure finely ground manganese dioxide is much used in the
-chemical industry, especially in the recovery of chlorine in
-the Weldon process and in the production of <i>potassium permanganate</i>,
-which is obtained by melting manganese dioxide with
-caustic soda and potassium chlorate or nitre, lixiviation and
-introduction of carbonic acid, or better by treatment with
-ozone.</p>
-
-<p>Manganese is also used in the production of colours: the
-natural and artificial umbers contain it; in glass works it is used
-to decolourise glass, and also in the production of coloured
-glass and glazes; in the manufacture of stove tiles, and in
-the production of driers for the varnish and oil industry.<span class="pagenum"><a name="Page_59" id="Page_59">[59]</a></span>
-Manganese and compounds of manganese are dangerous when
-absorbed into the system as dust.</p>
-
-<p>Already in 1837 nervous disorders had been described in
-workmen who ground manganese dioxide.<a href="#endnote46" id="endnote-ref46"><span class="endnote-marker">1</span></a> The malady was
-forgotten, until Jaksch<a href="#endnote47" id="endnote-ref47"><span class="endnote-marker">2</span></a> in Prague in 1901 demonstrated several
-such cases in persons employed in a large chemical factory in
-Bohemia, from the drying of Weldon mud. In the same
-year three similar cases were also described in Hamburg.<a href="#endnote48" id="endnote-ref48"><span class="endnote-marker">3</span></a> In
-1902 Jaksch observed a fresh case of poisoning, and in the
-factory in question described a condition of manganophobia
-among the workers, obviously hysterical, in which symptoms
-of real manganese poisoning were simulated. In all some
-twenty cases are known. Jaksch is of opinion that it is
-manganese dust rich in manganese protoxide that is alone
-dangerous, since, if the mud has been previously treated with
-hydrochloric acid, by which the lower oxides are removed, no
-illness can be found. The most dangerous compounds are
-MnO and Mn₃O₄.</p>
-
-<h4>PETROLEUM</h4>
-
-<p><span class="smcap">Occurrence and Uses.</span>—Crude petroleum flows spontaneously
-from wells in consequence of high internal pressure of
-gas or is pumped up. In America and Russia also it is conveyed
-hundreds of miles in conduits to the ports to be led
-into tank steamers.</p>
-
-<p>The crude oil is a dark-coloured liquid which, in the case
-of Pennsylvanian mineral oil, consists mainly of a mixture of
-hydrocarbons of the paraffin series, or, in Baku oil, of those of
-the naphtha series. There are in addition sulphur compounds,
-olefines, pyridin, &amp;c. The crude oil is unsuitable for illuminating
-purposes and is subjected to a distillation process. It is
-split up into three fractions by a single distillation, namely,
-(<i>a</i>) benzines (boiling-point 150° C.), (<i>b</i>) lighting oil (boiling-point
-150°-300° C.); at a temperature of 300° C. the distillation is
-stopped so that (<i>c</i>) the residuum boiling above 300° C. remains.
-Distillation is effected (in America) in large stills, in which
-periodically benzine and lighting oil up to 300° C. is distilled and
-the residuum run off. In Baku continuously working batteries
-of so-called cylindrical boilers are used, into which the crude<span class="pagenum"><a name="Page_60" id="Page_60">[60]</a></span>
-oil streams. In the first set of boilers, the temperature in
-which rises to 150° C., the benzine is distilled off, and in the
-succeeding ones, heated to 300° C., the illuminating petroleum
-oils (kerosine), the residuum flowing continually away.</p>
-
-<p>The <i>mineral oil residues</i> are used as fuel. Heating by
-this means, tried first only in Russia, is spreading, especially
-for the heating of boilers, in which case the liquid fuel is
-blown in generally as a spray. The combustion if rightly
-planned is economical and almost smokeless.</p>
-
-<p>The American oil residuum, rich in paraffin, is distilled, the
-distillate is cooled and separated by pressure into solid paraffin
-and liquid oil. The latter and the Russian mineral oil residues
-which are free from paraffin are widely used as lubricants.
-In the production of lubricants the residues are distilled at
-low temperature (in vacuo or by aid of superheated steam) and
-separated into various qualities by fractional cooling, are then
-purified with sulphuric acid, and finally washed with caustic
-soda solution.</p>
-
-<p>In the preparation of vaseline the residum is not distilled,
-but purified only with fuming sulphuric acid and decolourised
-with animal charcoal.</p>
-
-<p>The <i>illuminating oil</i> is next subjected to a purifying process
-(refining); it is first treated with sulphuric acid and well
-agitated by means of compressed air. The acid laden with the
-impurities is drawn off below, and the oil freed from acid by
-washing first with caustic soda and subsequently with water.
-It is then bleached in the sun. For specially fine and high
-flash point petroleum the oil undergoes a further distillation
-and purification with acid.</p>
-
-<p>The fractions of crude petroleum with low boiling-point
-(under 150° C.) are known commercially as raw <i>benzine</i> or
-<i>petrol naphtha</i>. It is used for cleaning, in extraction of fats
-and oils, and for benzine motors.</p>
-
-<p>Frequently raw benzine is subjected to a purifying process
-and to fractional distillation. Purification is carried out by
-means of sulphuric acid and soda liquor and subsequent
-separation into three fractions and a residue which remains in
-the retort—(<i>a</i>) <i>petroleum ether</i> (called gasoline, canadol, and
-rhigoline), which comes over between 40° and 70° C., and serves
-for carburetting water gas and other similar gases, as a solvent<span class="pagenum"><a name="Page_61" id="Page_61">[61]</a></span>
-for resin, oil, rubber, &amp;c.; (<i>b</i>) <i>purified benzine</i> (70°-120° C.) is
-used as motor spirit and in chemical cleaning; (<i>c</i>) <i>ligroine</i>
-(120°-135° C.), used for illuminating purposes; and (<i>d</i>) the
-<i>residual oil</i> (above 135° C.) serves for cleaning machinery and,
-especially, as a solvent for lubricating oil, and instead of
-turpentine in the production of lacquers, varnishes, and oil
-colours.</p>
-
-<p>In <i>chemical cleaning</i> works benzine is used in closed-in
-washing apparatus, after which the clothes are centrifugalised
-and dried. In view of the risk of fire in these manipulations,
-originating mainly from frictional electricity, various substances
-are recommended to be added to the benzine, of which
-the best known is that recommended by Richter, consisting of
-a watery solution of oleate of sodium or magnesium.</p>
-
-<p><span class="smcap">Effects on Health.</span>—Industrial poisoning in the petroleum
-industry is attributable to the gases given off from
-crude petroleum or its products and to inhalation of naphtha
-dust. Poisoning occurs principally in the recovery of petroleum
-and naphtha from the wells, in storage and transport (in
-badly ventilated tanks on board ship, and in entering petroleum
-tanks), in the refinery in cleaning out petroleum stills
-and mixing vessels, and in emptying out the residues. Further
-cases occur occasionally from use of benzine in chemical
-cleaning.</p>
-
-<p>In addition to poisoning the injurious effect of petroleum
-and its constituents on the skin must be borne in mind.
-Opinion is unanimous that this injurious action of mineral oil
-is limited to the petroleum fractions with high boiling-point
-and especially petroleum residues.</p>
-
-<p>Statistics officially collected in Prussia show the general
-health of petroleum workers to be favourable. These statistics
-related to 1380 persons, of whom forty-three were suffering
-from symptoms attributable to their occupation. Of these
-forty-three, nine only were cases of poisoning, the remainder
-being all cases of petroleum acne.</p>
-
-<p>The conditions also in French refineries from statistics
-collected in the years 1890-1903 seem satisfactory. Eighteen
-cases of petroleum acne were reported, eleven of which occurred
-at the paraffin presses, five in cleaning out the still residues,
-and two were persons filling vessels.</p>
-
-<p><span class="pagenum"><a name="Page_62" id="Page_62">[62]</a></span></p>
-
-<p>The conditions are clearly less favourable in the Russian
-petroleum industry.<a href="#endnote49" id="endnote-ref49"><span class="endnote-marker">1</span></a> </p>
-
-<p>The workers at the naphtha wells suffer from acute and
-chronic affections of the respiratory organs. Those suffer
-most who cover the wells with cast iron plates to enable the
-flow of naphtha to be regulated and led into the reservoirs.
-In doing this they inhale naphtha spray.</p>
-
-<p>Lewin<a href="#endnote50" id="endnote-ref50"><span class="endnote-marker">2</span></a> describes cases of severe poisoning with fatal issue
-among American workers employed in petroleum tanks. One
-man who wished to examine an outlet pipe showed symptoms
-after only two minutes. Weinberger describes severe poisoning
-of two workers engaged in cleaning out a vessel containing
-petroleum residue.</p>
-
-<p>Interesting particulars are given of the effect of petroleum
-emanations on the health of the men employed in the petroleum
-mines of Carpathia, among whom respiratory affections were
-rarely found, but poisoning symptoms involving unconsciousness
-and cerebral symptoms frequently. These experiences
-undoubtedly point to differing physiological effects of different
-kinds of naphtha.</p>
-
-<p>This is supported by the view expressed by Sharp in
-America that different kinds of American petroleum have
-different effects on the health of the workers, which can be
-easily credited from the different chemical composition of crude
-naphthas. Thus in Western Virginia, where a natural heavy
-oil is obtained, asphyxia from the gas is unknown, although
-transient attacks of headache and giddiness may occur, whereas in
-Ohio, where light oils are obtained, suffocative attacks are not
-infrequent. And it is definitely stated that some naphtha
-products irritate the respiratory passages, while others affect
-the central nervous system.<a href="#endnote51" id="endnote-ref51"><span class="endnote-marker">3</span></a> </p>
-
-<p>The authors mentioned refer to occurrence of cases of
-poisoning in the refining of naphtha from inhalation of the
-vapour of the light oils benzine and gasoline. Fatal cases have
-been recorded in badly ventilated workrooms in which the
-products of distillation are collected. Workers constantly
-employed in these rooms develop chronic poisoning, which
-is reported also in the case of women employed with
-benzine. Intoxication is frequently observed, it is stated,
-among the workmen employed in cleaning out the railway<span class="pagenum"><a name="Page_63" id="Page_63">[63]</a></span>
-tank waggons in which the mineral oils and petroleum are
-carried.</p>
-
-<p>Foulerton<a href="#endnote52" id="endnote-ref52"><span class="endnote-marker">4</span></a> describes severe poisoning in a workman who
-had climbed into a petroleum reservoir, and two similar cases
-from entering naphtha tanks are given in the Report of the
-Chief Inspector of Factories for 1908. Two fatal cases are
-reported by the Union of Chemical Industry in Germany in
-1905 in connection with naphtha stills. Such accidents are
-hardly possible, except when, through insufficient disconnection
-of the still from the further system of pipes, irrespirable
-distillation gases pass backwards into the opened still where
-persons are working. Ordinary cocks and valves, therefore, do
-not afford sufficient security. Thus, several workers engaged
-in repairing a still were rendered unconscious by gases drawn
-in from a neighbouring still, and were only brought round after
-oxygen inhalation.</p>
-
-<p>Gowers describes a case of chronic poisoning following on
-frequent inhalation of gases given off from a petroleum motor,
-the symptoms being slurring speech, difficulty of swallowing, and
-weakness of the orbicularis and facial muscles. Gowers believed
-this to be petroleum gas poisoning (from incomplete combustion),
-especially as the symptoms disappeared on giving up
-the work, only to return on resuming it again.<a href="#endnote53" id="endnote-ref53"><span class="endnote-marker">5</span></a> </p>
-
-<p>Girls employed in glove cleaning and rubber factories are
-described as having been poisoned by benzine.<a href="#endnote54" id="endnote-ref54"><span class="endnote-marker">6</span></a> Poisoning
-of chauffeurs is described by several writers.<a href="#endnote55" id="endnote-ref55"><span class="endnote-marker">7</span></a> </p>
-
-<p>Recent literature<a href="#endnote56" id="endnote-ref56"><span class="endnote-marker">8</span></a> tends to show marked increase in the
-number of cases of poisoning from greater demand for benzine
-as a motive power for vehicles. Such cases have been
-observed in automobile factories, and are attributable to the
-hydrocarbons of low boiling-point which are present as
-impurities in benzine.</p>
-
-<p>A worker in a paraffin factory had entered an open benzine
-still to scrape the walls free of crusts containing benzine. He
-was found unconscious and died some hours later. It appeared
-that he had been in the still several hours, having probably been
-overcome to such an extent by the fumes as to be unable
-to effect his escape.</p>
-
-<p>Attempt to wipe up benzine spilt in the storage cellar of a
-large chemical cleaning works resulted in poisoning.</p>
-
-<p><span class="pagenum"><a name="Page_64" id="Page_64">[64]</a></span></p>
-
-<p>A night worker in a bone extracting works having turned
-on the steam, instead of watching the process fell asleep on a
-bench. In consequence the apparatus became so hot that the
-solder of a stop valve melted, allowing fumes to escape. The
-man was found dead in the morning. In a carpet cleaning
-establishment three workers lost consciousness and were found
-senseless on the floor. They recovered on inhalation of oxygen.</p>
-
-<p>One further case reported from the instances of benzine
-poisoning collected recently<a href="#endnote57" id="endnote-ref57"><span class="endnote-marker">9</span></a> is worth quoting. A worker in a
-chemical factory was put to clean a still capable of distilling
-2500 litres of benzine. It contained remains of a previous
-filling. As soon as he had entered the narrow opening he
-became affected and fell into the benzine; he was carried
-unconscious to the hospital, his symptoms being vomiting,
-spastic contraction of the extremities, cyanosis, weak pulse,
-and loss of reflexes, which disappeared an hour and a half later.</p>
-
-<p>The occurrence of skin affections in the naphtha industry
-has been noted by several observers, especially among those
-employed on the unpurified mineral oils. Eruptions on the
-skin from pressing out the paraffin and papillomata (warty
-growths) in workers cleaning out the stills are referred to by
-many writers,<a href="#endnote58" id="endnote-ref58"><span class="endnote-marker">10</span></a> Ogston in particular.</p>
-
-<p>Recent literature refers to the occurrence of petroleum
-eczema in a firebrick and cement factory. The workers
-affected had to remove the bricks from moulds on to which
-petroleum oil dropped. An eczematous condition was produced
-on the inner surface of the hands, necessitating abstention
-from work. The pustular eczema in those employed only
-a short time in pressing paraffin in the refineries of naphtha
-factories is referred to as a frequent occurrence. Practically
-all the workers in three refineries in the district of
-Czernowitz were affected. The view that it is due to
-insufficient care in washing is supported by the report of the
-factory inspector in Rouen, that with greater attention in this
-matter on the part of the workers marked diminution in its
-occurrence followed.</p>
-
-<h4>SULPHUR</h4>
-
-<p><span class="smcap">Recovery and Use.</span>—Sulphur, which is found principally
-in Sicily (also in Spain, America, and Japan), is obtained by<span class="pagenum"><a name="Page_65" id="Page_65">[65]</a></span>
-melting. In Sicily this is carried out in primitive fashion by
-piling the rock in heaps, covering them with turf, and setting
-fire to them. About a third of the sulphur burns and escapes
-as sulphur dioxide, while the remainder is melted and collects
-in a hole in the ground.</p>
-
-<p>The crude sulphur thus wastefully produced is purified by
-distillation in cast-iron retorts directly fired. It comes on the
-market as stick or roll sulphur or as flowers of sulphur.</p>
-
-<p>Further sources for recovery of sulphur are the Leblanc
-soda residues (see Soda Production), from which the sulphur
-is recovered by the Chance-Claus process, and the gas purifying
-material (containing up to 40 per cent.), from which the sulphur
-can be recovered by carbon bisulphide (see Illuminating Gas
-Industry).</p>
-
-<p>The health conditions of the Sicilian sulphur workers are
-very unsatisfactory, due, however, less to the injurious effect
-of the escaping gases (noxious alike to the surrounding vegetation)
-than to the wretched social conditions, over exertion, and
-under feeding of these workers.</p>
-
-<p>Of importance is the risk to health from sulphuretted
-hydrogen gas, from sulphur dioxide in the recovery of sulphur
-from the soda residues, and from carbon bisulphide in the
-extraction of sulphur from the gas purifying material.</p>
-
-<h4>SULPHURETTED HYDROGEN GAS</h4>
-
-<p>Sulphuretted hydrogen gas is used in the chemical industry
-especially for the precipitation of copper in the nickel and
-cobalt industry, in de-arsenicating acid (see Hydrochloric and
-Sulphuric Acids), to reduce chrome salts in the leather industry,
-&amp;c. In addition it arises as a product of decomposition in
-various industries, such as the Leblanc soda process, in the
-preparation of chloride of antimony, in the decomposition of
-barium sulphide (by exposure to moist air), in the treatment
-of gas liquors, and in the preparation of carbon
-bisulphide: it is present in blast furnace gas, is generated in
-mines (especially in deep seams containing pyrites), arises
-in tar distillation, from use of gas lime in tanning, and in
-the preparation and use of sodium sulphide: large quantities
-of the gas are generated in the putrefactive processes<span class="pagenum"><a name="Page_66" id="Page_66">[66]</a></span>
-connected with organic sulphur-containing matter such as glue
-making, bone stores, storage of green hides, in the decomposition
-of waste water in sugar manufacture and brewing,
-in the retting of flax, and especially in sewers and middens.</p>
-
-<p>Both <i>acute</i> and <i>chronic</i> poisoning are described.</p>
-
-<p>The following case is reported by the Union of Chemical
-Industry in 1907: Three plumbers who were employed on the
-night shift in a chemical factory and had gone to sleep in a
-workroom were found in a dying condition two hours later.
-In the factory barium sulphide solution in a series of large
-saturating vessels was being converted into barium carbonate
-by forcing in carbonic acid gas; the sulphuretted hydrogen
-gas evolved was collected in a gasometer, burnt, and utilised
-for manufacture of sulphuric acid. In the saturating vessels
-were test cocks, the smell from which enabled the workers to
-know whether all the sulphuretted hydrogen gas had been
-driven out. If this was so the contents of the retort were
-driven by means of carbonic acid gas into a subsidiary vessel,
-and the vessel again filled with barium sulphide liquor. From
-these intermediate vessels the baryta was pumped into filter
-presses, the last remains of sulphuretted hydrogen gas being
-carried away by a fan into a ventilating shaft. The subsidiary
-vessel and ventilating shaft were situated in front of the
-windows of the repairing shop. On the night in question a
-worker had thoughtlessly driven the contents out of one
-saturating vessel before the sulphuretted hydrogen gas had
-been completely removed, and the driving belt of the fan
-was broken. Consequently, the sulphuretted hydrogen gas
-escaping from the subsidiary vessel entered through the
-windows of the workshop and collected over the floor where
-the victims of the unusual combination of circumstances slept.</p>
-
-<p>In another chemical works two workers suffered from
-severe poisoning in the barium chloride department. The
-plant consisted of a closed vat which, in addition to the
-openings for admitting the barium sulphide liquor and sulphuric
-acid, had a duct with steam injector connected with
-the chimney for taking away the sulphuretted hydrogen gas.
-Owing to a breakdown the plant was at a standstill, as a
-result of which the ventilating duct became blocked by ice.
-When the plant was set in motion again the sulphuretted<span class="pagenum"><a name="Page_67" id="Page_67">[67]</a></span>
-hydrogen gas escaped through the sulphuric acid opening.
-One of the workers affected remained for two days unconscious.<a href="#endnote59" id="endnote-ref59"><span class="endnote-marker">1</span></a> </p>
-
-<p>The report of the Union of Chemical Industry for 1905
-cites a case where an agitating vessel, in which, by action
-of acid on caustic liquor, sulphuretted hydrogen gas was given
-off and drawn away by a fan, had to be stopped to repair one of
-the paddles. The flow of acid and liquor was stopped, and the
-cover half removed. The deposit which had been precipitated
-had to be got rid of next in order to liberate the agitator. The
-upper portion of the vessel was washed out with water, and
-since no further evolution of sulphuretted hydrogen was
-possible from any manufacturing process, the work of removing
-the deposit was proceeded with. After several bucketfuls had
-been emptied the man inside became unconscious and died.
-The casualty was no doubt due to small nests of free caustic
-and acid which the spading brought into contact and subsequent
-developement of sulphuretted hydrogen afresh. A case
-is reported of sulphuretted hydrogen poisoning in a man
-attending to the drains in a factory tanning leather by a quick
-process. Here, when sulphurous acid acts on sodium sulphide,
-sulphuretted hydrogen is given off. In cleaning out a trap
-close to the discharge outlet of a tannery two persons were
-rendered unconscious, and the presence of sulphuretted hydrogen
-was shown by the blackening of the white lead paint
-on a house opposite and by the odour.<a href="#endnote60" id="endnote-ref60"><span class="endnote-marker">2</span></a> </p>
-
-<p>In the preparation of ammonium salts Eulenberg<a href="#endnote61" id="endnote-ref61"><span class="endnote-marker">3</span></a> cites
-several cases where the workers fell as though struck down,
-although the processes were carried on in the open air. They
-quickly recovered when removed from the spot.</p>
-
-<p>Oliver cites the case where, in excavating soil for a dock,
-four men succumbed in six weeks; the water contained 12 vols.
-per cent. of sulphuretted hydrogen.</p>
-
-<p>Not unfrequently acute poisoning symptoms result to
-sewer men. Probably sulphuretted hydrogen gas is not wholly
-responsible for them, nor for the chronic symptoms complained
-of by such workers (inflammation of the conjunctiva, bronchial
-catarrh, pallor, depression).</p>
-
-<p>In the distillation processes connected with the paraffin
-industry fatalities have been reported.</p>
-
-<p><span class="pagenum"><a name="Page_68" id="Page_68">[68]</a></span></p>
-
-<h4>CARBON BISULPHIDE</h4>
-
-<p><span class="smcap">Manufacture.</span>—Carbon bisulphide is prepared by passing
-sulphur vapour over pure coal brought to a red heat in cast-iron
-retorts into which pieces of sulphur are introduced. The
-crude carbon bisulphide requires purification from sulphur,
-sulphuretted hydrogen, and volatile organic sulphur compounds
-by washing with lime water and subsequent distillation.</p>
-
-<p>Use is made of it principally in the extraction of fat and
-oil from bones and oleaginous seeds (cocoanut, olives, &amp;c.),
-for vulcanising, and as a solvent of rubber. It is used also
-to extract sulphur from gas purifying material and for the
-preparation of various chemical substances (ammonium
-sulphocyanide, &amp;c.), as well as for the destruction of pests
-(phylloxera and rats).</p>
-
-<p>Fat and oil are extracted from seeds, bones, &amp;c., by carbon
-bisulphide, benzine, or ether, and, to avoid evaporation, the
-vessels are as airtight as possible and arranged, as a rule, for
-continuous working.</p>
-
-<p><i>Vulcanisation</i> is the rendering of rubber permanently
-elastic by its combination with sulphur. It is effected by
-means of chloride of sulphur, sulphide of barium, calcium,
-or antimony, and other sulphur-containing compounds, heat
-and pressure, or by a cold method consisting in the dipping
-of the formed objects in a mixture of carbon bisulphide
-and chloride of sulphur. The process of manufacture is
-briefly as follows: The raw material is first softened and
-washed by hot water and kneading in rolls. The washed
-and dried rubber is then mixed on callender rolls with various
-ingredients, such as zinc white, chalk, white lead, litharge,
-cinnabar, graphite, rubber substitutes (prepared by boiling
-vegetable oils, to which sulphur has been added, with chloride
-of sulphur). In vulcanising by aid of heat the necessary
-sulphur or sulphur compound is added. Vulcanisation with
-sulphur alone is only possible with aid of steam and mechanical
-pressure in various kinds of apparatus according to the
-nature of the article produced. In the cold vulcanisation
-process the previously shaped articles are dipped for a few
-seconds or minutes in the mixture of carbon bisulphide and
-chloride of sulphur and subsequently dried in warm air as
-quickly as possible.</p>
-
-<p><span class="pagenum"><a name="Page_69" id="Page_69">[69]</a></span></p>
-
-<p>In view of the poisonous nature of carbon bisulphide,
-benzine is much used now. In the cold method use of chloride
-of sulphur in benzine can replace it altogether.</p>
-
-<p>Instead of benzine other solvents are available—chlorine
-substitution products of methane (dichlormethane, carbon
-tetrachloride). In other processes <i>rubber solvents</i> are largely
-used, for instance, acetone, oil of turpentine, petroleum
-benzine, ether, and benzene. Rubber solutions are used for
-waterproofing cloth and other materials.</p>
-
-<p>Similar to the preparation and use of rubber is that of
-guttapercha. But vulcanisation is easier by the lead and
-zinc thiosulphate process than by the methods used in the
-case of rubber.</p>
-
-<p><span class="smcap">Effects on Health of CS₂ and Other Dangers to
-Health in the Rubber Industry.</span>—In the manufacture of
-carbon bisulphide little or no danger is run either to health
-or from fire.</p>
-
-<p>In the rubber trade the poisonous nature of <i>benzine</i> and
-<i>chloride of sulphur</i> have to be borne in mind, and also the
-considerable risk of <i>lead poisoning</i> in mixing. Cases of plumbism,
-especially in earlier years, are referred to.<a href="#endnote62" id="endnote-ref62"><span class="endnote-marker">1</span></a> </p>
-
-<p><i>Benzine</i> poisoning plays only a secondary part in the rubber
-industry. No severe cases are recorded, only slight cases
-following an inhalation of fumes.</p>
-
-<p>Cases of poisoning are recorded in a motor tyre factory
-in Upsala.<a href="#endnote63" id="endnote-ref63"><span class="endnote-marker">2</span></a> Nine women were affected, of whom four died.
-Whether these cases were due to benzene or petroleum
-benzine is not stated. It is remarkable that two such very
-different substances as benzene and benzine should be so easily
-confused.</p>
-
-<p>But that in the rubber industry cases of benzene poisoning
-do actually occur is proved by the following recent cases:
-Rubber dissolved in benzol was being laid on a spreading
-machine in the usual way. Of three men employed one was
-rendered unconscious and died.<a href="#endnote64" id="endnote-ref64"><span class="endnote-marker">3</span></a> </p>
-
-<p>In a rubber recovery process a worker was rendered unconscious
-after entering a benzol still, also two others who sought
-to rescue him. Only one was saved.</p>
-
-<p>Cases of aniline poisoning are reported where aniline is
-used for extracting rubber.<a href="#endnote65" id="endnote-ref65"><span class="endnote-marker">4</span></a> </p>
-
-<p><i>Chloride of sulphur</i>, by reason of its properties and the<span class="pagenum"><a name="Page_70" id="Page_70">[70]</a></span>
-readiness with which it decomposes (see Chloride of Sulphur),
-causes annoyance to rubber workers, but rarely poisoning.</p>
-
-<p>Much importance attaches to <i>chronic carbon bisulphide
-poisoning</i> in the rubber industry. Many scientists have
-experimented as to its poisonous nature (see especially on this
-Part II, p. <a href="#Page_194">194</a>).</p>
-
-<p>Lehmann’s<a href="#endnote66" id="endnote-ref66"><span class="endnote-marker">5</span></a> experiments show that a proportion of 0·50-0·7
-mg. of CS₂ per litre of air causes hardly any symptoms;
-1·0-1·2 mg. slight effects which become more marked on
-continued exposure; 1·5 mg. produces severe symptoms.
-About 1·0 mg. per litre of air is the amount which may set up
-chronic effects. In vulcanising rooms this limit may easily be
-exceeded unless special preventive measures are adopted.</p>
-
-<p>Laudenheimer<a href="#endnote67" id="endnote-ref67"><span class="endnote-marker">6</span></a> has made several analyses of the proportion
-of CS₂ in workrooms. Thus 0·9-1·8 mg. per litre of air were
-found in a room where pouches were vulcanised; 0·5-2·4 mg.
-were aspirated one-half metre distant from the dipping vessels;
-and 0·18-0·27 mg. in the room for making ‘baby comforters.’</p>
-
-<p>In analyses made some years ago proportions of 2·9-5·6 mg.
-were obtained.</p>
-
-<p>Although literature contains many references to CS₂
-poisoning, too much importance ought not to be attached to
-them now in view of the arrangements in modern well-equipped
-vulcanising premises. Laudenheimer has collected particulars
-of 31 cases of brain, and 19 of nervous, diseases among 219
-persons coming into contact with CS₂ between 1874 and
-1908, all of whom had been medically attended. In the last
-ten years, however, the psychical symptoms were seven times
-less than in the preceding period. Between 1896 and 1898 the
-average proportion of brain disease in the vulcanising department
-was 1·95 per cent., and of nervous diseases 0·22 per
-cent., as compared with 0·92 per cent. and 0·03 per cent. in
-the textile. Moreover, he maintains that practically all
-workers who come at all into contact with CS₂ must be to
-some extent affected injuriously by it.</p>
-
-<p>Studies on the injurious nature of CS₂ date from the years
-1851-60, when the French writers Pazen, Duchenne, Beaugrand,
-Piorry, &amp;c., came across cases from the Parkes’ process
-(cold vulcanisation by means of CS₂ and SCl₂). Delpech<a href="#endnote68" id="endnote-ref68"><span class="endnote-marker">7</span></a>
-published in 1860 and 1863 details of twenty-four severe cases<span class="pagenum"><a name="Page_71" id="Page_71">[71]</a></span>
-in rubber workers, some of which were fatal, and at the same
-time described the pitiable conditions under which the work
-was carried on.</p>
-
-<p>In Germany Hermann, Hirt and Lewin, and Eulenberg
-dealt with the subject, but their work is more theoretical in
-character; and in Laudenheimer’s work referred to the
-histories of several cases are given in detail.</p>
-
-<p>Mention should be made of the injury caused to the skin
-by the fluids used in extraction of fat and in vulcanising—especially
-by benzine and carbon bisulphide. Perrin considers
-the effect due partly to the withdrawal of heat and
-partly to the solvent action on the natural grease, producing
-an unpleasant feeling of dryness and contraction of the skin.</p>
-
-<h4>ILLUMINATING GAS</h4>
-
-<p>Illuminating gas is obtained by the dry distillation of coal.
-The products of distillation are subjected on the gasworks to
-several purifying processes, such as condensation in coolers,
-moist and dry purifying, from which valuable bye-products
-(such as tar, ammonia, cyanogen compounds) are obtained.
-The purified gas is stored in gas holders containing on an
-average 49 per cent. hydrogen, 34 per cent. methane, 8 per cent.
-carbonic oxide, 1 per cent. carbon dioxide, 4 per cent. nitrogen,
-and about 4 per cent. of the heavy hydrocarbons (ethylene,
-benzene vapour, acetylene, and their homologues) to which the
-illuminating properties are almost exclusively due.</p>
-
-<p>The most important stages in its preparation will be shortly
-described. <i>Distillation</i> is effected in cylindrical, usually horizontal,
-fireclay retorts placed in a group or setting (<a href="#fig11">fig. 11</a>),
-which formerly were heated by coke but in modern works
-always by gas. Charging with coal and removal of the coke
-takes place about every four hours, often by means of
-mechanical contrivances.</p>
-
-<p>Iron pipes conduct the products of distillation to the
-<i>hydraulic main</i>. This is a long covered channel extending the
-entire length of the stack and receiving the gas and distillate
-from each retort. In it the greater part of the tar and of
-the ammoniacal water condense and collect under the water
-which is kept in the main to act as a seal to the ends of the dip<span class="pagenum"><a name="Page_72" id="Page_72">[72]</a></span>
-pipes, to prevent the gas from passing back into the retort
-when the latter is opened. While the liquid flows from the
-hydraulic main into cisterns, the gas passes into <i>coolers</i> or
-<i>condensers</i>, tall iron cylinders, in which, as the result of air
-and water cooling, further portions of the tar and ammoniacal
-liquor are condensed. To free it still more from particles
-of tar the gas passes through the <i>tar separator</i>.</p>
-
-<div class="figcenter" style="width: 500px;" id="fig11">
-
-<img src="images/fig11.jpg" width="500" height="475" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 11.</span>—Manufacture of Illuminating Gas. Horizontal fireclay retorts placed in
-a setting and heated by gas(<i>after Ost</i>)</p>
-
-</div>
-
-<p>The tar which remains behind flows through a tube to the
-cistern. From the tar separator the gas goes through <i>scrubbers</i>
-(<a href="#fig12">fig. 12</a>), where the gas is washed free of ammonia and part of
-the sulphuretted hydrogen and carbon dioxide with water.
-The scrubbers are tower-like vessels filled with coke or charcoal
-through which the gas passes from below upwards, encountering
-a spray of water. Several scrubbers in series are used, so that
-the water constantly becomes richer in ammonia. Mechanical
-scrubbers are much used, so-called standard washers; they are
-rotating, horizontal cylinders having several chambers filled
-with staves of wood half dipping in water. In them the same
-principle of making the gas meet an opposing stream of water<span class="pagenum"><a name="Page_73" id="Page_73">[73]</a></span>
-is employed, so that the last traces of ammonia are removed
-from the gas.</p>
-
-<p>The various purifying apparatus through which the gas has
-to pass cause considerable resistance to its flow. Escape in
-various ways would occur had the gas to overcome it by its own
-pressure, and too long contact of the gas with the hot walls
-of the retorts would be detrimental. Hence an exhauster is
-applied to the system which keeps the pressure to the right
-proportion in the retorts and drives on the gas.</p>
-
-<div class="figcenter" style="width: 500px;" id="fig12">
-
-<img src="images/fig12.jpg" width="500" height="275" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 12.</span>—Washer or Scrubber</p>
-
-</div>
-
-<p>After purification in the scrubbers <i>dry purification</i> follows,
-having for its object especially removal of compounds of sulphur
-and cyanogen and carbon dioxide. To effect this several
-shallow receptacles are used, each having a false bottom
-upon which the purifying material is spread out. The boxes
-are so arranged that the gas first passes through purifying
-material which is almost saturated and finally through fresh
-material, so that the material becomes richer in sulphur and
-cyanogen compounds. The <i>gas purifying material</i> formerly
-used was slaked lime, and it is still frequently used, but more
-generally bog iron ore or artificially prepared mixtures are used
-consisting mostly of oxide of iron. The saturated purifying
-material is regenerated by oxidation on spreading it out in the
-air and turning it frequently. After having been thus treated<span class="pagenum"><a name="Page_74" id="Page_74">[74]</a></span>
-some ten times the mass contains 50 per cent. sulphur, and
-13 to 14 per cent. ferrocyanide.</p>
-
-<div class="figcenter" style="width: 700px;" id="fig13">
-
-<img src="images/fig13.jpg" width="700" height="200" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 13.</span>—Manufacture of Illuminating Gas. Diagrammatic view (<i>after Lueger</i>)
-A Retort setting and hydraulic main; B Condensers and coolers; C Exhauster; D Well; E Water
-tank; F Tar extractor; G Scrubber; H Purifier; I Station meter; K Gas holder; L Pressure regulator.</p>
-
-</div>
-
-<p>The <i>naphthalene</i> in illuminating gas does not separate in
-the condenser, and therefore is generally treated in special
-apparatus by washing the gas
-with heavy coal tar.</p>
-
-<p>The gas purified, as has
-been described, is measured by
-a meter and stored in gasometers.
-These are bells made
-up of sheet iron which hang
-down into walled receptacles
-filled with water to act as a
-water seal, and are raised by
-the pressure of the gas which
-streams into them. The gas
-passes to the network of
-mains by pressure of the
-weight of the gasometer, after
-having passed through a pressure
-regulating apparatus.</p>
-
-<p>As to recovery of bye-products
-in the illuminating gas
-industry, see the sections on
-Ammonia, Cyanogen Compounds,
-Tar, Benzene, &amp;c.</p>
-
-<p><span class="smcap">Effect on Health.</span>—Opinions
-differ as to the effect
-on health which employment
-in gas works exerts. This is
-true of old as well as of modern
-literature.</p>
-
-<p>Hirt<a href="#endnote69" id="endnote-ref69"><span class="endnote-marker">1</span></a> maintains that gas
-workers suffer no increase in
-illness because of their employment.
-They reach, he says, a
-relatively high age and their mortality he puts down at from
-0·5 to 1 per cent. (my own observations make me conclude that
-the average mortality among persons insured in sick societies
-in Bohemia is 1 per cent., so that Hirt’s figure is not high).</p>
-
-<p><span class="pagenum"><a name="Page_75" id="Page_75">[75]</a></span></p>
-
-<p>Layet<a href="#endnote70" id="endnote-ref70"><span class="endnote-marker">2</span></a> agreed with Hirt, but was of opinion that gas
-workers suffered from anæmia and gastro-intestinal symptoms
-attributable to inhalation of injurious gases. The sudden
-symptoms of intoxication, ‘exhaustion and sinking suddenly
-into a comatose condition,’ which he attributes to the effect of
-hydrocarbons and sulphuretted hydrogen gas, may well have
-been the symptoms of carbonic oxide poisoning.</p>
-
-<p>Goldschmidt<a href="#endnote71" id="endnote-ref71"><span class="endnote-marker">3</span></a> in recent literature considers manufacture
-of illuminating gas by no means dangerous or unhealthy, and
-speaks of no specific maladies as having been observed by him.
-Nevertheless, he admits with Layet that the men employed
-in the condensing and purifying processes are constantly in an
-atmosphere contaminated by gas, and that the cleaning and
-regeneration of the purifying mass is associated with inflammation
-of the eyes, violent catarrh, and inflammation of the
-respiratory passages, since, on contact of the purifying mass
-with the air, hydrocyanic acid gas, sulphocyanic acid gas,
-and fumes containing carbolic, butyric, and valerianic acids
-are generated.</p>
-
-<p>Other writers<a href="#endnote72" id="endnote-ref72"><span class="endnote-marker">4</span></a> refer to the injurious effects from manipulating
-the purifying material. In general, though, they
-accept the view, without however producing any figures,
-that work in gas works is unattended with serious injury
-to health and that poisonings, especially from carbonic oxide,
-are rare. Such cases are described,<a href="#endnote73" id="endnote-ref73"><span class="endnote-marker">5</span></a> but the authors are not
-quite at one as to the healthiness or otherwise of the industry.
-The one opinion is based on study of the sick club reports for
-several years of a large gas works employing some 2400 workers
-(probably Vienna).<a href="#endnote74" id="endnote-ref74"><span class="endnote-marker">6</span></a> The average frequency of sickness
-(sickness percentage), excluding accidents, was 48·7 per cent.
-The conclusion is drawn that the health conditions of gas
-workers is favourable. It is pointed out, however, that
-diseases of the respiratory and digestive organs (12·8 and 10·16
-per cent. of the persons employed) are relatively high, and
-that the mortality (1·56 per cent.) of gas-workers is higher
-than that of other workers. This is attributed to the constant
-inhalation of air charged with injurious gases. Work at the
-retorts, coke quenching, and attending to the purifying plant
-are considered especially unhealthy.</p>
-
-<p>The other figures relate to the Magdeburg gas works;<span class="pagenum"><a name="Page_76" id="Page_76">[76]</a></span>
-they are higher than those quoted. The morbidity of the gas
-workers was found to be 68·5 per cent., of which 18 per cent.
-was due to disease of the digestive system, 20·5 per cent. to
-disease of the respiratory organs, and 1 per cent. to poisoning.
-No details of the cases of poisoning are given. Carbonic oxide
-poisoning is said to be not infrequent, the injurious effect
-of cleaning the purifiers is referred to, and poisoning by inhalation
-of ammonia is reported as possible.</p>
-
-<p>Still, no very unfavourable opinion is drawn as to the
-nature of the work. The sickness frequency in sick clubs is
-about 50 per cent., and even in well-managed chemical works
-Leymann has shown it to be from 65 to 80 per cent. The
-recently published elaborate statistics of sickness and mortality
-of the Leipzig local sickness clubs<a href="#endnote75" id="endnote-ref75"><span class="endnote-marker">7</span></a> contain the following
-figures for gas workers: Among 3028 gas workers there were
-on an average yearly 2046 cases of sickness, twenty deaths,
-and four cases of poisoning. The total morbidity, therefore,
-was 67·57 per cent., mortality 0·66 per cent., and the morbidity
-from poisoning 0·13 per cent. Diseases of the respiratory
-tract equalled 10·63 per cent., of the digestive tract 10·87
-per cent., of the muscular system 13·10 per cent., and from
-rheumatism 11·10 per cent. These figures, therefore, are not
-abnormally high and the poisoning is very low.</p>
-
-<p>Still, industrial cases of poisoning in gas works are recorded.
-Of these the most important will be mentioned. Six persons
-were employed in a sub-station in introducing a new sliding
-shutter into a gas main, with the object of deviating the gas for
-the filling of balloons. A regulating valve broke, and the gas
-escaped from a pipe 40 cm. in diameter. Five of the men
-were rendered unconscious, and resuscitation by means of
-oxygen inhalation failed in one case. In repairing the damage
-done two other cases occurred.<a href="#endnote76" id="endnote-ref76"><span class="endnote-marker">8</span></a> In emptying a purifier a
-worker was killed from failure to shut off the valve.</p>
-
-<p>Besides poisoning from illuminating gas, industrial poisoning
-in gas works is described attributable, in part at least, to
-ammonia. Thus the report of the factory inspectors of
-Prussia for 1904 narrates how a worker became unconscious
-while superintending the ammonia water well, fell in, and was
-drowned.</p>
-
-<p>A further case is described in the report of the Union<span class="pagenum"><a name="Page_77" id="Page_77">[77]</a></span>
-of Chemical Industry for 1904. In the department for concentrating
-the gas liquor the foreman and an assistant on the
-night shift were getting rid of the residues from a washer
-by means of hot water. The cover had been removed, but,
-contrary to instructions, the steam had not been shut off.
-Ammonia fumes rushed out and rendered both unconscious,
-in which condition there were found by the workmen coming
-in the morning.<a href="#endnote77" id="endnote-ref77"><span class="endnote-marker">9</span></a> </p>
-
-<p>In the preparation of ammonium sulphate, probably in
-consequence of too much steam pressure, gas liquor was
-driven into the sulphuric acid receiver instead of ammonia gas.
-The receiver overflowed, and ammonia gas escaped in such
-quantity as to render unconscious the foreman and two men
-who went to his assistance.<a href="#endnote78" id="endnote-ref78"><span class="endnote-marker">10</span></a> </p>
-
-<p>The use of illuminating gas in industrial premises can give
-rise to poisoning. Thus the women employed in a scent
-factory, where so-called quick gas heaters were used, suffered
-from general gas poisoning.<a href="#endnote79" id="endnote-ref79"><span class="endnote-marker">11</span></a> </p>
-
-<p>In Great Britain in 1907 sixteen cases of carbonic
-oxide poisoning from use of gas in industrial premises were
-reported.</p>
-
-<h4>COKE OVENS</h4>
-
-<p>Coke is obtained partly as a residue in the retorts after
-the production of illuminating gas. Such <i>gas coke</i> is unsuitable
-for metallurgical purposes, as in the blast furnace. Far
-larger quantities of coal are subjected to dry distillation for
-metallurgical purposes in coke ovens than in gas works. Hence
-their erection close to blast furnaces. In the older form of
-coke oven the bye-products were lost. Those generally used
-now consist of closed chambers heated from the outside, and
-they can be divided into coke ovens which do, and those which
-do not, recover the bye-products. These are the same as
-those which have been considered under manufacture of
-illuminating-gas—tar, ammonia, benzene and its homologues,
-cyanogen, &amp;c. In the coke ovens in which the bye-products
-are not recovered the gases and tarry vapours escaping
-on coking pass into the heating flues, where, brought
-into contact with the air blast, they burn and help to<span class="pagenum"><a name="Page_78" id="Page_78">[78]</a></span>
-heat the oven, while what is unused goes to the main chimney
-stack.</p>
-
-<div class="figcenter" style="width: 400px;" id="fig14">
-
-<img src="images/fig14.jpg" width="400" height="450" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 14.</span>—Distillation Coke Oven (<i>after Lueger</i>)</p>
-
-<p class="caption">A, A´ Coal to be coked; B, B´ Standpipes; C Hydraulic main; D Condensing
-apparatus; E Purified gas: F, F´ Air inlets; G G,´ G´´ Combustion
-chambers.</p>
-
-</div>
-
-<p>In the modern <i>distillation ovens</i> with recovery of the bye-products
-the gases escaping from the coal are led (air being
-cut off as completely as possible) through ascending pipes into
-the main collector, where they are cooled, and the tarry ingredients
-as well as a part of the ammonia are absorbed by
-water; subsequently the gases pass through washing apparatus
-with a view to as complete a recovery of the ammonia and
-benzene as possible. The purified gases are now again led
-to the ovens and burnt with access of air in the combustion
-chambers between two ovens. Generally these ovens are so
-constructed as to act as non-recovery ovens also (especially in
-starting the process).</p>
-
-<p>The coal is charged into the ovens through charge holes on<span class="pagenum"><a name="Page_79" id="Page_79">[79]</a></span>
-the top and brought to a level in the chambers either by hand
-or mechanically. Removal of the coke block after completion
-of the coking operation is done by a shield attached to a rack and
-pinion jack. Afterwards the coke is quenched with water.</p>
-
-<p>Recovery of the <i>bye-products</i> of coke distillation ovens is
-similar to the method described for illuminating gas, i.e.
-first by condensation with aid of air or water cooling, then
-direct washing with water (generally in scrubbers), whereby
-tar and ammonia water are recovered. <i>Recovery of benzene</i>
-and its homologues (see Benzene later) depends on the fact
-that the coke oven gases freed from tar and ammonia are
-brought into the closest possible contact with the so-called
-wash oils, i.e. coal tar oils with high boiling-point (250-300° C.).
-For this purpose several washing towers are employed. The
-waste oil enriched with benzene is recovered in stills intermittently
-or continuously and used again.</p>
-
-<p><span class="smcap">Effects on Health.</span>—Injury to health from work at coke
-ovens is similar to that in the manufacture of illuminating
-gas. There is the possibility of carbonic oxide poisoning from
-escape of gas from leakage in the apparatus. As further
-possible sources of danger ammonia, cyanogen and sulpho-cyanogen
-compounds, and benzene have to be borne in mind.</p>
-
-<p>In the distillation of the wash oil severe poisoning can
-arise, as in a case described, where two men were fatally
-poisoned in distilling tar with wash oil.<a href="#endnote80" id="endnote-ref80"><span class="endnote-marker">1</span></a> </p>
-
-<p>The details of the case are not without interest. The
-poisoning occurred in the lavatory. The gases had escaped
-from the drain through the ventilating shaft next to the closet.
-The gases came from distillation of the mixture of tar and
-wash oil, and were driven by means of air pumps in such a
-way that normally the uncondensed gases made their way to the
-chimney stack. On the day of the accident the pumps were
-out of use, and the gases were driven by steam injectors into the
-drain. Analysis showed the gases to contain much sulphuretted
-hydrogen. When this was absorbed, a gas which could be
-condensed was obtained containing carbon bisulphide and
-hydrocarbons of unknown composition (? benzene). Only
-traces of cyanogen and sulpho-cyanogen compounds were
-present. Physiological experiment showed that poisoning
-was attributable mainly to sulphuretted hydrogen gas, but<span class="pagenum"><a name="Page_80" id="Page_80">[80]</a></span>
-that after this was removed by absorption a further poisonous
-gas remained.</p>
-
-<h4>Other Kinds of Power and Illuminating Gas</h4>
-
-<p><i>Producer gas</i> or <i>generator gas</i>.—Manufacture of producer gas
-consists in dealing separately with the generation of the gas
-and the combustion of the gases which
-arise. This is effected by admitting only
-so much air (primary air supply) to the
-fuel as is necessary to cause the gases to
-come off, and then admitting further air
-(secondary supply) at the point where
-the combustion is to take place; this
-secondary supply and the gas formed in
-the gas producer are heated in regenerators
-before combustion by bringing
-the gases to be burnt into contact with
-<i>Siemens’s heaters</i>, of which there are
-four. Two of these are always heated
-and serve to heat the producer gas and
-secondary air supply.</p>
-
-<div class="figcenter" style="width: 200px;" id="fig15">
-
-<img src="images/fig15.jpg" width="200" height="300" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 15.</span>—Horizontal
-Regenerative Grate (<i>after
-Lueger</i>)</p>
-
-</div>
-
-<p>A producer gas furnace, therefore, consists of a gas
-producer, a gas main leading to the
-furnace hearth, the heater, and the
-chimney.</p>
-
-<div class="figcenter" style="width: 300px;" id="fig16">
-
-<img src="images/fig16.jpg" width="300" height="275" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 16.</span>—Step Regenerative
-Grate (<i>after Lueger</i>)</p>
-
-</div>
-
-<p>The gas producer is a combustion
-chamber filled with coal in
-which the coal in the upper layer
-is burnt. Generators may have
-horizontal or sloping grate (see
-figs. <a href="#fig15">15</a> and <a href="#fig16">16</a>). The <i>Siemens’s</i>
-heaters or regenerators are chambers
-built of, and filled loosely with, fireclay
-bricks and arranged in couples.
-Should the gas producers become
-too hot, instead of the chambers subdivided air heaters are
-used, whereby the hot furnace gases are brought into contact
-with a system of thin-walled, gastight fireclay pipes, to
-which they give up their heat, while the secondary air supply
-for the furnace is led beside these pipes and so becomes<span class="pagenum"><a name="Page_81" id="Page_81">[81]</a></span>
-heated indirectly. Previous heating of the producer gas is
-here not necessary; no valves are needed because the three
-streams of gas all pass in the same direction.</p>
-
-<div class="figcenter" style="width: 400px;" id="fig17">
-
-<p class="caption"><span class="smcap">Fig. 17a.</span>—Siemens’s Regenerative Furnace</p>
-
-<p class="caption">L Air; G Gas</p>
-
-<img src="images/fig17.jpg" width="400" height="700" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 17b.</span>—Siemens’s Regenerative Furnace</p>
-
-</div>
-
-<p>Such air heating arrangements are used for heating the
-retorts in gas works, for melting the ‘metal’ in glass works, and
-very generally in other industries, as they offer many technical
-and hygienic advantages. Generator gas from coke contains
-34 per cent. carbonic oxide, 0·1 per cent. hydrogen, 1·9 per
-cent. carbon dioxide, and 64 per cent. nitrogen.</p>
-
-<p><span class="pagenum"><a name="Page_82" id="Page_82">[82]</a></span></p>
-
-<p><i>Blast furnace gas.</i>—Blast furnace gas is formed under the
-same conditions as have been described for generator gas;
-it contains more carbon dioxide (about 10 per cent.). (Further
-details are given in the section on Iron—Blast Furnaces.)</p>
-
-<p><i>Water gas.</i>—Water gas is made by the passage of steam
-through incandescent coal, according to the equation:</p>
-
-<ul>
-<li>C + H₂O = CO + 2H.</li>
-</ul>
-
-<p>The iron gas producer, lined with firebrick, is filled with
-anthracite or coke and heated by blowing hot air through it.
-This causes producer gas to escape, after which steam is blown
-through, causing water gas to escape—containing hydrogen and
-carbonic oxide to the extent of 45-50 per cent., carbon
-dioxide and nitrogen 2-6 per cent., and a little methane.</p>
-
-<p>The blowing of hot air and steam is done alternately, and
-both kinds of gas are led away and collected separately, the
-water gas being previously purified in scrubbers, condensers,
-and purifiers. It serves for the production of high temperatures
-(in smelting of metals). Further, when carburetted and
-also when carefully purified in an uncarburetted state, it
-serves as an illuminant. The producer gas generated at the
-same time is used for heating purposes (generally for heating
-boilers).</p>
-
-<p><i>Dowson gas.</i>—Dowson gas is obtained by collecting and
-storing together the gases produced in the manner described
-for water gas. Under the grating of the wrought-iron gas
-producer (lined with firebrick and similarly filled with coke or
-anthracite) a mixture of air and steam, produced in a special
-small boiler, is blown through by means of a Körting’s
-injector.</p>
-
-<p>Before storage the gas is subjected to a purifying process
-similar to that in the case of water gas. The mixed gas
-consists of 1 vol. water gas and 2-3 vols. producer gas, with
-about 10-15 vols. per cent. H, 22-27 vols. per cent. CO,
-3-6 per cent. CO₂, and 50-55 per cent. N. It is an admirable
-power gas for driving gas motors (<a href="#fig18">fig. 18</a>).</p>
-
-<p><i>Mond gas</i> similarly is a mixed gas obtained by blowing
-much superheated steam into coal at low temperature.
-Ammonia is produced at the same time.</p>
-
-<p><span class="pagenum"><a name="Page_83" id="Page_83">[83]</a></span></p>
-
-<div class="figcenter" style="width: 700px;" id="fig18">
-
-<img src="images/fig18.jpg" width="700" height="350" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 18.</span>—Power Gas Installation (<i>after Lueger</i>)</p>
-
-<ul>
-<li>A Steam boiler</li>
-<li>a Steam injector</li>
-<li>B Furnace</li>
-<li>b Charging hopper</li>
-<li>c Cover g</li>
-<li>d Valve C</li>
-<li>e Cock D</li>
-<li>f Vent pipe</li>
-<li>g Steam Pipe</li>
-<li>C Washer</li>
-<li>D Coke tower</li>
-<li>E Sawdust purifier</li>
-</ul>
-
-</div>
-
-<p><i>Suction gas.</i>—In contradistinction to the Dowson system,
-in which air mixed with steam is forced into the producer by a
-steam injector, in the suction gas plant the air and steam are
-drawn into the generator by the apparatus itself. The whole
-apparatus while in action is under slight negative pressure. A<span class="pagenum"><a name="Page_84" id="Page_84">[84]</a></span>
-special steam boiler is unnecessary because the necessary steam
-is got up in a water container surrounding or connected with
-the cover of the generator. The plant is set in motion by
-setting the fire in action by a fan.</p>
-
-<div class="figcenter" style="width: 500px;" id="fig19">
-
-<img src="images/fig19.jpg" width="500" height="500" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 19.</span>—Suction Gas Plant (<i>after Meyer</i>)</p>
-
-</div>
-
-<p><a href="#fig19">Fig. 19</a> shows a suction gas plant. B is the fan. Above
-the generator A and at the lower part of the feed hopper is an
-annular vessel for generating steam, over the surface of which
-air is drawn across from the pipe e, passing then through the
-pipe f into the ash box g, and then through the incandescent
-fuel. The gas produced is purified in the scrubber D, and
-passes then through a pipe to the purifier containing sawdust
-and to the motor.</p>
-
-<p><i>Carburetted gas.</i>—Gas intended for illuminating purposes is
-carburetted to increase its illuminating power, i.e. enriched
-with heavy hydrocarbons. Carburetting is effected either by a<span class="pagenum"><a name="Page_85" id="Page_85">[85]</a></span>
-hot method—adding the gases distilled from mineral or other
-oils—or by a cold method—allowing the gas to come into contact
-with cold benzol or benzine. Coal gas as well as water gas
-is subjected to the carburetting process, but it has not the same
-importance now in relation to illuminating power, as reliance
-is more and more being placed on the use of mantles.</p>
-
-<h5>ACETYLENE</h5>
-
-<p><i>Calcium carbide.</i>—Acetylene is prepared from calcium
-carbide, which on contact with water gives off acetylene.</p>
-
-<p><i>Calcium carbide</i> is prepared electro-chemically. A mixture
-of burnt lime and coke is ground and melted up together at
-very high temperature in an electric furnace, in doing which
-there is considerable disengagement of carbonic oxide according
-to the equation:</p>
-
-<ul>
-<li>CaO + 3C = CaC₂ + CO.</li>
-</ul>
-
-<p>The furnaces used in the production of calcium carbide are of
-different construction. Generally the furnace is of the nature
-of an electric arc, and is arranged either as a crucible furnace for
-intermittent work or like a blast furnace for continuous work.</p>
-
-<p>Besides these there are resistance furnaces in which the heat
-is created by the resistance offered to the passage of the current
-by the molten calcium carbide.</p>
-
-<p>The carbonic oxide given off in the process causes
-difficulty. In many furnaces it is burnt and so utilised for
-heating purposes. The calcium carbide produced contains
-as impurities silicon carbide, ferro-silicon, calcium sulphide,
-and calcium phosphide.</p>
-
-<p><i>Acetylene</i> (C₂H₂), formed by the decomposition of calcium
-carbide by means of water (CaC₂ + 2H₂O = Ca(OH)₂ + C₂H₂),
-furnishes when pure an illuminating gas of great brilliancy and
-whiteness. Its production is relatively easy. Used for the
-purpose are (1) apparatus in which water is made to drop on
-the carbide, (2) apparatus in which the carbide dips into water
-and is removed automatically on generation of the gas, (3)
-apparatus in which the carbide is completely immersed in
-water, and (4) apparatus in which the carbide in tiny lumps
-is thrown on to water. These are diagrammatically represented
-in <a href="#fig20">figs. 20<span class="smcap">a</span> to 20<span class="smcap">d</span></a> .</p>
-
-<p><span class="pagenum"><a name="Page_86" id="Page_86">[86]</a></span></p>
-
-<div class="figcenter" style="width: 500px;" id="fig20">
-
-<table>
-  <tr>
-    <td><span class="smcap">Fig. 20a.</span></td>
-    <td><span class="smcap">Fig. 20b.</span></td>
-  </tr>
-</table>
-
-<img src="images/fig20.jpg" width="500" height="650" alt="" />
-
-<table>
-  <tr>
-    <td><span class="smcap">Fig. 20c.</span></td>
-    <td><span class="smcap">Fig. 20d.</span></td>
-  </tr>
-</table>
-
-<p class="caption">Acetylene Apparatus—diagrammatic (<i>after Lueger</i>)
-A Dripping; B Dipping; C Submerging; D Throwing in</p>
-
-</div>
-
-<p>The most important impurities of acetylene are ammonia,
-sulphuretted hydrogen gas, and phosphoretted hydrogen.
-Before use, therefore, it is subjected to purification in various
-ways. In Wolf’s method the gas is passed through a washer
-(with the object of removing ammonia and sulphuretted
-hydrogen gas) and a purifying material consisting of chloride<span class="pagenum"><a name="Page_87" id="Page_87">[87]</a></span>
-of lime and bichromate salts. In Frank’s method the gas
-passes though a system of vessels containing an acid solution
-of copper chloride, and also through a washer. Chloride of
-lime with sawdust is used as a purifying agent. Finally, the
-gas is stored and thence sent to the consumer (<a href="#fig21">see fig. 21</a>).</p>
-
-<div class="figcenter" style="width: 500px;" id="fig21">
-
-<img src="images/fig21.jpg" width="500" height="450" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 21.</span>—Acetylene Gas Apparatus (<i>after Lueger</i>)</p>
-
-</div>
-
-<p><span class="smcap">Effects on Health.</span>—Almost all the poisoning caused in
-the industries in question is due to carbonic oxide gas, of which
-water gas contains 41 per cent., generator gas 35 per cent., and
-suction and Dowson gas 25 per cent.</p>
-
-<p>That industrial carbonic oxide poisoning is not rare the
-reports of the certifying surgeons in Great Britain sufficiently
-show. In the year 1906 fifty-five persons are referred to as
-having suffered, with fatal issue in four. In 1907 there were<span class="pagenum"><a name="Page_88" id="Page_88">[88]</a></span>
-eighty-one, of which ten were fatal. Of the 1906 cases twenty
-resulted from inhalation of producer, Mond, or suction gas,
-sixteen from coal gas (in several instances containing
-carburetted water gas), seventeen from blast furnace gas,
-and one each from charcoal fumes from a brazier, and from
-the cleaning out of an oil gas holder.</p>
-
-<p>As causes of the poisoning from suction gas were (1) improper
-situation of gas plant in cellar or basement, allowing gas to
-collect or pass upward; (2) defective fittings; (3) starting the
-suction gas plant by the fan with chimney valve closed; (4)
-cleaning out ‘scrubbers’ or repairing valves, &amp;c.; (5) defective
-gasometer. In the seventeen cases due to blast furnace gas
-six were due to conveyance of the gas by the wind from a
-flue left open for cleaning purposes into an engineering shed,
-two to charging the cupola furnace, two to entering the
-furnace, and four to cleaning the flues.</p>
-
-<p>The following are instances taken from recent literature
-on gas poisoning<a href="#endnote81" id="endnote-ref81"><span class="endnote-marker">1</span></a> : Several cases of poisoning by <i>water gas</i>
-occurred in a smelting works. The poisoning originated
-when a blowing machine driven by water gas was started.
-Owing to premature opening of the gas valve two men
-employed in a well underneath the machine were overcome.
-The attendant who had opened the valve succeeded in lifting
-both from the well; but as he was trying to lift a third man
-who had come to his assistance and fallen into the well he
-himself fell in and was overcome. The same fate befell the
-engineer and his assistant who came to the rescue. All efforts
-to recover the four men by others roped together failed, as all
-of them to the number of eight were rendered unconscious.
-With the aid of rescue appliances (helmets, &amp;c.) the bodies
-were recovered, but efforts at artificial respiration failed.</p>
-
-<p>A workman was killed by <i>suction gas</i> while in the water-closet.
-It appeared that some time previously when the plant
-was installed the ventilating pipe between the purifier and
-motor, instead of being led through the roof, had been led
-out sideways on a level with the floor immediately above the
-closet.</p>
-
-<p>In another case the suction gas attendant had taken out
-the three-way cock between the generator and motor for repairs
-and had not reinserted it properly, so that when effort was<span class="pagenum"><a name="Page_89" id="Page_89">[89]</a></span>
-made to start the motor this failed, as gas only and no air was
-drawn in. The motor was thought to be at fault, and the fan
-was worked so vigorously that the gas forced its way out
-through the packing of the flange connections and produced
-symptoms of poisoning in the persons employed.</p>
-
-<p>More dangerous than suction gas plants, in which normally
-no escape takes place, are installations depending on gas
-<i>under pressure</i>. Such an installation was used for heating gas
-irons in a Berlin laundry. The arrangements were considered
-excellent. The gas jets were in stoves from which the fumes
-were exhausted. The gas was made from charcoal and contained
-13 per cent. of hydrogen. No trace of carbonic oxide
-was found in the ironing room on examination of the air.
-After having been in use for months the mechanical ventilation
-got out of order, with the result that twelve women suffered
-severely from symptoms of carbonic oxide poisoning, from
-which they were brought round by oxygen inhalation. The
-laundry reverted to the use of illuminating gas. The conclusion
-to be drawn is that installations for gas heating are to be used
-with caution.<a href="#endnote82" id="endnote-ref82"><span class="endnote-marker">2</span></a> </p>
-
-<p>Industrial poisoning from <i>blast furnace gas</i> is frequent.
-Two fatal cases were reported<a href="#endnote83" id="endnote-ref83"><span class="endnote-marker">3</span></a> in men employed in the gas
-washing apparatus. They met their death at the manhole
-leading to the waste-water outlet. In another case a workman
-entered the gas main three hours after the gas had been
-cut off to clear it of the dust which had collected. He succumbed,
-showing that such accumulations can retain gas for a
-long time. Steps had been taken three hours previously to
-ventilate the portion of gas main in question.</p>
-
-<p>A fatal case occurred in the cleaning out of a blast furnace
-flue which had been ventilated for 1½ hours by opening all
-manholes, headplates, &amp;c. The foreman found the deceased
-with his face lying in the flue dust; both he and a helper were
-temporarily rendered unconscious.</p>
-
-<p>Cases of poisoning by <i>generator gas</i> are described.<a href="#endnote84" id="endnote-ref84"><span class="endnote-marker">4</span></a> A
-workman who had entered a gasometer containing the gas
-died in ten minutes, and another remained unconscious for
-ten days and for another ten days suffered from mental disturbance,
-showing itself in hebetude and weakness of memory.</p>
-
-<p><i>Acetylene</i> is poisonous to only a slight extent. Impurities<span class="pagenum"><a name="Page_90" id="Page_90">[90]</a></span>
-in it, such as carbon bisulphide, carbonic oxide (present to the
-extent of 1-2 per cent.), and especially phosphoretted hydrogen
-gas, must be borne in mind.</p>
-
-<p>American calcium carbide<a href="#endnote85" id="endnote-ref85"><span class="endnote-marker">5</span></a> yields acetylene containing
-0·04 per cent. of phosphoretted hydrogen; Lunge and Cederkreutz
-have found as much as 0·06 per cent. in acetylene.</p>
-
-<h4>AMMONIA AND AMMONIUM COMPOUNDS</h4>
-
-<p><span class="smcap">Preparation.</span>—Ammonia and ammonium salts are now
-exclusively obtained as a bye-product in the dry distillation of
-coal, from the ammonia water in gas works, and as a bye-product
-from coke ovens.</p>
-
-<p>The ammonia water of gas works contains from 2-3 per
-cent. of ammonia, some of which can be recovered on boiling,
-but some is in a non-volatile form, and to be recovered the
-compound must be decomposed. The volatile compounds
-are principally ammonium carbonate and, to a less extent,
-ammonium sulphide and cyanide; the non-volatile compounds
-are ammonium sulphocyanide, ammonium chloride, sulphate,
-thiosulphate, &amp;c. Other noteworthy substances in ammonia
-water are pyridine, pyrrol, phenols, hydrocarbons, and tarry
-compounds.</p>
-
-<p>Decomposition of the non-volatile compounds is effected
-by lime. Hence the ammonia water is distilled first alone,
-and then with lime. The distillate is passed into sulphuric
-acid, ammonium sulphate being formed. Distillation apparatus
-constructed on the principle usual in rectifying spirit
-is used, so that continuous action is secured; the ammonia
-water flows into the apparatus continuously and is freed of
-the volatile compounds by the steam. At a later stage milk
-of lime is added, which liberates the ammonia from the nonvolatile
-compounds.</p>
-
-<p>Of the ammonium salts there require mention:</p>
-
-<p><i>Ammonium sulphate</i> ((NH₄)₂SO₄), which serves for the production
-of other ammonium salts. It is usually centrifugalised
-out from the sulphuric acid tank previously described.</p>
-
-<p><i>Ammonium chloride</i> (sal-ammoniac, NH₄Cl) is formed by
-bringing the ammonia fumes given off in the process described<span class="pagenum"><a name="Page_91" id="Page_91">[91]</a></span>
-in contact with hydrochloric acid vapour. The crude salt
-so obtained is recrystallised or sublimed.</p>
-
-<p><i>Ammonium phosphate</i> ((NH₄)₂HPO₄) is made in an analogous
-manner by leading ammonia into phosphoric acid. It is
-useful as an artificial manure.</p>
-
-<p><i>Ammonium carbonate</i> is made either by bringing together
-ammonia vapour and carbonic acid or by subliming ammonium
-sulphate with calcium carbonate. It is very volatile. The
-thick vapour is collected and purified in leaden chambers.</p>
-
-<div class="figcenter" style="width: 500px;" id="fig22">
-
-<img src="images/fig22.jpg" width="500" height="425" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 22.</span>—Preparation of Ammonia. Column Apparatus of Feldman (<i>after Ost</i>)</p>
-
-<p class="caption">A, B, C Columns; D Saturator; (a) Settling tank and regulator for flow of
-ammonia; (b) Economiser; (f) Milk of lime; (g) Pump</p>
-
-</div>
-
-<p><i>Caustic ammonia</i> is prepared either from gas liquor or, more
-usually, from ammonium sulphate by distillation with caustic
-alkali in a continuous apparatus.</p>
-
-<p><span class="smcap">Use of Ammonia.</span>—Ammonia is used in laundries and<span class="pagenum"><a name="Page_92" id="Page_92">[92]</a></span>
-bleaching works in dyeing and wool washing. It is used
-especially in making ammonium salts, in the preparation of
-soda by the Solvay process (see Soda Manufacture), and in
-making ice artificially.</p>
-
-<p>It is used also in the preparation of indigo, in lacquers and
-colours, and the extraction of chloride of silver, &amp;c.</p>
-
-<p><span class="smcap">Effects on Health.</span>—Industrial ammonia poisoning is
-rare. It occurs most frequently in gas works and occasionally
-in its use, especially the manufacture of ammonium salts. Those
-engaged in subliming ammonium carbonate incur special
-risk, but often it is not the ammonia vapour so much as the
-escaping evil-smelling gases containing carbon bisulphide and
-cyanogen compounds which are the source of trouble.</p>
-
-<p>Occasionally in the production of ice through leakage or
-by the breaking of carboys of ammonia accidental poisoning
-has occurred.</p>
-
-<p>Some cases are cited from recent literature:</p>
-
-<p>A worker was rendered unconscious and drowned in an
-ammonia water well.<a href="#endnote86" id="endnote-ref86"><span class="endnote-marker">1</span></a> Two workers were poisoned (one
-fatally) in the concentration of gas liquor. Three workers were
-gassed (one fatally) in the preparation of ammonium sulphate
-in a gas works. Probably as the result of excessive steam
-pressure gas water was driven over with the ammonia into
-the sulphuric acid vessel.<a href="#endnote87" id="endnote-ref87"><span class="endnote-marker">2</span></a> </p>
-
-<p>Eulenberg<a href="#endnote88" id="endnote-ref88"><span class="endnote-marker">3</span></a> reports the occurrence of sulphuretted hydrogen
-gas poisoning in the production of ammonium salts. The
-workers succumbed as though shot, although work was being
-carried on in the open air. They recovered when removed
-from the poisonous atmosphere.</p>
-
-<p>In a large room of a chemical factory phosphoric acid was
-being saturated with ammonia gas water in an iron lead-lined
-vessel. Carbonic acid gas and hydrogen gas were
-evolved, but not to such extent as to be noticeable in the large
-room. A worker not employed in the room had to do something
-close to the vessel, and inhaled some of the fumes given
-off. A few yards from the vessel he was found lying unconscious,
-and although removed into the open air failed to respond
-to the efforts at artificial respiration.<a href="#endnote89" id="endnote-ref89"><span class="endnote-marker">4</span></a> </p>
-
-<p>Lewin, in an opinion delivered to the Imperial Insurance
-Office, describes poisoning in a man who during two days had<span class="pagenum"><a name="Page_93" id="Page_93">[93]</a></span>
-been employed repairing two ammonia retorts in a chemical
-factory. On the evening of the second day he suffered from
-severe symptoms of catarrh, from which he died five days
-later. Lewin considered the case to be one of acute ammonia
-poisoning.<a href="#endnote90" id="endnote-ref90"><span class="endnote-marker">5</span></a> </p>
-
-<p>Ammonia is frequently used in <i>fulling</i> cloth, the fumes
-of which collect on the surface after addition of sulphuric acid
-to the settling vats. This is especially liable to occur on a
-Monday, owing to the standing of the factory over the Sunday,
-so that entrance into the vats without suitable precautions
-is strictly forbidden. Despite this, a worker did go in to fetch
-out something that had fallen in, becoming immediately unconscious.
-A rescuer succumbed also and lost his life. The first
-worker recovered, but was for long incapacitated by paralytic
-symptoms.</p>
-
-<p>Cases of poisoning in <i>ice factories</i> and refrigerator rooms
-from defective apparatus are reported.</p>
-
-<p>Acute and chronic poisoning among sewer men are due
-mainly to sulphuretted hydrogen gas and only partly to
-ammonia. The more ammonia and the less sulphuretted
-hydrogen sewer gases contain the less poisonous are they.</p>
-
-<h4>CYANOGEN COMPOUNDS</h4>
-
-<p><span class="smcap">Treatment of the Materials used in Gas purifying.</span>—Cyanogen
-compounds are still sometimes prepared by the
-original method of heating to redness nitrogenous animal
-refuse (blood, leather, horn, hair, &amp;c.) with potash and iron
-filings; potassium cyanide is formed from the nitrogen, carbon,
-and alkali, and this with the sulphur and iron present is easily
-converted into potassium ferrocyanide (yellow prussiate of
-potash, K₄FeC₆N₆) by lixiviation of the molten mass. It
-crystallises out on evaporation.</p>
-
-<p>Cyanogen compounds are obtained in large quantity from
-the material used in purifying the gas in gas works. This
-saturated spent material contains, in addition to 30-40 per
-cent. of sulphur, 8-15 per cent. of cyanogen compounds and
-1-4 per cent. of sulphocyanogen compounds.</p>
-
-<p>By lixiviation with water the soluble ammonium salts are
-extracted from the purifying material. This solution furnishes<span class="pagenum"><a name="Page_94" id="Page_94">[94]</a></span>
-<i>sulphocyanide of ammonium</i>, from which the remaining unimportant
-sulphocyanide compounds are obtained (used in cloth
-printing). The further treatment of the purifying material
-for potassium ferrocyanide is rendered difficult because of
-the sulphur, which is either removed by carbon bisulphide
-and the ferrocyanide obtained by treatment with quicklime
-and potassium chloride, or the mass is mixed with quicklime,
-steamed in closed vessels, lixiviated with water, and decomposed
-by potassium chloride; ferrocyanide of potassium and
-calcium separates out in crystals, and this, treated with
-potash, yields potassium ferrocyanide.</p>
-
-<p>The well-known non-poisonous pigment Prussian blue is
-obtained by decomposing ferrocyanide of potash with chloride
-or oxide of iron in solution.</p>
-
-<p><i>Potassium cyanide</i> (KCN) is prepared from potassium
-ferrocyanide by heating in absence of air, but it is difficult to
-separate it entirely from the mixture of iron and carbon which
-remains. All the cyanogen is more easily obtained in the form
-of potassium and sodium cyanide from potassium ferrocyanide
-by melting it with potash and adding metallic sodium.</p>
-
-<p>The very poisonous <i>hydrocyanic acid</i> (prussic acid, HCN)
-is formed by the action of acids on potassium or sodium
-cyanide; small quantities indeed come off on mere exposure
-of these substances to the air. The increasing demand for
-potassium cyanide has led to experimental processes for
-producing it synthetically.</p>
-
-<p>One method consists in the production of potassium
-cyanide from potash and carbon in a current of ammonia gas.
-Small pieces of charcoal are freed from air, saturated with a
-solution of potash, dried in the absence of air, and heated in
-upright iron cylinders to 100° C., while a stream of ammonia
-gas is passed through.</p>
-
-<p>Again, sodium cyanide is prepared from ammonia, sodium,
-and carbon by introducing a definite amount of sodium and
-coal dust into melted sodium cyanide and passing ammonia
-through. The solution is then concentrated in vacuo and
-sodium cyanide crystallises out on cooling.</p>
-
-<p><span class="smcap">Use of Cyanides.</span>—Potassium cyanide is principally used
-in the recovery of gold, in gold and silver electroplating, in
-photography, for soldering (it reduces oxides and makes<span class="pagenum"><a name="Page_95" id="Page_95">[95]</a></span>
-metallic surfaces clean), for the production of other cyanogen
-compounds, for the removal of silver nitrate stains, &amp;c. Hydrocyanic
-acid gas is given off in electroplating, photography, in
-smelting fumes, in tanning (removing hair by gas lime), &amp;c.</p>
-
-<p><span class="smcap">Effects on Health.</span>—Industrial cyanogen poisoning is
-rare. Weyl<a href="#endnote91" id="endnote-ref91"><span class="endnote-marker">1</span></a> states that he could find no case in any of the
-German factory inspectors’ reports for the twenty years prior
-to 1897, nor in some twenty-five volumes of foreign factory
-inspectors’ reports. I have found practically the same in my
-search through the modern literature.</p>
-
-<p>Of the very few references to the subject I quote the most
-important.</p>
-
-<p>A case of (presumably) chronic hydrocyanic acid poisoning
-is described in a worker engaged for thirteen years in silver
-electroplating of copper plates.<a href="#endnote92" id="endnote-ref92"><span class="endnote-marker">2</span></a> The plates were dipped in a
-silver cyanide solution and then brushed. After two years
-he began to show signs of vomiting, nausea, palpitation, and
-fatigue, which progressed and led to his death.</p>
-
-<p>A case of sudden death is described<a href="#endnote93" id="endnote-ref93"><span class="endnote-marker">3</span></a> occurring to a worker
-in a sodium cyanide factory who inhaled air mixed with hydrocyanic
-acid gas from a leaky pipe situated in a cellar. The
-factory made sodium cyanide and ammonium sulphate from
-the residue after removal of the sugar from molasses. This is
-the only definite case of acute cyanogen poisoning in a factory
-known to me. I believe that under modern conditions, in
-which the whole process is carried on under negative pressure,
-chance of escape of cyanogen gases is practically excluded.</p>
-
-<p>It should be mentioned that hydrocyanic acid vapour is
-given off in the burning of celluloid. In this way eight persons
-were killed at a fire in a celluloid factory.<a href="#endnote94" id="endnote-ref94"><span class="endnote-marker">4</span></a> </p>
-
-<p>Skin affections are said to be caused by contact with fluids
-containing cyanogen compounds, especially in electroplating.
-It is stated that workers coming into contact with solutions
-containing cyanides may absorb amounts sufficient to cause
-symptoms, especially if the skin has abrasions. Such cases
-are described.<a href="#endnote95" id="endnote-ref95"><span class="endnote-marker">5</span></a> In electroplating, further, in consequence of
-the strong soda solutions used, deep ulceration and fissures of
-the skin of the hand can be caused.</p>
-
-<p><span class="pagenum"><a name="Page_96" id="Page_96">[96]</a></span></p>
-
-<h4>COAL TAR AND TAR PRODUCTS</h4>
-
-<p>Of the products of the illuminating gas industry tar has
-considerably the most importance. Coal tar as such has
-varied use in industry, but far greater use is made of the products
-obtained by fractional distillation from it such as benzene,
-toluene, naphthalene, anthracene, carbolic acid, pyridine, and
-the other constituents of tar, a number of which form the
-starting-point in the production of the enormous coal-tar dye
-industry. Especially increasing is the consumption of benzene.
-In Germany alone this has increased in ten years from 20 to
-70 million kilos. This is partly due to the need of finding
-some cheap substitute for benzine, the consumption and cost
-of which has increased, and it has in many respects been found
-in benzene.</p>
-
-<p>Besides benzene and its homologues, toluene, anthracene, and
-naphthalene are valuable. Anthracene is used in the manufacture
-of alizarine and naphthalene in that of artificial indigo
-and of the azo-colours. Carbolic acid (phenol) and the homologous
-cresols serve not only as disinfectants but also in
-the manufacture of numerous colours and in the preparation
-of picric acid and salicylic acid. Further, a number of pharmaceutical
-preparations and saccharin are made from the
-constituents of tar.</p>
-
-<p>The important <i>constituents of tar</i> are:</p>
-
-<p>1. Hydrocarbons of the methane series: paraffins, olefines;
-hydrocarbons of the aromatic series: benzene and its homologues,
-naphthalene, anthracene, phenanthrene, &amp;c.</p>
-
-<p>2. Phenols (cresols, naphthols).</p>
-
-<p>3. Sulphides: sulphuretted hydrogen, carbon bisulphide,
-mercaptan, thiophene.</p>
-
-<p>4. Nitrogen compounds: ammonia, methylamine, aniline,
-pyridine, &amp;c.</p>
-
-<p>5. Fifty to sixty per cent. of tar consists of pitch constituting
-a mixture of many different substances which
-cannot be distilled without decomposition.</p>
-
-<p><i>Crude tar</i>, i.e. tar which separates in the dry distillation of
-coal, is employed as such for preserving all kinds of building
-materials, for tarring streets, as plastic cement, as a disinfectant,<span class="pagenum"><a name="Page_97" id="Page_97">[97]</a></span>
-in the preparation of roofing paper or felt, lampblack,
-briquettes, &amp;c.</p>
-
-<p><i>Brattice cloth</i> and <i>roofing felt</i> are made by passing the
-materials through hot tar and incorporating sand with them;
-in doing this heavy fumes are given off.</p>
-
-<p><i>Lampblack</i> is made by the imperfect combustion of tar or
-tar oil by letting them drop on to heated iron plates with as
-limited an air supply as possible; the burnt gases laden with
-carbon particles are drawn through several chambers or sacks
-in which the soot collects.</p>
-
-<div class="figcenter" style="width: 500px;" id="fig23">
-
-<img src="images/fig23.jpg" width="500" height="425" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 23.</span>—Tar Still (<i>after Krämer</i>)</p>
-
-</div>
-
-<p><i>Briquettes</i> (patent fuel) are made by mixing small coal (coal
-dust) with tar or pitch and then pressing them in moulds.</p>
-
-<p>The separation and recovery of the valuable ingredients is
-effected by <i>fractional distillation</i>. This is carried out by heating
-the tar at gradually increasing temperature in a wrought-iron
-still, the bottom of which is arched and having a cast-iron
-still head, or in horizontal boilers by direct fire. Before
-commencing the distillation the tar is freed as far as possible
-of water by storage. On gradual increase of temperature the
-volatile constituents, the so-called ‘light oil,’ and later the
-heavier volatile constituents come over. The constituents<span class="pagenum"><a name="Page_98" id="Page_98">[98]</a></span>
-are liberated in a gaseous state and are collected in fractions.
-The pitch remains behind in the still. Considerable quantities
-of coal tar are not distilled for pitch. Often the light oils
-and a portion of the heavy oils are collected, when soft pitch
-remains, or, if the light oils and only a very small portion of
-the heavy oils are collected, <i>asphalt</i> remains behind, this residue
-being used as a basis for the manufacture of roofing felt.
-The vapours are condensed in iron coils round which cold
-water circulates. The receivers in which the distillate is caught
-are changed at definite times as the temperature gradually
-rises. If five fractions have come over they are called (1) first
-runnings, (2) light oil to 170° C., (3) middle oil (carbolic oil to
-230° C.), (4) heavy oil to 270° C., and lastly (5) anthracene
-oil, which distills at over 270° C.; the pitch remaining behind
-is let out of the still by an opening at the bottom.</p>
-
-<p>We will briefly sketch the further treatment and use of
-these fractions, so far as a knowledge of the most important
-processes is necessary for our purpose.</p>
-
-<p>1. The <i>light oils</i> (including first runnings) coming over
-up to 170° C. are again distilled and then purified with
-sulphuric acid in lead-lined cast-iron or lead-lined wooden
-tanks. The dark-coloured acid used for purifying after
-dilution with water, which precipitates tarry matters, is treated
-for ammonium sulphate; the basic constituents of the light
-oils extracted with sulphuric acid and again liberated by lime
-yield <i>pyridine</i> (C₅H₅N) and the homologous pyridine bases, a
-mixture of which is used for denaturing spirit. After the
-light oils have been washed with dilute caustic soda liquor,
-whereby the phenols are removed, they are separated by
-another fractional distillation into (<i>a</i>) crude benzol (70°-130° C.)
-and (<i>b</i>) solvent naphtha (boiling-point 130°-170° C.).</p>
-
-<p><i>Crude benzol</i> (70°-140° C.) consists chiefly of benzene and
-toluene and is separated into its several constituents in
-special rectifying apparatus. For this production of pure
-benzene (boiling-point 80°-82° C.) and pure toluene (boiling-point
-110° C.) fractionating apparatus is used (<a href="#fig24">fig. 24</a>).</p>
-
-<p>The <i>commercial products</i> in use which are obtained from
-the fractional distillation of the light oil are:</p>
-
-<p>(<i>a</i>) <i>Ninety per cent. benzol</i>, so called because in the
-distillation 90 per cent, should come over at a temperature<span class="pagenum"><a name="Page_99" id="Page_99">[99]</a></span>
-of 100° C. It is
-made up of 80-85
-per cent. benzene,
-13-15 per cent.
-toluene, 2-3 per
-cent. xylene, and
-contains, as impurities,
-traces of
-olefines, paraffins,
-sulphuretted hydrogen,
-and other
-bodies.</p>
-
-<p>(<i>b</i>) <i>Fifty per
-cent. benzol</i> contains
-50 per cent.
-of constituents
-distilling at 100°
-C. and 90 per cent.
-at 120° C.; it is
-a very mixed product,
-with only
-40-50 per cent. of
-benzene.</p>
-
-<p>(<i>c</i>) <i>Solvent
-naphtha</i>, so called
-because it is largely
-used for dissolving
-rubber, is free
-from benzene, but
-contains xylene
-and its homologues
-and other
-unknown hydrocarbons.</p>
-
-<div class="figcenter" style="width: 350px;" id="fig24">
-
-<img src="images/fig24.jpg" width="350" height="700" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 24.</span>—Column Apparatus of Hickman for Distillation
-of Benzene (<i>after Ost</i>)</p>
-
-<p class="caption">A Still body; B Analysing column; C Cooler; D Condenser
-for pure distillate.</p>
-
-</div>
-
-<p>Benzol is widely
-used. Ninety
-per cent. benzol
-is largely used in
-the chemical industry,
-serving<span class="pagenum"><a name="Page_100" id="Page_100">[100]</a></span>
-for the preparation of dye stuffs, pharmaceutical preparations,
-scents, &amp;c. In other industries it took the place of
-benzine and also of turpentine oil, especially in the paint
-industry, since it evaporates quickly and readily dissolves
-resins. Hence it is used in the preparation of quick drying
-ship’s paints, as a protection against rust, and as an isolating
-lacquer (acid proof colours) for electrical apparatus, in the
-production of deck varnishes, and as a solvent of resins.</p>
-
-<p>This use of benzol in the paint industry is by no means
-unattended with danger, as benzol is poisonous. Far less
-harmful, if not altogether without risk, is use of benzol free
-solvent naphtha—but this evaporates only slowly and hence
-cannot take the place of benzol.</p>
-
-<p>Benzol serves further for fat extraction from bones in
-manure factories and of caffein from coffee beans.</p>
-
-<p>Again, it is used as a motive power in motor vehicles.</p>
-
-<p>The solvent naphtha above mentioned with boiling-point
-above 140° C. and all the light oils are employed in chemical
-cleaning and for dissolving indiarubber (see Indiarubber).</p>
-
-<p>These are known in the trade erroneously as ‘benzine,’
-which unfortunately often leads to confusion with petroleum
-benzine (see Petroleum) and to mistakes in toxicological
-accounts of poisoning.</p>
-
-<p>2. Between 150° and 200° C. the <i>middle oil</i> comes over, from
-which on cooling <i>naphthalene</i> (C₁₀H₈) crystallises out, and is
-subsequently washed with caustic soda liquor and with acid;
-it is re-distilled and hot pressed. The remaining liquor yields,
-when extracted with caustic soda, <i>phenol</i> (carbolic acid, C₆H₅OH),
-which, on addition of sulphuric acid or carbonic acid, separates
-from the solution and then—generally in special factories—is
-obtained pure by distillation and special purifying
-processes.</p>
-
-<p>From the sodium salt of carbolic acid (sodium phenolate)
-<i>salicylic acid</i> (C₆H₄OH.COOH) is obtained by combination
-with compressed CO₂ at a temperature of 150° C. <i>Picric acid</i>
-(trinitrophenol, C₆H₂OH.(NO₂)₃) is obtained by treating phenol
-with a mixture of sulphuric and nitric acids (nitration). The
-yellow crystals of this explosive which separate are carefully
-washed, recrystallised, centrifugalised, and dried.</p>
-
-<p>3. The <i>heavy oils</i> which come over between 200° and 300° C.<span class="pagenum"><a name="Page_101" id="Page_101">[101]</a></span>
-containing cresols, naphthols, naphthaline, quinoline bases,
-fluid paraffins, &amp;c., are seldom separated further. The disinfectants
-lysol, sapocarbolic, &amp;c., are obtained from such
-fractions.</p>
-
-<p>The heavy oils are much in use for <i>impregnating wood</i>
-(piles, railway sleepers, &amp;c.), to prevent rotting. This is
-done in special creosoting installations. The wood is first
-freed from moisture under vacuum and lastly the heavy oil
-forced in. This is a better means of preserving timber than
-the analogous method by means of chloride of zinc.</p>
-
-<p>4. <i>Anthracene oil</i> or ‘green oil’ comes over between 300°
-and 400° C. and contains the valuable anthracene which
-crystallises out, is separated from the oil in filter presses, or
-dried in centrifugal machines. <i>Alizarin</i> dyes are made from
-it. Raw anthracene oil further is used commercially as a paint
-under the name of carbolineum for preserving wood.</p>
-
-<p>5. The <i>pitch</i> remaining behind in the still serves (like tar)
-for making varnishes, patent fuel, &amp;c. For our purpose use of
-pitch in the preparation of iron varnishes which adhere to
-metals and protect them from oxidation have interest. Pitch
-and the heavy oils are melted together or, if for thin varnishes,
-dissolved in solvent naphtha. The volatile constituents
-evaporate after the coat has been applied.</p>
-
-<p><span class="smcap">Effects on Health.</span>—Severe injury to health or poisoning
-cases scarcely arise through manipulations with or use of tar.
-Inhalation, however, of large quantities of tar vapour is
-without doubt unpleasant, as a number of poisonous substances
-are contained in the fumes. And the ammonia water
-which separates on standing can give off unpleasantly
-smelling odours from the sulphur compounds in it, especially
-if it comes into contact with waste acids, with consequent
-development of sulphuretted hydrogen gas.</p>
-
-<p>I could not find in the literature of the subject references
-to any clearly proved case of poisoning from tar emanations.
-But deserving of mention in this connection are the <i>effects
-on the skin</i> caused by tar.</p>
-
-<p>Workers coming into contact with tar suffer from an
-inflammatory affection of the skin, so-called tar eczema, which
-occasionally takes on a cancerous (epithelioma) nature similar
-to chimney-sweep’s cancer, having its seat predominantly on<span class="pagenum"><a name="Page_102" id="Page_102">[102]</a></span>
-the scrotum. In lampblack workers who tread down the
-soot in receptacles the malady has been observed to affect the
-lower extremities and especially the toes.</p>
-
-<p>In tar distillation and in the <i>production</i> and <i>use</i> of <i>benzene</i>
-industrial poisoning frequently occurs. Many cases are recorded,
-but in several the immediate exciting cause is doubtful, and
-consequently it is often difficult to classify the cases.</p>
-
-<p>Most frequently the manufacture and use of benzene come
-in question. Besides this, in tar distillation poisoning may be
-caused by other substances, such as sulphuretted hydrogen gas,
-carbonic oxide gas, &amp;c. In the production of antipyrin,
-aspirin, &amp;c., and in the preparation and use of anthracene injury
-to health is recognised.</p>
-
-<p>From the list of recognised cases of these forms of poisoning
-the most characteristic are chosen from the recent literature on
-the subject.</p>
-
-<p>The Prussian factory inspectors’ reports for 1904 describe
-the following: In cleaning out a tar still two workers were
-killed by inhalation of gas. The nature of the gas was not
-ascertained. But what probably happened was that the cock
-on the foul gas pipe collecting the gases from the stills leaked
-and allowed fumes to pass over from one still to another.</p>
-
-<p>A foreman and worker were rendered unconscious on
-entering a receiver for heavy oil for cleaning purposes. On
-treatment with oxygen gas they speedily recovered.</p>
-
-<p><i>Industrial benzene poisoning</i> is especially frequent now in
-view of the increasing use to which it is put. Several cases
-have proved fatal.</p>
-
-<p>A worker, for instance, forgot to open the cock for the water
-to cool the condenser, so that some of the benzene vapour
-remained uncondensed. The case proved fatal.</p>
-
-<p>The Report of the Union of Chemical Industry for 1905
-stated that a worker on night duty, whose duty it was to
-regulate the introduction of steam and the cooling of the benzol
-plant, was found lying dead in front of the building. Inquiry
-showed that he had not opened the valve for running the
-distillate into the appropriate receiver. Eight thousand
-litres overflowed.</p>
-
-<p>In an indiarubber extracting factory a worker was rendered
-unconscious while inspecting a benzol still; before entering he<span class="pagenum"><a name="Page_103" id="Page_103">[103]</a></span>
-had omitted to observe the instructions to drive steam through
-and have a mate on watch at the manhole. Two other workmen
-were similarly affected who went to the rescue without
-adoption of precautions. Only one survived.</p>
-
-<p>In a further accident (already mentioned under ‘Coke
-Furnaces’) two workmen were killed. In the factory in question
-the thick tar from the coke ovens was being distilled under
-slight pressure. The air pumps, however, were out of order,
-and temporary use was being made of Körting’s injectors,
-whereby the steam and tar constituents were cooled and led
-into the drain in front of the closet, near to which was a ventilating
-shaft. Probably, in addition to benzene and its homologues,
-sulphuretted hydrogen and cyanogen compounds were
-present in the poisonous gases.</p>
-
-<p>In cleaning out a benzene extracting apparatus a workman
-was killed by the stagnant fumes in it.</p>
-
-<p>A similar case of benzene poisoning occurred in a
-naphthalamine works through inspecting an extracting vessel
-which had contained benzene and naphthalamine and had
-to be cleaned. The vessel had been empty for twenty-two
-hours and had been washed and ventilated, but through a
-leaking pipe benzene had dropped down into it. The workman
-engaged was rendered unconscious inside the retort,
-but was rescued by an engineer equipped with a breathing
-helmet. Others who without such apparatus tried to effect a
-rescue were overcome, and one who had entered the retort
-succumbed.<a href="#endnote96" id="endnote-ref96"><span class="endnote-marker">1</span></a> </p>
-
-<p>Benzene poisoning has often occurred in the cleaning of
-tanks, &amp;c., for the transport and storage of the substance.
-The following examples are taken from the Reports of the
-Union of Chemical Industry.</p>
-
-<p>A worker during the pause for breakfast had, unknown to
-his employer, cleaned out an empty truck for crude benzol.
-Later he was with difficulty removed unconscious through the
-manhole and could not be resuscitated. Only a short time
-previously a similar occurrence had taken place in the same
-factory.</p>
-
-<p>Two further fatal cases were reported in 1908 in the cleaning
-out of railway tank waggons. The tank had previously been
-thoroughly sprayed with water. The partition plates which are<span class="pagenum"><a name="Page_104" id="Page_104">[104]</a></span>
-required in such tanks increase the difficulty of cleaning from
-the manhole. After the foreman had tested the air by putting
-his head inside and considered it free from danger, a man
-entered to clean out the deposit; another man on watch
-outside had evidently gone in for rescue purposes. Resuscitation
-in both cases failed.</p>
-
-<p>A worker died and several were affected in the cleaning out
-of a benzol storage tank in a tar distillery. The tank had
-had air blown through it several weeks before, and had been
-thoroughly cleaned by steam and water. Also in the inspection
-the greatest care was taken in only permitting work for
-short spells. This shows that, notwithstanding great care,
-the last traces of benzol cannot be entirely removed and that
-quite small quantities are sufficient to cause severe and even
-fatal poisoning. Workers should only clean out tanks,
-therefore, when properly equipped with helmets.</p>
-
-<p>In the German factory inspectors’ reports for 1902 a case
-of intoxication is described in a man who was engaged painting
-the inside of an iron reservoir with an asphalt paint dissolved in
-benzol.</p>
-
-<p>Of special interest is a fatal case from inhalation of benzol
-fumes in a rubber factory. Rubber dissolved in benzol was
-being rubbed into the cloth on a spreading machine in the
-usual way. The cloth then passes under the cleaning doctor
-along the long heated plate to the end rolls. Of the three men
-employed at the process one was found to be unconscious and
-could not be brought round again.</p>
-
-<p>The cases described<a href="#endnote97" id="endnote-ref97"><span class="endnote-marker">2</span></a> of poisoning with impure benzol in
-a pneumatic tyre factory in Upsala are, perhaps, analogous.
-Here nine young women had severe symptoms, four of whom
-died.</p>
-
-<p>In reference to the cases which occurred in rubber
-factories it is conceivable that carbon bisulphide played a
-part, since in such factories not only are mixtures of benzol
-and carbon bisulphide used, but also frequently the ‘first
-runnings’ of benzol, which, on account of the high proportion
-(sometimes 50 per cent.) of carbon bisulphide in them, make an
-excellent solvent for rubber.</p>
-
-<p>From some coke ovens crude benzol was collected in two
-large iron receivers. They were sunk in a pit projecting very<span class="pagenum"><a name="Page_105" id="Page_105">[105]</a></span>
-little above the ground. To control the valves the workmen
-had to mount on the receiver, the manholes of which were kept
-open during filling. The pit was roofed over and two wooden
-shafts served both for ventilation and as approaches to the
-valves. One summer day benzol had been blown in the usual
-way into a railway truck and a worker had entered the space
-to control the valves. Some time afterwards he was found in a
-doubled-up position on the receiver, grasping the valves, from
-which later he fell off down to the bottom of the pit. Three
-rescuers entered, but had to retire as they became affected. A
-fourth worker, in the presence of the manager, was let down
-by a rope, but succumbed immediately and was dragged up
-a corpse. Finally, equipped with a smoke helmet, a rescuer
-brought up the lifeless body of the first man. It was believed
-that the benzol had distilled over warm and had evaporated
-to such an extent as to fill with fumes the unsuitably arranged
-and inadequately ventilated space. Possibly other volatile
-compounds were responsible for the poisoning.<a href="#endnote98" id="endnote-ref98"><span class="endnote-marker">3</span></a> </p>
-
-<p>A similar though less serious accident occurred to a foreman
-who forgot to set the cooling apparatus at work at the commencement
-of distillation, and became unconscious from the
-escaping fumes, as also did a rescuer. The latter was brought
-round by oxygen inhalation, but the former, although alive
-when recovered, succumbed despite efforts at artificial
-respiration.</p>
-
-<p>A fatal case occurred in an aniline factory where benzol
-fumes had escaped owing to faulty arrangement of the valves.
-The worker, although ordered at once to leave the room, was
-found there ten minutes later dead.</p>
-
-<p>Interesting are the following cases of accidents due to use
-of paints containing benzol.</p>
-
-<p>In painting a retort with an anti-corrosive paint called
-‘Original Anti-corrosive,’ unconsciousness followed on completion
-of the painting, but by prompt rescue and medical
-assistance life was saved. The accident was attributed to
-benzol fumes from the paint insufficiently diluted by the air
-coming in at the open manhole. A similar case arose from use
-of a rust-preventing paint—‘Preolith’—and only with difficulty
-was the man using it pulled out from the inside of the steam
-boiler. Although resuscitated by oxygen inhalation, he was<span class="pagenum"><a name="Page_106" id="Page_106">[106]</a></span>
-incapacitated for eight days. Crude benzol was a constituent
-of ‘Preolith.’ Obviously use of such paints in closely confined
-spaces is very risky.</p>
-
-<p>The frequency of such poisonings caused Schaefer,<a href="#endnote99" id="endnote-ref99"><span class="endnote-marker">4</span></a> Inspector
-of Factories in Hamburg, to go fully into the question. He
-lays stress on the dangerous nature of paints containing a high
-proportion of benzol, but considers use of unpurified constituents
-with boiling-point between 130°-170° C., such as solvent naphtha,
-as free from risk (cf. in Part II the experiments on benzene and
-the commercial kinds of benzol). Schaefer mentions that in
-1903 and 1904 cases of unconsciousness from painting the
-inside of boilers were numerous. The proportion of benzol
-in the paints was 20-30 per cent. In 1905 and 1906 the cases
-were attributable rather to inhalation of hydrocarbons in
-cleaning of apparatus. Use of ‘Dermatin’ affected two
-painters. One case in 1906 happened to a man painting the
-double bottom of a ship in Hamburg harbour with ‘Black
-Varnish Oil’ through the manhole, in doing which he inhaled
-much of the fumes. This paint consisted of coal-tar pitch in
-light coal-tar oil, the latter constituent (distilling at 170° C.)
-amounting to 31-33 per cent. Investigation showed further
-that the bulk of the tar oil volatilised at ordinary temperatures
-and so quickly dried. Sulphuretted hydrogen gas was given
-off on slight warming. The person after using it for some
-time felt poorly, and then became ill with severe inflammation
-of the respiratory passages, which proved fatal after twenty-four
-days.</p>
-
-<p>Several similar cases occurred in 1908 and 1909. Painting
-the inside of a boiler with ‘Auxulin’ caused unconsciousness
-in four persons, of whom three were rescuers. A fatal case
-was due to use of a patent colour containing 30-40 per cent.
-benzol in an entirely closed-in space (chain-well), although
-the worker was allowed out into fresh air at frequent
-intervals.</p>
-
-<p>A case of chronic industrial xylene poisoning is described
-in a worker using it for impregnating indiarubber goods. The
-symptoms were nervous, resembling neurasthenia.</p>
-
-<p>Some of the cases of poisoning, especially when severe and
-fatal, in the production of distillation constituents of coal tar
-are doubtless attributable to <i>sulphuretted hydrogen gas</i>. Thus<span class="pagenum"><a name="Page_107" id="Page_107">[107]</a></span>
-in England, in the years 1901-3, there were eleven fatal and
-as many other severe cases reported from tar distilleries, of
-which the majority were due to sulphuretted hydrogen gas.</p>
-
-<p>One case of <i>carbonic oxide</i> poisoning in coal-tar distillation
-is described.<a href="#endnote100" id="endnote-ref100"><span class="endnote-marker">5</span></a> In cleaning out pitch from a still fourteen days
-after the last distillation a workman succumbed to carbonic
-oxide poisoning. This is at all events a rare eventuality,
-since no other case is to be found in the literature of the subject,
-but it is a proof that in the last stage of coal-tar distillation
-carbonic oxide plays a part.</p>
-
-<p>Mention must be made of the frequent occurrence of
-severe skin affections in <i>anthracene workers</i>; they take the
-form of an eruption on the hands, arms, feet, knees, &amp;c., and
-sometimes develop into cancer.</p>
-
-<p>Observations in a chemical factory since 1892 showed that
-of thirty thus affected in the course of ten years twenty-two
-came into contact with paraffin.</p>
-
-<h5>Artificial Organic Dye Stuffs (Coal-tar Colours)</h5>
-
-<p><span class="smcap">Manufacture.</span>—The starting-points for the preparation of
-artificial coal-tar dyes are mainly those aromatic compounds
-(hydrocarbons) described in the preceding section. Besides
-these, however, there are the derivatives of the fatty series such
-as methyl alcohol (wood spirit), ethyl alcohol, phosgene, and,
-latterly, formaldehyde.</p>
-
-<p>The <i>hydrocarbons of the benzene series</i> from tar distillation
-are delivered almost pure to the colour factory. Of these
-benzene, toluene, xylene, naphthalene, anthracene, and the
-phenols, cresols, &amp;c., have to be considered.</p>
-
-<p>Further treatment is as follows:</p>
-
-<p>1. Nitration, i.e. introduction of a nitro-group by means of
-nitric acid.</p>
-
-<p>2. Reduction of the nitrated products to amines.</p>
-
-<p>3. Sulphonation, i.e. conversion to sulphonic acids by
-means of concentrated sulphuric acid.</p>
-
-<p>4. The sulphonic acids are converted into phenols by
-fusing with caustic soda.</p>
-
-<p>5. Introduction of chlorine and bromine.</p>
-
-<p><i>Nitro-derivatives</i> are technically obtained by the action of<span class="pagenum"><a name="Page_108" id="Page_108">[108]</a></span>
-a mixture of nitric and concentrated sulphuric acids on the
-aromatic body in question. The most important example is
-<i>nitrobenzene</i>.</p>
-
-<p>Benzene is treated for several hours in cylindrical cast-iron
-pans with nitric and concentrated sulphuric acids. The vessel
-is cooled externally and well agitated. A temperature of
-25° C. should not be exceeded.</p>
-
-<div class="figcenter" style="width: 600px;" id="fig25">
-
-<img src="images/fig25.jpg" width="600" height="450" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 25.</span>—Preparation of Intermediate Products in the Aniline Colour Industry
-(Closed Apparatus), showing Arrangement for Condensation (<i>after Leymann</i>)</p>
-
-</div>
-
-<p>On standing the fluid separates into two layers: the lower
-consists of dilute sulphuric acid in which there is still some
-nitric acid, and the upper of nitrobenzene. The latter is freed
-of remains of acid by washing and of water by distillation.
-<i>Toluene</i> and <i>xylene</i> are nitrated in the same way. <i>Dinitro
-products</i> (such as metadinitrobenzene) are obtained by further
-action of the nitro-sulphuric acid mixture on the mononitro-compound
-at higher temperature.</p>
-
-<p><span class="pagenum"><a name="Page_109" id="Page_109">[109]</a></span></p>
-
-<p>For conversion of phenol into <i>picric acid</i> (trinitrophenol)
-the use of a nitro-sulphuric acid mixture is necessary.</p>
-
-<p>The <i>aromatic bases</i> (aniline, toluidine, xylidine) are obtained
-by reduction of the corresponding nitro-compound by means
-of iron filings and acid (hydrochloric, sulphuric, or acetic).
-Thus in the case of <i>aniline</i> pure nitrobenzene is decomposed
-in an iron cylindrical apparatus, provided with agitators and
-a condenser, and avoidance of a too violent reaction, by means
-of fine iron filings and about 5 per cent. hydrochloric acid.
-After completion of the reaction the contents are rendered
-alkaline by addition of lime and the aniline distilled over.
-Manufacture of <i>toluidine</i> and <i>xylidine</i> is analogous.</p>
-
-<p><i>Dimethylaniline</i> is obtained by heating aniline, aniline
-hydrochloride, and methyl alcohol.</p>
-
-<p><i>Diethylaniline</i> is prepared in an analogous way with the
-use of ethyl alcohol.</p>
-
-<p>By the action of nitrous acid (sodium nitrite and hydrochloric
-acid) on the acid solution of the last-named compound
-the <i>nitroso compounds</i> are formed.</p>
-
-<p><i>Sulphonic acids</i> arise by the action of concentrated or fuming
-sulphuric acid on the corresponding bodies of the aromatic
-series: benzene disulphonic acid from benzene and fuming
-sulphuric acid, &amp;c.</p>
-
-<p><i>Phenols</i> and <i>cresols</i> are obtained pure from tar distillation.
-The remaining hydroxyl derivatives (resorcin, α- and β-naphthol,
-&amp;c.), are generally obtained by the action of concentrated
-caustic soda on aromatic sulphonic acids.</p>
-
-<p>The most important aromatic aldehyde, <i>benzaldehyde</i>,
-is obtained from toluene; on introducing chlorine at boiling
-temperature benzyl chloride is first formed, then benzal-chloride
-and finally benzo-trichloride. In heating benzal-chloride
-with milk of lime (under pressure) benzaldehyde is
-formed (C₆H₅COH).</p>
-
-<p><i>Picric acid</i> and <i>naphthol yellow</i> belong to the <i>nitro dyestuffs</i>;
-the last named is obtained by sulphonating α-naphthol with
-fuming sulphuric acid and by the action of nitric acid on
-the sulphonated mixture.</p>
-
-<p>Nitroso derivatives of aromatic phenols yield (with metal
-oxides) the material for production of nitroso dyestuffs. To
-these belong naphthol green, &amp;c.</p>
-
-<p><span class="pagenum"><a name="Page_110" id="Page_110">[110]</a></span></p>
-
-<p>The most important <i>azo dyestuffs</i> technically are produced
-in principle by the action of nitrous acid on the aromatic
-amines. The amido compound is converted into the diazo
-salt by treatment with sodium nitrite in acid solution. Thus
-diazo-benzene is made from aniline. Diazo compounds are
-not usually isolated but immediately coupled with other
-suitable compounds—amido derivatives, phenols—i.e. converted
-into azo compounds.</p>
-
-<div class="figcenter" style="width: 500px;" id="fig26">
-
-<img src="images/fig26.jpg" width="500" height="475" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 26.</span>—Nitrating Plant (<i>after Leymann</i>)</p>
-
-<ul>
-<li>I Nitric acid</li>
-<li>II Balance</li>
-<li>III Storage tank</li>
-<li>IV Nitrating pan</li>
-<li>V Waste acid tank</li>
-<li>VI Acid egg</li>
-<li>VII Hydrocarbon</li>
-<li>VIII Balance</li>
-<li>IX Storage tank</li>
-<li>X Washing vessel</li>
-<li>XI Centrifugal machine</li>
-<li>XII Egg</li>
-<li>- - - Exhaust ventilation pipe.</li>
-</ul>
-
-</div>
-
-<p>The combination of the two constituents takes place at
-once and quantitatively. The colour is separated from the
-aqueous solution by salting-out, and is then put through a
-filter press. The reactions are carried out generally in wooden
-vats arranged in stages. Besides a second, a third constituent
-can be introduced, and in this way naphthol—and naphthylamine
-sulphonic acids yield a large number of colouring matters.
-A very large number of azo dyestuffs can thus be produced<span class="pagenum"><a name="Page_111" id="Page_111">[111]</a></span>
-by the variation of the first component (the primary base)
-with the second and again with the third component, but it
-would carry us too far to deal further with their preparation.</p>
-
-<p><i>Anthracene colours</i>—yielding so-called direct dyes—are prepared
-from anthracene, which is converted into anthraquinone
-by the action of bichromate and dilute sulphuric acid when
-heated; the crude ‘quinone’ is purified with concentrated
-sulphuric acid and converted into anthraquinone monosulphonic
-acid to serve in the preparation of <i>alizarin</i>, which is made from
-it by heating for several days with concentrated caustic soda
-to which sodium chlorate is added. The process is carried on
-in cast-iron pans provided with agitators.</p>
-
-<p><i>Alizarin</i> is the starting-point for the alizarin dyes, but of
-their production we will not speak further, as they, and indeed
-most of the coal-tar dyes, are non-poisonous.</p>
-
-<p><i>Indigo</i> to-day is generally obtained by synthesis. It
-is prepared from phenylglycine or phenylglycine ortho-carboxylic
-acid, which on heating with sodamide becomes
-converted into indoxyl or indoxyl carboxylic acid. These in
-presence of an alkali in watery solution and exposure to the
-oxygen of the air immediately form indigo. The necessary
-glycine derivatives are obtained by the action of monochloracetic
-acid on aniline or anthranilic acid, which again are derived
-from naphthalene (by oxidation to phthalic acid and treatment
-of phthalimide with bleaching powder and soda
-liquor).</p>
-
-<p><i>Fuchsin</i> belongs to the group of triphenylmethane dyestuffs,
-with the production of which the epoch of coal-tar colour
-manufacture began, from the observation that impure aniline
-on oxidation gave a red colour. The original method of
-manufacture with arsenic acid is practically given up in
-consequence of the unpleasant effects which use and recovery
-of large quantities of arsenic acid gave rise to. The method
-consisted in heating a mixture of aniline and toluidine with
-a solution of arsenic acid under agitation in cast-iron cylinders.
-The cooled and solidified mass from the retorts was boiled,
-and from the hot solution, after filtration, the raw fuchsin was
-precipitated with salt and purified by crystallisation.</p>
-
-<p>Now by the usual nitrobenzene process, aniline, toluidine,
-nitrobenzene, and nitrotoluene are heated with admixture of<span class="pagenum"><a name="Page_112" id="Page_112">[112]</a></span>
-hydrochloric acid and some iron protochloride or zinc chloride.
-Further treatment resembles the arsenic process.</p>
-
-<p>By alkylation, i.e. substitution of several hydrogen atoms of
-the amido-groups by ethyl, &amp;c., through the action of alkyl
-halogens and others, it was found possible to convert fuchsin
-into other triphenylmethane colours. But it was soon found
-simpler to transfer already alkylated amines into the colours in
-question. Thus, for example, to prepare <i>methyl violet</i> dimethyl
-aniline was heated for a long time with salt, copper chloride,
-and phenol containing cresol in iron mixing drums. The
-product is freed from salt and phenol by water and calcium
-hydrate, subsequently treated with sulphuretted hydrogen
-or sodium sulphide, and the colour separated from copper
-sulphide by dissolving in dilute acid.</p>
-
-<p>Mention must be made, finally, of the <i>sulphur dyes</i> obtained
-by heating organic compounds with sulphur or sodium
-sulphide. For the purpose derivatives of diphenylamine, nitro- and
-amido-phenols, &amp;c., serve as the starting-point.</p>
-
-<p><span class="smcap">Effects on Health.</span>—From what has been said of the
-manufacture of coal-tar dyes it is evident that poisoning
-can arise from the initial substances used (benzene, toluene,
-&amp;c.), from the elements or compounds employed in carrying
-out the reactions (such as chlorine, nitric acid, sulphuric acid,
-arsenious acid, sodium sulphide, and sulphuretted hydrogen
-gas), from the intermediate bodies formed (nitro and amido
-compounds, such as nitrobenzene, dinitrobenzene, aniline,
-&amp;c.), and that, finally, the end products (the dyes themselves)
-can act as poisons. It has already been said that most of
-the dyes are quite harmless unless contaminated with the
-poisonous substances used in their manufacture.</p>
-
-<p>We have seen that many of the raw substances used in the
-manufacture of coal-tar dyes are poisonous, and we shall learn
-that several of the intermediate products (especially the nitro
-and amido compounds) are so also.</p>
-
-<p>According to Grandhomme,<a href="#endnote101" id="endnote-ref101"><span class="endnote-marker">1</span></a> of the raw materials benzene
-is the one responsible for most poisoning. He describes two
-fatal cases of benzene poisoning. In one case the worker was
-employed for a short time in a room charged with benzene
-fumes, dashed suddenly out of it, and died shortly after. In
-the other, the workman was employed cleaning out a vessel in<span class="pagenum"><a name="Page_113" id="Page_113">[113]</a></span>
-which lixiviation with benzene had taken place. Although
-the vessel had been steamed and properly cooled, so much
-benzene fume came off in emptying the residue as to overcome
-the workman and cause death in a short time.</p>
-
-<p>Grandhomme describes no injurious effect from naphthalene
-nor, indeed, from anthracene, which he considered was without
-effect on the workers.</p>
-
-<p>Similarly, his report as to nitrobenzene was favourable.
-No reported case of poisoning occurred among twenty-one men
-employed, in some of whom duration of employment was from
-ten to twenty years. Aniline poisoning, however, was frequent
-among them. In the three years there was a total of forty-two
-cases of anilism, involving 193 sick days—an average
-of fourteen cases a year and sixty-four sick days. None
-was fatal and some were quite transient attacks.</p>
-
-<p>In the fuchsin department no cases occurred, and any evil
-effects in the manufacture were attributable to arsenic in the
-now obsolete arsenic process. Nor was poisoning observed in
-the preparation of the dyes in the remaining departments—blues,
-dahlias, greens, resorcin, or eosin. In the manufacture
-of methylene blue Grandhomme points out the possibility of
-evolution of arseniuretted hydrogen gas from use of hydrochloric
-acid and zinc containing arsenic. Poisoning was
-absent also in the departments where alizarine colours and
-pharmaceutical preparations were made.</p>
-
-<p>Among the 2500-2700 workers Grandhomme records
-122 cases of industrial sickness in the three years 1893-5,
-involving 724 sick days. In addition to forty-two cases of
-anilism there were seventy-six cases of lead poisoning with 533
-sick days. Most of these were not lead burners, but workers
-newly employed in the nitrating department who neglected
-the prescribed precautionary measures. Lastly, he mentions
-the occurrence of chrome ulceration.</p>
-
-<p>The frequency of sickness in the Höchst factory in each of
-the years 1893-5 was remarkably high: 126 per cent., 91 per
-cent., and 95 per cent. Much less was the morbidity in the
-years 1899-1906—about 66 per cent.—recorded by Leymann<a href="#endnote102" id="endnote-ref102"><span class="endnote-marker">2</span></a> —probably
-the same Höchst factory with 2000 to 2200
-employed. And the cases of industrial poisoning also
-were less. He cites only twenty-one in the whole of the<span class="pagenum"><a name="Page_114" id="Page_114">[114]</a></span>
-period 1899-1906. Of these twelve were due to aniline,
-involving thirty sick days, only five to lead poisoning, with
-fifty-four sick days, one to chrome ulceration, one to
-arseniuretted hydrogen gas (nine sick days), and one
-fatal case each from sulphuretted hydrogen gas and from
-dimethyl sulphate. In 1899, of three slight cases of aniline
-poisoning one was attributable to paranitraniline (inhalation
-of dust), and the two others to spurting of aniline oil on
-to the clothing, which was not at once changed. Of the
-four cases in 1900, one was a plumber repairing pipes
-conveying aniline and the others persons whose clothes had
-been splashed.</p>
-
-<p>In 1903 a worker employed for eleven and a half years in
-the aniline department died of cancer of the bladder. Such
-cancerous tumours have for some years been not infrequently
-observed in aniline workers, and operations for their removal
-performed. Leymann thinks it very probable that the
-affection is set up, or its origin favoured, by aniline. This
-view must be accepted, and the disease regarded as of industrial
-origin. Three slight cases in 1904 and 1905 were due partly to
-contamination of clothing and partly to inhalation of fumes.
-Of the five cases of lead poisoning three were referable to
-previous lead employment. Perforation of the septum of the
-nose by bichromate dust was reported once only. A fatal
-case from sulphuretted hydrogen gas and a case of poisoning
-by arseniuretted hydrogen gas occurred in 1906, but their
-origin could not be traced.</p>
-
-<p>In large modern aniline dye factories, therefore, the health
-of the workers is, on the whole, good and industrial poisoning
-rare. Comparison of the two sets of statistics show that
-improvement in health has followed on improved methods of
-manufacture. Such cases of aniline poisoning as are reported
-are usually slight, and often accounted for by carelessness on
-the part of the workers.</p>
-
-<p>Data as to the health of workers in factories manufacturing
-or using nitro compounds are given in the English factory
-inspectors’ reports for 1905. Even with fortnightly medical
-examination in them, more than half the workers showed
-signs of anæmia and slight cyanosis. Two men in a factory<span class="pagenum"><a name="Page_115" id="Page_115">[115]</a></span>
-employing twelve men in the manufacture of nitro compounds
-were treated in hospital for cyanosis, distress of breathing,
-and general weakness. One had only worked in the factory
-for nine days. In another badly ventilated factory, of
-twenty persons examined fourteen showed bluish-grey coloration
-of the lips and face, ten were distinctly anæmic, and six
-showed tremor and weakness of grasp.</p>
-
-<p>Nitrobenzene poisoning arises from the fumes present in
-aniline and roburite factories. Acute and chronic poisoning
-by nitro compounds of the benzene series are described,
-brought about by accident (fracture of transport vessels)
-and by carelessness (splashing on to clothes). Cases of
-optic neuritis (inflammation of the optic nerve) as a result
-of chronic nitrobenzene poisoning are described.</p>
-
-<p>Dinitrobenzene and other nitro and dinitro compounds
-are present in safety explosives. Thus roburite and bellite
-consist of metadinitrobenzene and ammonium nitrate;
-ammonite of nitronaphthalene and ammonium nitrate;
-securite of the materials in roburite with ammonium oxalate
-in addition. In roburite there may be also chlorinated nitro
-compounds.</p>
-
-<p>Leymann,<a href="#endnote103" id="endnote-ref103"><span class="endnote-marker">3</span></a> describing accidents in the preparation of nitrophenol
-and nitrochloro compounds, mentions four fatal cases
-occurring in the manufacture of black dyes from mono- and
-di-nitrophenols as well as mono- and di-nitrochlorobenzene and
-toluene. In three of the cases dinitrophenol was the compound
-at fault owing to insufficient care in the preparation,—the
-result of ignorance until then of risk of poisoning from
-mono- and tri-nitrophenol. One of the men had had to empty a
-washing trough containing moist dinitrophenol. He suddenly
-became collapsed, with pain in the chest, vomiting, fever, and
-convulsions, and died within five hours. Another suffered from
-great difficulty of breathing, fever, rapid pulse, dilatation of
-the pupils, and died within a few hours in convulsions. Two
-further cases of nitrochlorobenzene poisoning are referred to,
-one of which was fatal. Four chlorobenzene workers after a
-bout of drinking were found unconscious in the street, and
-only recovered after eight to ten hours in hospital. The
-symptoms were grey-blue colour of the skin, pallor of mucous<span class="pagenum"><a name="Page_116" id="Page_116">[116]</a></span>
-membranes, lips, nose, and conjunctivæ, and peculiar chocolate-coloured
-blood.</p>
-
-<p>Many cases of poisoning from roburite are recorded.<a href="#endnote104" id="endnote-ref104"><span class="endnote-marker">4</span></a> In
-the Witten roburite factory it is stated that during the years
-1890-7 almost all the workers had been ill.<a href="#endnote105" id="endnote-ref105"><span class="endnote-marker">5</span></a> Only three
-looked healthy—all the others suffered from more or less
-pallor, blue lips, and yellowish conjunctivæ.</p>
-
-<p>A case of chlorobenzene poisoning was reported with
-symptoms of headache, cyanosis, fainting attacks, difficulty
-of breathing, &amp;c., in a man who had worked only three weeks
-with the substance.<a href="#endnote106" id="endnote-ref106"><span class="endnote-marker">6</span></a> </p>
-
-<p>In the nitrotoluene department of an explosives factory
-a number of the workmen suffered from symptoms of distress
-in breathing, headache, &amp;c., of whom two, employed only a
-short time, died. The poisoning was attributed, partly to
-nitrotoluene and partly to nitrous fumes. As a contributing
-cause it was alleged that in view of shortage of hands unsuitable
-persons were engaged who neglected precautions.<a href="#endnote107" id="endnote-ref107"><span class="endnote-marker">7</span></a> </p>
-
-<p>Nitronaphthalene is said to cause inflammation and
-opacity of the cornea,<a href="#endnote108" id="endnote-ref108"><span class="endnote-marker">8</span></a> attributable either to long-continued
-exposure (four to eight months) to nitronaphthalene vapour
-or to spurting of the liquid into the eye.</p>
-
-<p>I could not find reference in literature to actual cases of
-poisoning by picric acid. They are referred to in a general
-way only as causing skin affections.</p>
-
-<p>Aniline poisoning arises generally from inhalation, but
-absorption through the skin and less frequently inhalation of
-dust of aniline compounds cause it. We have already laid
-stress on the frequently severe cases resulting from carelessness
-in spilling on to or splashing of, clothes without at once
-changing them, breaking of vessels containing it, and entering
-vessels filled with the vapour. In literature of old date many
-such cases have been described, and it was stated that
-workers were especially affected on hot days, when almost
-all showed cyanosis. Such observations do not state fairly
-the conditions to-day in view of the improvements which
-Grandhomme and Leymann’s observations show have taken
-place in aniline factories. Still, cases are fairly frequent.
-Thus in a factory with 251 persons employed, thirty-three
-cases involving 500 days of sickness were reported.</p>
-
-<p><span class="pagenum"><a name="Page_117" id="Page_117">[117]</a></span></p>
-
-<p>The Report of the Union of Chemical Industry for 1907
-cites the case of a worker who was tightening up the leaky
-wooden bung of a vessel containing aniline at a temperature of
-200° C. He was splashed on the face and arms, and although
-the burns were not in themselves severe he died the next day
-from aniline absorption.</p>
-
-<p>Cases of anilism are not infrequent among dyers. The
-reports of the Swiss factory inspectors for 1905 describe a
-case where a workman worked for five hours in clothes on to
-which aniline had spurted when opening an iron drum. Similar
-cases are described in the report of the English factory
-inspectors for the same year. Aniline black dyeing frequently
-gives rise to poisoning, and to this Dearden<a href="#endnote109" id="endnote-ref109"><span class="endnote-marker">9</span></a> of Manchester
-especially has called attention.</p>
-
-<p>Typical aniline poisoning occurred in Bohemia in 1908
-in a cloth presser working with black dyes. While crushing
-aniline hydrochloride with one hand, he ate his food with the
-other. That the health of persons employed in aniline black
-dyeing must be affected by their work is shown by medical
-examination. For instance, the English medical inspector of
-factories in the summer months of 1905 found among sixty
-persons employed in mixing, preparing, and ageing 47 per cent.
-with greyish coloration of lips and 57 per cent. characteristically
-anæmic. Further, of eighty-two persons employed in padding,
-washing, and drying, 34 per cent. had grey lips, 20 per cent.
-were anæmic, and 14 per cent. with signs of acute or old effects
-of chrome ulceration. Gastric symptoms were not infrequently
-complained of. The symptoms were worse in hot
-weather.</p>
-
-<p>Use of aniline in other industries may lead to poisoning.
-Thus in the extraction of foreign resins with aniline seventeen
-workers suffered (eleven severely). Interesting cases of
-poisoning in a laundry from use of a writing ink containing
-aniline have been recorded.<a href="#endnote110" id="endnote-ref110"><span class="endnote-marker">10</span></a> </p>
-
-<p>Reference is necessary to tumours of the bladder observed
-in aniline workers. The first observations on the subject were
-made by Rehn of Frankfurt, who operated in three cases.
-Bachfeld of Offenbach noticed in sixty-three cases of aniline
-poisoning bladder affections in sixteen. Seyberth described
-five cases of tumours of the bladder in workers with long<span class="pagenum"><a name="Page_118" id="Page_118">[118]</a></span>
-duration of employment in aniline factories.<a href="#endnote111" id="endnote-ref111"><span class="endnote-marker">11</span></a> In the Höchst
-factory (and credit is due to the management for the step)
-every suspicious case is examined with the cystoscope. In
-1904 this firm collected information from eighteen aniline
-factories which brought to light thirty-eight cases, of which
-eighteen ended fatally. Seventeen were operated on, and of
-these eleven were still alive although in three there had been
-recurrence.</p>
-
-<p>Tumours were found mostly in persons employed with
-aniline, naphthylamine, and their homologues, but seven
-were in men employed with benzidine.</p>
-
-<p>Cases of benzene and toluidine poisoning in persons
-superintending tanks and stills have been described.</p>
-
-<p>Industrial paranitraniline poisoning has been described, and
-a fatal case in the Höchst dye works was attributed by Lewin
-(as medical referee) to inhalation of dust. Before his death
-the workman had been engaged for five hours in hydro-extracting
-paranitraniline.</p>
-
-<p>Paraphenylene diamine leads not unfrequently to industrial
-poisoning from use of ursol as a dye. It produces skin eruptions
-and inflammation of the mucous membrane of the
-respiratory passages.<a href="#endnote112" id="endnote-ref112"><span class="endnote-marker">12</span></a> No doubt the intermediate body
-produced (diimine) acts as a powerful poison.</p>
-
-<p>A case of metaphenylene diamine poisoning is quoted
-in the Report of the Union of Chemical Industry for 1906.
-A worker had brought his coffee and bread, contrary to the
-rules, into the workroom and hidden them under a vessel containing
-the substance. Immediately after drinking his coffee
-he was seized with poisoning symptoms, and died a few days
-later. Some of the poison must have dropped into his coffee.</p>
-
-<p>Few instances of poisoning from pure aniline colours are
-recorded.</p>
-
-<p>At first all tar colours were looked upon as poisonous, but
-as they were mostly triphenylmethane colours they would
-contain arsenious acid. When the arsenic process was given
-up people fell into the other extreme of regarding not only
-the triphenylmethane colours but all others as non-poisonous,
-until experience showed that production and use of some of
-the tar colours might affect the skin.</p>
-
-<p><span class="pagenum"><a name="Page_119" id="Page_119">[119]</a></span></p>
-
-<p>Finally, mention must be made of inflammation of the
-cornea caused by methyl violet dust. The basic aniline
-dyes are said to damage the eye. As opposed to this view is
-the fact that methyl violet and auramine are used as anti-bactericidal
-agents, for treatment of malignant tumours, and
-especially in ophthalmic practice.</p>
-
-<p><span class="pagenum"><a name="Page_120" id="Page_120">[120]</a></span></p>
-
-<h3 id="II_SMELTING_OF_METALS">II. SMELTING OF METALS</h3>
-
-<h4>LEAD (ZINC, SILVER)</h4>
-
-<h5>OCCURRENCE OF INDUSTRIAL LEAD POISONING IN GENERAL</h5>
-
-<p><i>Chronic lead poisoning</i> plays the most important rôle in
-industrial metallic poisoning, and indeed in industrial poisoning
-generally. The result everywhere where inquiry into industrial
-poisoning has been instituted has been to place the number
-of cases of lead poisoning at the top of the list; for one case
-of other forms of industrial poisoning there are twenty of
-lead.</p>
-
-<p>In the last few years a very extensive literature and one
-not easily to be surveyed has grown up on the subject of
-chronic industrial lead poisoning. I cannot attempt as I have
-done with other forms of poisoning to do justice to all sources
-of literature on this subject.</p>
-
-<p>As there is no obligation to notify industrial lead
-poisoning<a name="FNanchor_2" id="FNanchor_2"></a><a href="#Footnote_2" class="fnanchor">[B]</a>—or indeed any form of industrial poisoning—in
-many countries, the most important source of information
-is wanting. Nevertheless more or less comprehensive
-inquiries as to the extent of the disease in general have been
-made in different countries and large cities which furnish
-valuable data.</p>
-
-<p>An idea of the yearly number of cases of lead poisoning
-occurring in Prussia is given in the following statistics of cases
-treated in Prussian hospitals for the years 1895-1901:</p>
-
-<p><span class="pagenum"><a name="Page_121" id="Page_121">[121]</a></span></p>
-
-<table summary="Yearly number of cases of lead poisoning in Prussia" class="borders">
-  <tr>
-    <th>Year.</th>
-    <th>Males.</th>
-    <th>Females.</th>
-    <th>Total.</th>
-  </tr>
-  <tr>
-    <td>1895</td>
-    <td class="tdr">1120</td>
-    <td class="tdr">43</td>
-    <td class="tdr">1163</td>
-  </tr>
-  <tr>
-    <td>1899</td>
-    <td class="tdr">1601</td>
-    <td class="tdr">23</td>
-    <td class="tdr">1624</td>
-  </tr>
-  <tr>
-    <td>1900</td>
-    <td class="tdr">1509</td>
-    <td class="tdr">14</td>
-    <td class="tdr">1523</td>
-  </tr>
-  <tr>
-    <td class="bb">1901</td>
-    <td class="tdr bb">1359</td>
-    <td class="tdr bb">24</td>
-    <td class="tdr bb">1383</td>
-  </tr>
-</table>
-
-<p>The occupation of these cases was as follows:</p>
-
-<table summary="Occupation of the cases in the previous table" class="borders">
-  <tr>
-    <th>Year.</th>
-    <th>Metallic Lead.</th>
-    <th>White Lead.</th>
-    <th>Painters.</th>
-  </tr>
-  <tr>
-    <td>1895</td>
-    <td class="tdr">364</td>
-    <td class="tdr">312</td>
-    <td class="tdr">347</td>
-  </tr>
-  <tr>
-    <td>1899</td>
-    <td class="tdr">551</td>
-    <td class="tdr">310</td>
-    <td class="tdr">460</td>
-  </tr>
-  <tr>
-    <td>1900</td>
-    <td class="tdr">516</td>
-    <td class="tdr">360</td>
-    <td class="tdr">378</td>
-  </tr>
-  <tr>
-    <td class="bb">1901</td>
-    <td class="tdr bb">498</td>
-    <td class="tdr bb">282</td>
-    <td class="tdr bb">339</td>
-  </tr>
-</table>
-
-<p>About half the cases, therefore, are caused by use of white
-lead. The report of the sick insurance societies of the Berlin
-painters gives information as to the proportion treated in
-hospital to those treated at home, which was as 1:4.</p>
-
-<p>The industries may be classified according to risk as
-follows<a href="#endnote113" id="endnote-ref113"><span class="endnote-marker">1</span></a> :</p>
-
-<p>White lead workers, 33 per cent.; red lead workers, 32 per
-cent.; shot and lead pipe workers, 20 per cent.; painters,
-7-10 per cent.; lead and zinc smelters, 8-9 per cent.; printers,
-0·5 per cent.</p>
-
-<p>In Austria through the Labour Statistical Bureau comprehensive
-information is being collected as to the occurrence of
-lead poisoning in the most dangerous trades, but is not yet
-published. The reports of the factory inspectors give a very
-incomplete picture; for example, in 1905 only fifteen cases are
-referred to. In the most recent report (1909) information of
-lead poisoning is only given for thirty works. Teleky has
-made a general survey of the occurrence of lead poisoning
-from the reports of the Austrian sick insurance societies.<a href="#endnote114" id="endnote-ref114"><span class="endnote-marker">2</span></a>
-From this we gather that in Vienna, with an average
-membership of 200,000, there were, in the five year period
-1902-6, 634, 656, 765, 718, 772 cases of illness involving
-incapacity from mineral poisons, which Teleky assumes were
-practically all cases of lead poisoning. By circularising
-Austrian sick insurance societies outside Vienna with a<span class="pagenum"><a name="Page_122" id="Page_122">[122]</a></span>
-membership of about 400,000, Teleky obtained information
-of 189 cases, which he considers too few.</p>
-
-<p>In 1906-1908 inquiry was made by the sick insurance
-societies in Bohemia as to the extent of lead poisoning. With
-an average number employed of from 700,000 to 850,000 information
-was obtained of 91, 147, and 132 cases in the three years
-in question. The increase in 1907 was probably accounted for
-by the greater attention paid to the subject.<a href="#endnote115" id="endnote-ref115"><span class="endnote-marker">3</span></a> The number of
-ascertained cases of lead poisoning treated by the societies
-of Hungary was 225 in 1901 and 161 in 1902. Teleky again
-considers these figures too low, which is proved by Toth’s
-publications as to lead poisoning in Hungarian lead smelting
-works, and especially Chyzer’s on lead poisoning among
-Hungarian potters. Legge has reported fully in the second
-International Congress for Industrial Diseases in Brussels
-(September 1910) on occurrence of industrial lead poisoning in
-Great Britain in the years 1900 to 1909. During that period
-6762 cases with 245 deaths occurred. The number of cases in
-the course of the ten years had diminished by 50 per cent.
-These figures appear remarkably small, but it has to be borne
-in mind that the statistics referred to related only to cases
-occurring in factories and workshops, and do not include cases
-among house painters and plumbers. The number of such
-cases which came to the knowledge of the Factory Department
-in 1909 was 241 (with 47 deaths) and 239 in 1908 (with
-44 deaths).</p>
-
-<h5>LEAD, SILVER, AND ZINC SMELTING</h5>
-
-<p><i>Lead</i> is obtained almost entirely from galena by three
-different processes. In the <i>roast and reaction process</i> galena
-is first roasted at 500°-600° C. and partially converted into
-lead oxide and lead sulphate: on shutting off the air supply
-and increase of temperature the sulphur of the undecomposed
-galena unites with the oxygen of the lead oxide and sulphate to
-form sulphur dioxide, while the reduced metallic lead is tapped.
-In the <i>roast and reduction</i> process the ore is completely calcined
-so as to get rid of sulphur, arsenic, and antimony. The oxides
-(and sulphates) formed are reduced by means of coke in a blast
-furnace. This process is generally applicable and is, therefore,
-that most in use. The <i>precipitation</i> process consists chiefly in
-melting galena with coke and iron flux, whereby the lead is
-partly freed from the sulphur, and, in addition to lead, iron
-sulphide is formed, which acts on the remaining lead sulphide,
-producing a lead matte which can be further treated.</p>
-
-<p><span class="pagenum"><a name="Page_123" id="Page_123">[123]</a></span></p>
-
-<div class="figcenter" style="width: 500px;" id="fig27">
-
-<img src="images/fig27.jpg" width="500" height="700" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 27.</span>—Smelting Furnace, showing mechanical charging and exhaust ventilation
-applied to slag runs, &amp;c. (<i>Locke, Lancaster &amp; W. W. &amp; R. Johnson &amp;
-Sons, Ltd. By permission of the Controller of H.M. Stationery Office.</i>)</p>
-
-</div>
-
-<p><span class="pagenum"><a name="Page_124" id="Page_124">[124]</a></span></p>
-
-<p>The roast and reaction process is carried out in specially
-constructed reverberatory furnaces; small furnaces with small
-amounts of ore and at as low a temperature as possible are the
-rule in the Kärntner process. In the English process large
-amounts of ore are melted in large furnaces at high temperatures
-so as to oxidise the material. The so-called Tarnowitz process
-combines these two—large amounts of ore are roasted in
-large furnaces at a moderate temperature. In the roast and
-reduction process it depends on the nature of the ore whether
-the roasting is done in reverberatory or blast furnaces.
-Generally the ore is in the form of powder—less often in pieces.
-Pyritic ore (ore with much sulphur) is almost always roasted in
-blast furnaces, and the sulphur dioxide evolved can be used in
-the manufacture of sulphuric acid. Open-hearth furnaces are
-rarely used now. Reverberatory furnaces are employed most
-frequently.</p>
-
-<p>The lead thus obtained contains several other metals,
-especially silver, copper, arsenic, antimony, iron, zinc, bismuth,
-and tin. Lead containing silver (work-lead) is next <i>de-silverised</i>,
-after which follows refining to get rid of the other impurities.
-For de-silverising work-lead rich in silver (containing about
-10 per cent.) <i>cupellation</i> is practised, in which the silver lead is
-melted and oxidised so that the lead is converted into <i>litharge</i>,
-metallic silver remaining behind. In a cupellation furnace
-the flame strikes on the top of the lead bath, and at the same
-time air under slight pressure is driven in; the litharge which
-forms is removed through suitable openings. The litharge
-that is first formed contains silver and is treated again; the
-remainder is ready for market. After the litharge has run
-off silver appears, containing still 5-10 per cent. of lead,
-and it is again submitted to an analogous refining process.
-Work-lead which does not contain enough silver to be
-cupelled at once is generally treated first by either the
-Pattinson or the Parkes’ process.</p>
-
-<p>In the <i>Pattinson</i> crystallising process work-lead is melted in<span class="pagenum"><a name="Page_125" id="Page_125">[125]</a></span>
-open semi-circular pots: as the pots cool crystals of lead poor
-in silver form on the surface and are transferred by a perforated
-ladle into the next pot: the silver collects in the small amount
-of molten lead remaining behind. Lead that has become
-enriched by repeated crystallisation contains a high percentage
-of silver and is cupelled. The <i>Parkes’</i> process or <i>zinc
-de-silverisation</i> depends on the formation of a lead-zinc alloy
-which is less fusible than lead. Work-lead is melted and
-agitated with addition of pure zinc. The crust which first
-rises on cooling contains gold, copper, zinc, and lead, and
-is removed. Further addition of zinc is then made: the
-rich silver crust which separates is subsequently freed from
-lead by gradual heating in a reverberatory furnace, and from
-zinc, in a zinc distilling retort. Other impurities are got rid
-of by oxidising in reverberatory or other furnaces. Small
-quantities of antimony and arsenic are removed by stirring with
-fresh green sticks.</p>
-
-<p><i>Zinc</i> is obtained principally from blende (sulphide of zinc)
-and from calamine (carbonate of zinc). The process of zinc
-recovery depends on the production of zinc oxide and reduction
-of this by carbon to metallic zinc.</p>
-
-<p>Conversion of the ore to zinc oxide is effected by roasting.
-Since the temperature at which reduction takes place is higher
-than the melting-point of zinc the latter is volatilised (distilled)
-and must be condensed in suitable condensers.</p>
-
-<p>Calamine is calcined in a blast furnace. Blende was
-formerly roasted in reverberatory furnaces, but such nuisance
-arose to the neighbourhood from sulphur dioxide vapour
-that now Hasenclever-Helbig calcining furnaces are used.
-These furnaces furnish a gas so rich in sulphur dioxide that
-they serve at once for the production of sulphuric acid. The
-Hasenclever furnaces consist of muffles placed one above
-another: the finely ground ore is charged through hoppers
-above and then raked down from muffle to muffle.</p>
-
-<p>Reduction is carried out in the Belgian or Silesian process
-by strongly heating calcined matte with coal in retorts. The
-zinc as it distils is caught in special condensing receptacles
-(prolongs). After distillation is complete the residue is raked
-out of the muffle and the furnace charged afresh. As zinc ores
-generally contain much lead, the work-zinc is therefore refined<span class="pagenum"><a name="Page_126" id="Page_126">[126]</a></span>
-by remelting in a reverberatory furnace, during which process
-the impurities collect on the zinc as dross and are removed by
-agitation with sal-ammoniac or magnesium chloride.</p>
-
-<div class="figcenter" style="width: 500px;" id="fig28">
-
-<img src="images/fig28.jpg" width="500" height="500" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 28.</span>—Arrangement of Spelter Furnace showing Ventilating Hood.</p>
-
-</div>
-
-<p><span class="smcap">Risk of Poisoning in Lead, Silver, and Zinc Smelting.</span>—As
-the description of the manipulations in smelting
-processes shows, all involve risk of lead poisoning. As a matter
-of fact in lead smelting much lead passes into the atmosphere.
-In the smelting works at Tarnowitz yearly some 36,000 kilos
-of oxidised lead escape.</p>
-
-<p>Estimations<a href="#endnote116" id="endnote-ref116"><span class="endnote-marker">4</span></a> of the amount of lead in air samples collected
-in lead smelting works have been made. Thus in a cubic
-metre of air immediately over the slag run from 0·0029 to<span class="pagenum"><a name="Page_127" id="Page_127">[127]</a></span>
-0·0056 g. of lead were found, so that a worker in a ten-hour
-day would inhale from 0·013 to 0·025 g. of lead. In a
-cubic metre of air immediately above the Parkes’ melting-pot
-from 0·0056 to 0·0090 g. were found, so that a worker would
-inhale daily from 0·0252 to 0·0405 g. if he kept constantly
-close to the pot. On the handles of a de-silveriser 0·112 g.
-were found. In Hungarian lead-smelting works the water in
-which the hands had been washed was found to contain
-1·27 g. of lead per litre. The hands of litharge grinders
-and sifters showed the highest amounts.</p>
-
-<p>Work carried on in lead-smelting works may be divided
-into five classes according to risk. Those most exposed to risk
-are the smelters at lead hearths and reverberatory furnaces,
-persons employed at the lead and slag runs, flue cleaners, and
-in crushing and packing flake litharge. Next come those
-employed at the refining furnaces, those breaking up the
-roasted ore, blast furnace workers, and those employed at the
-cupellation process. Attended with danger also is the removal
-of lead ashes and distillation of the zinc crust. Less dangerous
-are transport of material, crushing and mixing the ore, refining
-the work-lead and zinc crust, and work at the Pattinson
-and Parkes’ processes.</p>
-
-<p>In zinc smelting risk of lead poisoning is great, no matter
-which process is in question, because of the high proportion of
-lead in the ore and work-zinc. Swedish blende contains as
-much as 9 per cent. of lead, and Upper Silesian 2½ per cent. or
-less. There is risk in calcination, but it is much less than in
-the distillation process.<a href="#endnote117" id="endnote-ref117"><span class="endnote-marker">5</span></a> </p>
-
-<p>There are no quite satisfactory statistics as to the number
-of cases of lead poisoning in smelting works. Nevertheless,
-a number of recent publications give valuable
-data for certain smelting works in Germany, Austria, and
-Hungary.</p>
-
-<p>From details<a href="#endnote118" id="endnote-ref118"><span class="endnote-marker">6</span></a> of lead poisoning at Tarnowitz it would
-appear that the conditions have materially improved since
-1884, the cases having declined from 32·7 per 100 employed in
-1884 to 6·2 in 1894 and 1895. The following figures show the
-proportion affected in the different processes in the years 1901
-and 1902:</p>
-
-<p><span class="pagenum"><a name="Page_128" id="Page_128">[128]</a></span></p>
-
-<table summary="Yearly number of cases of lead poisoning at Tarnowitz" class="borders">
-  <tr>
-    <th colspan="2">Process.</th>
-    <th>Year.</th>
-    <th>No. Employed.</th>
-    <th>Cases.</th>
-    <th>Per Cent.</th>
-  </tr>
-  <tr>
-    <td class="valign" rowspan="2">Reverberatory Furnace</td>
-    <td class="nbl">{</td>
-    <td>1901</td>
-    <td class="tdr">131</td>
-    <td class="tdr">11</td>
-    <td class="tdr">8·3</td>
-  </tr>
-  <tr>
-    <td class="nbl">{</td>
-    <td>1902</td>
-    <td class="tdr">111</td>
-    <td class="tdr">4</td>
-    <td class="tdr">3·6</td>
-  </tr>
-  <tr>
-    <td class="valign" rowspan="2">Blast Furnace</td>
-    <td class="nbl">{</td>
-    <td>1901</td>
-    <td class="tdr">152</td>
-    <td class="tdr">47</td>
-    <td class="tdr">30·9</td>
-  </tr>
-  <tr>
-    <td class="nbl">{</td>
-    <td>1902</td>
-    <td class="tdr">187</td>
-    <td class="tdr">21</td>
-    <td class="tdr">11·1</td>
-  </tr>
-  <tr>
-    <td class="valign" rowspan="2">Cupelling Furnace</td>
-    <td class="nbl">{</td>
-    <td>1901</td>
-    <td class="tdr">12</td>
-    <td class="tdr">1</td>
-    <td class="tdr">8·3</td>
-  </tr>
-  <tr>
-    <td class="nbl">{</td>
-    <td>1902</td>
-    <td class="tdr">12</td>
-    <td class="tdr">1</td>
-    <td class="tdr">8·3</td>
-  </tr>
-  <tr>
-    <td class="valign" rowspan="2">De-silverising</td>
-    <td class="nbl">{</td>
-    <td>1901</td>
-    <td class="tdr">32</td>
-    <td class="tdr">10</td>
-    <td class="tdr">31·2</td>
-  </tr>
-  <tr>
-    <td class="nbl">{</td>
-    <td>1902</td>
-    <td class="tdr">34</td>
-    <td class="tdr">7</td>
-    <td class="tdr">20·6</td>
-  </tr>
-  <tr>
-    <td class="valign" rowspan="2">Other Employment</td>
-    <td class="nbl">{</td>
-    <td>1901</td>
-    <td class="tdr">300</td>
-    <td class="tdr">7</td>
-    <td class="tdr">2·3</td>
-  </tr>
-  <tr>
-    <td class="bb nbl">{</td>
-    <td class="bb">1902</td>
-    <td class="tdr bb">350</td>
-    <td class="tdr bb">2</td>
-    <td class="tdr bb">0·6</td>
-  </tr>
-</table>
-
-<p>In one smelting works the percentage attack rate was 17·8
-in 1901, and 27·1 in 1902. Here the number of workers had
-increased from 73 in 1901 to 129 in 1902, and the absolute and
-relative increase probably has relation to the well-known fact
-that newly employed untrained workers become affected.
-Similar incidence according to process can be given for the
-Friedrich’s smelting works during the years 1903-1905:</p>
-
-<table summary="Yearly number of cases of lead poisoning at Tarnowitz" class="borders">
-  <tr>
-    <th colspan="2">Process.</th>
-    <th>Year.</th>
-    <th>No. Employed.</th>
-    <th>Cases.</th>
-    <th>Per Cent.</th>
-  </tr>
-  <tr>
-    <td class="valign" rowspan="3">Reverberatory Furnace</td>
-    <td class="nbl">{</td>
-    <td>1903</td>
-    <td class="tdr">86</td>
-    <td class="tdr">12</td>
-    <td class="tdr">13·9</td>
-  </tr>
-  <tr>
-    <td class="nbl">{</td>
-    <td>1904</td>
-    <td class="tdr">87</td>
-    <td class="tdr">8</td>
-    <td class="tdr">9·2</td>
-  </tr>
-  <tr>
-    <td class="nbl">{</td>
-    <td>1905</td>
-    <td class="tdr">83</td>
-    <td class="tdr">11</td>
-    <td class="tdr">13·3</td>
-  </tr>
-  <tr>
-    <td class="valign" rowspan="3">Blast Furnace</td>
-    <td class="nbl">{</td>
-    <td>1903</td>
-    <td class="tdr">267</td>
-    <td class="tdr">59</td>
-    <td class="tdr">22·1</td>
-  </tr>
-  <tr>
-    <td class="nbl">{</td>
-    <td>1904</td>
-    <td class="tdr">232</td>
-    <td class="tdr">24</td>
-    <td class="tdr">10·3</td>
-  </tr>
-  <tr>
-    <td class="nbl">{</td>
-    <td>1905</td>
-    <td class="tdr">247</td>
-    <td class="tdr">27</td>
-    <td class="tdr">10·9</td>
-  </tr>
-  <tr>
-    <td class="valign" rowspan="3">De-silverising</td>
-    <td class="nbl">{</td>
-    <td>1903</td>
-    <td class="tdr">56</td>
-    <td class="tdr">12</td>
-    <td class="tdr">21·4</td>
-  </tr>
-  <tr>
-    <td class="nbl">{</td>
-    <td>1904</td>
-    <td class="tdr">73</td>
-    <td class="tdr">4</td>
-    <td class="tdr">5·5</td>
-  </tr>
-  <tr>
-    <td class="nbl">{</td>
-    <td>1905</td>
-    <td class="tdr">75</td>
-    <td class="tdr">4</td>
-    <td class="tdr">5·3</td>
-  </tr>
-  <tr>
-    <td class="valign" rowspan="3">Cupelling</td>
-    <td class="nbl">{</td>
-    <td>1903</td>
-    <td class="tdr">16</td>
-    <td class="tdr">4</td>
-    <td class="tdr">25·0</td>
-  </tr>
-  <tr>
-    <td class="nbl">{</td>
-    <td>1904</td>
-    <td class="tdr">15</td>
-    <td class="tdr">1</td>
-    <td class="tdr">6·7</td>
-  </tr>
-  <tr>
-    <td class="nbl">{</td>
-    <td>1905</td>
-    <td class="tdr">14</td>
-    <td class="tdr">1</td>
-    <td class="tdr">7·1</td>
-  </tr>
-  <tr>
-    <td class="valign" rowspan="3">Other Employment</td>
-    <td class="nbl">{</td>
-    <td>1903</td>
-    <td class="tdr">330</td>
-    <td class="tdr">5</td>
-    <td class="tdr">1·5</td>
-  </tr>
-  <tr>
-    <td class="nbl">{</td>
-    <td>1904</td>
-    <td class="tdr">309</td>
-    <td class="tdr">4</td>
-    <td class="tdr">1·3</td>
-  </tr>
-  <tr>
-    <td class="bb nbl">{</td>
-    <td class="bb">1905</td>
-    <td class="tdr bb">347</td>
-    <td class="tdr bb">7</td>
-    <td class="tdr bb">2·0</td>
-  </tr>
-</table>
-
-<p>Among 3028 cases of lead poisoning treated between 1853
-and 1882 in smelting works near Freiberg (Saxony) gastric
-symptoms were present in 1541, rheumatic pains in 215,
-cerebral symptoms in 144, paralysis in 58, and lead colic in 426.</p>
-
-<p>The recent reports of the German factory inspectors
-point still to rather high incidence in many lead smelting
-works. Thus in the district of Aix la Chapelle in 1909 there
-were sixty cases involving 1047 sick days, as compared with
-58 and 878 in 1908.</p>
-
-<p><span class="pagenum"><a name="Page_129" id="Page_129">[129]</a></span></p>
-
-<p>In a well-arranged smelting works near Wiesbaden fifty-two
-and forty-two cases were reported in 1908 and 1909 respectively,
-among about 400 persons employed. This relatively high
-number was believed to be closely connected with frequent
-change in the <i>personnel</i>. Introduction of the Huntingdon-Heberlein
-method is thought to have exercised an unfavourable
-influence.</p>
-
-<p>Other smelting works in Germany appear to have a relatively
-small number of reported cases. Thus in 1909 among
-550 workers employed in four smelting works in the Hildesheim
-district only four cases were reported, and in the district of
-Potsdam among 600 smelters only five were found affected on
-medical examination. There is no doubt that many of the
-cases described as gastric catarrh are attributable to lead.
-Full information as to the conditions in Austria is contained
-in the publication of the Imperial Labour Statistical Bureau.
-In this comprehensive work the conditions in smelting works
-are described. In the lead smelting works at Przibram the
-cases had dropped from an average of 38·2 among the 4000-5000
-persons employed to twenty-two in 1894 and to six in
-1903, but only the severer cases are included. No single case
-has occurred among the 350-450 persons engaged in mining
-the ore, as galena (lead sulphide) is practically non-poisonous.
-It was found, for example, that 50 per cent. of the furnace men
-had (according to their statement) suffered from lead colic.
-Of eight employed in the Pattinson process, seven stated they
-had suffered from colic. The lead smelting works in Gailitz
-showed marked frequency of lead poisoning—here the appointed
-surgeon attributed anæmia and gastric and intestinal catarrh
-to lead:</p>
-
-<table summary="Yearly number of cases of lead poisoning in Gailitz" class="borders">
-  <tr>
-    <th rowspan="2">Year.</th>
-    <th rowspan="2">No. Employed.</th>
-    <th rowspan="2">Lead Colic.</th>
-    <th colspan="3">Illness of Saturnine Origin.</th>
-    <th rowspan="2">Total Lead Sickness.</th>
-    <th rowspan="2">Total Sickness.</th>
-    <th rowspan="2">Per Cent. due to Lead.</th>
-  </tr>
-  <tr>
-    <th>Anæmia.</th>
-    <th>Gastric Catarrh.</th>
-    <th>Intestinal Catarrh.</th>
-  </tr>
-  <tr>
-    <td>1899</td>
-    <td class="tdr">61</td>
-    <td class="tdr">14</td>
-    <td class="tdr">2</td>
-    <td class="tdr">76</td>
-    <td class="tdr">16</td>
-    <td class="tdr">108</td>
-    <td class="tdr">178</td>
-    <td class="tdr">60·0</td>
-  </tr>
-  <tr>
-    <td>1900</td>
-    <td class="tdr">57</td>
-    <td class="tdr">6</td>
-    <td class="tdr">2</td>
-    <td class="tdr">16</td>
-    <td class="tdr">5</td>
-    <td class="tdr">29</td>
-    <td class="tdr">80</td>
-    <td class="tdr">36·2</td>
-  </tr>
-  <tr>
-    <td>1901</td>
-    <td class="tdr">48</td>
-    <td class="tdr">4</td>
-    <td class="tdr">2</td>
-    <td class="tdr">17</td>
-    <td class="tdr">1</td>
-    <td class="tdr">24</td>
-    <td class="tdr">60</td>
-    <td class="tdr">40·0</td>
-  </tr>
-  <tr>
-    <td>1902</td>
-    <td class="tdr">47</td>
-    <td class="tdr">—</td>
-    <td class="tdr">—</td>
-    <td class="tdr">24</td>
-    <td class="tdr">6</td>
-    <td class="tdr">30</td>
-    <td class="tdr">56</td>
-    <td class="tdr">53·5</td>
-  </tr>
-  <tr>
-    <td class="bb">1903</td>
-    <td class="tdr bb">49</td>
-    <td class="tdr bb">—</td>
-    <td class="tdr bb">3</td>
-    <td class="tdr bb">11</td>
-    <td class="tdr bb">4</td>
-    <td class="tdr bb">18</td>
-    <td class="tdr bb">57</td>
-    <td class="tdr bb">31·6</td>
-  </tr>
-</table>
-
-<p><span class="pagenum"><a name="Page_130" id="Page_130">[130]</a></span></p>
-
-<p>The diminution in the number of cases, especially of colic,
-is attributable to the efforts of the appointed surgeon.</p>
-
-<p>At Selmeczbanya a diminution from 196 cases in 1899
-(50·7 per cent.) to six (2·2 per cent.) in 1905 had taken place.
-These figures point clearly to the success of the hygienic
-measures adopted in the last few years.</p>
-
-<p>In the large spelter works of Upper Silesia during the years
-1896-1901, among 3780 persons employed, there were eighty-three
-cases of lead colic and paralysis, that is, about 2·2 per
-cent. each year. The following tables show the incidence
-among spelter workers in the works in question from 1902 to
-1905:</p>
-
-<p class="center"><span class="smcap">Illness among Zinc Smelters</span></p>
-
-<table summary="Yearly number of cases of lead poisoning in Upper Silesia" class="borders">
-  <tr>
-    <th>Year.</th>
-    <th>Lead Colic and Lead Paralysis.</th>
-    <th>Kidney Disease.</th>
-    <th>Gastric Catarrh.</th>
-    <th>Anæmia.</th>
-    <th>Rheumatism.</th>
-    <th>No. Employed.</th>
-  </tr>
-  <tr>
-    <td>1902</td>
-    <td class="tdr">29</td>
-    <td class="tdr">18</td>
-    <td class="tdr">137</td>
-    <td class="tdr">18</td>
-    <td class="tdr">448</td>
-    <td class="tdr">4417</td>
-  </tr>
-  <tr>
-    <td>1903</td>
-    <td class="tdr">28</td>
-    <td class="tdr">21</td>
-    <td class="tdr">151</td>
-    <td class="tdr">24</td>
-    <td class="tdr">470</td>
-    <td class="tdr">4578</td>
-  </tr>
-  <tr>
-    <td>1904</td>
-    <td class="tdr">44</td>
-    <td class="tdr">23</td>
-    <td class="tdr">181</td>
-    <td class="tdr">35</td>
-    <td class="tdr">596</td>
-    <td class="tdr">4677</td>
-  </tr>
-  <tr>
-    <td class="bb">1905</td>
-    <td class="tdr bb">50</td>
-    <td class="tdr bb">18</td>
-    <td class="tdr bb">223</td>
-    <td class="tdr bb">40</td>
-    <td class="tdr bb">612</td>
-    <td class="tdr bb">4789</td>
-  </tr>
-  <tr>
-    <td class="bb">Average</td>
-    <td class="tdr bb">0·8%</td>
-    <td class="tdr bb">0·5%</td>
-    <td class="tdr bb">3·7%</td>
-    <td class="tdr bb">0·6%</td>
-    <td class="tdr bb">11·5%</td>
-    <td class="tdr bb">4615</td>
-  </tr>
-</table>
-
-<p class="center"><span class="smcap">Illness among Calciners</span></p>
-
-<table summary="Yearly number of cases of lead poisoning in Upper Silesia" class="borders">
-  <tr>
-    <th>Year.</th>
-    <th>Lead Colic and Lead Paralysis.</th>
-    <th>Kidney Disease.</th>
-    <th>Gastric Catarrh.</th>
-    <th>Anæmia.</th>
-    <th>Rheumatism.</th>
-    <th>No. Employed.</th>
-  </tr>
-  <tr>
-    <td>1902</td>
-    <td class="tdr">—</td>
-    <td class="tdr">—</td>
-    <td class="tdr">5</td>
-    <td class="tdr">1</td>
-    <td class="tdr">78</td>
-    <td class="tdr">1149</td>
-  </tr>
-  <tr>
-    <td>1903</td>
-    <td class="tdr">—</td>
-    <td class="tdr">—</td>
-    <td class="tdr">9</td>
-    <td class="tdr">—</td>
-    <td class="tdr">112</td>
-    <td class="tdr">1087</td>
-  </tr>
-  <tr>
-    <td>1904</td>
-    <td class="tdr">2</td>
-    <td class="tdr">—</td>
-    <td class="tdr">68</td>
-    <td class="tdr">1</td>
-    <td class="tdr">136</td>
-    <td class="tdr">1140</td>
-  </tr>
-  <tr>
-    <td class="bb">1905</td>
-    <td class="tdr bb">1</td>
-    <td class="tdr bb">2</td>
-    <td class="tdr bb">47</td>
-    <td class="tdr bb">2</td>
-    <td class="tdr bb">134</td>
-    <td class="tdr bb">1159</td>
-  </tr>
-  <tr>
-    <td class="bb">Average</td>
-    <td class="tdr bb">0·08%</td>
-    <td class="tdr bb">0·05%</td>
-    <td class="tdr bb">2·6%</td>
-    <td class="tdr bb">0·1%</td>
-    <td class="tdr bb">10·2%</td>
-    <td class="tdr bb">1134</td>
-  </tr>
-</table>
-
-<p>In thirty-two spelter works in the district of Oppeln in the
-year 1905, among 4789 spelter workers proper, there were
-50 cases of colic, 18 of kidney disease, 223 of gastric and
-intestinal catarrh, 40 of anæmia, and 612 of rheumatism, and
-among 1159 calciners 1 case of colic, 2 of kidney disease,
-47 of gastric catarrh, 2 of anæmia, and 134 of rheumatism.
-Cases are much more numerous in spelter works where<span class="pagenum"><a name="Page_131" id="Page_131">[131]</a></span>
-Swedish blende containing lead is worked. It is remarkable,
-however, that in large spelter works in Upper Silesia, where
-for years no cases of lead poisoning were reported, medical
-examination showed that 20·5 per cent. had signs of lead
-absorption.</p>
-
-<h5>White Lead and Lead Colours</h5>
-
-<p><span class="smcap">Manufacture.</span>—The primitive Dutch process consisted in
-placing lead grids in earthenware pots containing dilute
-acetic acid and covering them with tan bark. Fermentation
-ensued with evolution of carbonic acid gas and increase in
-temperature. The acetic acid vapour forms, with aid of
-atmospheric oxygen, first basic lead acetate, which, by the
-action of the carbonic acid gas, becomes converted into white
-lead and neutral lead acetate. The product is crushed, sieved,
-and dried. In the German or Austrian process thin sheets of
-metallic lead are hung saddle-wise in chambers. Acetic acid
-vapour and carbonic acid gas (produced by burning coke)
-are led in from below. The chamber is then sealed and kept
-so for a considerable time. When the chamber is ‘ripe’ the
-white lead that has formed is taken out, freed from uncorroded
-lead by spraying, dried, finely ground, and packed. White
-lead comes on the market either as a powder or incorporated
-with oil. Of the remaining lead colours, red lead (Pb₃O₄) is
-much used. It is produced by heating lead oxide in reverberatory
-furnaces with access of air and stirring.</p>
-
-<h5>Lead Poisoning in the Manufacture of White Lead and
-Lead Colours</h5>
-
-<p>The manufacture by the German process may be divided
-into three categories according to the degree of risk run:</p>
-
-<p>1. The most dangerous processes are hanging the plates
-in the chambers, work at the filter press, drying, pulverising,
-and packing by hand.</p>
-
-<p>2. Less dangerous are transport to the washer, washing, and
-grinding.</p>
-
-<p>3. Relatively the least dangerous are casting the plates,<span class="pagenum"><a name="Page_132" id="Page_132">[132]</a></span>
-transport of them to the chambers, drying, mechanical packing,
-and mixing with oil.</p>
-
-<p>The number of cases of lead poisoning in white lead factories
-is often relatively great despite regulations. Casual labourers
-especially run the greatest risk. This is frequently brought
-out in the reports of the German factory inspectors, who
-connect the high proportion of cases directly with the large
-number of unskilled workers. Regulations are really only
-successful in factories with regular employment.</p>
-
-<p>This has been found also in Great Britain, where the Medical
-Inspector of Factories showed that the cases among regular
-workers numbered 6 per cent. and among casual workers
-39 per cent.</p>
-
-<p>The following table gives particulars as to the occurrence of
-lead poisoning in the white lead factories in the district of
-Cologne in 1904, some of which have admirable hygienic
-arrangements:</p>
-
-<table summary="Cases of lead poisoning in Cologne in 1904" class="borders">
-  <tr>
-    <th rowspan="2">Place.</th>
-    <th rowspan="2" colspan="2">Manufacture.</th>
-    <th colspan="3">No. Employed.</th>
-    <th colspan="3">Cases of Lead Poisoning.</th>
-    <th rowspan="2">No. of Cases of Gastric Catarrh.</th>
-  </tr>
-  <tr>
-    <th>Regular</th>
-    <th>Casual</th>
-    <th>Average</th>
-    <th>Regular</th>
-    <th>Casual</th>
-    <th>Total</th>
-  </tr>
-  <tr>
-    <td rowspan="2" class="valign nw">Cologne I.</td>
-    <td rowspan="2" class="valign">White lead</td>
-    <td class="nbl">{</td>
-    <td class="tdr">46</td>
-    <td class="tdr">59</td>
-    <td class="tdr">32</td>
-    <td class="tdr">9</td>
-    <td class="tdr">16</td>
-    <td class="tdr">25</td>
-    <td class="tdr">16</td>
-  </tr>
-  <tr>
-    <td class="nbl">{</td>
-    <td class="tdr">173</td>
-    <td class="tdr">95</td>
-    <td class="tdr">127</td>
-    <td class="tdr">13</td>
-    <td class="tdr">17</td>
-    <td class="tdr">30</td>
-    <td class="tdr">22</td>
-  </tr>
-  <tr>
-    <td rowspan="2" class="valign nw"><span class="ditto">”</span> I.</td>
-    <td rowspan="2" class="valign">Litharge and red lead</td>
-    <td class="nbl">{</td>
-    <td class="tdr">46</td>
-    <td class="tdr">4</td>
-    <td class="tdr">38</td>
-    <td class="tdr">5</td>
-    <td class="tdr">1</td>
-    <td class="tdr">6</td>
-    <td class="tdr">7</td>
-  </tr>
-  <tr>
-    <td class="nbl">{</td>
-    <td class="tdr">76</td>
-    <td class="tdr">62</td>
-    <td class="tdr">49</td>
-    <td class="tdr">3</td>
-    <td class="tdr">4</td>
-    <td class="tdr">7</td>
-    <td class="tdr">15</td>
-  </tr>
-  <tr>
-    <td rowspan="2" class="valign nw"></td>
-    <td rowspan="2" class="valign">Chromate</td>
-    <td class="nbl">{</td>
-    <td class="tdr">14</td>
-    <td class="tdr">2</td>
-    <td class="tdr">11</td>
-    <td class="tdr">—</td>
-    <td class="tdr">—</td>
-    <td class="tdr">—</td>
-    <td class="tdr">5</td>
-  </tr>
-  <tr>
-    <td class="nbl">{</td>
-    <td class="tdr">43</td>
-    <td class="tdr">72</td>
-    <td class="tdr">33</td>
-    <td class="tdr">—</td>
-    <td class="tdr">—</td>
-    <td class="tdr">—</td>
-    <td class="tdr">7</td>
-  </tr>
-  <tr>
-    <td rowspan="2" class="valign nw">Cologne II.</td>
-    <td rowspan="2" class="valign">White lead, litharge, and red lead</td>
-    <td class="nbl">{</td>
-    <td class="tdr">107</td>
-    <td class="tdr">332</td>
-    <td class="tdr">91</td>
-    <td class="tdr">6</td>
-    <td class="tdr">34</td>
-    <td class="tdr">40</td>
-    <td class="tdr">30</td>
-  </tr>
-  <tr>
-    <td class="nbl bb">{</td>
-    <td class="tdr bb">102</td>
-    <td class="tdr bb">332</td>
-    <td class="tdr bb">76</td>
-    <td class="tdr bb">9</td>
-    <td class="tdr bb">19</td>
-    <td class="tdr bb">28</td>
-    <td class="tdr bb">38</td>
-  </tr>
-</table>
-
-<p>It is worth noting that cases of lead poisoning have been
-reported in the manufacture of zinc white, as, for example, in
-Bohemia in 1907 and 1908.</p>
-
-<h5>USE OF LEAD COLOURS AND PAINTS (HOUSE PAINTERS,
-DECORATORS, ETC.)</h5>
-
-<p>Use of lead colours, especially by painters and decorators,
-causes relatively much lead poisoning. Apart from ignorance
-of danger on the part of the worker, and lack of personal
-cleanliness, unsuitable methods of working add to the danger,<span class="pagenum"><a name="Page_133" id="Page_133">[133]</a></span>
-especially dry rubbing of painted surfaces, which gives rise to
-much dust containing lead. Again, the crushing and mixing
-of lumps of white lead and rubbing lead colours with the
-hand are very dangerous.</p>
-
-<p>The following German and Austrian figures enable conclusions
-to be drawn as to the frequency of lead poisoning among
-painters. In the sick insurance societies of Frankfurt-a-M.
-in 1903 of every 100 painters 11·6 suffered from an attack of
-lead poisoning. The similar sick insurance society of painters
-in Berlin has kept useful statistics which are given in the
-following table for the ten years 1900-9:</p>
-
-<table summary="Cases of lead poisoning in Frankfurt-am-Main" class="borders">
-  <tr>
-    <th>Year.</th>
-    <th>No. of Members.</th>
-    <th>No. of<br />Cases of<br />Lead Poisoning.</th>
-    <th>Cases per<br />100 Members.</th>
-  </tr>
-  <tr>
-    <td>1900</td>
-    <td class="tdr">3889</td>
-    <td class="tdr">357&nbsp;&nbsp;</td>
-    <td class="tdr">9·18</td>
-  </tr>
-  <tr>
-    <td>1901</td>
-    <td class="tdr">3616</td>
-    <td class="tdr">335&nbsp;&nbsp;</td>
-    <td class="tdr">9·26</td>
-  </tr>
-  <tr>
-    <td>1902</td>
-    <td class="tdr">3815</td>
-    <td class="tdr">308&nbsp;&nbsp;</td>
-    <td class="tdr">8·07</td>
-  </tr>
-  <tr>
-    <td>1903</td>
-    <td class="tdr">4397</td>
-    <td class="tdr">470&nbsp;&nbsp;</td>
-    <td class="tdr">10·69</td>
-  </tr>
-  <tr>
-    <td>1904</td>
-    <td class="tdr">5029</td>
-    <td class="tdr">516&nbsp;&nbsp;</td>
-    <td class="tdr">10·26</td>
-  </tr>
-  <tr>
-    <td>1905</td>
-    <td class="tdr">5328</td>
-    <td class="tdr">471&nbsp;&nbsp;</td>
-    <td class="tdr">8·84</td>
-  </tr>
-  <tr>
-    <td>1906</td>
-    <td class="tdr">5355</td>
-    <td class="tdr">347&nbsp;&nbsp;</td>
-    <td class="tdr">6·48</td>
-  </tr>
-  <tr>
-    <td>1907</td>
-    <td class="tdr">5173</td>
-    <td class="tdr">379&nbsp;&nbsp;</td>
-    <td class="tdr">7·32</td>
-  </tr>
-  <tr>
-    <td>1908</td>
-    <td class="tdr">4992</td>
-    <td class="tdr">298&nbsp;&nbsp;</td>
-    <td class="tdr">5·97</td>
-  </tr>
-  <tr>
-    <td class="bb">1909</td>
-    <td class="tdr bb">4781</td>
-    <td class="tdr bb">285&nbsp;&nbsp;</td>
-    <td class="tdr bb">5·96</td>
-  </tr>
-  <tr>
-    <td class="bb">Average</td>
-    <td class="tdr bb">4637</td>
-    <td class="tdr bb">376·6</td>
-    <td class="tdr bb"> 8·11</td>
-  </tr>
-</table>
-
-<p>This shows that lead poisoning among the painters of
-Berlin is happily diminishing, which may be attributed to
-recent regulations. The society, however, complains in its
-reports that not all cases of lead appear as such in their statistics,
-and believes that all diseases entered as rheumatism, gastric
-catarrh, nervous complaints, heart and kidney disease, should
-be regarded as associated with lead. The kinds of work in
-which painters suffer most are painting iron girders and
-machines, sheet metal and iron furniture, railway waggons,
-agricultural implements, coach painting, cabinet-making, shipbuilding,
-and the use of red and white lead. The use of
-lead colours, <i>lead acetate</i>, and <i>lead chromate</i> often give rise to
-lead poisoning. Colours containing lead are not infrequently
-used in the textile industry in dyeing, printing, and finishing.
-White lead has been used for weighting the weft.</p>
-
-<p><span class="pagenum"><a name="Page_134" id="Page_134">[134]</a></span></p>
-
-<p>Teleky has described cases of lead poisoning in which <i>silk
-thread</i> was weighted with acetate of lead. As a consequence
-a number of women engaged in sewing on fringes with the
-thread suffered. The English factory inspectors’ reports
-describe cases from manipulating <i>yarn dyed with chromate of
-lead</i>.<a href="#endnote119" id="endnote-ref119"><span class="endnote-marker">7</span></a> </p>
-
-<p><i>Chromate of lead</i> and <i>white lead</i> are used in colouring oil-cloth,
-artificial flowers, paper, rubber goods, pencils, penholders,
-socks, sealing-wax, candles, and stamps.</p>
-
-<h5>USE OF LEAD IN THE CHEMICAL INDUSTRY</h5>
-
-<p>Lead poisoning has been frequently observed in such
-branches of the chemical industry as require large leaden or
-lead-lined vessels and pipes: the persons affected are principally
-those engaged in lead burning.</p>
-
-<p>Risk is considerable in manufacture of lead acetate. The
-most dangerous processes are drying and packing the crystals.</p>
-
-<h4>MANUFACTURE OF ELECTRIC ACCUMULATORS</h4>
-
-<p>The manufacture of accumulators begins with the casting
-of lead plates, which are then polished and dressed. Next
-follows ‘pasting,’ that is, smearing the negative plate with a
-paste of litharge, the positive plate being ‘formed’ by having an
-electric current passed through so that the lead is converted
-into spongy peroxide. The wooden boxes in which the plates
-are assembled are lead-lined.</p>
-
-<p>The most dangerous processes are casting, wire-brushing,
-and pasting—the latter especially when done by hand.</p>
-
-<p>In the years 1908 and 1909 among about 761 workers
-employed in the accumulator factories of Cologne there were
-fifty-six cases of lead colic and seventy-nine of gastric and
-intestinal catarrh. Further figures for German accumulator
-works show that in the two largest accumulator factories in
-the district of Potsdam employing 142 workers there were
-fifteen cases in 1904. In Great Britain, in the ten years 1900-1909,
-285 cases were reported—an average of about thirty a
-year.</p>
-
-<p><span class="pagenum"><a name="Page_135" id="Page_135">[135]</a></span></p>
-
-<h4>THE CERAMIC INDUSTRY</h4>
-
-<p>Risk is present in several branches of the ceramic industry.
-It is greatest in glazing earthenware, but not infrequent
-also in the porcelain and glass industries. It is impossible
-to deal with the extensive literature on this subject exhaustively.
-A comprehensive and detailed survey of lead
-poisoning in the ceramic industry on the Continent is that by
-Kaup. Distinction is made between leadless glazes which melt
-at high temperature and lead glazes which have the advantage
-of a low melting-point. Galena and litharge are used in the
-preparation of glazes for common earthenware and red and
-white lead for ware of better quality. Distinction has to be
-made between a lead silicious glaze for pottery ware, a lead and
-boric acid glaze for stoneware, and a lead and zinc oxide glaze
-for ordinary faience and stoneware. Seegar, the celebrated
-expert, praises the advantage of lead glaze and the use of lead
-in the ceramic industry—it is indeed practically indispensable—and
-speaks of the poisonous nature of lead as its only fault.
-The components of the glaze must have definite relation to
-the hardness or softness of the body. The higher the proportion
-of silicic acid in the glaze the harder the firing it will
-stand; the more the flux materials are in excess the lower will
-the melting point be.</p>
-
-<p>The most important flux materials are, arranged in order of
-decreasing fusibility, lead oxide, baryta, potash, soda, zinc
-oxide, chalk, magnesia, and clay.</p>
-
-<p>The <i>glaze</i> is made by first mixing the ingredients dry, and
-then either fritting them by fluxing in a reverberatory furnace
-and finally grinding them very finely in water or using the
-raw material direct. In the fritting process in the case of the
-lead glazes the soluble lead compounds become converted
-into less soluble lead silicates and double silicates.</p>
-
-<p>The glaze is applied in different ways—dipping, pouring,
-dusting, blowing, and volatilising. Air-dried and biscuited
-objects are dipped; pouring the glaze on is practised in coarse
-ware, roofing-tiles, &amp;c.; dusting (with dry finely ground glaze,
-litharge, or red lead) also in common ware; glaze-blowing
-(aerographing) and glaze dusting on porcelain. In these
-processes machines can be used. Bricks are only occasionally<span class="pagenum"><a name="Page_136" id="Page_136">[136]</a></span>
-glazed with glazes of felspar, kaolin, and quartz, to which lead
-oxide is often added in very large quantity. Lead poisoning in
-<i>brick works</i> in view of the infrequent use of lead is not common,
-but when lead is used cases are frequent. Kaup quotes several
-cases from the factory inspectors’ reports: thus in three roof-tiling
-works examination by the district physician showed
-that almost all the workers were affected.</p>
-
-<p><i>Coarse ware pottery</i> is made of pervious non-transparent
-clay with earthy fracture—only a portion of this class of ware
-(stoneware) is made of raw materials which fire white. Such
-ware generally receives a colourless glaze. The clay is shaped
-on the potter’s wheel, and is then fired once or, in the better
-qualities, twice.</p>
-
-<p>Grinding the ingredients of the glaze is still often done in
-primitive fashion in mortars. The glaze is usually composed
-of lead oxide and sand, often with addition of other lead compounds
-as, for example, in quite common ware, of equal parts
-of litharge, clay, and coarse sand. Sometimes, instead of
-litharge, galena (lead sulphide) or, with better qualities of
-ware, red lead or ‘lead ashes’ are used.</p>
-
-<p>The grinding of the glazes in open mills or even in mortars
-constitutes a great danger which can be prevented almost
-entirely by grinding in ball mills. The glaze material is next
-mixed with water, and the articles are either dipped into
-the creamy mass or this is poured over them. In doing
-this the hands, clothes, and floors are splashed. The more
-dangerous dusting-on of glaze is rarely practised. Occasionally
-mechanical appliances take the place of hand dipping. Placing
-the ware in the glost oven is done without placing it first in
-saggars.</p>
-
-<p>In the better qualities of pottery cooking utensils, which are
-fired twice, a less fusible fritted lead glaze is generally used.
-Coloured glaze contains, besides the colouring metallic oxides,
-30-40 per cent. of litharge or red lead.</p>
-
-<p>As Kaup shows, Continental factory inspectors’ reports
-make only isolated references to occurrence of lead poisoning
-in potteries. Insight into the conditions in small potteries is
-obtained only from the Bavarian reports. In Upper Bavaria
-ninety-three potteries employ 157 persons who come into
-contact with lead glaze. Eleven cases were known to have<span class="pagenum"><a name="Page_137" id="Page_137">[137]</a></span>
-occurred in the last four years. Teleky found thirty-six cases
-of lead poisoning (mostly among glostplacers) in the records
-of the Potters’ Sick Insurance Society of Vienna.</p>
-
-<p>Chyzer has described the striking conditions in Hungary.
-There there are about 4000 potters, of whom 500 come into
-contact with lead glaze. Chronic lead poisoning is rife
-among those carrying on the occupation as a home industry.
-Members of the family contract the disease from the dust in
-the living rooms. This dust was found to contain from
-0·5 to 8·7 per cent. of lead.</p>
-
-<p>In the china and earthenware factories in Great Britain, in
-the ten years 1900-9, 1065 cases with fifty-seven deaths were
-reported.</p>
-
-<p><i>Manufacture of stove tiles.</i>—The application of glaze to
-stove tiles is done in different ways. The two most important
-kinds are (1) fired tiles and (2) slipped tiles. In the production
-of fired tiles a lead-tin alloy consisting of 100 parts lead and
-30-36 parts tin—so-called ‘calcine’—are melted together in fireclay
-reverberatory or muffle furnaces and raked about when at
-a dull red heat so as to effect complete oxidation. The material
-when cool is mixed with the same quantity of sand and
-some salt, melted in the frit kiln, subsequently crushed,
-ground, mixed with water, and applied to the previously fired
-tiles. In this process risk is considerable. Presence of lead in
-the air has been demonstrated even in well-appointed ‘calcine’
-rooms. In unsuitably arranged rooms it was estimated that
-in a twelve-hour day a worker would inhale 0·6 gramme of
-lead oxide and that 3-8 grammes would collect on the clothes.</p>
-
-<p><i>Slipped tiles</i> are made in Meissen, Silesia, Bavaria, and
-Austria by first applying to them a mixture of clay and china
-clay. The glaze applied is very rich in lead, containing 50-60
-parts of red lead or litharge. Generally the glaze is applied
-direct to the unfired tiles and fired once. Figures as to occurrence
-of poisoning in Germany are quoted by Kaup from the
-towns of Velten and Meissen. Among from 1748 to 2500
-persons employed thirty-four cases were reported in the five
-years 1901-5. Thirteen cases were reported as occurring in
-the three largest factories in Meissen in 1906.</p>
-
-<p>From other districts similar occurrence of poisoning is
-reported. In Bohemia in a single factory in 1906 there were<span class="pagenum"><a name="Page_138" id="Page_138">[138]</a></span>
-fourteen cases with one death, in another in 1907 there were
-fourteen, and in 1908 twelve cases; eight further cases occurred
-among majolica painters in 1908.</p>
-
-<p><i>Stoneware and porcelain.</i>—Hard stoneware on a base of
-clay, limestone, and felspar has usually a transparent lead glaze
-of double earth silicates of lead and alkalis, with generally boric
-acid to lower the fusing-point; the lead is nearly always added
-in the form of red lead or litharge. The portion of the glaze
-soluble in water is fritted, and forms, when mixed with the insoluble
-portion, the glaze ready for use. The frit according to
-Kaup contains from 16 to 18 per cent. of red lead, and the added
-material (the mill mixing) 8-26 parts of white lead; the glaze
-contains from 13 to 28 parts of lead oxide. The ware is dipped
-or the glaze is sometimes aerographed on. Ware-cleaning by
-hand (smoothing or levelling the surface with brushes, knives,
-&amp;c.) is very dangerous work unless carried out under an
-efficient exhaust. Colouring the body itself is done with
-coloured metal oxides or by applying clay (slipping) or by the
-direct application of colours either under or over the glaze.
-Some of the under-glaze colours (by addition of chrome yellow
-or nitrate of lead or red lead) contain lead and are applied
-with the brush or aerograph or in the form of transfers.</p>
-
-<p><i>Plain earthenware</i> is either not glazed or salt glazed; only
-when decorated does it sometimes receive an acid lead glaze.</p>
-
-<p><i>Porcelain</i> receives a leadless glaze of difficultly fusible
-silicate (quartz sand, china clay, felspar). Risk is here confined
-to painting with lead fluxes (enamel colours) containing
-lead. These fluxes are readily fusible glasses made of
-silicic acid, boric acid, lead oxide, and alkalis, and contain
-much lead (60-80 per cent. of red lead).</p>
-
-<p>In the <i>glass industry</i> lead poisoning may occur from use of
-red lead as one of the essential ingredients. In Great Britain,
-in the years 1900-9, forty-eight cases were reported in glass
-polishing from use of putty powder.</p>
-
-<h4>LETTERPRESS PRINTING, ETC.</h4>
-
-<p>Type metal consists of about 67 per cent. lead, 27 per cent.
-antimony, and 6 per cent. tin, but sometimes of 75 per cent.
-lead, 23 per cent. antimony, and 2 per cent. tin.</p>
-
-<p><span class="pagenum"><a name="Page_139" id="Page_139">[139]</a></span></p>
-
-<p>The actual printer comes least of all in contact with lead.
-Use of lead colours (white lead, chromate of lead, &amp;c.) may
-be a source of danger, especially in the preparation of printing
-inks from them and in cleaning the printing rolls. A further,
-if slight, danger arises from the use of bronze powder consisting
-of copper, zinc, and tin. The two last-named metals contain
-from 0·1 to 0·5 per cent. of lead, and in the application and
-brushing off of the bronze there is a slight risk.</p>
-
-<p>The compositor is exposed to constant danger from handling
-the type and disturbing the dust in the cases. This dust may
-contain from 15 to 38 per cent. of lead. Blowing the dust out
-of the cases with bellows is especially dangerous, and want of
-cleanliness (eating and smoking in the workroom) contributes
-to the risk.</p>
-
-<p>Type founders and persons engaged in rubbing and preparing
-the type suffer. Introduction of type-casting machines
-(linotype, monotype) has lessened the danger considerably.</p>
-
-<p>No lead fumes are developed, as a temperature sufficiently
-high to produce them is never reached. In all the processes,
-therefore, it is lead dust which has to be considered.</p>
-
-<p>The following figures of the Imperial Statistical Office as
-to occurrence of lead poisoning among printers in Vienna
-indicate the relative danger:</p>
-
-<table summary="Cases of lead poisoning in Vienna" class="borders">
-  <tr>
-    <th>Occupation.</th>
-    <th>Average No. of Members, 1901-1906.</th>
-    <th>Average No. of Cases, 1901-1906.</th>
-    <th>Percentage of Cases, 1901-1906.</th>
-  </tr>
-  <tr>
-    <td>Compositors</td>
-    <td class="tdr">3182</td>
-    <td class="tdr">90·3</td>
-    <td class="tdr">2·8</td>
-  </tr>
-  <tr>
-    <td>Printers</td>
-    <td class="tdr">809</td>
-    <td class="tdr">20·3</td>
-    <td class="tdr">2·4</td>
-  </tr>
-  <tr>
-    <td>Casters and Stereotypers</td>
-    <td class="tdr">241</td>
-    <td class="tdr">15·8</td>
-    <td class="tdr">6·6</td>
-  </tr>
-  <tr>
-    <td class="bb nw">Females employed in casting</td>
-    <td class="tdr bb">74</td>
-    <td class="tdr bb">8·17</td>
-    <td class="tdr bb">10·8</td>
-  </tr>
-</table>
-
-<p>In Bohemia there is reference to thirty-eight cases in letterpress
-printing in 1907 and twenty-seven in 1908.</p>
-
-<p>Among 5693 persons treated for lead poisoning between
-the years 1898 and 1901 in hospitals in Prussia, 222 were letterpress
-printers.</p>
-
-<p>Between 1900 and 1909 in Great Britain 200 cases of lead
-poisoning were reported.</p>
-
-<p><span class="pagenum"><a name="Page_140" id="Page_140">[140]</a></span></p>
-
-<h4>VARIOUS BRANCHES OF INDUSTRY</h4>
-
-<p>The number of industries using lead is very large. Layet
-as long ago as 1876 enumerated 111. We, however, limit ourselves
-to those in which the risk is considerable.</p>
-
-<p>Use of <i>lead beds</i> in <i>file-cutting</i> has given rise to many cases.
-Further, to harden the file it is dipped into a bath of molten
-lead. From 3 to 6 per cent. of lead has been found in the dust
-in rooms where hardening is done.</p>
-
-<p>Of 7000 persons employed in file-cutting in the German
-Empire in the years 1901-5 on an average 30·5 or 0·43 per
-cent. were affected yearly. In Great Britain 211 cases were
-reported in the years 1900-9.</p>
-
-<p>In <i>polishing precious stones</i> formerly many cases of lead
-poisoning occurred, the reason being that the polishers come
-into contact with particles of lead and fix the diamonds to be
-polished in a vice composed of an alloy of lead and tin. Danger
-is increased when the stones are actually polished on revolving
-leaden discs. In Bohemia granite polishing used to be done in
-this way, but is now replaced in many factories by carborundum
-(silicon carbide).</p>
-
-<p>Musical instrument making in Bohemia in the years
-1906-8 was found regularly to give rise to cases of lead
-poisoning from use of molten lead in filling them with a view to
-shaping and bending. In lead pipe and organ pipe works,
-lead burning, plumbing, &amp;c., considerable risk is run.</p>
-
-<p>Often the causes of lead poisoning are difficult to discover,
-and, when found, surprising. Thus shoemakers have suffered
-from holding leaden nails in the mouth. Again, cases in women
-have been reported from cutting out artificial flowers or paper
-articles with aid of lead patterns, or counting stamps printed
-in lead colours.<a href="#endnote120" id="endnote-ref120"><span class="endnote-marker">8</span></a> </p>
-
-<h4>MERCURY</h4>
-
-<p>As metallic mercury gives off vapour even at ordinary
-temperatures, poisoning can occur not only in the recovery of
-the metal from the ore, but also in all processes in which it is
-used.</p>
-
-<p>Chronic industrial poisoning occurs principally in the<span class="pagenum"><a name="Page_141" id="Page_141">[141]</a></span>
-preparation and use of mercury salts, in recovery of the metal
-itself and of other metals with use of an amalgam, in water
-gilding, from use of nitrate of mercury in the preparation of
-rabbit fur for felt hat making, from use of mercury pumps
-in producing the vacuum in electric filament lamps, and in
-making barometers and thermometers.</p>
-
-<p><span class="smcap">Preparation.</span>—Mercury is obtained by roasting cinnabar
-(sulphide of mercury). When cinnabar is heated with access
-of air the sulphide burns to sulphur dioxide and the mercury
-volatilises and is subsequently condensed. Formerly the
-process was carried on in open hearths; now it is done usually
-in blast furnaces. The mercury is condensed in Idria in large
-chambers cooled with water, while at Almaden in Spain it is
-collected in a series of small earthenware receptacles (aludels),
-from small openings in which the mercury flows in gutters and
-collects. The mercury so recovered is usually redistilled.</p>
-
-<p>On the walls of the condensers a deposit of sulphide and
-oxide of mercury collects, removal of which is one of the
-operations most attended with risk.</p>
-
-<p>Recovery of silver or gold by amalgamation with mercury
-is carried on only in America. The metallic silver or gold
-is taken up by the mercury, from which it is recovered by
-distillation.</p>
-
-<p>The conditions in the quicksilver mines of Idria in Austria
-have improved of late years. Thus in the five years prior to
-1886 of 500 cases of illness more than 11 per cent. were due
-to chronic mercurial poisoning. In 1906, 209 persons were
-employed, of whom only one-third were permanent hands.
-Among these the sickness rate was very high (95-104 per
-cent.). Of 741 cases of illness among the miners there were
-six of mercury poisoning, and of 179 among persons employed
-in recovery of the metal, twelve cases.<a href="#endnote121" id="endnote-ref121"><span class="endnote-marker">1</span></a> </p>
-
-<p>The conditions of employment in the cinnabar mines of
-Monte Amiata in Italy have recently been described in detail.<a href="#endnote122" id="endnote-ref122"><span class="endnote-marker">2</span></a>
-Here, although the recovery of the metal is carried out in
-modern furnaces, thus greatly reducing the danger, nevertheless
-nearly all the furnace workers suffer from chronic poisoning.</p>
-
-<p>In <i>silvering of mirrors</i> the leaf of tinfoil was spread out
-on an inclined table; mercury was poured over it and the
-sheet of glass laid on the top with weights. The superfluous<span class="pagenum"><a name="Page_142" id="Page_142">[142]</a></span>
-mercury was squeezed out and ran away owing to the sloping
-position of the table. Now this process, even in Fürth, is
-almost entirely replaced by the nitrate of silver and ammonia
-process. Years ago the number of cases of poisoning was
-very serious in places where, as in Fürth, the work was
-carried on as a home industry.</p>
-
-<p>In the production of <i>incandescent electric bulbs</i> danger arises
-from breaking of the glass pipes of the pumps and scattering
-of mercury on the floor of the workrooms. Since there is
-a growing tendency to replace mercury pumps by air pumps
-such cases ought to become rare.</p>
-
-<p>In <i>water gilding</i>—a process little employed now—the
-metal objects (military buttons, &amp;c.) to be gilded, after treatment
-with a flux, are brushed over with the mercury amalgam,
-and subsequently fired to drive off the mercury. Unless
-careful provision is made to carry away the vapour chronic
-poisoning cannot fail to occur. Even sweeps have been affected
-after cleaning the chimneys of water gilders’ workshops. In
-Great Britain, between 1899 and 1905, six cases were reported
-among water gilders.</p>
-
-<p>In the <i>manufacture of barometers</i> and thermometers mercury
-poisoning is not infrequent. Between 1899 and 1905 sixteen
-such cases were reported in England; during the same period
-there were seventeen cases among those putting together
-electrical meters.</p>
-
-<p>Risk of mercurial poisoning is constantly present in <i>hatters’
-furriers’ processes</i> and in subsequent processes in felt hat
-factories. The risk from use of nitrate of mercury is considerable
-to those brushing the rabbit skins with the solution
-(carotting), and subsequently drying, brushing, cutting,
-locking, and packing them. According to Hencke in 100
-kilos of the carotting liquid there are 20 kilos of mercury.
-In England, in the years 1899-1905, thirteen cases of
-mercurial poisoning were reported in hatters’ furriers’ processes.
-Among eighty-one persons so employed the medical
-inspector found twenty-seven with very defective teeth as
-the result of the employment, and seventeen with marked
-tremor.</p>
-
-<p>In the <i>manufacture of mercurial salts</i> poisoning occurs<span class="pagenum"><a name="Page_143" id="Page_143">[143]</a></span>
-chiefly when they are made by sublimation, as in the
-manufacture of vermilion, of corrosive sublimate (when
-mercurous sulphate is sublimed with salt), and in the preparation
-of calomel (when sublimate ground with mercury or
-mercurous sulphate mixed with mercury and salt is sublimed).
-Between 1899 and 1905 in England seven cases were
-reported from chemical works. As to occurrence of mercury
-poisoning from <i>fulminate of mercury</i>, see the chapter on
-Explosives.</p>
-
-<h4>ARSENIC</h4>
-
-<p>Chronic industrial <i>arsenical poisoning</i>, both as to origin and
-course, is markedly different from the acute form.</p>
-
-<p>The chronic form arises mainly from inhalation of minute
-quantities of metallic arsenic or its compounds in recovery from
-the ore, or from the use of arsenic compounds in the manufacture
-of colours, in tanyards, and in glass making. Acute
-industrial <i>arseniuretted hydrogen poisoning</i> is especially likely
-to occur where metals and acids react on one another and
-either the metal or the acid contains arsenic in appreciable
-amount. Further, arseniuretted hydrogen may be contained
-in gases given off in smelting operations and in chemical
-processes.</p>
-
-<p><span class="smcap">Recovery of Arsenic and White Arsenic.</span>—Pure
-arsenic is obtained from native cobalt and arsenical pyrites
-by volatilisation on roasting the ore in the absence of air.
-After the furnace has been charged sheet iron condensing tubes
-are affixed to the mouths of the retorts, which project out of
-the furnace, and to these again iron or earthenware prolongs.
-Arsenic condenses on the sides of the sheet metal tubes and
-amorphous arsenic, oxides, and sulphides in the prolongs.
-After sublimation has been completed the contents of the
-prolongs are removed and used for production of other arsenic
-compounds; the (generally) argentiferous residues in the retorts
-are removed and further treated in silver smelting works;
-finally, the crusts of crystalline arsenic (artificial fly powder)
-are knocked out from the carefully unrolled sheet iron tubes.</p>
-
-<p>As can be readily understood from the description opportunity<span class="pagenum"><a name="Page_144" id="Page_144">[144]</a></span>
-of poisoning from volatilisation of arsenic and of
-arsenic compounds is considerable. Metallic arsenic is used
-for making hard shot, and for increasing the brilliancy and
-hardness of metal alloys (type metal, &amp;c.).</p>
-
-<p><i>White arsenic</i> (arsenic trioxide) is obtained by roasting
-with access of air in reverberatory furnaces arsenical ores and
-smelting residues. The vapours of white arsenic sublime
-and are condensed as a powder in long walled channels or
-in chambers, and are resublimed in iron cylinders. White
-arsenic is used in making colours, in glass (for decolourising
-purposes), as an insecticide in the stuffing of animals, &amp;c.</p>
-
-<p><span class="smcap">Industrial Arsenic Poisoning.</span>—In the <i>extraction of
-arsenic</i> and preparation of arsenious acid danger is present.
-But reliable accounts in literature of poisoning among those
-engaged in arsenic works are wanting.</p>
-
-<p>Those engaged in roasting operations and packing suffer
-much from skin affections. Similar poisoning is reported in
-the smelting of other arsenical ores—nickel, cobalt, lead,
-copper, iron, and silver, from arsenic compounds present in
-the fumes. This is especially the case in the smelting of
-tin, which generally contains arsenical pyrites.</p>
-
-<p>Danger is present also in <i>unhairing</i> (i.e. removing the
-wool from sheep skins), since the skins imported from Buenos
-Aires and Monte Video are treated with a preservative which,
-in addition to sodium nitrate, soda, and potash, contains
-generally arsenious acid.</p>
-
-<p>In <i>tanneries</i> a mixture of arsenic sulphide (realgar) and lime
-is used for unhairing. Arsenic is used also for preserving
-and stuffing animal furs; but although affections of the skin are
-described I cannot find reference to arsenical poisoning.</p>
-
-<p>The inspector for East London in 1905 refers to severe
-eczematous eruptions on face, neck, and hands, affecting
-workers in a <i>sheep dip</i> works—mainly in the packing of the
-light powder in packets.</p>
-
-<p>Formerly the use of arsenic in the manufacture of colours
-was great, especially of <i>emerald (Schweinfurter) green</i>. This
-is made by dissolving arsenious acid in potash with addition of
-acetate of copper. Drying and grinding the material constitute
-the main danger. Scheele’s green is another arsenical colour.</p>
-
-<p>Use of <i>arsenic colours</i> is becoming less and less. But in<span class="pagenum"><a name="Page_145" id="Page_145">[145]</a></span>
-colour printing of paper and colouring of chalk they are still
-employed. They are used, too, as mordants in dyeing, but
-cases of poisoning from these sources in recent years are not
-to be found.</p>
-
-<p>The dust in many glass works contains, it is stated, as much
-as 1·5 per cent of white arsenic.</p>
-
-<p>Despite the numerous opportunities for arsenical poisoning
-in industries it is rare or, at any rate, is only rarely reported.</p>
-
-<p><span class="smcap">Arseniuretted Hydrogen Poisoning.</span>—Industrial poisoning
-from arseniuretted hydrogen is caused mostly by inhalation
-of the gases developed by the action on one another of acids
-and metals which contain arsenic. Hydrogen gas as usually
-prepared for filling balloons gives occasion for poisoning.</p>
-
-<p>In Breslau in 1902 five workmen became affected, of whom
-three died from inhalation of arseniuretted hydrogen gas in
-filling toy balloons.<a href="#endnote123" id="endnote-ref123"><span class="endnote-marker">1</span></a> </p>
-
-<p>Further, use of hydrogen in lead burning may expose to
-risk, and also preparation of zinc chloride flux.</p>
-
-<p>Of thirty-nine recorded cases of arseniuretted hydrogen
-poisoning twelve were chemists, eleven workers filling toy
-balloons, seven aniline workers, five lead smelters, three balloonists,
-and in one the origin could not be traced. Nineteen of
-these proved fatal within from three to twenty-four days.<a href="#endnote124" id="endnote-ref124"><span class="endnote-marker">2</span></a> </p>
-
-<p>Cases are recorded (1) in the reduction of nitroso-methylaniline
-with zinc and hydrochloric acid; (2) in the preparation
-of zinc chloride from zinc ashes and hydrochloric acid;
-(3) from manufacture of zinc sulphate from crude sulphuric
-acid and zinc dust; (4) in spelter works in the refining of
-silver from the zinc crust with impure hydrochloric acid; and
-(5) in the formation room of accumulator factories.</p>
-
-<p>The English factory inspectors’ report describes in 1906
-occurrence of three cases in an electrolytic process for the
-recovery of copper in which the copper dissolved in sulphuric
-acid was deposited at the cathode, and hydrogen at the lead
-anode. In the 1907 report mention is made of two cases, one
-affecting a chemist separating bismuth from a solution of
-bismuth chloride in hydrochloric acid, and the other (which
-proved fatal) a man who had cleaned a vitriol tank.</p>
-
-<p>The poisoning resulting from ferro-silicon is in part referable
-to development of arseniuretted hydrogen gas.</p>
-
-<p><span class="pagenum"><a name="Page_146" id="Page_146">[146]</a></span></p>
-
-<h4>ANTIMONY</h4>
-
-<p>It seems doubtful if industrial poisoning can really be
-traced to antimony or its compounds; generally the arsenic
-present with the antimony is at fault. Erben<a href="#endnote125" id="endnote-ref125"><span class="endnote-marker">1</span></a> considers that
-industrial antimony poisoning occurs among workmen employed
-in smelting antimony alloys in making tartar emetic through
-inhalation of fumes of oxide of antimony.</p>
-
-<p>A case is cited of a workman in Hamburg engaged in pulverising
-pure antimony who was attacked with vomiting
-which lasted for several days, and the inspector of factories
-noted epistaxis (nose bleeding) and vomiting as following on
-the crushing of antimony ore.</p>
-
-<p>Compositors in addition to chronic lead poisoning may
-suffer, it is alleged, from chronic antimony poisoning, showing
-itself in diminution in the number of white blood corpuscles
-and marked eosinophilia. These changes in the blood could
-be brought about experimentally in rabbits. Antimony was
-found by the Marsh test in the stools of those affected.</p>
-
-<h4>IRON</h4>
-
-<p><i>Pig iron</i> is obtained by smelting iron ores in blast furnaces
-(<a href="#fig29">fig. 29</a>), through the upper opening of which charges of ore,
-limestone or similar material to act as a flux, and coke are
-fed in succession. The furnaces are worked continuously,
-using a blast of heated air; carbon monoxide is produced
-and effects the reduction of the ore to molten iron. The
-latter accumulates in the hearth and is covered with molten
-slag; this flows constantly away through an opening and is
-collected in slag bogies for removal, or is sometimes cooled in
-water.</p>
-
-<p>The crude iron is tapped from time to time, and is led in
-a fluid condition into moulds called ‘pigs,’ in which it
-solidifies. Cast iron is occasionally used direct from the blast
-furnace for the purpose of making rough castings, but
-generally it is further refined before being used in a foundry
-by remelting with cast iron scrap in a cupola furnace.</p>
-
-<p><span class="pagenum"><a name="Page_147" id="Page_147">[147]</a></span></p>
-
-<div class="figcenter" style="width: 250px;" id="fig29">
-
-<img src="images/fig29.jpg" width="250" height="500" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 29.</span></p>
-
-<p class="caption"><i>a</i> Hearth; <i>b</i> Bosh; <i>c</i> Shaft; <i>d</i> Gas uptake; <i>e</i> Down-comer; <i>f</i> Tuyères with
-water cooling arrangement; <i>g</i> Blast pipes; <i>h</i> Tapping hole; <i>k</i> Supporting
-columns; <i>l</i> Furnace bottom; <i>m</i> Charging hopper; <i>n</i> Bell with raising and
-lowering arrangement.</p>
-
-</div>
-
-<p><span class="pagenum"><a name="Page_148" id="Page_148">[148]</a></span></p>
-
-<p><i>Wrought iron</i> is made by treating pig iron in refinery and
-puddling furnaces; in these much of the carbon is removed
-as carbon monoxide, and from the puddling furnace the iron
-is obtained as a pasty mass which can be worked into bars,
-rods, or plates.</p>
-
-<p><i>Steel</i> is made in various ways. The Acid Bessemer process
-consists in forcing compressed air in numerous small streams
-through molten cast iron, in iron vessels (converters) which
-are lined with ganister, a silicious sandstone. These can
-be rotated on trunnions. Basic Bessemer steel is made in
-similar converters by the Thomas-Gilchrist or basic process,
-which can be applied to pig irons containing phosphorus.
-The latter is removed by giving the converter a basic lining
-of calcined magnesium limestone mixed with tar.</p>
-
-<p>In the <i>Martin</i> process steel is obtained by melting together
-pig iron with steel scrap, wrought iron scrap, &amp;c., on the
-hearth of a Siemens regenerative furnace with a silicious
-lining.</p>
-
-<p>In iron smelting the most important danger is from <i>blast
-furnace gas</i> rich in carbonic oxide. Sulphur dioxide, hydrocyanic
-acid, and arseniuretted hydrogen gas may possibly be
-present.</p>
-
-<p>When work was carried out in blast furnaces with open tops
-the workers engaged in charging ran considerable risk. But
-as the blast furnace gas is rich in carbonic oxide and has high
-heating capacity these gases are now always led off and utilised;
-the charging point is closed by a cup (Parry’s cup and cone
-charger) and only opened from time to time mechanically,
-when the workers retire so far from the opening as to be
-unaffected by the escaping gas. The gas is led away (<a href="#fig29">fig. 29</a>)
-through a side opening into special gas mains, is subjected to
-a purifying process in order to rid it of flue dust, and then used
-to heat the blast, fire the boilers, or drive gas engines.</p>
-
-<p>Severe blast furnace gas poisoning, however, does occur in
-entering the mains for cleaning purposes. Numerous cases of
-the kind are quoted in the section on Carbonic oxide poisoning.</p>
-
-<p>The gases evolved on tapping and slag running can also
-act injuriously, and unpleasant emanations be given off in
-granulating the slag (by receiving the fluid slag in water).</p>
-
-<p>In the puddling process much carbonic oxide is present.
-Other processes, however, can scarcely give rise to poisoning.</p>
-
-<p>The <i>basic slag</i> produced in the Thomas-Gilchrist process is a
-valuable manure on account of the phosphorus it contains;<span class="pagenum"><a name="Page_149" id="Page_149">[149]</a></span>
-it is ground in edge runners, and then reduced to a very fine
-dust in mills and disintegrators. This dust has a corrosive
-action already referred to in the chapter on Phosphorus and
-Artificial Manures.</p>
-
-<p>The poisoning caused by <i>ferro-silicon</i> is of interest. Iron
-with high proportion of silicon has been made in recent years
-on a large scale for production of steel. Some 4000 tons of
-ferro-silicon are annually exported to Great Britain from
-France and Germany. It is made by melting together iron ore,
-quartz, coke, and lime (as flux) at very high temperature in
-electrical furnaces. The coke reduces the quartz and ore to
-silicon and metal with the production of ferro-silicon. Certain
-grades, namely those with about 50 per cent. silicon, have
-the property of decomposing or disintegrating into powder
-on exposure for any length of time to the air, with production
-of very poisonous gases containing phosphoretted and
-arseniuretted hydrogen. The iron and quartz often contain
-phosphates, which in presence of carbon and at the high
-temperature of the electrical furnace would no doubt be
-converted into phosphides combining with the lime to form
-calcium phosphide; similarly any arsenic present would yield
-calcium arsenide. These would be decomposed in presence of
-water and evolve phosphoretted and arseniuretted hydrogen
-gas. In addition to its poisonous properties it has also given
-rise to explosions.</p>
-
-<p>[In January 1905 fifty steerage passengers were made
-seriously ill and eleven of them died. In 1907 five passengers
-died on a Swedish steamer as the result of poisonous gases given
-off from ferro-silicon, and more recently five lives were lost
-on the steamer <i>Aston</i> carrying the material from Antwerp to
-Grimsby.<a name="FNanchor_3" id="FNanchor_3"></a><a href="#Footnote_3" class="fnanchor">[C]</a> This accident led to full investigation of the
-subject by Dr. Copeman, F.R.S., one of the Medical Inspectors
-of the Local Government Board, Mr. S. R. Bennett, one of
-H.M. Inspectors of Factories, and Dr. Wilson Hake, Ph.D.,
-F.I.C., in which the conclusions arrived at are summarised as
-follows:</p>
-
-<div class="blockquote">
-
-<p>1. Numerous accidents, fatal and otherwise, have been caused
-within the last few years by the escape of poisonous and explosive<span class="pagenum"><a name="Page_150" id="Page_150">[150]</a></span>
-gases from consignments of ferro-silicon, which, in every
-instance, have been found to consist of so-called high-grade
-ferro-silicon, produced in the electric furnace.</p>
-
-<p>2. These accidents, for the most part, have occurred during
-transport of the ferro-silicon by water, whether in sea-going
-vessels or in barges and canal-boats plying on inland waters.</p>
-
-<p>3. These accidents have occurred in various countries and
-on vessels of different nationalities, while the ferro-silicon
-carried has, in almost every instance, been the product of a
-different manufactory.</p>
-
-<p>4. Ferro-silicon, especially of grades containing from 40 per
-cent. to 60 per cent. of silicon, is invariably found to evolve
-considerable quantities of phosphoretted hydrogen gas, and,
-in less amount, of arseniuretted hydrogen, both of which are
-of a highly poisonous nature. A certain amount of the gas
-evolved is present, as such, in the alloy, being ‘occluded’ in
-minute spaces with which its substance is often permeated.</p>
-
-<p>5. As the result of careful investigation, it has been shown
-that certain grades of ferro-silicon—notably such as contain
-about 33 per cent., 50 per cent., and 60 per cent. of silicon—even
-when manufactured from fairly pure constituents, are
-both brittle and liable to disintegrate spontaneously, this latter
-characteristic being apt to be specially marked in the case of the
-50 per cent. grade.</p>
-
-<p>All these grades are commonly employed at the present time.</p>
-
-<p>6. In the event of disintegration occurring, the amount of
-surface exposed will, obviously, be greater than if the mass were
-solid.</p>
-
-<p>7. Evolution of poisonous gases is greatly increased by the
-action of moisture, or of moist air, under the influence of which
-phosphoretted hydrogen is generated from calcium phosphide,
-which, in turn, is formed, in large part, at any rate, from the
-calcium phosphate present in anthracite and quartz, at the high
-temperature of the electric furnace. If spontaneous disintegration
-of the alloy also occurs, much larger quantities of gas
-would be given off from such friable and unstable material,
-other conditions being equal. The greater or less tendency of
-a given sample to evolve poisonous gases, and even a rough
-estimate of their probable amount may be arrived at by the use
-of test-papers prepared with silver nitrate.</p>
-
-<p>8. There is no evidence that low-grade ferro-silicon (10 to
-15 per cent.), produced in the blast-furnace, has ever given rise
-to accidents of similar character to those known to have been
-caused by the high-grade electrically produced alloy. Blast-furnace<span class="pagenum"><a name="Page_151" id="Page_151">[151]</a></span>
-ferro-silicon does not evolve poisonous gases even in
-presence of moisture.</p>
-
-<p>9. As regards ferro-silicon produced in the electric furnace,
-the evidence available goes to show that certain percentage
-grades are practically quite innocuous. This statement applies
-to grades of alloy of a silicon content up to and including 30 per
-cent., and probably also, though in considerably less degree, to
-those of 70 per cent. and over.</p>
-
-<p>10. In view of the fact that the use of ferro-silicon of grades
-ranging between 30 per cent. and 70 per cent. apparently is not
-essential in metallurgical operations, with the possible exception
-of basic steel manufacture, it will be advisable that the production
-of this alloy of grades ranging between these percentages
-should be discontinued in the future.</p>
-
-<p>11. The proprietors of iron and steel works making use of
-ferro-silicon will assist in the protection of their workpeople,
-and at the same time act for the public benefit by restricting
-their orders to grades of this material, either not exceeding
-30 per cent., or of 70 per cent. and upwards, according to the
-special nature of their requirements.</p>
-
-<p>12. But as, pending international agreement on the question,
-intermediate percentages of ferro-silicon will doubtless continue
-to be manufactured and sold, the issue, by the Board of Trade, of
-special regulations will be necessary in order to obviate, so far as
-may be possible, chance of further accidents during the transport
-of this substance.</p>
-
-<p><i>Inter alia</i>, these regulations should require a declaration of
-the nature, percentage, date of manufacture, and place of origin
-of any such consignment.</p>
-
-</div>
-
-<p>The suggested regulations are printed on p. <a href="#Page_291">291</a>.]</p>
-
-<h4>ZINC</h4>
-
-<p>Industrial poisoning from zinc is unknown. The chronic
-zinc poisoning among spelter workers described by Schlockow
-with nervous symptoms is undoubtedly to be attributed to
-lead.</p>
-
-<h4>COPPER: BRASS</h4>
-
-<p><i>Occurrence of brass-founder’s ague.</i>—Opinion is divided as
-to whether pure copper is poisonous or not. Lehmann has
-at any rate shown experimentally that as an industrial poison
-it is without importance.</p>
-
-<p><span class="pagenum"><a name="Page_152" id="Page_152">[152]</a></span></p>
-
-<p>Occurrence, however, of brass-founder’s ague is undoubtedly
-frequent. Although neither pure zinc nor pure copper give rise
-to poisoning, yet the pouring of brass (an alloy of zinc and
-copper) sets up a peculiar train of symptoms. As the symptoms
-are transient, and medical attendance is only very rarely
-sought after, knowledge of its frequency is difficult to obtain.</p>
-
-<p>Sigel,<a href="#endnote126" id="endnote-ref126"><span class="endnote-marker">1</span></a> who has experimented on himself, believes that the
-symptoms result from inhalation of superheated zinc fumes.
-In large well-appointed brass casting shops (as in those of
-Zeiss in Jena) incidence is rare.</p>
-
-<p>Lehmann<a href="#endnote127" id="endnote-ref127"><span class="endnote-marker">2</span></a> very recently has expressed his decided opinion
-that brass-founder’s ague is a zinc poisoning due to inhalation
-of zinc oxide and not zinc fumes. This conclusion he came to
-as the result of experiments on a workman predisposed to
-attacks of brass-founder’s ague. Lehmann’s surmise is that the
-symptoms are due to an auto-intoxication from absorption
-of dead epithelial cells lining the respiratory tract, the cells
-having been destroyed by inhalation of the zinc oxide. He
-found that he could produce typical symptoms in a worker
-by inhalation of the fumes given off in burning pure zinc.</p>
-
-<p><i>Metal pickling.</i>—The object of metal dipping is to give
-metal objects, especially of brass (buckles, lamps, electric
-fittings, candlesticks, &amp;c.), a clean or mat surface and is
-effected by dipping in baths of nitric, hydrochloric, or sulphuric
-acid. Generally after dipping in the dilute bath the articles go
-for one or two minutes into strong acid, from which injurious
-fumes, especially nitrous fumes, develop with occasionally
-fatal effect (see the chapter on Nitric Acid). Unfortunately,
-there are no references in the literature of the subject as to
-the frequency of such attacks.</p>
-
-<p>Recovery of gold and silver has been already referred to
-in the chapters on Mercury, Lead, and Cyanogen.</p>
-
-<p>Mention must be made of <i>argyria</i>. This is not poisoning in
-the proper sense of the word, as injury to health is hardly
-caused. Argyria results from absorption of small doses of silver
-salts which, excreted in the form of reduced metallic silver, give
-the skin a shiny black colour. Cases are most frequently seen
-in silverers of glass pearls who do the work by suction.
-Local argyria has been described by Lewin in silvering of
-mirrors and in photographers.</p>
-
-<p><span class="pagenum"><a name="Page_153" id="Page_153">[153]</a></span></p>
-
-<h3 id="III_OCCURRENCE_OF_INDUSTRIAL_POISONING">III. OCCURRENCE OF INDUSTRIAL POISONING
-IN VARIOUS INDUSTRIES</h3>
-
-<p>The most important facts have now been stated as to the
-occurrence of poisoning in industry, and there remain only a
-few gaps to fill in and to survey briefly the risks in certain
-important groups of industry.</p>
-
-<h4>TREATMENT OF STONE AND EARTHS</h4>
-
-<h5>Lime Burning: Glass Industry</h5>
-
-<p>Lead poisoning in the ceramic industry (earthenware,
-porcelain, glass, polishing of precious stones, &amp;c.) has been
-dealt with in detail in the chapter on Lead. There is further
-the possibility of chrome-ulceration, of arsenic poisoning, and
-conceivably also of manganese. Further, poisoning by <i>carbonic
-oxide</i> and carbon dioxide may occur from the escape of furnace
-gases where hygienic conditions are bad. In charging lime
-kilns poisoning by carbonic oxide has occurred. The report
-of the Union of Chemical Industry in 1906 describes the case
-of a workman who was assisting in filling the kiln with limestone.
-As the furnace door was opened for the purpose gas
-escaped in such amount as to render him unconscious. He
-was picked up thirty minutes later, but efforts at resuscitation
-failed.</p>
-
-<p>Carbonic oxide poisoning, again, may arise from the use
-of Siemens regenerative furnaces, especially glass furnaces:
-details are given in the chapter on Illuminating Gas.</p>
-
-<p><i>Hydrofluoric acid</i> is present as an industrial poison in
-<i>glass etching</i> (see Fluorine Compounds). Persons employed in
-this process suffer from inflammation of the respiratory tract
-and ulceration of the skin of the hands. I could not find any
-precise statement as to the frequency of the occurrence of
-such injuries. Use of sand-blasting to roughen the surface of<span class="pagenum"><a name="Page_154" id="Page_154">[154]</a></span>
-glass has to some extent taken the place of etching by hydrofluoric
-acid.</p>
-
-<h4>TREATMENT OF ANIMAL PRODUCTS</h4>
-
-<p>In <i>tanning</i> use of arsenic compounds for detaching the
-wool from skins and of gas lime for getting rid of hair may
-cause injury to health. With the latter there is possibility
-of the action of cyanogen compounds (see the chapters on
-Arsenic and Cyanogen).</p>
-
-<h4>PREPARATION OF VEGETABLE FOOD STUFFS AND THE LIKE</h4>
-
-<p>In <i>fermentation</i> processes as in breweries and the sugar
-industry accumulations of carbonic acid gas occur, and suffocation
-from this source has been repeatedly described. Mention in
-this connection should be made of the use of salufer containing
-some 2 per cent. of silicofluoric acid as a preservative and antiseptic
-in beer brewing. In the <i>sulphuring</i> of hops, wine, &amp;c.,
-the workers may run risk from the injurious action of sulphur
-dioxide. <i>Arsenic</i> in the sulphuric acid used for the production
-of <i>dextrine</i> may set up industrial poisoning. Poisoning from
-<i>ammonia</i> gas can occur in <i>cold storage</i> premises. Industrial
-poisoning from tobacco is not proved, but the injurious effect
-of the aroma and dust of tobacco—especially in women—in
-badly arranged tobacco factories is probable.</p>
-
-<h4>WOOD WORKING</h4>
-
-<p><i>Injurious woods.</i>—In recent literature there are several
-interesting references to injury to health from certain poisonous
-kinds of wood—skin affections in workers manipulating satinwood,
-and affections of the heart and general health in workers
-making shuttles of African boxwood. Details of these forms
-of poisoning are reported from England and Bavaria. The
-wood used for making the shuttles was West African boxwood
-(Gonioma Kamassi). It appears that the wood contains an
-alkaloidal poison which affects the heart’s action. The
-workers suffered from headache, feeling of sleepiness, lachrymation,
-coryza, difficulty of breathing, nausea, and weakness.
-Four workers had to give up the work because of the difficulty
-in breathing. Inquiry was made by Dr. John Hay of
-Liverpool in 1908 and by the medical inspector of factories
-in 1905. The following table shows the symptoms found:</p>
-
-<p><span class="pagenum"><a name="Page_155" id="Page_155">[155]</a></span></p>
-
-<table summary="Symptoms experienced by workers poisoned by wood" class="borders">
-  <tr>
-    <th rowspan="3">Symptoms.<br />(1)</th>
-    <th colspan="4">Persons Examined.</th>
-  </tr>
-  <tr>
-    <th colspan="2">1905.</th>
-    <th colspan="2">1907-1908.</th>
-  </tr>
-  <tr>
-    <th>Number.<br />(2)</th>
-    <th>Per cent.<br />(3)</th>
-    <th>Number.<br />(4)</th>
-    <th>Per Cent.<br />(5)</th>
-  </tr>
-  <tr>
-    <td>Headache</td>
-    <td class="tdr">27</td>
-    <td class="tdr">24·1</td>
-    <td class="tdr">18</td>
-    <td class="tdr">22·8</td>
-  </tr>
-  <tr>
-    <td>Feeling of somnolence</td>
-    <td class="tdr">10</td>
-    <td class="tdr">9·0</td>
-    <td class="tdr">17</td>
-    <td class="tdr">21·5</td>
-  </tr>
-  <tr>
-    <td>Running of eyes</td>
-    <td class="tdr">13</td>
-    <td class="tdr">11·6</td>
-    <td class="tdr">9</td>
-    <td class="tdr">11·3</td>
-  </tr>
-  <tr>
-    <td>Running of nose</td>
-    <td class="tdr">28</td>
-    <td class="tdr">25·0</td>
-    <td class="tdr">20</td>
-    <td class="tdr">28·0</td>
-  </tr>
-  <tr>
-    <td>Breathing affected</td>
-    <td class="tdr">34</td>
-    <td class="tdr">30·4</td>
-    <td class="tdr">13</td>
-    <td class="tdr">16·4</td>
-  </tr>
-  <tr>
-    <td>Nausea or sickness</td>
-    <td class="tdr">13</td>
-    <td class="tdr">11·6</td>
-    <td class="tdr">3</td>
-    <td class="tdr">3·8</td>
-  </tr>
-  <tr>
-    <td class="bb">Faintness or weakness</td>
-    <td class="tdr bb">11</td>
-    <td class="tdr bb">9·6</td>
-    <td class="tdr bb">1</td>
-    <td class="tdr bb">1·2</td>
-  </tr>
-</table>
-
-<p>The later inquiry shows considerable diminution in the
-amount of complaint as to respiratory trouble. This may have
-been due to the improved conditions of working, freely acknowledged
-by the men. Men were examined who had complained
-of the effects of the wood in 1905, and had continued uninterruptedly
-at the same kind of work during the interval
-without any obvious further injury to their health, although
-they preferred working on other woods.</p>
-
-<p>East Indian boxwood had to be discarded in the shuttle
-trade owing to its irritant action on the eyes. Sabicu wood
-from Cuba was stated to give off ‘a snuffy dust under the
-machine and hand planes, the effect of which upon the worker
-is to cause a running at the eyes and nose, and a general feeling
-of cold in the head. The symptoms pass off in an hour or so
-after discontinuance of work.’ Reference was made in the
-report for 1906 to eczematous eruptions produced by so-called
-Borneo rosewood, a wood used owing to its brilliant
-colour and exquisite grain in fret-saw work. The Director
-of the Imperial Institute experimented with this wood, but
-failed to discover injurious properties in it. At the same time
-experiments with the wood and sawdust of East and West
-Indian satinwood were undertaken, but also without result.</p>
-
-<p>From inquiries subsequently made it appeared that much
-confusion existed as to the designation ‘satinwood,’ as under
-this name were classed both East and West Indian satinwood
-and also satin walnut. The evidence was clear that East
-Indian satinwood was more irritating than West Indian.
-Satin walnut wood is apparently harmless. In the shipbuilding
-yards of East London, Glasgow, and Bristol affections
-of the skin were recognised, but susceptibility to the wood<span class="pagenum"><a name="Page_156" id="Page_156">[156]</a></span>
-varied. One man asserted that merely laying a shaving on
-the back of his hand would produce a sore place. The injurious
-effects here seem to disappear quickly. Exhaust ventilation is
-applied, but there is a tendency to give up the use of the wood.</p>
-
-<p>Isolated cases of illness have been ascribed to working teak
-and olive wood. In Sheffield the following are held to be
-irritating: ebony, magenta rosewood, West Indian boxwood,
-cocos wood. Some kinds of mahogany are said to affect the
-eyes and nose.</p>
-
-<p>Use of methylated spirit in polishing furniture is said to
-lead to injury to health although not to set up actual poisoning.
-Lead poisoning can occur from the sand-papering of coats of
-paint applied to wood.</p>
-
-<p>In impregnating wood with creosote and tar the effects on
-the skin noted in the chapter on Tar are observed.</p>
-
-<h4>TEXTILE INDUSTRY</h4>
-
-<p>In getting rid of the grease from animal wool carbon
-bisulphide or <i>benzine</i> may be used.</p>
-
-<p>The process of <i>carbonising</i> in the production of shoddy may
-give rise to injury to health from acid fumes. Lead poisoning
-used to be caused by the knocking together of the leaden
-weights attached to the Jacquard looms. This is a thing of
-the past, as now iron weights are universal.</p>
-
-<p>Opportunity for lead poisoning is given in the weighting of
-yarn—especially of silk with lead compounds.</p>
-
-<p>In <i>bleaching</i> use of chlorine and sulphur dioxide has to be
-borne in mind.</p>
-
-<p>In <i>chemical cleaning</i> poisoning by benzine may occur.</p>
-
-<p>In <i>dyeing</i> and <i>printing</i> use of poisonous colours is lessening,
-as they have been supplanted by aniline colours. On occurrence
-of aniline poisoning in aniline black dyeing see the section on
-Aniline. Use of lead colours and of chromate of lead are dealt
-with in special sections.</p>
-
-<hr />
-
-<p><span class="pagenum"><a name="Page_157" id="Page_157">[157]</a></span></p>
-
-<h2 id="PART_II">PART II<br />
-<span class="smaller"><i>THE SYMPTOMS AND TREATMENT OF
-INDUSTRIAL POISONING</i></span></h2>
-
-<p>In this section the most important diseases and symptoms
-of industrial poisoning will be described. In doing this—considering
-the mainly practical purpose of this book—theoretical
-toxicological details and any full discussion of
-disputed scientific points will be omitted.</p>
-
-<h3 id="I_INTRODUCTORY">I. INTRODUCTORY</h3>
-
-<p>Hitherto in this book we have intentionally followed the
-inductive method, from the particular to the general: we
-began by citing a number of important instances of industrial
-poisoning, but only now will endeavour be made to give a
-definition of the terms ‘poison’ and ‘poisoning.’</p>
-
-<p>Attempts at such definitions are numerous; every old and
-new text-book of toxicology contains them. A few only hold
-good for our purpose. It is characteristic that Lewin, after
-attempting a definition of the conception ‘poisoning,’ himself
-rejects it and declares that he can see no practical disadvantage
-in the impossibility of defining this notion, because deductions
-based upon the knowledge of undoubted cases can never be
-dispensed with, even if a definition were possible: one justification
-the more for our inductive method.</p>
-
-<p>But we will not quite dispense with a definition.</p>
-
-<p><i>Poisons are certain substances which are able chemically to
-act on an organism in such a way as to effect a permanent
-or transient injury to its organs and functions; an injury<span class="pagenum"><a name="Page_158" id="Page_158">[158]</a></span>
-consequently to the health and well-being of the person affected;
-this injury we call poisoning.</i></p>
-
-<p>In the present book we have refrained from including
-industrial infections among industrial poisonings, and the
-subject has been limited to poisoning in the restricted and
-current sense of the word.</p>
-
-<p>An industrial poison is a poison employed, produced, or
-somehow occasioned in industrial occupation, which is brought
-about inadvertently, and consequently against the will of the
-person poisoned.</p>
-
-<p>From a simple survey of the action of industrial poisons in
-general we may group them as follows:</p>
-
-<div class="blockquote">
-
-<p>1. Poisons which act <i>superficially</i>, i.e. which cause in the
-organs which they touch gross anatomical lesions
-(irritation, corrosion, &amp;c.)—so-called contact-effect. To
-this class belong especially irritant and corrosive
-poisons.</p>
-
-<p>2. <i>Blood</i> poisons, i.e. poisons which are absorbed by the
-blood and change it; this change can affect either
-the blood colouring-matter, with which certain poisons
-form chemical compounds, or the blood corpuscles
-themselves can be altered or destroyed (for instance,
-poisons having a hæmolytic action).</p>
-
-<p>3. Poisons with definite <i>internal</i> action, so-called remote
-or specific effect. To this class belong the poisons
-which, after being absorbed into the system, act upon
-definite organs or tissues in a specific manner (nerve
-poisons, heart poisons, &amp;c.).</p>
-
-</div>
-
-<p>It is indeed possible for one and the same poison to display
-two or all three of these modes of action.</p>
-
-<p>The effect of poison depends upon an interaction of the
-poison and the organism, or its single organs. Selection as
-regards quality and quantity is a property of the organism as
-well as of the poison: the nature and amount of the poison
-taken in are determining factors on the one side, and on the
-other the constitution, size, and weight of the affected
-organism. The chemical constitution of the poisonous substance
-determines the qualitative property of the poison.</p>
-
-<p>Further, certain physical properties of the poison determine<span class="pagenum"><a name="Page_159" id="Page_159">[159]</a></span>
-its action, especially its form, solubility in water, and its power
-of dissolving fat. These affect its susceptibility to absorption,
-to which point we shall return shortly; the hygroscopic
-capacity of a poison produces a highly irritant and corrosive
-action.</p>
-
-<p>Industrial poisons can be absorbed (1) as solid substances,
-(2) as liquids, and (3) as gases. Since industrial poisoning, as
-defined above, is of course neither desired nor intended by the
-sufferer, who unsuspectingly takes into his system poison used
-or developed in the factory, solid substances in finely divided
-condition—in the form of dust—can be considered as industrial
-poisons. Accordingly, industrial poisons can be classed as due
-to dust, gases, and liquids.</p>
-
-<p>The poison may be introduced into the body through the
-functional activity of the organism by the lungs or alimentary
-tract, or it may penetrate the uninjured or injured surface of
-the skin.</p>
-
-<p>Industrial poisons which contaminate the air of the factory
-are inhaled—these are consequently either poisonous dusts
-or gases and vapours.</p>
-
-<p>As a rule, only industrial poisons in a liquid form enter
-through the skin, which may be either intact or wounded;
-gaseous poisons seldom do; poisons in the form of fat or dust
-can only pass through the skin after they have been first
-dissolved by the secretions of the skin or of a wound, so that
-they come to be absorbed in solution. Most frequently
-those liquid poisons which are capable of dissolving the
-fat of the skin are thus absorbed, and next, such liquids
-as have a corrosive effect, breaking down the resistance
-of the skin covering and producing an inflamed raw surface.
-But such poisons much more easily enter through the mucous
-membrane, as this naturally offers a much weaker resistance
-than the skin.</p>
-
-<p>From a quantitative point of view it is especially the
-amount of poison actively assimilated which determines the
-effect. Every poison is without effect if assimilated in correspondingly
-small quantities. There is consequently a minimum
-poisonous dose, after which the poison begins to act; but this
-minimum dose can only be ascertained and specified when
-the qualitative properties and the weight of the organism are<span class="pagenum"><a name="Page_160" id="Page_160">[160]</a></span>
-also taken into consideration; it has therefore a relative value.
-The strongest effect which a poison is able to produce is the
-destruction of the life functions of the organism, the fatal
-effect. This fatal dose, however, can only be determined
-relatively to the qualities of the organism in question.</p>
-
-<p>Not only is the absolute quality of the poison of decisive
-significance, but the degree of concentration often influences
-its action, that is to say, the greater or less amount of effective
-poison contained in the substance conveying it into the
-organism; concentration plays an important part in many
-industrial poisons, especially, as is obvious, in corrosive
-poisons.</p>
-
-<p>A further important point is the time which it takes to
-absorb the poison. The action of the poison—the whole expression
-of the symptoms of poisoning—is essentially influenced
-by this fact.</p>
-
-<p>Usually gradual and repeated absorption of small quantities
-produces slow onset of symptoms, while sudden absorption
-of larger quantities of poison brings about rapid onset of
-illness. In the former case the poisoning is called <i>chronic</i>,
-in the latter, <i>acute</i>. Acute industrial poisoning is sometimes
-so sudden that the affected person cannot withdraw himself
-in time from the influence of the poison, nor prevent its entrance
-in considerable quantities into his system; this is often caused
-by the fact that the effect of the poison is so rapid that he is
-often suddenly deprived of power to move or of consciousness,
-and remains then exposed to the action of the poison until help
-comes. Such accidents are mostly caused by poisonous gases.
-Occasionally also considerable quantities of poison enter quite
-unnoticed into the body, such as odourless poisonous gases in
-breathing, or poisonous liquids through the skin. In chronic
-industrial poisoning unsuspected accumulation of poison
-takes place, until symptoms of illness ultimately reveal
-themselves; as the first stages of poisoning are not recognised
-in time by the person affected, he continues exposed to the
-influence of the poison for weeks, months, even years, until the
-chronic effect has reached its full development and becomes
-obvious. Such insidious industrial poisoning arises through
-the continual absorption into the lungs or stomach of small
-quantities of poisonous dust, gases, and vapours, during<span class="pagenum"><a name="Page_161" id="Page_161">[161]</a></span>
-constant or frequent work in an atmosphere containing
-such gases; poisonous liquids also, by soiling hands and
-food, or by penetrating the skin, can produce slow industrial
-poisoning.</p>
-
-<p>Industrial poisoning which in respect of its duration
-stands midway between acute and chronic is called sub-acute
-poisoning. This usually means that more frequent absorption
-of greater quantities of poison has taken place, though not in
-doses large enough to produce an immediately acute effect.
-This is important legally because industrial poisonings caused
-through the sudden absorption of poison in sufficient quantity
-to act immediately or to bring about subsequent symptoms
-of poisoning, are reckoned as accidents. Thus acute and
-many sub-acute industrial poisonings are accounted accidents.
-Chronic industrial poisonings, acquired gradually, count as
-illnesses. But as in certain cases it cannot be decided whether
-sudden or gradual absorption of the industrial poison is in
-question, this distinction is an unnatural one. It is also unnatural
-in the legal sense, for there is often no material reason
-for regarding as legally distinct cases of chronic and acute
-industrial poisoning. To this we shall refer later in discussing
-the question of insurance against industrial poisoning.</p>
-
-<p>We have from the outset assumed that the effect of the
-poison depends not only on the nature of the poison itself,
-but also on that of the organism, considered both quantitatively
-and qualitatively.</p>
-
-<p>Significant in a quantitative respect is the body weight of
-the organism, and the fatal dose of the poison must be ascertained
-and stated in connection with the body weight, calculated
-as a rule per kilo of the live weight.</p>
-
-<p>The qualitative point of view must reckon with the differing
-susceptibility of organisms for poison. This varying susceptibility
-to the action of poison, the causes of which are very
-obscure, is called disposition.</p>
-
-<p>Different species (of animals and men) exhibit often very
-different degrees of susceptibility towards one and the same
-poison; the differences in this respect are often very considerable,
-and one cannot simply transfer the experience experimentally
-gained from one species of animal to man or another
-species of animal, without further experiment. Besides disposition,<span class="pagenum"><a name="Page_162" id="Page_162">[162]</a></span>
-sex, and still more age, often determine within the
-same species marked difference of susceptibility to a poison.
-Further, there is an individual disposition due to qualities
-peculiar to the individual, which makes some persons more
-than usually immune and others specially susceptible. Individuals
-weakened by illness are particularly susceptible to
-poisoning. Two diseases, in especial, favour the operation
-of poison, influencing disastrously the capacity for assimilating
-food, and reducing the general resisting power of the body;
-of these tuberculosis stands first.</p>
-
-<p>Individual disposition plays in industrial poisoning a part
-which must not be under-estimated; it determines the possibility
-of acclimatisation to a poison; some individuals capable
-of resistance habituate themselves—often comparatively easily—to
-a poison, and become, up to a certain limit, immune
-against it, that is, they can tolerate a quantity which would
-be injurious to others not so accustomed. With other individuals,
-however, the opposite effect is apparent. Repeated
-exposure to the action of the poison leads to an increased
-susceptibility, so that acclimatisation is not possible. Innate
-hyper-sensitiveness of the individual towards a poison is
-called idiosyncrasy. Frequently, for example, this quality
-shows itself as hyper-sensitiveness of the skin towards the
-harmful action of certain poisons. A marked lowering in the
-sensitiveness, innate or acquired, of the organism towards a
-poison is called immunity.</p>
-
-<p>The possibility of the absorption and action of a poison
-presupposes—speaking generally—its solubility, and indeed
-its solubility in the body juices.</p>
-
-<p>In general, poison can be absorbed at very different points
-of the body; so far as industrial poisons are concerned, these
-are the mucous membrane of the respiratory passages, the
-mucous membrane of the digestive tract, and the skin, intact
-or broken. The rapidity of absorption depends on the nature
-of the poison, of the individual, and the channel of absorption.
-Of industrial poisons gases are relatively the most quickly
-absorbed; sometimes indeed so swiftly that the effect follows
-almost immediately.</p>
-
-<p>Elimination of industrial poisons is effected principally<span class="pagenum"><a name="Page_163" id="Page_163">[163]</a></span>
-by the kidneys, the intestinal canal, the respiratory organs,
-and, more rarely, the skin. Rapidity of elimination also
-depends on the nature of the poison and of the person
-poisoned.</p>
-
-<p>If elimination is insufficient, or absorption takes place more
-quickly than excretion, the poison accumulates in the body,
-and has a cumulative effect which in chronic industrial poisonings
-plays a very important rôle. Under certain circumstances
-poisons are not thrown off, but stored up—fixed—in
-the body.</p>
-
-<p>The poison absorbed in the body can act unchanged from
-the place where it is stored. A number of poisons, however,
-undergo in the organism chemical change through which the
-action of the poison is partly lessened, rarely increased. Among
-such changes and weakening of the poison are: oxidation, as,
-for example, of organic poisons into their final products
-(carbonic acid, water, &amp;c.), oxidation of benzene into phenol,
-oxidation of sulphur dioxide into sulphuric acid, &amp;c.; reduction
-in the case of metals, peroxides, &amp;c.; neutralisation of
-acids by alkaline juices; chemical union (for instance, of aromatic
-compounds with sulphuric acid). The splitting up of
-albuminous bodies is not of importance in regard to industrial
-poisons.</p>
-
-<h4>GENERAL REMARKS ON THE TREATMENT OF INDUSTRIAL
-POISONINGS</h4>
-
-<p>Although in industrial poisoning the importance of treatment
-is small in comparison with that of preventive measures,
-in discussing particular forms of poisoning, full weight must
-be given to it; and in order to avoid repetition, certain points
-will be brought forward here.</p>
-
-<p>Of the treatment of chronic industrial poisonings not
-much in general can be said; unfortunately, special treatment
-has often little chance. It will usually be of advantage
-to maintain the activity of the excretory organs. So far as
-there is question of poisons affecting metabolism and injuriously
-influencing the general state of nutrition, treatment aiming at
-improving the general health and strength offers hope of
-success. For nervous symptoms, especially paralysis, disturbance<span class="pagenum"><a name="Page_164" id="Page_164">[164]</a></span>
-in sensation, &amp;c., treatment generally suitable to nervous
-diseases can be tried (electro-therapeutics, baths, &amp;c.). In
-treatment of acute industrial poisonings, which often demand
-the prompt intervention of laymen, ‘first aid’ is more
-hopeful.</p>
-
-<p>The most important general rules of treatment arise in
-reference to irritant poisons which produce ulceration of the
-skin, and further in regard to those poisons which cause
-unconsciousness, especially blood poisons.</p>
-
-<p>When an irritant poison is acting on the skin, the first
-object to be aimed at is naturally the immediate removal
-of the cause of corrosion by water, or, better still, neutralisation
-by an alkaline solution (for example, soda solution) in
-the case of corrosive acids, and weak acids (organic acids, acetic
-acid, citric acid) in the case of caustic action by alkalis. Such
-remedies must be at hand in factories as part of the equipment
-for first aid, where irritant poisonings can occur.</p>
-
-<p>In those industrial poisonings which result in loss of consciousness,
-arrest of respiration and suffocation, attempts at
-resuscitation should at once be made. In these attempts
-at resuscitation, <i>artificial respiration</i> is of the greatest importance;
-of course the sufferer must first be withdrawn from the
-influence of the poison, i.e. be brought into fresh air. Great
-care must be taken, especially where it is necessary to enter
-places filled with a poisonous atmosphere, to prevent the
-rescuers, as is often the case, themselves falling victims to the
-influence of the poison. They should be provided with suitable
-smoke helmets or breathing apparatus.</p>
-
-<p>We will not describe the methods of resuscitation and
-artificial respiration universally enjoined; they can be found
-in every first-aid handbook.</p>
-
-<p>Emphasis is laid on the great importance of <i>treatment by
-oxygen</i> in cases of industrial poisoning through gaseous blood
-poisons, as this treatment is attended with good results.
-Apparatus for the administration of oxygen should be kept
-wherever there exists the possibility of such poisoning,
-especially in mines, smelting works, chemical factories, and
-chemical laboratories.</p>
-
-<p>Oxygen treatment rests on the fact that by raising the
-pressure of the oxygen from 113 mm., as it is generally in<span class="pagenum"><a name="Page_165" id="Page_165">[165]</a></span>
-ordinary air, to 675 mm., which is reached in presence of pure
-oxygen, the quantity of oxygen absorbed in the blood rises
-from 0·3 to 1·8 per 100 c.c. Further, the saturation of the
-hæmoglobin, the colouring matter of the blood, undergoes an
-increase of 2·4 per cent. This increase of oxygen in the blood
-can save life in cases where through poisoning a deficiency of
-oxygen has resulted.</p>
-
-<p>The introduction of oxygen is done by special apparatus
-which acts essentially on
-the principle that during
-inhalation oxygen is pressed
-into the lungs which are
-below normal physiological
-pressure, while exhalation is
-effected by a deflating
-arrangement when the
-poisoned individual no longer
-breathes of his own accord.
-When natural breathing
-begins, the introduction of
-oxygen without special apparatus
-generally suffices.</p>
-
-<div class="figcenter" style="width: 250px;" id="fig30">
-
-<img src="images/fig30.jpg" width="250" height="300" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 30.</span>—Dräger’s Oxygen Box</p>
-
-<p class="caption">I Oxygen cylinder; A Valve on cylinder;
-B Manometer; C Key for opening
-and closing the flow of oxygen; F Economiser;
-H Facepiece.</p>
-
-</div>
-
-<p>Dräger’s <i>oxygen apparatus</i>
-(<a href="#fig30">fig. 30</a>) consists of a small
-oxygen cylinder provided
-with a closing valve, a small
-manometer, a so-called
-‘automatic’ reducing valve
-with an arrangement for
-opening and closing the
-oxygen supply, a bag to act as a receiver or economiser, a
-breathing mask, and a metal tube connecting the breathing
-mask with the other parts of the apparatus. The oxygen
-cylinder, when filled, contains about 180 litres of oxygen, and
-the manometer allows the manipulator to control at any time
-whatever oxygen it still contains. The automatic arrangement
-not only reduces the pressure but at the same time
-controls the supply of oxygen. This dose is fixed at three
-litres of oxygen per minute, so that the apparatus with the
-same oxygen cylinder will last for sixty minutes. The oxygen
-is not inhaled pure, but is mixed with atmospheric air
-according to need, and in order to make this possible the
-breathing mask is provided with a small hole through which
-atmospheric air finds entrance.</p>
-
-<p><span class="pagenum"><a name="Page_166" id="Page_166">[166]</a></span></p>
-
-<div class="figcenter" style="width: 400px;" id="fig31">
-
-<img src="images/fig31.jpg" width="400" height="325" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 31.</span>—Oxygen Inhaling Apparatus</p>
-
-</div>
-
-<div class="figcenter" style="width: 500px;" id="fig32">
-
-<img src="images/fig32.jpg" width="500" height="450" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 32.</span>—Showing apparatus in use (<i>Siebe, Gorman &amp; Co.</i>)</p>
-
-</div>
-
-<p><span class="pagenum"><a name="Page_167" id="Page_167">[167]</a></span></p>
-
-<p>As the oxygen flows continuously from the cylinder waste
-during exhalation is prevented by the economiser, in which,
-during exhalation, the inflowing oxygen accumulates, to be
-absorbed again in inhalation. A small relief valve in the
-screw head of the bag prevents the entrance into it of
-exhaled air.</p>
-
-<div class="figcenter" style="width: 600px;" id="fig33">
-
-<img src="images/fig33.jpg" width="600" height="500" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 33.</span>—Dräger’s Pulmotor (<i>R. Jacobson</i>)</p>
-
-</div>
-
-<p>Another oxygen inhaling apparatus for resuscitating purposes,
-that of Siebe, Gorman &amp; Co., is illustrated in figs. <a href="#fig31">31</a>
-and <a href="#fig32">32</a>.</p>
-
-<p>Dräger also constructs an apparatus called the ‘Pulmotor’
-which simultaneously accomplishes the introduction of oxygen
-and artificial respiration.</p>
-
-<p><span class="pagenum"><a name="Page_168" id="Page_168">[168]</a></span></p>
-
-<p>Inflation and deflation are effected by an injector driven by
-compressed oxygen; this alternately drives fresh air enriched
-with oxygen into the lungs and then by suction empties them
-again. While with the mechanical appliances of resuscitation
-belonging to older systems the hand of the helper regulated the
-rate of breathing, in the case of the Pulmotor the lungs,
-according to their size, automatically fix the rate of breathing;
-as soon as the lungs are filled the apparatus of its own accord
-marks the moment for ‘deflation,’ and as soon as they are
-emptied of ‘inflation.’ This automatic reversal is effected by
-a little bellows which is connected with the air tubes. During
-inflation the same pressure is exerted in the bellows as in the
-lungs. As soon as the lungs are filled, the pressure in the
-bellows increases and it expands, its forward movement causing
-the reversal to deflation. When the lungs are emptied the
-bellows contracts, and through this contraction results the
-reversal to inflation.</p>
-
-<p>If, in an exceptional case, the breathing for some reason
-does not act automatically, the hand of the helper can
-manipulate it by means of a backward and forward movement
-of a lever. According to choice, either a nose-mask or a mask
-covering both mouth and nose can be worn.</p>
-
-<p>Combined with the regular apparatus for resuscitation is an
-ordinary apparatus for the inhalation of oxygen; by the simple
-altering of a lever, either the one or the other can be employed.</p>
-
-<p><span class="pagenum"><a name="Page_169" id="Page_169">[169]</a></span></p>
-
-<h3 id="II_INDUSTRIAL_POISONING_IN_PARTICULAR_INDUSTRIES">II. INDUSTRIAL POISONING IN PARTICULAR INDUSTRIES</h3>
-
-<p>After the foregoing general remarks we may now consider
-various points of view in regard to classification of industrial
-poisonings into groups:</p>
-
-<div class="blockquote">
-
-<p>(1) Toxicological, based on the action of the poisons.</p>
-
-<p>(2) Chemical, based on the chemical composition of the
-poisons.</p>
-
-<p>(3) Physical, based on the varying density of the poisons.
-(Division into solid (in form of dust), gaseous, and
-liquid poisons.)</p>
-
-</div>
-
-<p>To which may be added:</p>
-
-<div class="blockquote">
-
-<p>(4) Classification according to the source of the poisoning
-and therefore according to industry, upon which
-Part I is mainly based.</p>
-
-</div>
-
-<p>In this section (Part II) a system is adopted which takes
-into consideration as far as possible all the principles of
-division mentioned above, in order to classify industrial
-poisonous substances in such a manner that general practical
-conclusions can be clearly drawn, and supervision rendered
-easy.</p>
-
-<h4><i>GROUP: MINERAL ACIDS, HALOGENS, INORGANIC
-HALOGEN COMPOUNDS, ALKALIS</i></h4>
-
-<p>Common to this group is a strong corrosive and irritant
-effect, varying however in degree; as gases this group corrode
-or inflame the mucous membrane of the respiratory passages,
-and in liquid form or in solution, the skin.</p>
-
-<p>Besides this superficial effect single members of this group,<span class="pagenum"><a name="Page_170" id="Page_170">[170]</a></span>
-especially those containing nitrogen, produce a remote effect
-upon the blood.</p>
-
-<p>After absorption of the acids a decrease in the alkalinity
-of the blood can take place and in its power to take up
-carbonic acid, thus vitally affecting the interchange of
-gases in the body, and producing symptoms of tissue
-suffocation.</p>
-
-<p>As regards treatment in the case of acids and alkalis,
-neutralisation has been already mentioned; further, oxygen
-treatment may be recommended in cases where the blood has
-been injuriously affected. In cases of poisoning through
-breathing in acid vapours, inhalation of extremely rarefied
-vapour of ammonia or of a spray of soda solution (about
-1 per cent.) is advisable.</p>
-
-<h5>MINERAL ACIDS</h5>
-
-<p><b>Hydrochloric Acid</b> (HCl) is a colourless, pungently smelling
-gas which gives off strong white fumes. Experiments on
-animals, carefully carried out by Leymann, produced the
-following symptoms.</p>
-
-<p>Even in a concentration of 2-5 per thousand clouding of
-the cornea ensues, and after about an hour inflammation of
-the conjunctiva, violent running from every exposed mucous
-membrane with marked reddening, and frequently inflammation
-(necrosis) of the septum of the nose; the lungs are distended
-with blood, here and there hæmorrhages occur in the
-respiratory and also in the digestive tracts. The animal dies
-of œdema (swelling) of the lungs and hæmorrhage into the
-lungs if exposed long enough to the action of HCl, even
-though (according to Lehmann) there may not be accumulation
-of HCl in the blood; the chief effect is the irritant
-one; 1·5-5 per thousand parts HCl in the air suffices, after
-three or four hours’ exposure, to affect smaller animals
-(rabbits) so much that they die during the experiment or
-shortly after it. Man can tolerate an atmosphere containing
-0·1 to 0·2 per thousand HCl; a somewhat greater proportion
-of HCl produces bronchial catarrh, cough, &amp;c.</p>
-
-<p>The solution of hydrochloric acid in water is about 40 per<span class="pagenum"><a name="Page_171" id="Page_171">[171]</a></span>
-cent. Simply wetting the skin with concentrated solution of
-hydrochloric acid does not generally have an irritant effect
-unless persisted in for some time; the action of the acid, when
-continued, has a marked effect upon the mucous membranes
-and upon the eyes.</p>
-
-<p>The same treatment already recommended in the introductory
-remarks on poisoning by inhalation of acid fumes in
-general applies.</p>
-
-<p><b>Hydrofluoric Acid</b> (HFl), a pungently smelling, colourless
-gas, causes even in weak solutions (0·02 per cent.) irritant
-symptoms (catarrh of the mucous membrane of the respiratory
-organs, lachrymation, &amp;c.). Stronger solutions set up
-obstinate ulcers, difficult to heal, in the mucous membrane
-and the skin.</p>
-
-<p><b>Silico-fluoric Acid</b> (H₂SiFl₆) produces an analogous though
-somewhat less marked corrosive action.</p>
-
-<p>As regards treatment the reader is again referred to the
-introductory sentences on this group.</p>
-
-<p><b>Sulphur Dioxide</b> (SO₂) is a colourless, pungently smelling
-gas which, acting in low concentration or for a short period,
-causes cough and irritation of the mucous membrane of the
-respiratory passages and of the eyes; acting for a longer
-period, it sets up inflammation of the mucous membrane,
-bronchial catarrh, expectoration of blood, and inflammation
-of the lungs.</p>
-
-<p>As Ogata and Lehmann have proved by experiments—some
-of them made on man—a proportion of 0·03-0·04 per thousand
-of sulphur dioxide in the air has a serious effect on a person
-unaccustomed to it, while workmen used to this gas can
-tolerate it easily.</p>
-
-<p>As sulphur dioxide probably does not affect the blood,
-treatment by oxygen inhalation is useless. Otherwise the
-treatment spoken of as applying to acid poisonings in general
-holds good.</p>
-
-<p><b>Sulphuric Acid</b> (H₂SO₄). Concentrated sulphuric acid occasionally
-splashes into the eye or wets the skin, causing severe
-irritation and corrosion, unless the liquid is quickly washed
-off or neutralised. If the action of the acid persists, the corrosive
-effect becomes deepseated and leads to disfiguring scars.</p>
-
-<p><b>Nitrous Fumes, Nitric Acid.</b>—Nitric oxide (NO) oxidises in the<span class="pagenum"><a name="Page_172" id="Page_172">[172]</a></span>
-air with formation of red fumes composed of nitrogen trioxide
-(N₂O₃) and nitrogen peroxide (NO₂). These oxides are contained
-in the gases evolved from fuming nitric acid and where nitric
-acid acts upon metals, organic substances, &amp;c.</p>
-
-<p>Industrial poisoning by nitrous fumes is dangerous; unfortunately
-it frequently occurs and often runs a severe, even
-fatal, course; sometimes numerous workers are poisoned
-simultaneously. The main reason why nitrous fumes are so
-dangerous is because their effect, like that of most other
-irritant gases, is not shown at once in symptoms of irritation,
-such as cough, cramp of the glottis, &amp;c., which would at
-least serve as a warning to the affected person; on the contrary,
-generally no effect at all is felt at first, especially if the
-fumes are not very concentrated. Symptoms of irritation
-usually appear only after some hours’ stay in the poisonous
-atmosphere. By this time a relatively large quantity of the
-poisonous gas has been absorbed, and the remote effect on the
-blood induced.</p>
-
-<p>The first symptoms of irritation (cough, difficulty of
-breathing, nausea, &amp;c.) generally disappear when the affected
-person leaves the charged atmosphere, and he then often
-passes several hours without symptoms, relatively well. Later
-severe symptoms supervene—often rather suddenly—difficulty
-of breathing, fits of suffocation, cyanosis, and copious frothy
-blood-stained expectoration with symptoms of inflammation
-of the bronchial tubes and lungs. These attacks may last a
-longer or shorter time, and in severe cases can lead to death;
-slight cases end in recovery, without any sequelæ.</p>
-
-<p>In poisoning by nitrous acid fumes, oxygen inhalation,
-if applied in time, undoubtedly holds out hope of success,
-and should always be tried. Chloroform has been repeatedly
-recommended as a remedy. Probably its inhalation produces
-no actual curative effect, but only an abatement of the
-symptoms through the narcosis induced.</p>
-
-<p>Nitric acid (HNO₃) in solution has an irritant corroding
-action if, when concentrated, it comes into contact with the
-skin or mucous membrane.</p>
-
-<p><span class="pagenum"><a name="Page_173" id="Page_173">[173]</a></span></p>
-
-<h5>THE HALOGENS (CHLORINE, BROMINE, IODINE)</h5>
-
-<p>Chlorine (Cl) is a yellow-green, pungently smelling gas,
-Bromine (Br) a fuming liquid, and Iodine (I) forms crystals
-which volatilise slightly at ordinary temperatures.</p>
-
-<p>According to Lehmann’s experiments on animals the effect
-of chlorine gas and bromine fumes is completely similar. Lehmann
-and Binz assume that chlorine has a twofold effect:
-(1) narcotic, paralysing the outer membrane of the brain, and
-(2) the well-known irritant action upon the mucous membrane,
-producing a general catarrh of the air passages, and inflammation
-of the lungs; it is, however, only the latter which causes
-menace to life. Other writers do not mention the narcotic
-effect upon the brain and assume that the halogens when
-brought into contact with the mucous membrane are quickly
-converted into halogen hydrides, and, as such, produce a corrosive
-effect. According to Lehmann, even 0·01 per thousand Cl
-or Br in the air is injurious, even 0·1 per thousand produces
-ulceration of the mucous membrane, and one or two hours’ exposure
-to the poison endangers life. Lehmann has further tested
-(on dogs) acclimatisation to chlorine, and finds that after a
-month the power of resistance to chlorine appears to be increased
-about ten times. In a further series of experiments the same
-author has proved that even the smallest quantities of chlorine
-present in the atmosphere are completely absorbed in breathing.</p>
-
-<p>Continued or frequent action of chlorine upon the organism
-produces symptoms which have been described as chronic
-chlorine poisoning—such as anæmia and indigestion, in
-addition to catarrhal and nervous symptoms. Further, in
-factories where chlorine is produced by the electrolytic process,
-workers were found to be suffering from the so-called chlorine
-rash (first observed by Herxheimer). This skin disease consists
-in an inflammation of the glands of the skin, with occasional
-development of ulcers and scars. Severe cases are accompanied
-by digestive disturbance. Bettmann, Lehmann, and
-others maintain that it is not caused by chlorine alone,
-but by chlorinated tar products, which are formed in the
-production of chlorine and hydrochloric acid.</p>
-
-<p>In acute cases of chlorine poisoning oxygen treatment should
-be tried, but in any case the patient should have free access to<span class="pagenum"><a name="Page_174" id="Page_174">[174]</a></span>
-pure air. Approved remedies are inhalation of soda spray or
-very dilute ammonia, or of a vapourised solution of sodium
-hypochlorite. If the patient is in great pain, he may be
-allowed to inhale cocaine solution (0·2 per cent.).</p>
-
-<p>The administration of arsenic (solutio arsenicalis) is recommended,
-especially in cases of acne. In general the usual
-treatment for diseases of the skin is followed; salicylic
-acid lotions, sulphur baths, and sulphur ointments may be
-made use of.</p>
-
-<p><b>Chlorides.</b>—<i>Chlorides of Phosphorus</i>, <i>Phosphorus-trichloride</i>
-(PCl₃), and <i>Phosphorus oxychloride</i> (POCl₃), are strong-smelling
-liquids, fuming in the air, and when brought
-into contact with water decomposing into phosphorous
-acid and hydrochloric acid. These halogen compounds of
-phosphorus have a violently irritant action upon the respiratory
-organs and the eyes, in that they decompose on the mucous
-membrane into hydrochloric acid and an oxyacid of phosphorus.
-Inhalation of the fumes of these compounds causes
-cough, difficulty of breathing, inflammation of the respiratory
-passages, and blood-stained expectoration.</p>
-
-<p>Treatment is similar to that for acid poisoning in general
-and hydrochloric acid in particular.</p>
-
-<p>Similar to that of the chlorides of phosphorus is the action
-of <i>chlorides of sulphur</i>, of which <i>sulphur monochloride</i> (S₂Cl)₂
-is of industrial hygienic importance as it is employed in the
-vulcanising of indiarubber. It is a brown, oily, fuming liquid,
-which, mixed with water or even in damp air, decomposes into
-sulphur dioxide and hydrochloric acid. The fumes of sulphur
-monochloride have therefore a marked irritant effect, like
-that of hydrochloric acid and sulphur dioxide. The action of
-sulphur chloride was thoroughly studied by Lehmann. Industrial
-poisoning by sulphur chloride is mentioned by Leymann
-and also in the reports of the Prussian factory inspectors for
-1897. The latter case ended fatally owing to the ignorance of
-the would-be rescuers: a workman had spilt trichloride of
-phosphorus upon his clothes, and the by-standers, not knowing
-its dangerous action when combined with water, poured water
-on him.</p>
-
-<p>Treatment is similar to that of poisoning from hydrochloric
-acid or sulphur dioxide.</p>
-
-<p><span class="pagenum"><a name="Page_175" id="Page_175">[175]</a></span></p>
-
-<p><i>Chloride of zinc</i> (zinc chloride, ZnCl₂) likewise has corroding
-and irritant action upon the mucous membrane of the
-respiratory organs.</p>
-
-<h5>AMMONIA</h5>
-
-<p>Ammonia (NH₃) is a colourless, pungent-smelling gas which
-dissolves to the extent of about 33 per cent. in water. Inhaled,
-it first produces violent reflex coughing, then irritation
-and corrosion of the mucous membrane of the respiratory
-organs, and finally death through suffocation (spasm of the
-glottis) if exposure to its action has lasted a sufficiently long
-time. Microscopic sections exhibit a diphtheritic appearance
-of the mucous membrane, and inflammation of the lungs. The
-effects upon the central nervous system (irritation of the
-medulla and spinal cord) which are peculiar to ammonia
-compounds need not be considered, as the corrosion of the
-respiratory passage is sufficient alone to cause death. When
-the action of the gas is less intense, the patient rallies from the
-first stage, but often severe symptoms come on later affecting
-the lungs.</p>
-
-<p>Lehmann in experiments upon himself could tolerate as
-much as 0·33 per thousand NH₃ for thirty minutes; he found
-in gas works (with fairly marked odour) hardly more than
-0·1 per thousand NH₃ in the atmosphere, and considers 0·5
-per thousand distinct evidence of excess. He found that he
-could produce in dogs acclimatisation up to 1·0 per thousand
-NH₃ (five times as much as could at first be borne). About 88
-per cent. of the ammonia contained in the air is absorbed
-in breathing; ammonia is said to exercise also a reducing
-action upon the oxygen of the blood (oxyhæmoglobin).</p>
-
-<p>Chronic poisoning by ammonia can hardly be said to occur.
-In those who clean out sewers and drains, the inflammation
-of the eyes and digestive disturbance attributed partly to
-ammonia are probably due more to the action of sulphur
-compounds—ammonium sulphide and sulphuretted hydrogen.
-Irritation due to solution of ammonia does not come into
-account in industrial employment.</p>
-
-<p>As regards treatment, fresh air or administration of oxygen
-is most likely to be successful. Inhalation also of very dilute<span class="pagenum"><a name="Page_176" id="Page_176">[176]</a></span>
-acetic acid vapour, steam, or spray of sodium carbonate is
-advocated.</p>
-
-<h5>ALKALIS</h5>
-
-<p>The alkaline hydroxides (potassium and sodium hydroxide,
-KOH, NaOH) have an albumen-dissolving and therefore
-caustic effect. Industrially it occurs in the caustic action of
-concentrated (often hot) lyes upon the skin or upon the eye—through
-splashing. Quicklime (CaO) has also a caustic
-action, producing inflammation of the skin or eyes (especially
-in those engaged in the preparation of mortar).</p>
-
-<p>Under this head comes also the effect upon the respiratory
-passages—described by several authors—caused in the production
-of artificial manure discussed at length in Part I.</p>
-
-<p>As regards treatment of the irritant effect of alkalis, what
-has been said as to corrosives in general applies here (rinsing
-with water or weak organic acids), and in inflammation of the
-eye caused by lime a drop of castor oil is recommended.</p>
-
-<h4><i>GROUP: METALS AND METAL-COMPOUNDS</i></h4>
-
-<p>The various substances of this group differ markedly
-in their action. Under this heading come principally
-chronic metal poisonings, characterised by a general, often
-very intense, disturbance of nutrition, which justifies their
-delineation as ‘metabolic poisons’; among these poisons also
-are included certain others which produce chronic poisoning
-accompanied by severe disturbance of the peripheral and
-central nervous system.</p>
-
-<p>The corrosive action common to the metal oxides (when
-acting in a concentrated condition), attributable to the
-formation of insoluble albuminates, need not, in industrial
-poisoning, be taken so much into account. The corrosive
-effect is characteristic only of the compounds, especially of
-the acid salts of chromium, which, as an acid-forming element,
-may be classed in the preceding group. Disturbance of health
-in workmen handling nickel compounds are also ascribed to
-the corrosive action of these substances.</p>
-
-<p><span class="pagenum"><a name="Page_177" id="Page_177">[177]</a></span></p>
-
-<h5>LEAD, LEAD COMPOUNDS</h5>
-
-<p>Lead poisoning is the most frequent and important chronic
-industrial poisoning; the symptoms are very varied and
-associated with the most different groups of organs. We shall
-describe the typical course of a case of industrial lead poisoning,
-laying stress, however, on the fact that numerous cases
-follow an irregular course, in that special symptoms or complications
-of symptoms are in some especially accentuated, while
-in others they become less marked or are absent altogether.</p>
-
-<p>A premonitory indication of chronic lead poisoning is a
-blue line on the gum, indicated by a slate gray or bluish black
-edging to the teeth, the appearance of which is usually accompanied
-by an unpleasant sweetish taste in the mouth. The
-cause of this blue line was for some time disputed. It is
-obviously due to the formation and deposit of sulphide of lead
-through the action of sulphuretted hydrogen arising from
-decomposition in the mouth cavity. At the same time a
-general feeling of malaise and weakness often comes on,
-occasionally accompanied by tremor of the muscles and
-disinclination for food, at which stage the sufferer consults the
-doctor. Frequently he complains also of pains in the stomach,
-not difficult to distinguish from the lead colic to be described
-later. Usually the patient already exhibits at this stage
-general emaciation and marked pallor.</p>
-
-<p>The blue line was formerly considered a characteristic early
-indication of lead poisoning; but it has now been proved that
-occasionally it is absent even in severe attacks. But although
-the blue line may fail as an ‘initial symptom,’ it will nevertheless
-be a valuable aid to the practitioner in the recognition
-of lead poisoning. It is worth while to mention the fact that
-other metallic poisons produce a very similar ‘line,’ especially
-mercury, also iron and silver (as in the case of argyria); it has
-been stated that the blue line can be simulated by particles
-of charcoal on the gum. The pallor of the patient at the commencement
-of lead poisoning drew attention to the condition
-of the blood. The diminution in the amount of hæmoglobin
-often met with, which under certain circumstances is accompanied<span class="pagenum"><a name="Page_178" id="Page_178">[178]</a></span>
-by diminution of the red blood cells, offers nothing
-characteristic. On the other hand, structural changes in the
-red blood cells—presence of basophil granules in them—are
-asserted by a number of writers to be characteristic of the first
-stages of lead poisoning. The basophil granules are believed
-to be due to regenerative changes in the nucleus. But these
-changes are also found in pernicious anæmia, cancer, leucæmia,
-anæmia, tuberculosis, &amp;c.; also in a number of poisonings such
-as phenylhydrazine, dinitrobenzene, corrosive sublimate, and
-others; they are therefore the less characteristic of chronic
-lead poisoning, as occasionally they cannot be found in actual
-lead poisoning, a point upon which I have convinced myself
-in the case both of men and animals. Still, the appearance of
-much basophilia in the red blood cells is a valuable aid to
-diagnosis, especially as the method of staining to demonstrate
-them is simple.</p>
-
-<p>Other anomalies of the blood observed in lead poisoning
-may here be mentioned. Glibert found a striking diminution
-in the elasticity of the red blood corpuscles, and experiments
-I have made point to the fact that the power of resistance
-of the red blood corpuscles to chemically acting hæmolytic
-agents, such as decinormal soda solution, is considerably
-reduced.</p>
-
-<p>The pulse is generally hard and of high tension, especially
-during the attacks of colic. Further, cramp of the bloodvessels
-(also in the retinal arteries) has been observed. To
-these functional disturbances in the circulation are added
-sometimes definite changes in the vessel wall. Later,
-obliterative arteritis comes on (in the brain arteries), and
-arteriosclerosis.</p>
-
-<p>The most important symptom of fully developed lead
-poisoning is colic, which is usually preceded by the initial
-symptoms described (especially the gastric symptoms), but not
-always so, as occasionally colic sets in without any warning.
-The colic pains often set in with marked vehemence. They
-radiate from the navel on all sides, even through the whole
-body; the abdomen is contracted and as hard as a board.
-Pressure on the lower part diminishes the pain somewhat,
-so that the sufferer often involuntarily lies flat on his<span class="pagenum"><a name="Page_179" id="Page_179">[179]</a></span>
-stomach. During the attack the pulse is often remarkably
-slow. Constipation occurs, and often does not yield to purgatives.
-The attacks last sometimes for hours, occasionally for
-days, or the pains can (with remissions) even distress the
-patient for weeks. The frequency of attacks is also very
-variable. Occasionally one attack follows another, often
-there are intervals of weeks, even years, according to the
-severity of the poisoning and duration of exposure. If the
-patient is removed from the injurious action of lead, as a rule
-recovery soon ensues.</p>
-
-<div class="figcenter" style="width: 400px;" id="fig34">
-
-<img src="images/fig34.jpg" width="400" height="375" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 34.</span>—Paralysis of the Ulnar Nerve in Lead Poisoning</p>
-
-</div>
-
-<div class="figcenter" style="width: 500px;" id="fig34a">
-
-<img src="images/fig34a.jpg" width="500" height="400" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 34a.</span>—Different Types of Paralysis of the Radial Nerve in Hungarian Potters
-poisoned by Lead (<i>after Chyzer</i>)</p>
-
-</div>
-
-<p>Often with the colic, or at any rate shortly after it, appear
-lead tremor and arthralgia, paroxysmal pain mostly affecting
-the joints, but occasionally also the muscles and bones. They
-are often the precursor of severe nervous symptoms which
-affect the peripheral and central nervous system. In a lead
-poisoning case running a typical course the predominant
-feature is the peripheral motor paralysis of the extensors of<span class="pagenum"><a name="Page_180" id="Page_180">[180]</a></span>
-the forearms. Next the muscles supplied by the radial and
-ulnar nerves are affected. Often the progress of the paralysis
-is typical; it begins with paralysis of the extensor digitorum
-communis, passes on to the remaining extensors, then to the
-abductor muscles of the hand; the supinator longus and triceps
-escape. Sometimes the shoulder muscles are attacked;
-also paralysis in the region supplied by the facial nerve and
-of the lower extremities is observed. It appears plausible
-that overstrain of single groups of muscles plays a decisive
-part; this seems proved by the fact that paralysis first affects,
-among right-handed people, the right hand (especially of
-painters), but in the case of left-handed, the left hand;
-and among children the lower extremities are often attacked
-first. Disturbance of sight increasing to amaurosis is often
-an indication of severe brain symptoms. The view of some
-writers that the cause of the sight disturbance lies in vasomotor<span class="pagenum"><a name="Page_181" id="Page_181">[181]</a></span>
-influences (cramp of the bloodvessels) is very probable,
-and supports the view that the brain symptoms are entirely
-due to diseases of the arteries (arteritis). These symptoms
-are distinguished by the collective name of saturnine
-encephalopathy; they include apoplexy, hemiplegia, epilepsy,
-delirium, and mania. The brain symptoms may cause death.</p>
-
-<p>As later symptoms of lead poisoning may be mentioned
-lead gout and kidney disease (lead nephritis). The genesis of
-both these diseases is much disputed. It seems to be proved
-that the gout is true gout (with presence of tophi) and that the
-contracted kidney is indistinguishable from ordinary chronic
-Bright’s disease.</p>
-
-<p>The kidney symptoms suggest that a regular excretion of
-lead through the urine takes place which, if it were a fact,
-would have been an important aid to diagnosis. But often
-analysis of urine for presence of lead is negative. Excretion of
-lead by the skin is scarcely to be credited, although occasionally
-affirmed. Elimination of lead is effected mainly through
-the intestines (probably for the most part as sulphide of
-lead).</p>
-
-<p>All lead compounds more or less are to be regarded as poisonous,
-although the intensity of the action depends on the amount
-absorbed. For this its solubility in water or in weak acids
-(hydrochloric acid of the gastric juice) is the simplest test.
-According to this acetate of lead, lead chloride, carbonate
-of lead (white lead), oxide of lead (lead dross), minium
-(red oxide of lead) are relatively the most poisonous. Lead
-sulphate and lead iodide are to be regarded as relatively less
-poisonous, although by no means innocuous. The least
-poisonous, if not altogether innocuous, is sulphide of lead,
-because it is an insoluble lead compound.</p>
-
-<p>Treatment of lead poisoning ought to aim first and foremost
-at the elimination of lead from the body. But unfortunately
-such attempts have had little success. Treatment of symptoms
-is all that for the most part is possible. Administration of
-iodide of potassium to assist the excretion of lead has not been
-found the success which many anticipated. This remedy
-however, can be tried; better results are to be expected
-from careful regulation of the bowels by means of purgatives.<span class="pagenum"><a name="Page_182" id="Page_182">[182]</a></span>
-During colic administration of opium or morphia may be
-advisable to relieve pain and overcome the probable cramp
-of the intestinal muscles. The cautious administration of
-atropine (occasionally with cocaine) also serves the same
-purpose. Hot compresses and mustard plasters may be
-applied, and liquid diet should be given. Lead cachexia
-must be treated by strengthening diet. Electrical treatment
-for lead paralysis is advocated. From baths (sulphur baths)
-nothing more is to be expected than a bracing effect—elimination
-of lead through increased diaphoresis is hardly to be
-hoped for.</p>
-
-<h5>ZINC (ZINC ALLOYS)</h5>
-
-<p>Zinc (Zn) melts at 412° C. and distills at about 900° C.;
-exposed to the air it burns, when heated, into zinc oxide.
-Older writers, when investigating gastric and intestinal diseases
-and affections of the nervous system observed in zinc smelters,
-regarded them as the result of chronic zinc poisoning; but it
-may now be accepted as certain that these symptoms are due
-to the lead always present in the zinc.</p>
-
-<p>On the other hand so-called <i>brass-founders’ ague</i> may be
-regarded as a form of acute industrial zinc poisoning. Brass-founders’
-ague occurs exclusively in brass casters, and not in
-zinc workers. Sigel and Lehmann have shown that founders’
-ague is also caused by pure zinc if this is heated so strongly
-that it burns.</p>
-
-<p>Premonitory symptoms often occur before the onset of
-the disease; usually they appear early, soon after casting
-has begun. The workman has general malaise accompanied
-by slight cough, nausea, throat irritation, &amp;c., but these
-symptoms mostly disappear, returning again after a few hours
-with renewed violence, often in the evening before going to
-bed. Frequently, trembling sets in rather suddenly, often
-accompanied by headache, nausea, and muscular pains, and
-soon develops into a pronounced shivering fit, lasting
-generally about a quarter of an hour, but in severe cases
-for several hours (with intervals). At the same time
-the breathing is hurried and the heart’s action quickened<span class="pagenum"><a name="Page_183" id="Page_183">[183]</a></span>
-(asthma and palpitation). Often the temperature rises as
-high as 104° F. The attack ends with profuse perspiration,
-and the patient sinks exhausted to sleep, awaking in the
-morning generally quite restored or with but slight signs of
-fatigue; only rarely is he unable to resume work.</p>
-
-<p>It is noteworthy that some workmen are extraordinarily
-susceptible to brass-founders’ ague, and are attacked again
-and again, while others remain completely immune, so that
-idiosyncrasy and immunity both play a part. Workmen
-who are susceptible to the disease, yet without marked disposition
-(idiosyncrasy) towards it, can become acclimatised
-to the poison. Lehmann has succeeded in artificially producing
-an attack in a brass-caster who was highly susceptible.
-The symptoms in him were the result of work with pure zinc
-in a burning condition. The proof, therefore, is clear that
-brass-founders’ ague is due to zinc, and not, as some authors
-have supposed, to copper or the simultaneous action of both
-metals. The symptoms are produced through inhalation of
-zinc oxide, not zinc fumes.</p>
-
-<p>Lehmann conjectures that brass-founders’ ague may be a
-secondary fever due to absorption into the system of the remains
-of cells in the respiratory tract that have been killed by the
-action of the zinc.</p>
-
-<p>The treatment can only be symptomatic; as the attack
-is so transient, medical attendance is hardly necessary.</p>
-
-<h5>MERCURY, MERCURY COMPOUNDS</h5>
-
-<p>Mercury (Hg), on account of its volatility, is classed
-among industrial poisons. Although boiling at 360° C. it is
-volatile even at ordinary temperature. Industrial mercurial
-poisoning is caused by the frequent inhalation of small quantities
-of vapour, sometimes, but more rarely, of dust containing
-mercury, and assumes usually a chronic form.</p>
-
-<p>Industrial mercurial poisoning often begins with inflammation
-of the mucous membrane of the mouth and gums.
-There is increased flow of saliva, a disagreeable metallic
-taste in the mouth, and foul breath. This may be limited
-to a simple inflammation of the gum, or go on to ulceration<span class="pagenum"><a name="Page_184" id="Page_184">[184]</a></span>
-with falling out of teeth, or even to gangrene of the gum
-and mucous membrane inside the mouth. Gastric attacks
-also occur in the early stages; occasionally, however, they
-are absent.</p>
-
-<p>The main symptoms of chronic mercurial poisoning are
-nervous and psychical derangement, to which in severe cases
-are added general disturbance of digestion and loss of strength.</p>
-
-<p>Sometimes, after repeated attacks, more or less severe,
-a cachectic condition is induced, showing itself in general
-emaciation, decrease of strength, atrophy of the muscles,
-anæmia, and disturbed digestion, which—often intensified
-by some intercurrent disease, such as tuberculosis—lead to
-death. Slight cases of mercurialism recover, leaving no evil
-results, if the patient is removed in time from the influence
-of the poison.</p>
-
-<p>The treatment of chronic mercury poisoning is symptomatic.
-To allay the inflammation of the mucous membrane of the
-mouth the patient should use a mouth wash of potassium
-chlorate and peroxide of hydrogen; the general condition
-should be raised by strengthening, unstimulating food; for
-the nervous symptoms baths and electricity should be tried;
-and for very marked erythism and tremor recourse to narcotics
-may be necessary.</p>
-
-<p>Industrial mercurial poisoning is produced not only by
-metallic mercury but also by many compounds, of which
-industrially the oxides are the most important. Nitrate of
-mercury (Hg₂(NO₃)₂) comes into account in the treatment of
-fur. Mercury cyanide (HgCy₂) deserves mention, as small
-quantities cause mercurial and large quantities cyanogen
-poisoning.</p>
-
-<h5>MANGANESE, MANGANESE COMPOUNDS</h5>
-
-<p>Manganese (Mn) or manganese compounds are used
-industrially in fine powder; continuous absorption of dust
-containing manganese produces chronic manganese poisoning.
-Instances of such poisoning are not very numerous; altogether
-about twenty cases have been described. Recent publications
-agree in asserting that only the dust rich in manganese
-protoxide is dangerous.</p>
-
-<p><span class="pagenum"><a name="Page_185" id="Page_185">[185]</a></span></p>
-
-<p>Industrial manganese poisoning runs its course extraordinarily
-slowly, and resembles chronic poisoning by other
-heavy metals, such as lead and mercury, in that nervous and
-psychical symptoms, rather than digestive, are prominent.
-Sometimes—but not always—the disease is introduced or
-accompanied by psychical symptoms, both of excitement and
-depression (hilarity, laughing, or depression and weeping).
-In the course of the disease nervous disturbances arise, deafness,
-tingling, paralysis and paræsthesia, in the arms and legs,
-giddiness, difficulty of walking, tremor, increased knee-jerks
-and difficulty in speech. Often at the same time swelling of
-the lower extremities (œdema) and loss of strength (cachexia,
-marasmus) come on. Slight cases make a good recovery.
-An interesting case of illness is described by Jaksch as manganophobia,
-in which the symptoms were simulated, and
-were brought on solely by the fear of manganese poisoning.</p>
-
-<p>As regards treatment, electricity, massage, and baths are
-advocated to allay the nervous symptoms, as in the case of
-chronic metal poisoning and suitable strengthening food.</p>
-
-<h5>CHROMIUM, CHROME COMPOUNDS</h5>
-
-<p>Chromium trioxide (CrO₃) dissolves in water, forming
-chromic acid (H₂CrO₄); of the salts of chromic acid the
-neutral and acid alkaline salts concern our inquiry. These
-are normal and acid sodium or potassium chromate (K₂CrO₄
-and K₂Cr₂O₇). Chromate of lead (PbCrO₄) can cause lead
-poisoning.</p>
-
-<p>Poisoning can be produced by dust and by alkaline
-chromates, the latter, when hot, giving off steam which, as
-has been proved, contains excessively fine chrome particles.
-Chrome compounds attack especially the surface of the body,
-the skin and the mucous membrane.</p>
-
-<p>The bichromate and chromate dust produce ulcers where
-slight injuries to the skin already exist. The ulcers develop
-slowly, and have a smooth, heaped-up, undermined edge;
-deep-seated, they can even pierce to the bone; they heal with
-great difficulty. Naturally they occur most frequently on the
-uncovered parts of the body, especially on the arms and<span class="pagenum"><a name="Page_186" id="Page_186">[186]</a></span>
-hands. Characteristic also is an analogous ulceration attacking
-the mucous membrane of the nose, from which hardly any
-chrome worker (especially if brought into contact with
-chromate dust) is free. Perforation and destruction of the
-cartilaginous septum of the nose is very common. Ulcers
-on the mucous membrane at the entrance of the throat (on
-tonsils and palate or in the larynx) have been occasionally
-observed.</p>
-
-<p>Absorption of small quantities of chrome compounds into
-the body are said to cause disturbances of digestion of an
-inflammatory character, and especially inflammation of the
-kidneys.</p>
-
-<p>The treatment of chrome ulcers is similar to that of other
-chronic ulcers. An antidote for industrial chrome poisoning is
-not known.</p>
-
-<h5>OTHER METALS AND METAL COMPOUNDS</h5>
-
-<p><b>Nickel Salts.</b>—Of late years in nickel-plating establishments
-an eczematous inflammation of the skin has been described
-affecting first of all the hands, and occasionally spreading over
-the arms and even the whole body. The skin becomes inflamed,
-and vesicles appear on the affected part. Some persons are
-extraordinarily susceptible to this disease, others only become
-so after having worked for years quite unaffected, and are then
-obliged to give up their occupation. Probably the action of
-nickel salts (especially nickel sulphate) used in electrolytic baths
-causes the disease. But it was in fact traced by several writers
-to contact with benzene, petroleum, and lime by the workmen.
-The simultaneous action of these substances upon the skin
-would no doubt encourage its appearance. The application
-to the skin of vaseline or cream is recommended. Careful
-cleanliness and attention to the skin is on the whole by far
-the most reliable protection.</p>
-
-<p>[<b>Nickel carbonyl</b> (Ni(CO)₄).—Mond, Langer, and Quincke
-in 1890 discovered that, on passing a current of carbon
-monoxide over finely divided (pyrophoric) metallic nickel, a
-gaseous compound of nickel and carbon monoxide was formed.
-When heated to 150° C. the gas decomposes into its constituents
-and metallic nickel is deposited.</p>
-
-<p><span class="pagenum"><a name="Page_187" id="Page_187">[187]</a></span></p>
-
-<p>Nickel carbonyl is a clear, pale straw-coloured liquid,
-volatilising at room temperature. It has a peculiar soot-like
-smell detectable when present to the extent of about 1 vol. in
-2,000,000, while the Bunsen flame becomes luminous when
-nickel carbonyl is present in the air to the extent of 1 vol. in
-400,000—two facts of great importance in detecting escape
-of the gas in the manufacture of pure nickel by the Mond
-process.</p>
-
-<p><i>Occurrence of poisoning by nickel carbonyl.</i>—At the first
-introduction of the process about 1902, before the dangerous
-properties of the gas had been sufficiently recognised, some
-twenty-five men were poisoned, of whom three died. Poisoning
-only occurred when, as a result of the breakdown of the automatic
-working of the plant, hand labour took the place of
-machinery.</p>
-
-<p>This very rare form of poisoning has been very fully investigated
-by H. W. Armit (<i>Journ. of Hygiene</i>, 1907, p. 526, and
-1908, p. 565). The symptoms in man, he says, were transient
-headache and giddiness and at times dyspnœa, quickly passing
-off on removal to fresh air. After from twelve to thirty-six
-hours the dyspnœa returned, cyanosis appeared, and the
-temperature began to be raised. Cough with more or less
-blood-stained sputum appeared on the second day. The
-pulse rate became increased, but not in proportion to the
-respiratory rate. The heart remained normal. Delirium of
-varying types frequently occurred. Death took place in the
-fatal cases between the fourth and eleventh days. The chief
-changes found post mortem were hæmorrhages in the lungs,
-œdema of the lungs, and hæmorrhages in the white matter of the
-brain, while some doubt exists as to whether any blood changes
-were present.</p>
-
-<p>Precisely analogous results were found in experiments on
-animals (rabbits, cats, and dogs).</p>
-
-<p>The points Armit investigated experimentally were (1) Is the
-carbon monoxide of the compound wholly or partly responsible
-for the symptoms, or (2), is nickel carbonyl absorbed as such,
-or (3), is it the nickel of the compound which produces the
-symptoms? His conclusions are that the poisonous effects
-of nickel carbonyl are entirely due to the nickel of the
-compound. The peculiar toxicity is due to the fact that,<span class="pagenum"><a name="Page_188" id="Page_188">[188]</a></span>
-being introduced in a gaseous form, the nickel is deposited
-as a slightly soluble compound in a very fine state of subdivision
-over the immense area of the respiratory surface.
-Nickel carbonyl when mixed with air cannot be absorbed as
-such by an animal as it becomes split up into the nickel containing
-substance (possibly hydrated basic carbonate of nickel)
-and carbon monoxide before or soon after reaching the alveoli
-of the lungs. The nickel is dissolved from the respiratory
-surface by the tissue fluids and is then taken up by the blood.
-The hæmorrhages found after death follow as the result of fatty
-degeneration of the vessel walls which is the specific pathological
-change set up by nickel.]</p>
-
-<p><b>Copper.</b>—Symptoms which have been described by some
-writers as chronic industrial copper poisoning are probably
-due to admixtures of other poisonous metals, especially lead
-and arsenic. Although some copper workers, especially those
-careless of cleanliness, exhibit hair and teeth coloured by the
-action of copper compounds (green tinge on hair and edge
-of teeth), symptoms of illness traceable to copper are not
-demonstrable.</p>
-
-<p><i>Brass-founders’ fever</i>, which by some earlier writers was
-ascribed to copper or combined copper and zinc action, is
-traceable to zinc (see Zinc).</p>
-
-<p><b>Ferro-silicon.</b>—The illnesses due to this are phosphoretted
-or arseniuretted hydrogen poisoning (see pp. <a href="#Page_191">191</a> and <a href="#Page_197">197</a>).</p>
-
-<p><b>Silver and Silver Compounds.</b>—Gradual absorption of small
-quantities of a solution of silver may produce industrial
-argyria, often beginning with the appearance of a black
-edge to the gums and darkening of the hair and nails,
-followed by black spots on the skin which in severe cases
-coalesce, so that the whole or almost the whole surface of the
-body becomes black and glossy.</p>
-
-<p>Argyria is due to the absorption of silver compounds
-into the circulation, and subsequent deposition of the reduced
-silver in the body (liver, kidneys, spinal cord, &amp;c.). The
-black colouring of the skin is caused by the action of light.</p>
-
-<p>No interference with health worth mentioning is observed.</p>
-
-<p><span class="pagenum"><a name="Page_189" id="Page_189">[189]</a></span></p>
-
-<h4><i>GROUP: ARSENIC, PHOSPHORUS</i></h4>
-
-<p>The poisons (gradually absorbed) belonging to this group
-are mainly such as affect metabolism; they impair the
-processes essential to metabolism (in especial the oxidation
-processes) and cause severe damage to the cells, through
-destruction of albumen. The poisons of this group also have
-a paralysing effect upon the central nervous system.</p>
-
-<p>Generally speaking the effects produced by the poisons of
-this group vary considerably. Among the arsenic compounds
-arseniuretted hydrogen, which is supremely a blood poison,
-must be excluded from the group and included among the
-blood poisons.</p>
-
-<h5>ARSENIC, OXIDES OF ARSENIC</h5>
-
-<p>Pure <i>metallic arsenic</i> (As) is considered innocuous. <i>Oxides
-of arsenic</i> especially are held to be industrial poisons such as
-arsenic trioxide (As₂O₃), the anhydride of arsenious acid
-(H₃AsO₃), a white powder, which is known under the name of
-white arsenic; <i>arsenic acid</i> (H₃AsO₄), which forms crystals easily
-soluble in water, and the salts of these acids, especially copper
-arsenite, formerly employed in the production of dyes, and
-also <i>arsenic chloride</i> (arsenic trichloride, AsCl₃). <i>Arseniuretted
-hydrogen</i> will be treated separately as it has a completely
-different poisonous effect from that of the oxidic compounds of
-arsenic. <i>Arsenic sulphides</i> (realgar, AsS₂, and orpiment, AsS₃)
-are regarded as innocuous in consequence of their insolubility
-in a pure state. But it may be remarked that arsenic sulphides
-(sulphur arsenic ores) which are used industrially, and even
-metallic arsenic, are to be considered poisonous, as they contain
-oxidic arsenic compounds in great quantity.</p>
-
-<p>Chronic arsenical poisoning is caused by gradual absorption
-through the respiratory or digestive tracts of small quantities
-of the oxidic arsenic compounds either in solution or as dust
-or fumes.</p>
-
-<p>The disease usually begins with digestive derangement which
-shows itself in more or less severe gastric and intestinal catarrh
-(loss of appetite, vomiting and diarrhœa); sometimes there<span class="pagenum"><a name="Page_190" id="Page_190">[190]</a></span>
-are severe affections of the respiratory tract,—pharyngeal
-and bronchial catarrhs; often the illness is accompanied by
-skin affections of various kinds, rashes, pustular eczema,
-loosening of the nails, abscesses, dark pigmentation of particular
-parts of the skin, and other symptoms. The nervous symptoms
-vary much according to the severity of the disease; first of
-all, deafness and feeling of pins and needles, or loss of sensation
-(paræsthesia and anæsthesia) of the extremities. Further,
-rheumatic joint pains, weakness of the extremities and
-characteristic symptoms of paralysis occur, with accompanying
-atrophy of the muscles, and gradual loss of energy
-leading to total incapacity for work. Severe cases end in
-general exhaustion and loss of strength, with signs of severe
-injury to the central nervous system, such as epileptic fits,
-mental hebetude, &amp;c.</p>
-
-<h5>PHOSPHORUS</h5>
-
-<p><i>Phosphorus</i> (P) is polymorphic; red (amorphous) phosphorus
-is innocuous, while white or yellow is poisonous.
-Phosphorus at various stages of oxidation is little if at all
-poisonous. White phosphorus is volatile and fumes in the
-air—the fumes consisting of phosphorus, phosphoric and
-phosphorous acids.</p>
-
-<p>Chronic industrial phosphorus poisoning is produced by
-continued inhalation of the fumes of white phosphorus
-resulting in inflammation of the periosteum of the bone,
-with which necrosis and formation of new bone are associated.
-It attacks especially the lower jawbone (ossifying periostitis).
-The inflammation begins with increased flow of saliva, painful
-swelling of the gums, which, as it increases, brings about the
-death of the jawbone (necrosis, phosphorus necrosis). This
-becomes covered again with newly formed bone substance
-from the periosteum. The process ends with the formation
-of a fistula (a passage filled with pus), which discharges
-outwards, and through which the dead bone (sequestrum) is
-eventually cast off. Occasionally the process attacks the
-upper jaw, rarely other bones.</p>
-
-<p>With these characteristic symptoms of phosphorus
-necrosis, derangement of nutrition together with anæmia,<span class="pagenum"><a name="Page_191" id="Page_191">[191]</a></span>
-indigestion and bronchial catarrh, may be associated. Further,
-a general brittleness of the bones (fragilitas ossium) is
-observed with the result that the long bones of the leg or
-arm sometimes break at relatively small exertion of force;
-such cases from Bohemia came lately under my notice.</p>
-
-<p>Some authorities regard caries of the teeth as the pre-disposing
-cause of phosphorus necrosis; according to this
-view the carious teeth constitute the means of entrance for
-the poison. Opposed to this so-called ‘local’ theory is the
-view that chronic phosphorus poisoning is a ‘general’ one.
-The truth may lie midway. On the one hand phosphorus
-necrosis probably arises partly from the general poisonous
-action of the phosphorus, and on the other from local
-inflammation which leads to the occurrence of local symptoms.
-The general symptoms of chronic phosphorus poisoning
-described above support this view, especially the effect
-observed on the bones of the skeleton. This view is also
-strengthened by the fact that workmen with perfectly
-sound teeth, who had been exposed to phosphorus fumes
-for many years, were attacked by necrosis only when
-traumatic inflammation produced by chance injury was set
-up.</p>
-
-<p>The treatment of phosphorus necrosis is surgical. Formerly
-the treatment recommended was to wait for formation of new
-bone and exfoliation of the dead bone (expectant treatment);
-the necrosed portions of bone were then extracted through
-the fistula. Recently early operative interference has succeeded
-in preserving the periosteum which enabled the new
-bone to form.</p>
-
-<h5>Phosphoretted Hydrogen</h5>
-
-<p>Industrial poisoning by gaseous phosphoretted hydrogen
-(PH₃) calls for attention in connection with the preparation
-and employment of calcium carbide (acetylene) and also of
-ferro-silicon.</p>
-
-<p>Phosphoretted hydrogen is a dangerous poison. Even
-0·025 per cent. in the air is harmful to animals after a time;
-0·2 per cent. PH₃ in the air quickly causes death.</p>
-
-<p>The poison produces changes in the lungs, though without<span class="pagenum"><a name="Page_192" id="Page_192">[192]</a></span>
-injuring the respiratory passages by corrosion, and finally has
-a paralysing effect upon the central nervous system. It has
-no effect upon the blood. An autopsy on a person who has
-died of phosphoretted hydrogen poisoning reveals as a rule no
-characteristic sign, except centres of inflammation in the lungs.</p>
-
-<p>The symptoms of phosphoretted hydrogen poisoning are—difficulty
-of breathing, cough, fainting fits, noises in the ears,
-and nausea; in severe cases coma and death. Slight cases
-soon recover without after-effects.</p>
-
-<h4><i>GROUP: SULPHURETTED HYDROGEN, CARBON BISULPHIDE,
-AND CYANOGEN (NERVE POISONS)</i></h4>
-
-<p>In this group are comprised industrial poisons the principal
-effect of which is upon the nervous system, especially the central
-nervous system. The chemical composition of the separate
-members of the group differs much.</p>
-
-<h5>SULPHURETTED HYDROGEN</h5>
-
-<p>Industrial poisoning by pure sulphuretted hydrogen (SH₂),
-the well-known colourless, nauseous-smelling gas, occurs comparatively
-rarely. Poisoning is generally acute, but chronic
-illness in workers has been traced back to inhalation of
-the gas.</p>
-
-<p>This poison exerts a paralysing action upon the central
-nervous system and is slightly irritating to the mucous membranes
-and respiratory organs.</p>
-
-<p>Its action can be described as follows: When absorbed
-into the blood union of the poison with the alkaline constituents
-takes place with formation of an alkaline sulphide. Presence
-of only slight quantities of sulphuretted hydrogen in the air acts
-injuriously. Lehmann has shown that about 0·15 to 0·2 per
-thousand sulphuretted hydrogen is not without effect, and that
-prolonged inhalation of 0·5 per thousand becomes dangerous.
-Continued exposure to the poison seems only to increase
-susceptibility to its action. An almost complete absorption
-of the whole of the sulphuretted hydrogen present in the air
-breathed takes place.</p>
-
-<p><span class="pagenum"><a name="Page_193" id="Page_193">[193]</a></span></p>
-
-<p>Continued inhalation of small quantities of sulphuretted
-hydrogen produces irritation of the mucous membrane, cough,
-and lacrymation; headache, giddiness, nausea, and mental
-dulness soon ensue; occasionally also symptoms of intestinal
-catarrh follow; if at this stage—or after a longer exposure
-to the action of a smaller amount—the patient is
-withdrawn from its further influence, there still continue
-for some time symptoms of irritation of the mucous membrane
-(such as inflammation of the conjunctiva and of the
-respiratory passages).</p>
-
-<p>Further exposure or absorption of greater amounts induces
-general discomfort and passes on to a second stage of convulsions
-and delirium.</p>
-
-<p>Inhalation of a large dose of sulphuretted hydrogen causes
-almost instantaneous death; the affected person falls dead—often
-without a sound—as if struck by a blow; occasionally
-a short stage of unconsciousness, with symptoms of suffocation,
-precede death.</p>
-
-<p>This acute form often occurs, especially in acute sewer
-gas poisoning. Besides this, a sub-acute form of sewer gas
-poisoning is recognised which is attributable, in part at least,
-to the action of sulphuretted hydrogen, the prominent symptoms
-being irritation of the mucous membranes and of the
-intestinal canal. In other severe cases symptoms of the central
-nervous system preponderate (headache, giddiness, and
-delirium). These forms of poisoning can be caused not only
-by sulphuretted hydrogen, but also by other poisonous gases
-which are found in drains or sewers.</p>
-
-<p>As regards treatment, continued inhalation of oxygen,
-supported by artificial respiration, is often, in serious cases,
-effective. In severe poisonings also saline injections and
-bleeding may be advocated. Other symptoms (catarrh, &amp;c.)
-must be treated symptomatically.</p>
-
-<h5>CARBON BISULPHIDE</h5>
-
-<p>Pure carbon bisulphide (CS₂) is a colourless, peculiar-smelling
-liquid which boils at 46° C.</p>
-
-<p>As Lehmann has shown, even 1·5 to 3·0 mg. CS₂ per litre of<span class="pagenum"><a name="Page_194" id="Page_194">[194]</a></span>
-air produces distress—with acute symptoms of poisoning
-(congestion, giddiness, sickness, &amp;c.).</p>
-
-<p>Industrial carbon bisulphide poisoning is, however,
-chronic in nature and induced by continuous inhalation of
-small quantities of the fumes. To understand the action of
-carbon bisulphide, its capacity for dissolving fats and fatty
-substances must be taken into account. Its injurious effect
-extends to the nerve tissues (central and peripheral nervous
-system) and the glandular tissues.</p>
-
-<p>Throughout chronic industrial carbon bisulphide poisoning,
-which has been described fully by Delpech, Laudenheimer, and
-others, nervous and psychical symptoms predominate, together
-with severe chronic digestive derangement.</p>
-
-<p>The patient after exposure for some time suffers from
-violent headache, giddiness, and sickness; he has sensations
-of cold, pains in the limbs, a feeling of ‘needles and pins,’ and
-itching in different parts of the body. Gradually a condition of
-general excitement develops. Sleeplessness, cramps, and palpitation
-set in. At the same time the nervous system becomes
-involved—hypersensitiveness, loss of sensation or complete
-numbness of some parts of the skin, diminution of muscular
-power, disturbances of movement, twitching, violent trembling,
-wasting of the muscles, and paralysis; the sight also is sometimes
-affected. The stage of excitement, in which the patient
-often becomes strikingly loquacious without cause, passes
-gradually, as the nervous symptoms develop, into the stage
-of depression; sometimes this takes weeks and months;
-excitement and gaiety give place to deep depression; other
-symptoms appear—weakness of memory, mental dulness,
-and difficulty in speaking. The powers of sensation become
-affected, paralysis increases, and digestive disturbances,
-anæmia, and general loss of strength are manifest. Occasionally
-definite mental disease (psychosis, mania, melancholia,
-dementia, &amp;c.) develops.</p>
-
-<p>Certain cases of chronic carbon bisulphide poisoning in
-indiarubber workers have come under my notice, and some
-remarks concerning them may be of interest. The characteristic
-symptoms are essentially as follows: the invalid
-appears in the consulting-room in a bent position, leaning upon
-a stick with head and hands shaking. The gait is clumsy<span class="pagenum"><a name="Page_195" id="Page_195">[195]</a></span>
-(spastic-paralysis) so that the patient ‘steps’ rather than walks.
-When seated, the tremor ceases to some extent, but in purposive
-movements increases rapidly, involving the whole body,
-so that an exact systematic examination becomes impossible,
-and the invalid sinks back into the chair exhausted and bathed
-in perspiration. He complains of cold in the extremities. He
-looks pale; the skin of the upper extremities is totally without
-feeling, as also is the upper part of the feet; the skin of the
-head is hypersensitive; the muscular strength of the arms
-is almost lost; testing the strength brings on marked shaking,
-followed by a fainting-fit caused by exhaustion. The
-extremities of the patient are cyanotic (livid); the knee
-jerks are exaggerated. The patient suffers from indigestion,
-constipation, headache, and giddiness; he is irritable, and
-depressed; his memory is weak; mental derangement cannot
-be proved.</p>
-
-<p>Chronic carbon bisulphide poisoning is rarely fatal. Slight
-cases end in recovery after more or less long continuance; in
-severe cases improvement occasionally takes place, but serious
-nervous disturbance (paralysis, weakness of the muscles,
-deterioration of intellect) usually persists.</p>
-
-<p>Treatment is symptomatic, aiming especially at relieving
-the nervous symptoms and improving the state of nutrition.
-If psychical disturbances are prominent, treatment in an
-institution is necessary.</p>
-
-<h5>CYANOGEN AND CYANOGEN COMPOUNDS (CYANOGEN GAS,
-PRUSSIC ACID, CYANIDES)</h5>
-
-<p>Industrial cyanogen poisoning is not frequent. <i>Cyanogen
-gas</i> (C₂N₂, existing in small quantities in furnace gas, illuminating
-gas, and other kinds of gas) and especially <i>hydrocyanic acid</i>
-(CNH, prussic acid) are considered industrial poisons; the
-latter is a very unstable, colourless, pungent-smelling liquid,
-boiling at 27° C. Among the cyanides employed industrially
-and having an effect similar to that of prussic acid must be
-mentioned <i>cyanide of potassium</i> and <i>cyanide of sodium</i> (KCN
-and NaCN), <i>cyanide of silver</i> (AgCN) and <i>cyanide of mercury</i>
-(Hg[CN]₂).</p>
-
-<p><span class="pagenum"><a name="Page_196" id="Page_196">[196]</a></span></p>
-
-<p>Cyanogen and cyanogen compounds are extraordinarily
-powerful poisons. The minimum dose lies, as Lehmann has
-proved by experiments on animals, at about 0·05 per thousand
-of hydrocyanic acid in the atmosphere breathed; 1-5 mg. per
-kg. weight is fatal to animals; to man about 60 mg. would be
-fatal.</p>
-
-<p>The poisonous action of cyanogen and cyanogen compounds
-depends upon their power of preventing absorption of oxygen
-from the blood by the tissues with the result that the venous
-blood flowing to the heart retains the bright red colour which
-otherwise only arterial blood exhibits. This effect is due to
-cessation of the gaseous exchange in the body, and results
-in tissue suffocation. At the same time these poisons have at
-first an exciting and then a paralysing effect upon the central
-nervous system. In severe poisoning the nerve effect is
-masked by the effect upon the exchange of gases in the blood,
-since this quickly leads to death.</p>
-
-<p>Most of the cases of industrial poisoning under this heading
-result from inhalation; absorption of liquid cyanogen
-compounds through the skin can rarely come into consideration.</p>
-
-<p>If large quantities of hydrocyanic acid have been inhaled,
-death ensues very quickly. The person affected falls down
-suddenly, breathes with difficulty, the pulse soon becomes
-imperceptible, and after a more or less long stage of deep
-unconsciousness (coma) life becomes extinct.</p>
-
-<p>In slight cases of poisoning the patient feels a sensation
-of irritation in the throat, giddiness, sickness, and difficulty
-in breathing; occasionally such disturbances persist for some
-time.</p>
-
-<p>Some writers have described symptoms in workers
-manipulating prussic acid and cyanides, which they believe
-to be due to chronic prussic acid poisoning. Complaint
-is made of oppression of the chest, throat irritation, giddiness,
-difficulty in breathing, palpitation, hebetude, exhaustion,
-and nausea and vomiting; in certain instances the attack,
-aggravated by exhaustion and weakness, culminates in death.
-It is a question whether such poisonings are chronic in the
-true sense of the word. In view of the mode of action of
-hydrocyanic acid, such cases of sickness should rather be<span class="pagenum"><a name="Page_197" id="Page_197">[197]</a></span>
-accounted acute or sub-acute poisonings through repeated
-action of small quantities of the poison.</p>
-
-<p>It may be mentioned that in persons working with alkaline
-cyanides (especially in electro-plating) skin affections occasionally
-occur; these are traceable to the caustic effect of
-alkaline cyanides.</p>
-
-<p>Treatment by oxygen inhalation with simultaneous artificial
-respiration holds out most prospect of success. This holds
-good for acute poisoning by the other poisons belonging to
-this group. Besides this, saline injections and bleeding are
-recommended, and also the administration of an infusion of
-sodium thiosulphate solution.</p>
-
-<h4><i>GROUP: ARSENIURETTED HYDROGEN AND
-CARBONIC OXIDE (BLOOD POISONS)</i></h4>
-
-<p>Included in this group, as in the former one, are substances
-chemically very different from each other, but of which the
-action is especially on the blood. Besides this common
-effect, these substances also produce various other effects, such
-as local irritation, effect on the nervous system, &amp;c. The
-industrial blood poisons, which according to their chemical
-constitution are classed among the aliphatic and the aromatic
-series of organic compounds, will, for the sake of clearness,
-be discussed in the following chapters.</p>
-
-<h5>ARSENIURETTED HYDROGEN</h5>
-
-<p>Acute arseniuretted hydrogen poisoning, produced by
-inhalation of relatively very small quantities of arseniuretted
-hydrogen gas (AsH₃) is in most cases industrial in origin.
-The absorption of an amount corresponding to about 0·01
-mg. arsenic suffices to produce severe poisoning symptoms.
-The poisonous effect results chiefly from action upon the
-red blood corpuscles, which are dissolved (hæmolysis).
-Arseniuretted hydrogen is therefore a genuine blood poison.
-The effect upon the blood, if not immediately fatal to life,
-is to cause the dissolved blood-colouring matter to pass into
-the tissues where, though some is deposited, most goes to,<span class="pagenum"><a name="Page_198" id="Page_198">[198]</a></span>
-and acts injuriously on, the organs, especially the liver, spleen,
-and kidneys. In cases running at once a fatal course, the
-impoverishment of the blood caused by the lack of colouring
-matter necessary to internal respiration produces tissue
-suffocation, which is therefore the primary cause of death.
-In cases not immediately fatal, the injury to the functions of
-the organs alluded to (for instance, cessation of the functions
-of the kidneys, &amp;c.) may lead to death secondarily.</p>
-
-<p>Symptoms of the disease appear often only some time after
-the poisoning has set in, and begin with general malaise,
-sickness, collapse, fainting fits, and difficulty of breathing;
-after some hours the characteristic signs follow—the urine
-becomes dark red to black, containing quantities of blood
-colouring matter and dissolved constituents of the blood,
-and later also bile colouring matter, so that a coppery
-jaundice comes on if the illness is prolonged. The region of
-the liver, spleen, and kidneys is painful. Severe cases often
-end fatally during the first stage of the illness, more rarely
-later, with increased difficulty of breathing; sometimes
-death occurs after a preceding comatose stage marked by
-convulsions and delirium. In slighter poisoning cases the
-symptoms abate in a few days and recovery follows.</p>
-
-<p>The treatment of arseniuretted hydrogen poisoning is
-similar to that adopted in the case of all other blood poisonings:
-in addition, if possible, direct transfusion of blood from the
-artery of the giver into the vein of the receiver, liquid
-nourishment, saline injections, and, above all, prolonged
-oxygen inhalation.</p>
-
-<h5>CARBONIC OXIDE (CO)</h5>
-
-<p>Carbonic oxide (CO) is a colourless, odourless gas which
-frequently causes both acute and, it is said, chronic industrial
-poisoning.</p>
-
-<p>Carbonic oxide is a very poisonous gas; even as little as
-0·5 per thousand in the atmosphere breathed has a poisonous
-effect; about 2-3 per thousand can be dangerous to life.</p>
-
-<p>Its poisonous effect results from its power of combining<span class="pagenum"><a name="Page_199" id="Page_199">[199]</a></span>
-with the blood-colouring matter or hæmoglobin to form
-carboxy-hæmoglobin; the affinity of carbonic oxide for the
-hæmoglobin of the blood is more than 200 times greater than
-that of oxygen, so that, however small the amount of
-carbonic oxide in the air, it is inevitably absorbed by the
-blood and retained. The blood so altered, assumes a cherry-red
-colour, is unable to effect the necessary exchange of gases
-for internal respiration, and in consequence of the lack of
-oxygen suffocation ensues.</p>
-
-<p>Without doubt, however, carbonic oxide has also an
-immediate effect upon the central nervous system (first excitation,
-followed quickly by paralysis). It is maintained also
-that besides the action upon the hæmoglobin it favours coagulation
-of the blood through the disintegration of the blood
-corpuscles. The last-mentioned action is thought to account
-for the sequelæ of carbonic oxide poisoning, but they can
-also naturally be accounted for by the direct effect of the
-poison.</p>
-
-<p>Onset of symptoms is very sudden if a large quantity of
-pure carbonic oxide is inhaled. The affected person immediately
-falls down unconscious and succumbs after drawing a
-few breaths with difficulty.</p>
-
-<p>In less acute cases the illness begins with premonitory
-symptoms, generally headache, sickness, giddiness, sleepiness,
-though in cases of fairly rapid absorption these are absent,
-and are naturally absent also when the poisoning creeps upon
-the affected persons while asleep, as occasionally happens
-in cabins, &amp;c., in factories. If the poisoning continues, increasing
-mental dulness, accompanied by nausea and vomiting,
-leads sometimes to a short stage of seemingly drunken excitement,
-which preludes deep unconsciousness during which there
-is often a convulsive stage, followed by complete loss both of
-sensation and of reflex action; the breathing becomes shallow
-and intermittent, the pulse small and irregular, and finally
-death ensues. Occasionally in the stage of unconsciousness,
-death is hastened by entrance of vomited matter into the
-respiratory passages. Bright red patches are seen on the body
-after death.</p>
-
-<p>If persons affected by severe carbonic oxide poisoning<span class="pagenum"><a name="Page_200" id="Page_200">[200]</a></span>
-are withdrawn from the poisonous atmosphere after having
-reached the stage of unconsciousness, they may recover,
-but often with difficulty; not infrequently—in spite of suitable
-treatment—death occurs some considerable time later
-from the symptoms described above. Still, in many cases,
-under the influence of right treatment, gradual recovery
-has been brought about, even after long unconsciousness
-accompanied by repeated convulsions. In the rescued the
-symptoms described as characteristic of the first stage often
-continue for at least a day. Further, they are liable to a
-number of serious after effects, such as severe inflammation
-of the lungs due to infection by the entrance of vomited
-matter into the air passages, skin affections (rashes),
-and especially severe nervous and mental affections. Frequently
-these develop from centres of softening in the brain
-or from inflammation of the peripheral nerves (neuritis);
-occasionally the poisoning may really only be the predisposing
-cause for the outbreak of an existing psychical disease. It is
-not our task to enumerate all the extremely varied disturbances
-which are observed after carbonic acid gas poisoning.
-Neuralgias and paralyses have been described as associated
-with the peripheral nerve symptoms over areas supplied by
-different nerves; various forms of diseases of the brain and
-spinal cord (poliomyelitis, paralysis, sclerosis, &amp;c.); and finally
-a series of psychoses (neurasthenia, melancholia, mania, &amp;c.),
-occasionally passing into dementia and imbecility. Glycosuria
-(sugar in the urine) has also been noted as a sequela.</p>
-
-<p>Chronic carbonic oxide poisoning, arising from continued
-inhalation of small quantities of the gas, sets in usually
-with symptoms similar to those of acute carbonic oxide
-poisoning; if the worker continues exposed to danger, severe
-symptoms may arise which point to marked alteration of
-the blood and later also of the digestion and bodily functions.
-Under certain circumstances severe nervous and mental
-affections are said to occur similar to those which we have
-mentioned as sequelæ of acute carbonic oxide poisoning (convulsions,
-disturbances of mental activity, symptoms which
-resemble progressive muscular atrophy, &amp;c.).</p>
-
-<p>In acute carbonic oxide poisoning oxygen inhalation indefatigably
-continued and supported by artificial respiration<span class="pagenum"><a name="Page_201" id="Page_201">[201]</a></span>
-is often successful. The serious danger from this form of
-poisoning renders it very necessary that in all premises where
-there is risk provision should be made for the administration
-of oxygen. The sequelæ can of course only be treated
-symptomatically.</p>
-
-<h5>OXYCHLORIDE OF CARBON (PHOSGENE)</h5>
-
-<p>Oxychloride of carbon (COCl₂), also called phosgene, is, at
-the ordinary temperature, a colourless gas with a disagreeable
-smell. This decomposes in moist air into carbonic oxide,
-hydrochloric acid, or chlorine, and produces a strongly irritant
-local effect upon the mucous membranes. Industrial poisoning
-by phosgene is characterised by great difficulty in breathing
-and inflammation of the respiratory tract (bronchitis and
-bloodstained expectoration).</p>
-
-<p>Several cases have been treated successfully by oxygen
-inhalation.</p>
-
-<h5>NICKEL CARBONYL</h5>
-
-<p>The effects of nickel carbonyl are described on pp.
-<a href="#Page_186">186-8</a>.</p>
-
-<h5>CARBONIC ACID</h5>
-
-<p>Carbonic acid (CO₂), a colourless gas, is heavier than air
-(specific weight, 1·526), and therefore, wherever it collects,
-sinks to the ground. Carbonic acid is only very slightly
-poisonous; about 10 per cent. carbonic acid in the air
-causes asphyxia. The extinguishing of a candle flame will
-serve as an indication that the amount of carbonic acid in
-the atmosphere has reached this point. Cases of industrial
-carbonic acid asphyxia are sudden; they do not occur
-frequently.</p>
-
-<p>The gradual action of the gas when mixed with air produces
-first a tingling sensation on the surface of the body,
-reddening of the face, irritation of the mucous membrane
-and the respiratory organs, after which succeed difficulty in
-breathing, palpitation, fainting, and unconsciousness.</p>
-
-<p><span class="pagenum"><a name="Page_202" id="Page_202">[202]</a></span></p>
-
-<p>Sudden and fatal poisoning occurs industrially. Upon
-entering places filled with carbonic acid gas the affected person
-falls down dead almost immediately. These are cases of
-asphyxia, in which the lack of oxygen certainly plays the
-greatest part. If those affected by acute carbonic acid
-poisoning are removed in time out of the dangerous atmosphere
-they usually recover quickly.</p>
-
-<p>Oxygen inhalations and artificial respiration are to be
-applied in severer cases. There are no sequelæ.</p>
-
-<h4><i>GROUP: HYDROCARBONS OF THE ALIPHATIC AND
-AROMATIC SERIES AND THEIR HALOGEN AND
-HYDROXYL SUBSTITUTION PRODUCTS</i></h4>
-
-<p>The industrial poisons comprised in this group have as their
-principal general effect injurious action upon the functions
-of the central nervous system (paralysis or causing excitation)
-which is prominent in most of the cases of industrial
-poisoning caused by these substances. This effect is most
-marked in the case of the readily volatile (low boiling) hydrocarbons,
-while those less volatile and boiling at a higher
-temperature often have collateral effects (such as local irritation).
-The characteristic poisonous effect caused by the
-chlorine and hydroxyl-substitution products (chloroform and
-alcohol group) is also mainly on the central nervous system
-(narcosis).</p>
-
-<h5>HYDROCARBONS OF MINERAL OIL<br />
-BENZINE, LIGROINE, PETROLEUM, PARAFFIN, VASELINE</h5>
-
-<p><i>Mineral oil</i> (crude petroleum) has, according to its origin,
-differing composition. Thus in American mineral oil hydrocarbons
-of the methane series preponderate; in the Russian,
-hydrocarbons of the aromatic series. Reference has been
-made in Part I. to this point, as well as to the separation of
-crude petroleum into its different fractions.</p>
-
-<p><span class="pagenum"><a name="Page_203" id="Page_203">[203]</a></span></p>
-
-<p>The injury to health produced by crude petroleum and its
-derivatives is of two kinds. Direct contact with liquid petroleum
-and the semi-liquid and solid deposit after distillation
-(paraffin) cause local injury to the skin. Inhalation of the
-volatile constituents of raw petroleum causes symptoms
-affecting mainly the central nervous system. They have
-moreover a markedly irritating effect upon the mucous membrane
-of the respiratory organs. These substances clearly
-exhibit the characteristic we have referred to, namely, that
-the hydrocarbons boiling at low temperature act as nerve
-poisons, whereas those boiling at a higher temperature produce
-a local irritant effect.</p>
-
-<p>The skin affections take the form of inflammation of the
-hair follicles (acne), eruptions with characteristic formation
-of vesicles, and pimples and pustules which precede the deep-seated
-formation of ulcers, abscesses, &amp;c.</p>
-
-<p>In paraffin workers the acne-like skin inflammations are
-known as ‘paraffin eczema.’ They develop sometimes into
-cancer of the skin (warty and epitheliomatous growths).</p>
-
-<p>In the general poisoning produced by inhalation of petroleum
-fumes the effect upon the central nervous system is all
-the more plainly and clearly marked when the irritant effect of
-the hydrocarbons boiling at higher temperature is slight or
-absent; that is, in the case of poisoning which arises solely
-from industrial products of low boiling hydrocarbons; among
-these benzine is included.</p>
-
-<p>Acute poisoning from inhalation of benzine fumes begins
-with headache, sickness, and attacks of giddiness resembling
-alcoholic intoxication. If very much has been inhaled, the
-patient quickly becomes unconscious, with occasionally
-muscular tremors, convulsions, difficulty in breathing, and
-cyanosis.</p>
-
-<p>In cases of poisoning by inhalation of fumes of crude petroleum,
-these symptoms may be complicated by coughing,
-intense inflammation of the mucous membrane of the respiratory
-organs—congestion, bronchitis, bloodstained expectoration,
-and inflammation of the lungs. In workers who
-frequently remain long in an atmosphere filled with benzine
-fumes, further symptoms of chronic benzine poisoning show
-themselves—mental hebetude, pains in the limbs, trembling,<span class="pagenum"><a name="Page_204" id="Page_204">[204]</a></span>
-weakness of the muscles, and other disturbances of the nervous
-system; in such cases these may really be signs of continued
-attacks of acute or sub-acute poisoning; many benzine
-workers are anæmic.</p>
-
-<p>The treatment of acute benzine poisoning consists in
-oxygen inhalation, with simultaneous artificial respiration.
-Treatment of chronic derangement of health is symptomatic.</p>
-
-<h5>HYDROCARBONS OF THE AROMATIC SERIES<br />
-BENZENE AND ITS HOMOLOGUES</h5>
-
-<p><i>Benzene</i> (C₆H₆) is a characteristically smelling (aromatic)
-liquid which boils at 80·5° C. Acute benzene poisoning,
-which plays an important part as an industrial poisoning, is
-caused by inhalation of benzene fumes. The various kinds
-of benzol used commercially contain, besides benzene,
-alkyl benzenes, especially <i>toluene</i> (methylbenzene, C₆H₅.CH₃,
-boiling-point 111° C.); <i>xylene</i> (dimethylbenzene, C₆H₄[CH₃]₂,
-boiling-point 140° C.); <i>pseudocumene</i> and <i>mesitylene</i> (tri-methylbenzene,
-C₆H₃[CH₃]₃, boiling-point 169° or 163° C.); the
-regular presence of <i>thiophene</i> (C₄H₄S, boiling-point 84° C.) in
-commercial benzol must also be taken into account. Industrial
-benzol poisoning arises, therefore, as a rule, not from the
-action of pure benzene vapour, but from fumes which contain
-a mixture of the compounds mentioned.</p>
-
-<p>The course run by industrial benzol poisoning is often very
-acute, if large quantities are inhaled—death occurring suddenly,
-after a short illness with symptoms of vertigo. Gradual
-inhalation of lesser quantities gives rise to headache, giddiness,
-malaise, then twitchings appear which develop into convulsions,
-and lastly unconsciousness. In order to ascertain in
-what manner the various substances contained in commercial
-benzol share in the poisonous effect, experimental research
-seemed to me to be indispensable, especially as published statements
-so far gave no accurate data.</p>
-
-<p>Two cases of industrial benzol poisoning have given rise
-to close experimental research upon the poisonous nature of
-benzene.</p>
-
-<p><span class="pagenum"><a name="Page_205" id="Page_205">[205]</a></span></p>
-
-<p>Lewin undertook experiments on animals; which he confined
-under bells and caused to inhale fumes of chemically pure and
-impure benzene. He mentions that even at comparatively low
-concentration poisoning results, and indeed more readily and
-certainly from the action of impure than pure benzene. Lewin
-found that when air was made to flow slowly first through
-benzene and then into the bell, symptoms of paralysis, convulsions,
-and unconsciousness showed themselves in from four to
-six minutes. After-effects by this means could not be observed.
-Lewin maintains, however, that in man even slight acute
-action of benzene can be followed by after-effects (giddiness,
-sickness, headache, distress in breathing, and oppression of
-the heart).</p>
-
-<p>Santesson made researches upon the poisonous action of
-benzene in connection with occurrence of certain cases of poisoning
-through ‘impure benzol’ (coal-tar benzene) in a rubber tyre
-factory. In the factory mentioned nine young women were
-poisoned, of whom four died. The symptoms shown were
-lassitude, anæmia, giddiness, headache, vomiting, and fever.
-Post mortem, hæmorrhages and fatty degeneration of the
-endothelium of the bloodvessels and various organs were
-found. Experimental research showed that commercial
-benzol and chemically pure benzene had the same effect.
-Santesson did not succeed in his experiments on animals in
-producing chronic poisoning by inhalation of benzine and of
-benzene fumes (which two completely different poisons he does
-not distinguish strictly from each other, as is the case, unfortunately,
-with many other writers). My experimental researches
-upon the poisonous effect of pure benzene, pure toluene,
-cumene, thiophene, and the most important kinds of commercial
-benzol gave the following results:</p>
-
-<p>For rabbits the limit of toxicity is a proportion of 0·015
-to 0·016 per thousand pure benzene in the air, that is 0·015
-to 0·016 c.c. benzene vapour per litre of air.</p>
-
-<p>A concentration of 0·056-0·057 per thousand pure benzene in
-the air causes in rabbits at once—after one minute—twitching
-of the muscles; after eight minutes, convulsions; after ten
-minutes, deep narcosis; and after twenty-five minutes, coma.
-If the animal is taken out of the bell in time, even if it has
-shown marked symptoms, it recovers very quickly (in two to<span class="pagenum"><a name="Page_206" id="Page_206">[206]</a></span>
-ten minutes) without manifesting any after effects. Even in
-animals repeatedly exposed to the poison sequelæ were not
-observed.</p>
-
-<p>Dogs are somewhat more susceptible to pure benzene than
-rabbits; 0·024 per thousand causes after ten minutes severe
-convulsions, which after twenty minutes become continuous;
-0·042 per thousand kills after twenty minutes (sudden death
-in a state of tetanus).</p>
-
-<p>Cats are less sensitive than dogs and more sensitive than
-rabbits; 0·03-0·04 per thousand causes after ten minutes
-attacks of cramp and, after twenty minutes, convulsions; 0·05
-per thousand at once brings on poisoning symptoms. As
-regards the character of the symptoms (cramps, convulsions,
-quick recovery, no after effects) the above statements apply
-to all three kinds of animals (rabbit, dog, and cat).</p>
-
-<p>Chloral hydrate completely checks the convulsions and
-enables animals to tolerate higher concentrations of benzene for
-a longer time.</p>
-
-<p>Benzene is thus to be counted among nerve irritant poisons.
-The convulsions are probably provoked by excitement of the
-motor centres in the brain.</p>
-
-<p>In view of the fact that thiophene in a concentration of
-0·03-0·05 per thousand in the air was borne by animals for
-an hour without producing any symptoms of poisoning, the
-proportion of thiophene in commercial benzol must be looked
-upon as practically non-injurious.</p>
-
-<p>The so-called 90 <i>benzol</i>—a commercial benzol of which
-90 per cent. distils at 100° C.—has naturally a somewhat
-weaker action, although, in respect of the poisoning symptoms
-produced, it is similar to that of pure benzene.</p>
-
-<p><i>Pure toluene</i> (boiling-point 111° C.) and purified toluol
-(commercial product, boiling-point 109°-112° C.) produce, when
-inhaled, gradually increasing narcosis in the three kinds of
-animals referred to; they produce no symptoms of convulsions
-or spasms.</p>
-
-<p>After the animals have been taken out of the bell, recovery
-is not so rapid as after benzine inhalation, but takes from
-half an hour to one hour. In rabbits and cats 0·046-0·05 per
-thousand produces after fifteen minutes staggering and paresis;
-after thirty minutes deep narcosis. The dog is again somewhat<span class="pagenum"><a name="Page_207" id="Page_207">[207]</a></span>
-more susceptible, as little as 0·034 per thousand causing these
-symptoms in the same time.</p>
-
-<p>‘Purified toluol’ (commercial product) acts somewhat
-less rapidly than pure toluene, but this small difference in
-effect need hardly be considered.</p>
-
-<p>Other poisons were also investigated:—</p>
-
-<p><i>Solvent naphtha I</i>, a commercial product, of which 90 per
-cent. comes over at 160° C.; it contains little toluene, chiefly
-xylene, pseudocumene, and cumene.</p>
-
-<p><i>Solvent naphtha II</i>, of which 90 per cent. comes over at
-175° C, it contains besides xylene, chiefly pseudocumene,
-mesitylene, cumene, &amp;c.</p>
-
-<p>The fumes of solvent naphtha I cause, when inhaled by
-rabbits, dogs, and cats, gradual narcosis, although not nearly
-so quickly as toluene at similar concentrations; recovery usually
-takes over an hour after the deeply narcotised animals have
-been removed from the bell. Rabbits and cats are affected in
-about equal degree. The dog is the more sensitive. Rabbits
-and cats can tolerate about 0·012-0·013 per thousand of the
-fumes of solvent naphtha I in the atmosphere for a long time
-without any symptoms. Only after breathing for fifty minutes
-air containing 0·0536 per thousand do they become narcotised.
-In the dog 0·036 per thousand causes narcosis only
-after thirty minutes.</p>
-
-<p>With the fumes of solvent naphtha II I could not affect
-rabbits at all. The cat also, in spite of long inhalation of the
-heavy fumes, showed no marked symptoms of poisoning. In
-the dog gradual narcosis came about only after an hour’s
-inhalation of 0·048 per thousand.</p>
-
-<p>The fumes of pure <i>xylene</i> caused narcosis in rabbits after
-forty minutes’ inhalation of 0·05 per thousand in the atmosphere;
-after being taken out of the bell the animals recovered
-slowly (after half an hour to one hour).</p>
-
-<p><i>Cumene</i> causes no symptoms after one hour’s inhalation in
-a concentration of 0·06 to 0·07 per thousand. This explains
-the effects of solvent naphtha I (in which xylene preponderates)
-and solvent naphtha II (in which pseudocumene, cumene, &amp;c.,
-preponderate). After effects were not observed.</p>
-
-<p>Benzol and toluol fumes, and particularly those of solvent
-naphtha, exercise a distinctly irritant effect upon the<span class="pagenum"><a name="Page_208" id="Page_208">[208]</a></span>
-mucous membrane, which, however, passes off without after
-effects.</p>
-
-<p>Pure benzene, therefore, proved the most poisonous of
-the substances under investigation. When inhaled its effect
-(convulsions, with quick recovery) differs essentially from that
-of toluene, solvent naphtha, xylene, and cumene (gradual
-narcosis, slow recovery). The fumes of the various kinds of
-commercial benzol (solvent naphtha) boiling at a higher
-temperature are practically non-poisonous (solvent naphtha
-II). Pure benzene fumes are, however poisonous, even in
-very small quantities in the air. The limit for animals lies at
-0·015-0·016 per thousand.</p>
-
-<p>Lehmann has shown in a recent work that man, exposed
-to a mixture of benzene and air, absorbs 80 per cent. of the
-benzene.</p>
-
-<p>Treatment of acute industrial benzene poisoning consists
-in severe cases of artificial respiration, with simultaneous
-administration of oxygen; in slight cases it is sufficient to
-bring the patient into fresh air.</p>
-
-<p><i>Naphthalene.</i>—Naphthalene, which is insoluble in water,
-has irritant effect upon the mucous membrane and upon the
-skin when brought into contact with it.</p>
-
-<p>Long continuance in an atmosphere containing naphthalene
-as dust or fumes causes headache, nausea, giddiness, &amp;c.</p>
-
-<h5>HALOGEN SUBSTITUTION PRODUCTS<br />
-ALIPHATIC SERIES (NARCOTIC POISONS)</h5>
-
-<p>The halogen substitution products of the aliphatic series
-are not of much account as industrial poisons. They have
-generally a narcotic effect, that is, a paralysing effect upon the
-central nervous system, usually preceded by a short stage of
-excitement. This effect shows itself typically on inhalation
-of chloroform (methanetrichloride, CHCl₃), which however plays
-no part as an industrial poison. The narcotic effect of the
-other alkyl chlorides is less than that of chloroform. With
-carbon tetrachloride (CCl₄) the narcotic effect is only half
-that of chloroform; it causes, however, a more violent excitation;<span class="pagenum"><a name="Page_209" id="Page_209">[209]</a></span>
-inhaling the fumes brings on nausea, coughing, sickness,
-headache, &amp;c.</p>
-
-<p><i>Methylchloride</i> (CH₃Cl) has a less narcotising effect. On
-the other hand it has a stronger local irritant action, which is
-indeed present also in chloroform, though not so apparent.
-This gas, as is well known, is used as a local anæsthetic in
-medicine.</p>
-
-<p>Pure <i>methylene chloride</i> (CH₂Cl₂) similarly is much less
-powerful than chloroform. Severe poisoning, alleged to
-have resulted from methylene chloride was caused by a
-mixture, called indeed methylene chloride, but composed of
-methylalcohol and chloroform.</p>
-
-<p>Of the remaining halogen substitution products of methane,
-<i>methyl bromide</i> (CH₃Br) and <i>methyl iodide</i> (CH₃I) have given
-rise to industrial poisoning.</p>
-
-<p>These poisons also act in the same way as the alkyl chlorides,
-but the excitement accompanying the narcosis is more marked—so
-far as the scanty observations allow conclusions to be
-drawn. The symptoms first show themselves in sickness,
-giddiness, hebetude, slowing of respiratory movements and
-of the heart’s action; convulsions or delirium ensue.</p>
-
-<p>Treatment consists in artificial respiration or promotion of
-breathing by a plentiful supply of fresh air or oxygen; in
-pronounced narcosis stimulating remedies should be applied.</p>
-
-<h5>BENZENE SERIES</h5>
-
-<p><i>Chlorobenzene</i>, and <i>nitro-</i> and <i>dinitro-chlorobenzene</i> and
-<i>benzoylchloride</i>, have given rise to industrial poisoning.</p>
-
-<p>To chlorobenzene similar action is attributed as to benzene
-(headache, fainting, rapid breathing, cyanosis); changes in the
-blood (methæmoglobin formation) have also been observed.</p>
-
-<p>Nitro- and dinitro-chlorobenzene are active poisons; the
-effect corresponds in general to that of nitro- and dinitrobenzene,
-but in addition the fumes or dust have markedly
-irritant action on the skin (dermatitis).</p>
-
-<p><i>Benzoylchloride</i> (C₆H₅COCl), a colourless, pungent-smelling
-liquid, produces a violently irritant effect upon the mucous
-membrane, decomposing into hydrochloric acid and benzoic
-acid.</p>
-
-<p><span class="pagenum"><a name="Page_210" id="Page_210">[210]</a></span></p>
-
-<p>Treatment is analogous to that of benzene poisoning, and
-in cases of benzoyl chloride poisoning to that by hydrochloric
-acid.</p>
-
-<p>It may be mentioned that chlorine rash is attributed to the
-action of chlorinated tar products (chlorobenzene compounds).</p>
-
-<h5>HYDROXYL SUBSTITUTION PRODUCTS<br />
-FATTY SERIES (ALCOHOLS)</h5>
-
-<p>The hydroxyl substitution products of the fatty series
-belong mainly to the narcotic poisons; the greater the molecular
-weight of the alcohol, the more marked is usually the
-narcotic effect. According to this propylalcohol is eighteen
-times as poisonous as ethylalcohol; butylalcohol and amylalcohol
-have from 36 to 120 times as great a narcotic effect as
-methylalcohol.</p>
-
-<p><i>Methylalcohol</i> (wood spirit, CH₃OH) plays relatively the
-greatest part among alcohols as an industrial poison, because
-it is employed as a means of denaturing spirit. Its poisonous
-nature is relatively great, being very persistent. Industrial
-poisoning by methylalcohol is due to inhalation of the
-vapour and is rarely of a severe nature. The fumes have
-a strongly irritant effect upon the mucous membrane, giving
-rise to throat irritation, cough, hoarseness, and in severe
-cases bronchitis and inflammation of the conjunctiva of the
-eye. In addition inhalation of methylalcohol vapour causes
-headache, giddiness, nausea (inclination to vomit), and
-occasionally also twitchings and tremor.</p>
-
-<p>The <i>higher alcohols</i> (propyl-, butyl-, amyl-alcohol, C₃H₇.OH,
-C₄H₉.OH, and C₅H₁₁.OH) occur in fusel oil. They cause but
-slight (if any) industrial poisoning. Cases of more severe
-industrial poisoning through amylalcohol fumes have been
-described (in factories for smokeless powder), with symptoms
-of sickness, headache, giddiness, with fatal issue in some cases,
-preceded by severe nervous symptoms (convulsions or
-delirium).</p>
-
-<p>Beyond speedy removal out of the dangerous atmosphere,
-probably no special treatment is needed in these cases of
-industrial poisoning from alcoholic vapour.</p>
-
-<p><span class="pagenum"><a name="Page_211" id="Page_211">[211]</a></span></p>
-
-<h4><i>GROUP: NITRO AND AMIDO COMPOUNDS OF THE
-ALIPHATIC AND AROMATIC SERIES (BLOOD
-POISONS WHICH FORM METHÆMOGLOBIN)</i></h4>
-
-<p>Characteristic of the nitro and amido compounds of the
-aliphatic and aromatic series of the organic substances is
-their action upon the blood. The normal oxyhæmoglobin
-(blood-colouring matter) is changed into methæmoglobin,
-with which the oxygen is so firmly combined that
-the internal exchange of gases necessary to life becomes
-impossible. Methæmoglobin has a dark chocolate-brown
-colour and a clearly defined characteristic spectrum.</p>
-
-<p>Of the poisons belonging to this group several are important.
-In so far as these substances are volatile—and this is generally
-the case with those causing industrial poisoning—effects are
-due to inhalation of fumes, but it is proved that the poisons of
-this group in liquid form can be absorbed by the intact skin,
-and this channel of absorption is characteristic of industrial
-poisoning. Severe poisoning results especially from wetting
-the skin by spilling on the clothes, &amp;c.</p>
-
-<p>The grey-blue discoloration of the mucous membrane,
-especially of the lips, is characteristic; sometimes also the skin
-is altered in colour. This discoloration is often noticed
-by others before the patient feels unwell. Soon the
-person affected has general nausea, vomiting, headache,
-giddiness, severe nervous symptoms, feeling of anxiety,
-and difficulty of breathing; in severe cases unconsciousness
-comes on, and death occurs with increasing cyanosis
-(lividity).</p>
-
-<p>Treatment is naturally that which has been emphasised in the
-introductory words to Part II, which hold for all blood poisonings.
-In mild cases oxygen treatment has given good results.
-In all factories where such poisoning can occur provision should
-be made for immediate oxygen treatment. Besides this, the
-workers must be adequately instructed as to the danger and
-symptoms of poisoning, especially of the characteristic premonitory
-skin discoloration, in order to be able to assist their
-fellows.</p>
-
-<p><span class="pagenum"><a name="Page_212" id="Page_212">[212]</a></span></p>
-
-<h5>NITROCOMPOUNDS<br />
-ALIPHATIC SERIES</h5>
-
-<p><i>Nitro-glycerin</i> (triple nitric acid ester of glycerin,
-C₃H₅.[NO₃]₃), the well-known oily explosive liquid, has also an
-irritant local effect. When absorbed into the body, in addition
-to methæmoglobin formation, it causes dilatation of the bloodvessels,
-slowing of the respiration and heart’s action, and attacks
-of suffocation. The general remarks upon this group apply here,
-but symptoms referable to central paralysis occur as the
-methæmoglobin formation is slow. Industrial poisoning arises
-through inhalation of gases containing nitro-glycerin and
-also by absorption through the skin. Statements as to its
-poisonous nature are very varied. Under certain conditions
-moistening the skin with small quantities of nitro-glycerin
-suffices to produce symptoms. Probably the susceptibility of
-different persons varies greatly.</p>
-
-<p><i>Amylnitrite</i> (nitric acid amyl ester, C₅H₁₁NO₂), a characteristically
-smelling liquid, acts similarly. The fumes of
-amylnitrite, even when inhaled in small quantities, cause
-marked dilatation of the bloodvessels, through paralysis of the
-muscular walls of the bloodvessels, thus causing marked flushing
-of the face; the pulse becomes quick, then weak and slow.</p>
-
-<h5>NITRO AND AMIDO COMPOUNDS<br />
-AROMATIC SERIES</h5>
-
-<p>The substances of this group are important.</p>
-
-<p><i>Nitrobenzene</i> (C₆H₅NO₂, named oil of mirbane), a yellowish
-liquid of characteristic smell, induces especially the formation
-of methæmoglobin in the blood; the effect upon the central
-nervous system (first excitation, then depression) is often
-absent. The description of the disease in general in the
-introductory words of this whole group is characteristic.
-Occasionally signs of asphyxia show themselves; sometimes
-there are twitchings, disturbance of the power of sensation,
-and convulsions; early discoloration of the mucous membrane
-and the skin, which assume a blue to grey-black colour, is
-characteristic.</p>
-
-<p><span class="pagenum"><a name="Page_213" id="Page_213">[213]</a></span></p>
-
-<p>Chronic poisoning is also attributed to nitrobenzene, showing
-itself in lassitude, headache, malaise, giddiness, and other
-disturbances of the nervous system.</p>
-
-<p><i>Nitrotoluene</i> (C₆H₄CH₃NO₂), of which the ortho-compound
-acts most powerfully, and also <i>nitroxylene</i> (C₆H₃[CH₃]₂NO₂)
-have similar but less marked effect.</p>
-
-<p>The <i>dinitrobenzenes</i> (C₆H₄[NO₂]₂) are stable bodies. Meta-dinitrobenzene
-inhaled as dust or otherwise, can produce
-marked poisoning symptoms essentially the same as those
-described. Especially characteristic is the early dark
-discoloration of the skin.</p>
-
-<p>Symptoms resembling nitrobenzene poisoning in general
-are caused by <i>nitrophenols</i> (C₆H₄.OH.NO₂), of which
-paranitrophenol is the most toxic; also by <i>dinitrophenols</i>
-(C₆H₃[NO₂]₂OH), solid crystalline substances which melt at
-different temperatures, and the <i>mono-</i> and <i>di-nitrochlorobenzenes</i>
-(C₆H₄.Cl.NO₂ and C₆H₃.Cl[NO₂]₂). In cases of industrial
-poisoning by dinitrophenol, observed by Leymann, the
-workers were taken suddenly ill, with symptoms of collapse,
-pains in the chest, vomiting, distress of breathing, rapid pulse,
-and convulsions, and died within a few hours. At the autopsy
-a yellow substance was found with picric acid reaction which
-appeared to be di- or tri-nitrophenol. In other cases, some
-fatal, of industrial nitrochlorobenzene poisoning, also observed
-by Leymann, the typical grey-blue discoloration of the skin
-was obvious, and the chocolate-brown colour of the blood
-produced by methæmoglobin.</p>
-
-<p><i>Trinitrophenol</i> (picric acid, C₆H₂[NO₂]₃OH) is a yellow
-crystalline compound with bitter taste; poisoning by this
-substance exhibits clearly strong local irritant action (upon
-skin, mucous membrane, and intestinal canal, and especially
-upon the kidneys), besides effect on the blood and central
-nervous system. Prolonged action of picric acid upon the skin
-causes inflammation. Absorption of picric acid dust causes
-inflammation of the mucous membrane of the respiratory
-passages and symptoms of gastric and intestinal catarrh as well
-as inflammation of the kidneys.</p>
-
-<p>A jaundice-like discoloration of the skin and darkening
-of the urine are also characteristic; sometimes picric acid<span class="pagenum"><a name="Page_214" id="Page_214">[214]</a></span>
-poisoning produces a rash resembling that of measles and
-scarlet fever.</p>
-
-<p><i>Nitronaphthalene</i> (C₁₀H₇[NO₂]) and <i>nitronaphthol</i>
-(C₁₀H₆.NO₂.OH) in addition to methæmoglobin formation
-have an irritant action. It is stated also that dulness of
-the cornea is produced.</p>
-
-<p><i>Azobenzenes</i> also, which are to be considered as intermediate
-between nitrobenzene and aniline, form methæmoglobin (azobenzene,
-C₆H₅N = NH₅C₆).</p>
-
-<p><i>Aniline</i> (amidobenzene, C₆H₅.NH₂), a colourless, oily liquid
-of aromatic smell, has only slight local irritant effect. In the
-frequent cases of industrial poisoning by ‘aniline oil’ or aniline
-hydrochloride, in which the aniline enters through the skin or is
-inhaled in the form of fume, there appear the typical symptoms
-common to this group, of the action upon the blood
-through methæmoglobin formation: headache, weakness,
-cyanosis, difficulty in breathing, &amp;c., to which are added
-nervous symptoms such as convulsions and psychical disturbance,
-although these play a subordinate part in industrial
-poisoning. In severe cases the typical symptoms of air
-hunger are shown. Occasionally recovery only takes place
-gradually, and signs of irritation of the kidneys and inflammation
-of the urinary organs are seen. These symptoms occur
-only rarely in acute industrial poisoning, but are, however,
-in so far worthy of notice because of the frequent occurrence
-of tumours in the bladder among aniline workers. It is
-possible that here the irritant action of the urine which contains
-aniline plays a part. The tumours in the bladder operated
-upon, in some cases with success, were many of them non-malignant
-(papillomata), but some were carcinomata (cancerous
-new growths) running a malignant course, and recurring after
-operation. In the urine the aniline combines with sulphuric
-acid, and is partly excreted as paramidophenol sulphuric acid.</p>
-
-<p>The treatment of aniline poisoning is the same as that for
-all the poisons of this group. In view of the occurrence
-of tumours of the bladder in aniline workers, they should
-be instructed to seek medical aid on the first indications of
-trouble, so that a careful cystoscopic examination may be
-made.</p>
-
-<p><i>Toluidine</i> (C₆H₄.CH₃.NH₂), which is mixed with aniline for<span class="pagenum"><a name="Page_215" id="Page_215">[215]</a></span>
-industrial use, produces the same symptoms with marked
-irritation of the renal organs.</p>
-
-<p>Of the <i>nitroanilines</i> (C₆H₄.NH₂.NO₂) <i>paranitroaniline</i> is
-the most poisonous. Characteristic of the action of this compound
-is methæmoglobin formation, central paralysis and
-paralysis of the heart’s action.</p>
-
-<p>Of the <i>benzenediamines</i>, <i>paraphenylene diamine</i> (C₆H₄[NH₂]₂)
-may be regarded as an industrial poison. The irritant action
-of this substance is prominent; it induces skin affections, inflammation
-of the mucous membranes, more especially of the
-respiratory organs, and sometimes inflammation of the kidneys.
-They have been noted in workers using ursol as a dye; here,
-doubtless, the action of diimine (C₆H₄.NH.NH.) must be taken
-into account, which arises as an intermediate product and
-exercises a markedly irritant action. Further, the general
-effect of paraphenylene diamine is an irritant one upon the
-central nervous system.</p>
-
-<h4><i>APPENDIX</i><br />
-TURPENTINE, PYRIDINE BASES, ALKALOIDS</h4>
-
-<p><i>Turpentine oil.</i>.—Turpentine oil is a peculiar-smelling,
-colourless liquid of the composition C₁₀H₁₆; different reactions
-show that turpentine oil contains the aromatic nucleus
-(cymene). It is used in the manufacture of varnish, and thus
-can cause industrial poisoning by inhalation of fumes. Even
-from 3 to 4 mg. of vapour of turpentine oil per litre of air
-brings on severe symptoms. Turpentine oil acts as a local
-irritant, and when absorbed into the system has an exciting
-effect upon the central nervous system. Inhalation of large
-quantities of turpentine vapour cause rapid breathing,
-palpitation, giddiness, stupor, convulsions, and other
-nervous disturbances, pains in the chest, bronchitis, and
-inflammation of the kidneys. The last-mentioned symptom
-also arises from the chronic action of turpentine vapours.</p>
-
-<p><i>Pyridine.</i>—Pyridine (C₅H₅N), a colourless liquid of peculiar
-odour, is employed as well as methylalcohol in denaturing
-alcohol. The disturbance of health observed in workers<span class="pagenum"><a name="Page_216" id="Page_216">[216]</a></span>
-occupied with the denatured spirit are probably mainly
-due to the inhalation of fumes of methylalcohol. Pyridine is
-comparatively innocuous. Eczema, from which persons suffer
-who come into contact with denatured spirit, is ascribed to the
-action of pyridine. Larger doses produce a paralysing effect,
-but this need not be considered in its industrial use.</p>
-
-<p><i>Nicotine, tobacco.</i>—According to various published statements,
-effects among tobacco factory workers are attributed
-to the nicotine contained in tobacco dust and to the aroma
-which fills the air. Nicotine in large doses has at first an
-exciting followed by a paralysing effect upon the central
-nervous system; it causes moreover contraction of the
-unstriped muscles and has a local irritant effect.</p>
-
-<p>The symptoms of illness ascribed to nicotine are: conjunctivitis,
-catarrh of the air passages, palpitation, headache,
-want of appetite, and, particularly, tendency to abortion
-and excessive menstruation. Severe industrial poisoning due
-to nicotine has only been observed in workers who chewed
-tobacco leaves.</p>
-
-<p><i>Poisonous wood.</i>—The symptoms of disease noticed in
-workers who manipulate certain kinds of wood are attributed
-by some writers to the presence of alkaloids. Such knowledge
-as we have of the illness due to them—they are evidently
-of the nature of poisoning—is referred to at the end of Part I.</p>
-
-<hr />
-
-<p><span class="pagenum"><a name="Page_217" id="Page_217">[217]</a></span></p>
-
-<h2 id="PART_III">PART III<br />
-<span class="smaller"><i>PREVENTIVE MEASURES AGAINST INDUSTRIAL POISONING</i></span></h2>
-
-<h3 id="GENERAL_MEASURES">I<br />
-<span class="smaller"><i>GENERAL MEASURES</i></span></h3>
-
-<p>In discussing preventive measures against industrial poisoning
-the deductive method from the general to the particular
-will be followed. The numerous instances of poisoning
-mentioned in Part I afford a practical basis on which to
-formulate general rules before passing on to describe special
-measures. Technical details will be omitted, as they must be
-left to the technical expert whose business it is to draw up the
-plans as a whole and to modify them according to the requirements
-of individual cases.</p>
-
-<p>In the effort to control industrial poisoning and disease it
-is necessary to insist absolutely on the concerted action of all
-concerned. In this co-operation every one is called who
-through his knowledge and sphere of activity is in a position to
-assist.</p>
-
-<p>The medical man comes in with his special knowledge of the
-action of poisons as toxicologist, as practising physician (especially
-as works surgeon and doctor of the sick insurance society),
-and also in an official capacity as appointed surgeon or medical
-officer of health; the technical expert comes in as engineer, as
-manager, as foreman, and as factory inspector. But above
-all the interest and active co-operation of employers and
-employed are needed as well as the organisations of both.
-That the workers should understand and co-operate is essential
-for the success of preventive measures, and subsequently it
-will be shown in what direction this co-operation is most
-necessary.</p>
-
-<p><span class="pagenum"><a name="Page_218" id="Page_218">[218]</a></span></p>
-
-<p>To make possible such co-operation interest must be
-aroused and suitable information and teaching supplied to the
-parties concerned. Medical men and practical workers require
-to receive instruction in industrial hygiene, and teaching on
-this subject should be arranged for in secondary and technical
-schools. Medical men and others who, as officials and insurance
-doctors, are brought constantly into touch with industrial
-workers should have opportunity—by means of special courses
-and lectures—to keep pace with advancing knowledge in this
-direction. Beside these there are, as educative organisations,
-special Institutes of Industrial Hygiene and special hospitals
-for treatment of diseases of occupation which bring together
-the patients and the teaching staff and so facilitate pursuit of
-knowledge and research. A beginning of this kind has
-already been made by the Industrial Hygiene Institute,
-Frankfurt a.-Main, and the hospital for diseases of occupation
-at Milan, showing that the ideas are attainable. International
-agencies which unite all circles interested in the
-subject irrespective of profession or nationality in common
-interchange of thought and discussion are of great significance
-for uniform development of needful preventive measures;
-international congresses, often in connection with exhibitions,
-have given valuable stimulus and have been the starting-point
-of permanent international societies, unions, and organisations.
-The significance for our inquiry of these international efforts
-will be more closely considered in the following pages.</p>
-
-<h3>II<br />
-<span class="smaller"><i>GENERAL CONSIDERATIONS ON SOCIAL AND LEGISLATIVE MEASURES</i></span></h3>
-
-<h4>INTERNATIONAL PREVENTIVE MEASURES, NOTIFICATION OF
-INDUSTRIAL POISONING, LISTS AND SCHEDULES OF INDUSTRIAL
-POISONS</h4>
-
-<p>Experience and inquiry in the field of industrial poisoning
-led to a series of demands which, supported as they were by a
-general movement for the protection of workers, were soon
-followed by regulations and legislative action. For a long time
-efforts have been directed to treat industrial disease and poisoning<span class="pagenum"><a name="Page_219" id="Page_219">[219]</a></span>
-in the same way as has been done in the case of industrial
-accidents. The question, however, is attended with much
-greater difficulty. On the other hand, uniform international
-regulation of questions affecting prevention of disease is called
-for both on humanitarian and economic grounds.</p>
-
-<p>The idea of international legislation for the protection of
-workers was first mooted about the year 1870. The possibility
-and need of such intervention was much discussed and interest
-in it kept constantly alive, especially in Switzerland, until
-the organisations of the workers took up the idea. Several
-attempts failed. In France in 1883 a proposal of the Socialist
-party aiming at international agreement on the subject of
-protection of the workers was rejected. In 1885 (in opposition
-to Hertling) Prince Bismarck expressed himself strongly against
-the possibility of such international protection. But the stone,
-once set rolling, could not be stayed. In the years 1886, 1887,
-and 1888 the French and English trade unions, as well as the
-Swiss Federal Council, took up the question afresh. These
-endeavours at last took tangible shape in the first International
-Conference for the protection of workers held in Berlin in
-March 1890. This date remains a landmark in the history
-of the subject, but not until ten years later—1900—did the
-Congress held in Paris for the international legal protection of
-workers lead to the establishment of what had been repeatedly
-urged, namely, creation of an International Bureau. This
-was inaugurated at Basle in 1901 and forms the headquarters
-of the National Associations for Labour Legislation called into
-being in various countries.</p>
-
-<p>This International Association meets regularly in conference,
-as in Cologne (1902), Berne (1905), Lucerne (1908), Lugano
-(1910), and Zurich (1912). The questions raised in the International
-Labour Bureau, which receives financial aid from a
-number of States, are fully and scientifically discussed with the
-object of finding a basis on which to bring into agreement the
-divergent laws of the different countries. A further task of
-this strictly scientific institution is the collection and publication
-of literature bearing on the protection of workers in one
-and another country, distribution of information, and the
-editing of reports and memoranda. The question of prevention
-of industrial poisoning has always taken a foremost place in the<span class="pagenum"><a name="Page_220" id="Page_220">[220]</a></span>
-programme of the International Association and in the agenda
-of the International Labour Bureau. At its first meeting a
-resolution was adopted advocating the prohibition of the
-use of white phosphorus and white lead, and the Labour
-Bureau in Basle was instructed to take the necessary
-steps. Special, if not prohibitive, economical considerations
-foreshadowed difficulties—all the greater because the matter
-at issue concerned prohibition of articles playing a part in the
-markets of the world. Just on that account international
-treatment of such questions is necessary, since a peaceful and
-orderly solution can only be arrived at on such lines. International
-effort endeavours here to press with equal weight on the
-countries competing with one another commercially, so that in
-the protection of the workers economic adjustment is sought
-in order that efforts based on humanitarian grounds shall not
-at the same time cause economic disadvantages, the aim being
-to produce general welfare and not merely protection of one
-class at the expense of another.</p>
-
-<p>Through these international agreements between various
-countries success in the direction aimed at is hopeful, and
-indeed to a certain extent—as in the phosphorus and lead
-questions—actually attained. Thus, for example, Germany
-and Italy were in a position to enforce prohibition of the use
-of white phosphorus early, while their neighbour Austria, on
-account of commercial and political considerations and the
-conditions of the home lucifer match industry, has only
-recently decided on prohibition.</p>
-
-<p>As international agreement for the protection of workers is
-advisable on economic grounds, so also is it reasonable and
-just from purely humanitarian reasons that workers, without
-reference to civil condition or nationality, should be equally
-protected. On this point it is proposed to take a vote and to
-press only for those reforms which are thoroughly sound and
-recognised as necessary.</p>
-
-<p>The first step in such a comprehensive attack is precise knowledge
-of the extent and source of origin of the particular forms
-of industrial poisoning and disease and the collection of reliable
-statistics. This suggested the obligation to notify such cases
-to the proper authorities in the same way as is now done in
-the case of infectious disease. A motion to this effect had<span class="pagenum"><a name="Page_221" id="Page_221">[221]</a></span>
-already been passed at the Conference of the International
-Association for Labour Legislation held in Basle, and a
-request was made to the Labour Bureau to prepare a list
-of the diseases and poisonings in question. To them we
-shall refer later, but a schedule is necessary as a basis
-to work upon. Yet even when this is done there are
-obviously great difficulties to be overcome in carrying out
-the requirement of notification when the aim is kept in
-mind of collecting complete statistical data for controlling
-the conditions giving rise to industrial disease. The proposal
-of the International Association seeks to make notification
-obligatory on the part both of the medical practitioner in
-attendance and the occupier, and in connection with this to
-secure the co-operation of the Sick Insurance Society.<a name="FNanchor_4" id="FNanchor_4"></a><a href="#Footnote_4" class="fnanchor">[D]</a> The
-proposal to require the appointed surgeons and surgeons of the
-Insurance Society to notify all cases is hardly feasible in view
-of their dependent position. Nor can the obligation on the
-occupiers lead to the desired result because of their lack of
-medical knowledge and the fact that by notifying they might
-be forced to act to their own disadvantage. A successful
-effort in this direction is recorded in Saxony, where lead
-poisoning was first made a notifiable disease, and later the
-general duty of notification of industrial poisoning was prescribed
-by Order dated March 4, 1901.</p>
-
-<p><span class="pagenum"><a name="Page_222" id="Page_222">[222]</a></span></p>
-
-<table summary="Yearly frequency of cases of poisoning" class="big borders">
-  <tr>
-    <th rowspan="2" colspan="2">Disease and Industry.<br />(1)</th>
-    <th colspan="26">Reported Cases.<a name="FNanchor_5" id="FNanchor_5"></a><a href="#Footnote_5" class="fnanchor">[E]</a></th>
-  </tr>
-  <tr>
-    <th colspan="2">1912.<br />(2)</th>
-    <th colspan="2">1911.<br />(3)</th>
-    <th colspan="2">1910.<br />(4)</th>
-    <th colspan="2">1909.<br />(5)</th>
-    <th colspan="2">1908.<br />(6)</th>
-    <th colspan="2">1907.<br />(7)</th>
-    <th colspan="2">1906.<br />(8)</th>
-    <th colspan="2">1905.<br />(9)</th>
-    <th colspan="2">1904.<br />(10)</th>
-    <th colspan="2">1903.<br />(11)</th>
-    <th colspan="2">1902.<br />(12)</th>
-    <th colspan="2">1901.<br />(13)</th>
-    <th colspan="2">1900.<br />(14)</th>
-  </tr>
-  <tr>
-    <td colspan="2">Lead Poisoning</td>
-    <td class="tdr nbr">587</td>
-    <td class="tdr nbl"><span class="smaller">44</span></td>
-    <td class="tdr nbr">669</td>
-    <td class="tdr nbl"><span class="smaller">37</span></td>
-    <td class="tdr nbr">505</td>
-    <td class="tdr nbl"><span class="smaller">38</span></td>
-    <td class="tdr nbr">553</td>
-    <td class="tdr nbl"><span class="smaller">30</span></td>
-    <td class="tdr nbr">646</td>
-    <td class="tdr nbl"><span class="smaller">32</span></td>
-    <td class="tdr nbr">578</td>
-    <td class="tdr nbl"><span class="smaller">26</span></td>
-    <td class="tdr nbr">632</td>
-    <td class="tdr nbl"><span class="smaller">33</span></td>
-    <td class="tdr nbr">592</td>
-    <td class="tdr nbl"><span class="smaller">23</span></td>
-    <td class="tdr nbr">597</td>
-    <td class="tdr nbl"><span class="smaller">26</span></td>
-    <td class="tdr nbr">614</td>
-    <td class="tdr nbl"><span class="smaller">19</span></td>
-    <td class="tdr nbr">629</td>
-    <td class="tdr nbl"><span class="smaller">14</span></td>
-    <td class="tdr nbr">863</td>
-    <td class="tdr nbl"><span class="smaller">34</span></td>
-    <td class="tdr nbr">1058</td>
-    <td class="tdr nbl"><span class="smaller">38</span></td>
-  </tr>
-  <tr>
-    <td class="tdr tdsub1 nbr">1.</td>
-    <td class="nbl">Smelting of metals</td>
-    <td class="tdr nbr">56</td>
-    <td class="tdr nbl"><span class="smaller">7</span></td>
-    <td class="tdr nbr">48</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">34</td>
-    <td class="tdr nbl"><span class="smaller">5</span></td>
-    <td class="tdr nbr">66</td>
-    <td class="tdr nbl"><span class="smaller">5</span></td>
-    <td class="tdr nbr">70</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">28</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">38</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">24</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">33</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">37</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">28</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">54</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">34</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-  </tr>
-  <tr>
-    <td class="tdr tdsub1 nbr">2.</td>
-    <td class="nbl">Brass works</td>
-    <td class="tdr nbr">5</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">9</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">7</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">5</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">6</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">9</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">11</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">5</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">10</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">15</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">5</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">6</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">3</td>
-  </tr>
-  <tr>
-    <td class="tdr tdsub1 nbr">3.</td>
-    <td class="nbl">Sheet lead and lead piping</td>
-    <td class="tdr nbr">6</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">12</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">4</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">9</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">14</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">6</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">7</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">9</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">7</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">11</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">12</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">17</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">17</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-  </tr>
-  <tr>
-    <td class="tdr tdsub1 nbr">4.</td>
-    <td class="nbl">Plumbing and soldering</td>
-    <td class="tdr nbr">35</td>
-    <td class="tdr nbl"><span class="smaller">5</span></td>
-    <td class="tdr nbr">37</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">25</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">28</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">27</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">20</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">16</td>
-    <td class="tdr nbl"><span class="smaller">4</span></td>
-    <td class="tdr nbr">24</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">21</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">26</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">23</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">23</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">9</td>
-  </tr>
-  <tr>
-    <td class="tdr tdsub1 nbr">5.</td>
-    <td class="nbl">Printing</td>
-    <td class="tdr nbr">37</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">32</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">33</td>
-    <td class="tdr nbl"><span class="smaller">4</span></td>
-    <td class="tdr nbr">21</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">30</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">26</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">16</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">19</td>
-    <td class="tdr nbl"><span class="smaller">4</span></td>
-    <td class="tdr nbr">15</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">13</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">19</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">23</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">18</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-  </tr>
-  <tr>
-    <td class="tdr tdsub1 nbr">6.</td>
-    <td class="nbl">File cutting</td>
-    <td class="tdr nbr">13</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">18</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">9</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">8</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">9</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">10</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">15</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">12</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">20</td>
-    <td class="tdr nbl"><span class="smaller">4</span></td>
-    <td class="tdr nbr">24</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">27</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">46</td>
-    <td class="tdr nbl"><span class="smaller">7</span></td>
-    <td class="tdr nbr">40</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-  </tr>
-  <tr>
-    <td class="tdr tdsub1 nbr">7.</td>
-    <td class="nbl">Tinning</td>
-    <td class="tdr nbr">15</td>
-    <td class="tdr nbl"><span class="smaller">11</span></td>
-    <td class="tdr nbr">13</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">17</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">22</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">10</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">25</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">18</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">14</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">10</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">14</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">11</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">10</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">5</td>
-  </tr>
-  <tr>
-    <td class="tdr tdsub1 nbr">8.</td>
-    <td class="nbl">White lead</td>
-    <td class="tdr nbr">23</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">41</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">34</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">32</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">79</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">71</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">108</td>
-    <td class="tdr nbl"><span class="smaller">7</span></td>
-    <td class="tdr nbr">90</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">116</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">109</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">143</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">189</td>
-    <td class="tdr nbl"><span class="smaller">7</span></td>
-    <td class="tdr nbr">358</td>
-    <td class="tdr nbl"><span class="smaller">6</span></td>
-  </tr>
-  <tr>
-    <td class="tdr tdsub1 nbr">9.</td>
-    <td class="nbl">Red lead</td>
-    <td class="tdr nbr">3</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">13</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">10</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">10</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">12</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">7</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">6</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">10</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">11</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">6</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">13</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">14</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">19</td>
-  </tr>
-  <tr>
-    <td class="tdr tdsub1 nbr">10.</td>
-    <td class="nbl">China and earthenware</td>
-    <td class="tdr nbr">80</td>
-    <td class="tdr nbl"><span class="smaller">14</span></td>
-    <td class="tdr nbr">92</td>
-    <td class="tdr nbl"><span class="smaller">6</span></td>
-    <td class="tdr nbr">77</td>
-    <td class="tdr nbl"><span class="smaller">11</span></td>
-    <td class="tdr nbr">58</td>
-    <td class="tdr nbl"><span class="smaller">5</span></td>
-    <td class="tdr nbr">117</td>
-    <td class="tdr nbl"><span class="smaller">12</span></td>
-    <td class="tdr nbr">103</td>
-    <td class="tdr nbl"><span class="smaller">9</span></td>
-    <td class="tdr nbr">107</td>
-    <td class="tdr nbl"><span class="smaller">4</span></td>
-    <td class="tdr nbr">84</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">106</td>
-    <td class="tdr nbl"><span class="smaller">4</span></td>
-    <td class="tdr nbr">97</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">87</td>
-    <td class="tdr nbl"><span class="smaller">4</span></td>
-    <td class="tdr nbr">106</td>
-    <td class="tdr nbl"><span class="smaller">5</span></td>
-    <td class="tdr nbr">200</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-  </tr>
-  <tr>
-    <td class="tdr tdsub1 nbr">10a.</td>
-    <td class="nbl">Litho-transfers</td>
-    <td class="tdr nbr">1</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">1</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">1</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">1</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">2</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">10</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">5</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">5</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">3</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">3</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">2</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">7</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">10</td>
-  </tr>
-  <tr>
-    <td class="tdr tdsub1 nbr">11.</td>
-    <td class="nbl">Glass cutting and polishing</td>
-    <td class="tdr nbr">1</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">5</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">—</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">4</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">3</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">4</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">4</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">3</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">—</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">4</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">8</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">11</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">7</td>
-  </tr>
-  <tr>
-    <td class="tdr tdsub1 nbr">12.</td>
-    <td class="nbl">Vitreous Enamelling</td>
-    <td class="tdr nbr">5</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">19</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">17</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">7</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">7</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">6</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">4</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">2</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">3</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">4</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">3</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">9</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">11</td>
-  </tr>
-  <tr>
-    <td class="tdr tdsub1 nbr">13.</td>
-    <td class="nbl">Electric accumulators</td>
-    <td class="tdr nbr">38</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">24</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">31</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">27</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">25</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">21</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">26</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">27</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">33</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">28</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">16</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">49</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">33</td>
-  </tr>
-  <tr>
-    <td class="tdr tdsub1 nbr">14.</td>
-    <td class="nbl">Paints and colours</td>
-    <td class="tdr nbr">19</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">21</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">17</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">39</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">25</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">35</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">37</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">57</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">32</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">39</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">46</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">56</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">56</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-  </tr>
-  <tr>
-    <td class="tdr tdsub1 nbr">15.</td>
-    <td class="nbl">Coach building</td>
-    <td class="tdr nbr">84</td>
-    <td class="tdr nbl"><span class="smaller">7</span></td>
-    <td class="tdr nbr">104</td>
-    <td class="tdr nbl"><span class="smaller">5</span></td>
-    <td class="tdr nbr">70</td>
-    <td class="tdr nbl"><span class="smaller">6</span></td>
-    <td class="tdr nbr">95</td>
-    <td class="tdr nbl"><span class="smaller">6</span></td>
-    <td class="tdr nbr">70</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">70</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">85</td>
-    <td class="tdr nbl"><span class="smaller">7</span></td>
-    <td class="tdr nbr">56</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">49</td>
-    <td class="tdr nbl"><span class="smaller">4</span></td>
-    <td class="tdr nbr">74</td>
-    <td class="tdr nbl"><span class="smaller">5</span></td>
-    <td class="tdr nbr">63</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">65</td>
-    <td class="tdr nbl"><span class="smaller">4</span></td>
-    <td class="tdr nbr">70</td>
-    <td class="tdr nbl"><span class="smaller">5</span></td>
-  </tr>
-  <tr>
-    <td class="tdr tdsub1 nbr">16.</td>
-    <td class="nbl">Ship building</td>
-    <td class="tdr nbr">34</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">36</td>
-    <td class="tdr nbl"><span class="smaller">6</span></td>
-    <td class="tdr nbr">21</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">27</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">15</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">22</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">26</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">32</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">48</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">24</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">15</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">28</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">32</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-  </tr>
-  <tr>
-    <td class="tdr tdsub1 nbr">17.</td>
-    <td class="nbl">Paint used in other industries</td>
-    <td class="tdr nbr">48</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">56</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">51</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">42</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">47</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">49</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">37</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">49</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">27</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">46</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">44</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">61</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">50</td>
-    <td class="tdr nbl"><span class="smaller">5</span></td>
-  </tr>
-  <tr>
-    <td class="tdr tdsub1 nbr">18.</td>
-    <td class="nbl">Other industries</td>
-    <td class="tdr nbr">84</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">88</td>
-    <td class="tdr nbl"><span class="smaller">4</span></td>
-    <td class="tdr nbr">47</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">52</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">78</td>
-    <td class="tdr nbl"><span class="smaller">5</span></td>
-    <td class="tdr nbr">56</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">66</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">70</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">53</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">40</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">64</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">89</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">86</td>
-    <td class="tdr nbl"><span class="smaller">4</span></td>
-  </tr>
-  <tr>
-    <td colspan="2">Phosphorus Poisoning</td>
-    <td class="tdr nbr">—</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">—</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">—</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">3</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">1</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">1</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">—</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">3</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">1</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">—</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">1</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">4</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">3</td>
-  </tr>
-  <tr>
-    <td colspan="2">Arsenic Poisoning</td>
-    <td class="tdr nbr">5</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">10</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">7</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">4</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">23</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">9</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">5</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">1</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">5</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">5</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">5</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">12</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">22</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-  </tr>
-  <tr>
-    <td colspan="2">Mercurial Poisoning</td>
-    <td class="tdr nbr">17</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">12</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">10</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">9</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">10</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">7</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">4</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">8</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">3</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">8</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">8</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">18</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">9</td>
-  </tr>
-  <tr>
-    <td colspan="2">Anthrax</td>
-    <td class="tdr nbr">47</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">64</td>
-    <td class="tdr nbl"><span class="smaller">11</span></td>
-    <td class="tdr nbr">51</td>
-    <td class="tdr nbl"><span class="smaller">9</span></td>
-    <td class="tdr nbr">56</td>
-    <td class="tdr nbl"><span class="smaller">12</span></td>
-    <td class="tdr nbr">47</td>
-    <td class="tdr nbl"><span class="smaller">7</span></td>
-    <td class="tdr nbr">58</td>
-    <td class="tdr nbl"><span class="smaller">11</span></td>
-    <td class="tdr nbr">67</td>
-    <td class="tdr nbl"><span class="smaller">22</span></td>
-    <td class="tdr nbr">59</td>
-    <td class="tdr nbl"><span class="smaller">18</span></td>
-    <td class="tdr nbr">50</td>
-    <td class="tdr nbl"><span class="smaller">10</span></td>
-    <td class="tdr nbr">47</td>
-    <td class="tdr nbl"><span class="smaller">12</span></td>
-    <td class="tdr nbr">38</td>
-    <td class="tdr nbl"><span class="smaller">9</span></td>
-    <td class="tdr nbr">39</td>
-    <td class="tdr nbl"><span class="smaller">10</span></td>
-    <td class="tdr nbr">37</td>
-    <td class="tdr nbl"><span class="smaller">7</span></td>
-  </tr>
-  <tr>
-    <td class="tdsub1" colspan="2">Wool</td>
-    <td class="tdr nbr">31</td>
-    <td class="tdr nbl"><span class="smaller">6</span></td>
-    <td class="tdr nbr">35</td>
-    <td class="tdr nbl"><span class="smaller">10</span></td>
-    <td class="tdr nbr">28</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">28</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">18</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">23</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">24</td>
-    <td class="tdr nbl"><span class="smaller">8</span></td>
-    <td class="tdr nbr">34</td>
-    <td class="tdr nbl"><span class="smaller">12</span></td>
-    <td class="tdr nbr">12</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">20</td>
-    <td class="tdr nbl"><span class="smaller">5</span></td>
-    <td class="tdr nbr">12</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">6</td>
-    <td class="tdr nbl"><span class="smaller">4</span></td>
-    <td class="tdr nbr">9</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-  </tr>
-  <tr>
-    <td class="tdsub1" colspan="2">Horsehair</td>
-    <td class="tdr nbr">7</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">8</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">6</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">8</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">10</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">17</td>
-    <td class="tdr nbl"><span class="smaller">4</span></td>
-    <td class="tdr nbr">10</td>
-    <td class="tdr nbl"><span class="smaller">4</span></td>
-    <td class="tdr nbr">7</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">12</td>
-    <td class="tdr nbl"><span class="smaller">4</span></td>
-    <td class="tdr nbr">7</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">10</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">9</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">12</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-  </tr>
-  <tr>
-    <td class="tdsub1" colspan="2">Handling of hides and skins</td>
-    <td class="tdr nbr">8</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">20</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">14</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">18</td>
-    <td class="tdr nbl"><span class="smaller">6</span></td>
-    <td class="tdr nbr">13</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">12</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">19</td>
-    <td class="tdr nbl"><span class="smaller">7</span></td>
-    <td class="tdr nbr">17</td>
-    <td class="tdr nbl"><span class="smaller">4</span></td>
-    <td class="tdr nbr">18</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">12</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">11</td>
-    <td class="tdr nbl"><span class="smaller">5</span></td>
-    <td class="tdr nbr">20</td>
-    <td class="tdr nbl"><span class="smaller">5</span></td>
-    <td class="tdr nbr">9</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-  </tr>
-  <tr>
-    <td class="tdsub1 bb" colspan="2">Other industries</td>
-    <td class="tdr nbr bb">1</td>
-    <td class="tdr nbl bb"></td>
-    <td class="tdr nbr bb">1</td>
-    <td class="tdr nbl bb"></td>
-    <td class="tdr nbr bb">3</td>
-    <td class="tdr nbl bb"><span class="smaller">2</span></td>
-    <td class="tdr nbr bb">2</td>
-    <td class="tdr nbl bb"><span class="smaller">1</span></td>
-    <td class="tdr nbr bb">6</td>
-    <td class="tdr nbl bb"><span class="smaller">3</span></td>
-    <td class="tdr nbr bb">6</td>
-    <td class="tdr nbl bb"><span class="smaller">2</span></td>
-    <td class="tdr nbr bb">14</td>
-    <td class="tdr nbl bb"><span class="smaller">3</span></td>
-    <td class="tdr nbr bb">1</td>
-    <td class="tdr nbl bb"><span class="smaller">1</span></td>
-    <td class="tdr nbr bb">8</td>
-    <td class="tdr nbl bb"><span class="smaller">2</span></td>
-    <td class="tdr nbr bb">8</td>
-    <td class="tdr nbl bb"><span class="smaller">5</span></td>
-    <td class="tdr nbr bb">5</td>
-    <td class="tdr nbl bb"></td>
-    <td class="tdr nbr bb">4</td>
-    <td class="tdr nbl bb"></td>
-    <td class="tdr nbr bb">7</td>
-    <td class="tdr nbl bb"><span class="smaller">1</span></td>
-  </tr>
-</table>
-
-<p><span class="pagenum"><a name="Page_223" id="Page_223">[223]</a></span></p>
-
-<p>My own experience does not lead me to expect much in
-elucidation of industrial diseases from the Sick Insurance
-Societies. In Austria they make a statistical return as to
-the causation of illness to the central authorities. I have
-myself—in my capacity as an official of the State Central
-Board—examined these in order to try and gain knowledge
-of the extent of industrial disease in Bohemia. In spite of
-the returns drawn up by the district surgeon who visits the
-factories in question, it was impossible for me to obtain a complete
-picture of the extent of industrial sickness. The reports
-only give valuable data on which to base action in particular
-cases, and from this standpoint I do not under-estimate their
-value. But so far as the expressed wish of the International
-Association is concerned they appear to fulfil it, inasmuch as
-for specially dangerous trades special reports are issued, the
-Austrian law for sick insurance requiring such industries to
-institute separate sick insurance funds with separate statistics.
-Hence, under present conditions, I do not see how the duty
-of notification will be effective. There remains the endeavour
-to secure insurance and the right to claim compensation for
-industrial disease in the same way as is provided for accidents.
-This point was fully discussed at the eighth International
-Congress for Workmen’s Insurance held in Rome in 1908.
-There is no valid ground for granting compensation only for
-<i>sudden</i> disturbance of health arising in the course of employment
-by accident or acute poisoning, and withholding it in the
-case of <i>gradual</i> disturbance of health caused equally by the
-trade, as the effects of such chronic indisposition weigh often no
-less heavily on the sufferer. Inclusion of industrial disease in
-the same category as accident insurance, as indeed has been<span class="pagenum"><a name="Page_224" id="Page_224">[224]</a></span>
-done in France, Switzerland and Great Britain, has, apart
-from the fact that it is dictated by fairness and humanity, the
-advantage of removing existing hardship and of solving
-doubtful cases. Correct statistics, further, would thus be
-obtainable for the first time, and the employer by insurance
-would be freed from the legal proceedings now frequently
-brought against him for injury due to chronic industrial
-poisoning. And it seems the more right and just course to
-institute a general scheme of insurance against industrial
-disease than to have recourse to an Employer’s Liability Act
-in this or that case, particularly as the question often arises
-in regard to a disease which develops gradually—In whose
-employment was the disease contracted?</p>
-
-<p>Clearly in such a scheme of insurance against both accident
-and industrial disease only specific industrial diseases would be
-included, i.e. diseases in which the connection with the industry
-can be clearly established as due to causes inherent in the
-industry, and traceable to definite materials used. Such diseases
-as tuberculosis and the effects of dust inhalation (bronchitis,
-&amp;c.), which as industrial diseases occur only too often, cannot
-be called specific, because they arise outside the industry and
-make decision impossible as to whether or not in a particular
-case the disease owed its origin to the occupation. In order to
-determine what should be regarded as specific industrial poisons
-it was deemed necessary to draw up a schedule. For one such
-list Sommerfeld (in collaboration with Oliver and Putzeys) is
-responsible, Carozzi of Milan for a second, and Fischer<a name="FNanchor_6" id="FNanchor_6"></a><a href="#Footnote_6" class="fnanchor">[F]</a> for a<span class="pagenum"><a name="Page_225" id="Page_225">[225]</a></span>
-third, published in 1910. Those by Sommerfeld and Fischer are
-constructed in similar fashion—enumeration of (1) the poisonous
-substance, (2) the industries in which it is made or used,
-(3) the channel of absorption, and (4) the symptoms produced.
-Sommerfeld enumerates the poisons in alphabetical order,
-noting against each the requisite preventive measures, while
-Fischer adopts a chemical classification, confining himself to
-general introductory remarks as to prevention.</p>
-
-<p>Sommerfeld proposes to limit notification to poisoning
-sharply defined as to the symptoms set up, such as lead, phosphorus,
-mercury, arsenic, chromium, carbonic oxide, aniline,
-benzene, nitrobenzene, carbon bisulphide, and nitrous fumes.
-This simplifies the obligation to notify, but does not dissipate
-the fears expressed above as to the difficulty, because in the
-present development of the chemical industries new substances
-involving new danger to the persons handling them are constantly
-being discovered, and thus there can be no finality as
-to which industrial poisonings should entitle to compensation.
-And if recourse were had from time to time to additions of new
-substances to the schedule, reliance would have to be placed on
-experience with regard to each substance added, and thus the
-actual individual who had suffered would not benefit. Fischer,
-indeed, acknowledges that any schedule must be incomplete,
-and emphasises the fact that continual additions would be
-necessary; otherwise it would be better to refrain altogether
-from publication of a list. Such lists may be valuable guides,
-but no sure foundation for insurance legislation. The only
-possible way to do this is to give as far as possible a correct
-definition of the industrial diseases entitling to compensation
-and, in isolated cases, to leave the decision to the expert opinion
-of competent judges.</p>
-
-<p>Extension of workmen’s insurance to cover chronic
-industrial poisoning is, however, most desirable in the interest
-of employers and employed, and also of science. The German
-accident insurance legislation is especially suited to do this,
-since the trade organisations direct their attention not only to
-the prevention of accidents but of industrial diseases also.</p>
-
-<p><span class="pagenum"><a name="Page_226" id="Page_226">[226]</a></span></p>
-
-<h3>III<br />
-<span class="smaller"><i>SPECIAL PREVENTIVE MEASURES FOR WORKERS</i></span></h3>
-
-<h4>SELECTION, CHOICE OF TRADE, ALTERNATION OF EMPLOYMENT,
-MEDICAL CONTROL, SAFETY APPLIANCES, INSTRUCTION AND
-CO-OPERATION OF WORKERS, CLOTHING, ATTENTION TO
-CLEANLINESS, FOOD, GENERAL WELFARE</h4>
-
-<p>As a practical measure in protection against trade risk
-selection of those capable of resisting danger has to be considered.
-It is obviously desirable to select for employment
-in a dangerous trade persons possessing powers of resistance,
-because predisposition and resistance to the action of poisons
-differ markedly in individuals. To some extent such a
-selection comes of itself, as those who are very susceptible are
-obliged by repeated attacks to give up the work. The social
-and physical misery, undeserved loss of employment, illness,
-and perhaps early death following on this kind of selection
-might be checked by timely medical examination so as to weed
-out the unfit. But medical examination prior to admission
-into a dangerous trade (actually practised in many industries
-involving risk of poisoning) inflicts hardship on those seeking
-employment, and recruits the ranks of the unwillingly
-unemployed. It would be much better were it possible to meet
-the need of selection by pertinent direction and guidance in
-choice of calling. There should be insistence in technical
-schools especially on the dangers inherent in certain industries,
-school medical examination as to physical qualifications for
-certain industries, and careful note made of individual suitability
-in labour bureaus, apprentice agencies, and the like.</p>
-
-<p>Young female workers, naturally less able to resist, should
-be excluded from work involving risk of poisoning—a principle
-which has been acted on in the legislation of civilised
-countries.</p>
-
-<p>Further, workers engaged in industries involving risk
-should not be exposed to the pernicious influence for too long a
-time. Hence the hours of employment should be shortened in
-occupations proved to be injurious to health. An important<span class="pagenum"><a name="Page_227" id="Page_227">[227]</a></span>
-aid in this respect is alternation of employment. Change of
-occupation is particularly recommended where the nature of
-the poisoning of which there is risk is cumulative in action,
-because in the intervals from the work the system will rid
-itself of the accumulated store. In this way a number of
-skilled resistant workers, familiar with the risk and knowing
-how to meet it, will be maintained. Casual labour works in a
-vicious circle—increase of fresh workers increases the danger
-and the number of cases of poisoning, and, <i>vice versa</i>, these
-augment again the need of change in the personnel, so that the
-number of cases of poisoning rises very high. Thus the industry
-itself may be endangered, since its prosperity depends mainly
-upon the existence of a skilled staff of workers. In dangerous
-trades, therefore, Hermann Weber’s words, ‘Change of work
-instead of change of workers,’ have much force.</p>
-
-<p>Periodical medical examination in these industries cannot
-well be omitted in order to weed out the physically unfit, and
-to suspend from work those who show early symptoms.
-Note should be kept of the state of health of the workers, the
-results of the periodical medical examination, the duration
-of symptoms, and the treatment of any illness that occurs.
-Medical supervision presupposes special training and experience
-in the medical man entrusted with the task.</p>
-
-<p>Further, in some industries in which poisonous materials
-are used, especially such as set up acute sudden poisoning,
-there should be a trained staff competent to recognise the first
-symptoms of poisoning and to render first aid, and having at
-its disposal adequate means of rescue.</p>
-
-<p>Apart from the rescue appliances generally needed in
-dangerous trades, stress must be laid on the value of oxygen
-apparatus as a means of saving life. In addition to what
-is needed for the sufferer there must be defensive apparatus at
-hand for the rescuers (breathing helmets, &amp;c.), to facilitate
-and make safe their rescue work when in a poisonous atmosphere.
-Without such defensive equipment rescuers should
-never venture into gas conduits, or into any place where
-presumably a poisonous atmosphere is to be met with. It
-hardly requires to be said that in dangerous industries medical
-aid should be within easy reach; in large works actual medical
-attendance may be necessary.</p>
-
-<p><span class="pagenum"><a name="Page_228" id="Page_228">[228]</a></span></p>
-
-<p>In acute as well as in chronic cases of poisoning early medical
-intervention is advisable. Hence medical aid should be sought
-on the earliest appearance of symptoms, and the worker, therefore,
-should know the nature and action of the poison with
-which he comes into contact. This brings us to the subject
-of the education of the worker and particularly observance
-of all those rules and regulations in which his co-operation is
-necessary. This co-operation of the workers is indispensable;
-it is the most important condition of effective defence. The
-best regulations and preventive measures are worthless if the
-worker does not observe them. He must be taught their aim,
-the way of using the means of defence; he must be admonished
-to use them, and, if necessary, compelled to do so. The
-co-operation of workmen’s organisations in this matter can
-avail much, since a workman most readily follows the advice
-of a fellow-worker.</p>
-
-<p>Teaching of the kind suggested can be done in different
-ways. Apart from lectures and practical courses, concise
-instructions, either in the form of notices or as illustrated
-placards, should be posted up in the workrooms or handed
-in the form of leaflets particularly to the newly employed.
-Distribution of such leaflets might well be placed as a duty
-on the employer.</p>
-
-<p>Of preventive measures applying to the individual those are
-of prime importance which serve to protect the worker, as far
-as is practicable, from coming into contact with the poison.
-Protection of this kind is attained by wearing suitable
-clothing, use of respirators, and careful cleanliness—especially
-before partaking of food. It cannot be too strongly urged that
-these precautions are a very potent defence against the danger
-of industrial poisoning, especially of the chronic forms, and
-in teaching workers their importance must be insisted on. It
-is not sufficient merely to put on overalls over the ordinary
-clothes. The ordinary clothes must be taken off before the
-commencement of work, and working suits put on, to be taken
-off again before the principal midday meal and before leaving
-work. They should be made of smooth, durable, washable
-material, and be properly washed and dried not less often than
-once a week. They must be plainly cut without folds or pockets.</p>
-
-<p>Direct handling of the poisonous substances is to be avoided,<span class="pagenum"><a name="Page_229" id="Page_229">[229]</a></span>
-but where this is necessary impervious gloves may have to be
-worn, especially in the case of poisons which can be absorbed
-through, or act injuriously on, the skin. If there is risk of
-splashing or spilling of poisonous liquids on to the clothes,
-impermeable or partly impermeable overalls (aprons, &amp;c.)
-should be worn. The obligation of providing the overalls or
-working suits falls naturally on the employer in industries
-where poisonous substances are used, and there is equally
-obligation on the employee to use the
-articles provided.</p>
-
-<p>Suitable cloakroom accommodation
-is essential, by which is meant room not
-only to change clothes with cupboards
-or hooks on one side for clothing taken
-off on commencement of work and on
-the other the working suits, but also
-ample washing accommodation. These
-cupboards should be double, that is,
-be divided by a partition into two
-parts, one serving for the ordinary and
-the other for the working clothes.</p>
-
-<div class="figcenter" style="width: 200px;" id="fig35">
-
-<img src="images/fig35.jpg" width="200" height="300" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 35.</span>—Aluminium
-Respirator</p>
-
-</div>
-
-<p>Protection of the respiratory organs
-can to some extent be obtained by so-called
-respirators worn over the mouth
-and nose. Often they consist simply of a moist sponge or folds
-of cloth, or again may be complicated air-proof affairs enclosing
-mouth and nose, or the whole face like a mask, or even the head
-like a helmet; they fit close, and the aperture for respired air
-is provided with filtering material (cotton wool, &amp;c.) placed
-between two layers of wire gauze. The outer layer of the
-gauze moves on a hinge, so that the filtering material can be
-renewed after each time that it has been used. The construction
-of respirators is extraordinarily varied. One form is
-illustrated. They must be light, and in order not to obstruct
-breathing seriously they are often provided with valves—closing
-during inspiration and opening during exhalation.
-Generally the respirators in common use do not quite satisfactorily
-fulfil the conditions required. After a time the
-pressure becomes irksome, the face becomes hot, breathing
-more difficult, and discomfort from wearing them unbearable.</p>
-
-<p><span class="pagenum"><a name="Page_230" id="Page_230">[230]</a></span></p>
-
-<p>Respirators are only to be regarded in the light of secondary
-aids and for occasional use.</p>
-
-<p>During temporary exposure to an atmosphere charged
-with poisonous dust the wearing of an efficient apparatus—preferably
-one protecting the head—is very desirable.</p>
-
-<div class="figcenter" style="width: 400px;" id="fig36">
-
-<img src="images/fig36.jpg" width="400" height="450" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 36.</span>—Smoke Helmet, Flexible Tubing, and Foot Bellows (<i>Siebe, Gorman &amp; Co.</i>)</p>
-
-</div>
-
-<p>Respirators afford no protection, or a very imperfect one,
-against dangerous gases or fumes. If soaked with an absorbing
-or neutralising fluid they can scarcely be worn for any length
-of time.</p>
-
-<p><span class="pagenum"><a name="Page_231" id="Page_231">[231]</a></span></p>
-
-<p>In an atmosphere charged with poisonous gas recourse
-should be had either to a smoke helmet with flexible tubing and
-bellows or to an oxygen breathing apparatus so constructed
-that the workman carries the necessary supply of oxygen with
-him in a knapsack on his back. In the latter case oxygen
-from a compressed cylinder of the gas is conveyed to the
-breathing mask, so that respiration is independent of the
-surrounding atmosphere.</p>
-
-<div class="figcenter" style="width: 500px;" id="fig37">
-
-<img src="images/fig37.jpg" width="500" height="400" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 37.</span>—Diagram of Draeger 1910-11, Pattern H (<i>R. Jacobson</i>)</p>
-
-<p class="caption">P Alkali cartridges; K Cooler; C Aspirating pipe; L₁ Purified air;
-L₂ Expired air.</p>
-
-</div>
-
-<p>The mode of working is represented diagrammatically in
-figs. <a href="#fig37">37</a> and <a href="#fig40">40</a>. After putting on the helmet, the bag is first
-filled with fresh air, the air valve is then closed, and the valve
-of the oxygen cylinder unscrewed so as to permit of the flow of
-the oxygen which, mixes with the air in the bag, and begins to
-circulate; the expired air passes through the caustic potash
-pellets P, which free it of carbonic acid gas, so that, with a fresh
-supply of oxygen from the cylinder through the pipe C, it is<span class="pagenum"><a name="Page_232" id="Page_232">[232]</a></span>
-regenerated and made fit for breathing again. The pressure
-in the cylinder is measured by a manometer, which indicates
-also when the supply of oxygen gives out.</p>
-
-<div class="figcenter" style="width: 500px;" id="fig38">
-
-<img src="images/fig38.jpg" width="500" height="450" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 38.</span>—Showing the Potash Cartridge No. 2 with Change Mechanism X;
-No. 2 Oxygen Cylinder with Spanner V; and on the Left a Hexagonal Socket U,
-for unscrewing the Locking Nuts of Reserve Cylinders (<i>R. Jacobson</i>)</p>
-
-</div>
-
-<div class="figcenter" style="width: 475px;" id="fig39">
-
-<img src="images/fig39.jpg" width="475" height="500" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 39.</span>—‘Proto’ patent self-contained breathing apparatus (<i>Siebe,
-Gorman &amp; Co.</i>)</p>
-
-</div>
-
-<div class="blockquote">
-
-<p>Another apparatus—the ‘Proto’ patent self-contained breathing
-apparatus (Fleuss-Davis patents)—is also illustrated in <a href="#fig39">fig.
-39</a>. <a href="#fig40">Illustration 40</a> gives a diagrammatic view of the principle
-upon which it is designed. The instructions for using the
-‘Proto’ apparatus are as follows:</p>
-
-<p><i>The oxygen cylinders</i> (B, B), having been charged with
-oxygen through the nipple at (H) to a pressure of 120 atmospheres
-(about 1800 lbs. per square inch), are to be re-attached to the
-belt as shown, and the reducing valve, with its tubes, &amp;c., is to<span class="pagenum"><a name="Page_233" id="Page_233">[233]</a></span>
-be connected to the nipple at (H). This supply is sufficient for
-fully two hours.</p>
-
-<p><i>Charging the breathing bag.</i>—Put 4 lbs. of stick caustic <i>soda</i>
-into the bag (D), i.e. 2 lbs. into each compartment, and immediately
-fasten the mouth of the bag by means of the clamps
-and wing nuts (O). If the apparatus is not to be used at once,
-but is to be hung up for use at some future time, the indiarubber
-plug which is supplied with the apparatus should be tightly
-fitted into the mouthpiece in order to prevent access of air to
-the caustic soda, and to preserve it until required for use.</p>
-
-<p>See that the inlet and outlet valves (T and S) and the connection
-(N) are screwed up tightly.</p>
-
-<p>The small relief valve (K) is only to be opened (by pressing<span class="pagenum"><a name="Page_234" id="Page_234">[234]</a></span>
-it with the finger) when the bag becomes unduly inflated
-through excess of oxygen. This may occur from time to time, as
-the reducing valve is set to deliver more than the wearer actually
-requires.</p>
-
-<p><i>Equipment.</i>—The whole apparatus is supported upon a
-broad belt which is strapped round the body. The bag is also
-hung by a pair of shoulder braces.</p>
-
-<p>The wearer having put the equipment over his shoulders,
-fastens the belt and takes the plug out of the mouthpiece. The
-moment the mouthpiece is put into the mouth or the mask is
-adjusted, the main valve (H) is to be opened not more than
-one turn and the necessary supply of oxygen will then flow into
-the bag. It is advisable to open the by-pass (I) to inflate
-partially the breathing bag (D) for a start, but this valve should
-again be screwed up quite tight and not touched again, except
-in the case of emergency as previously described should the bag
-become deflated. Breathing will then go on comfortably.</p>
-
-<p>Should the by-pass (I) on the reducing valve (C) get out of
-order then the wearer should turn on the by-pass (I) from
-time to time to give himself the necessary quantity of oxygen,
-but, as stated above, this is only to be done in case of deflation
-of the bag. The best guide as to the quantity of oxygen to
-admit <i>in the above circumstances</i> is the degree of inflation of the
-breathing bag. It will be found to be quite satisfactory if the
-bag be kept moderately distended.</p>
-
-<p><i>After using the apparatus.</i>—The caustic soda should <i>at once</i> be
-thrown away, but if it is neglected and the soda becomes caked,
-it must be dissolved out with warm water before putting in a
-fresh supply. Caustic soda will not damage vulcanised indiarubber,
-but it will damage canvas and leather, and will burn the
-skin if allowed to remain upon it.</p>
-
-<p>If the apparatus is to be used again at once, it can be recharged
-with caustic soda at once, but if it is only to be charged
-ready for use at some future time the indiarubber bag should
-be thoroughly washed out with warm water and dried inside
-with a cloth or towel.</p>
-
-<p>When emptying or recharging the rubber bag with caustic
-soda, it must always be removed from the canvas bag. After
-use each day, it is advisable to wash the rubber mouthpiece
-(or mask, as the case may be) with yellow soap and water. This
-acts as a preservative to the indiarubber.</p>
-
-<p>Every man who is to use the apparatus should have his own
-mouthpiece and noseclip, or mask, as the case may be, under
-his own special care, both for sanitary reasons and so that he
-may shape and adjust the mask to fit himself comfortably and
-air-tightly, to such an extent that if the outlets are stopped up
-by the hands while the mask is held in position by its bands no
-breath can pass in or out.</p>
-
-</div>
-
-<p><span class="pagenum"><a name="Page_235" id="Page_235">[235]</a></span></p>
-
-<div class="figcenter" style="width: 525px;" id="fig40">
-
-<img src="images/fig40.jpg" width="525" height="700" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 40.</span>—‘Proto’ Patent Self-breathing Apparatus (<i>Siebe, Gorman &amp; Co.</i>)</p>
-
-</div>
-
-<p><span class="pagenum"><a name="Page_236" id="Page_236">[236]</a></span></p>
-
-<div class="figcenter" style="width: 475px;" id="fig41">
-
-<img src="images/fig41.jpg" width="475" height="700" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 41.</span>—Arrangement of Cloak-room, Washing and Bath Accommodation,
-and Meal-room in a White Lead Factory</p>
-
-</div>
-
-<p><span class="pagenum"><a name="Page_237" id="Page_237">[237]</a></span></p>
-
-<p>Where poisonous substances giving off dust or fumes are used,
-regular washing and rinsing the mouth (especially before meals
-and on leaving) is of great importance. Naturally the washing
-conveniences (basins, soap, brushes, towels) must be sufficient
-and suitable, and the workers instructed as to the importance
-of cleanliness by the foreman. They should be urged to bath
-in rotation, and time for it should be allowed during working
-hours.</p>
-
-<p>The taking of meals and use of tobacco in the workrooms
-must be prohibited. Meal rooms should be so arranged as to be
-contiguous to the cloakroom and washing accommodation, the
-worker gaining access to the meal room through the cloakroom
-and bathroom. The arrangement described is illustrated in
-<a href="#fig41">fig. 41</a>. The meal room serves also the purpose of a sitting-room
-during intervals of work, and it goes without saying that
-cloakroom and lavatory accommodation are as necessary in
-small as in large premises.</p>
-
-<p>Simple lavatory basins of smooth impervious surface fitted
-with a waste pipe and plug, or tipping basins, are recommended
-in preference to troughs which can be used by several persons
-at once. Troughs, however, without a plug, and with jets of
-warm water, are free from objection.</p>
-
-<p>The douche bath has many advantages for workmen over
-the slipper bath. The initial cost is comparatively small, so
-that it can be placed at the disposal of the workers at very small
-outlay. Maintenance and cleanliness of douche baths are
-more easily secured than of other kinds, where changing the
-water and keeping the bath in good order involve time and
-expense. A dressing-room should form part of the douche
-or slipper bath equipment. Walls and floors must be impervious
-and, preferably, lined with smooth tiles or cement.
-It is better that the shower bath should be under the control of
-the worker by a chain rather than be set in motion by means of
-mechanism when trodden upon. The arrangement of baths is
-illustrated in <a href="#fig43">fig. 43</a>. In many large works large bath buildings
-have been erected. <a href="#fig44a">Fig. 44</a> is a plan of the splendid bath
-arrangements at the colour works of Messrs. Lucius, Meister
-&amp; Brüning of Höchst a.-M.</p>
-
-<p><span class="pagenum"><a name="Page_238" id="Page_238">[238]</a></span></p>
-
-<div class="figcenter" style="width: 700px;" id="fig42">
-
-<img src="images/fig42.jpg" width="700" height="475" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 42.</span>—Good Washing and Bath Accommodation in a Lead Smelting Works</p>
-
-</div>
-
-<p><span class="pagenum"><a name="Page_239" id="Page_239">[239]</a></span></p>
-
-<div class="figcenter" style="width: 700px;" id="fig43">
-
-<img src="images/fig43.jpg" width="700" height="475" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 43.</span>—Washing Trough, Douche Baths, and Clothes Cupboards, Type common on the Continent</p>
-
-</div>
-
-<p><span class="pagenum"><a name="Page_240" id="Page_240">[240]</a></span></p>
-
-<div class="figcenter" style="width: 400px;" id="fig44a">
-
-<img src="images/fig44a.jpg" width="400" height="175" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 44a.</span>—Baths in the Höchst Aniline Works (<i>after Grandhomme</i>)</p>
-
-</div>
-
-<div class="figcenter" style="width: 500px;" id="fig44b">
-
-<img src="images/fig44b.jpg" width="500" height="425" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 44b.</span>—Ground Floor</p>
-
-</div>
-
-<div class="figcenter" style="width: 600px;" id="fig44c">
-
-<img src="images/fig44c.jpg" width="600" height="475" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 44c.</span>—First Floor.
-<i>a</i>, <i>c</i>, Baths (slipper and douche) for workmen; <i>b</i>, Washing accommodation for
-workmen; <i>d</i>, <i>e</i>, Baths for officials; <i>g</i>, Attendant’s quarters; <i>f</i>, Hot air (Turkish)
-baths; <i>i</i>, Warm water reservoir.</p>
-
-</div>
-
-<p>Naturally maintenance of the general health by good
-nourishing diet is one of the best means of defence against
-onset of chronic industrial poisoning. Over and over again it
-has been noticed that ill-fed workers speedily succumb to doses
-of poison which well-nourished workers can resist. It is not
-our province here to discuss fully the diet of a working-class
-population. We merely state that it is a matter of vital<span class="pagenum"><a name="Page_241" id="Page_241">[241]</a></span>
-importance to those employed in dangerous trades. The
-question of a suitable drink for workers to take the place of
-alcohol calls for special attention, as, when complicated with
-alcoholism, both acute and chronic poisonings entail more
-serious results than they otherwise would do. Over-indulgence
-in alcohol, owing to its effect on the kidneys, liver, digestion,
-nervous system, and power of assimilation generally, requires
-to be checked in every way possible. Apart from good drinking
-water, milk, coffee, tea, fruit juices and the like, are excellent.
-Milk is especially recommended, and should be supplied gratis
-to workers in dangerous trades, notably where there is risk
-of lead poisoning.</p>
-
-<p>Lastly, other features such as games and exercise in the
-open air, which help to strengthen bodily health, must not be
-forgotten. In this connection much good work has already
-been done by employers’ and workers’ organisations.</p>
-
-<p><span class="pagenum"><a name="Page_242" id="Page_242">[242]</a></span></p>
-
-<h3>IV<br />
-<span class="smaller"><i>GENERAL REMARKS ON PREVENTIVE MEASURES</i></span></h3>
-
-<h4>GENERAL PRINCIPLES, SUBSTITUTES FOR DANGEROUS MATERIALS,
-CLEANLINESS OF WORKROOMS, CUBIC SPACE, VENTILATION,
-REMOVAL OF DUST AND FUMES</h4>
-
-<p>Preventive measures against industrial poisoning aim at
-an unattainable goal of so arranging industrial processes that
-employment of poisonous substances would be wholly avoided.
-Such an ideal must be aimed at wherever practicable. Prohibition
-of direct handling of poisonous substances is also
-sometimes demanded, which presupposes (although it is not
-always the case) that this is unnecessary or can be made unnecessary
-by suitable mechanical appliances. We have to be
-contented, therefore, for the most part, with removal of injurious
-dust and fumes as quickly as possible at the point
-where they are produced, and regulations for the protection
-of workers from industrial poisoning deal mainly with the
-question of the prevention of air contamination and removal of
-contaminated air. Substitution of non-injurious for injurious
-processes is only possible in so far as use of the harmless process
-gives technically as good results as the other. If such a substitute
-can be found let it be striven for. Mention has already
-been made of international prohibition of certain substances,
-and attention has been drawn to economical considerations
-affecting this point.</p>
-
-<p>Prohibition obviously may paralyse branches of industry
-and hit heavily both employers and employed. The skilled
-trained workers are just the ones to suffer, since they are no
-longer in a position to take up another equally remunerative
-trade.</p>
-
-<p>Judgment has to be exercised before enforcing new regulations
-in order that good and not harm may follow. If a
-satisfactory substitute be discovered for methods of work
-injurious to health, then ways and means will be found to
-make the alteration in the process economically possible. It
-may, however, demand sacrifice on the part of employers and
-employed, but the progress is worth the sacrifice.</p>
-
-<p><span class="pagenum"><a name="Page_243" id="Page_243">[243]</a></span></p>
-
-<p>The following are instances of substitution of safe processes
-for those involving risk: generation of dust can sometimes be
-avoided by a ‘wet’ method (watering of white lead chambers,
-grinding pulp lead with oil, damping of smelting mixtures, &amp;c.);
-the nitrate of silver and ammonia process has replaced the tin
-and mercury amalgam used in silvering of mirrors; electroplating
-instead of water gilding (coating objects with mercury
-amalgam and subsequently volatilising the mercury); enamelling
-with leadless instead of lead enamels; use of air instead
-of mercury pumps in producing the vacuum in incandescent
-electric lamps.</p>
-
-<p>Dealing further with the sanitation of the factory and workshop
-after personal cleanliness, the next most important measure
-is cleanliness of the workroom and purity of the air. Workrooms
-should be light and lofty; and have floors constructed of smooth
-impervious material easily kept clean. The walls should be
-lime-washed or painted with a white oil paint. Angles and
-corners which can harbour dirt should be rounded. Cleansing
-requires to be done as carefully and as often as possible, preferably
-by washing down or by a vacuum cleaner. Saturation
-of the floor with dust oil is recommended by some authorities
-in trades where poisonous dust is developed and is permitted
-as an alternative to the methods described. I refrain from
-expressing an opinion on this method of laying dust, since by
-adoption of the practice insistence on the need for removal of
-the poisonous material from the workrooms loses its force—a
-thing, in my opinion, to be deprecated.</p>
-
-<p>The necessity of keeping the atmosphere of workrooms
-pure and fresh makes it essential that there should be sufficient
-cubic space per person and that proper circulation of the air
-should be maintained. The minimum amount of cubic space
-legally fixed in many countries—10-15 cubic metres—is a
-minimum and should be greatly exceeded where possible.
-Natural ventilation which is dependent upon windows,
-porosity of building materials, cracks in the floors, &amp;c.,
-fails when, as is desirable for purposes of cleanliness, walls
-and floors are made of smooth impermeable material, and
-natural ventilation will rarely supply the requisite cubic feet
-of fresh air quickly enough. Ordinarily, under conditions
-of natural ventilation, the air in a workroom is renewed in<span class="pagenum"><a name="Page_244" id="Page_244">[244]</a></span>
-from one to two hours. Artificial ventilation therefore becomes
-imperative. Natural ventilation by opening windows and doors
-can only be practised in intervals of work and as a rule only
-in small workrooms. During work time the draught and
-reduction of temperature so caused produce discomfort.</p>
-
-<p><i>Artificial ventilation</i> is effected
-by special openings and ducts
-placed at some suitable spot in the
-room to be ventilated and arranged
-so that either fresh air is introduced
-or air extracted from the
-room. The first method is called
-propulsion, the latter exhaust ventilation.
-Various agencies will produce
-a draught in the ventilating
-ducts, namely, difference of temperature
-between the outside and
-inside air, which can be artificially
-strengthened (<i>a</i>) by utilising the
-action of the wind, (<i>b</i>) by heating
-the air in the exhaust duct, (<i>c</i>) by
-heating apparatus, and (<i>d</i>) by
-mechanical power (use of fans).</p>
-
-<p>Where advantage is taken of
-the action of the wind the exit
-to the ventilating duct must be
-fitted with a cowl.</p>
-
-<p>The draught in pipes is materially
-increased if they are led
-into furnace flues or chimneys; in
-certain cases there is advantage
-in constructing perpendicular
-ventilating shafts in the building
-extending above the roof and fitted
-with cowls. Combination of heating and ventilation is very
-effective.</p>
-
-<div class="figcenter" style="width: 150px;" id="fig45">
-
-<img src="images/fig45.jpg" width="150" height="400" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 45.</span>—Steam Injector (<i>after
-Körting</i>), showing steam injector
-and air entry</p>
-
-</div>
-
-<p>In workrooms, however, where there is danger of poisoning
-by far the most effective method of ventilation is by means of
-fans driven by mechanical power. All the means for securing
-artificial ventilation hitherto mentioned depend on a number of<span class="pagenum"><a name="Page_245" id="Page_245">[245]</a></span>
-factors (wind, difference of temperature, &amp;c.), the influence of
-which is not always in the direction desired. Exact regulation,
-however, is possible by fans, and the quantity of air introduced
-or extracted can be accurately calculated beforehand
-in planning the ventilation. In drawing up such a plan,
-detailing the arrangement, proportions of the main and branch
-ducts, expenditure of power, &amp;c., a ventilating engineer should
-be consulted, as it is his business to deal with complicated
-problems of ventilation depending
-entirely for success on the design
-of the ventilation.</p>
-
-<p>Injectors are usually only employed
-for special technical or
-economical reasons. A jet of
-steam or compressed air which
-acts on the injector creates a
-partial vacuum and so produces
-a powerful exhaust behind. <a href="#fig45">Fig.
-45</a> shows the mechanism of
-an injector. They are used for
-exhausting acid fumes which
-would corrode metal fans and
-pipes, and for explosive dust
-mixtures where fans are inadmissible.</p>
-
-<div class="figcenter" style="width: 325px;" id="fig46">
-
-<img src="images/fig46.jpg" width="325" height="400" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 46.</span>—Propeller Fan coupled
-to Electromotor (<i>Davidson &amp;
-Co., Ltd.</i>)</p>
-
-</div>
-
-<p>In the industries described in this book fans are most
-commonly used. These are, in the main, wheels with two
-or more wing-shaped flattened blades. Some are encased,
-others are open and fitted by means of annular frames in the
-ducts according to the intended effect and kind of fan. Fans are
-of two kinds, propeller and centrifugal, and, according to the
-pressure they exert, of low, medium, or high pressure. They
-are now often driven electrically, in which case there is advantage
-in coupling them directly with the motor.</p>
-
-<p><i>Propeller fans</i> have curved screw-shaped blades and are
-set at right angles in the duct upon the column of air in which
-they act by suction. The air is moved in the direction of the
-axis of the fan, and generally it is possible, by reversing the
-action, to force air in instead of extracting it. The draught
-produced is a low-pressure one (generally less than 15 mm. of<span class="pagenum"><a name="Page_246" id="Page_246">[246]</a></span>
-water). The current of air set in motion travels at a relatively
-slow speed, yet such fans are capable, when suitably proportioned,
-of moving large volumes of air. Propeller fans are
-specially suitable for the general ventilation of rooms when
-the necessary change of air is not being effected by natural
-means.</p>
-
-<div class="figcenter" style="width: 325px;" id="fig47">
-
-<img src="images/fig47.jpg" width="325" height="400" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 47.</span>—The Blackman (Belt-driven) Fan.</p>
-
-</div>
-
-<p><i>Centrifugal</i> or <i>high-pressure fans</i> (see figs. <a href="#fig48a">48<span class="smcap">a</span></a> and <a href="#fig48b">48<span class="smcap">b</span></a> ) are
-always encased in such a way that the exhaust ducts enter
-on one or both sides of the axis. The air thus drawn in is
-thrown by the quickly rotating numerous straight blades to
-the periphery and escapes at the outlet. The centrifugal fan
-travels at a great speed, and the air current has therefore great
-velocity and high pressure. When the pressure is less than
-120 mm. it is described as a medium, and when greater, a high-pressure
-fan. For the former a galvanised iron casing suffices;
-for the latter the casing requires to be of cast iron. Medium
-pressure centrifugal fans are used to exhaust dust or fumes
-locally from the point at which they are produced. They
-play a great part in industrial hygiene.</p>
-
-<p><span class="pagenum"><a name="Page_247" id="Page_247">[247]</a></span></p>
-
-<div class="figcenter" style="width: 400px;" id="fig48a">
-
-<img src="images/fig48a.jpg" width="400" height="325" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 48a.</span>—‘Sirocco’ Centrifugal Fan</p>
-
-</div>
-
-<div class="figcenter" style="width: 400px;" id="fig48b">
-
-<img src="images/fig48b.jpg" width="400" height="375" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 48b.</span>—Showing exhaust aperture and fan blades</p>
-
-</div>
-
-<p>High-pressure fans are used mainly for technical purposes,
-as, for example, the driving of air or gas at high pressure.
-Localised ventilation is needed to limit diffusion of dust
-and fumes, which is attained in a measure also by separation
-of those workrooms in which persons come into contact
-with poisonous materials from others. Separation of workrooms,
-however, is not enough, as it is the individual who
-manipulates the poison for whom protection is desired. To
-enclose or hood over a dusty machine or fume-producing
-apparatus completely, or to close hermetically a whole series
-of operations by complicated technical arrangements, is only
-possible when no opening or hand feeding is required.
-Dangerous substances can only be wholly shut in by substitution
-of machinery for handwork.</p>
-
-<p><span class="pagenum"><a name="Page_248" id="Page_248">[248]</a></span></p>
-
-<div class="figcenter" style="width: 700px;" id="fig49">
-
-<img src="images/fig49.jpg" width="700" height="475" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 49.</span>—Localised Exhaust Ventilation in a Colour Factory (<i>Sturtevant Engineering Co., Ltd.</i>)</p>
-
-</div>
-
-<p><span class="pagenum"><a name="Page_249" id="Page_249">[249]</a></span></p>
-
-<div class="figcenter" style="width: 500px;" id="fig50">
-
-<img src="images/fig50.jpg" width="500" height="275" alt="" />
-
-<table>
-  <tr>
-    <td><span class="smcap">Fig. 50a.</span></td>
-    <td><span class="smcap">Fig. 50b.</span></td>
-  </tr>
-</table>
-
-<p class="caption">Ball Mills</p>
-
-</div>
-
-<p>Where, however, absolute contact is unavoidable the dust
-or fume must be carried away at its source. This is done by
-exhaust ventilation, locally applied, in the following manner:
-A suitable hood or air guide of metal or wood is arranged
-over the point where the dust is produced, leaving as small an
-opening as possible for necessary manipulations. The hood
-is connected with a duct through which the current of air
-travels. An exhaust current dependent upon heat will only
-suffice in the case of slight development of dust or fumes.
-As a rule exhaust by a fan is necessary. Where exhaust
-ventilation has to be arranged at several points all these are
-connected up by branch ducts with the main duct and centrifugal
-fan. Where the ducts lie near the floor it is advisable
-to fix adjustable openings in them close to the floor to remove
-the sweepings.</p>
-
-<div class="figcenter" style="width: 400px;" id="fig51">
-
-<img src="images/fig51.jpg" width="400" height="600" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 51.</span>—Ventilated Packing Machine (<i>after Albrecht</i>)</p>
-
-<p class="caption"><i>A</i> Worm; <i>B</i> Collector; <i>D</i> Fan; <i>E</i> Filter bag; <i>J</i>, <i>F</i> Movable shutters;
-<i>H</i> Jolting arrangement</p>
-
-</div>
-
-<p>It is important for the exhaust system of ventilation to be
-designed in general so that the dust is drawn away from the
-face of the worker downwards and backwards. Many horrible<span class="pagenum"><a name="Page_250" id="Page_250">[250]</a></span>
-arrangements are found in which the dust is first aspirated past
-the mouth and nose before it is drawn into a hood overhead.
-The proportions of the branch pipes to the main duct require to
-be thought out, and friction and resistance to the flow must be
-reduced as far as possible by avoidance of sharp bends. Branch
-pipes should enter the main duct at an angle of thirty<span class="pagenum"><a name="Page_251" id="Page_251">[251]</a></span>
-degrees. A completely satisfactory system requires very special
-knowledge and often much ingenuity when the apparatus is
-complicated.</p>
-
-<p>Disintegrators and edge runners can generally be covered in
-and the cover connected with an exhaust. Ball mills, when
-possible, are best as the rotating iron cylinder containing the
-steel balls and the material to be pulverised is hermetically
-closed.</p>
-
-<p>Powdered material can be carried mechanically from one
-place to another by worms, screws, endless bands, or be driven
-in closed pipes by means of compressed air. The inevitable
-production of dust in packing can be avoided by the use of
-ventilated packing machines, which are especially necessary
-in the case of white lead, bichromates, basic slag, &amp;c.</p>
-
-<div class="figcenter" style="width: 400px;" id="fig52">
-
-<img src="images/fig52.jpg" width="400" height="250" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 52.</span></p>
-
-</div>
-
-<p>The difficulty is great in preventing dust in sieving and
-mixing, since this is mainly done by hand. Still here, for
-example, by use of cases with arm-holes and upper glass cover,
-injury to health can be minimised. Benches with a wire screen
-and duct through which a downward exhaust passes are useful
-in sorting operations (<a href="#fig52">fig. 52</a>).</p>
-
-<p><a href="#fig53">Fig. 53</a> illustrates a grinding or polishing wheel fitted with
-localised exhaust.</p>
-
-<p><span class="pagenum"><a name="Page_252" id="Page_252">[252]</a></span></p>
-
-<div class="figcenter" style="width: 475px;" id="fig53">
-
-<img src="images/fig53.jpg" width="475" height="700" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 53.</span>—Removing Dust from Bobs and Mops (<i>James Keith &amp; Blackman Co.,
-Ltd. By permission of the Controller of H.M. Stationery Office</i>)</p>
-
-</div>
-
-<p><span class="pagenum"><a name="Page_253" id="Page_253">[253]</a></span></p>
-
-<p>To prevent escape of injurious gases all stills and furnaces
-must be kept as airtight as possible and preferably under a
-slight negative pressure. Agitators must be enclosed and
-should be fitted with arrangements for carrying on the work
-mechanically or by means of compressed air and, if necessary,
-exhaust ventilation applied to them. The aim should be to
-enclose entirely drying and extracting apparatus.</p>
-
-<div class="figcenter" style="width: 500px;" id="fig54">
-
-<img src="images/fig54.jpg" width="500" height="375" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 54.</span>—‘Cyclone’ Separator (<i>Matthews &amp; Yates, Ltd.</i>)</p>
-
-</div>
-
-<p>An important question remains as to what shall be done with
-the dust and fumes extracted. In many cases they cannot
-be allowed to escape into the atmosphere outside, and in the
-interests of economy recovery and utilisation of the waste
-is the thing to aim at. This vital subject can only receive
-barest mention here. The dust or fumes extracted require
-to be subjected to processes of purification with a view to
-recovery of the often valuable solid or gaseous constituents
-and destruction of those without value.</p>
-
-<p><span class="pagenum"><a name="Page_254" id="Page_254">[254]</a></span></p>
-
-<div class="figcenter" style="width: 500px;" id="fig55">
-
-<img src="images/fig55.jpg" width="500" height="525" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 55a.</span> <span class="smcap">Fig. 55b.</span></p>
-
-<p class="caption">Dust-filter of Beth-Lübeck (<i>after Albrecht</i>)</p>
-
-</div>
-
-<div class="figcenter" style="width: 500px;" id="fig56">
-
-<img src="images/fig56.jpg" width="500" height="250" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 56.</span>—Dust-filter of Beth-Lübeck—Detail</p>
-
-</div>
-
-<p><span class="pagenum"><a name="Page_255" id="Page_255">[255]</a></span></p>
-
-<p>Collection of dust may take place in settling chambers as
-in a cyclone separator in which the air to be purified is made
-to travel round the interior of a cone-shaped metal receptacle,
-depositing the dust in its passage (<a href="#fig54">see fig. 54</a>).</p>
-
-<div class="figcenter" style="width: 400px;" id="fig57">
-
-<img src="images/fig57.jpg" width="400" height="450" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 57.</span>—Arrangement for Precipitating Dust (<i>after Leymann</i>)</p>
-
-<p class="caption"><i>A</i> Entry of dust laden air; <i>B</i> Fan; <i>C</i> Purified air; <i>D</i> Pipe carrying
-away water and last traces of dust; <i>E</i> Worm carrying away collection of dust.</p>
-
-</div>
-
-<p>The most effective method, however, is filtration of the
-air through bags of canvas or other suitable fabric as in the
-‘Beth’ filter (see figs. <a href="#fig55">55</a> and <a href="#fig56">56</a>). In the ‘Beth’ filter a
-mechanical knocking apparatus shakes the dust from the
-bag to the bottom of the casing, where a worm automatically
-carries it to the collecting receptacle. In the absence of
-mechanical knocking the filtering material becomes clogged
-and increases the resistance in the system. Contrivances of
-the kind unintelligently constructed become a source of
-danger to the workers. Dust of no value is usually precipitated
-by being made to pass through a tower down which
-a fine spray of water falls. If the gases and fumes can be
-utilised they are either absorbed or condensed—a procedure
-of the utmost importance for the protection of the workers.</p>
-
-<p>Condensation of the gases into a liquid is effected by
-cooling and is an essential part of all processes associated
-with distillation. The necessary cooling is effected either
-by causing the vapours to circulate through coils of pipes<span class="pagenum"><a name="Page_256" id="Page_256">[256]</a></span>
-surrounded by cold water or by an increase in the condensing
-surface (extension of walls, &amp;c.), and artificial cooling of the
-walls by running water.</p>
-
-<p>Absorption of gases and fumes by fluids (less often by
-solid substances) is effected by bubbling the gas through
-vessels filled with the absorbing liquid or conducting it through
-towers (packed with coke, flints, &amp;c.), or chambers down or
-through which the absorbent flows. Such absorption towers
-and chambers are frequently placed in series.</p>
-
-<p>The material thus recovered by condensation and absorption
-may prove to be a valuable bye-product. Frequently the
-gases (as in blast furnace gas, coke ovens, &amp;c.) are led away
-directly for heating boilers, or, as in the spelter manufacture,
-to make sulphuric acid.</p>
-
-<h3 id="PARTICULAR_INDUSTRIES">V<br />
-<span class="smaller"><i>PREVENTIVE REGULATIONS FOR CHEMICAL INDUSTRIES</i></span></h3>
-
-<h4>Sulphuric Acid Industry</h4>
-
-<p class="center">(See also pp. <a href="#Page_4">4-14</a> and <a href="#Page_171">171</a>)</p>
-
-<p>Danger arises from escape of acid gases or in entering
-chambers, towers, containers, &amp;c., for cleaning purposes.
-The whole chamber system, therefore, requires to be impervious
-and the sulphur dioxide and nitrous gases utilised to
-their fullest extent—a procedure that is in harmony with
-economy in production. The pyrites furnace must be so
-fired as to prevent escape of fumes, which is best attained by
-maintenance of a slight negative pressure by means of fans.
-The cinders raked out of the furnace because of the considerable
-amount of sulphur dioxide given off from them should
-be kept in a covered-in place until they have cooled. Any
-work on the towers and lead chambers, especially cleaning
-operations, should be carried out under strict regulations. Such
-special measures for the emptying of Gay-Lussac towers have
-been drawn up by the Union of Chemical Industry. Before
-removal of the sediment on the floor they require a thorough<span class="pagenum"><a name="Page_257" id="Page_257">[257]</a></span>
-drenching with water, to be repeated if gases are present.
-Perfect working of the Gay-Lussac tower at the end of the
-series of chambers is essential to prevent escape of acid gases.
-In a well-regulated sulphuric acid factory the average total
-acid content of the final gases can be reduced to 0·1 vol. per
-cent. Under the Alkali Works Regulation Act of 1881 the
-quantity was limited to 0·26 per cent. of sulphur dioxide—and
-this should be a maximum limit.</p>
-
-<p><i>Entering and cleaning out chambers and towers</i> should only
-be done, if practicable, by workmen equipped with breathing
-apparatus, and never without special precautionary measures,
-as several fatalities have occurred at the work. Towers,
-therefore, are best arranged so as to allow of cleaning from the
-outside; if gases are noticed smoke helmets should be donned.
-The same holds good for entering tanks or tank waggons.
-After several cases of poisoning from this source had occurred
-in a factory the following official regulations were issued:</p>
-
-<div class="blockquote">
-
-<p>The deposit on the floor of waggons or tanks shall be
-removed either by flushing with water without entering the
-tank itself, or if the tank be entered the deposit is to be
-scooped out without addition of water or dilute soda solution.</p>
-
-<p>Flushing out shall only be done after the workmen have
-got out.</p>
-
-<p>Workmen are to be warned every time cleaning is undertaken
-that poisonous gases are developed when the deposit
-on the floor is diluted.</p>
-
-<p>Acid eggs, further, are to be provided with a waste pipe
-and manhole to enable cleaning to be done from outside.</p>
-
-</div>
-
-<p>The poisoning likely to arise is partly due to arsenic impurity
-(development of arseniuretted hydrogen gas) in the sulphuric
-acid used. Unfortunately arsenic free acid is very difficult to
-obtain.</p>
-
-<h4>Hydrochloric Acid—Saltcake and Soda Industries</h4>
-
-<p class="center">(See also pp. <a href="#Page_15">15-23</a> and <a href="#Page_170">170</a>)</p>
-
-<p>Preventive measures here depend upon observance of
-the general principles already discussed.</p>
-
-<p>The <i>saltcake pan</i> and reverberatory furnace require to be
-accurately and solidly constructed and the process carefully<span class="pagenum"><a name="Page_258" id="Page_258">[258]</a></span>
-regulated. Regulations indeed were drawn up at an early
-date in England as to their working to prevent escape of
-gases when adding the acid, raking over in the reverberatory
-furnace, and withdrawal of the still fuming saltcake.</p>
-
-<p>The following are the most important of these recommendations:</p>
-
-<div class="blockquote">
-
-<p>The saltcake pan must not be charged when overheated.</p>
-
-<p>Sulphuric acid shall be added only after all the salt has
-been charged and the door shut.</p>
-
-<p>If hydrochloric acid fumes escape at the door when the
-Glover acid flows in the flow must be interrupted.</p>
-
-<p>All doors must be closed while work is in progress.</p>
-
-<p>Definite times shall be fixed for withdrawal of the saltcake
-in order to try and ensure that it be not still fuming, but
-should this be the case cold sulphate of soda shall be
-sprinkled over it.</p>
-
-</div>
-
-<p>The general principle should be observed of maintaining
-a slight negative pressure in the furnace by insertion of a fan
-in the gas conduit so as to avoid possible escape of gas. The
-fuming saltcake is best dealt with by depositing it at once to
-cool in ventilated receptacles or chambers.</p>
-
-<p>On grounds of economy and hygiene as complete an
-absorption as possible of the hydrochloric acid gas developed
-in the saltcake and soda ash process is to be aimed at,
-by conveying it through impervious conduits to the
-bombonnes and lofty absorption tower filled with coke or
-flints down which water trickles. The entire loss of hydrochloric
-acid should not amount to more than 1·5 per cent. of
-the whole. Under the Alkali Act at first 5 per cent. was
-allowed, but this is excessive now in view of improved methods
-of condensation.</p>
-
-<p>In the <i>Leblanc</i> process the revolving furnace is on health
-grounds to be preferred to the hand furnace. Such a furnace
-occupies the space of but three hand furnaces and can
-replace eighteen of them. The vast accumulation of waste,
-consisting mainly of calcium sulphide, and generating sulphuretted
-hydrogen gas in such amount as to constitute a
-nuisance, is only partially prevented by the Chance-Claus
-and other methods of recovery, and makes it most desirable
-to adopt the Solvay ammonia process.</p>
-
-<p><span class="pagenum"><a name="Page_259" id="Page_259">[259]</a></span></p>
-
-<p><i>Note.</i>—<i>Sulphonal, Oxalic acid, Ultramarine, Alum.</i>—The
-production of <i>sulphonal</i> is intensely unpleasant owing to the
-disagreeable smell (like cats’ excrement) of the mercaptan
-developed. All work therefore must be carried on in air-tight
-apparatus under negative pressure and careful cooling. Any
-escaping fumes must be absorbed in solution of acetone and
-fine water spray.</p>
-
-<p>Preparation of <i>oxalic acid</i> unless carried on in closed-in
-vessels gives rise to injurious and troublesome fumes. If
-open pans are used, hoods and ducts in connection with a fan
-should be placed over them.</p>
-
-<p>Grinding of <i>ultramarine</i> and <i>alum</i> requires to be done in
-closed-in mills, and any dust drawn away by locally applied
-ventilation and filtered. The gases given off in the burning
-process contain 3 per cent. of sulphur dioxide, which requires
-to be absorbed—a procedure most easily effected in towers
-where the upstreaming gas comes into contact with a dilute
-solution of lime or soda.</p>
-
-<h4>Chlorine, Bleaching Powder, Chlorine Compounds</h4>
-
-<p class="center">(See also pp. <a href="#Page_23">23-9</a> and <a href="#Page_173">173</a>)</p>
-
-<p>What has been said as to imperviousness of apparatus,
-negative pressure maintained by the tall chimney stack or
-earthenware or fireclay fan, &amp;c., applies equally here. The
-exhaust ventilation is also required to aspirate the gas into
-the bleaching chambers.</p>
-
-<p>At the end of the system there must be either a tower
-packed with quicklime to absorb the last traces of chlorine or
-such a number of bleach chambers into which the gas can
-be led that no chlorine escapes. Production of chlorine gas
-electrolytically is to be preferred to other processes on hygienic
-grounds.</p>
-
-<p>Careful cleanliness is the best prophylactic against occurrence
-of <i>chlorine rash</i> among persons employed in the electrolytic
-production of chlorine. In some factories attempt has
-been made to use other substances (magnetite) instead of
-carbon for the anode, and the success attending their adoption
-is further proof that the tar cement at the anode helped to
-cause the acne.</p>
-
-<p><span class="pagenum"><a name="Page_260" id="Page_260">[260]</a></span></p>
-
-<p>In the <i>Weldon</i> process care must be taken that the water
-lutes are intact, and the stills must not be opened before
-the chlorine has been drawn off. All processes in which
-manganese dust can arise (grinding of manganese dioxide
-and drying of Weldon deposit) should be done under locally
-applied exhaust. The <i>bleaching powder</i> chambers must be
-impervious and care taken that they are not entered before
-the chlorine has been absorbed. Usually the number of lime
-chambers connected up with each other is such that no chlorine
-escapes free into the air. Emptying of the finished product
-should not be done by hand, as considerable quantities of
-chlorine escape and make the work extremely irksome.
-Mechanical methods of emptying should be adopted in substitution
-for hand labour, and of these the Hasenclever closed-in
-apparatus is the best.</p>
-
-<h4>Nitric Acid and Explosives</h4>
-
-<p class="center">(See also pp. <a href="#Page_39">39-49</a> and <a href="#Page_172">172</a>)</p>
-
-<p>In the production of <i>nitric acid</i> complete imperviousness of
-the system and as complete condensation of the gases as
-possible by means of tourilles, cooling condensers, and the
-requisite number of towers are necessary. The method
-suggested by Valentine of manufacture of nitric acid in
-apparatus under a partial vacuum has advantages from a
-hygienic standpoint. Earthenware fans are used to force
-the nitric acid gases onwards and have the advantage of
-creating a negative pressure. Great care is needed in
-handling, emptying, packing, conveying, and storing the
-acid in consequence of the danger from breaking or spilling.
-The bottles used must be in perfect condition and must be well
-packed. No greater stock of nitric acid should be allowed
-in a room than is absolutely necessary, and care must be
-exercised in the event of a carboy breaking that the spilt acid
-does not come into contact with organic substances, as that
-would increase development of nitrous fumes.</p>
-
-<p>Workers must be warned not to remain in rooms in which
-acid has been spilt. They are only to be entered by workers
-equipped with breathing apparatus (smoke helmets).</p>
-
-<p><span class="pagenum"><a name="Page_261" id="Page_261">[261]</a></span></p>
-
-<p>Among the special regulations on the subject may be
-mentioned those of the Prussian Ministerial Decree, dated
-January 8, 1900, concerning nitrous fumes and means of
-protection for workers employed with the acid. What has
-been said on p. <a href="#Page_257">257</a> in regard to the transport of sulphuric
-acid applies equally to nitric acid.</p>
-
-<p>In the <i>nitrating</i> process in the manufacture of explosives
-(see p. <a href="#Page_47">47</a>) it is essential that the apparatus is hermetically
-closed, that agitation is done mechanically, or better still
-by means of compressed air, and that any fumes developed
-are exhausted and condensed. In the preparation of <i>nitro-glycerin</i>
-(see p. <a href="#Page_46">46</a>) the gases developed in the nitration of
-the waste acid require to be carefully condensed. Contact
-of nitro-glycerin with the skin has to be avoided and the
-attention of the workers drawn to the danger. Preparation
-of <i>gun cotton</i> (see p. <a href="#Page_48">48</a>) takes place in machines which are
-at the same time nitrating and centrifugalising machines.
-The apparatus is first filled with the nitrating acid and the
-cotton added; the fumes are drawn off by earthenware
-ducts and fans, and lastly the bulk of the acid is removed by
-centrifugal action. Such machines carry out effectually the
-principles of industrial hygiene.</p>
-
-<p>In the preparation of <i>fulminate of mercury</i> nitrous fumes,
-cyanogen compounds, and acetic acid compounds are developed
-by the action of the nitric acid on mercury, and require to
-be dealt with by exhaust ventilation.<a name="FNanchor_7" id="FNanchor_7"></a><a href="#Footnote_7" class="fnanchor">[G]</a></p>
-
-<h4>Artificial Manures, Fertilizers</h4>
-
-<p class="center">(See also pp. <a href="#Page_53">53</a> and <a href="#Page_54">54</a>)</p>
-
-<p>In grinding phosphorite and superphosphates, corrosive
-dust is produced. All grinding operations must, therefore, be
-carried out automatically in closed apparatus (ball mills,
-disintegrators, &amp;c.). In making the phosphorite soluble by
-treatment with sulphuric acid, and subsequent drying of the
-product, corrosive hydrofluoric acid gas is developed, which
-requires to be carried away by an acid proof exhaust fan, and<span class="pagenum"><a name="Page_262" id="Page_262">[262]</a></span>
-condensed in a tower by water (<a href="#fig58">see fig. 58</a>). The modern
-revolving drying machines are especially serviceable.</p>
-
-<div class="figcenter" style="width: 500px;" id="fig58">
-
-<img src="images/fig58.jpg" width="500" height="550" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 58.</span>—Washing tower for hydrofluoric acid (<i>after Leymann</i>.)</p>
-
-</div>
-
-<p>In the production of <i>basic slag</i> corrosive dust is given off,
-causing ulceration of the mucous membrane. Grinding and
-other manipulations creating dust must be carried on in
-apparatus under local exhaust ventilation. The following—somewhat
-shortened—are the German Imperial Regulations,
-dated July 3, 1909, for basic slag factories.</p>
-
-<div class="blockquote">
-
-<p class="center"><span class="smcap">Basic Slag Regulations</span></p>
-
-<p>1. Workrooms in which basic slag is crushed, ground, or
-stored (if not in closed sacks) shall be roomy and so arranged
-as to ensure adequate change of air. Floors shall be of impervious
-material allowing of easy removal of dust.</p>
-
-<p>2. Preliminary breaking of the slag by hand shall not be<span class="pagenum"><a name="Page_263" id="Page_263">[263]</a></span>
-done in the grinding rooms, but either in the open air or in open
-sheds.</p>
-
-<p>3. Slag crushers, grinding mills, and other apparatus shall
-be so arranged as to prevent escape of dust as far as possible
-into the workrooms. They shall be provided with exhaust
-ventilation and means for collecting the dust if this cannot be
-done in the absence of dust.</p>
-
-<p>4. Arrangements shall be made whereby barrows conveying
-material to the grinding mills shall be emptied directly into
-partially hooded hoppers provided with exhaust ventilation so as
-to prevent escape of dust into the workrooms.</p>
-
-<p>5. The casing and joints of the grinding mills, ducts, dust
-collectors and sieves shall be airtight; if leaks are noticed they
-must be repaired forthwith.</p>
-
-<p>6. Ducts, dust collectors and sieves shall be so arranged as
-to enable periodical cleansing to be undertaken from the outside.</p>
-
-<p>7. Repairs of the plant mentioned in Para. 5 in which workers
-are exposed to inhalation of slag dust shall be entrusted by the
-occupier only to such workers as wear respirators supplied for
-the purpose or other means of protecting mouth and nostrils
-such as wet sponges, handkerchiefs, &amp;c.</p>
-
-<p>8. Emptying of slag powder from the grinding mills and
-dust collectors and transference to the store rooms shall only
-be done in accordance with special regulations designed to
-minimise dust.</p>
-
-<p>9. Filling slag powder into sacks from the outlets of the
-mills, elevating and discharging it into receptacles shall only
-be done under efficient exhaust ventilation.</p>
-
-<p>10. Sacks in which the powder is transported and piled in
-heaps shall be of a certain defined strength to be increased in
-the case of sacks to be piled in heaps more than 3½ metres in
-height. Special rooms separated from other workrooms shall be
-provided for storage of slag powder in sacks. Only the sacks
-representing the previous day’s production may be stored in the
-grinding rooms.</p>
-
-<p>Basic slag in powder and not in sacks shall be kept in
-special storage rooms shut off entirely from other workrooms.
-No person shall enter such storage rooms when they are
-being filled or emptied. Discharging the contents of the sacks
-into them shall be done under exhaust ventilation.</p>
-
-<p>11. The floors of the workrooms described in Para. 1
-shall be cleaned before the commencement of each shift or
-in an interval during each shift. No person except those
-engaged in cleaning shall be present during the operation. If<span class="pagenum"><a name="Page_264" id="Page_264">[264]</a></span>
-cleaning is effected by sweeping, the occupier shall require the
-persons doing it to wear the respirators provided or other
-protection for the mouth and nose.</p>
-
-<p>12. The occupier shall not permit the workers to bring
-spirits into the factory.</p>
-
-<p>13. A lavatory and cloakroom and, separated from them
-and in a part of the building free from dust, a meal room shall
-be provided. These rooms shall be kept clean, free from dust,
-and be heated during the winter.</p>
-
-<p>In the lavatory and cloakroom water, soap, and towels shall
-be provided and adequate arrangements shall be made for keeping
-the clothing taken off before commencing work.</p>
-
-<p>The occupier shall give the persons employed opportunity
-to take a warm bath daily before leaving work in a bathroom
-erected inside the factory and heated during the winter.</p>
-
-<p>14. No woman or male young person under eighteen years
-of age shall work or remain in a room into which basic slag is
-brought.</p>
-
-<p>Persons under eighteen years of age shall not be employed in
-beating sacks which have contained basic slag.</p>
-
-<p>15. No person employed in breaking or grinding, emptying,
-packing, or storing basic slag, shall work more than ten hours
-daily.</p>
-
-<p>There shall be intervals during working hours amounting
-in the aggregate to two hours, one of them lasting at least an
-hour. If duration of employment daily is limited to seven
-hours with never longer than four hours’ work without an
-interval, only one interval of at least one hour is required.</p>
-
-<p>16. For work mentioned in Para. 15 no person shall
-be employed without a certificate from an approved surgeon
-stating that he is free of disease of the lungs and not alcoholic.
-The occupier shall place the supervision of the health of the
-workers under a surgeon who shall examine them at least once
-a month for signs of disease of the respiratory organs and
-alcoholism. Workers engaged in the operations mentioned in
-Para. 15 shall be suspended from employment when the
-surgeon suspects such illness or alcoholism. Those showing
-marked susceptibility to the effect of basic slag dust shall be
-permanently suspended.</p>
-
-<p>17. A health Register shall be kept in which shall be entered
-the precise employment, duration of work, and state of health
-of the persons employed.</p>
-
-<p>18. The occupier shall obtain a guarantee from the workers
-that no alcohol or food shall be taken into the workrooms.</p>
-
-</div>
-
-<p><span class="pagenum"><a name="Page_265" id="Page_265">[265]</a></span></p>
-
-<h4>Preparation of Hydrofluoric Acid</h4>
-
-<p class="center">(See also pp. <a href="#Page_37">37</a> and <a href="#Page_171">171</a>)</p>
-
-<p>The fumes given off in the preparation of hydrofluoric acid
-require to be collected in leaden coolers and vessels; that
-which escapes requires to be absorbed by a water spray in
-towers. The apparatus must be impervious and kept under a
-slight negative pressure.</p>
-
-<h4>Chromium Compounds</h4>
-
-<p class="center">(See also pp. <a href="#Page_55">55-8</a> and <a href="#Page_185">185</a>)</p>
-
-<p>The German Imperial Decree, dated May 16, 1907, contains
-the preventive measures necessary in bichromate factories.
-According to this, workers suffering from ulceration of the
-skin (chrome holes, eczema) are not to be employed except
-on a medical certificate that they are free from such affections,
-and daily examination for signs of ulceration is enjoined, so
-that those affected may receive prompt treatment. Further,
-periodical medical examination of the workers is required at
-monthly intervals. Respirators (for work in which dust cannot
-be avoided), with lavatory, cloakroom, and meal room accommodation,
-are to be provided, and also baths. In handling
-bichromates wearing of impervious gloves may be necessary,
-and smearing the hands and face with vaseline is recommended.
-In addition diffusion of dust and fumes must be minimised;
-machines in which mixing, crushing, and grinding are done
-must be impervious, and provided with exhaust ventilation.
-Charging of the furnaces, where possible, should be effected
-mechanically and the fumes developed both in manipulation
-of the furnaces and from hot bichromate liquor removed by
-an exhaust.</p>
-
-<p>A leaflet containing directions for workers coming into
-contact with chromium compounds in chemical factories,
-dyeing, tanning, wood staining, calico printing, wall paper
-printing, painting, &amp;c., has been drawn up by Lewin. It
-contains a list of the poisonous chrome compounds and of the
-industries in which chrome poisoning occurs, information as to
-the action of chrome upon the skin and mucous membrane, and
-the preventive measures necessary. Among the last named are:<span class="pagenum"><a name="Page_266" id="Page_266">[266]</a></span>
-smearing the skin with oil, use of impervious gloves, respirators
-in work where dust arises, necessity of cleanliness, and periodical
-medical examination.</p>
-
-<p>For the <i>chrome tanning industry</i> the following leaflet was
-drawn up by the Imperial Health Office in Berlin, which
-succinctly states the measures against chrome poisoning in
-these industries and contains much practical information
-for the workers:</p>
-
-<div class="blockquote">
-
-<p>In chrome tanning by the two bath process, the first bath
-containing potassium bichromate and hydrochloric acid has a
-corroding effect upon broken surfaces of the skin (scratches,
-chapped hands, eruptions, &amp;c.). In consequence, they develop
-into round ulcers (chrome holes) with hard raised edges which
-are difficult to heal and go on increasing in size unless work at
-the process is temporarily given up. In persons with very
-sensitive skin, even though the surface may be intact, handling
-the liquor brings on sometimes an obstinate rash (eczema) on
-the hands and forearms.</p>
-
-<p>The solution used in the one bath process has no corrosive
-action, but it is a strong poison, just as is the solution of
-potassium bichromate of the two bath process. If swallowed,
-the solutions cause vomiting, diarrhœa, kidney trouble, and
-even death. Chromium compounds can also enter the body
-through skin wounds and cause illness.</p>
-
-<p><i>Prevention.</i>—In order to prevent the occurrence of chrome
-ulceration, workers employed with chrome or chrome solutions
-must be especially careful in avoiding injury to the skin of the
-hands or forearms. This applies especially to workers who
-carry the vessels containing bichromate, who weigh and dissolve
-the potassium bichromate, or who come into contact with the
-tanning liquor or with undressed skins and hides which have
-lain in the liquor.</p>
-
-<p>If, in spite of precautions, eruptions, rashes, or ulceration
-occur, all work necessitating contact with corrosive tanning
-liquors should be suspended until they are healed.</p>
-
-<p>In order to reduce risk of action of the liquor on the skin,
-workers employed in the process described would do well if,
-before commencing work, they carefully smeared hands and
-forearms with unsalted lard, vaseline, or the like, and during
-work avoided, as much as possible, soiling the bare hands and
-arms with the liquor.</p>
-
-<p>If, nevertheless, a worker has contracted a chrome hole, or<span class="pagenum"><a name="Page_267" id="Page_267">[267]</a></span>
-eruption, he should consult a medical man, informing him at
-the same time of the nature of his work.</p>
-
-<p>To avoid internal absorption of chrome, workers preparing
-the baths must carefully avoid inhaling the dust of chromium
-salts. These and all other workers engaged with the liquors containing
-chromium must not take food and drink while at work.
-Working suits should be taken off and face and hands washed
-with soap before eating or drinking, and before leaving the
-factory.</p>
-
-</div>
-
-<h4>Petroleum, Benzine</h4>
-
-<p class="center">(See also pp. <a href="#Page_59">59-64</a> and <a href="#Page_222">222-4</a>)</p>
-
-<p>As crude petroleum and the higher fractions first distilled
-from it affect the skin injuriously, wetting the skin should be
-avoided, and careful cleanliness on the part of the workers
-enjoined. Workers exposed to the influence of gases escaping
-from naphtha springs and wells should be equipped with
-breathing apparatus (smoke helmets); this applies to those
-who have to enter stills and other apparatus connected with
-the distillation of petroleum.</p>
-
-<p>In the preparation of petroleum by sulphuric acid
-sulphur dioxide in great quantity is developed, constituting
-a distinct danger to the workers. This process, therefore,
-should be carried on in closed vessels furnished with mechanical
-stirrers or compressed air agitators. The most suitable
-apparatus is that illustrated in <a href="#fig13">fig. 13</a>.</p>
-
-<p>Petroleum tanks must be thoroughly aired before they are
-cleaned and should be entered only by workers equipped with
-breathing apparatus. Apparatus containing petroleum and
-benzine requires, as far as possible, to be closed in and air tight
-(as, for example, in the extraction of fat from bones and oil
-seed, in the rubber industry, and in chemical cleaning establishments);
-where benzine fumes develop they should be immediately
-drawn away by suitably applied exhaust ventilation.
-This is necessary, on account of the danger of fire, in chemical
-cleaning establishments where purification is effected by means
-of benzine in closed drums.</p>
-
-<p>Regulations for benzine extraction plants are contained in
-the Prussian Ministerial Decree, dated January 5, 1909, for
-benzine extraction works, and also in that of August 3, 1903,
-for dry-cleaning premises, to which last were added ‘Directions<span class="pagenum"><a name="Page_268" id="Page_268">[268]</a></span>
-for safety,’ containing important regulations as to risk from
-fire. From our standpoint the following points are of interest:
-care is to be taken to provide and maintain exhaust ventilation
-directly across the floor. The air, however, must not be
-allowed to pass near any fire. Drying rooms especially are to
-be lofty and airy, and separated from other workrooms. In
-factories with mechanical power the authorities may require
-provision of artificial ventilation for the drying rooms. Washing
-machines, centrifugalising machines, and benzine rinsing
-vessels should be furnished with well-fitting covers to be
-removed only for such time as is absolutely necessary for
-putting in and taking out the articles to be cleaned, shaken, or
-rinsed. The vessels named are to be examined as to their
-imperviousness at least once every quarter by a properly
-qualified person. The condition in which they are found is
-to be noted in a book to be shown to the Factory Inspector
-and police authorities on demand.</p>
-
-<p>Lastly, substitution for benzine of other less poisonous
-substances such as carbon tetrachloride has been urged.</p>
-
-<h4>Phosphorus, Lucifer Matches</h4>
-
-<p class="center">(See also pp. <a href="#Page_49">49-53</a> and <a href="#Page_190">190</a>)</p>
-
-<p>In view of the danger of the lucifer match industry,
-measures were taken at an early date in almost all civilised
-states to guard against phosphorus poisoning, and in many
-countries have led to the prohibition of the use of white
-phosphorus. Complete prohibition of its manufacture and use
-was first enacted in Finland (1872) and in Denmark (1874).
-Prohibition was decreed in Switzerland in 1879 (in January
-1882 this was revoked, but again enacted in 1893), and in the
-Netherlands in 1901. In Germany the law prohibiting the use
-of white phosphorus came into force in January 1908, and
-runs as follows:</p>
-
-<div class="blockquote">
-
-<p>1. White or yellow phosphorus shall not be employed in the
-production of matches and other lighting substances. Lighting
-substances made with white phosphorus shall not be kept for
-sale, or sold, or otherwise brought on the market. Provided
-that this shall not apply to ignition strips which serve for the
-lighting of safety lamps.</p>
-
-<p><span class="pagenum"><a name="Page_269" id="Page_269">[269]</a></span></p>
-
-<p>2. Persons wilfully infringing this law shall be punished by
-a fine of 2000 marks. If the infringement occurs through
-ignorance the fine shall consist of 150 marks.</p>
-
-<p>In addition to the fine, all prohibited articles produced,
-imported, or brought into the trade shall be confiscated, as well
-as the implements used in their production, without reference
-to whether they belong to the person convicted or not. If
-prosecution or conviction of the guilty party cannot be brought
-home, confiscation nevertheless is to be carried out independently.</p>
-
-</div>
-
-<p>Roumania and France have a state monopoly of matches;
-in these states no white phosphorus matches have been produced
-since 1900 and 1898 respectively. France, by the Law
-of December 17, 1908, signified concurrence with the International
-Convention in regard to the prohibition of the use of
-white phosphorus.</p>
-
-<p>In Sweden and Norway the prohibition of white phosphorus
-is in force only for the home trade. A Swedish Decree, dated
-December 9, 1896, permitted factories carrying on the manufacture
-for export to use white phosphorus, and almost precisely
-similar provisions are contained in the Norwegian Decree.
-The Swedish Decree, dated March 30, 1900, permits white
-phosphorus matches to be exported, but not to be sold in the
-country. In Austria difficulties in regard to prohibition of
-white phosphorus arose owing to trade conditions (especially in
-the East), and the attitude of the states competing in the lucifer
-match trade, particularly Italy and Japan. Austria, therefore,
-made agreement with international prohibition of white phosphorus,
-dependent on the attitude of Japan; since Japan did
-not concur, the decision of Austria fell through. When, however,
-Italy in the year 1906 joined the Convention, the difficulties
-were also overcome in Austria, and by a law similar to
-that of Germany, dated July 13, 1909, prohibition of the
-manufacture and sale of white phosphorus matches dates
-from the year 1912.<a name="FNanchor_8" id="FNanchor_8"></a><a href="#Footnote_8" class="fnanchor">[H]</a></p>
-
-<p>Belgium has refrained from prohibition of white phosphorus,
-but on the other hand has passed a series of enactments relating
-to the match manufacture, of which the most essential are<span class="pagenum"><a name="Page_270" id="Page_270">[270]</a></span>
-here cited, since they characterise the measures which come
-into consideration for factories in which white phosphorus is
-still employed.</p>
-
-<div class="blockquote">
-
-<p class="center"><i>Royal Decree, dated March 25, 1890, modified by the Royal
-Decree, dated February 12, 1895, and November 17, 1902,
-concerning employment in lucifer match factories.</i></p>
-
-<p>1. In match factories where white phosphorus is used,
-mixing the paste and drying the dipped matches shall be carried
-on in a place specially set apart for the purpose.</p>
-
-<p>2. Mixing the paste shall be carried on in an entirely closed
-vessel or in one connected with an efficient exhaust draught
-locally applied.</p>
-
-<p>The proportion of white phosphorus in the paste shall not
-exceed in weight 8 per cent. of the total material, not including
-water.</p>
-
-<p>3. Hoods and ducts communicating with an exhaust
-draught shall be installed at the level of the plates for dipping
-white phosphorus matches, and over the vessels containing
-the paste.</p>
-
-<p>4. Drying rooms for white phosphorus matches, if entered
-by the workers, shall be mechanically ventilated.</p>
-
-<p>5. Rooms in which phosphorus fumes can arise shall be
-lofty and well ventilated, preferably by an exhaust at the
-level of the work benches, communicating with the main
-chimney stack.</p>
-
-<p>The workrooms shall be kept clean. No food or drink
-shall be taken in them.</p>
-
-<p>6. In every match factory the workers shall have at their
-disposal a special cloak room and suitable and sufficient washing
-accommodation, so as to be able to change clothes before
-commencing, and at the end of, work, and to wash the hands
-and face on leaving.</p>
-
-<p>Cleanliness will be obligatory upon the workers manipulating
-phosphorus paste or matches.</p>
-
-<p>7. Workers coming into contact with phosphorus paste or
-matches shall be examined monthly by a surgeon appointed
-by the Minister of Industry, who shall be paid by the occupier.</p>
-
-<p>Workers having decayed, unstopped teeth, or exhibiting
-symptoms of gingivitis or stomatitis, or in poor health at the
-time of examination, shall be temporarily suspended from work.</p>
-
-<p>The surgeon shall enter the results of his monthly examinations
-in a prescribed register.</p>
-
-<p><span class="pagenum"><a name="Page_271" id="Page_271">[271]</a></span></p>
-
-<p>This register shall be shown to the Factory Inspector on
-demand.</p>
-
-</div>
-
-<p>These decrees are supplemented by further orders regarding
-the taking of samples of paste in match factories and store
-houses (Royal Orders of March 25, 1890; February 12, 1895;
-April 18, 1898; November 17, 1902).</p>
-
-<p>As is evident from the Belgian enactment, in states where
-prohibition of white phosphorus is not in force, palliative
-measures only are possible and even then they can only be
-enforced in large factories when automatic machinery is used
-to eliminate hand labour in dangerous operations. In this
-respect the introduction of closed, ventilated, mechanical
-mixing apparatus provided with mechanical stirrers, closed
-and ventilated mechanical dipping and drying apparatus, are
-especially important. Certain modern American machines
-carry through the whole complicated process of the phosphorous
-match industry automatically. Seeing that prohibition of
-white phosphorus is an accomplished fact and that matches
-free from risk in their manufacture answer every purpose,
-the universal enforcement of the prohibition of white
-phosphorus should be striven for in civilised states.</p>
-
-<h4>Carbon bisulphide</h4>
-
-<p class="center">(See also pp. <a href="#Page_68">68-71</a> and <a href="#Page_193">193-5</a>)</p>
-
-<p>Use of carbon bisulphide in the vulcanising of indiarubber
-goods by dipping them into the liquid and subsequently
-drying them (usually in a current of hot air) causes
-development of carbon bisulphide fumes in considerable
-quantity, especially if the articles to be dried are laid on
-shelves or hung up in the workroom, a procedure which should
-never be permitted. Drying must be carried out under local
-exhaust ventilation.</p>
-
-<p>All vessels holding carbon bisulphide used for dipping can
-be placed in a wooden channel above the dipping vessels, provided
-with openings for manipulation, and connected with an
-exhaust system.</p>
-
-<p>The following are the German Imperial Regulations, dated
-March 1, 1902, for vulcanising of indiarubber by means of
-carbon bisulphide:</p>
-
-<p><span class="pagenum"><a name="Page_272" id="Page_272">[272]</a></span></p>
-
-<div class="blockquote">
-
-<p class="center"><span class="smcap">Vulcanising by Means of Carbon Bisulphide</span></p>
-
-<p>(Notice concerning the erection and management of industrial
-premises in which indiarubber goods are vulcanised by means
-of carbon bisulphide or chloride of sulphur.)</p>
-
-<p>The following regulations shall apply in accordance with
-paragraph 120 (<i>e</i>) of the Industrial Code:</p>
-
-<p>1. The floor of such rooms as are used for the vulcanising
-of indiarubber goods by means of carbon bisulphide shall not
-be lower than the surrounding ground. The rooms shall have
-windows opening into the outer air, and the lower halves shall be
-capable of being opened so as to render possible sufficient renewal
-of air.</p>
-
-<p>The rooms shall be ventilated by fans mechanically driven.
-With the approval of the higher authorities permission to
-dispense with mechanical draught may be allowed, provided
-that in other ways powerful change of air is secured. With the
-approval of the higher authorities special ventilating arrangements
-can be dispensed with if the fumes of carbon bisulphide
-are removed immediately, at the point where they are produced,
-by means of a powerful draught, and in this way purity of the
-air be secured.</p>
-
-<p>2. The vulcanising rooms shall not be used as a dwelling, or
-for sleeping in, or for preparing food in, or as a store, or drying
-room, nor shall other processes than those of vulcanising be
-carried on in them. No persons, except those engaged in vulcanising
-processes, shall be allowed in the rooms.</p>
-
-<p>There shall be at least 20 cubic meters (700 cubic feet) of air
-space allowed for each person employed therein.</p>
-
-<p>3. Only such quantities of carbon bisulphide shall be brought
-into the vulcanising rooms as shall serve for the day’s supply.
-Further storage shall be made in a special place separate from
-the workrooms. Vessels to hold the vulcanising liquid shall be
-strongly made, and when filled and not in use shall be well
-covered.</p>
-
-<p>4. Vulcanising and drying rooms shall be warmed only by
-steam or hot-water pipes.</p>
-
-<p>These rooms shall be lighted only by means of strong
-incandescent electric lamps.</p>
-
-<p>Exceptions from paragraphs 1 and 2 may be allowed by
-the higher authorities.</p>
-
-<p>5. Machines intended for vulcanising long sheets of cloth
-shall be covered over (<i>e.g.</i>, with a glass casing) so as to prevent
-as far as possible the entrance of carbon bisulphide fumes into
-the workrooms, and from the casing the air shall be drawn<span class="pagenum"><a name="Page_273" id="Page_273">[273]</a></span>
-away effectually by means of a fan mechanically driven.
-Entrance to the space which is enclosed shall only be allowed
-in case of defects in the working.</p>
-
-<p>In cases where a covering of the machine is not practicable
-for technical reasons the higher authorities can, if suitable means
-of protection are used (especially when the machine is placed
-in an open hall, and provided that no person works at the
-machine for more than two days a week), allow of exception
-to the above arrangement.</p>
-
-<p>6. Vulcanising of other articles (not mentioned in par. 5),
-unless carried out in the open air, shall be done in covered-in
-boxes into which the worker need only introduce his hands, and
-so arranged as to keep the fumes away from the face of the
-worker.</p>
-
-<p>The air must be drawn away from the box by means of a
-powerful draught.</p>
-
-<p>7. Rule 6 shall apply in vulcanising both the outside and
-inside of indiarubber goods. In vulcanising the inside no
-worker shall be allowed to suck the fluid through with the
-mouth.</p>
-
-<p>8. The goods after their immersion in the vulcanising fluid
-shall not lie open in the room, but shall either be placed
-under a ventilated cover or at once be carried into the drying
-chamber.</p>
-
-<p>The drying chamber or drying rooms in which the wares are
-exposed to artificial heat immediately after vulcanising shall be
-so arranged that actual entrance into them for the putting in
-or taking out of the vulcanised goods shall not be necessary. No
-person shall be allowed to enter the drying chamber while work
-is going on. The higher authorities can permit of exceptions to
-this rule in the case of the drying of long rolls if sufficient protecting
-arrangements are made.</p>
-
-<p>9. When vulcanisation is effected by means of chloride of
-sulphur the vessels or chambers used for holding it shall be
-so arranged that escape of the fumes is prevented.</p>
-
-<p>No person shall enter the vulcanising chamber until the
-air in the chamber has been completely changed; it shall
-not be used for purposes other than vulcanising.</p>
-
-<p>10. Employment in vulcanising with carbon bisulphide or
-in other work exposing the workers to carbon bisulphide vapour
-shall not be allowed without a break for more than two hours
-and in no case for more than four hours in one day; after
-two hours a pause of at least one hour must be allowed before
-resumption.</p>
-
-<p><span class="pagenum"><a name="Page_274" id="Page_274">[274]</a></span></p>
-
-<p>No person under 18 years of age shall be employed.</p>
-
-<p>11. The occupier shall provide all workers employed in work
-mentioned in paragraph 10 with proper and sufficient overalls.
-By suitable notices and supervision he shall see that when not
-in use they are kept in their proper place.</p>
-
-<p>12. Separate washing accommodation and dressing-rooms
-for each sex shall be provided, distinct from the workrooms,
-for all persons employed as stated in paragraph 11.</p>
-
-<p>Water, soap, and towels and arrangements for keeping the
-clothes put off before the commencement of work shall be
-provided in sufficient amount.</p>
-
-<p>13. The occupier shall appoint a duly qualified medical
-practitioner (whose name shall be sent to the Inspector of
-Factories) to supervise the health of those exposed to the
-effects of carbon bisulphide. He shall examine the workers
-once every month with a view to the detection of poisoning
-by carbon bisulphide.</p>
-
-<p>By direction of the medical practitioner workers showing
-signs of carbon bisulphide poisoning shall be suspended from
-work and those who appear peculiarly susceptible shall be
-suspended permanently from work in processes mentioned in
-paragraph 10.</p>
-
-<p>14. The occupier shall keep a book, or make some official
-responsible for its keeping, of the changes in the personnel in
-the processes mentioned in paragraph 10 and as to their state
-of health. The book shall contain—</p>
-
-<div class="blockquote">
-
-<p>(1) The name of the person keeping the book;</p>
-
-<p>(2) The name of the appointed surgeon;</p>
-
-<p>(3) Surname, Christian name, age, residence, date of
-first employment, and date of leaving of every worker
-mentioned in paragraph 10, and the nature of the employment;</p>
-
-<p>(4) The date of any illness and its nature;</p>
-
-<p>(5) Date of recovery;</p>
-
-<p>(6) The dates and results of the prescribed medical
-examination.</p>
-
-</div>
-
-<p>15. The occupier shall require the workers to subscribe to
-the following conditions:—</p>
-
-<div class="blockquote">
-
-<p>No worker shall take food into the vulcanising rooms;</p>
-
-<p>The workers shall use the protection afforded in
-paragraphs 5-7 and use the overalls in the work named;</p>
-
-<p>The workers shall obey the directions of the occupier
-given in accordance with Rule 5, paragraphs 1 and 2, Rule
-8, paragraphs 1 and 2, and Rule 9, paragraph 2. Workers<span class="pagenum"><a name="Page_275" id="Page_275">[275]</a></span>
-contravening these orders shall be liable to dismissal
-without further notice.</p>
-
-<p>If in a factory regulations already exist (paragraph 134(a)
-of the Industrial Code) the above shall be included.</p>
-
-</div>
-
-<p>16. In the vulcanising rooms mentioned in Rule 1 there
-shall be posted up a notice by the police stating—</p>
-
-<div class="blockquote">
-
-<p>(<i>a</i>) The cubic capacity of the rooms;</p>
-
-<p>(<i>b</i>) The number of workers who may be employed.</p>
-
-</div>
-
-<p>Further, in every vulcanising room there shall be posted
-up in a conspicuous place and in clear characters Rules 1-15
-and the conditions in paragraph 15.</p>
-
-</div>
-
-<p>Reference should be made also to the Prussian Ministerial
-Decree, dated February 23, 1910, on the preparation, storing,
-and manufacture of carbon bisulphide, and to the French
-Ministerial Circular, dated January 20, 1909 (Manufacture
-of Indiarubber).</p>
-
-<p>Employment of benzine and chloride of sulphur for
-vulcanising is, from a hygienic standpoint, to be preferred to
-that of the much more dangerous carbon bisulphide. The
-same applies also to the process of the extraction of fat.</p>
-
-<p>In the references made to general arrangements for the
-protection of workers dealing with poisons, stress was laid on
-the complete enclosing of extraction apparatus. This applies,
-of course, to extraction by means of carbon bisulphide, both on
-grounds of economy, health, and risk from fire.</p>
-
-<p>On account of the risk to health, efforts have been made
-to substitute other means of equal efficiency, free from danger.
-Such a substitute may be found in <i>carbon tetrachloride</i>. This
-extracts well, and dissolves grease spots (like benzine), is not
-explosive, is scarcely inflammable, and is less poisonous than
-the substances commonly used for extraction. Its employment
-is to be recommended on hygienic grounds, but the
-relatively high price may stand in the way of its use.</p>
-
-<h4>Illuminating Gas Industry. Production of Tar and Coke</h4>
-
-<p class="center">(See also pp. <a href="#Page_71">71-90</a> and <a href="#Page_199">199</a>)</p>
-
-<p>In illuminating gas factories imperviousness of the whole
-working system is especially important from an economical
-and hygienic standpoint, since only in this way can danger<span class="pagenum"><a name="Page_276" id="Page_276">[276]</a></span>
-to the working staff be avoided. This applies especially
-to the retorts, from which no gas should be allowed to
-escape. If the exhaust is working satisfactorily this should
-not be possible, as the pressure of the gas in the retorts during
-distillation will be a negative one. Correct regulation of
-pressure is thus of the greatest importance in the prevention
-of poisoning in gas works.</p>
-
-<p>Further, special precaution is necessary in operations with
-gas purifying material containing cyanogen, since otherwise
-the workers suffer from the gases developed from the gas
-lime.</p>
-
-<p>Work with gas purifying material should be so arranged
-that injurious gases are carried away by suitable ventilating
-arrangements. Consideration for the neighbourhood forbids
-their discharge into the open air, and forbids also operations
-with the gas purifying material in the open air; therefore non-injurious
-removal of these gases is necessary.</p>
-
-<p>Quenching of the coke also should, on account of the
-annoyance to the working staff and to lessen nuisance to the
-neighbourhood, be carried out so that the fumes are drawn into
-the main chimney stack.</p>
-
-<p>In coke ovens escape of tarry constituents and of poisonous
-emanations are prevented by imperviousness of the apparatus,
-by sufficiency of the exhaust draught, and especially by
-passing the products of distillation, which cannot be condensed,
-under a fire, or by absorbing them either with water
-or oil.</p>
-
-<p>Special precautionary measures are needed further in the
-distillation of the washing oil, and generally escape of poisonous
-emanations must be prevented by the greatest possible imperviousness
-of the distillation system and corresponding
-regulation of pressure.</p>
-
-<h4>Gas Motors (Power Gas Stations)</h4>
-
-<p class="center">(See also pp. <a href="#Page_80">80-5</a>)</p>
-
-<p>The following points, taken from an Austrian Ministerial
-Decree (dated December 2, 1903), for the prevention of
-poisoning in power gas works, may be useful:</p>
-
-<p><span class="pagenum"><a name="Page_277" id="Page_277">[277]</a></span></p>
-
-<div class="blockquote">
-
-<p class="center"><span class="smcap">Power Gas Installations</span></p>
-
-<p>In mixed gas installations (Dowson, water gas) of the older
-system, the way in which the gas is produced causes the
-whole apparatus and pipes to be under slight negative pressure,
-because the steam required for the process must be blown into
-the generator. In these works, therefore, a small special steam
-boiler is required and a gas receiver to store the gas.</p>
-
-<p>In more modern suction generator gas installations the
-piston is used to suck in steam and air as well as the gases
-arising in the generator and to draw them into the motor
-cylinder. Thus the whole system is kept in a condition of
-slight negative pressure during the process. While the suction
-generator gas system is working, only so much gas is produced
-as the motor uses for the time being, so that with this system
-there is no greater store of gas than is requisite.</p>
-
-<p>In such an installation the following rules should be borne
-in mind:</p>
-
-<p>1. All the apparatus (gas pipes, valves, &amp;c.) must be constructed
-and maintained in a completely impervious condition.
-Any water seals especially which may be in use must receive
-attention.</p>
-
-<p>2. Precautions must be taken to prevent the gases from the
-generator passing into the coolers and purifiers when the engine
-is at rest.</p>
-
-<p>3. Care is to be taken when the apparatus is at rest to prevent
-any possible subsequent escape of gas into the room where the
-apparatus is installed.</p>
-
-<p>4. The return of explosive gas out of the gas engine into
-the gas pipe by failure to ignite or other accident, must be made
-impossible.</p>
-
-<p>5. The apparatus through which the generator is charged
-must possess a tightly fitting double valve to prevent escape
-of gas into the room during charging.</p>
-
-<p>6. The pipes for conducting away the unpleasantly smelling
-bituminous constituents in the water mixed with sulphuretted
-hydrogen from the scrubbers must not communicate with the
-workroom.</p>
-
-<p>7. Precautions must be taken to minimise the danger
-during the cleaning of the generator (removal of ashes and
-slag).</p>
-
-<p>8. All stop-cocks and valves are to be so arranged that their
-position at any time (open or shut) is clearly visible from outside.</p>
-
-<p>9. Purifiers with a capacity greater than two cubic meters<span class="pagenum"><a name="Page_278" id="Page_278">[278]</a></span>
-must be provided with appliances which make possible thorough
-removal of the gas before they are opened.</p>
-
-<p>10. The gas washing and cleaning apparatus and pipes are
-to be fitted with gauges indicating the pressure existing in them
-at any moment.</p>
-
-<p>11. When a suction gas plant is first installed and also at
-times when there is no gas in the pipes and plant between
-the generator and the engine, gas must be blown in until all
-air is expelled before the engine is set going.</p>
-
-<p>12. During the cleaning of apparatus and pipes which, when
-in action, contain gas, the rooms must be thoroughly ventilated.</p>
-
-<p>13. Rooms in which suction gas plant is installed must be
-of such a height that all the plant and its connections can be
-easily reached for cleaning, &amp;c., and be capable of such free
-ventilation as to render impossible an accumulation of gas.</p>
-
-<p>14. These rooms must be separated from living rooms by
-a wall without any openings in it. Emanations also must be
-prevented as far as possible from entering into living or working
-rooms situated over the gas engine.</p>
-
-<p>15. Erection of apparatus for generating and purifying
-suction gas in cellars shall only be allowed if specially effective
-ventilation is provided by natural or mechanical means.</p>
-
-</div>
-
-<p>Other Regulations are those of the Prussian Ministerial
-Decree, dated June 20, 1904, as to the arrangement and
-management of suction gas premises.</p>
-
-<h4><span class="smcap">Acetylene Gas Installations</span></h4>
-
-<p class="center">(See also pp. <a href="#Page_85">85-7</a>)</p>
-
-<p>The following regulations for the protection of workers in
-acetylene gas installations are taken from the Prussian
-Ministerial Decree, dated 2 November, 1897:</p>
-
-<div class="blockquote">
-
-<p>1. Preparation and condensation of acetylene on the one
-hand, and liquefaction on the other, must be carried on in
-separate buildings.</p>
-
-<p>2. If the pressure employed for condensation of the gas
-exceeds eight atmospheres, this work must take place in a room
-set apart for the purpose.</p>
-
-<p>3. Rooms in which acetylene is prepared, condensed, or
-liquefied shall not be used as, nor be in direct connection with,
-living rooms. They must be well lighted and ventilated.</p>
-
-<p><span class="pagenum"><a name="Page_279" id="Page_279">[279]</a></span></p>
-
-<p>4. The carbide must be kept in closed watertight vessels,
-so as to ensure perfect dryness and only such quantities shall
-be taken out as are needed. The vessels must be kept in dry,
-light, well-ventilated rooms; cellar rooms may not be used for
-storage purposes.</p>
-
-<p>5. Crushing of carbide must be done with the greatest
-possible avoidance of dust. Workers are to be provided with
-respirators and goggles.</p>
-
-<p>6. Acetylene gasometers must be fitted up in the open air
-or in a well-ventilated room, separated from the gas generator.
-Every gas receiver must have a water gauge showing the pressure
-in the receiver.</p>
-
-<p>7. Between the gasometer and receiver a gas purifier must
-be provided so as to remove impurities (phosphoretted hydrogen,
-arseniuretted hydrogen, carbon bisulphide, ammonia, &amp;c.).</p>
-
-<p>8. Condensation of acetylene gas at a pressure exceeding
-ten atmospheres shall only be done in combination with cooling.</p>
-
-</div>
-
-<h4><span class="smcap">Distribution and Use of Power and Illuminating Gas</span></h4>
-
-<p>The Austrian Gas Regulations (of July 18, 1906) contain
-general provisions as to impermeability and security of the
-gas pipes and the precautions to be observed in their installation.
-Special directions follow as to main flues, material,
-dimensions, branches, and connections, valve arrangements,
-testing of the pipes against leakage, directions for discovering
-leaks, and other defects; also the nature of the branch pipes
-(dimensions and material), valves, cocks, syphons, water seals,
-and pressure gauges. In addition there are directions as to
-testing pipes and how to deal with escape of gas, freezing of
-pipes, and other mishaps.</p>
-
-<h4>Ammonia</h4>
-
-<p class="center">(See also pp. <a href="#Page_90">90-3</a> and <a href="#Page_175">175</a>)</p>
-
-<p>In the production of ammonia and ammonium salts
-(ammonium sulphate) combination of the ammoniacal vapour
-with the sulphuric acid is accompanied with the formation of
-volatile dangerous gases containing sulphuretted hydrogen
-and cyanogen compounds, which produce marked oppression
-and sometimes endanger the health of the workers. Drawing-off
-these fumes into the furnace (practised sometimes<span class="pagenum"><a name="Page_280" id="Page_280">[280]</a></span>
-in small industries) is not advisable, as the sulphuretted
-hydrogen is burnt to sulphur dioxide; if it is burnt absorption
-of the sulphur dioxide should follow, or working it up into
-sulphuric acid (Leymann). Often these gases are freed from
-cyanogen compounds and sulphuretted hydrogen by means of
-gas purifying materials, such as are used in gas works. The
-whole apparatus must be impervious. Where liquids containing
-ammonia are used exhaust ventilation is necessary.</p>
-
-<h4>Cyanogen, Cyanogen Compounds</h4>
-
-<p class="center">(See also pp. <a href="#Page_93">93-5</a> and <a href="#Page_195">195-7</a>)</p>
-
-<p>Processes in which cyanogen gas can develop, require to
-be done under a powerful exhaust draught.</p>
-
-<p>In the production of cyanogen compounds possibility of the
-escape of hydrocyanic acid (prussic acid) has to be borne in
-mind. Such escape is possible in its production from raw
-animal products.</p>
-
-<p>The most careful cleanliness and observance of general
-measures for personal hygiene are necessary in factories in
-which cyanogen compounds are manufactured or handled. In
-crushing cyanide of potassium the workers should wear indiarubber
-gloves and respirators. The products should be stored
-in closed vessels in dry store rooms set apart for the purpose.</p>
-
-<p>Modern cyanide of potassium factories which work up
-molasses, from which the sugar has been removed, and also
-residuary distillery liquors, so far conform with hygienic requirements
-that all the apparatus is under negative pressure,
-so that poisonous gases cannot escape into the workrooms.</p>
-
-<h4>Coal Tar, Tar Products</h4>
-
-<p class="center">(See also pp. <a href="#Page_96">96-119</a>)</p>
-
-<p>Care must be taken for the removal of injurious gases
-developed in the manipulation and use of tar (tar distillation)
-and in the processes of cleaning connected therewith. This can
-be most effectively done by carrying on the processes in closed
-apparatus. Hofmann describes such a factory where all<span class="pagenum"><a name="Page_281" id="Page_281">[281]</a></span>
-mixing vessels in which the distillation products are further
-treated are completely closed in, so that even in mixing and
-running off, no contact is possible with the material.</p>
-
-<p>The vessels for holding tar, tar-water, &amp;c., must be impervious
-and kept covered. Only the cold pitch and asphalt
-should be stored in open pits. The cooling of the distillation
-products and residues, so long as they give off poisonous
-and strongly-smelling fumes, should be carried out in metal
-or bricked receivers. Such directions find a place in the
-‘Technical Instructions’ appended to the German Factory
-Code. Without doubt, tar is, because of its smell and for
-other reasons, unpleasant to handle, and the danger to health
-from contact with it is not a matter of indifference. Spilling
-of small quantities of tar during transport and other manipulations
-can hardly be avoided. Careful cleanliness, therefore,
-on the part of workers is strongly urged. It may
-be mentioned that if tar is covered with a layer of tar-water,
-treatment with acid fluids develops sulphur and
-cyanogen compounds, which may affect the workers. Tar
-water should, therefore, be separated carefully from the tar
-and used for the preparation of ammonia.</p>
-
-<p>The same remarks as to cleanliness, &amp;c., apply in the
-manufacture of felt, lamp-black, and briquettes, with use of tar.
-Saturation of felt, and manufacture of tar plaster should be
-done in closed apparatus. In the production of lamp-black,
-even with a great number of soot chambers, there is escape of
-soot causing nuisance to workers and the neighbourhood.
-Complete avoidance of this seems to be difficult, so that
-measures for personal hygiene must be assured. In briquette
-factories it has been found useful to heat the tar by means of
-steam instead of by direct fire, which renders possible the use
-of a closed apparatus and mechanical stirring.</p>
-
-<p>In the distillation of tar, during the first distillation period
-(first runnings) unpleasant and injurious gases containing
-ammonia and sulphur escape from the stills. These should
-(according to Leymann) be carried away through closed pipes
-branching off from the lower end of the running-off pipe,
-either into the furnace (in doing which a possible back flash of
-flame is to be guarded against) or be subjected to purification<span class="pagenum"><a name="Page_282" id="Page_282">[282]</a></span>
-by lime or oxide of iron (similar to that in the case of illuminating
-gas) with a view to recovery of ammonia and sulphur.
-The lower end of the distillation pipes should be U-shaped
-so as to form a liquid seal—the pipes for the drawing off of
-the gases branching off before the curve. In the later stages
-of distillation risk can be checked by careful cooling and
-imperviousness of the apparatus.</p>
-
-<p>Very unpleasant yellow fumes develop in great quantity
-when pitch is run off from the hot still. Hence hot pitch should
-not be run off into open pitch receptacles, but be cooled first in
-closed receptacles.</p>
-
-<p>The crude products obtained by distillation (light oil,
-creosote oil) are subjected to purification consisting in treatment
-on the one hand with alkali and on the other with acid
-and followed by fractional distillation. In these processes
-injurious fumes may develop, therefore they must—as already
-mentioned—be carried on in closed vessels provided with
-means of escape for fumes and appliances for mechanical
-stirring; the fumes drawn off must be led into the chimney
-stack.</p>
-
-<p>In the distillation of brown coal, of tar, and of resin, it is
-necessary, as in the distillation of coal tar, to insist above all on
-careful cooling and condensation, and thorough absorption of
-uncondensed gases in washing towers. Special precautionary
-rules are necessary to guard against the danger of entering tar
-stills for cleaning purposes. Such directions were approved in
-Great Britain in 1904 in view of accidents which occurred in
-this way:</p>
-
-<div class="blockquote">
-
-<p class="center"><span class="smcap">Tar Distilling</span></p>
-
-<p>The following directions<a name="FNanchor_9" id="FNanchor_9"></a><a href="#Footnote_9" class="fnanchor">[I]</a> are approved by the Home Office and
-are applicable to factories in which is carried on the distillation
-of tar for the production of naphtha, light oil, creosote oil,
-and pitch.</p>
-
-<p>1. During the process of cleaning, every tar still should be
-completely isolated from adjoining tar stills either by disconnecting
-the pipe leading from the swan neck to the condenser
-worm, or by disconnecting the waste gas pipe fixed to the worm<span class="pagenum"><a name="Page_283" id="Page_283">[283]</a></span>
-end or receiver. Blank flanges should be inserted between the
-disconnections. In addition, the pit discharge pipe or cock at
-the bottom of the still should be disconnected.</p>
-
-<p>2. Every tar still should be ventilated and allowed to cool
-before persons are allowed to enter.</p>
-
-<p>3. Every tar still should be inspected by the foreman or
-other responsible person before any workman is allowed to enter.</p>
-
-<p>4. The inspecting foreman on first entering any tar still or
-tank, and all persons employed in tar stills or tanks in which there
-are no cross stays or obstructions likely to cause entanglement,
-should be provided with a belt securely fastened round the
-body with a rope attached, the free end being left with two
-men outside whose sole duty should be to watch and draw out
-any person appearing to be affected by gas. The belt and rope
-should be adjusted and worn in such a manner that the wearer
-can be drawn up head foremost and through the manhole and
-not across it.</p>
-
-<p>5. A bottle of compressed oxygen, with mouthpiece, should
-be kept at all times ready for use; and printed instructions
-as to the use of this bottle, and the method to be employed for
-resuscitation by means of artificial respiration should be kept
-constantly affixed. A draft of such instructions is appended.</p>
-
-<p>6. A supply of suitable chemical respirators properly charged
-and in good condition should be kept ready for use in case of
-emergency arising from sulphuretted hydrogen or certain
-poisonous gases. (Granules of carbon saturated with a solution
-of caustic soda readily absorb sulphuretted hydrogen and may
-be used for charging respirators.)</p>
-
-<p>7. The use of naked lights should be strictly prohibited in
-any portion of the works where gas of an inflammable nature
-is liable to be given off.</p>
-
-<p>8. Each still should be provided with a proper safety valve,
-which should at all times be kept in efficient working condition.</p>
-
-</div>
-
-<h4><span class="smcap">Gassing</span></h4>
-
-<div class="blockquote">
-
-<p><i>Symptoms.</i>—The first symptoms are giddiness, weakness in the legs, and
-palpitation of the heart. If a man feels these he should at once move into
-fresh warm air, when he will quickly recover if slightly affected. He should
-avoid exposure to cold. He should not walk home too soon after recovery;
-any exertion is harmful.</p>
-
-<p><i>First Aid.</i>—Remove the patient into fresh warm air. Send for the oxygen
-apparatus. Send for a doctor. Begin artificial breathing at once if the
-patient is insensible and continue it for at least half-an-hour, or until natural<span class="pagenum"><a name="Page_284" id="Page_284">[284]</a></span>
-breathing returns. Give oxygen<a name="FNanchor_10" id="FNanchor_10"></a><a href="#Footnote_10" class="fnanchor">[J]</a> at the same time and continue it after
-natural breathing returns.</p>
-
-<p><i>Artificial Breathing</i> (<i>Schäfer Method</i>).—Place the patient face downwards
-as shown in the diagrams.</p>
-
-<p>Kneel at the side of the patient and place your hands flat in the small of
-his back with thumbs nearly touching, and the fingers spread out on each
-side of the body over the lowest ribs (<i>see</i> Diagram 1).</p>
-
-<div class="figcenter" style="width: 500px;">
-<img src="images/diagram1.jpg" width="500" height="275" alt="" />
-<p class="caption"><span class="smcap">Diagram 1</span></p>
-</div>
-
-<p>Then promote artificial breathing by leaning forward over the patient
-and, without violence, produce a firm, steady, downward pressure (<i>see</i> Diagram
-2). Next release all pressure by swinging your body backwards without
-lifting your hands from the patient (<i>see</i> Diagram 1).</p>
-
-<div class="figcenter" style="width: 500px;">
-<img src="images/diagram2.jpg" width="500" height="300" alt="" />
-<p class="caption"><span class="smcap">Diagram 2</span></p>
-</div>
-
-<p>Repeat this pressure and relaxation of pressure without any marked
-pause between the movements, <i>about 15 times a minute</i>, until breathing is
-established.</p>
-
-</div>
-
-<p><span class="pagenum"><a name="Page_285" id="Page_285">[285]</a></span></p>
-
-<p>In my opinion as expressed in the general discussion, use of
-breathing apparatus (smoke helmets) with oxygen is strongly
-advisable; these implements must be put on before entering the
-still.</p>
-
-<p>In creosoting wood, opening the apparatus and taking out
-the steeped wood should only be done when the apparatus is
-sufficiently cooled, as otherwise injurious fumes escape.</p>
-
-<p>In heating asphalt unpleasant fumes arise which should
-be drawn off into a furnace, or absorbed by a condenser
-charged with oil (Leymann); open pans should be avoided, as
-injurious to workers.</p>
-
-<h4>Organic Dye-stuffs, Coal-Tar Colours.</h4>
-
-<p class="center">(See also pp. <a href="#Page_107">107-19</a> and <a href="#Page_204">204-15</a>)</p>
-
-<p>The hygienic measures to be adopted for the prevention of
-industrial poisoning in coal-tar colour factories are chiefly
-concerned with the poisonous nature on the one hand of the raw
-material (benzene, toluene, &amp;c.) and on the other of the intermediate
-products (nitrobenzene, aniline, toluidine, &amp;c.) and
-the subsidiary substances (chlorine, acids, especially nitric
-acid, &amp;c.,) used.</p>
-
-<p>The most important measures are as follows:</p>
-
-<p>In purifying the raw materials (benzene, &amp;c.) the distillation
-requires to be done under effective cooling and in impervious
-apparatus. If injurious solvents are employed (such as
-pyridine in the production of anthracene) the manipulations
-should be performed in closed apparatus if possible, under
-negative pressure. The fumes exhausted should be carefully
-condensed by cooling or absorbed by a spray of water or oil.</p>
-
-<p>In view of the poisonous nature of benzene, the apparatus,
-stills, receivers, tanks, tank waggons, &amp;c., should only be
-entered for the purpose of cleaning or repairing after preliminary
-thorough removal of all residue of benzene, complete isolation
-from all similar apparatus near, and thorough ventilation.<span class="pagenum"><a name="Page_286" id="Page_286">[286]</a></span>
-Workers entering the stills, &amp;c., should always be equipped with
-breathing apparatus (smoke helmets) and with a supply of
-oxygen. Other aids, such as safety belts which are held by
-helpers, are not here advocated in view of the often sudden
-fatal poisoning, especially as the rescuer is easily induced to
-spring to the assistance of his unfortunate mate without the
-necessary equipment. The frequency of such accidents calls
-urgently for the use of breathing apparatus.</p>
-
-<p>In the manufacture of <i>diazo-</i> and <i>nitroso-compounds</i> and
-generally in nitrating operations poisonous nitrous fumes are
-developed. By reduction in an acid solution, acid fumes
-and singularly pungent-smelling compounds can be given off.
-If reduction by means of tin is practised, the arsenic in the tin
-can cause evolution of the extremely poisonous arseniuretted
-hydrogen gas. In sulphonating, sulphur dioxide can develop;
-and sulphuretted hydrogen gas on heating with sulphur or
-sulphide of sodium.</p>
-
-<p>All manipulations should take place in tightly closed-in
-apparatus provided with exhaust, and the gases drawn off
-should be absorbed or effectively carried away. In the case
-of many injurious gases it is not sufficient merely to conduct
-them into the flue; they ought to be condensed and got rid of.
-Thus acid fumes (nitrous fumes, sulphur dioxide, hydrochloric
-acid vapour, chlorine gas) are neutralised by water or milk of
-lime, or a solution of soda; ammonia or alcohol by water;
-sulphuretted hydrogen and arseniuretted hydrogen by lime
-and oxide of iron; aniline, &amp;c., by dilute acids.</p>
-
-<p>Production of <i>nitrobenzene</i>, by nitrating benzene requires
-to be done in closed apparatus, provided with mechanical
-agitators. In the subsequent separation of the nitrating acids
-from the resulting nitro-compounds, escape of vapourised
-nitro-compounds can scarcely be avoided even if closed
-apparatus is used. Provision, therefore, must be made for
-abundant ventilation of the workrooms. The reduction of the
-nitro-compounds (nitrobenzene, nitrotoluene) to aniline
-(toluidine) must similarly take place in closed agitating vessels.
-Introduction of the iron filings and sulphuric or hydrochloric
-acids, also the subsequent saturation with lime, and driving
-over of the aniline, &amp;c., with steam, and collection of the distillate,
-must take place in completely closed apparatus.<span class="pagenum"><a name="Page_287" id="Page_287">[287]</a></span>
-Nevertheless, escape of small quantities of aniline is very
-difficult to prevent unless ample ventilation is provided.</p>
-
-<p>In the production of <i>fuchsin</i> by heating aniline hydrochloride
-(toluidine, red oil) with nitrobenzene (formerly arsenic acid)
-in closed vessels, furnished with mechanical stirring apparatus
-the aniline remaining unconverted after the melting escapes in
-the form of steam carrying aniline fumes, even with careful
-condensation, so that thorough ventilation and the other general
-measures for the protection of workers set forth on pp. <a href="#Page_242">242
-<i>et seq.</i></a> are required.</p>
-
-<p>Marked injury to health and distress to workers through acid
-fumes are sometimes caused by the denitration of the waste
-mixture of sulphuric and nitric acids in the nitrating process,
-that is, by the separation of nitric acid from the acid mixture.
-This denitration takes place usually in the Glover towers of the
-lead chamber system which is often associated with the manufacture
-of aniline. The mixed nitro-compounds of the waste
-acids, however, are often not completely condensed, but pass
-through the chambers and Gay-Lussac towers and escape into
-the air, whence arises the constant smell of nitrobenzene in
-aniline factories (Leymann). In the production of <i>naphthylamine</i>
-and recovery of chlorinated products, escaping chlorine
-should be led into chloride of lime chambers, hydrochloric
-acid fumes into towers to be absorbed by water and milk of
-lime or a solution of soda.</p>
-
-<p>In aniline factories danger can scarcely be wholly avoided,
-as the workers, on the one hand, come into contact with
-poisonous substances, nitrobenzene, aniline, &amp;c., and on the
-other hand, in spite of all technical hygienic measures, can
-hardly help breathing in some of the aniline. Apart from the
-technical regulations, therefore, there must be insistence on
-cleanliness of the workrooms, personal cleanliness on the part
-of the workers (washing, baths, working suits, cloak-rooms, &amp;c.).
-Besides this, contact with aniline, nitrobenzene, &amp;c., wetting
-of the body and clothes with these substances, and, especially
-spilling, splashing, and scattering these fluids must be carefully
-avoided. The workers require to be suitably instructed as to
-the symptoms of nitrobenzene and aniline poisoning, and the
-right steps to take, if poisoned. The oxygen apparatus must
-always be at hand, ready for use; the workers must be<span class="pagenum"><a name="Page_288" id="Page_288">[288]</a></span>
-instructed how to use it. Further, workers, especially those
-newly employed, must be under supervision in order that
-assistance may be rendered them on the first signs of poisoning;
-medical assistance ought to be within easy reach. Workers
-also should know of the tendency of aniline to cause cancer of
-the bladder.</p>
-
-<p>Precautions against the poisonous nitro-derivatives of
-benzene (nitrophenol, picric acid, &amp;c.), which are in the form
-of poisonous dust, must take the form of entirely closed-in
-grinding and packing apparatus, or, at all events, removal of
-the dust at its source.</p>
-
-<p>Among official regulations may be mentioned the Prussian
-Ministerial Edict, dated December 18, 1908, as to purification
-and storage of benzene, and further the Regulations dated
-December 13, 1907, and December 30, 1908, in force in Great
-Britain for the manufacture of nitro- and amido-derivatives of
-benzene, and the manufacture of explosives with use of dinitrobenzene
-or dinitrotoluene.</p>
-
-<h3>VI<br />
-<span class="smaller"><i>PREVENTIVE REGULATIONS—THE EXTRACTION
-OF METALS (SMELTING WORK IN GENERAL)</i></span></h3>
-
-<p>Danger is incurred when the furnace leaks, a condition which
-generally occurs in the course of time, or if gases escape during
-the necessary manipulations through the working doors. This
-can be avoided by maintaining the walls in as air-tight a state
-as possible; but as very small leakages are almost unavoidable
-the best course is to so regulate the draught in the furnace (by
-means of fans) that a slight negative pressure always exists
-in it. Naturally, poisonous gases escaping from the furnace
-such as sulphur dioxide, carbonic oxide, carbon dioxide, and
-hydrocarbons require to be drawn away and rendered harmless.
-This can often be done by merely conducting them into
-the main flue. Gases containing carbonic oxide possess high
-heating capacity, and their escape can usually be prevented by
-suitable cupola bells. They can be led away in impervious
-conduits and utilised for heating purposes or for driving gas<span class="pagenum"><a name="Page_289" id="Page_289">[289]</a></span>
-engines. Entering the flues for cleaning or repairing purposes
-is especially dangerous; and as it is difficult to isolate one
-portion entirely from another, such operations might well
-be carried on by persons equipped with breathing apparatus
-(smoke helmets or oxygen apparatus).</p>
-
-<p>In roasting operations handwork can be largely replaced by
-furnaces worked mechanically. If the gases generated are rich
-in sulphur dioxide they can be utilised for the manufacture of
-sulphuric acid or for the production of liquid sulphur dioxide
-either directly or after concentration; if not, they must be
-rendered harmless by treatment with milk of lime in absorption
-towers. Other methods of rendering the sulphur dioxide
-(unsuited for manufacture of sulphuric acid) harmless depend
-on treatment with minerals containing calcium carbonate, or
-magnesium or aluminium hydrate, sodium sulphide, &amp;c.
-Sometimes the sulphurous gases are led into blast furnaces
-containing oxide of iron and coal (so as to form sulphide of
-iron) or are absorbed by means of moist scraps of sheet iron or
-brown coal or peat briquettes.</p>
-
-<p>Use of chlorine compounds in the extraction of metals from
-ores (silver, copper) causes evolution of chlorine and hydrochloric
-acid vapour. These should be dealt with in absorption
-towers. Metallic fumes are collected by suitable condensing
-arrangements. Flue dust is retained in flue dust chambers,
-but in the cleaning of such condensing flues and chambers
-danger to the workers is considerable and they should be
-equipped with respirators, working suits, &amp;c. Personal
-hygiene must be insisted on.</p>
-
-<h4>Iron</h4>
-
-<p class="center">(See also pp. <a href="#Page_146">146-51</a>)</p>
-
-<p>In blast furnace work, industrial poisoning occurs mainly
-from escaping gases rich in carbonic oxide. They may also
-contain sulphur dioxide and cyanogen compounds. The high
-proportion of carbonic oxide, however, makes these gases
-valuable and serviceable, because of their great heating value.
-They are, therefore, now led away and utilised, the furnace
-being closed by a cupola bell only opened by means of a
-mechanical contrivance when charging is necessary; while this<span class="pagenum"><a name="Page_290" id="Page_290">[290]</a></span>
-is being done the ignited blast furnace gases pour out, and the
-workers retire from the opening, so that danger to them is
-avoided. The construction of a blast furnace with a cupola
-bell can be seen in <a href="#fig29">fig. 29</a>. The blast furnace gases are conducted
-away by an opening in the side, and pass along special
-pipes to be utilised, after having gone through a purifying
-process mainly for the removal of flue dust, &amp;c. The gases
-serve partly for the heating of the blast for the furnace itself,
-and partly for driving the gas engines which serve the electrical
-power apparatus, electric lighting, &amp;c., in the works. Through
-the rational utilisation of the blast furnace gases, the workers
-are protected from their injurious action during the working
-of the furnace. Serious gas poisoning, however, occurs not
-infrequently to workers who have to enter the gas mains for
-cleaning purposes. Workers, therefore, should only be permitted
-to enter the flues, &amp;c., a considerable time after the
-process has been stopped and after as complete and thorough
-a ventilation of the system as is possible.</p>
-
-<p>Any portion of the gas system which is to undergo cleaning
-must be completely isolated. Ventilation is best effected by
-the introduction of compressed air. Thus a foundry (in the
-Duisburg district) has provided all its cellars and passages,
-through which gas pipes pass, and which must be entered during
-repairs, with compressed air pipes. It is, however, advisable
-that gas conduits should only be entered by workers equipped
-with breathing apparatus and oxygen supply. Naturally
-adequate instruction of workers and training in first aid are
-necessary, as well as a sufficient supply of oxygen in constant
-readiness.</p>
-
-<p>Injurious gases can escape from the furnace during tapping
-and slag running; poisonous gases with a disagreeable
-odour, from presence of sulphuretted hydrogen, also arise in
-granulating the slag, that is, when the fluid slag is led into water
-for subsequent use in preparation of cement. These gases
-should be collected by hoods, and be carried away as far as
-possible.</p>
-
-<p>In the manufacture of <i>steel</i> by the <i>Bessemer</i> or <i>Thomas-Gilchrist</i>
-process, the dark smoke arising out of the converter
-during the blowing operation should be drawn off (led into
-flues), as it is injurious to health. In the <i>Martin</i> furnaces<span class="pagenum"><a name="Page_291" id="Page_291">[291]</a></span>
-poisoning may occur, especially when the gas flues are entered
-after cessation of work. In letting out the gas in order to stop
-the furnaces, the gas and air valves must first be closed and the
-outlet valves for gas be opened only after the pipes have been
-filled with steam. Steam is to be driven through until the
-pipes are quite free from gas, and the system only entered after
-it has become thoroughly cooled. If need arises for entering
-portions of the system while neighbouring parts are still filled
-with gas, the workers employed require to be provided with
-breathing apparatus and smoke helmets.</p>
-
-<p>In the transport of <i>ferro-silicon</i> several cases of poisoning
-have occurred. Cautionary regulations, therefore, relating to
-this work have been found necessary.</p>
-
-<p>Such directions are contained in the police regulations of
-the Prussian Minister of Trade and Industry respecting the
-transport on the Rhine of corrosive and poisonous substances
-(dated September 29, 1910).</p>
-
-<p>It is prescribed: (1) that ferro-silicon be packed in strong
-watertight cases of wood or metal; (2) that on the cases
-be inscribed, legibly and indelibly, the notice ‘Ferro-silicon.
-To be kept dry! With care!’ (3) that the substance be
-delivered dry and in dry cases; (4) that the cases be
-stored in airy places on the deck of the ship in such a
-manner that they are protected from wet.</p>
-
-<p>Further, care is to be taken that the storage on ships is
-done in such a way that possible damage to the material in
-which it is packed entails no risk. The harbour authorities
-where loading or landing takes place can deal with special
-cases as they think fit.</p>
-
-<p>International regulation as to transport of ferro-silicon in
-the spirit of the above regulations would be most desirable in
-view of the oversea trade in this substance.<a name="FNanchor_11" id="FNanchor_11"></a><a href="#Footnote_11" class="fnanchor">[K]</a></p>
-
-<p><span class="pagenum"><a name="Page_292" id="Page_292">[292]</a></span></p>
-
-<h4>Lead</h4>
-
-<p class="center">(See also pp. <a href="#Page_120">120-40</a> and <a href="#Page_177">177-82</a>)</p>
-
-<p>For protection against lead poisoning, the most widely
-spread of the slow industrial poisonings, all those measures are
-of moment which we have described in our general discussion
-on protection against danger from poison in industries, both
-personal and general.</p>
-
-<p>Personal hygiene, especially careful washing after work,
-prohibition of eating in workrooms, suitable working clothes,
-provision of cloak rooms, meal rooms, baths, &amp;c., are important
-and effective measures for the protection of workers against
-industrial lead poisoning.</p>
-
-<p>The worker should naturally be adequately instructed as to
-the risk. Appropriate printed notices are especially adapted
-for this purpose.</p>
-
-<p>Further, selection of workers should be made under medical
-supervision. Workers who suffer from specific disease which, if
-associated with lead poisoning, may prove dangerous, should be
-excluded from all contact with lead. Among such illnesses must
-be reckoned tuberculosis in all its forms, alcoholism, epilepsy,
-tendency to mental disease (nervous disposition, hysteria,
-neurasthenia, &amp;c.), rheumatism, and disease of the kidneys.</p>
-
-<p>Overtime work undoubtedly increases risk; therefore working
-hours should be shortened as much as possible, and handwork
-replaced by machine work where possible. Young
-persons and women especially should be excluded from work in
-lead. Alternation of employment also is beneficial and essential
-in very dangerous lead work, because the poison accumulates
-in the body and only during intervals wherein absolutely
-no poison can be absorbed has it time to be eliminated.</p>
-
-<p><span class="pagenum"><a name="Page_293" id="Page_293">[293]</a></span></p>
-
-<p>Periodical medical examination by a surgeon is of great
-value with systematic entry of the results of examination in a
-health register. As bearing on this, early diagnosis is of the
-greatest importance, so that workers in whom the first signs
-of lead poisoning appear may at once be suspended or transferred
-to other work.</p>
-
-<p>Lead workers should take suitable nourishing food and
-avoid particularly alcoholic excess.</p>
-
-<p>When the danger is due to fumes or dust in the air
-the measures prescribed on pages 242-55 apply, particularly
-those which aim at keeping the workrooms and the air in
-the factories free of them by locally applied exhaust ventilation.</p>
-
-<p>In order to replace or reduce the use of lead we strongly
-advocate the use of non-poisonous, or at any rate less poisonous,
-substances, where this can be done without technical difficulties,
-as, for instance, carborundum discs instead of lead in polishing
-of precious stones, leadless glaze in pottery for lead glaze (so
-far as this is possible, as to which see page 319), beds free of
-lead (in different industries) for lead beds. In a number of
-cases, however, such substitution is impracticable on technical
-grounds or can only partially be carried out, as, for example, in
-letterpress printing and in the paint and colour industry, in
-which the prohibition of lead has often been repeatedly urged.
-So far, unfortunately, it must be admitted that repeated
-attempts to find a non-poisonous substitute for lead colours,
-especially for white lead, of equal value technically, have not
-succeeded. Endeavours have been made to substitute for lead,
-zinc preparations (zinc white, lithopone, &amp;c.), but hitherto (in
-regard to durability, opacity, &amp;c.) with incomplete success.</p>
-
-<p>Mention must be made of the measures based upon the relatively
-non-poisonous nature of lead sulphide. Lead sulphide
-is, in spite of various assertions to the contrary, practically
-non-poisonous; a fact attributable to its insolubility in water
-and weak acids. As lead sulphide is the only non-poisonous
-lead compound it is a duty to take advantage of this fact for
-purposes of lead prophylaxis.</p>
-
-<p>Attempts with this end in view were made by the introduction
-of sulphur soaps in lead factories. Soaps containing
-in large quantity soluble alkaline sulphides convert lead<span class="pagenum"><a name="Page_294" id="Page_294">[294]</a></span>
-compounds adhering to the skin into black lead sulphide.
-The lead compounds are in this way made harmless, and
-besides this the worker is impelled to remove the staining
-by washing. Such a sulphur soap has been brought into
-the market under the name of akremnin soap, but does not
-enjoy special popularity with the workmen on account of its
-unpleasant smell.</p>
-
-<p>The struggle against the risks of lead employment has been
-going on ever since efforts for the protection of workers were
-commenced.</p>
-
-<p>The International Association for Labour Legislation has
-made valuable inquiries in this direction. The question of
-lead poisoning had been repeatedly discussed by this Association
-and its branches in various countries. The International
-Labour Bureau also took up the issue and in 1906—supported
-by the Institute for General Welfare in Frankfurt a-M.—offered
-a prize for the best treatise on the prevention of industrial
-lead poisoning. The outcome of this competition was the
-volume compiled by Leymann, ‘Die Bekämpfung der Bleigefahr
-in der Industrie’ (published by Fischer, Jena, 1908).</p>
-
-<p>In connection with the resolution adopted at the third
-Congress of the International Association for Labour Legislation
-the Union of Social Reform (as the German branch is
-called) addressed the Federal Council on the white lead question,
-the chief points insisted upon being the need for: (1) regulations
-for the house painting industry in pursuance of Section 120 of
-the Factory Code; (2) report by the Imperial Health Office on
-the practicability of substitutes for lead; (3) exclusion of lead
-colours from use in the painting of public buildings; and (4)
-treatment of lead poisoning by the State Insurance Office as an
-accident entitling to compensation.</p>
-
-<p>These demands were supported by the central office of the
-Society for Promoting the Welfare of Workers, which had as
-far back as its seventh conference in 1898 occupied itself with
-the question of dangerous trades and especially, at its conference
-in 1905, taken up the subject of the protection of workers
-against industrial poisoning.</p>
-
-<p>In Germany these efforts resulted in the passage of a
-number of Imperial Regulations for separate lead industries.</p>
-
-<p>In other countries similar action was set on foot. In<span class="pagenum"><a name="Page_295" id="Page_295">[295]</a></span>
-Austria, where the subject is of special importance in view of
-the part played by lead in the home industries, the Government
-undertook to improve the conditions in industries attended
-with risk of lead poisoning. For this purpose the Statistical
-Office of the Ministry of Commerce and Labour has, since
-1904, carried out extensive inquiries into lead and zinc smelting
-works, paint and colour factories, the painting and varnishing
-trades, letterpress printing, and the ceramic industry. The
-results are contained in the volume ‘Lead Poisoning in
-Smelting Works and Industries Generally’ (published by
-Hölder, Vienna).</p>
-
-<p>As in Germany and Austria, so also in Great Britain, France,
-Switzerland, Belgium, and the Netherlands, regulations in
-various lead industries were enforced after previous official
-inquiry and report.</p>
-
-<p>A general code, however, affecting all lead industries has
-only been published in one or two states. And yet this would,
-in my opinion, be of very great practical value as it is hardly
-possible to regulate each single branch of industry.</p>
-
-<p>In Germany the Regulations dated May 26, 1903, dealing
-with lead colours are certainly comprehensive, but relate
-primarily to paint factories, and are not, therefore, a general
-Order in the sense indicated. In Saxony the decree of June
-27, 1901, made notification of lead poisoning compulsory,
-and in the subsequent decree of April 16, 1909, prescribed
-general measures against lead poisoning. In Switzerland
-single cantons have made general regulations. In France, by
-a decree dated April 23, 1908 (in pursuance of the general
-law of June 12, 1893), all industries attended with risk of
-lead poisoning were brought under Regulation.</p>
-
-<p>We give the provisions of this interesting decree, as it is a
-good example of the kind of Regulations we have in mind.</p>
-
-<div class="blockquote">
-
-<p class="center"><span class="smcap">Decree of the President of the French Republic (April 23,
-1908) relating to certain industries in which lead
-is used</span></p>
-
-<p>1. In the lead industries hereinafter mentioned, viz.:
-smelting, cupellation of argentiferous lead, manufacture of
-accumulators, glass-making, manufacture and use of lead
-enamels, manufacture of pottery, decoration of porcelain or<span class="pagenum"><a name="Page_296" id="Page_296">[296]</a></span>
-faience, ceramic chromo-lithography, manufacture of lead
-alloys, oxides, salts and colours—employers, directors or
-managers are required, apart from the general measures prescribed
-by the Decree of 29 November, 1904, to take special
-measures for protection and health as set forth in the following
-sections.</p>
-
-<p>2. Lead melting pots shall be erected in an airy place
-separated from the other workrooms.</p>
-
-<p>Hoods or other means for the effectual removal of fumes
-shall be provided:—</p>
-
-<p>(<i>a</i>) Over the openings for the run of lead and slag in
-lead smelting.</p>
-
-<p>(<i>b</i>) Before the furnace doors in the manufacture of
-lead oxides.</p>
-
-<p>(<i>c</i>) Above the pots for melting lead or its alloys, in the
-other industries enumerated in Section 1.</p>
-
-<p>3. All work with oxides and other compounds of lead capable
-of producing dust shall be done as far as possible when in a damp
-condition.</p>
-
-<p>When this work cannot be done in the presence of water or
-other liquid, it shall be carried out by mechanical means, in
-covered air-tight apparatus.</p>
-
-<p>If it is impossible to conform to the requirements of either
-of the first two paragraphs of this section, the work shall be
-done under a strong draught so arranged that the harmful products
-may be intercepted by apparatus suitably placed.</p>
-
-<p>Finally, if none of these systems is possible the workmen
-shall be supplied with respirators.</p>
-
-<p>4. Oxides and other compounds of lead, whether dry or
-damp, in suspension or solution, shall not be handled with the
-bare hand. The employer shall at his own expense provide
-the workers in these operations with either gloves made of
-impervious material such as indiarubber, or suitable appliances,
-and shall cause them to be kept in good repair and frequently
-cleaned.</p>
-
-<p>5. Tables on which these products are handled shall be
-covered with some impervious material, kept in a perfectly
-water-tight condition.</p>
-
-<p>The same requirement applies to the floors of the workrooms,
-which shall also be kept damp.</p>
-
-<p>The floor shall be slightly sloped towards a water-tight
-receptacle for collecting the lead substances which are washed
-down.</p>
-
-<p>The work shall be so arranged that there shall be no splashing.<span class="pagenum"><a name="Page_297" id="Page_297">[297]</a></span>
-The tables, floors and walls shall be washed at least once
-a week.</p>
-
-<p>6. Without prejudice to the requirements of section 3, the
-grinding and mixing of lead products, and the use of them in
-dusting shall be effected in special places with active ventilation.</p>
-
-<p>If the materials cannot be damped, the workers shall be
-provided with respirators.</p>
-
-<p>7. Pottery shall not be dipped with bare hands in solutions
-containing litharge, red lead, galena or white lead in suspension.</p>
-
-<p>8. No food or drink shall be brought into the works.</p>
-
-<p>9. Employers shall, at their own expense, provide and
-maintain for the use of the workers, overalls or clothing for
-use during work only, in addition to gloves and respirators.</p>
-
-<p>10. In a part of the building separated from the workrooms,
-there shall be provided for the use of the workers exposed to
-lead dust or fumes, a cloak room and lavatory kept in good order,
-provided with basins or taps in sufficient number, a plentiful
-supply of water, soap and a towel for each worker replaced at
-least once a week.</p>
-
-<p>The cloak rooms shall be provided with cupboards or drawers
-with locks or padlocks, the ordinary clothing being kept apart
-from the working clothes.</p>
-
-<p>11. A warm bath or shower bath shall be provided each
-week for the workers exposed to lead dust or fumes.</p>
-
-<p>A warm bath or shower bath shall be provided every day
-after work, for each worker employed, either in emptying or
-cleaning the condensing chambers and flues, in repairing
-furnaces in lead works, in carrying lead corrosions from the
-beds in white lead factories, in packing red lead, in grinding
-lead enamels and in dry dusting.</p>
-
-<p>12. Employers are required to exhibit, in a conspicuous
-position in the works, regulations imposing on the workers the
-following obligations:—</p>
-
-<div class="blockquote">
-
-<p>To use the appliances, gloves, respirators, and working
-clothes placed at their disposal.</p>
-
-<p>Not to bring into the works either food or drink.</p>
-
-<p>To pay great care, before each meal, to the cleanliness of
-the mouth, nose, and hands.</p>
-
-<p>To take the baths weekly or daily as provided in section 11.</p>
-
-</div>
-
-<p>13. The Minister of Labour may, by Order made with the
-advice of the Consultative Committee for Arts and Manufactures,
-exempt an establishment for a specified period, from all
-or part of the requirements of Regs. 2ᵃ, 2ᵇ, 2ᶜ, 5² and 6¹ in any
-case where it is found that observance of these requirements is<span class="pagenum"><a name="Page_298" id="Page_298">[298]</a></span>
-practically impossible, and that the health and safety of the
-workers are assured by conditions at least equivalent to those
-prescribed in the present Order.</p>
-
-<p>14. Subject to additional postponements which may be
-granted by the Minister in pursuance of Section 6 of the Act of
-12th June, 1893 (as amended by that of 11th July, 1903), the
-delay required for the carrying out of the alterations necessitated
-by the present Decree is limited to one year from the date of its
-publication.</p>
-
-<p>15. The Ministry of Labour is charged with the administration
-of this Decree.</p>
-
-</div>
-
-<p>This decree was supplemented by further noteworthy
-additions requiring medical supervision in lead industries as
-follows:</p>
-
-<div class="blockquote">
-
-<p class="center"><span class="smcap">Decree of December 28, 1909, Organising Medical
-Service in Industries Exposing the Workers to Risk
-of Lead Poisoning</span></p>
-
-<p>1. In premises in which the processes enumerated in Regulation
-1 of the Decree of April 23, 1908, are carried on medical
-attendance as prescribed below shall be provided.</p>
-
-<p>2. A surgeon appointed by the occupier shall examine the
-workers and enter the results of examination required in
-Regulations 3 and 4. The examinations shall be paid for by
-the occupier.</p>
-
-<p>3. No person shall be employed in work mentioned in
-Regulation 1 of the Decree of April 23, 1908, without a certificate
-from the surgeon stating that he is free from symptoms of lead
-poisoning and of illness which might render him specially
-susceptible.</p>
-
-<p>4. No worker shall remain at the same employment unless
-the certificate is renewed one month after commencement of
-employment and subsequently at quarterly intervals.</p>
-
-<p>In addition to the periodical examination the occupier shall
-give an order on the surgeon to every workman declaring himself
-to be ill from his employment or who desires to undergo
-medical examination.</p>
-
-<p>5. A special Register open to the Factory Inspector shall be
-kept containing the following particulars of each worker:</p>
-
-<p>(1) Dates and duration of absence on account of illness
-of any kind;</p>
-
-<p>(2) Dates of medical certificates for such illness, the<span class="pagenum"><a name="Page_299" id="Page_299">[299]</a></span>
-notes made by the surgeon and the name of the
-surgeon furnishing them;</p>
-
-<p>(3) Instructions given by the appointed surgeon in
-pursuance of Regulations 3 and 4 above.</p>
-
-</div>
-
-<h5>Lead Smelting Works</h5>
-
-<p class="center">(See also pp. <a href="#Page_122">122-31</a>)</p>
-
-<p>As the fumes in lead smelting works contain a high proportion
-of lead, all apparatus, especially furnaces and working
-doors, should be provided with efficient exhaust ventilation
-and all flues, furnaces, and other apparatus be as airtight as
-possible. Where lead dust is created exhaust ventilation
-locally applied is necessary. Two of the most important
-preventive measures are personal cleanliness and alternation of
-employment. Dust arising in the furnaces and borne along
-by the furnace gases together with arsenical fumes and dust
-must be deposited in flues or chambers.</p>
-
-<p>In view of the importance of proper instruction of smelters
-as regards the danger we quote the warning note prepared
-by the Institute for Industrial Hygiene, Frankfurt a.-M.,
-which deserves wide circulation.</p>
-
-<div class="blockquote">
-
-<p class="center"><span class="smcap">Lead Leaflet for Smelters</span></p>
-
-<p class="center"><i>How does Lead Poisoning arise?</i></p>
-
-<p>The danger of lead poisoning in lead, spelter and other
-smelting premises can be avoided if due care is observed.</p>
-
-<p>Lead poisoning occurs when lead enters the system. This
-takes place by breathing dust and fume containing lead, or by
-eating and drinking, smoking, snuff taking and tobacco chewing
-if food or tobacco is taken into the mouth with dirty hands
-and dirty face and beard.</p>
-
-<p>No one is immune from lead. Lead accumulates in the
-body of careless persons and he who is not sick to-day can be so
-to-morrow or after weeks or months.</p>
-
-<p class="center"><i>How can Plumbism be avoided?</i></p>
-
-<p>All smelters must observe cleanliness. In this respect they
-should see to the following points:</p>
-
-<p><span class="pagenum"><a name="Page_300" id="Page_300">[300]</a></span></p>
-
-<p>1. It is to their interest to see that the exhaust ventilation
-is kept in order and that the Special Rules or Regulations are
-exactly followed. Further, special clothing should be worn,
-the mouth and nose should be covered, and the floors sprinkled.</p>
-
-<p>2. It is especially important that in intervals and at the
-close of work the mouth, face, beard, and hands should be
-carefully cleaned. Food should not be eaten or the premises
-left without putting on fresh clothes and thoroughly washing
-or, still better, bathing. When drinking, the edge of the
-drinking glass should not be fingered with dirty hands.
-Especially important is it that the teeth should be cleaned
-and the mouth washed out.</p>
-
-<p>3. During work smoking, snuff taking, and tobacco chewing,
-which invariably convey lead into the mouth, should be given
-up, as it is impossible to prevent the hands getting contaminated
-with lead. Lighting the pipe with glowing lead ashes
-is in the highest degree dangerous from the risk of inhaling
-lead fume. The body must be strengthened to withstand the
-action of lead. Moderation in drinking, especially avoidance
-of spirits, should be observed. Alcoholic subjects succumb to
-lead poisoning much more readily than the temperate.</p>
-
-<p>Food should be abundant and rich in fat, for example milk
-and bacon. Thick soups are excellent before work. Work
-should never be begun on an empty stomach. And lastly as
-much fresh air as possible. Walking, athletics, work in the
-garden and field will help to keep off many an attack. If
-anyone thinks that he is suffering from lead poisoning he should
-at once in his own and his family’s interest see the doctor of his
-sick club.</p>
-
-</div>
-
-<p>The following are the</p>
-
-<div class="blockquote">
-
-<p class="center"><span class="smcap">German Imperial Regulations for Lead Smelting Works,
-dated June 16, 1905</span></p>
-
-<p class="center"><i>General Regulations</i></p>
-
-<p>1. Workrooms in which lead ores are roasted, sintered, or
-smelted, pig lead produced and submitted to further treatment,
-distillation of rich lead (bullion cupellation) litharge, red lead,
-or other oxides of lead prepared, ground or sieved, stored or
-packed, or zinc skimmings distilled, shall be roomy, high, and
-so arranged that a sufficient constant exchange of air takes
-place. They shall be provided with a level and solid floor to
-allow of easy removal of dust by a moist method.</p>
-
-<p><span class="pagenum"><a name="Page_301" id="Page_301">[301]</a></span></p>
-
-<p>The walls shall be smooth so as to prevent collection of
-dust; they shall be either washed down or lime washed at least
-once a year.</p>
-
-<p>Provided that this shall not apply in the case of calcining
-sheds with wooden walls.</p>
-
-<p>2. An abundant supply of good drinking water, protected
-against contamination from dust, shall be provided for the
-workers on the furnaces and smelting pots, and in such close
-proximity to them, that they can obtain it at any time without
-having to go into the open air.</p>
-
-<p>Arrangements for sprinkling the floors shall be provided
-near the furnaces. The floors of the rooms mentioned in
-paragraph 1 shall be wet cleansed at least once daily.</p>
-
-<p>3. Prepared (i.e. concentrated) lead ores and leady smelting
-products, unless moist, shall not be crushed except in an
-apparatus so arranged as to prevent as far as possible penetration
-of dust into the workrooms.</p>
-
-<p>Provided that this shall not apply to calcined material from
-converters.</p>
-
-<p>Sacks in which lead ores and materials containing lead have
-been packed shall not be freed from dust and cleaned except
-in a dust-proof apparatus or by washing.</p>
-
-<p>4. Materials containing lead for charging the blast-furnaces,
-if they are oxides and form dust, shall be damped before they
-are mixed with other materials, stocked on the feeding floor, or
-charged into the blast-furnaces.</p>
-
-<p>Provided that this shall not apply in the case of calcined
-material from converters.</p>
-
-<p>5. Dust, gases, and lead fumes, escaping from furnaces, and
-converters, tapping spouts, tapping pots, drain sump, slag pots,
-slag cars, or slag channels, and from glowing residues taken from
-the furnaces, shall be caught as near as possible to the point of
-origin and removed harmlessly.</p>
-
-<p>Dust collecting chambers, flues, as well as furnaces which
-have been ‘blown down,’ shall not be entered by workmen
-unless sufficiently cooled and ventilated.</p>
-
-<p class="center"><i>Special Regulations for such parts of a factory where lead colours
-are prepared</i></p>
-
-<p>6. In grinding, sieving and packing dry leady materials, in
-charging, and emptying litharge and red lead furnaces, in
-collecting the red lead and similar operations in which leady<span class="pagenum"><a name="Page_302" id="Page_302">[302]</a></span>
-dust is developed, exhaust arrangements shall be provided for
-preventing the entrance of dust into the workrooms.</p>
-
-<p>7. Apparatus producing leady dust, if their construction and
-manner of use does not effectually prevent evolution of dust, shall
-have all cracks protected by thick layers of felt or woollen
-material, or by similar means, so as to prevent the entrance of
-dust into the workrooms.</p>
-
-<p>Apparatus of this character shall be provided with arrangements
-for preventing compression of air in them. They shall
-only be opened when the dust in them shall have completely
-settled, and they are absolutely cool.</p>
-
-<p class="center"><i>Special arrangements in force for the distillation of zinc skimmings</i></p>
-
-<p>8. Proposed new furnaces for the distillation of zinc
-skimmings (for which according to pars. 16 and 25 of the Industrial
-Code a special permission is required) shall be so arranged
-that (1) there shall be at least a clear space of 10 feet in front
-of the charging opening; (2) any passages under the distillation
-rooms shall be roomy, at least 11½ feet high in the centre, light
-and airy.</p>
-
-<p>9. Dust, gases, and fumes arising from the zinc skimmings
-distillation furnaces shall be collected as near as possible to the
-point of origin, and carried outside the smelting room.</p>
-
-<p>The entrance of gases from the fires into the smelting room
-shall be prevented as far as possible by suitable arrangements
-for drawing them off.</p>
-
-<p>10. Sieving and packing of by-products obtained in the
-distillation of zinc skimmings (poussière, flue dust) shall not be
-done except in a special room separated from the other workrooms,
-and complying with the requirements of Reg. 1.</p>
-
-<p>Sieving shall only be done in an apparatus so constructed
-that dust shall not escape.</p>
-
-<p class="center"><i>Employment of workers.</i></p>
-
-<p>11. Women and young persons shall not be employed or
-permitted in rooms mentioned in Reg. 1, in flue dust chambers,
-or dust flues, or in the removal of flue dust.</p>
-
-<p>12. No person shall be newly employed in rooms mentioned
-in Reg. 1, in flue dust chambers, or dust flues, or in the transport
-of flue dust, without a certificate of fitness from the surgeon
-appointed by the higher authorities.</p>
-
-<p><span class="pagenum"><a name="Page_303" id="Page_303">[303]</a></span></p>
-
-<p>These certificates shall be collected and shown to the Factory
-Inspector and Appointed Surgeon on request.</p>
-
-<p>13. No person shall be employed in charging blast furnaces,
-apart from mere labouring work on the floors, for more than
-eight hours daily. The same shall apply in the case of workmen
-employed in the inside of furnaces when cool, or in emptying flue
-dust chambers, or dust flues which contain wet flue dust.</p>
-
-<p>No person shall be employed in cleaning out, from inside,
-flue dust chambers, or dust flues containing dry flue dust for
-more than four hours daily; and including emptying and work
-of transport of this kind altogether no longer than eight hours
-daily.</p>
-
-<p>Other workers in rooms specified in Reg. 1 shall not work
-more than 10 hours in 24, exclusive of mealtimes.</p>
-
-<p>Exception to this is allowed in the case of those workers who
-are employed for the purpose of a weekly change of shift, and for
-whom exception as to Sunday employment is permitted by
-Imperial Decree.</p>
-
-<p class="center"><i>Clothing, overalls, lavatory accommodation, &amp;c.</i></p>
-
-<p>14. The occupier shall provide for all persons employed in
-cleaning out flue dust chambers, dust flues, repairing of cooled
-furnaces, grinding, sieving and packing of litharge, red lead, or
-other lead colours, complete suits of working clothes, including
-caps and respirators.</p>
-
-<p>15. Work with lead salts in solution shall not be done except
-by workers who either grease their hands or are provided with
-impermeable gloves.</p>
-
-<p>16. The suit of clothes, or overalls, provided in Regs. 14
-and 15, respirators and gloves, shall be provided in sufficient
-amount and in proper condition. The occupier shall see that
-they are always suitable for their purpose, and are not worn
-except by those workers for whom they are intended; and that
-they, at stated intervals (the overalls at least once a week, the
-respirators and gloves prior to use), are cleaned, and during the
-time that they are not in use are kept in a place specially reserved
-for each article.</p>
-
-<p>17. A lavatory and cloak room shall be provided for the use
-of the workmen in a part of the building free from dust. Separate
-from it there shall be a dining-room. These rooms must be kept
-free from dust and be warmed during the winter.</p>
-
-<p>In a suitable place provision shall be made for warming the
-workers’ food.</p>
-
-<p><span class="pagenum"><a name="Page_304" id="Page_304">[304]</a></span></p>
-
-<p>Water, soap, and towels, and arrangements for keeping
-separate the overalls from other clothing taken off before the
-commencement of work shall be provided in sufficient amount in
-the lavatory and cloak room.</p>
-
-<p>The occupier shall afford opportunity for persons engaged
-in cleaning out flue dust chambers, dust flues, and the cooled
-furnaces, to take a bath daily after the end of the work, and for
-those handling oxides of lead, at least once a week, during
-working hours inside the works. The bathroom shall be
-warmed during the winter.</p>
-
-<p>18. The occupier shall place the supervision of the health of
-the workers in the hands of a surgeon, appointed by the higher
-authorities for this purpose, whose name shall be sent to the
-Inspector of Factories. The surgeon shall examine the workers
-at least once a month in the factory, with a view to the detection
-of symptoms of lead poisoning.</p>
-
-<p>The occupier shall not employ persons suspected by the
-surgeon of having contracted lead poisoning in the processes
-mentioned in Reg. 1 or in cleaning out flue dust chambers, dust
-flues, or furnaces when cold, or transport of the flue dust, until
-they are quite well. Those who appear peculiarly susceptible
-shall be permanently suspended from working in these processes.</p>
-
-<p>19. The Health Register shall be shown to the Factory
-Inspector and Appointed Surgeon on demand. (Similar to
-Reg. 15 of Spelter Regulations.)</p>
-
-<p>20. The occupier shall require the workers to subscribe to the
-following conditions:—</p>
-
-<div class="blockquote">
-
-<p>(1) Food must not be taken into the workrooms.
-Meals may only be taken outside the workrooms.</p>
-
-<p>(2) Workmen must only enter the meal room to take
-their meals or leave the factory, after they have
-taken off their overalls and carefully washed their
-face and hands.</p>
-
-<p>(3) Workmen must use the overalls, respirators and
-gloves in those workrooms and for the particular
-processes for which they are given them.</p>
-
-<p>(4) Cigar and cigarette smoking during work is forbidden.</p>
-
-<p>(5) A bath in the factory must be taken every day at
-the close of their work by those engaged in the
-emptying and cleaning of flue dust chambers, flues,
-and furnaces when cold, and by those employed on
-oxides of lead once a week.</p>
-
-</div>
-
-<p>Provided that this shall not apply in the case of workmen
-exempted by the appointed surgeon.</p>
-
-<p><span class="pagenum"><a name="Page_305" id="Page_305">[305]</a></span></p>
-
-<p>Workers contravening these orders will be liable to dismissal
-without further notice.</p>
-
-<p>21. In every workroom, as well as in the cloak room and meal
-room, there shall be posted up by the occupier, in a conspicuous
-place and in clear characters, a notice of these regulations.</p>
-
-<p>The occupier is responsible for seeing that the requirement of
-Reg. 20 (1) is obeyed. He shall make a manager or foreman
-responsible for the precise carrying out of Reg. 20 (1) (2) and (5).
-The person thus made responsible shall see to the carrying out
-of the regulations and for the exercise of necessary care as
-prescribed in par. 151 of the Factory Act.</p>
-
-<p>22. No work in a lead smelting works shall be commenced
-until notice of its erection has been sent to the Factory Inspector.
-After receipt of the notice he shall personally visit to see whether
-the arrangements are in accordance with these regulations.</p>
-
-<p>23. These regulations come into force on 1st January, 1906.
-Where structural alterations are necessary for the carrying
-out of Regs. 1, 5 (1), 6, 9, 10 and 17, the higher authorities may
-allow an extension of time to a date not later than January 1st,
-1908.</p>
-
-<p>If it seems necessary on strong grounds of public interest, the
-Council (Bundesrath) may extend the time in particular works
-until 1st January, 1913, and until then allow exceptions from the
-regulations as regards Reg. 13 (1) and (2).</p>
-
-</div>
-
-<h5>Accumulator Factories</h5>
-
-<p>[Dr. Rambousek gives a very brief synopsis of the German
-Imperial Regulations in force for this industry and mentions
-that in Great Britain the Regulations of the Secretary of State
-dated 1903 are similar. We have printed these, as the code is
-fairly representative of the English Regulations for (1) smelting
-of metals; (2) paints and colours; (3) tinning of hollow ware;
-(4) yarn dyed with chromate of lead; (5) vitreous enamelling;
-and the special rules for (6) white lead and (7) earthenware:</p>
-
-<div class="blockquote">
-
-<p class="center"><span class="smcap">Regulations dated November 21, 1903, made by the
-Secretary of State for the Manufacture of Electric
-Accumulators</span></p>
-
-<p>Whereas the manufacture of electric accumulators has been
-certified in pursuance of Section 79 of the Factory and Workshop
-Act, 1901, to be dangerous;</p>
-
-<p><span class="pagenum"><a name="Page_306" id="Page_306">[306]</a></span></p>
-
-<p>I hereby, in pursuance of the powers conferred on me by that
-Act, make the following regulations, and direct that they shall
-apply to all factories and workshops or parts thereof in which
-electric accumulators are manufactured.</p>
-
-<p><i>Definitions.</i>—In these Regulations ‘lead process’ means
-pasting, casting, lead burning, or any work involving contact
-with dry compounds of lead.</p>
-
-<p>Any approval given by the Chief Inspector of Factories in
-pursuance of these Regulations shall be given in writing, and
-may at any time be revoked by notice in writing signed by him.</p>
-
-<p class="center"><i>Duties of Occupier</i></p>
-
-<p>1. <i>Ventilation.</i>—Every room in which casting, pasting or
-lead burning is carried on shall contain at least 500 cubic feet of
-air space for each person employed therein, and in computing
-this air space, no height above 14 feet shall be taken into account.</p>
-
-<p>These rooms and that in which the plates are formed shall
-be capable of through ventilation. They shall be provided with
-windows made to open.</p>
-
-<p>2. <i>Separation of processes.</i>—Each of the following processes
-shall be carried on in such manner and under such conditions as
-to secure effectual separation from one another and from any
-other process:</p>
-
-<div class="blockquote">
-
-<p>(<i>a</i>) Manipulation of dry compounds of lead;</p>
-
-<p>(<i>b</i>) Pasting;</p>
-
-<p>(<i>c</i>) Formation, and lead burning necessarily carried on
-therewith;</p>
-
-<p>(<i>d.</i>) Melting down of old plates.</p>
-
-</div>
-
-<p>Provided that manipulation of dry compounds of lead carried
-on as in Regulation 5 (b) need not be separated from pasting.</p>
-
-<p>3. <i>Floors.</i>—The floors of the rooms in which manipulation of
-dry compounds of lead or pasting is carried on shall be of cement
-or similar impervious material, and shall be kept constantly
-moist while work is being done.</p>
-
-<p>The floors of these rooms shall be washed with a hose pipe
-daily.</p>
-
-<p>4. <i>Melting pots.</i>—Every melting pot shall be covered with a
-hood and shaft so arranged as to remove the fumes and hot air
-from the workrooms.</p>
-
-<p>Lead ashes and old plates shall be kept in receptacles
-especially provided for the purpose.</p>
-
-<p>5. <i>Manipulation of dry compounds of lead.</i>—Manipulation of
-dry compounds of lead in the mixing of the paste or other<span class="pagenum"><a name="Page_307" id="Page_307">[307]</a></span>
-processes, shall not be done except (<i>a</i>) in an apparatus so closed,
-or so arranged with an exhaust draught, as to prevent the escape
-of dust into the work room: or (<i>b</i>) at a bench provided with (1)
-efficient exhaust draught and air guide so arranged as to draw
-the dust away from the worker, and (2) a grating on which each
-receptacle of the compound of lead in use at the time shall stand.</p>
-
-<p>6. <i>Covering of benches.</i>—The benches at which pasting is done
-shall be covered with sheet lead or other impervious material,
-and shall have raised edges.</p>
-
-<p>7. <i>Prohibition of employment.</i>—No woman, young person, or
-child shall be employed in the manipulation of dry compounds
-of lead or in pasting.</p>
-
-<p>8. (<i>a</i>) <i>Appointed Surgeon.</i>—A duly qualified medical practitioner
-(in these Regulations referred to as the ‘Appointed
-Surgeon’) who may be the Certifying Surgeon, shall be appointed
-by the occupier, such appointment unless held by the Certifying
-Surgeon to be subject to the approval of the Chief Inspector of
-Factories.</p>
-
-<p>(<i>b</i>) <i>Medical examination.</i>—Every person employed in a lead
-process shall be examined once a month by the Appointed
-Surgeon, who shall have power to suspend from employment in
-any lead process.</p>
-
-<p>(<i>c</i>) No person after such suspension shall be employed in a
-lead process without written sanction entered in the Health
-Register by the Appointed Surgeon. It shall be sufficient compliance
-with this regulation for a written certificate to be given
-by the Appointed Surgeon and attached to the Health Register,
-such certificate to be replaced by a proper entry in the Health
-Register at the Appointed Surgeon’s next visit.</p>
-
-<p>(<i>d</i>) <i>Health Register.</i>—A Health Register in a form approved
-by the Chief Inspector of Factories shall be kept, and shall contain
-a list of all persons employed in lead processes. The
-Appointed Surgeon will enter in the Health Register the dates
-and results of his examinations of the persons employed and
-particulars of any directions given by him. He shall on a
-prescribed form furnish to the Chief Inspector of Factories on the
-1st day of January in each year a list of the persons suspended by
-him during the previous year, the cause and duration of such
-suspension, and the number of examinations made.</p>
-
-<p>The Health Register shall be produced at any time when
-required by H.M. Inspectors of Factories or by the Certifying
-Surgeon or by the Appointed Surgeon.</p>
-
-<p>9. <i>Overalls.</i>—Overalls shall be provided for all persons
-employed in manipulating dry compounds of lead or in pasting.</p>
-
-<p><span class="pagenum"><a name="Page_308" id="Page_308">[308]</a></span></p>
-
-<p>The overalls shall be washed or renewed once every week.</p>
-
-<p>10. <i>Cloak and dining rooms.</i>—The occupier shall provide and
-maintain:</p>
-
-<div class="blockquote">
-
-<p>(<i>a</i>) a cloak room in which workers can deposit clothing put
-off during working hours. Separate and suitable
-arrangements shall be made for the storage of the
-overalls required in Regulation 9.</p>
-
-<p>(<i>b</i>) a dining room unless the factory is closed during meal
-hours.</p>
-
-</div>
-
-<p>11. <i>Food, &amp;c.</i>—No person shall be allowed to introduce,
-keep, prepare or partake of any food, drink, or tobacco, in any
-room in which a lead process is carried on. Suitable provision
-shall be made for the deposit of food brought by the workers.</p>
-
-<p>This regulation shall not apply to any sanitary drink provided
-by the occupier and approved by the Appointed Surgeon.</p>
-
-<p>12. <i>Washing.</i>—The occupier shall provide and maintain for
-the use of the persons employed in lead processes a lavatory, with
-soap, nail brushes, towels, and at least one lavatory basin for
-every five such persons. Each such basin shall be provided with
-a waste pipe, or the basins shall be placed on a trough fitted with
-a waste pipe. There shall be a constant supply of hot and cold
-water laid on to each basin.</p>
-
-<p>Or, in the place of basins the occupier shall provide and
-maintain troughs of enamel or similar smooth impervious
-material, in good repair, of a total length of two feet for every
-five persons employed, fitted with waste pipes, and without
-plugs, with a sufficient supply of warm water constantly
-available.</p>
-
-<p>The lavatory shall be kept thoroughly cleansed and shall be
-supplied with a sufficient quantity of clean towels once every
-day.</p>
-
-<p>13. Before each meal and before the end of the day’s work,
-at least ten minutes, in addition to the regular meal times, shall
-be allowed for washing to each person who has been employed in
-the manipulation of dry compounds of lead or in pasting.</p>
-
-<p>Provided that if the lavatory accommodation specially
-reserved for such persons exceeds that required by Regulation 12,
-the time allowance may be proportionately reduced, and that if
-there be one basin or two feet of trough for each such person
-this Regulation shall not apply.</p>
-
-<p>14. <i>Baths.</i>—Sufficient bath accommodation shall be provided
-for all persons engaged in the manipulation of dry compounds
-of lead or in pasting, with hot and cold water laid on, and a
-sufficient supply of soap and towels.</p>
-
-<p><span class="pagenum"><a name="Page_309" id="Page_309">[309]</a></span></p>
-
-<p>This rule shall not apply if in consideration of the special
-circumstances of any particular case, the Chief Inspector of
-Factories approves the use of local public baths when conveniently
-near, under the conditions (if any) named in such
-approval.</p>
-
-<p>15. <i>Cleaning.</i>—The floors and benches of each workroom
-shall be thoroughly cleansed daily, at a time when no other work
-is being carried on in the room.</p>
-
-<p class="center"><i>Duties of Persons Employed</i></p>
-
-<p>16. <i>Medical examination.</i>—All persons employed in lead
-processes shall present themselves at the appointed times for
-examination by the Appointed Surgeon as provided in
-Regulation 8.</p>
-
-<p>No person after suspension shall work in a lead process, in
-any factory or workshop in which electric accumulators are
-manufactured, without written sanction entered in the Health
-Register by the Appointed Surgeon.</p>
-
-<p>17. <i>Overalls.</i>—Every person employed in the manipulation
-of dry compounds of lead or in pasting shall wear the overalls
-provided under Regulation 9. The overalls, when not being
-worn, and clothing put off during working hours, shall be
-deposited in the places provided under Regulation 10.</p>
-
-<p>18. <i>Food, &amp;c.</i>—No person shall introduce, keep, prepare, or
-partake of any food, drink (other than any sanitary drink provided
-by the occupier and approved by the Appointed Surgeon),
-or tobacco in any room in which a lead process is carried on.</p>
-
-<p>19. <i>Washing.</i>—No person employed in a lead process shall
-leave the premises or partake of meals without previously and
-carefully cleaning and washing the hands.</p>
-
-<p>20. <i>Baths.</i>—Every person employed in the manipulation of
-dry compounds of lead or in pasting shall take a bath at least
-once a week.</p>
-
-<p>21. <i>Interference with safety appliances.</i>—No person shall in
-any way interfere, without the concurrence of the occupier or
-manager, with the means and appliances provided for the
-removal of the dust or fumes, and for the carrying out of these
-Regulations.</p>
-
-<p>These Regulations shall come into force on the 1st day of
-January, 1904.</p>
-
-</div>
-
-<p><span class="pagenum"><a name="Page_310" id="Page_310">[310]</a></span></p>
-
-<h5>White Lead</h5>
-
-<p class="center">(See also pp. <a href="#Page_131">131</a> and <a href="#Page_132">132</a>)</p>
-
-<p>In the manufacture of white lead processes which create
-dust are specially dangerous, namely, emptying the corrosion
-chambers, drying and grinding, transport of the material
-in the form of powder, and packing. The following measures
-are called for: emptying the chambers should only be
-done by men wearing respirators or equipped with breathing
-helmets after preliminary damping of the corrosions by means
-of a spray. Use of a vacuum cleaning apparatus suggests
-itself. Drying should be done as far as possible in stoves
-charged mechanically, the temperature in which can be watched
-from the outside; grinding must be done in closed and ventilated
-mills; transport of the dried material should be effected by
-mechanical means or vacuum apparatus, and packing should
-be done in mechanical packing machines. Further, cleanliness
-and strict discipline are essential. Alternation of employment
-is advisable. The question of substitutes for white lead is
-referred to on p. <a href="#Page_293">293</a>.</p>
-
-<p>Manufacture of red lead calls for precisely similar preventive
-measures. Charging and emptying the oxidising
-furnaces should be done under efficient exhaust ventilation.
-Conveyance, sifting, and grinding of the cooled material
-requires to be done in the same way as has been described for
-white lead.</p>
-
-<p>In the production of chrome colours (lead chromates)
-besides the danger from lead the injurious action of chrome has
-to be borne in mind.</p>
-
-<p>Regulations for white lead factories have been made in
-Germany, Belgium, and Great Britain. We give below the
-German Imperial Regulations dated May 26, 1903.</p>
-
-<div class="blockquote">
-
-<p class="center"><span class="smcap">Regulations for Manufacture of Lead Colours and
-Lead Products</span></p>
-
-<p>(1) The following regulations apply to all premises in
-which lead colours or other chemical lead products (white lead,
-chromate of lead, masicot, litharge, minium, peroxide of lead,
-Cassel yellow, English yellow, Naples yellow, lead iodide, lead
-acetate, &amp;c., are manufactured), or in which mixtures of lead are
-prepared as the principal or as a subsidiary business. They<span class="pagenum"><a name="Page_311" id="Page_311">[311]</a></span>
-shall not apply to lead smelting works, even though processes
-named in paragraph (1) are carried on.</p>
-
-<p>Neither shall they apply to workplaces in which manufactured
-colours are intimately mixed or ground in oil or varnish in
-connection with another industry.</p>
-
-<p>(2) The workrooms in which the materials mentioned in
-paragraph 1 are prepared or packed shall be roomy, lofty, and
-so arranged that sufficient and constant exchange of air can take
-place.</p>
-
-<p>They shall be provided with a solid and smooth floor
-permitting of easy removal of dust by a moist method. The
-floor, unless for purposes of manufacture, shall be kept constantly
-wet, and shall be wet cleansed at least once daily.</p>
-
-<p>The walls, when not of a smooth washable surface or
-painted with oil, shall be whitewashed at least once a year.</p>
-
-<p>(3) The entrance of lead dust, or fumes, into the workrooms
-shall be prevented by suitable means as far as possible. Rooms
-which cannot be thus protected must be so separated from other
-rooms that neither dust nor fumes can enter them.</p>
-
-<p>(4) Lead melting pots shall be covered with a hood and shaft
-communicating directly or by a chimney with the open air.</p>
-
-<p>(8)<a name="FNanchor_12" id="FNanchor_12"></a><a href="#Footnote_12" class="fnanchor">[L]</a> Grinding, sieving, and packing dry lead compounds,
-emptying litharge and minium furnaces, and other operations in
-which lead dust is generated, shall not be done except under
-an exhaust draught, or other efficient means for preventing the
-entrance of dust into the workrooms.</p>
-
-<p>In the packing of colours containing only a little lead, in
-small amounts, or in small packages for retail purposes, exception
-to these regulations can be allowed by the higher authorities.</p>
-
-<p>(9) Machines generating lead dust and not efficiently protected
-by their construction or method of use against the escape
-of dust, shall have all cracks occluded by means of thick layers
-of felt or similar material, so as to prevent the entrance of dust
-into the workrooms.</p>
-
-<p>Machines of this kind shall be provided with arrangements
-preventing pressure of the air inside. They shall not be opened
-until they are cool, and until the dust generated has settled.</p>
-
-<p>(10) Women shall not be employed in factories in which the
-colours specified in paragraph (1) are prepared except in work
-which does not expose them to the action of lead dust or fumes.
-Young persons shall not be employed nor be allowed on
-the premises in factories concerned exclusively or in great<span class="pagenum"><a name="Page_312" id="Page_312">[312]</a></span>
-part with the preparation of lead colours or other lead
-compounds.</p>
-
-<p>(11) No person shall be employed in rooms where the
-processes specified in paragraph (1) are carried on who is not
-provided with a certificate from a qualified surgeon stating that
-he is physically fit and free from disease of the lungs, kidneys,
-and stomach, and that he is not addicted to alcohol. This
-certificate shall be kept and produced on demand to the Factory
-Inspector or Appointed Surgeon.</p>
-
-<p>(12) No person shall be employed in packing lead colours or
-mixtures containing lead or other lead compounds in a dry state,
-or with the coopering of the filled casks for more than eight hours
-daily. This regulation shall not apply where the packing
-machines are provided with effectual exhaust arrangements,
-or so constructed and used as effectually to prevent the escape
-of dust.</p>
-
-<p>No person under 18 years of age shall be employed in the
-process mentioned in the above paragraph, but exception can
-be allowed in the packing of colours containing lead in small
-amount, or in small packages for retail purposes, on application
-to the higher authorities.</p>
-
-<p>For the rest, no person coming into contact with lead or lead
-compounds shall be employed for more than 10 hours within the
-space of 24 hours.</p>
-
-<p>(13) The occupier shall provide overalls and head-coverings
-for all persons coming into contact with lead or lead compounds,
-and suitable footwear for those emptying the oxidising
-chambers.</p>
-
-<p>(14) The occupier shall not allow work involving exposure
-to dust to be performed except by workers provided with
-respirators or moist sponges covering the nose and mouth.</p>
-
-<p>(15) The occupier shall not allow work involving contact
-with soluble salts of lead to be done except by workers provided
-with waterproof gloves or by those whose hands have previously
-been smeared with vaseline.</p>
-
-<p>(16) The occupier shall provide the overalls, respirators, &amp;c.,
-mentioned in paragraphs (13) (14) and (15) for each one of the
-workers in sufficient number and in good condition. He shall
-take care that they are used only by the workers to whom they
-are severally assigned, and that in the intervals of work and
-during the time when they are not in use they shall be kept in
-their appointed place. Overalls shall be washed every week,
-and the respirators, sponges, and gloves before each time that
-they are used.</p>
-
-<p><span class="pagenum"><a name="Page_313" id="Page_313">[313]</a></span></p>
-
-<p>(17) Lavatories and cloak rooms, and, separate from these,
-a mess room, shall be provided for the workers coming into
-contact with lead or lead compounds in a part of the works free
-from dust. These rooms shall be kept in a cleanly condition,
-free from dust, and shall be heated during the cold seasons. In
-the meal room or in some other suitable place there shall be
-means for warming food. The lavatories and cloak rooms shall
-be provided with water, vessels for rinsing the mouth, nail
-brushes for cleaning the hands and nails, soap, and towels.
-Arrangements shall also be made for keeping separate clothes
-worn during work from these taken off before the commencement
-of work. The occupier shall give facilities for all persons
-employed in emptying the oxidizing chambers to have a warm
-bath daily after the end of the work, and for those persons
-coming into contact with lead or lead compounds, twice weekly.
-The time for this shall be during the hours of work, and in the
-cold season the bath room, which must be on the factory premises,
-shall be heated.</p>
-
-<p>(18) The occupier shall appoint a duly qualified medical
-practitioner, whose name shall be sent to the Inspector of
-Factories and to the Health Authority. He shall examine the
-workers at least twice every month with a view to the
-detection of symptoms of lead poisoning. The occupier shall
-not employ workers suspected of symptoms of lead poisoning
-in occupations exposing them to lead or lead compounds until
-they have completely recovered. Those who appear peculiarly
-susceptible shall be suspended permanently from work.</p>
-
-<p>(19) The occupier shall keep a book, or make some official
-responsible for its keeping, recording any change in the personnel
-employed in lead or lead compounds and as to their state of
-health. He shall be responsible for the completeness and
-correctness of the entries except those made by the surgeon.</p>
-
-</div>
-
-<p>The remaining regulations as to entries in the Health
-Register, &amp;c., are similar to those already given in the
-Regulations for lead smelting works on p. <a href="#Page_300">300</a>.</p>
-
-<h5>Use of Lead Colours</h5>
-
-<p class="center">(See also pp. <a href="#Page_132">132-4</a>)</p>
-
-<p>As explained on pp. <a href="#Page_132">132-134</a> use of lead in the painting and
-varnishing trades frequently causes lead poisoning. This has<span class="pagenum"><a name="Page_314" id="Page_314">[314]</a></span>
-led to regulations in various countries having for their object
-partly hygienic measures and partly also limitation of colours
-containing lead, such as prohibition of the use of lead paints in
-the interior of buildings or in the painting of public buildings
-and of ships, &amp;c.</p>
-
-<p>The details of such regulations are seen in the German
-Imperial Regulations dated June 27, 1905:</p>
-
-<div class="blockquote">
-
-<p class="center"><span class="smcap">Order of the Imperial Chancellor relating to the
-Processes of Painting, Distempering, Whitewashing,
-Plastering, or Varnishing. June 27, 1906</span></p>
-
-<p>I.—<i>Regulations for carrying on the Industries of Painting, Distempering,
-Whitewashing, Plastering, or Varnishing.</i></p>
-
-<p><i>Regulation 1.</i>—In the processes of crushing, blending,
-mixing, and otherwise preparing white lead, other lead colours,
-or mixtures thereof with other substances in a dry state, the
-workers shall not directly handle pigment containing lead,
-and shall be adequately protected against the dust arising
-therefrom.</p>
-
-<p><i>Regulation 2.</i>—The process of grinding white lead with oil or
-varnish shall not be done by hand, but entirely by mechanical
-means, and in vessels so constructed that even in the process of
-charging them with white lead no dust shall escape into places
-where work is carried on.</p>
-
-<p>This provision shall apply to other lead colours. Provided
-that such lead colours may be ground by hand by male workers
-over 18 years of age, if not more than one kilogram of red lead
-and 100 grains of other lead colours are ground by any one
-worker on one day.</p>
-
-<p><i>Regulation 3.</i>—The processes of rubbing-down and pumice-stoning
-dry coats of oil-colour or stopping not clearly free from
-lead shall not be done except after damping.</p>
-
-<p>All <i>débris</i> produced by rubbing down and pumice-stoning
-shall be removed before it becomes dry.</p>
-
-<p><i>Regulation 4.</i>—The employer shall see that every worker who
-handles lead colours or mixtures thereof is provided with, and
-wears, during working hours, a painter’s overall or other complete
-suit of working clothes.</p>
-
-<p><i>Regulation 5.</i>—There shall be provided for all workers engaged
-in processes of painting, distempering, whitewashing, plastering,<span class="pagenum"><a name="Page_315" id="Page_315">[315]</a></span>
-or varnishing, in which lead colours are used, washing utensils,
-nail brushes, soap and towels. If such processes are carried on
-in a new building or in a workshop, provision shall be made for
-the workers to wash in a place protected from frost, and to store
-their clothing in a clean place.</p>
-
-<p><i>Regulation 6.</i>—The employer shall inform workers, who
-handle lead colours or mixtures thereof, of the danger to health
-to which they are exposed, and shall hand them, at the commencement
-of employment, a copy of the accompanying leaflet
-(not printed with this edition), if they are not already provided
-with it, and also a copy of these Regulations.</p>
-
-<p>II.—<i>Regulations for the Processes of Painting, Distempering,
-Whitewashing, Plastering, or Varnishing when carried on
-in connection with another Industry.</i></p>
-
-<p><i>Regulation 7.</i>—The provisions of paragraph 6 shall apply to
-the employment of workers connected with another industry
-who are constantly or principally employed in the processes of
-painting, distempering, whitewashing, plastering, or varnishing,
-and who use, otherwise than occasionally, lead colours or
-mixtures thereof. The provisions of paragraphs 8-11 shall also
-apply if such employment is carried on in a factory or shipbuilding
-yard.</p>
-
-<p><i>Regulation 8.</i>—Special accommodation for washing and for
-dressing shall be provided for the workers, which accommodation
-shall be kept clean, heated in cold weather, and furnished
-with conveniences for the storage of clothing.</p>
-
-<p><i>Regulation 9.</i>—The employer shall issue regulations which
-shall be binding on the workers, and shall contain the following
-provisions for such workers as handle lead colour and mixtures
-thereof:</p>
-
-<div class="blockquote">
-
-<p>1. Workers shall not consume spirits in any place where work
-is carried on.</p>
-
-<p>2. Workers shall not partake of food or drink, or leave the
-place of employment until they have put off their
-working clothes and carefully washed their hands.</p>
-
-<p>3. Workers, when engaged in processes specified by the
-employer, shall wear working clothes.</p>
-
-<p>4. Smoking cigars and cigarettes is prohibited during work.</p>
-
-</div>
-
-<p>Furthermore, it shall be set forth in the regulations that<span class="pagenum"><a name="Page_316" id="Page_316">[316]</a></span>
-workers who, in spite of reiterated warning, contravene the
-foregoing provisions may be dismissed before the expiration of
-their contract without notice. If a code of regulations has been
-issued for the industry (par. 134a of the G.O.) the above indicated
-provisions shall be incorporated in the said code.</p>
-
-<p><i>Regulation 10.</i>—The employer shall entrust the supervision
-of the workers’ health to a duly qualified medical man approved
-of by the public authority, and notified to the factory inspector
-(par. 139b of the G.O.), and the said medical man shall examine
-the workers once at least in every six months for symptoms
-indicative of plumbism.</p>
-
-<p>The employer shall not permit any worker who is suffering
-from plumbism or who, in the opinion of the doctor, is suspected
-of plumbism, to be employed in any work in which he has to
-handle lead colours or mixtures thereof, until he has completely
-recovered.</p>
-
-<p><i>Regulation 11.</i>—The employer shall keep or shall cause to be
-kept a register in which shall be recorded the state of health of
-the workers, and also the constitution of and changes in the staff;
-and he shall be responsible for the entries being complete and
-accurate, except in so far as they are affected by the medical
-man.</p>
-
-</div>
-
-<p>Then follow the regulations as to entries in the Register,
-as to which see the Regulations as to lead smelting works,
-p. <a href="#Page_300">300</a>.</p>
-
-<h5>Type Founding and Compositors’ Work</h5>
-
-<p class="center">(See also pp. <a href="#Page_138">138</a> and <a href="#Page_139">139</a>)</p>
-
-<p>Fumes which may carry up lead dust are generated in the
-casting of letters. Dust arises also in setting the type. General
-hygienic measures are especially called for such as healthy
-conditions in the workrooms. Much can be done by exhaust
-ventilation locally applied to the type cases and to letter (mono-
-and linotype) casting machines. Vacuum cleaning of printing
-workshops and type cases is strongly advised.</p>
-
-<p>As some lead poisoning in printing works is attributable to
-lead colours or bronze powder containing lead their use should
-be limited as much as possible.</p>
-
-<p>The German Imperial Regulations for printing works and
-type foundries are as follows:</p>
-
-<p><span class="pagenum"><a name="Page_317" id="Page_317">[317]</a></span></p>
-
-<div class="blockquote">
-
-<p class="center"><span class="smcap">Order of the Federal Council of July 31st, 1897,
-regulating Letterpress Printing Works and Type
-Foundries, in pursuance of Section 120<i>e</i> of the
-Industrial Code</span></p>
-
-<p>I. In rooms in which persons are employed in setting up
-type or manufacture of type or stereotype plates the following
-provisions apply:</p>
-
-<div class="blockquote">
-
-<p>1. The floor of workrooms shall not be more than a half a
-meter (1·64 feet) below the ground. Exceptions may
-only be granted by the higher administrative authority
-where hygienic conditions are secured by a dry area, and
-ample means of lighting and ventilating the rooms.</p>
-
-<p>Attics may only be used as workrooms if the roof is provided
-with a lathe and plaster ceiling.</p>
-
-<p>2. In workrooms in which the manufacture of type or
-stereotype plates is carried on, the number of persons
-shall not exceed such as would allow at least fifteen
-cubic meters of air space (529·5 cubic feet) to each. In
-the rooms in which persons are employed only in other
-processes, there shall be at least twelve cubic meters of
-air space (423·5 cubic feet) to each person.</p>
-
-<p>In cases of exceptional temporary pressure the higher
-administrative authority may, on the application of the
-employer, permit a larger number in the workrooms, for
-at the most 30 days in the year, but not more than will
-allow ten cubic meters of air space (353 cubic feet)
-for each person.</p>
-
-<p>3. The rooms shall be at least 2·60 meters (8· feet) in
-height where a minimum of fifteen cubic meters are
-allowed for each person, in other cases at least 3 meters
-(9·84 feet) in height.</p>
-
-<p>The rooms shall be provided with windows which are
-sufficient in number and size to let in ample light for
-every part of the work. The windows shall be so constructed
-that they will open and admit of complete
-renewal of air in workrooms. Workrooms with sloping
-roof shall have an average height equal to the
-measurements given in the first paragraph of this
-section.</p>
-
-<p>4. The rooms shall be laid with close fitting impervious floor,
-which can be cleared of dust by moist methods. Wooden
-floors shall be smoothly planed, and boards fitted to
-prevent penetration of moisture.<span class="pagenum"><a name="Page_318" id="Page_318">[318]</a></span>
-All walls and ceilings shall, if they are not of a smooth
-washable surface or painted in oil, be limewashed once
-at least a year. If the walls and ceilings are of a smooth
-washable surface or painted in oil, they shall be washed
-at least once a year, and the oil paint must, if varnished,
-be renewed once in ten years, and if not varnished once
-in five years.</p>
-
-<p>The compositors’ shelves and stands for type boxes shall
-be either closely ranged round the room on the floor, so
-that no dust can collect underneath, or be fitted with
-legs, so that the floor can be easily cleaned of dust
-underneath.</p>
-
-<p>5. The workrooms shall be cleared and thoroughly aired once
-at least a day, and during the working hours means shall
-be taken to secure constant ventilation.</p>
-
-<p>6. The melting vessel for type or stereotype metal shall be
-covered with a hood connected to an exhaust ventilator
-or chimney with sufficient draught to draw the fumes
-to the outer air.</p>
-
-<p>Type founding and melting may only be carried on in
-rooms separate from other processes.</p>
-
-<p>7. The rooms and fittings, particularly the walls, cornices,
-and stands for type, shall be thoroughly cleansed twice a
-year at least. The floors shall be washed or rubbed over
-with a damp cloth, so as to remove dust once a day at
-least.</p>
-
-<p>8. The type boxes shall be cleansed before they are put in use,
-and again as often as necessary, but not less than twice
-at least in the year.</p>
-
-<p>The boxes may only be dusted out with a bellows in the
-open air, and this work may not be done by young
-persons.</p>
-
-<p>9. In every workroom spittoons filled with water and one at
-least for every five persons shall be provided. Workers
-are forbidden to spit upon the floor.</p>
-
-<p>10. Sufficient washing appliances, with soap and at least one
-towel a week for each worker, shall be provided as near
-as possible to the work for compositors, cutters, and
-polishers.</p>
-
-<p>One wash-hand basin shall be provided for every five
-workers, fitted with an ample supply of water.</p>
-
-<p>The employer shall make strict provision for the use of the
-washing appliances by workers before every meal and
-before leaving the works.</p>
-
-<p><span class="pagenum"><a name="Page_319" id="Page_319">[319]</a></span></p>
-
-<p>11. Clothes put off during working hours shall either be kept
-outside the workroom or hung up in cupboards with
-closely fitting doors or curtains, which are so shut or
-drawn as to prevent penetration of dust.</p>
-
-<p>12. Artificial means of lighting which tend to raise the
-temperature of the rooms shall be so arranged or
-such counteracting measures taken that the heat of the
-workrooms shall not be unduly raised.</p>
-
-<p>13. The employer shall draw up rules binding on the workers
-which will ensure the full observance of the provisions
-in sections 8, 9, 10, and 11.</p>
-
-</div>
-
-<p>II. A notice shall be affixed and a copy sent to the local
-police authority shewing:</p>
-
-<div class="blockquote">
-
-<p>(<i>a</i>) The length, height, and breadth of the rooms.</p>
-
-<p>(<i>b</i>) The air space in cubic measure.</p>
-
-<p>(<i>c</i>) The number of workers permitted in each room.</p>
-
-<p>A copy of Rules 1 to 13 must be affixed where it can be easily
-read by all persons affected.</p>
-
-</div>
-
-<p>III. Provides for the method of permitting the exceptions
-named above in sections 2 and 3, and makes it a condition of
-reduction in cubic air space for each person employed as type
-founder or compositor that there shall be adequate mechanical
-ventilation for regulating temperature and carrying off products
-of combustion from workrooms.</p>
-
-</div>
-
-<h5>Ceramic Industry</h5>
-
-<p class="center">(See also pp. <a href="#Page_135">135-8</a>.)</p>
-
-<p>A complete substitute for lead in glazes seems as yet impossible
-on technical grounds, as glaze containing lead has
-qualities which cannot be obtained without its use. In small
-works the technique necessary for the production of leadless
-glazes (special kinds of stoves) cannot be expected, especially
-as those carrying on a small industry lack the necessary knowledge
-of how to be able to dispense with the use of lead glazes
-and substitute leadless materials without complete alteration
-in their methods of manufacture. And yet discontinuance or
-the utmost possible limitation of the use of lead glazes and
-colours is most urgently needed in all small ceramic workshops,
-as they are not in a position to put in localised exhaust ventilation,
-&amp;c., which is possible in large factories. Observance of
-even the simplest hygienic measures can scarcely be obtained.<span class="pagenum"><a name="Page_320" id="Page_320">[320]</a></span>
-Consequently very severe cases of lead poisoning are met with
-in small works. An effort in the direction of discontinuance
-of lead glazes was made in Bohemia, where (at the cost of
-the State) technical instruction was given by an expert on the
-preparation of leadless glazes especially in districts where the
-industry was carried on in the homes of the workers. This
-procedure, extension of which is expected, had good results.</p>
-
-<p>Many have demanded, in view of the possibility of substituting
-leadless for lead glazes, the total prohibition of lead.
-Such is the view of the Dutch inspector De Vooys; Teleky
-and Chyzer share the view expressed so far as the small
-industry is concerned, since the practicability of the change
-has been demonstrated.</p>
-
-<p>English authorities (Thorpe, Oliver) propose diminution
-of the lead in the glaze in such a way that on shaking with
-weak acid not more than a specified small quantity shall be
-dissolved (Thorpe test). In my opinion such a measure is
-hardly enough for the small industry. I do not expect much
-good from obligatory use of fritted glazes.</p>
-
-<p>In addition to earthenware, manufacture of tiles and
-bricks leads not infrequently to cases of lead poisoning from
-use of lead glaze.</p>
-
-<p>The following measures apply to the larger ceramic works.
-Since risk is considerable, not only in glost placing but also
-in grinding, ware-cleaning, &amp;c., closed ball mills in grinding
-and locally applied exhaust ventilation in ware-cleaning
-operations, &amp;c., must be arranged. Personal cleanliness and
-proper equipment of a factory in all the essentials insisted on
-on pp. <a href="#Page_226">226-9</a> are important, but nothing can take the place
-of efficient locally applied ventilation.</p>
-
-<p>Vitreous enamelling of household utensils, baths, gas stoves,
-signs, &amp;c., is an analogous process as enamels containing lead
-may be used. Sieving on the dry powder and brushing off
-superfluous glaze often cause poisoning. Here generally the
-same preventive measures apply.</p>
-
-<p>[In Great Britain the china and earthenware industry is
-placed under Regulations dated January 2, 1913, which
-supersede the previous Special Rules. These Regulations—thirty-six
-in number—provide, among other usual provisions,
-(1) for efficient exhaust ventilation in (<i>a</i>) processes giving rise<span class="pagenum"><a name="Page_321" id="Page_321">[321]</a></span>
-to injurious mineral dust (fettling and pressing of tiles, bedding,
-and flinting, brushing and scouring of biscuit) and (<i>b</i>) dusty
-lead processes (ware cleaning, aerographing, colour dusting,
-litho-transfer making, &amp;c.); and (2) monthly periodical
-medical examination of workers in scheduled lead processes.]</p>
-
-<p>In the Netherlands, in consequence of lead poisoning in
-porcelain works, committees were appointed to inquire into
-the subject in 1901, 1902, and 1903.</p>
-
-<h5>File Cutting</h5>
-
-<p class="center">(See also p. <a href="#Page_140">140</a>)</p>
-
-<p>In file cutting the file is cut on a lead bed or a bed of an
-alloy of zinc and lead. The same source of poisoning occurs
-in other industries such as amber working. Lead poisoning
-among file cutters is pronounced. The best preventive
-measure is substitution of a bed of pure zinc for lead. The
-German Imperial Health Office have issued a ‘Warning notice’
-for file-cutters.</p>
-
-<div class="blockquote">
-
-<p class="center"><span class="smcap">Leaflet for File-cutters</span></p>
-
-<p>The use of lead beds or of alloys of lead with other metals
-has repeatedly brought about lead poisoning in file-cutters.
-The beds also supposed to be made of zinc usually contain a
-considerable proportion of lead, and are thus dangerous to
-health.</p>
-
-<p>Among file-cutters lead poisoning arises from absorption of
-the metal in small quantities by means of dirty hands, eating,
-drinking, smoking or chewing of tobacco. The consequences
-of this absorption are not at once noticeable. They appear only
-after weeks, months, or even years, according to the extent to
-which the lead has accumulated in the system.</p>
-
-<p><i>How does lead poisoning show itself?</i>—The first sign is usually
-a bluish-grey line on the gums called the blue line, associated
-with anæmia or pallor. Later symptoms are very varied.
-Most frequently lead colic comes on, the affected person suffering
-from violent cramplike pains starting from the navel; the
-stomach is hard and contracted; very often vomiting and
-constipation ensue, or, very occasionally, diarrhœa. In some
-cases paralysis shows itself—generally in those muscles which<span class="pagenum"><a name="Page_322" id="Page_322">[322]</a></span>
-extend the fingers, usually affecting both arms. In exceptional
-cases other muscles of the arms and legs are affected.
-Sometimes lead poisoning manifests itself in violent pains in
-the joints—generally the knee, more rarely in the shoulder and
-elbow. In specially severe cases brain trouble supervenes—violent
-headache, convulsions, unconsciousness or blindness.
-Finally lead poisoning may set up disease of the kidneys—Bright’s
-disease and gout.</p>
-
-<p>Women suffering from lead poisoning frequently miscarry.
-Children born alive may, in consequence of lead poisoning,
-die in their first year. Children fed at the breast are poisoned
-through the milk.</p>
-
-<p>Apart from severe cases complicated with brain trouble,
-which are often fatal, persons suffering from lead poisoning
-generally recover if they withdraw from further contact.
-Recovery takes place after a few weeks, but in severe cases
-only after months.</p>
-
-<p>The most effective preventive measures are cleanliness and
-temperance. Persons who, without being drunkards, are
-accustomed to take spirits in quantity are more likely to
-succumb than the abstemious. Spirits should not be taken
-during working hours. In regard to cleanliness, file-cutters
-using lead beds should be especially careful and observe the
-following rules:</p>
-
-<p>1. Since soiling the hands with lead cannot be entirely
-avoided, smoking and chewing tobacco during work should be
-given up.</p>
-
-<p>2. Workers should only take food and drink or leave the
-works after thoroughly washing the hands with soap—if possible
-with pumice stone; if drinking during work cannot be wholly
-given up the edges of the drinking vessels ought not to be
-touched by the hands.</p>
-
-<p>If a file-cutter falls ill in spite of precautions with symptoms
-pointing to lead poisoning he should, in his own and his family’s
-interest, at once consult a doctor, telling him that he has been
-working with a lead bed.</p>
-
-</div>
-
-<h5>Other Industries in which Lead is used</h5>
-
-<p>In cutting <i>precious stones</i> with use of lead discs lead
-poisoning frequently occurs, especially where this trade, as
-in some parts of Bohemia, is carried on as a home industry.
-The authorities have required substitution of carborundum<span class="pagenum"><a name="Page_323" id="Page_323">[323]</a></span>
-(silicon carbide) for lead discs. As, therefore, an efficient
-substitute is possible, use of lead should be prohibited.
-Similarly, use of lead in the making of musical instruments
-should, if possible, be discontinued. Brass pipes in <i>musical
-instrument</i> making are filled with lead to facilitate hammering
-and bending, and in this way poisoning has occurred. In
-numerous other industries where the use of lead cannot be
-avoided, and where consequently the danger must be present,
-as, for instance, in <i>lead melting</i>, <i>soldering</i>, <i>lead rolling</i>,
-<i>stamping</i>, <i>pressing</i>, &amp;c., in the manufacture of <i>lead
-piping</i>, <i>shot</i>, <i>wire</i>, <i>bottle capsules</i>, <i>foil</i>, <i>toys</i>, and many other
-articles, general preventive measures should be carefully
-carried out. <i>Melting of lead</i> and <i>lead alloys</i> should be
-carried out only under efficient exhaust ventilation. In larger
-works where dust is generated this should be drawn away at
-the point where it is produced. This applies also to processes
-in the chemical industries where lead or lead compounds are
-used, seeing that no substitute is possible.</p>
-
-<h4>Zinc, Brass-casting, Metal Pickling, Galvanising</h4>
-
-<p class="center">(See also pp. <a href="#Page_151">151</a> and <a href="#Page_182">182</a>)</p>
-
-<p>In zinc smelting account has to be taken of fumes which
-may contain lead, zinc, arsenic, sulphur dioxide, and carbonic
-oxide. Metallic fumes require to be condensed—a procedure
-in harmony with economic interests. This is effected
-in a technically arranged condensing system, consisting of a
-condenser and prolong, in which the fumes are given as large
-a space as possible in which to condense and cool. In order
-to prevent the entry of fumes into the shed when removing
-distillation residues, hoods should be arranged over the front
-of the furnace through which the gases can be conducted into
-the main chimney stack or be drawn away by a fan; in
-addition the residue should fall into trolleys which must either
-be covered at once or placed under a closely fitting hood
-until the fuming contents are cool. As the mixing of the
-materials for charging and the sifting and packing of the
-zinc dust (poussière) may cause risk, these processes require
-to be carried out mechanically with application of local<span class="pagenum"><a name="Page_324" id="Page_324">[324]</a></span>
-exhaust. Such an arrangement is shown in <a href="#fig59">fig. 59</a> below.
-The material which is fed in is carried by the elevator to the
-sifting machine, falls into the collecting bin, and is then
-packed. The points at which dust can come off are connected
-with the exhaust and carried to the dust collector; fans carry
-the filtered air to the outside atmosphere.</p>
-
-<div class="figcenter" style="width: 500px;" id="fig59">
-
-<img src="images/fig59.jpg" width="500" height="550" alt="" />
-
-<p class="caption"><span class="smcap">Fig. 59.</span>—Arrangement for Sieving and Packing Zinc Dust (poussière).</p>
-
-<p class="caption"><i>a</i> Charging hopper; <i>b</i> Distributor; <i>c</i> Elevator; <i>d</i> Sieve; <i>e</i> Collector; <i>f</i> Packing
-machine; <i>g</i> Exhaust pipe; <i>h</i> Worm; <i>i</i> Dust Collector; <i>k</i> Motor</p>
-
-</div>
-
-<p>Only paragraphs 3-8 of the German Imperial Regulations
-dated February 6, 1900, for Spelter Works are quoted, as the<span class="pagenum"><a name="Page_325" id="Page_325">[325]</a></span>
-remainder are on precisely similar lines to those for lead
-smelting works given in full on p. <a href="#Page_300">300</a>.</p>
-
-<div class="blockquote">
-
-<p>3. Crushing zinc ore shall not be done except in an apparatus
-so arranged as to prevent penetration of dust into the workroom.</p>
-
-<p>4. The roasting furnaces as well as the calcining furnaces
-shall be provided with effective exhaust arrangements for the
-escaping gases. The occupier shall be responsible for their
-efficiency during the time the furnace is at work.</p>
-
-<p>5. To avoid dust, ores intended for charging distillation
-furnaces shall not be stacked in front of or charged into the
-furnace, or mixed with other material, except in a damp condition.</p>
-
-<p>This regulation shall not apply to large so-called Silesian</p>
-
-<p>Retorts when in use in the zinc smelter; yet in the case of them
-also the Higher Authorities may require damping of the charging
-material if specially injurious to health.</p>
-
-<p>6. Dust, gases and vapours escaping from distillation
-furnaces shall be caught as near as possible to the point of origin
-by efficient arrangements and carried out of the smelting rooms.
-The entrance of the gases from the fires into the smelting room
-shall be prevented as far as possible by suitable arrangements
-for drawing them off.</p>
-
-<p>7. Residues shall not be drawn into the smelting room;
-they shall be caught in closed channels under the furnaces and
-emptied from these channels at once into waggons placed in
-passages beneath the distillation rooms.</p>
-
-<p>This regulation (where the Higher Authorities approve)
-shall not apply to existing plants, should it be impossible to
-make the arrangements mentioned in Reg. 1, or where such
-additions could only be added by rebuilding at a prohibitive cost.</p>
-
-<p>8. Sieving and packing of by-products obtained by the
-distillation of zinc (poussière, flue dust) shall not be done except
-in a special room separate from other workrooms, in accordance
-with Reg. 1.</p>
-
-<p>Sieving shall only be done in an apparatus so arranged as to
-prevent escape of dust.</p>
-
-</div>
-
-<p>In <i>brass casting</i>, in order to prevent occurrence of brass-founders’
-ague, it is necessary that the zinc oxide fumes
-evolved should be effectively drawn away from the crucible
-by locally applied exhaust ventilation. General ventilation
-merely of the room is almost useless, as in casting the fumes<span class="pagenum"><a name="Page_326" id="Page_326">[326]</a></span>
-rise up into the face of the pourer. Seeing that casting is
-carried on in different parts of the foundry, it is advisable to
-connect up the hoods over the moulds by means of metal
-piping with the exhaust system, or to arrange a flexible duct
-which can be moved about as occasion requires.</p>
-
-<p>Dangerous acid fumes (notably nitrous fumes) are evolved
-in metal pickling, especially of brass articles (such as harness
-furniture, lamp fittings, church utensils, &amp;c.), for the purpose
-of giving them a shiny or dull surface by immersion in baths
-of nitric, hydrochloric, or sulphuric acid. As severe and even
-fatal poisoning has occurred in these operations they should be
-conducted in isolated compartments or channels under exhaust
-ventilation. If the ventilation provided is mechanical an acid
-proof earthenware fan or an injector is necessary. The following
-description applies to one large works: The pickling
-troughs are placed in a wooden compartment closed in except
-for a small opening in front. To this compartment a stoneware
-pipe leading to a stoneware fan is connected. The nitrous
-fumes are drawn through the pipe and led into the lower part
-of an absorption tower filled with cone-shaped packing material
-through which water trickles from a vessel placed at the top.
-The greater part of the acid fumes are absorbed as they pass
-upwards and the water collects in a receiver below, from which
-it is blown by compressed air into the vessel above for utilisation
-again until it becomes so charged with acid that it can
-be used for pickling purposes.</p>
-
-<p>In <i>galvanising</i> and <i>tinning</i> acid fumes, injurious acroleic
-vapour, and metallic fumes can arise as the metal articles
-(iron, copper, &amp;c.) first require to be cleaned in an acid bath
-and then dipped into molten fat or molten zinc or tin. Here
-also the fumes should be drawn away in the manner described.</p>
-
-<h4>Recovery and Use of Mercury</h4>
-
-<p>Escape of mercury vapour and development of sulphur
-dioxide seriously endanger workers engaged in smelting
-cinnabar. The danger can be minimised by proper construction
-of furnaces preventing escape as far as possible of fumes
-and most careful condensation of the mercury in impervious
-and sufficiently capacious chambers and flues.</p>
-
-<p><span class="pagenum"><a name="Page_327" id="Page_327">[327]</a></span></p>
-
-<p>Continuous furnaces are to be preferred to those working
-intermittently. The system of condensing chambers and
-flues must offer as long a passage as possible to the fumes, and
-care must be taken to keep them thoroughly cool. Removal
-of the deposit rich in mercury from the flues is especially
-fraught with danger. This work should only be carried on
-after efficient watering by workers equipped with respirators,
-working suits, &amp;c.</p>
-
-<p><i>Use of mercury.</i>—Mirror making by coating the glass with
-mercury used to be one of the most dangerous occupations.
-Now that a fully adequate substitute for mercury has
-been found in the nitrate of silver and ammonia process,
-use of mercury should be prohibited. As a home industry
-especially mirror coating with mercury should be suppressed.
-Fortunately the dangerous mode of production is rapidly being
-ousted.</p>
-
-<p>The following requirements are contained in a decree of the
-Prussian Government dated May 18, 1889:</p>
-
-<p>(1) Medical certificate on admission to employment in
-mirror making with use of mercury;</p>
-
-<p>(2) restriction of hours to six in summer and in winter to
-eight daily, with a two hours’ mid-day interval;</p>
-
-<p>(3) fortnightly examination of the workers;</p>
-
-<p>(4) air space per person of 40 cubic meters in the coating
-room and 30 in the drying room, and, in both, introduction
-of 60 cubic meters of air per head per hour;</p>
-
-<p>(5) Work to cease if the temperature of the room in summer
-reaches 25° C.</p>
-
-<p>Measures are necessary to prevent occurrence of mercury
-poisoning in hatters’ furriers’ processes (preparation of rabbit
-fur for felt hats) in consequence of the use of nitrate of mercury.
-Danger arises chiefly in cutting the hair, in dressing and drying,
-in sorting, and also in the subsequent stages of hard felt hat
-manufacture. Aspiration of the dust and fluff at its point of
-generation, isolation of the drying rooms and prohibition of
-entry into them while drying is going on, are necessary. In
-dressing (commonly known as ‘carotting’), the nitric acid
-vapour requires to be drawn away. In addition strict personal
-hygiene, especially of the teeth, is very important. Processes
-involving <i>water gilding</i> (nowadays practised on a very small<span class="pagenum"><a name="Page_328" id="Page_328">[328]</a></span>
-scale) should only be carried on in stoves provided with exhaust
-ventilation. Electroplating, fortunately, has almost entirely
-taken its place.</p>
-
-<p>As cases of mercury poisoning have been reported from use
-of mercurial pumps in producing the vacuum inside <i>electric
-incandescent bulbs</i>, air pumps should be substituted for them
-whenever possible.</p>
-
-<p><i>Barometer</i> and <i>thermometer</i> makers may and do suffer
-severely if care is not taken to draw away the fumes and
-ensure good ventilation of the workrooms. Careless handling
-and the dropping of mercury on the benches make it difficult
-to prevent some volatilisation. Personal hygiene and especially
-a proper hygiene of the mouth are of the greatest importance in
-this class of work.</p>
-
-<p>Preparation of mercury compounds in chemical factories,
-especially the dry processes (sublimation), as in production of
-cinnabar, corrosive sublimate and calomel mixing, grinding,
-and sublimation, require to be carried on in closed apparatus.
-Preparation of the substances named above in solution involves
-much less risk than subliming. From our point of view,
-therefore, the former is to preferred.</p>
-
-<h4>Arsenic, Arsenic Compounds, Arseniuretted Hydrogen</h4>
-
-<p>For arsenic works imperviousness of the system and as
-complete condensation as possible are necessary to prevent
-escape of fumes.</p>
-
-<p>Respirators should be worn in manipulations with white
-arsenic, and such work as packing done under conditions of
-locally applied exhaust ventilation.</p>
-
-<p>Industrial use of arsenic compounds, in view of the risk
-attaching to them, should be reduced as much as possible.
-This has sometimes been achieved by technical improvement
-in processes of manufacture. Thus in the colour industry, where
-formerly colours containing arsenic played an important rôle,
-coal-tar colours have taken their place, and use of arsenic
-even in these (as in the manufacture of fuchsin) has been
-replaced by nitrobenzene.</p>
-
-<p>As the danger from arseniuretted hydrogen gas is especially
-great in processes in which acid acts on metal and either one<span class="pagenum"><a name="Page_329" id="Page_329">[329]</a></span>
-or both of them contain arsenic, the materials, should be as
-free from arsenic as possible, in the production, for example,
-of hydrogen for soldering, in extracting metals by means of
-acids, in galvanic elements, in accumulator works, in the
-storage and transport of acids in metal vessels, and in
-galvanising.</p>
-
-<p>In any case the workers in these industries should be
-warned of the danger and instructed in case of emergencies.
-For soldering exclusive use of hydrogen produced electrolytically
-and procurable in steel cylinders is advisable.</p>
-
-<h4>Extraction and Use of Gold and Silver</h4>
-
-<p>In the extraction of gold and silver by amalgamation and
-subsequent volatilisation of mercury there is risk of mercurial
-poisoning. The preventive measures necessary are similar to
-those for poisoning in the recovery of mercury (see p. <a href="#Page_327">327</a>).</p>
-
-<p><i>Argyria</i> in pearl bead blowers can be avoided by using
-pumps to blow the silver solution into the beads instead of the
-mouth.</p>
-
-<p>In electroplating the possibility of poisonous fumes arising
-from the baths must be guarded against because hydrocyanic
-(prussic) acid, though only in minute quantities, may be
-evolved; care must be taken that the workrooms are well
-ventilated or the baths hooded. Careful personal hygiene is
-essential, for the prevention of skin diseases from which
-workers in electroplating often suffer.</p>
-
-<h3 id="OTHER_TRADES">VII<br />
-<span class="smaller"><i>PREVENTIVE MEASURES IN OTHER TRADES</i></span></h3>
-
-<h4>Ceramic Industry</h4>
-
-<p>In the glass industry use of lead, chrome, and arsenic
-compounds should be restricted as much as possible or allowed
-only under suitable precautions (exhaust ventilation, personal
-hygiene, &amp;c.).</p>
-
-<p><i>Etching on glass</i> by means of hydrofluoric causes almost
-inevitably injury to the workers. Rendering the surface of<span class="pagenum"><a name="Page_330" id="Page_330">[330]</a></span>
-glass opaque should preferably be done by sand blast. When
-a bath of hydrofluoric acid for etching on glass is used the
-fumes require to be drawn away by hoods over the baths
-and the work-rooms well ventilated.</p>
-
-<p>Further precautionary measures are called for in view of
-industrial poisoning by furnace gases in various ceramic
-industries, as, for example, cement works, glass works, and
-tile works.</p>
-
-<p>The following suggestions are made in the technical introduction
-to the Germany Factory Act for prevention of poisoning
-from carbonic oxide, carbon dioxide, and sulphur dioxide:</p>
-
-<p>(1) Even the fixing of benches which might be used for
-sleeping on near the furnaces should be strictly forbidden;</p>
-
-<p>(2) All furnaces which are roofed over should be provided
-with adequate side and roof ventilation;</p>
-
-<p>(3) All gas pipes and cocks must be maintained in an
-impervious condition.</p>
-
-<h4>Manufacture and Use of Varnishes and Drying Oils</h4>
-
-<p>Unpleasant fumes are given off on boiling linseed oil with
-oxidising substances, which should be prevented by closely
-fitting covers and condensation of the fumes in cooling apparatus.
-In heating and dissolving resin for the production of
-varnishes the fumes evolved require to be dealt with in a
-similar way.</p>
-
-<p>Preventive measures must be taken also in the use of
-quick-drying paints on ships and inside steam boilers as, owing
-to the rapid evaporation of the poisonous solvents—benzene,
-benzine and turpentine—fatalities have occurred. As a result
-of elaborate investigation by the inspectors of factories in
-Hamburg the following instructions were issued:</p>
-
-<div class="blockquote">
-
-<p>Quick-drying paint for ships and for preventing rust should
-only be used under the supervision of a person conversant with
-the danger to health and risk from fire.</p>
-
-<p>They should only be allowed for the painting of interior
-surfaces after adoption of adequate precautions—free ventilation,
-use of smoke helmets with air conducting apparatus, and no
-naked lights, &amp;c. Since use of quick-drying paints cannot
-easily be prohibited and the fumes from the substitutes for<span class="pagenum"><a name="Page_331" id="Page_331">[331]</a></span>
-turpentine—benzene and other light tarry oils—exert injurious
-effect on man, precautionary measures are called for. Regulation
-of working hours is as important as provision of
-adequate ventilation. Workers, therefore, should be allowed
-proper intervals from work.</p>
-
-<p>Confined spaces in the interior of ships should be adequately
-ventilated before, after, and during work; all persons
-who use the paints should have opportunity for washing given
-them at their work places, and should be compelled to avail
-themselves of these facilities; indulgence in alcohol and smoking
-should be prohibited; receptacles in which quick-drying paints
-are sold should be provided with an air-tight cover and with a
-warning notice as to the danger of the contents.</p>
-
-<p>Paints made from petroleum fractions of low boiling-point,
-light coal-tar oils, turpentine oil, carbon bisulphide, and
-similar substances, are to be regarded as injurious to health.</p>
-
-<p>Persons under eighteen, and women, should not be allowed
-to work with quick-drying paints.</p>
-
-<p>Obligatory notification of cases of poisoning by hydrocarbons
-and other similar poisonings would have a good effect.</p>
-
-</div>
-
-<p>Schaefer (Inspector of Factories in Hamburg) has drawn
-up the following leaflet for painters, varnishers, workers in
-dry docks, and others engaged in painting with quick drying
-paints and oils:</p>
-
-<div class="blockquote">
-
-<p>All quick-drying paints and oils are more or less injurious
-to health and very inflammable, as they contain volatile substances
-such as benzine (naphtha, petrol ether), benzene, turpentine
-oil, carbon bisulphide, &amp;c. These paints are mostly
-used in painting interiors of ships, boilers, machinery, apparatus,
-&amp;c., and come on the market under various names, such as
-Black Varnish Oil, Solution, Patent Colour, Anti-corrosive,
-Dermatin, Acid-proof Paint, Apexior, Saxol, &amp;c.</p>
-
-<p>Even at ordinary temperatures the volatile fluids used as
-mediums for dry paint powders, or as a first coating, evaporate.
-Air filled with the fumes is not only harmful to health, but
-liable to explosion. Working with these paints and oils in the
-interior of ships, or steam boilers and the like, has repeatedly
-led to explosions and fatal poisoning.</p>
-
-<p><i>Danger of Poisoning.</i>—All persons are exposed to the danger
-of poisoning who use quick-drying paints in the interior of
-rooms or receptacles, or otherwise manipulate the paints. The
-warmer the room and the less ventilation there is before and<span class="pagenum"><a name="Page_332" id="Page_332">[332]</a></span>
-during the painting, the greater the danger of poisoning. On
-the other hand, use of these paints in the open air is generally
-without effect.</p>
-
-<p>Poisoning arises from inhaling the fumes of hydrocarbons.
-The symptoms are oppression, headache, inclination to vomit,
-cough, hiccough, giddiness, noises in the ears, drunken-like
-excitement, trembling and twitching. Inhalation of larger
-quantities brings on, quite suddenly and without previous
-warning, unconsciousness, which may last many hours and is
-often fatal. Except in severe cases the symptoms generally
-soon disappear, if the affected person withdraws from further
-contact with the fumes. The most effective protection therefore
-against poisoning is fresh air and temperance. In so far
-as painting with quick-drying materials is necessary in workrooms,
-interiors of ships, water and ballast tanks, double bottoms,
-bunkers, bilges, cabins, boilers and receptacles, care must be
-taken to ensure thorough ventilation before, after, and while
-the work is going on. Where no sufficient ventilation is possible
-these paints ought not to be used. Frequent intermission of
-work by a short stay in the open air is useful. When working
-in spaces not easily accessible, the worker should be roped.</p>
-
-<p>Speaking, singing, or whistling during work favours inhalation
-of the fumes and is, therefore, to be avoided. Indulgence
-in spirits, especially during working hours, increases the danger
-of poisoning. Habitual drinkers should not be allowed to work
-at all with quick-drying paints and oils.</p>
-
-<p>At the first signs of discomfort work should be stopped.
-An immediate stay in the open air will then usually dispel the
-poisonous symptoms.</p>
-
-<p>If, notwithstanding this, severe symptoms develop, oxygen
-inhalation should be commenced forthwith and medical aid
-called in.</p>
-
-</div>
-
-<h4>Production of Vegetable Foods and Luxuries</h4>
-
-<p class="center">(See also p. <a href="#Page_154">154</a>)</p>
-
-<p>Measures for the prevention of industrial poisoning have to
-be thought of in connection with drying processes (by smoke
-gases, carbon dioxide, and carbonic oxide), many processes
-of preserving (use of sulphur dioxide, &amp;c.), and fermentation
-(accumulation of carbonic acid).</p>
-
-<p>In breweries the use of kilns allowing fire gases to<span class="pagenum"><a name="Page_333" id="Page_333">[333]</a></span>
-enter the drying-rooms formerly caused carbonic oxide and
-carbonic acid poisoning. The general introduction of hot
-air kilns provided with mechanical malt-turning apparatus
-should be insisted on, and is in keeping with progress in technical
-methods.</p>
-
-<p>The accumulation of carbonic acid in the malting cellars
-can be prevented in the same way as in a distillery.</p>
-
-<p>If ammonia is used for <i>refrigeration</i>, precautions are
-necessary so that, in the event of leakage or bursting of pipes,
-the workers may escape. Naturally the imperviousness of
-the freezing system must be guaranteed.</p>
-
-<p>Oppression and danger to the health of the workers is
-occasionally caused by the development of gases in the coating
-of barrels with pitch, partly preventable by the use of pitching
-machines.</p>
-
-<p>In the production of <i>spirits</i> carbonic acid poisoning can
-occur from accumulation of carbonic acid in the fermentation
-cellars. These should be thoroughly ventilated and in view
-of the heaviness of the gas, openings for ventilation should
-always be located at the floor level.</p>
-
-<p>In the <i>sulphuring of malt</i> the following recommendations
-were made by the Austrian inspectors:</p>
-
-<p>During the sulphuring process the room ought not to be
-entered (for the turning over of the malt). When the sulphur
-has been burnt, the drying-room must be ventilated from the
-outside, by opening the windows and letting in cold currents
-of air, until the sulphur dioxide has completely dispersed,
-which can be tested by holding a strip of moistened blue
-litmus paper at the half-opened door. If it does not turn
-red, turning over of the malt may be proceeded with.</p>
-
-<p>As the <i>sulphuring of hops</i> in hop districts is done in primitive
-little kilns, in which the hops are spread out on a kind of gridiron
-and sulphur burnt below in iron pans, development of sulphur
-dioxide may affect the workers. The following regulations are
-therefore suggested for work in these kilns:</p>
-
-<div class="blockquote">
-
-<p>The rooms in which sulphuring takes place must be airtight,
-capable of being locked, and provided with arrangements which
-make it possible to remove the sulphur dioxide fumes before
-the room is entered. This can usually be done by a strong<span class="pagenum"><a name="Page_334" id="Page_334">[334]</a></span>
-coke fire, maintained in the chimney place, which creates the
-necessary draught. If fans are used, it must be remembered
-that iron is affected and destroyed by acid gases; stoneware
-fans are therefore advisable.</p>
-
-</div>
-
-<p>In the production of <i>vinegar</i>, air escapes laden with acetic
-acid vapour, alcohol, lower oxidation products of alcohol,
-aldehyde, acetic ether, &amp;c. Their escape can be avoided if
-the whole process is carried on in a closed self-acting apparatus
-with the advantage also that no loss occurs.</p>
-
-<p>In premises for <i>drying agricultural products</i> (fruit, chicory,
-turnips) the persons employed in the drying-room are exposed
-to the danger of carbonic oxide poisoning from direct firing.</p>
-
-<p>The following recommendations for work in drying-rooms
-with direct firing are taken from an Austrian decree of 1901:</p>
-
-<div class="blockquote">
-
-<p>The lower drying chambers, in which the real drying process
-is effected, should be so arranged that the objects dried in them
-can be removed by means of long-handled implements through
-a passage shut off from the drying-room. The separation of
-this passage can be effected by loose tin plates which can be
-removed as required for the work of turning or removal of the
-dried products, so that the worker need not come into contact
-with the gases.</p>
-
-<p>Open fires should be so arranged that if required they can
-be shut off, by simple arrangements, from the drying-rooms
-in which the workers are temporarily occupied in carrying in,
-and turning, the objects to be dried, transferring the partly
-dried products to hotter hurdles, and emptying them when
-finished, in such a way that the entrance of combustion gases
-into the drying chambers can be completely prevented. In
-order, however, to prevent a back draught, arrangements must
-be made for simultaneous removal of the gases by pipes
-connected with a chimney or smoke flue. The places from
-which the fires are charged should, in addition, be furnished
-with suitably arranged openings for ventilation leading into
-the outer air, in order to neutralise, in case of need, any back
-draught from the furnaces into the rooms.</p>
-
-<p>The windows of the drying chambers should be so arranged
-as to open both from within and without.</p>
-
-<p>The floor of the roof space, or attic, which forms at the same
-time the ceiling of the upper drying-room, should be kept
-perfectly airtight, as also the openings into it through which<span class="pagenum"><a name="Page_335" id="Page_335">[335]</a></span>
-the steam pipes pass. For this purpose the floor should be a
-double one and the openings or boxes into which material is
-thrown should have a double cover above and below. Further,
-situated in the highest point of the ceiling of the roof space,
-there should be a suitable number of openings topped by
-louvred turrets. In the roof space no work should be done
-except manipulations necessary for the charging of the hurdles
-with the goods to be dried. Use of the roof floor as a sleeping
-or living room is not permissible.</p>
-
-<p>Before the workers enter the drying chambers for the purpose
-of turning the materials, the stove should be shut off, the gases
-drawn from the furnace into the chimney or flue, and at the
-same time the doors and windows of the drying rooms opened.</p>
-
-<p>Entering of drying chambers for working purposes should
-only be done after a sufficient time has elapsed for removal of
-the air by ventilation.</p>
-
-<p>Charging of the furnaces should be so arranged that they
-burn as low as possible before the removal of the dried
-materials and before subsequent work in the drying chambers.
-Seeing that chicory and turnip drying is done intermittently
-by night, a special sleeping or waiting room with free ventilation
-should be provided. The regulations concerning the ventilation
-of the workrooms are to be made known to the workers.</p>
-
-</div>
-
-<h4>Cigar Industry</h4>
-
-<p>In order to prevent injury to health to tobacco workers
-the dust and fumes, especially at cutting and sifting machines,
-require to be drawn away by locally applied exhaust ventilation.
-The workrooms, moreover, must conform to hygienic
-requirements, especially as to cleanliness. Washing accommodation
-and baths are desirable, but are only likely to be
-provided in large works.</p>
-
-<h4>Wood Working</h4>
-
-<p class="center">(See also p. <a href="#Page_154">154</a>)</p>
-
-<p>Risk from poisonous woods can be avoided by exhaust
-ventilation applied to the wood-working machinery.</p>
-
-<p>To lessen the danger to health in the use of methylated
-spirits in the polishing of wood adequate ventilation of the<span class="pagenum"><a name="Page_336" id="Page_336">[336]</a></span>
-workrooms is necessary; drawing off the fumes by local
-ventilation is often impossible.</p>
-
-<h4>Production of Wood-pulp (Cellulose) and Paper.</h4>
-
-<p>In the <i>sulphite cellulose</i> process, sulphur dioxide may
-escape from the sulphur stoves or from the boilers; escape
-of sulphur dioxide is also possible through defective gas pipes
-and condensers. Gas pipes and condensers require to be
-quite impervious and condensation or absorption as complete
-as possible. The fumes escaping from the boilers should
-be led through pipes into closed boilers for condensation
-purposes; the gases not condensed here are to be led into
-absorption towers.</p>
-
-<p>In the manufacture of <i>paper</i> with use of chloride of lime
-for bleaching chlorine can be given off in considerable quantity,
-requiring removal of the gases from the apparatus.</p>
-
-<p>The use of poisonous colours containing lead or arsenic,
-and addition of lead-containing substances to the paper pulp,
-is now very rare.</p>
-
-<h4>Textile Industries.</h4>
-
-<p class="center">(See also p. <a href="#Page_156">156</a>)</p>
-
-<p>In the textile industry only a few manipulations are associated
-with serious risk of poisoning. Those engaged in
-carbonising are exposed to acid fumes; closed and ventilated
-apparatus, therefore, as far as possible, require to be used
-and the acid gases escaping from them should be absorbed.
-These requirements are fulfilled by carbonising stoves which
-are ventilated and connected with coke condensers. It is
-especially urged that only arsenic free acid be employed, as
-otherwise danger of poisoning by arseniuretted hydrogen may
-be incurred.</p>
-
-<p>In the making of <i>artificial silk</i>, according to the Chardonnet-Cadoret
-process, the precautionary measures recommended in
-nitrating together with careful exhaustion of the ether and
-camphor fumes apply.</p>
-
-<p>The combustion gases (containing carbonic oxide) developed<span class="pagenum"><a name="Page_337" id="Page_337">[337]</a></span>
-in the process of singeing are harmful and require
-to be led away at their source.</p>
-
-<p>Poisonous metallic salts, especially lead and lead-containing
-zinc, are used as weighting materials, in dressing or
-finishing, and sometimes cause symptoms among the workers.
-Apart from the danger to those occupied in spinning and
-weaving, the workers who handle these products (in the
-clothing trade) also run a risk from lead.</p>
-
-<p>Precautionary measures are necessary in the <i>varnishing of
-woven materials</i>, as the substances employed may contain
-volatile poisonous solvents. If these poisonous solvents
-cannot be replaced by others less poisonous, carefully applied
-exhaust ventilation must be provided. The same holds good
-when carbon bisulphide, benzene, and benzine are used as
-solvents in the production of woven materials impregnated
-with indiarubber.</p>
-
-<p>Employment of lead salts and other poisonous metallic
-salts in the glossing of woven materials, or in order to render
-them non-inflammable, is to be deprecated.</p>
-
-<p>Cases of lead poisoning have occurred in the working-up
-of asbestos, as lead wire is sometimes used in the process
-of weaving.</p>
-
-<p>To protect workers in <i>chlorine</i> and <i>sulphur bleaching</i> from
-poisoning by chlorine or sulphur dioxide the gases arising
-from the bleaching liquids should be drawn away. Use
-of closed bleaching apparatus, as is the case in large
-works, reduces the danger to a minimum. Bleaching-rooms
-should be connected with a powerful stoneware fan, so that
-they may be thoroughly aired before they are entered.</p>
-
-<h4>Dye Works</h4>
-
-<p>Industrial poisoning by dyes is, in general, rare, as the
-natural dyes (wood and tar dyes) are almost without
-exception non-poisonous. Further, the dyes are generally
-only used in diluted solution. Formerly the arsenic in many
-tar dyes caused poisoning, but now it is usually the
-mordants which have harmful effect. To this class belong
-chromic acid salts and mordants containing arsenic, antimony
-(tartar-emetic), and also chloride of tin. In the<span class="pagenum"><a name="Page_338" id="Page_338">[338]</a></span>
-scraping off of layers of paint containing arsenic, arsenic
-dust may arise. In Turkey red dyeworks, especially sodium
-arsenite is used for fixing the tar dyes.</p>
-
-<p>Orpiment dyes which may give off poisonous arseniuretted
-hydrogen gas are becoming less and less used; from the
-point of view of industrial hygiene, the utmost possible
-avoidance of the use of arsenic-containing preparations in
-dye works is to be recommended. Where this is not possible,
-strict personal hygiene must be enforced (as, for instance,
-application of vaseline to the skin).</p>
-
-<hr />
-
-<div class="footnotes">
-
-<h2>FOOTNOTES</h2>
-
-<div class="footnote">
-
-<p><a name="Footnote_1" id="Footnote_1"></a><a href="#FNanchor_1"><span class="label">[A]</span></a> Leymann has dealt with the conditions of health in a large aniline factory
-in a later work which is referred to in detail in the section on the aniline
-industry.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a name="Footnote_2" id="Footnote_2"></a><a href="#FNanchor_2"><span class="label">[B]</span></a> Poisoning by lead, phosphorus, and arsenic contracted in a factory or
-Workshop has been notifiable in Great Britain and Ireland since 1895.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a name="Footnote_3" id="Footnote_3"></a><a href="#FNanchor_3"><span class="label">[C]</span></a> ‘On the Nature, Uses, and Manufacture of Ferro-silicon,’ 1909, Cd. 4958.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a name="Footnote_4" id="Footnote_4"></a><a href="#FNanchor_4"><span class="label">[D]</span></a> In Great Britain section 73 of the Factory and Workshop Act, 1901, requires
-every medical practitioner attending on or called in to visit a patient whom he
-believes to be suffering from lead, phosphorus, arsenical or mercurial poisoning, or
-anthrax, contracted in any factory or workshop, to notify the Chief Inspector of
-Factories, and a similar obligation is placed on the occupier to send written notice
-of every case to the inspector and certifying surgeon of the district.</p>
-
-<p>The table on p. <a href="#Page_222">222</a> shows the number of reports included in returns for the
-years 1900-12.</p>
-
-<p>Cases of acute poisoning in factories and workshops are reportable to the
-Inspector and certifying surgeon, under the Notice of Accidents Act, 1906, when
-(<i>a</i>) causing loss of life or (<i>b</i>) due to molten metal, hot liquid, explosion, <i>escape of
-gas</i> or steam, and so disabling any person as to cause absence throughout at least
-one whole day from his ordinary work.</p>
-
-<p>The following table gives indication of the relative frequency of cases of
-poisoning from gases and fumes, although some were reported as accidents the
-result of the unconsciousness induced:</p>
-
-<table summary="Yearly frequency of cases of poisoning from gases and fumes" class="borders">
-  <tr>
-    <th>Nature of Gas or Fumes.<br />(1)</th>
-    <th colspan="2">1912.<br />(2)</th>
-    <th colspan="2">1911.<br />(3)</th>
-    <th colspan="2">1910.<br />(4)</th>
-    <th colspan="2">1909.<br />(5)</th>
-    <th colspan="2">1908.<br />(6)</th>
-  </tr>
-  <tr>
-    <td>Carbon monoxide</td>
-    <td class="tdr nbr">91</td>
-    <td class="tdr nbl"><span class="smaller">14</span></td>
-    <td class="tdr nbr">64</td>
-    <td class="tdr nbl"><span class="smaller">6</span></td>
-    <td class="tdr nbr">53</td>
-    <td class="tdr nbl"><span class="smaller">9</span></td>
-    <td class="tdr nbr">53</td>
-    <td class="tdr nbl"><span class="smaller">6</span></td>
-    <td class="tdr nbr">55</td>
-    <td class="tdr nbl"><span class="smaller">5</span></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">(<i>a</i>) Blast furnace</td>
-    <td class="tdr nbr">33</td>
-    <td class="tdr nbl"><span class="smaller">5</span></td>
-    <td class="tdr nbr">16</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">19</td>
-    <td class="tdr nbl"><span class="smaller">7</span></td>
-    <td class="tdr nbr">16</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">26</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">(<i>b</i>) Power (suction, producer, Mond, Dowson).</td>
-    <td class="tdr nbr">19</td>
-    <td class="tdr nbl"><span class="smaller">4</span></td>
-    <td class="tdr nbr">31</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">25</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">25</td>
-    <td class="tdr nbl"><span class="smaller">4</span></td>
-    <td class="tdr nbr">19</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">(<i>c</i>) Coal</td>
-    <td class="tdr nbr">29</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">6</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">4</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">11</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">9</td>
-    <td class="tdr nbl"></td>
-  </tr>
-  <tr>
-    <td class="tdsub1">(<i>d</i>) Other</td>
-    <td class="tdr nbr">10</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-    <td class="tdr nbr">11</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">5</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">1</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">1</td>
-    <td class="tdr nbl"></td>
-  </tr>
-  <tr>
-    <td>Sulphuretted hydrogen</td>
-    <td class="tdr nbr">6</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">8</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">2</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">5</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">8</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-  </tr>
-  <tr>
-    <td>Carbon dioxide</td>
-    <td class="tdr nbr">3</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">1</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">2</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">2</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">4</td>
-    <td class="tdr nbl"><span class="smaller">3</span></td>
-  </tr>
-  <tr>
-    <td>Ammonia</td>
-    <td class="tdr nbr">1</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">1</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">2</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">1</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">1</td>
-    <td class="tdr nbl"></td>
-  </tr>
-  <tr>
-    <td>Chlorine and hydrochloric acid fumes</td>
-    <td class="tdr nbr">3</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">5</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">3</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">1</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">1</td>
-    <td class="tdr nbl"></td>
-  </tr>
-  <tr>
-    <td>Nitrous fumes</td>
-    <td class="tdr nbr">12</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">18</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">11</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">12</td>
-    <td class="tdr nbl"><span class="smaller">2</span></td>
-    <td class="tdr nbr">3</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-  </tr>
-  <tr>
-    <td>Nitro and amido derivatives of benzene</td>
-    <td class="tdr nbr">9</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">21</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">18</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">4</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">2</td>
-    <td class="tdr nbl"></td>
-  </tr>
-  <tr>
-    <td>Naphtha and benzene</td>
-    <td class="tdr nbr">3</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">1</td>
-    <td class="tdr nbl"><span class="smaller">1</span></td>
-    <td class="tdr nbr">—</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">11</td>
-    <td class="tdr nbl"></td>
-    <td class="tdr nbr">2</td>
-    <td class="tdr nbl"></td>
-  </tr>
-  <tr>
-    <td class="bb">Other (Sulphur dioxide, &amp;c.)</td>
-    <td class="tdr bb nbr">7</td>
-    <td class="tdr bb nbl"><span class="smaller">2</span></td>
-    <td class="tdr bb nbr">4</td>
-    <td class="tdr bb nbl"></td>
-    <td class="tdr bb nbr">4</td>
-    <td class="tdr bb nbl"></td>
-    <td class="tdr bb nbr">4</td>
-    <td class="tdr bb nbl"></td>
-    <td class="tdr bb nbr">3</td>
-    <td class="tdr bb nbl"></td>
-  </tr>
-</table>
-
-<p>The principal figures are those of all cases, fatal and non-fatal; the small figures relate to fatal
-cases.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a name="Footnote_5" id="Footnote_5"></a><a href="#FNanchor_5"><span class="label">[E]</span></a> The principal numbers relate to cases, the small figures to deaths. Fatal cases not reported in previous years are included as both cases and deaths.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a name="Footnote_6" id="Footnote_6"></a><a href="#FNanchor_6"><span class="label">[F]</span></a> Fischer adopts a chemical basis in his classification. His two main subdivisions
-are (1) inorganic and (2) organic poisons. The sub-divisions of the
-inorganic poisons are (<i>a</i>) non-metallic—chlorine, calcium chloride, hydrochloric
-acid, potassium chlorate, hydrofluoric acid, carbonic oxide, phosgene, carbon
-dioxide, cyanogen compounds, ammonia, nitrous fumes, phosphorus, phosphoretted
-hydrogen, arsenic compounds, antimony compounds, sulphur dioxide, sulphuric
-acid, sulphuretted hydrogen, carbon bisulphide, chloride of sulphur; and (<i>b</i>)
-metallic—chromic acid and chromates, manganese dioxide, sulphate of nickel,
-mercury and lead. The sub-divisions of (2) the organic substances are into (<i>a</i>) the
-unsaturated carbon compounds—benzene, petroleum, methyl-, ethyl-, amyl-, and
-allyl-alcohol, oxalic acid, formal- and acetaldehyde, acrolein, acetone, methyl-bromide
-and iodide, nitro-glycerin, dimethyl-sulphate and amyl acetate, and (<i>b</i>) the
-aromatic series benzene, nitro-, chloro-nitro-, dinitro-, chloro-dinitro-benzene,
-phenol, picric acid, phenyl-hydrazine, aniline, and certain aniline colours, para-nitraniline,
-pyridine, naphthalene, nitro-naphthalene, naphthlyamine, naphthol,
-benzidine, acridine, turpentine, and nicotine.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a name="Footnote_7" id="Footnote_7"></a><a href="#FNanchor_7"><span class="label">[G]</span></a> A Prussian Ministerial Decree, dated March 31, 1892, deals with the preparation
-of nitrate of mercury.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a name="Footnote_8" id="Footnote_8"></a><a href="#FNanchor_8"><span class="label">[H]</span></a> In Great Britain and Ireland the White Phosphorus Matches Prohibition
-Act became operative from January 1, 1910. In the United States of America
-a Prohibition Act became operative on July 1, 1913.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a name="Footnote_9" id="Footnote_9"></a><a href="#FNanchor_9"><span class="label">[I]</span></a> Reprinted by permission of the Controller of H.M. Stationery Office.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a name="Footnote_10" id="Footnote_10"></a><a href="#FNanchor_10"><span class="label">[J]</span></a> <i>Use of Oxygen Cylinder.</i>—Open the valve gradually by tapping the
-lever key (which must first be extended to its full length) with the wrist,
-until the oxygen flows in a gentle stream from the mouthpiece into the patient’s
-mouth. The lips should not be closed round the mouthpiece. The nostrils
-should be closed during breathing in, and opened during breathing out.</p>
-
-<p>If the teeth are set, close the lips and one nostril. Let the conical end of
-the mouthpiece slightly enter the other nostril during breathing in, and
-remove it for breathing out.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a name="Footnote_11" id="Footnote_11"></a><a href="#FNanchor_11"><span class="label">[K]</span></a> The suggested regulations made after his inquiry (see p. 149) by Dr. Copeman
-are:</p>
-
-<p>1. Ferro-silicon should not be sent out from the works immediately after
-manufacture, but after being broken up into pieces of the size in which it is usually
-sold, should be stored under cover, but exposed to the air as completely as possible,
-for at least a month before being despatched from the works.</p>
-
-<p>2. Manufacturers should be required to mark in bold letters each barrel or other
-parcel of ferro-silicon with the name and percentage grade (certified by chemical
-analysis) of the material; the name of the works where it is produced; the date of
-manufacture; and date of despatch.</p>
-
-<p>3. The carriage of ferro-silicon on vessels carrying passengers should be prohibited.
-When carried on cargo boats it should, if circumstances permit, be stored
-on deck. If it be considered necessary to store it elsewhere, the place of storage
-should be capable of being adequately ventilated, and such place of storage should
-be cut off by airtight bulkheads from the quarters occupied by the crew of the
-vessel.</p>
-
-<p>4. This regulation should apply to the transport of ferro-silicon on river or
-canal barges as well as on sea-going vessels.</p>
-
-<p>5. Storage places at docks or at works where ferro-silicon is used should have
-provision for free access of air, and should be situated at a distance from work-rooms,
-mess-rooms, offices, &amp;c.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a name="Footnote_12" id="Footnote_12"></a><a href="#FNanchor_12"><span class="label">[L]</span></a> Regulations 5-7 contain precautions to be observed in the corroding
-chambers.</p>
-
-</div>
-
-</div>
-
-<hr />
-
-<p><span class="pagenum"><a name="Page_339" id="Page_339">[339]</a></span></p>
-
-<h2 id="APPENDIX">APPENDIX<br />
-<span class="smaller">REFERENCES</span></h2>
-
-<h3>PART I<br />
-<span class="smcap">Processes of Manufacture and Instances of Poisoning</span></h3>
-
-<h4><span class="smcap">General Survey of Poisoning in Chemical
-Industries</span></h4>
-
-<p><a href="#endnote-ref1"><span class="endnote-marker"
-id="endnote1">1</span></a> Leymann, <i>Concordia</i>, 1906, Nos. 7,
-8 and 9; <a href="#endnote-ref2"><span class="endnote-marker"
-id="endnote2">2</span></a> Grandhomme, <i>Die Fabriken der Farbwerke zu
-Höchst a. M.</i>, Verlag Mahlau, 4th edition.</p>
-
-<h4><span class="smcap">Sulphuric Acid Industry</span></h4>
-
-<p><a href="#endnote-ref3"><span class="endnote-marker"
-id="endnote3">1</span></a> <i>Zeitschr. für. Gewerbe-Hygiene</i>, 1907,
-p. 230; <a href="#endnote-ref4"><span class="endnote-marker"
-id="endnote4">2</span></a> Bath, <i>Zeitschr. f. Angew. Chemie</i>, 1896, p.
-477.</p>
-
-<h4><span class="smcap">Hydrochloric Acid and Saltcake
-Manufacture</span></h4>
-
-<p><a href="#endnote-ref5"><span class="endnote-marker"
-id="endnote5">1</span></a> <i>Zeitschr. f. Gewerbe-Hygiene</i>, 1906,
-p. 562; <a href="#endnote-ref6"><span class="endnote-marker"
-id="endnote6">2</span></a> <i>Zeitschr. f. Gew.-Hyg.</i> 1902, p.
-62; <a href="#endnote-ref7"><span class="endnote-marker"
-id="endnote7">3</span></a> Walther in Weyl’s <i>Arbeiterkrank-keiten</i>, p.
-666.</p>
-
-<h4><span class="smcap">Chlorine and Bleaching Powder</span></h4>
-
-<p><a href="#endnote-ref8"><span class="endnote-marker"
-id="endnote8">1</span></a> <i>Zeitschr. für. Gew.-Hyg.</i>, 1906,
-p. 280; <a href="#endnote-ref9"><span class="endnote-marker"
-id="endnote9">2</span></a> <i>Concordia</i>, 1906, No. 8;
-<a href="#endnote-ref10"><span class="endnote-marker"
-id="endnote10">3</span></a> <i>Arch. f. Hyg.</i>, vol. 46, p.
-322; <a href="#endnote-ref11"><span class="endnote-marker"
-id="endnote11">4</span></a> Egli, <i>Unf. b. Chem. Arb.</i>,
-Zurich, 1902, p. 40; <a href="#endnote-ref12"><span
-class="endnote-marker" id="endnote12">5</span></a> Vaubel,
-<i>Chemiker Zeitung</i>, 1903; <a href="#endnote-ref13"><span
-class="endnote-marker" id="endnote13">6</span></a> <i>Concordia</i>,
-1907, No. 7; <a href="#endnote-ref14"><span class="endnote-marker"
-id="endnote14">7</span></a> Rumpf, <i>D. Med. Wochenschr.</i>, 1908, vol.
-34, p. 1331; <a href="#endnote-ref15"><span class="endnote-marker"
-id="endnote15">8</span></a> Müller, <i>Vierteljahrsschr. f. Ger.
-Med. ü öffentl. Sanitätsw.</i>, vol. ix., p. 381; and Roth, <i>Komp.
-d. Gewerbekrankh</i>, p. 205; <a href="#endnote-ref16"><span
-class="endnote-marker" id="endnote16">9</span></a> Klocke-Bochum,
-<i>Zeitschr. f. Gew.-Hyg.</i>, 1906, p. 563; <a href="#endnote-ref17"><span
-class="endnote-marker" id="endnote17">10</span></a> Sury
-Bienz, <i>Vierteljahrsschr. f. Ger. Med.</i>, 1907, vol. 34, p.
-251; <a href="#endnote-ref18"><span class="endnote-marker"
-id="endnote18">11</span></a> Erben, <i>Handb. d. ärztl. Sachverst</i>,
-1910, vol. ii. p. 266; <a href="#endnote-ref19"><span
-class="endnote-marker" id="endnote19">12</span></a> <i>Concordia</i>,
-1902, No. 5., and <i>Vierteljahrsschr. f. öff. Ges. Pfl.</i>, 1902,
-Suppl. p. 371; <a href="#endnote-ref20"><span class="endnote-marker"
-id="endnote20">13</span></a> Mohr, <i>D. Med. Wochenschr</i>., 1902, vol.
-28, p. 73; <a href="#endnote-ref21"><span class="endnote-marker"
-id="endnote21">14</span></a> ‘Über Chlorakne,’ <i>Archiv. f.
-Dermatol.</i>, 1905, vol. 77, p. 323; <a href="#endnote-ref22"><span
-class="endnote-marker" id="endnote22">15</span></a> Dammer, <i>Handb.
-d. Arb. Wohlf.</i>, vol. i. p. 433; <a href="#endnote-ref23"><span
-class="endnote-marker" id="endnote23">16</span></a> <i>D. Arch. f.
-Klin. Med.</i>, 1901, vol. 71, p. 370; <a href="#endnote-ref24"><span
-class="endnote-marker" id="endnote24">17</span></a> Schuler,
-<i>D. Vierteljahrsschr. f. öffentl. Ges. Pfl.</i>, vol. 31, p.
-696; <a href="#endnote-ref25"><span class="endnote-marker"
-id="endnote25">18</span></a> Egli, <i>Unf. b. Chem. Arb.</i>, Zurich, 1902,
-pp. 22, 45; <a href="#endnote-ref26"><span class="endnote-marker"
-id="endnote26">19</span></a> Rambousek, <i>Concordia</i>, 1910, No. 6.</p>
-
-<p><span class="pagenum"><a name="Page_340" id="Page_340">[340]</a></span></p>
-
-<h4><span class="smcap">Manufacture and Use of Nitric Acid and its
-Compounds</span></h4>
-
-<p><a href="#endnote-ref27"><span class="endnote-marker"
-id="endnote27">1</span></a> Schmitz, <i>Berl. Klin. Wochenschr.</i>, 1884,
-vol. 21, p. 428, and Becker, <i>Aerztl. Sachv. Ztg.</i>, 1899, vol.
-v. p. 277; <a href="#endnote-ref28"><span class="endnote-marker"
-id="endnote28">2</span></a> <i>Concordia</i>, 1908, No. 23, p.
-498; <a href="#endnote-ref29"><span class="endnote-marker"
-id="endnote29">3</span></a> Schmieden, <i>Zentralbl. f. Klin. Med.</i>,
-1892, No. 11; Kockel, <i>Vierteljahrsschr. f. Ger. Med.</i>, 1898,
-vol. 15; <a href="#endnote-ref30"><span class="endnote-marker"
-id="endnote30">4</span></a> Egli, <i>Unf. b. chem. arb.</i>, 1903,
-p. 52; <a href="#endnote-ref31"><span class="endnote-marker"
-id="endnote31">5</span></a> <i>Chem. Industrie</i>, 1905, p.
-444; <a href="#endnote-ref32"><span class="endnote-marker"
-id="endnote32">6</span></a> <i>Chem. Industrie</i>, 1905, p.
-445; <a href="#endnote-ref33"><span class="endnote-marker"
-id="endnote33">7</span></a> <i>Berl. Klin. Wochenschr.</i>, 1886, vol.
-23, p. 417; <a href="#endnote-ref34"><span class="endnote-marker"
-id="endnote34">8</span></a> <i>Komp. d. Gewerbekrankheiten</i>, p.
-62; <a href="#endnote-ref35"><span class="endnote-marker"
-id="endnote35">9</span></a> <i>Intern. Uebers. über Gew.-Hyg.</i>, 1907, p.
-76.</p>
-
-<h4><span class="smcap">Phosphorus and Lucifer Match
-Manufacture</span></h4>
-
-<p><a href="#endnote-ref36"><span class="endnote-marker"
-id="endnote36">1</span></a> <i>Die Phosphornekrose, ihre Verbreitung
-in Oesterreich</i>, Wien, 1907; <a href="#endnote-ref37"><span
-class="endnote-marker" id="endnote37">2</span></a> Friedrichs,
-in <i>Arb. d. Ung. Ver. f. ges. Arbeiterschutz</i> 1908, vol. 4, pp.
-1-176; <a href="#endnote-ref38"><span class="endnote-marker"
-id="endnote38">3</span></a> v. Jaksch, <i>Handb. d. ärztl. Sachv.-Tät.</i>,
-1909, vol. 7, p. 239; and Lévai, <i>W. Klin. Rundsch.</i>, 1900,
-vol. 14, p. 33, and Dearden, <i>Brit. Med. Journ.</i>, 1899, vol. 1,
-p. 92; <a href="#endnote-ref39"><span class="endnote-marker"
-id="endnote39">4</span></a> Wodtke, <i>Vierteljahrsschr. f. ger. Med. und
-öffentl. Sanitätsw.</i>, vol. 18, p. 325.</p>
-
-<h4><span class="smcap">Chromium Compounds</span></h4>
-
-<p><a href="#endnote-ref40"><span class="endnote-marker"
-id="endnote40">1</span></a> Hermanni, <i>Münch med. Wochenschr.</i>, 1901,
-No. 14, and Wodtke, <i>loc. cit.</i>, p. 325; <a href="#endnote-ref41"><span
-class="endnote-marker" id="endnote41">2</span></a> <i>Zeitschr.
-f. Gew.-Hyg.</i>, 1908, p. 161; <a href="#endnote-ref42"><span
-class="endnote-marker" id="endnote42">3</span></a> Wutzdorff und Heise,
-<i>Arb. a. d. Kais. Ges. Amt.</i>, vol. xiii.; <a href="#endnote-ref43"><span
-class="endnote-marker" id="endnote43">4</span></a> <i>Zeitschr. f. öffentl.
-Ges. Pfl.</i>, 1894; <a href="#endnote-ref44"><span class="endnote-marker"
-id="endnote44">5</span></a> Burns, <i>Ann. Rept. of C. I. of F.</i>,
-1903; <a href="#endnote-ref45"><span class="endnote-marker"
-id="endnote45">6</span></a> Neisser, <i>Intern. Uebers. über Gew.-Hyg.</i>,
-1907, p. 92.</p>
-
-<h4><span class="smcap">Manganese Compounds</span></h4>
-
-<p><a href="#endnote-ref46"><span class="endnote-marker"
-id="endnote46">1</span></a> Couper, <i>Journ. de Chimie</i>, vol. 3,
-series ii.; <a href="#endnote-ref47"><span class="endnote-marker"
-id="endnote47">2</span></a> <i>Münch. med. Wochenschr.</i>, 1901,
-p. 412; <a href="#endnote-ref48"><span class="endnote-marker"
-id="endnote48">3</span></a> Embden, <i>D. med. Wochenschr.</i>, vol. 27, p.
-795.</p>
-
-<h4><span class="smcap">Petroleum and Benzine Industry</span></h4>
-
-<p><a href="#endnote-ref49"><span class="endnote-marker"
-id="endnote49">1</span></a> Berthenson, <i>D. Vierteljahrsschr. f. öffentl.
-ges.-Pfl.</i>, 1898, vol. 30, p. 315; <a href="#endnote-ref50"><span
-class="endnote-marker" id="endnote50">2</span></a> <i>Virchow’s Archiv</i>,
-vol. 112, p. 35; <a href="#endnote-ref51"><span class="endnote-marker"
-id="endnote51">3</span></a> Felix, <i>D. Vierteljahrsschr. f.
-öffentl. ges.-Pfl.</i>, 1872; <a href="#endnote-ref52"><span
-class="endnote-marker" id="endnote52">4</span></a> <i>Lancet</i>, 1886,
-p. 149; <a href="#endnote-ref53"><span class="endnote-marker"
-id="endnote53">5</span></a> <i>Ramazzini</i>, 1908, vol. 2, p.
-226; <a href="#endnote-ref54"><span class="endnote-marker"
-id="endnote54">6</span></a> Dorendorf, <i>Zeitschr. f. Klin. Med.</i>,
-1901, p. 42; <a href="#endnote-ref55"><span class="endnote-marker"
-id="endnote55">7</span></a> <i>Brit. Med. Journ.</i>, 1903, p. 546,
-and <i>ibid.</i>, 1908, p. 807; <a href="#endnote-ref56"><span
-class="endnote-marker" id="endnote56">8</span></a> <i>Zeitschr.
-f. Gew.-Hyg.</i>, 1907, p. 157; <a href="#endnote-ref57"><span
-class="endnote-marker" id="endnote57">9</span></a> Wichern, <i>Zeitschr.
-f. Gew.-Hyg.</i>, 1909, Nos. 3 and 4; <a href="#endnote-ref58"><span
-class="endnote-marker" id="endnote58">10</span></a> Mitchell, <i>Med. News</i>,
-iii., p. 152; <i>Ann. d’Hyg. publ.</i>, vol. 24, p. 500; Arlidge, <i>Dis. of
-Occupation</i>; <i>Revue d’Hygiène</i>, 1895, p. 166; Neisser, <i>Intern. Uebers.
-f. Gew.-Hyg.</i>, 1907, p. 96.</p>
-
-<h4><span class="smcap">Sulphuretted Hydrogen Gas</span></h4>
-
-<p><a href="#endnote-ref59"><span class="endnote-marker"
-id="endnote59">1</span></a> <i>Chem. Ind.</i>, 1908, p. 323; <a href="#endnote-ref60"><span class="endnote-marker"
-id="endnote60">2</span></a> Pfeiler, <i>D.
-Vierteljahrsschr. f. öffentl. Ges.-Pfl.</i>, 1904; <a href="#endnote-ref61"><span class="endnote-marker"
-id="endnote61">3</span></a> <i>Lehre v. d. schädl. u.
-gift. Gasen</i>, p. 274.</p>
-
-<h4><span class="smcap">Carbon Bisulphide</span></h4>
-
-<p><a href="#endnote-ref62"><span class="endnote-marker"
-id="endnote62">1</span></a> <i>Archiv f. Hyg.</i>, vol. 15, pp.
-125-141; <a href="#endnote-ref63"><span class="endnote-marker"
-id="endnote63">2</span></a> Santesson, <i>Archiv f. Hyg.</i>, vol. 31,
-p. 336; <a href="#endnote-ref64"><span class="endnote-marker"
-id="endnote64">3</span></a> <i>Chem. Ind.</i>, 1905, p. 442;
-<a href="#endnote-ref65"><span class="endnote-marker"
-id="endnote65">4</span></a> <i>Zeitschr. f. Gew.-Hyg.</i>, 1908 and
-1909; <a href="#endnote-ref66"><span class="endnote-marker"
-id="endnote66">5</span></a> <i>Arch. f. Hyg.</i>, xx., p. 74;
-<a href="#endnote-ref67"><span class="endnote-marker"
-id="endnote67">6</span></a> <i>Die Schwefelkohlenstoffvergiftung
-der Gumniarbeiter</i>, Leipzig, Veit &amp; Comp., 1899;
-<a href="#endnote-ref68"><span class="endnote-marker"
-id="endnote68">7</span></a> <i>Ann. d’Hyg. publ.</i>, 1863.</p>
-
-<p><span class="pagenum"><a name="Page_341" id="Page_341">[341]</a></span></p>
-
-<h4><span class="smcap">Illuminating Gas</span></h4>
-
-<p><a href="#endnote-ref69"><span class="endnote-marker"
-id="endnote69">1</span></a> <i>Krankheiten des Arbeiter</i>,
-1871; <a href="#endnote-ref70"><span class="endnote-marker"
-id="endnote70">2</span></a> <i>Gewerbepathologie</i>, 1877;
-<a href="#endnote-ref71"><span class="endnote-marker"
-id="endnote71">3</span></a> <i>Weyl’s Handb. d’Hyg.</i>, 1894, vol.
-8; <a href="#endnote-ref72"><span class="endnote-marker"
-id="endnote72">4</span></a> Sprenger and Albrecht: Albrecht’s
-<i>Gewerbehygiene</i>, 1896; <a href="#endnote-ref73"><span
-class="endnote-marker" id="endnote73">5</span></a> Jehle, ‘Hygiene
-der Gasarbeiter,’ <i>Zeitschr. f. Gew.-Hyg.</i>, 1901, pp. 245 and
-261; <a href="#endnote-ref74"><span class="endnote-marker"
-id="endnote74">6</span></a> Schütte: ‘Krankheiten der
-Gasarbeiter,’ Weyl’s <i>Arbeiterkrankheiten</i>, 1908, p. 239;
-<a href="#endnote-ref75"><span class="endnote-marker"
-id="endnote75">7</span></a> Heymann’s Verlag, 1910; <a
-href="#endnote-ref76"><span class="endnote-marker"
-id="endnote76">8</span></a> <i>Zeitschr. f. Gew.-Hyg.</i>, 1909,
-No. 12; <a href="#endnote-ref77"><span class="endnote-marker"
-id="endnote77">9</span></a> <i>Chem. Ind.</i>, 1905, p. 442;
-<a href="#endnote-ref78"><span class="endnote-marker"
-id="endnote78">10</span></a> Egli, <i>Über d. Unf. b. Chem. Arb.</i>,
-Zurich, 1903; <a href="#endnote-ref79"><span class="endnote-marker"
-id="endnote79">11</span></a> <i>Gewerb. techn. Ratgeber</i>, 1906, p. 96.</p>
-
-<h4><span class="smcap">Coke Ovens</span></h4>
-
-<p><a href="#endnote-ref80"><span class="endnote-marker"
-id="endnote80">1</span></a> Hesse, <i>Concordia</i>, 1909.</p>
-
-<h4><span class="smcap">Power Gas, Suction Gas, &amp;c.</span></h4>
-
-<p><a href="#endnote-ref81"><span class="endnote-marker"
-id="endnote81">1</span></a> <i>Zeitschr. f. Gew.-Hyg.</i>, 1906, p.
-250; 1909, p. 297; 1906, p. 19; <a href="#endnote-ref82"><span
-class="endnote-marker" id="endnote82">2</span></a> <i>Gewerbl.
-techn. Ratgeber</i>, 1906, p. 297; <a href="#endnote-ref83"><span
-class="endnote-marker" id="endnote83">3</span></a> Nottebohm,
-<i>Socialtechnik</i>, 1907, vol. 7, p. 80; <a href="#endnote-ref84"><span
-class="endnote-marker" id="endnote84">4</span></a> Finkelstein, <i>Jahr.
-d. Peych.</i>, 1897, vol. 15, p. 116; <a href="#endnote-ref85"><span
-class="endnote-marker" id="endnote85">5</span></a> Jokote, <i>Arch. f.
-Hyg.</i>, 1904, vol. 49, p. 275.</p>
-
-<h4><span class="smcap">Ammonia</span></h4>
-
-<p><a href="#endnote-ref86"><span class="endnote-marker"
-id="endnote86">1</span></a> <i>Ber. pr. Gew. Insp.</i>, 1904;
-<a href="#endnote-ref87"><span class="endnote-marker"
-id="endnote87">2</span></a> Egli, <i>loc. cit.</i>, No. 2, p.
-48; <a href="#endnote-ref88"><span class="endnote-marker"
-id="endnote88">3</span></a> <i>Lehre v. d. schädl. u. gift. Gasen</i>,
-p. 274; <a href="#endnote-ref89"><span class="endnote-marker"
-id="endnote89">4</span></a> <i>Zeitschr. f. gew.-Hyg.</i>, 1909, p.
-242; <a href="#endnote-ref90"><span class="endnote-marker"
-id="endnote90">5</span></a> <i>Berl. Klin. Wochenschr.</i>, 1908.</p>
-
-<h4><span class="smcap">Cyanogen Compounds</span></h4>
-
-<p><a href="#endnote-ref91"><span class="endnote-marker"
-id="endnote91">1</span></a> <i>Handb. d. Hyg.</i>, vol. 8, p.
-897; <a href="#endnote-ref92"><span class="endnote-marker"
-id="endnote92">2</span></a> Merzbach, <i>Hyg. Rundsch.</i>, 1899,
-No. 1; <a href="#endnote-ref93"><span class="endnote-marker"
-id="endnote93">3</span></a> <i>Zeitschr. f. Med. Beamte</i>, 1907, vol.
-20, p. 825; <a href="#endnote-ref94"><span class="endnote-marker"
-id="endnote94">4</span></a> Kockel, <i>Vierteljahrsschr. f. ger. Med.</i>,
-1903, vol. 26; <a href="#endnote-ref95"><span class="endnote-marker"
-id="endnote95">5</span></a> Erben, <i>Vergiftungen</i>, ii. p. 204.</p>
-
-<h4><span class="smcap">Tar and its Derivatives</span></h4>
-
-<p><a href="#endnote-ref96"><span class="endnote-marker"
-id="endnote96">1</span></a> Lewin, <i>Münchn. med. Wochenschr.</i>,
-1907; <a href="#endnote-ref97"><span class="endnote-marker"
-id="endnote97">2</span></a> Santesson, <i>Skand. Arch. f. Physiol.</i>,
-1900, vol. 10, pp. 1-36; <a href="#endnote-ref98"><span
-class="endnote-marker" id="endnote98">3</span></a> <i>Concordia</i>, 1901,
-p. 287 Jahresber. d. Staatl. Aufsichtsbeamten über Unfallverbütung,
-1909; <a href="#endnote-ref99"><span class="endnote-marker"
-id="endnote99">4</span></a> Arb. d. Hamb. Gewerbeinspektoren,
-1909; <a href="#endnote-ref100"><span class="endnote-marker"
-id="endnote100">5</span></a> Greiff, <i>Vierteljahrsschr. f. ger. Med.</i>,
-1890.</p>
-
-<h4><span class="smcap">Coal Tar Colours</span></h4>
-
-<p><a href="#endnote-ref101"><span class="endnote-marker"
-id="endnote101">1</span></a> <i>Die Fabriken der Farbwerke
-vorm. Meister Lucius &amp; Brüning zu Höchst a. M.</i>, 1896;
-<a href="#endnote-ref102"><span class="endnote-marker"
-id="endnote102">2</span></a> <i>Concordia</i>, 1910, p. 355;
-<a href="#endnote-ref103"><span class="endnote-marker"
-id="endnote103">3</span></a> <i>Vierteljahrsschr. f. öffentl. Ges.-Pfl.</i>,
-Supplem. pro 1902, p. 371; <a href="#endnote-ref104"><span
-class="endnote-marker" id="endnote104">4</span></a> Schröder,
-<i>Vierteljahrsschr. f. ger. Med.</i>, 1903, p. 138; Rump, <i>Zeitschr.
-f. Med. Beamte</i>, 1903, p. 57; <a href="#endnote-ref105"><span
-class="endnote-marker" id="endnote105">5</span></a> Brat, <i>D. med.
-Wochenschr.</i>, 1901, Nos. 19 and 20; <a href="#endnote-ref106"><span
-class="endnote-marker" id="endnote106">6</span></a> Mohr, <i>D.
-med. Wochenschr.</i>, 1902; <a href="#endnote-ref107"><span
-class="endnote-marker" id="endnote107">7</span></a> <i>Zeitschr.
-f. Gew.-Hyg.</i>, 1908, p. 383; <a href="#endnote-ref108"><span
-class="endnote-marker" id="endnote108">8</span></a> Hanke, <i>W.
-Klin. Wochenschr.</i>, 1899, vol. 12, p. 725; Frank, <i>Beiträge zur
-Angenheilk.</i>, 1898, vol. 31, p. 93; Silex, <i>Zeitschr. f. Angenheilk.</i>,
-1902, p. 178; <a href="#endnote-ref109"><span class="endnote-marker"
-id="endnote109">9</span></a> Dearden, <i>Brit. Med. Journ.</i>, 1902, vol.
-2, p. 750; <a href="#endnote-ref110"><span class="endnote-marker"
-id="endnote110">10</span></a> <i>Ann. Rept. of C. I. of F.</i>, 1905,
-p. 165; <a href="#endnote-ref111"><span class="endnote-marker"
-id="endnote111">11</span></a> <i>Münch, med. Wochenschr.</i>,
-1907; <a href="#endnote-ref112"><span class="endnote-marker"
-id="endnote112">12</span></a> Erdmann, <i>Arch. f. exp. Path.</i>, 1905, vol.
-53, p. 401.</p>
-
-<p><span class="pagenum"><a name="Page_342" id="Page_342">[342]</a></span></p>
-
-<h4><span class="smcap">Ferro-silicon</span></h4>
-
-<p><i>Nature, Uses and Manufacture of Ferro-silicon</i>, by S. M. Copeman, S.
-R. Bennett, and H. W. Hake. London. 1909. Cd. 4958.</p>
-
-<h4><span class="smcap">Lead and its Compounds</span></h4>
-
-<p>Legge and Goadby, <i>Lead Poisoning and Lead Absorption.</i> Edward Arnold.
-1912.</p>
-
-<p><a href="#endnote-ref113"><span class="endnote-marker"
-id="endnote113">1</span></a> Wächter, <i>Die gewerbliche Bleivergiftung
-im Deutschen Reich</i>, 1908, p. 36; <a href="#endnote-ref114"><span
-class="endnote-marker" id="endnote114">2</span></a> <i>XIV. Intern. Kongr.
-f. Hyg. und Dem.</i>, 1907, vol. 2, p. 746; <a href="#endnote-ref115"><span
-class="endnote-marker" id="endnote115">3</span></a> Rambousek,
-<i>Concordia</i>, 1910; <a href="#endnote-ref116"><span class="endnote-marker"
-id="endnote116">4</span></a> Müller, <i>Die Bekämpfung der Bleigefahr
-in Bleihütten</i>, Fischer, 1908, 156; <a href="#endnote-ref117"><span
-class="endnote-marker" id="endnote117">5</span></a> Frey,
-<i>Die Zinkgewinning und ihre Hygiene</i>, Hirschwald, Berlin,
-1907; <a href="#endnote-ref118"><span class="endnote-marker"
-id="endnote118">6</span></a> Wächter, <i>Die gew. Bleivergiftung</i>, 1908,
-Braun, Karlsruhe; <a href="#endnote-ref119"><span class="endnote-marker"
-id="endnote119">7</span></a> Clayton, <i>Brit. Med. Journ.</i>, 1906, vol.
-1, p. 310; <a href="#endnote-ref120"><span class="endnote-marker"
-id="endnote120">8</span></a> <i>Bericht an die Intern. Vereinigung für
-Arbeiterschutz</i>, 1908.</p>
-
-<h4><span class="smcap">Mercury and its Compounds</span></h4>
-
-<p><a href="#endnote-ref121"><span class="endnote-marker"
-id="endnote121">1</span></a> Laureck, <i>Weyl’s Arbeiterkr.</i>, p.
-62; <a href="#endnote-ref122"><span class="endnote-marker"
-id="endnote122">2</span></a> Giglioli, Ramazzini, 1909, vol. 3, p. 230.</p>
-
-<h4><span class="smcap">Arsenic and its Compounds</span></h4>
-
-<p><a href="#endnote-ref123"><span class="endnote-marker"
-id="endnote123">1</span></a> <i>Zeitschr. f. Gew.-Hyg.</i>, 1902, p.
-441; <a href="#endnote-ref124"><span class="endnote-marker"
-id="endnote124">2</span></a> Prölss, <i>Friedreich’s Bl. f. ger. Med.</i>,
-1901, p. 176.</p>
-
-<h4><span class="smcap">Antimony</span></h4>
-
-<p><a href="#endnote-ref125"><span class="endnote-marker"
-id="endnote125">1</span></a> <i>Vergiftungen</i>, vol. ii. p. 285.</p>
-
-<h4><span class="smcap">Brass</span></h4>
-
-<p><a href="#endnote-ref126"><span class="endnote-marker"
-id="endnote126">1</span></a> <i>Vierteljahrsschr. f. ger. Med.</i>, 1906,
-p. 185; <a href="#endnote-ref127"><span class="endnote-marker"
-id="endnote127">2</span></a> <i>Arch. f. Hyg.</i>, 1910, vol. 72, p. 358.</p>
-
-<h3>PART II<br />
-<span class="smcap">Pathology and Treatment</span></h3>
-
-<h4><span class="smcap">Oxygen Inhalation in Industrial Poisoning</span></h4>
-
-<p>Brat, ‘Bedeutung der Sauerstofftherapie in der Gewerbehygiene, <i>XIV. Intern.
-Kongr. f. Hyg. u. Dem.</i> und <i>Zeitschr. f. Gew.-Hyg.</i> 1908, Heft 13, S. 305; Dräger,
-‘Zur Physiologie des Rettungsapparates mit komprim. Sauerstoff, <i>I. Intern.
-Kongr. f. Rett.-Wes., Frankfurt a. M.</i> 1908, und <i>Fabrikfeuerwehr</i> 1908, Heft 19,
-S. 74; Klocke, ‘Die Bedeutung der Sauerstoffinhalationen in der Gewerbehygiene,’
-<i>Zeitschr. f. Gew.-Hyg.</i> 1906, Heft 20, S. 559; Dräger, ‘Neue Untersuchungen
-über die Erfordernisse eines zur Arbeit brauchbaren Rettungsapparates,’ <i>Zeitschr.
-f. Gew.-Hyg.</i> 1905, S. 49; Klocke, ‘Sauerstoffrettungsapparate,’ <i>Soz. Techn.</i> 1908,
-Nr. 14, S. 272.</p>
-
-<p><span class="pagenum"><a name="Page_343" id="Page_343">[343]</a></span></p>
-
-<h4><span class="smcap">Hydrofluoric Acid Poisoning</span></h4>
-
-<p>Egli, <i>Unf. b. chem. Arb.</i>, I, S. 23, und II, S. 45; Rambousek, ‘Gewerbekrankh.
-in Böhmen,’ <i>Concordia</i> 1910, Heft 6, und <i>Amtsarzt</i> 1910, Heft 7.</p>
-
-<h4><span class="smcap">Sulphuric Acid and Sulphur Dioxide</span></h4>
-
-<p>Ogata, <i>Arch. f. Hyg.</i>, Bd. 2; Lehmann, <i>Arch. f. Hyg.</i>, Bd. 18, S. 180 ff; Klocke
-‘(SO₂-Vergiftung und O-Inhal.),’ <i>Zeitschr. f. Gew.-Hyg.</i> 1906, S. 562 und 617;
-‘SO₂-Absorption beim Atemprozess,’ Chem. Ztg. 1909, S. 246; ‘Tod durch Einatmung
-von Schwefelsäuredampf,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1907, S. 430; ‘Schwefel-dioxydvergiftung
-in England,’ <i>Concordia</i> 1909, Heft 5, S. 105; ‘Schwefels.-Vergiftung,
-<i>Chem. Ind.</i> 1909 <i>(Ber. d. Berufsgen. f. chem. Ind. pro</i> 1908, S. 26); Egli,
-<i>Unf. b. chem. Arb.</i>, ii, S. 52.</p>
-
-<h4><span class="smcap">Nitric Acid and Nitrous Fumes</span></h4>
-
-<p>‘Verg. durch nitrose Gase in einer Zellulosefabrik,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1908
-Heft 24, S. 565; ‘Behandlung von Nitrosevergiftungen durch Sauerstoffinhalationen,’
-<i>Zeitschr. f. Gew.-Hyg.</i> 1908, Heft 20, S. 560; ‘Behandlung durch Chloroform,’
-<i>Zeitschr. f. Gew.-Hyg.</i> 1904, Heft 10, S. 226, und 1907, Heft 8, S. 183;
-‘Vergiftungen durch nitrose Gase (Zusammenfassung),’ Holtzmann, <i>Concordia</i>,
-1908, Nr. 23, S. 498.</p>
-
-<h4><span class="smcap">Chlorine, Bromine, and Iodine</span></h4>
-
-<p>Leymann, <i>Arch. f. Hyg.</i>, Bd. 7, S. 231; Binz, <i>Arch. f. exp. Path.</i>, Bd. 13;
-<i>Vierteljahrsschr. f. ger. Med.</i> 1888, S. 345; Lehmann, <i>Arch. f. Hyg.</i>, Bd. 34, S. 302,
-und <i>Arch. f. Hyg.</i>, Bd. 17, S. 336; <i>Arch. f. exp. Path. u. Ph.</i> 1887, S. 231; Egli,
-<i>Unf. b. chem. Arb.</i>, II, S. 51; Chlorverg., <i>Chem. Ind.</i> 1907, S. 347, 1908, S. 325;
-Neisser, <i>Intern. Uebers. über Gew.-Hyg.</i>, I, S. 94; ‘Chlorverg. in England,’ <i>Concordia</i>
-1909, S. 105.</p>
-
-<p><i>Literatur Über Chlorakne.</i>—Herxheimer, <i>Münchn. med. Wochenschr.</i> 1899
-S. 278; Bettmann, <i>D. med. Wochenschr.</i> 1901, S. 437; Lehmann, <i>Arch. f. Dermatol.</i>
-1905, S. 323; Leymann, ‘Erk.-Verh. der chem. Grossind.,’ <i>Concordia</i> 1906, Nr. 7-9;
-Holtzmann, <i>D. Vierteljahrsschr. f. öffentl. Ges.-Pfl.</i> 1907, Bd. 39, S. 258.</p>
-
-<h4><span class="smcap">Chlorides of Phosphorus</span></h4>
-
-<p>Vaubel, <i>Chem. Ztg.</i> 1903; Leymann, <i>Concordia</i> 1906, Nr. 7; Egli, <i>Unf. b.
-chem.-Arb.</i> 1902, S. 49; Rumpf, <i>D. med. Wochenschr.</i> 1908, Bd. 34, S. 1331.</p>
-
-<h4><span class="smcap">Chloride of Sulphur</span></h4>
-
-<p>Lehmann, <i>Arch. f. Hyg.</i> 1894, Bd. 20, S. 26; Leymann, <i>Concordia</i> 1906, Heft 7.</p>
-
-<h4><span class="smcap">Ammonia</span></h4>
-
-<p>Lehmann, ‘Verauche über die Wirkung,’ <i>Arch. f. Hyg.</i>, Bd. 5; ‘Vers. über
-die Resorption,’ <i>Arch. f. Hyg.</i>, Bd. 17 u. 67; ‘Versuche über die Gewöhnung,’
-<i>Arch. f. Hyg.</i>, Bd. 34; Lewin, ‘Tödl. Ammoniakverg. in einer chem. Fabrik,
-Berl. klin. Wochenschr. 1908; ‘Tödl. Ammoniakverg.,’ <i>Zeitschr. f. Gew.-Hyg.</i>
-1909, Wr. 9, S. 242; ‘Ammoniakverg. in der Kälte-Ind.’</p>
-
-<p><span class="pagenum"><a name="Page_344" id="Page_344">[344]</a></span></p>
-
-<h4><span class="smcap">Lead Poisoning</span></h4>
-
-<p>‘Vorkommen der Bleivergiftung. Bleierkrankungen in der Bleihütte
-Braubach,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1909, S. 291; <i>Bleivergiftungen in gewerbl. u
-hüttenmänn. Betrieben</i> (<i>Oesterreichs</i>), herausgegeben vom k. k. Arbeitsstat. Amt:
-I. Erhebungen in Blei- und Zinkhütten; II. Erhebungen in Bleiweiss- und Bleioxydfabriken;
-III. Expertise, betreffend die Blei- und Zinkhütten; IV. Expertise,
-betreffend die Bleiweiss- und Bleioxydfabriken; V. Erhebungen in Farbenfabriken
-und Betrieben mit Anstreicher-, Lackierer- und Malerarbeiten; VI. Expertise
-hierzu; VII. Erhebungen und Expertise in Buch- und Steindruckereien und
-Schriftgisseereien (alle Teile erschienen bei Alfr. Hölder, Wien 1905-1909). Frey,
-<i>Zinkgewinnung im oberschles. Industriebezirk</i>, Berlin 1907, Verlag Hirschwald;
-Leymann, <i>Die Bekämpfung der Bleigefahr in der Industrie</i>, Verlag Fischer, Jena
-1908; Müller, <i>Die Bekämpfung der Bleigefahr in Bleihütten</i>, Verlag Fischer, Jena
-1908; Wächter, <i>Die gewerbl. Bleiverg. im Deutschen Reich</i>, Verlag Braun, Karlsruhe
-1908; Chyzer, <i>Les intoxications par le plomb se présentant dans la céramiquen en
-Hongrie</i>, Schmidl, Budapest 1908; Kaup, <i>Bleiverg. in der keramischen Ind.</i>, als
-Manuskript gedruckt, D. Sekt. Ges. f. Soziale Reform; Teleky, ‘Beitrag z. H. d.
-Erzeug. v. ord. Töpferware usw. in Oesterr.,’ <i>Arbeiterschutz</i>, 1908, Nr. 19, 20; De
-Vooys, <i>Bleiverg. in der niederl. keram. Ind.</i> (Nederl. Vereen. voor wettelijke Beseherming
-van arbeiders 1908); Kaup, <i>Bleiverg. in österr. Gew.-Betrieben</i>, Schriften
-des österr. Vereines für Arbeiterschutz 1902, Heft 3; Sommerfeld, ‘Zur Bleiweissfrage,’
-<i>Soz. Praxis</i> 1902, Nr. 8; Friedinger, ‘Sanit. Verh. in d. Buchdr.,’ <i>Soz.
-Praxis</i> 1902, Nr. 9; Wutzdorff, <i>Bleiverg. in Zinkhütten</i>, Arb. a. d. Kais. Ges.-Amte,
-Bd. 17, S. 441; Blum, <i>Unters. über Bleiverg.</i>, Frankfurt a.M. 1900, <i>Vierteljahrsschr.
-f. öffentl. Ges.-Pfl.</i>, Suppl. 32, S. 630; Panwitz, <i>Bleiverg. in Buchdruckereien</i>,
-Veröff. d. Kais. Ges.-Amtes 1897, S. 503; Teleky, ‘Bleiverg. bei Fransenknüpferinnen,’
-Ref. <i>Zeitschr. f. Gew.-Hyg.</i> 1907, Nr. 1, S. 13; ’ Bleierkrankung und
-Bekämpfung ders., Literatursammlung,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1904, Nr. 6, S. 131;
-Teleky, ‘Die gewerbl. Bleiverg. in Oesterreich,’ <i>Soz. Techn.</i> 1909, Nr. 17, S. 333;
-Bleiverg. (Legge), Verh. d. II. Intern. Kongr. f. Gewerbekrankh. in Brüssel 1910;
-Bleiverg. in Böhmen (Rambousek), Concordia 1910, Nr. 7, Amtsarzt 1910, Nr. 6;
-Abelsdorff, Statistik d. Bleiverg., Concordia 1910, Heft 17, S. 359; Wutzdorff,
-‘Bleiverg. in Akkumulatoreniabr.,’ <i>Arb. a. d. Kais. Ges.-Amte</i> 1898, Bd. 15, S. 154;
-Rasch, ‘Ueber Bleiverg. d. Arb. in Kachelfabr.,’ <i>Arb. a. d. kais. Ges.-Amte</i> 1898,
-Bd. 14, S. 81.</p>
-
-<h4><span class="smcap">General Literature on Pathology and Treatment of Lead Poisoning</span></h4>
-
-<p>Jores, ‘Die allg. pathol. Anatomie der chron. Bleiverg. des Kaninchens,’
-<i>Beiträge z. path. Anat. u. allg. Path.</i> 1902, Bd. 31, S. 183; Glibert, <i>Le saturnisme
-experimental, extrait d. rapp. ann. de l’insp. du travail en 1906</i>, Bruxelles, 1907.
-Rambousek, ‘Die Pathol. d. Bleiverg.’ in Leymann’s <i>Bekämpfung d. Bleigef.</i>, S. 15,
-Velag Fischer, Jena 1908; <i>Die Verhütung d. Bleigefahr</i>, Verlag Hartleben 1908;
-Blum, ‘Unters. über Bleiverg., Frankfurt a.M. 1900,’ <i>Vierteljahrsschr. f. öffentl
-Ges.-Pfl.</i>, Suppl. 32, S. 630; Elschnig, ‘Sehstörungen b. Bleiverg.,’ Ges. d. Aerzte,
-Wien, Sitzung v. 15. April 1898, und <i>Wiener med. Wochenschr.</i> 1898, S. 1305;
-‘Neuere Forschungen über Bleiverg.,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1909, S. 629; Seeligmüller,
-‘Einfl. d. Bleies auf den Frauenorganismus usw.,’ <i>Berl. klin. Wochenschr.</i>
-1901, S. 842; Bernhardt, ‘Zur Pathol. d. Bleilähmung,’ <i>Berl. klin. Wochenschr.</i>
-1900, S. 26; Rambousek, ‘Die Bleierkrankung,’ <i>Zeitschr. f. ärztl. Fortbildung</i> 1909,
-Nr. 7; Israel, ‘Obd.-Befund b. Bleiverg.,’ <i>Berl. klin. Wochenschr.</i> 1895, S. 575;
-Gumpertz, Bernhardt, ‘Anom. d. elektr. Erregb. b. Bleiverg.,’ <i>Berl. klin. Wochenschr.</i><span class="pagenum"><a name="Page_345" id="Page_345">[345]</a></span>
-1894, S. 372 u. S. 284; Jolly, ‘Sekt.-Befund b. Bleilänmung, Entart. d. Gangl.,’
-<i>Berl. klin. Wochenschr.</i> 1893; Miura, ‘Ueber die Bedeutung des Bleinachweises auf
-der Haut Bleikranker,’ <i>Berl. klin. Wochenschr.</i> 1890, S. 1005; Mattirolo, ‘Behandlung
-d. Bleikolik mit Erythroltetranitrat,’ <i>Wiener med. Presse</i> 1901, <i>Wiener med.
-Wochenschr.</i> 1901, S. 2171; Oddo und Silbert, ‘Ausscheidung des Bleis,’ <i>Revue
-med.</i> 1892, Nr. 4, und <i>Wiener med. Presse</i> 1892, S. 1182; Mosse, ‘Veränderungen
-d. Gangl. coeliac. bei exper. Bleikolik,’ <i>Wiener klin. Wochenschr.</i> 1904, S. 935;
-Escherich, ‘Zwei Fälle v. Bleilähmung b. Kindern (Peroneuslähmung.),’ <i>Wiener
-klin. Wochenschr.</i> 1903, S. 229; Variot, ‘Ein Fall v. Bleilähmung b. einem Kinde
-(Peroneuslähmung),’ <i>Gaz. des Hôp.</i> 1902, S. 482, und <i>Wiener klin. Wochenschr.</i>
-1902; Sorgo, ‘Progress. Muskelatrophie nach Bleiverg.,’ <i>Weiner med. Wochenschr.</i>
-1902, S. 919; Variot, ‘Bleiverg. b. einem Kinde, Parese d. unt. Extrem.,’ <i>Wiener
-med. Wochenschr.</i> 1902, S. 2056; Rome, ‘Bleiverg. b. Kindern,’ <i>La trib. med.</i> 1902,
-Nr. 39, und <i>Wiener med. Wochenschr.</i> 1902, S. 2391; Layal, Laurencon, Rousel,
-‘Erscheinungen der Pylorusstenose b. Bleiverg.,’ <i>Wiener med. Wochenschr.</i> 1897;
-Macfairlain, ‘Chloroformbehandlung bei Bleikolik,’ <i>Wiener med. Wochenschr.</i> 1895;
-Bechtold, ‘Spast. Spinalparalyse b. Bleiverg.,’ <i>Med. chir. Zentralbl.</i> 1904, Nr. 40;
-Oliver, ‘Lead-poisoning, &amp;c.,’ <i>Lancet</i>, 1891, S. 530; Heymann, ‘Lähmungen d.
-Kehlkopfmuskeln b. Bleiverg.,’ <i>Arch. f. Laringol.</i> 1896, S. 256; Clayton, ‘Ind.
-lead-poisoning,’ <i>Brit. med. journ.</i> 1906, S. 310; Taylor, ‘Bleiamblyopie,’ <i>Lancet</i>
-1898, S. 742; Seeligmüller, ‘Zur Pathol. d. chron. Bleiverg.,’ <i>D. med. Wochenschr.</i>
-1902, S. 317; Lewin, ‘Puls b. Bleiverg.,’ <i>D. med. Wochenschr.</i> 1897, S. 177;
-Walko, ‘Erkr. d. Magens b. chron. Bleiverg.,’ <i>Münchn. med. Wochenschr.</i> 1907,
-S. 1728; Tielemanns, <i>Parotiserkr. b. Bleiverg.</i>, Monogr., Paris 1895; Borgen,
-‘Blutdruckbestimmungen b. Bleikolik,’ <i>D. Arch. f. klin. Med.</i> 1895, S. 248;
-Klieneberger, ‘Intox. saturn. und Nephritis sat.,’ <i>München. med. Wochenschr.</i>
-1904, S. 340; Bach, ‘Augenerkr. b. Bleiverg.,’ <i>Arch. f. Augenheilk.</i> 1893, S. 218;
-Redlich, ‘Tabes und chron. Bleiverg.,’ <i>Wiener med. Wochenschr.</i> 1897, S. 801;
-Seifert, ‘Kehlkopfmuskellähmung b. Bleiverg.,’ <i>Berl. klin. Wochenschr.</i> 1884,
-S. 555.</p>
-
-<h4><span class="smcap">Literature on Blood Changes in Lead Poisoning</span></h4>
-
-<p>Schmidt, ‘Die Bleiverg. und ihre Erkennung,’ <i>Arch. f. Hyg.</i> 1907, Bd. 63,
-Heft 1; Galperin-Teytelmann, <i>Die basophilen Granula der roten Blutk. b. Bleairbeitern,
-Ing. Diss.</i>, Bonn 1908; Carozzi, <i>Reperti ematol. e loro valore statistico nel
-saturn. prof. Corr. sanitar.</i> 1909, Bd. 20, Nr. 5 u. 6; Gilbert, <i>Le saturnisme exp.</i>,
-Bruxelles, 1907; Rambousek, ‘Beitrag z. Pathol. d. Stoffw. und d. Blutes b.
-Bleiverg., <i>Zeitschr. f. exp. Path. und Therap.</i> 1910, Bd. 7; Moritz, ‘Beziehungen
-der basophilen Granula zu den Erythrozyten,’ <i>Münchn. med. Wochenschr.</i> 1901,
-Nr. 5; <i>St. Petersburger med. Wochenschr.</i> 1901, Nr. 26, 1903, Nr. 50; <i>Verh. d. I.
-Intern. Kongr. f. Arb.-Krankh. in Mailand</i> 1906, <i>Atti del congresso</i>, S. 601-607;
-Trautmann, ‘Blutunters. b. Bleiverg.,’ <i>Münchn. med. Wochenschr.</i> 1909, S. 1371;
-Grawitz,’Ueber die körn. Degenerat. d. roten Blutkörperchen,’ <i>D. med. Wochenschr.</i>
-1899, Nr. 44; ‘Die klin. Bedeutung und exp. Erzeugung körn. Degener. in den
-roten Blutkörperchen,’ <i>Berl. klin. Wochenschr.</i> 1900, Nr. 9; Hamel, ‘Ueber die
-Beziehungen der körn. Degener. der roten Blutkörperchen zu den sonst. morph.
-Veränd. des Blutes mit besonderer Berücks. d. Bleiintox.,’ <i>D. Arch. f. klin. Med.</i>
-1900, Bd. 67; Frey, ‘Beitrag zur Frühdiagnose v. chron. Bleiverg.,’ <i>D. med.
-Wochenschr.</i> 1907, Nr. 6; Grawitz, <i>Klin. Pathol. des Blutes</i>, Leipzig 1906, S. 120 ff.;
-Naegeli, ‘Ueber die Entstehung der basoph. gek. roten Blutk.,’ <i>München. med.
-Wochenschr.</i> 1904, Nr. 5; Schmidt, ‘Zur Frage d. Entstehung d. basoph. Körner,’
-<i>D. med. Wochenschr.</i> 1902, Nr. 44; <i>Exp. Beiträge z. Pathol. d. Blutes</i>, Jena 1902;<span class="pagenum"><a name="Page_346" id="Page_346">[346]</a></span>
-‘Ein Beitrag. z. Frage d. Blutregen.,’ <i>Münchn. med. Wochenschr.</i> 1903, Nr. 13;
-Erben, ‘Chem. Zusammensetzung d. Blutes b. Bleiverg.,’ <i>Zeitschr. f. Heilkunde</i>,
-1905, S. 477.</p>
-
-<h4><span class="smcap">Literature on Changes in Metabolism in Lead Poisoning</span></h4>
-
-<p>Preti, ‘Beitrag z. Kenntn. d. Stickstoffums. b. Bleiverg.,’ 1909, S. 411; Rambousek,
-‘Beitrag z. Pathol. d. Stoffw. und d. Blutes,’ <i>Zeitschr. f. exp. Path. und
-Ther.</i> 1910, Bd. 7; ‘Pathol. d. Bleiverg.’ in Leymann’s <i>Bekämpfung d. Bleigefahr</i>,
-Fischer, Jena 1909; Minkowski, <i>Die Gicht</i>, Wien, 1903, Holders Verlag.; Schittenhelm
-und Brugsch, ‘Zur Stoffwechselpathol. d. Gicht,’ <i>Zeitschr. f. exp. Path. und
-Ther.</i>, Bd. 4, S. 494-495.</p>
-
-<h4><span class="smcap">Literature on Toxicity of Various Lead Compounds</span></h4>
-
-<p>Blum, ‘Unters. über Bleiverg., Frankfurt a. M. 1900,’ <i>Vierteljahrsschr. f.
-öffentl. Ges.-Pfl.</i>, Suppl. 32, S. 630; Rambousek, <i>Die Verhütung der Bleigefahr</i>,
-Verlag Hartleben 1908; Biondi und Rambousek, ‘Polemik über die Ungiftigkeit d.
-Bleisulfids,’ <i>I. Intern. Kongr. f. Gew.-Krankh. in Mailand</i> 1906, <i>Atti del congresso</i>,
-S. 617-622; Lehmann, ‘Hyg. Unters. über Bleichromat,’ <i>Arch. f. Hyg.</i> 1893,
-Bd. 16, S. 315.</p>
-
-<h4><span class="smcap">Zinc</span></h4>
-
-<p>Schlockow, ‘Ueber ein eigenartiges Rückenmarksleiden bei Zinkhüttenarbeitern,’
-<i>D. med. Wochenschr.</i> 1879, S. 208; Tracinsky, ‘Die oberschlesische
-Zinkindustrie usw.,’ <i>D. Vierteljahrsschr. f. öffentl. Ges.-Pfl.</i> 1888, Bd. 20, S. 59;
-Seiffert, ‘Erkr. d. Zinkhüttenarb. usw.,’ <i>ibidem</i> 1897, Bd. 31, S. 419; Lehmann,
-‘Beiträge z. hygien. Bedeutung d. Zinks,’ <i>Arch. f. Hyg.</i> 1897, Bd. 28, S. 300;
-Neuere Arbeiten: Frey, <i>Die Zinkgew. im oberschl. Industriebez.-usw.</i>,’ Verlag
-Hirschwald-Berlin 1907 und <i>Zeitschr. f. Gew.-Hyg.</i> 1907, Nr. 16, S. 376; Sigel,
-‘Das Giesserfieber u. seine Bekämpfung,’ <i>Vierteljahrsschr. f. ger. Med.</i> 1906, Bd. 32,
-S. 173; Lehmann, ‘Giess- oder Zinkfieber,’ <i>Arch. f. Hyg.</i> 1910, Bd. 72, S. 358.</p>
-
-<h4><span class="smcap">Mercury</span></h4>
-
-<p>Schönlank, <i>Fürther Spiegelfabriken</i> 1888 (Monogr.); Wollner, ‘Quecksilberspiegelfabrik
-in Fürth,’ <i>Vierteljahrsschr. f. öffentl. Ges.-Pfl.</i>, Bd. 19, 3, S. 421, und
-<i>Münchn. med. Wochenschr.</i> 1892, Bd. 39, S. 533; Stickler, ‘Hutfabrikation, 1886,’
-<i>Revue d’Hygiène</i>, VIII, S. 632; Charpentier, ‘Spiegelfabrik,’ <i>Annal. d’hyg. publ.</i>,
-avril 1885, S. 323; Henke, <i>Quecksilberverg. in Hutfabriken</i>, Knauer, Frankfurt
-1889; Wittzack, ‘Quecksilberverg. b. d. Spiegelbel. usw.,’ <i>Vierteljahrsschr. f.
-öffentl. Ges.-Pfl.</i> 1896, S. 216; Donath, ‘Quecksilberverg. in Gluhlampenfabriken,’
-<i>Wiener med. Wochenschr.</i> 1894, 8. 888; Renk, ’ Quecksilberverarbeitung,’ Arb.
-a. d. Kais. Ges.-Amte, Bd. 5, Heft I; Letulle, ‘Hasenhaarschneiderei,’ <i>Revue
-d’Hyg.</i>, XI, S. 40; Ueber Hasenfellbeize, <i>Zeitschr. f. Gew.-Hyg.</i> 1909, S. 821;
-<i>Sozialtechn.</i> 1910, S. 39; ‘Quecksilberverg. in d. Glühlampenind.,’ <i>Zeitschr.
-f. Gew.-Hyg.</i> 1908, S. 469; ‘Quecksilberverg. in Amiata in Italien (ausführliche
-Schilderung der Symptome schwerer Quecksilberverg.),’ Giglioli, im <i>Ramazzini</i>
-1909, Bd. 3, S. 230, und ‘Demonstration am II. Ital. Kongr. f. Arbeiterkrankh.
-in Florenz 1909,’ ref. <i>Zeitschr. f. Gew.-Hyg.</i> 1909, S. 289, und <i>Chem.
-Ztg.</i>, Repert., 1909, S. 411; ‘Quecksilberverg. in Hutfabriken in Italien,’
-<i>Ramazzini</i>, 1909, S. 230; Laureck, in Weyls <i>Handb. d. Arb.-Krankh.</i> 1909, S. 62.</p>
-
-<p><span class="pagenum"><a name="Page_347" id="Page_347">[347]</a></span></p>
-
-<h4><span class="smcap">Manganese</span></h4>
-
-<p>Couper, <i>Journ. de chim.</i>, 1837, Bd. 3, S. 2; Jaksch, <i>Münchn. med. Wochenschr.</i>
-1901, S. 602; Embden, <i>D. med. Wochenschr.</i>, Bd. 27, S. 795, u. <i>Münchn. med.
-Wochenschr.</i> 1901, S. 1852; Jaksch, ‘Ueber Manganintoxikationen u. Manganophobie,’
-<i>Münchn. med. Wochenschr.</i> 1907, Bd. 54, S. 969; Hauck, ‘Manganismus.’
-Vortrag auf dem XIV. Intern. Kongr. f. Hyg. u. Dem., Berlin 1907, Bd. 4, S. 337;
-Friedel, D. med. Wochenschr. 1909, S. 1292.</p>
-
-<h4><span class="smcap">Chromium</span></h4>
-
-<p>Delpech et Hillaret, <i>Annal. d’Hyg. publ.</i> 1876; Viron, <i>Contrib. à l’étude phys.
-et tox. de quelques prép. chromés</i>, Paris, 1885; Burghardt, ‘Chromverg. in der
-Zündhölzchenindustrie,’ <i>Charité Annalen</i>, XXIII, 1898, S. 189; Wutzdorff, ‘Die
-in den Chromatfabriken beobachteten Gesundheits-schädigungen.’</p>
-
-<h4><span class="smcap">Nickel</span></h4>
-
-<p>Nickelkrätze: ‘Jahresberichte d. preuss. Reg.- u. Gewerberäte für das Jahr
-1907,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1908, Nr. 8, S. 185, u. 1909, Nr. 14, S. 374; Klocke,
-<i>Soz. Med. u. Hyg.</i> 1910, Bd. 5, Nr. 2.</p>
-
-<h4><span class="smcap">Nickel Carbonyl</span></h4>
-
-<p>H. W. Armit: <i>Journ. of Hygiene</i>, 1907, p. 524, and 1908, p. 565; Vahlen,
-<i>Arch. exp. Pathol. u. Ph.</i> 1902, Bd. 48, S. 117; Mittasch, <i>Arch. f. exp. Path.</i> 1903,
-Bd. 49, S. 367; Langlois, <i>Compt. rend. de la soc. de Biol.</i> 1891, S. 212.</p>
-
-<h4><span class="smcap">Silver (Argyria)</span></h4>
-
-<p>Schubert, ‘Argyrie bei Glasperlenversilberern,’ <i>Zeitschr. f. Heilk.</i> 1895, Bd. 16,
-S. 341; Lewin, ‘Lokale Gewerbeargyrie,’ <i>Berl. klin. Wochenschr.</i> 1886, S. 417;
-Blaschko, <i>Arch. f. mikr. Anatomie</i>, Bd. 27, S. 651.</p>
-
-<h4><span class="smcap">Arsenic</span></h4>
-
-<p>‘Arsenverg. in der Delainage,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1906, Nr. 3, S. 71;
-‘Arsenikverg. in der Ind.,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1907, S. 353, und 1903, S. 476;
-‘Arsenikverg. in England, nach den Ber. der engl. Gew.-Insp.,’ <i>Concordia</i> 1909,
-Nr. 5, S. 105; Egli, <i>Unf. b. chem. Arb.</i>, II, S. 51.</p>
-
-<h4><span class="smcap">Phosphorus</span></h4>
-
-<p>Lorinser, <i>Med. Jahrb. d. österr. Staates</i>, 1845, Bd. 51, S. 257; und <i>Zeitschr. d.
-Gesellsch. d. Aerzte in Wien</i>, 1851, Bd. 55, S. 22; Geist u. Bibra, <i>Die Krankh. d. Arb.
-in der Phosphorzündholzfabrik</i>, Erlangen 1847; Wegner, <i>Virch.-Arch.</i> 1872, Bd. 55,
-S. 11; Magitot, <i>Revue d’Hygiène</i>, 1895, Bd. 17, S. 201; Kollin, ‘Oberkiefernekrose,’
-<i>Zentralbl. f. inn. Med.</i> 1889, S. 1279; Dearden, ‘Osseous fragilit. am.
-workers in luc. match fet.,’ <i>Brit. Med. Journ.</i> 1899, S. 92; Lévai, ‘Ueber Phosphornekrose,’
-<i>Wiener klin. Rundsch.</i> 1900, S. 33; ‘Ein Fall von Phosphornekrose
-19 Jahre nach der Arbeit in Zündhölzchenfabriken,’ <i>Wiener klin. Rundsch.</i> 1896,
-Nr. 29, S. 503; Stockman, <i>Brit. Med. Journ.</i> 1899; Stubenrauch, <i>Arch. f. klin.
-Chir.</i> 1899, Heft 1, und <i>Samml. klin. Vortr.</i> 1901, Nr. 303; Röpke, <i>Zeitschr. d.
-Zentralst. f. Arb.-Wohlf.-Einr.</i> 1901, Nr. 1; ‘Phosphorverg. in England (nach
-den Berichten der engl. Gew.-Insp.),’ <i>Concordia</i>, 1909, Nr. 5, S. 105; Teleky, ‘Die
-Phosphornekrose in Oesterreich,’ <i>Schriften der Oesterr. Gesellsch. f. Arbeiterschutz</i>,
-Heft 12, Verlag Deuticke 1907; Friedrich, ‘Die Phosphorverg. in Ungarn’ (in
-ungar. Sprache), <i>Schriften der Ungar. Gesellsch. f. Arbeiterschutz</i>, Heft 4, Budapest
-1908.</p>
-
-<p><span class="pagenum"><a name="Page_348" id="Page_348">[348]</a></span></p>
-
-<h4><span class="smcap">Phosphoretted Hydrogen</span></h4>
-
-<p>Schulz, <i>Arch. f. exp. Path. u. Phys.</i> 1890, Bd. 27, S. 314; Dietz, ‘Phosphorwasserstoffverg.
-bei einem Phosphorfabrikarb.,’ <i>Arch. f. Hyg.</i> 1904, Bd. 49.</p>
-
-<p>Spezielle Literatur über Phosphorwasserstoffvergiftung durch Ferrosilizium:
-Bahr, Lehnkering, ‘Phosphorverg. durch Ferrosiliz.,’ <i>Vierteljahrsschr. f. ger.
-Med.</i> 1906, S. 123; <i>Jahresber. d. engl. Gew.-Insp. f. d. J.</i> 1907 (vgl. <i>Soz. Techn.</i>
-1908, Bd. 7, S. 689 und 690); Oliver, <i>Diseases of Occupation</i>, 1908; H. Le Chatelier,
-<i>Ann. Min.</i> 1909, Bd. 15, S. 213; vgl. ferner <i>Zeitschr. f. Gew.-Hyg.</i> 1908, S. 574, und
-S. 181.</p>
-
-<h4><span class="smcap">Hydrogen Sulphide</span></h4>
-
-<p>Lehmann, ‘Exp. Studien über Schwefelw.,’ <i>Arch f. Hyg.</i>, Bd. 14, S. 142;
-‘Gewöhnung an Schwefelw.,’ <i>ibidem</i>, Bd. 34, S. 303; ‘Absorption von Schwefelw.,’
-<i>ibidem</i>, Bd. 17, S. 332; Blumenstock, ‘Lehre von der Verg. mit Kloakengasen,’
-<i>Vierteljahrsschr. f. ger. Med.</i> 1873, Bd. 18, S. 295; Kasper, ‘Massenverg. mit
-Kloakengas,’ <i>Vierteljahrsschr. f. ger. Med.</i>, Bd. 2, S. 593; Römer, ‘Akute tödl.
-Schwefelwasserstoffverg.,’ <i>Münchn. med. Wochenschr.</i> 1897, S. 851; Oliver, dieselbe,
-<i>Lancet</i>, 1903, S. 225; ‘Schwefelwasserstoffverg. bei der Saturation v. Schwefelbarium,’
-<i>Ber. d. Berufsgen. f. Chem. Ind.</i> 1907, <i>Chem. Ind.</i> 1908, S. 323; ‘Schwefelwasserstoffverg.
-in einer Fabrik auf Ammoniaksalze’; Egli, <i>Unf. b. chem. Arb.</i>,
-II, S. 46; ‘Schwefelwasserstoffverg. in England, Ber. d. engl. Gew.-Insp.,’ siehe
-<i>Concordia</i>, 1909, S. 105; ‘Schwefelwasserstoffverg. in d. chem. Ind.,’ <i>Techn.
-gewerbl. Ratgeber</i> 1906, S. 108; ‘Schwefelwasserstoffverg. und Sauerstoffinhalation,’
-<i>Zeitschr. f. Gew.-Hyg.</i> 1906, S. 587; ‘Erste Hilfe bei Schwefelwasserstoffverg.,’
-<i>Zeitschr. f. Gew.-Hyg.</i> 1908, S. 455, auch <i>Chem Ind.</i> 1908, S. 327.</p>
-
-<h4><span class="smcap">Carbon Bisulphide</span></h4>
-
-<p>Delpech, ‘Accidents qui développent chez les ouvriers en caoutchouc et du
-sulfure de carbone etc.,’ <i>L’Union méd.</i> 1876, No. 66; ‘Nouvelles recherches sur
-l’intox. du <i>CS</i>₂ etc.,’ <i>Ann. d’Hyg. publ.</i> Nr. 37; Sapelier, ‘Étude sur le sulfure de
-carbone,’ Thèse, Paris 1885; Rosenblatt, <i>Ueber die Wirkung v. CS₂-Dämpfen auf
-den Menschen</i>, Diss. Würzburg 1890; Pichler, <i>Ein Beitrag z. Kenntn. d. akuten CS₂-Verg.</i>,
-Berlin 1897 (Fischer); Lehmann, ‘Exp. Stud. über Schwefelk.,’ <i>Arch. f.
-Hyg.</i> 1894, Bd. 20, S. 56 ff.; <i>Zeitschr. f. Gew.-Hyg.</i> 1899, ‘Schutzmassregeln der
-Kautschukindustrie in England’; Laudenheimer, <i>Schwefelk.-Verg. d. Gummiarb.</i>
-899, Leipzig, Veit &amp; Comp.; Harmsen, ‘Die Schwefelk. im Fabr. Betrieb,’ <i>Vierteljahrsschr.
-f. ger. Med.</i> 1905, S. 149; Riegler, ‘Die nervösen Störungen bei
-CS₂-Verg.,’ <i>Zeitschr. f. Nervenh.</i> 1907, Bd. 33; Roth, ‘Gewerbl. CS₂-Verg. usw.,’
-<i>Berl. klin. Wochenschr.</i> 1901, S. 570; Reiner, ‘Schwefelk.-Amblyopie,’ <i>Wiener klin
-Wochenschr.</i> 1895, S. 919; Quensel, ‘Geistesstörungen nach CS₂-Verg.,’ <i>Monatsh. f.
-Psych.</i> 1905, Bd. 16.</p>
-
-<h4><span class="smcap">Cyanogen and Cyanogen Compounds (Prussic Acid, &amp;c.)</span></h4>
-
-<p>Merzbach, ‘Chron. Zyanverg. bei einem Galvaniseur,’ <i>Hyg. Rundsch.</i> 1899,
-Nr. 1; Pfeiffer, ‘Zyanverg. d. Kanalgase (Abgänge v. d. Zyangewinnung),’
-<i>Vierteljahrsschr. f. öffentl. Ges.-Pfl.</i> 1904; Stritt, ‘Verg. d. Zyanverb. im Düngemittel,’
-<i>Zeitschr. f. Hyg.</i> 1909, Bd. 62, S. 169; Tatham, ‘Zyanverg. beim Reinigen
-v. Goldspitzen,’ <i>Brit. Med. Journ.</i> 1884, S. 409; Kockel, ‘Blausäureverg. bei
-einem Zelluloidbrand,’ <i>Vierteljahrsschr. f. ger. Med.</i> 1903, S. 1; ‘Zyanverg. u.
-Sauerstoffinhal.’ (Brat), <i>Zeitschr. f. Gew.-Hyg.</i> 1906, S. 588; Lehmann, ‘Ueber die<span class="pagenum"><a name="Page_349" id="Page_349">[349]</a></span>
-Gift. d. gasförm. Blausäure (Giftigkeitsgrenzen),’ <i>Berl. klin. Wochenschr.</i> 1903,
-S. 918; Blaschko, ‘Berufsdermatosen d. Arb. (Hautleiden b. Verwendung v.
-Zyaniden),’ <i>D. med. Wochenschr</i>, 1889, S. 915; MacKelway s. (Hautleiden),
-<i>Amer. Journ. of Medic. Science</i>, 1905, S. 684; Wilkes (ditto), <i>Lancet</i>, 1904, S. 1058.</p>
-
-<h4><span class="smcap">Arseniuretted Hydrogen Gas</span></h4>
-
-<p>‘Arsenwasserstoffverg. (Verfertigen v. Kinderballons),’ <i>Zeitschr. f. Gew.-Hyg.</i>
-1902, S. 441; ‘Arsenwasserstoffverg. (Ausleeren eines Schwefelsäuretanks),’
-<i>Gewerbl. techn. Ratgeber</i> 1906, S. 109; ‘Arsenwasserstoffverg. im Hüttenbetriebe
-(<i>O</i>-Inhalation),’ <i>Zeitschr. f. Gew.-Hyg.</i> 1906, S. 589 u. S. 617; ‘Arsenwasserstoffverg.,’
-<i>Zeitschr. f. Gew.-Hyg.</i> 1908, S. 263, u. 1910, S. 179; ‘Arsenwasserstoffverg. in
-England, nach den Ber. d. engl. Gew.-Insp.,’ <i>Concordia 1909</i>, S. 105; Egli, ‘Arsenwasserstoffverg.,’
-<i>Unf. b. chem. Arb.</i>, II, S. 42; Lunge, ‘Arsenwasserstoffverg.
-beim Löten,’ <i>Chem.-Ztg.</i> 1904, S. 1169; Barié, ‘Arsenwasserstoffverg. durch
-Ballongas,’ <i>Arch. f. krim. Anthrop.</i> 1906, S. 147.</p>
-
-<h4><span class="smcap">Carbonic Oxide</span></h4>
-
-<p><i>General Literature on CO-Poisoning.</i>—Becker, ‘Die <i>CO</i>-Verg. u. ihre
-Verhütung,’ <i>Vierteljahrsschr. f. ger. Med.</i> 1893, S. 349; Greiff, ‘<i>CO</i>-Verg.
-bei d. Teerdestill., <i>Vierteljahrsschr. f. ger.</i> Med. 1890, S. 359; Brouardel, ‘<i>CO</i>-Verg.
-d. Kalkofengase,’ <i>Ann. d’Hyg. publ.</i> 1840; Becker, ‘Nachkrankheiten d. <i>CO</i>-Verg.,’
-<i>D. med. Wochenschr.</i> 1893, S. 571; Reinhold, ‘Chron. <i>CO</i>-Verg.,’ <i>Münchn. med.
-Wochenschr.</i> 1904, S. 793; ‘<i>CO</i>-Verg. beim Sengen des Garnes,’ <i>Zeitschr. f. Gew.-Hyg.</i>
-1909, S. 267.</p>
-
-<p><i>Literature on CO-Poisoning in Gas Works.</i>—Jehle, ‘Hyg. d. Gasarbeiter,’
-<i>Zeitschr. f. Gew.-Hyg.</i> 1901, Heft 14 u. 15, S. 245 ff.; Schütte, ‘Krankh. d. Gasarb.,’
-Weyls <i>Arbeiterkrankh.</i> 1908, S. 239 ff.; Rambousek, <i>Concordia 1910</i>, Nr. 6.</p>
-
-<h4><span class="smcap">Carbon Oxychloride (Phosgene Gas)</span></h4>
-
-<p>‘Tödl. Verg. d. Phosgen in einer Farbenfabrik,’ <i>Jahresber. d. Berufsgen. f. d.
-Chem. Ind.</i> 1905, vgl. <i>Gewerbl. techn. Ratgeber</i>, 1906, S. 108; Klocke, ‘Mehrere
-gewerbl. Phosgenverg.,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1906; Sury-Bienz, ‘B. z. Kasuistik
-d. Intox.,’ <i>Vierteljahrsschr. f. ger. Med.</i> 1907, S. 251; Müller, <i>Zeitschr. f. angew
-Chemie</i>, Bd. 13 (Heft v. 12. Aug. 1910).</p>
-
-<h4><span class="smcap">Carbon Dioxide</span></h4>
-
-<p>‘Kohlensäureverg. b. d. Kesselreinigung,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1906, S. 129;
-Kohlensäureverg. und <i>O</i>-Inhalation,’ ebenda 1906, S. 589; Lehmann, ‘Unters.
-über die langdauernde Wirkung mittlerer Kohlensäuremengen auf den Menschen,’
-<i>Arch. f. Hyg.</i> 1900, S. 335.</p>
-
-<h4><span class="smcap">Petroleum, Benzine, &amp;c.</span></h4>
-
-<p><i>Petroleumvergiftung.</i>—Borthenson, ‘Die Naphthaind. in sanit. Beziehung,’
-Vortrag auf dem XII. Intern. Aerztekongr. in Moskau 1897 u. <i>D. Vierteljahrsschr.
-f. öffentl. Ges.-Pfl.</i> 1898, Bd. 30, S. 315; Burenin, ‘Die Naphtha u. i. Verarb. in
-sanit. Beziehung, Petersburg 1888; Lewin, ‘Ueber allg. und Hautverg. d. Petrol.,’
-<i>Virchows Arch.</i> 1888, Bd. 112, S. 35; Sharp, ‘The Poison Effects of Petrol.,’
-<i>Med. News</i>, 1888; Samuel, ‘Verg. in Petroleumtanks,’ <i>Berl. klin. Wochenschr.</i>,
-1904, Bd. 41, S. 1047; Foulerton, ditto, <i>Lancet</i> 1886, S. 149; Mabille, ditto,
-<i>Revue d’Hyg.</i> Bd. 18, 1896, Nr. 3; <i>Ber. d. engl. Gew.-Insp.</i>; vgl. <i>Concordia</i> 1909,
-S. 105.</p>
-
-<p><span class="pagenum"><a name="Page_350" id="Page_350">[350]</a></span></p>
-
-<p><i>Skin diseases in Petroleum und Paraffinarbeiter.</i>—Chevallier, <i>Ann. d’Hyg.</i>
-1864; Lewin, <i>Virchows Arch.</i> 1888 (siehe oben); Mitchell, <i>Med. News</i>, Bd. 53,
-S. 152; Derville u. Guermonprez (Papillome), <i>Annal. derm.</i> 1890, S. 369; Brémont,
-<i>Revue d’Hyg.</i> 1895, S. 166; Rambousek, <i>Concordia</i> 1910, Nr. 6.</p>
-
-<p><i>Benzinvergiftung.</i>—Dorendorf (b. Kautschukarb.), <i>Zeitschr. f. klin. Med.</i> 1901,
-S. 42; Finlayson, <i>Brit. Med. Journ.</i> 1903, S. 546; Bürgi (Verg. d. Autobenzin),
-<i>Korr. f. Schweiz. Aerzte</i>, 1906, Bd. 36, S. 350; Box, <i>Brit. Med. Journ.</i> 1908, S. 807;
-<i>Zeitschr. f. Gew.-Hyg.</i> 1908, S. 333, 1907, S. 157, und 1906, S. 515; Schäfer,
-‘Verwendung u. schädl. Wirkung einiger Kohlenwasserstoffe u. anderer Kohlenstoffverbindungen,’
-<i>Hamb. Gew.-Insp.-Arb. u. Sonderberichte</i>, 1909, S. 7.</p>
-
-<h4><span class="smcap">Benzene</span></h4>
-
-<p>Benzolverg. b. d. Benzoldestill: <i>Zeitschr. f. angew. Chemie</i>, 1896, S. 675; <i>Chem.
-Ind.</i> 1906, S. 398; <i>Chem. Ztg.</i> 1910, S. 177. Benzolverg. (Benzolextrakt.-Appar.):
-Egli, <i>Unf. b. chem. Arb.</i> 1903, S. 58; <i>Chem. Ind.</i> 1907, S. 347; vgl. Lewin, <i>Münchn.
-med. Wochenschr.</i> 1907 und <i>Zeitschr. f. Gew.-Hyg.</i> 1907, S. 581. Benzolverg. b.
-Reinigen von Benzollagerkesseln: <i>Chem. Ind.</i> 1905, S. 444; 1907, S. 347; ferner
-1909, Nr. 14, Beil. S. 25. Benzolverg. in einer Gummifabrik: <i>Chem. Ind.</i> 1905,
-S. 442. Benzolverg. bei d. Fabr. v. Antipyrin: Egli, <i>Unf. b. chem. Arb.</i>, I, 1903,
-S. 58. Benzolverg. d. Asphaltanstrichmasse: <i>Zeitschr. f. Gew.-Hyg.</i> 1904, S. 292.
-Santesson, ‘Bensolverg. in einer Gummiw.-Fabrik. (und exper. Untersuchungen),’
-<i>Arch. f. Hyg.</i> 1897, Bd. 31, S. 336. Rambousek, <i>Die gewerbl. Benzolverg. Bericht am
-II. Int. Kongr. f. Gewerbekrankh. in Brüssel</i> 1910. Wojciechowski, <i>Ueber die
-Giftigkeit versch. Handelssorten des Benzols in Gasform</i>, Inaug.-Diss. Würzburg,
-1910; Lehmann, ‘Aufnahme von Benzol aus der Luft durch Tier und Mensch,’
-<i>Arch. f. Hyg.</i> 1910, Heft 4; Sury Bienz, ‘Tödliche Benzolverg.,’ <i>Vierteljahrsschr.
-f. ger. Med.</i> 1888, S. 138; Schaefer, ‘Verwendung u. schädl. Wirkung einiger
-Kohlenw. u. anderer Kohlenstoffverbindungen,’ <i>Hamb. Gew.-Insp., Arb. und
-Sonderberichte</i>, 1909.</p>
-
-<h4><span class="smcap">Halogen Substitution Products of the Aliphatic Hydrocarbons
-(Narcotics)</span></h4>
-
-<p>Lehmann, ‘Aufnahme chlorierter Kohlenwasserstoffe aus der Luft durch
-Mensch und Tier (Chloroform, Tetrachlorkohlenstoff, Tetrachloräthan),’ <i>Arch. f.
-Hyg.</i> 1910, Bd. 72, Heft 4; Grandhomme, <i>Die Fabr. d. A.-G. Farbwerke in Höchst
-a. M. in sanit. und soz. Beziehung</i>, 1893, 3 Aufl., S. 88 (Jodmethylverg. b. d.
-Antipyrinbereitung); Jacquet, ‘Gewerbl. Brom- und Jodmethylverg.,’ <i>D. Arch.
-f. klin. Med.</i> 1901, Bd. 71, S. 370; Schuler, ‘Gewerbl. Brommethylverg.,’ <i>D.
-Vierteljahrsschr. f. öffentl. Ges.-Pfl.</i> 1899, Bd. 31, S. 696; Schaefer, ‘Verwendungsart
-u. schädl. Wirkung einiger Kohlenwasserst. u. anderer Kohlenstoffverg.’
-(Tetrachlorkohlenstoff),’ <i>Ber. d. Hamburger Gewerbe-Inspektion</i>, 1909, S. 11.</p>
-
-<h4><span class="smcap">Halogen Substitution Products of the Benzene Series (Chlorbenzene, &amp;c.).</span></h4>
-
-<p>Leymann, ‘Erkr.-Verh. in einigen chem. Betr.,’ <i>Concordia</i> 1906, Heft 7 (Chlorbenzol,
-Benzoylchlorid); ‘Verg. mit Chlorbenzol, Nitrochlorbenzol usw.,’ <i>Vierteljahrsschr.
-f. öffentl. Ges.-Pfl.</i> 1902, Suppl. S. 371, und <i>Concordia</i> 1902, Nr. 5; Mohr,
-‘Chlorbenzolverg.,’ <i>D. med. Wochenschr.</i> 1902, S. 73.</p>
-
-<h4><span class="smcap">Hydroxyl Substitution Products of the Aliphatic Series (Alcohols)</span></h4>
-
-<p>Pohl, ‘Wirkungen von Methylalkohol,’ <i>Arch. f. exp. Path.</i> 1893, S. 281; Patillo u.
-Colbourn, ‘Gewerbl. Methylalkoholverg.,’ <i>Ophthalm. Rec.</i> 1899.</p>
-
-<p><span class="pagenum"><a name="Page_351" id="Page_351">[351]</a></span></p>
-
-<h4><span class="smcap">Nitro and Amido Derivatives of Benzene (Nitrobenzene, Aniline, &amp;c.)</span></h4>
-
-<p>Leymann, ‘Erkr.-Verh. in einer Anilinfarbenfabrik,’ <i>Concordia</i> 1910, Heft 17,
-S. 355; Grandhomme, <i>Die Fabr. d. A.-G. Farbw. in Höchst. a. M. in sanit. u. soz.
-Beziehung</i>, 1896 (und <i>Vierteljahrsschr. f. ger. Med.</i> 1880); ‘Nitrobenzol- und
-Anilinverg., Vorschr. f. d. Verhalten,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1906, Nr. 22, S. 619;
-‘Nitrobenzol (in Mineralöl),’ <i>Zeitschr. f. Gew.-Hyg.</i> 1910, S. 159; Röhl, ‘Akute
-u. chron. Verg. m. Nitrokörpern d. Benzolreihe,’ <i>Vierteljahrsschr. f. ger. Med.</i> 1890,
-S. 202; Letheby, ditto, <i>Proceed. of the Roy. Soc. London</i>, 1863, S. 550; Thompson,
-ditto, <i>British Med. Journ.</i> 1891, S. 801; Friedländer, ‘Intox. m. Benzol- u. Toluolderivaten,’
-<i>Neurol. Zentralbl.</i> 1900; S. 294; ‘Nitrotoluolverg. in einer Sprengstoffabrik,’
-<i>Zeitschr. f. Gew.-Hyg.</i> 1908, S. 383; ‘Nitroxylolverg.,’ <i>Chem. Ind.</i> 1905,
-S. 444; ‘Intox. m. Nitrokörpern. u. deren Behandl. m. Sauerstoffinhal.,’ <i>Zeitschr.
-f. Gew.-Hyg.</i> 1906, S. 617; Brat, ‘Gew. Methämoglobinverg. u. deren Behandl. m.
-Sauerstoff,’ <i>D. med. Wochenschr.</i> 1901, S. 296; Leymann, ‘Verg. m. Nitrobenzol,
-Nitrophenol, Dinitrophenol, Nitrochlorbenzol, usw.,’ <i>Concordia</i> 1902, Nr. 5;
-Schröder und Strassmann (Verg. in Roburitfabriken), <i>Vierteljahrsschr. f. ger. Med.</i>,
-Suppl. 1891, S. 138; Brat, ‘Erkr. in einer Roburitfabrik,’ <i>D. med. Wochenschr.</i>
-1901, Nr. 19 und Nr. 20; ‘Verg. m. Dinitrobenzol in England,’ <i>Concordia</i> 1909,
-S. 105; Mohr, ‘Verg. m. Chlorbenzol, <i>D. med. Wochenschr.</i> 1902, S. 73; Silex,
-‘Augenschädigungen d. Nitronaphthalin,’ <i>Zeitschr. f. Augenheilk.</i> 1902, S. 178;
-Häusermann und Schmidt, ‘Gewerbl. Nitrobenzol- u. Anilinverg.,’ <i>Vierteljahrsschr.
-f. ger. Med.</i> 1877, S. 307; ‘Gewerbl. Anilinverg.,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1909,
-S. 350 u. S. 602, 1908, S. 384, 1906, S. 455, S. 599, S. 617 u. 619 (Behandlung),
-1903, S. 133, 1902, S. 63; ‘Anilinverg. in England,’ <i>Concordia</i> 1909, S. 105;
-Hildebrandt, ‘Anilinderivate, Giftwirkung (Intern. med. Kongr. Budapest 1909),’
-<i>Chem. Ztg.</i> 1909, S. 997; Seyberth, ‘Blasengeschwülste d. Anilinarb.,’ <i>Münchn.
-med. Wochenschr.</i> 1907, S. 1573; ‘Erhebungen über das Vorkommen von Blasengeschwülsten
-bei Anilinarb.,’ <i>Zeitschr. für Gew.-Hyg.</i> 1910, S. 156; Rehn, ‘Blasengeschwülste
-bei Anilinarb.,’ <i>Arch. f. klin. Chir.</i> 1895, S. 588; Lewin, ‘Paranitranilinverg.,
-Obergutachten,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1909, S. 597; Criegern,
-‘Gewerbl. Paraphenylendiaminverg.,’ XX. Kongr. f. inn. Medizin, Wiesbaden,
-1902; Erdmann, Vahlen, ‘Wirkung des Paraphenylendiamins,’ <i>Arch. f. exp.
-Path.</i> 1905, S. 401; Georgievics (Wirkung d. Teerfarbstoffe), <i>Farbenchemie</i>, 1907,
-S. 13; Prosser White, Researches into the Aromatic Compounds, <i>Lancet</i>, 1901,
-Case of Aniline Poisoning, Intern. Cong. Brussels, 1910.</p>
-
-<h4><span class="smcap">Turpentine</span></h4>
-
-<p>Lehmann, ‘Beiträge z. Kenntn. d. Terpentinölwirkung,’ <i>Arch. f. Hyg.</i> 1899,
-S. 321; Reinhard, ‘Gewerbl. Terpentinintox.,’ <i>D. med. Wochenschr.</i> 1887, S. 256;
-Drescher, ‘Terpentindampfinh. tödl. Verg. eines Arb. beim Innenanstrich eines
-Kessels,’ <i>Zeitschr. f. med. Beamte</i> 1906, S. 131; Schaefer, ‘Verwendungsart u.
-schädl. Wirkung einiger Kohlenwasserstoffe u. and. Kohlenstoffverbind.,’ <i>Hamburger
-Gew.-Insp., Arbeiten und Sonderabdrücke</i>, 1909, S. 9.</p>
-
-<h4><span class="smcap">Pyridene</span></h4>
-
-<p>Blaschko, ‘Möbelpoliererekzem,’ <i>D. med. Wochenschr.</i> 1890, S. 475.</p>
-
-<h4><span class="smcap">Tobacco, Nicotine</span></h4>
-
-<p>Jehle, ‘Gesundh. Verhältn. d. Tabakarb.,’ <i>Arch. f. Unf.-Heilk.</i> 1901, ref.
-<i>Zeitschr. f. Gew.-Hyg.</i> 1901, S. 236; Rochs, ‘Einfluss d. Tabaks auf die Gesundheitsverhältnisse
-d. Tabakarb.,’ <i>Vierteljahrsschr. f. ger. Med.</i> 1889, S. 104.</p>
-
-<p><span class="pagenum"><a name="Page_352" id="Page_352">[352]</a></span></p>
-
-<h3>PART III<br />
-<span class="smcap">Preventive Measures</span></h3>
-
-<h4><span class="smcap">General Measures (Notification, Lists of Poisonous Substances, &amp;c.)</span></h4>
-
-<p>Fischer, <i>Liste der gewerbl. Gifte</i> (<i>Entwurf</i>), Frankfurt a. M. (als Manuskript
-gedruckt), 1910; Sommerfeld, <i>Liste der gewerbl. Gifte</i> (<i>Entwurf</i>) Verlag Fischer,
-Jena, 1908; Carozzi, <i>Avvelenamenti ed infezioni professionali</i> (<i>gewerbl. Gifte und
-Infektionen</i>), Verlag Fossati, Mailand, 1909; Rambousek, <i>IIᵉ Congrès int. des
-maladies prof. Bruxelles</i> 1910, S. 14; ‘Anzeigepflicht bei gewerbl. Erkrankungen,’
-Ber. über die Verh. d. Abt. f. Gewerbekrankh. auf der 36. Jahresvers. der British
-med. Assoc. in Sheffield 1908, <i>Brit. Med. Journ.</i> 1908, S. 401-408 und 480-496;
-Rambousek, ‘Arbeiterschutz und Versicherung bei gewerbl. Erkrankungen,’
-<i>Sozialtechnik</i> 1909, Heft 4, S. 65; Lewin, <i>Grundlagen für die med. und rechtl.
-Beurteilung des Zustandekommens und des Verlaufes von Vergiftungs- u. Infektions-Krankheiten
-im Betriebe</i> (Monogr.) Berlin, Heymanns Verlag, 1907.</p>
-
-<h4><span class="smcap">Sulphuric Acid Industry</span></h4>
-
-<p>‘Schwefelsäureerzeugung, Schutz gegen Nitroseverg.,’ <i>Gewerbl. techn. Ratgeber</i>,
-1906, Heft 6, S. 109; ‘Schwefelsäureerzeugung, Reinigung von Tankwaggons,’
-<i>Gewerbl. techn. Ratgeber</i>, 1906, Heft 6, S. 109; ‘Schwefelsäuretransport,’ <i>Zeitschr.
-f. Gew.-Hyg.</i> 1902, Nr. 4, S. 63; ‘Schwefelsäureverg., Verhütung,’ <i>Chem. Ind.</i>
-1909, Beilage, <i>Ber. d. Berufsgen. f. d. chem. Ind. f. d. J.</i> 1908, S. 26; ‘Ausräumen
-des Gay-Lussac, Verhütung von Verg., <i>Chem. Ind.</i> 1907, S. 351; ‘Sauerstoff gegen
-Schwefelsäureverg., Atemapparate,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1906, Nr. 20, S. 562,
-und 1906, Nr. 22, S. 617.</p>
-
-<h4><span class="smcap">Petroleum, Benzine</span></h4>
-
-<p>Berthenson, ‘Die Naphthaindustrie in sanit. Beziehung,’ <i>Vierteljahrsschr. f.
-öffentl. Ges.-Pfl.</i> 1898, Bd. 30, S. 315; Korschenewski, <i>Wratsch</i>, 1887, Nr. 17;
-Burenin, ‘Die Naphtha und ihre Verarbeitung in sanit Beziehung,’ Petersburg
-1888; Mabille, ‘Revue d’Hygiène,’ Bd. 18, Nr. 3; <i>Bericht der Berufsgen. f. chem.
-Ind.</i> 1905; <i>Bericht der preuss. Gew.-Insp.</i> 1904; Klocke, <i>Zeitschr. f. Gew.-Hyg.</i>
-1908, S. 379; ‘Benzinersatz (in chem. Wäschereien),’ <i>Zeitschr. f. Gew.-Hyg.</i> 1906,
-S. 248, und 1908, S. 384; ‘Schutz des Arbeiters vor Benzindämpfen,’ <i>Zeitschr.
-f. Gew.-Hyg.</i> 1906, S. 236.</p>
-
-<h4><span class="smcap">Carbon Bisulphide</span></h4>
-
-<p>‘Nachweisung von Schwefelkohlenstoffdämpfen in Fabrikräumen,’ <i>Zeitschr. f.
-Gew.-Hyg.</i> 1908, Nr. 5, S. 107; ‘Hygienische Einrichtung beim Vulkanisieren
-(Glibert),’ <i>Zeitschr. f. Gew.-Hyg.</i> 1902, Nr. 1, S. 1; ‘Absaugung der Dämpfe an
-Vulkanisiertischen,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1903, Nr. 14, S. 305; Laudenheimer,
-‘Die Schwefelkohlenstoffverg. bei Gummiarbeitern,’ Leipzig, Veit &amp; Comp., 1899;
-Roeseler,’Schwefelkohlenstofferkrankungen und deren Verhütung,’ <i>Vierteljahrsschr.
-f. Med. u. öffentl. Sanitätswesen</i> 1900, 3. Folge, Bd. 20, S. 293 (ref. <i>Zeitschr. f. Gew.-Hyg.</i>
-1901, S. 164); ‘Einrichtungen von Gummifabriken,’ <i>Zeitschr. f. Gew.-Hyg.</i>
-1903, S. 260 u. 484.</p>
-
-<h4><span class="smcap">Illuminating Gas</span></h4>
-
-<p>‘Leuchtgasverg.-Verhütung,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1909, Heft 22, S. 604;
-‘Kokslöscheinrichtung,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1908, Heft 10, S. 231; ‘Bedeutung<span class="pagenum"><a name="Page_353" id="Page_353">[353]</a></span>
-der Sauerstoffinhalationen in der Leuchtgasindustrie,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1906,
-Heft 21, S. 590; ‘Entleerung der Reinigungskästen in der Leuchtgasfabrik,
-<i>Zeitschr. f. Gew.-Hyg.</i> 1903, Nr. 13, S. 283; Jehle, ‘Hygiene der Gasarbeiter,’
-<i>Zeitschr. f. Gew.-Hyg.</i> 1901, Nr. 14, S. 245.</p>
-
-<h4><span class="smcap">Coal Tar Colours (Aniline Factories)</span></h4>
-
-<p>Grandhomme, <i>Die Fabriken der A.-G. Farbwerke vorm. Meister, Lucius &amp;
-Brüning zu Höchst a. M.</i>, Frankfurt a. M. 1896; Leymann, ‘Ueber die Erkrankungsverhältnisse
-in einer Anilinfabrik,’ <i>Concordia</i> 1910, Heft 17, S. 355 ff.;
-Leymann, <i>Die Verunreinigung der Luft durch gewerbliche Betriebe</i> (Fischer, Jena,
-1903); ‘Sauerstoffinhalationen in Anilinfabriken,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1906,
-Nr. 22, S. 617, und 1908, S. 327.</p>
-
-<h4><span class="smcap">Lead (General)</span></h4>
-
-<p>Legge &amp; Goadby, ‘Lead Poisoning and Lead Absorption,’ 1912; <i>Bleiverg. in
-gewerbl. u. hüttenmänn. Betrieben Oesterreichs</i>, herausgeg. vom. k. k. Arbeitsstatist.
-Amte, I-VI, Verlag Hölder, 1905-1909; Leymann, <i>Die Bekämpfung der Bleigefahr
-in der Ind.</i>, Verlag Fischer, Jena, 1908; Wächter, <i>Die gewerbl. Bleiverg. im
-Deutschen Reiche</i>, Verlag Braun, Karlsruhe 1908; Blum, ‘Untersuch, über
-Bleiverg., Frankfurt a. M. 1900,’ <i>Wiener klin. Wochenschr.</i> 1904, S. 1935; Rambousek,
-<i>Ueber die Verhütung der Bleigefahr, Wien</i>, Hartleben, 1908; Teleky, ‘Die
-gewerbl. Bleiverg. in Oesterr.,’ <i>Sozialtechnik</i> 1909, S. 333, <i>Wiener klin. Wochenschr.</i>
-1907, S. 1500.</p>
-
-<h4><span class="smcap">Lead Smelting</span></h4>
-
-<p><i>Bleiverg. in gewerbl. u. hüttenmänn. Betrieben Oesterr.</i>, I und III, Verlag Hölder,
-Wien; Müller, <i>Die Bekämpfung der Bleigefahr in Bleihütten</i>, Verlag Fischer, Jena,
-1908; Wutzdorff, <i>Bleiverg. in Zinkhütten</i>, Arb. a. d. Kaiserl. Ges.-Amte, Bd. 17,
-S. 441; Elsässer, ‘Schädl. in Blei- und Silberhütten,’ <i>Vierteljahrsschr. f. ger.
-Med.</i> 1903, Bd. 25, S. 136.</p>
-
-<h4><span class="smcap">Paints and Colour Factories</span></h4>
-
-<p>Über Hygiene der Erzeugung und Verwendung von Bleifarben: <i>Bleiverg. in
-gewerbl. u. hüttenm. Betrieben Oesterreichs</i>, IV., V. und VI. Teil, <i>Hölder Wien</i>;
-Stüler, ‘Bleiverg. bei Malern’; <i>Vierteljahrsschr. f. öffentl. Ges.-Pfl.</i> 1895, S. 661;
-‘Bleiweissfabriken (Staubabsaugung),’ <i>Zeitschr. f. Gew.-Hyg.</i> 1909, Nr. 22, S. 601;
-‘Kampf gegen die Bleifarben in Frankreich,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1909, Nr. 23,
-S. 543; ‘Gefahren in Bleiweissfabriken,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1907, Nr. 9, S. 205;
-‘Bleiweissersatz (Ausstellung),’ <i>Zeitschr. f. Gew.-Hyg.</i> 1907, Nr. 11, S. 254; ’ Bleifarbenverbot,’
-<i>Zeitschr. f. Gew.-Hyg.</i> 1904, Nr. 10, S. 221; ‘Bleigefahr im Gewerbe
-der Anstreicher, Maler usw.,’ <i>Soz. Technik.</i> 1909, Nr. 17, S. 333; ‘Bleiweissfrage,’
-<i>Sozialtechn.</i> 1908, Nr. 16, S. 310.</p>
-
-<h4><span class="smcap">Electric Accumulator Factories</span></h4>
-
-<p>Wutzdorff, <i>Bleiverg. in Akkumul.-Fabr.</i>, Arb. a. d. Kaiserl. Ges.-Amt
-1908, Bd. 15, S. 154; ‘Hygiene der Akkumulatorräume,’ <i>Zeitschr. f. Gew.-Hyg.</i>
-1909, Heft 3, S. 79, und Heft 21, S. 494; Chyzer, ‘Hygiene der Akkumulatorräume,’
-<i>Zeitschr. f. Gew.-Hyg.</i> 1907, Nr. 20, S. 476; ‘Bekämpfung von Verg. in
-Akkumulatorräumen,’ <i>Concordia</i> 1908, Heft 13, S. 273.</p>
-
-<h4><span class="smcap">Letterpress Printing</span></h4>
-
-<p><i>Bleiverg. in gewerbl. u. hüttenm. Betrieb. Oesterr.</i>, k. k. Arbeitsstat. Amt, VII.
-Teil, Wien, Hölder 1909; Panwitz, <i>Bleiverg. in Buchdruckereien</i>, Veröff. d. Kais.
-Ges.-Amtes, Bd. 17, S. 503; ‘Bleiverg. in der Buchdruckerei (Enquete),’ <i>Zeitschr.<span class="pagenum"><a name="Page_354" id="Page_354">[354]</a></span>
-f. Gew.-Hyg.</i> 1909, Heft 6, S. 152 ff.; ‘Bleifreie Druckfarben und Bronzen (Preisausschriebung),’
-<i>Zeitschr. f. Gew.-Hyg.</i> 1909, Heft 23, S. 630 ff.; ‘Setzkasten mit
-doppeltem Boden,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1908, Nr. 10, S. 237; ‘Bleinachweis in
-den Dämpfen der Typengiesserei,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1906, Nr. 24, S. 677;
-‘Schriftsetzerei (Typenbläserei),’ <i>Zeitschr. f. Gew.-Hyg.</i> 1904, Nr. 8, S. 176;
-‘Bleigefahr in Druckereien,’ <i>Concordia</i> 1908, Heft 18, S. 384.</p>
-
-<h4><span class="smcap">Filecutting</span></h4>
-
-<p>‘Bleiverg. bei Feilenhauern in England,’ <i>Zeitschr. d. Zentralst. f. Arb.-Wohlf.-Einr.</i>
-1901, S. 232; ‘Bleierkr. b. Feilenhauern,’ <i>Gewerbl. techn. Ratgeber</i> 1905,
-Heft 3, S. 50; ‘Hygiene d. Feilenhauerei (Chyzer),’ <i>Zeitschr. f. Gew.-Hyg.</i> 1908,
-N. 13, S. 303.</p>
-
-<h4><span class="smcap">Zinc Smelting</span></h4>
-
-<p>Frey, <i>Die Zinkgewinnung im oberschles. Industriebezirk und ihre Hygiene</i>,
-Berlin 1907, Verlag Hirschwald; Sigel, ‘Das Giesserfieber und seine Bekämpfung,’
-<i>Vierteljahrsschr. f. ger. Med.</i> 1906, Bd. 32, S. 173; ‘Lehmann, Beiträge zur hyg.
-Bedeutung des Zinks,’ <i>Arch. f. Hyg.</i> 1897, Bd. 28, S. 300; ‘Giess- oder Zinkfieber,’
-<i>Arch. f. Hyg.</i> 1910, Bd. 72, S. 328; ‘Hyg. der Zinkerei,’ <i>Zeitschr. f. Gew.-Hyg.</i>
-1907, Nr. 2, S. 39; ‘Zinkhütten, hyg. Einricht.,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1901, Nr. 18,
-S. 321, und 1910, Heft 11, S. 250; ‘Giesserfieber, Bekämpfung,’ <i>Soz. Techn.</i> 1907,
-Heft 3, S. 51; ‘Giesserei, Hyg.,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1903, Heft 16, S. 351,
-Heft 21, S. 479, und 1904, Heft 13, S. 344, ‘Schutz gegen Säuredämpfe bei der
-Metallbearbeitung,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1904, Heft 1, S. 5 u. 11, ferner Heft 14,
-S. 317, u. 1905, Heft 10, S. 287, Heft 22, S. 643.</p>
-
-<h4><span class="smcap">Mercury</span></h4>
-
-<p>Quecksilberhütten in Idria: Laureck in Weyls <i>Handb. d. Arb.-Krankh.</i> 1909,
-S. 62; ‘Quecksilberhütten in Amiata’: Giglioli, <i>Ramazzini</i> 1909, Bd. 3, S. 230.</p>
-
-<p>Quecksilberbelegerei, Hyg: Schönlanck, <i>Fürther Spiegelbelegen</i> (Monogr.) 1888;
-Wollner, ‘Fürther Spiegelbelegen,’ <i>Vierteljahrsschr. f. öffentl. Ges.-Pfl.</i> XXIX
-3, S. 421, und <i>München. med. Wochenschr.</i> 1892, Bd. 39, S. 533; Charpentier,
-‘Fürther Spiegelbelegen,’ <i>Ann. d’Hyg. publ.</i> 1885, S. 323.</p>
-
-<p>Quecksilber in Hutfabriken, Quecksilberbeize: Stickler, <i>Revue d’Hygiène</i> 1886,
-S. 632; Henke (Monogr.), Frankfurt a. M. 1899; Hasenfellbeize (Ersatz), <i>Jahresber.
-d. Fabr.-Insp.</i> 1884, S. 489, <i>Zeitschr. f. Gew.-Hyg.</i> 1902, S. 360, 1909, S. 281, <i>Soz.
-Techn.</i> 1910, S. 39; Hutfabriken in Italien (Hyg.), <i>Ramazzini</i> 1909, S. 230.</p>
-
-<p>Sonstige Gewerbe: Glühlampenind. (Hyg.): Donath, <i>Wiener med. Wochenschr.</i>
-1894, S. 888, <i>A. Mitt. a. d. Ber. d. Gew.-Insp.</i> 1899, <i>Zeitschr. f. Gew.-Hyg.</i> 1902,
-Heft 20, S. 356, und 1908, Heft 20, S. 469, Thermometererzeug. (Hyg.), <i>Zeitschr. f.
-Gew.-Hyg.</i> 1901, S. 32.</p>
-
-<h4><span class="smcap">Arsenic</span></h4>
-
-<p>‘Arsenikbestimmung im Hüttenrauch’ (Harkins &amp; Swein), <i>Journ. Amer. Chem.
-Soz.</i> 1907, Bd. 29, S. 970; <i>Chem. Ztg.</i>, Rep. 1907, S. 447; ‘Arsenikverg. in der
-Ind.’ (Heim, Herbert), <i>Zeitschr. f. Gew.-Hyg.</i> 1907, Bd. 14, S. 354; ‘Arsenverg. in
-der Delainage,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1906, Nr. 3, S. 71; ‘Gewerbl. Arsenverg.’
-(Legge), <i>Zeitschr. f. Gew.-Hyg.</i> 1903, Heft 21, S. 476; ‘Arsenwasserstoffverg. im
-Gewerbe (Prophyl.),’ <i>Zeitschr. f. Gew.-Hyg.</i> 1908, Nr. 10, S. 229; ‘Arsenwasserstoff
-im Ballongas (Beseitigung),’ <i>Zeitschr. f. Gew.-Hyg.</i> 1908, Nr. 11, S. 263; ‘Arsenwasserstoff
-beim Ausleeren von Schwefelsäuretanks (Verhütung),’ <i>Gewerbl. techn.
-Ratgeber</i> 1906, Heft 6, S. 109; ‘Arsenfreier Wasserstoff zum Löten,’ <i>Gewerbl. techn.
-Ratgeber</i> 1906, Heft 10, S. 173; und <i>Zeitschr. f. Gew.-Hyg.</i> 1905, Heft 9, S. 252;
-‘Befreiung der Salzsäure vom Arsengehalt,’ <i>Zeitschr. f. Gew.-Hyg.</i> 1903, Heft 21,
-S. 477.</p>
-
-<hr />
-
-<p><span class="pagenum"><a name="Page_355" id="Page_355">[355]</a></span></p>
-
-<h2 id="INDEX">INDEX</h2>
-
-<p>Heavy type refers to the main treatment of the subject and the Roman
-figures in brackets following to the Part of the book: (i) Occurrence
-of Poisoning; (ii) Pathology; (iii) Preventive Measures.</p>
-
-<ul>
-
-<li class="ifrst">Absorption towers, <a href="#Page_256">256</a>, <a href="#Page_258">258</a>, <a href="#Page_289">289</a></li>
-
-<li class="indx">Accumulator manufacture, <a href="#Page_135"><b>135</b></a> (i), <a href="#Page_145">145</a>, <a href="#Page_295">295</a>, <a href="#Page_305"><b>305-9</b></a> (iii)</li>
-
-<li class="indx">Acetic acid, <a href="#Page_9">9</a>, <a href="#Page_46">46</a>, <a href="#Page_333">333</a></li>
-
-<li class="indx">Acetylene, <a href="#Page_52">52</a>, <a href="#Page_85"><b>85-87</b></a> (i), <a href="#Page_278"><b>278</b></a> (iii), <a href="#Page_279">279</a></li>
-
-<li class="indx">Acrolein vapour, <a href="#Page_326">326</a></li>
-
-<li class="indx">Aerograph, <a href="#Page_138">138</a></li>
-
-<li class="indx">Akremnin soap, <a href="#Page_294">294</a></li>
-
-<li class="indx">Alcohol, <a href="#Page_99">99</a>, <a href="#Page_100">100</a>, <a href="#Page_210">210</a>, <a href="#Page_216">216</a>, <a href="#Page_333">333</a></li>
-
-<li class="indx">Alcoholism, <a href="#Page_241">241</a></li>
-
-<li class="indx">Aliphatic series. <a href="#Hydrocarbons">See Hydrocarbons</a></li>
-
-<li class="indx">Alizarin, <a href="#Page_111">111</a>, <a href="#Page_113">113</a></li>
-<li class="isub1">colours, <a href="#Page_3">3</a>, <a href="#Page_10">10</a>, <a href="#Page_57">57</a>, <a href="#Page_96">96</a>, <a href="#Page_111">111</a>, <a href="#Page_112">112</a>, <a href="#Page_114">114</a></li>
-
-<li class="indx">Alkaline bromides, <a href="#Page_36">36</a></li>
-<li class="isub1">hydroxides, <a href="#Page_176">176</a></li>
-
-<li class="indx">Alkaloids, <a href="#Page_216">216</a></li>
-
-<li class="indx">Alternation of employment, <a href="#Page_227"><b>227</b></a> (iii), <a href="#Page_293">293</a>, <a href="#Page_299">299</a></li>
-
-<li class="indx">Amalgam. <a href="#Mercury_amalgam">See Mercury amalgam</a></li>
-
-<li class="indx">Amido compounds, <a href="#Page_110">110</a>, <a href="#Page_112">112</a>, <a href="#Page_201">201</a>, <a href="#Page_211">211</a>, <a href="#Page_212"><b>212</b></a> (ii), <a href="#Page_287">287</a></li>
-
-<li class="indx">Amines, <a href="#Page_33">33</a>, <a href="#Page_107">107</a>, <a href="#Page_111">111</a></li>
-
-<li class="indx">Ammonia, <a href="#Page_44">44</a>, <a href="#Page_68">68</a>, <a href="#Page_71">71</a>, <a href="#Page_72">72</a>, <a href="#Page_76">76-79</a>, <a href="#Page_82">82</a>, <a href="#Page_90"><b>90-93</b></a> (i), <a href="#Page_94">94</a>, <a href="#Page_175"><b>175</b></a> (ii), <a href="#Page_279"><b>279</b></a> (iii), <a href="#Page_280">280</a></li>
-
-<li class="indx" id="Ammonia_soda">Ammonia soda process, <a href="#Page_14">14</a>, <a href="#Page_20"><b>20</b></a> (i), <a href="#Page_92">92</a>, <a href="#Page_258">258</a></li>
-
-<li class="indx">Ammonium carbonate, <a href="#Page_44">44</a>, <a href="#Page_91">91</a>, <a href="#Page_92">92</a></li>
-<li class="isub1">compounds, <a href="#Page_67">67</a>, <a href="#Page_90"><b>90</b></a> (i), <a href="#Page_92">92</a>, <a href="#Page_174"><b>174</b></a> (ii), <a href="#Page_279"><b>279</b></a> (iii)</li>
-<li class="isub1">nitrate, <a href="#Page_44">44</a>, <a href="#Page_115">115</a></li>
-<li class="isub1">oxalate, <a href="#Page_115">115</a></li>
-<li class="isub1">phosphate, <a href="#Page_50">50</a>, <a href="#Page_92">92</a></li>
-<li class="isub1">superphosphate, <a href="#Page_55">55</a></li>
-
-<li class="indx">Amyl alcohol, <a href="#Page_45">45</a>, <a href="#Page_210">210</a></li>
-<li class="isub1">nitrite, <a href="#Page_45">45</a>, <a href="#Page_46">46</a>, <a href="#Page_212">212</a></li>
-
-<li class="indx">Aniline, <a href="#Page_3">3</a>, <a href="#Page_57">57</a>, <a href="#Page_69">69</a>, <a href="#Page_70">70</a>, <a href="#Page_96">96</a>, <a href="#Page_105">105</a>, <a href="#Page_109">109</a>, <a href="#Page_111">111</a>, <a href="#Page_112">112</a>, <a href="#Page_114">114</a>, <a href="#Page_116"><b>116-119</b></a> (i), <a href="#Page_145">145</a>, <a href="#Page_156">156</a>, <a href="#Page_212"><b>212-214</b></a> (ii), <a href="#Page_286"><b>286-288</b></a> (iii)</li>
-
-<li class="indx">Aniline black, <a href="#Page_117">117</a>, <a href="#Page_156">156</a></li>
-<li class="isub1" id="Aniline_colours">colours, <a href="#Page_3">3</a>, <a href="#Page_4">4</a>, <a href="#Page_57">57</a>, <a href="#Page_112">112</a>, <a href="#Page_115">115</a>, <a href="#Page_117">117</a>, <a href="#Page_118">118</a>, <a href="#Page_156">156</a>, <a href="#Page_214">214</a>, <a href="#Page_285"><b>285-288</b></a> (iii)</li>
-<li class="isub1">oil, <a href="#Page_117">117</a>, <a href="#Page_214">214</a></li>
-<li class="isub1">poisoning, <a href="#Page_3">3</a>, <a href="#Page_69">69</a>, <a href="#Page_113">113</a>, <a href="#Page_116"><b>116-119</b></a> (i), <a href="#Page_212"><b>212-214</b></a> (ii), <a href="#Page_256"><b>256-288</b></a> (iii)</li>
-
-<li class="indx">Animal products, <a href="#Page_154">154</a></li>
-
-<li class="indx">Anthracene, <a href="#Page_3">3</a>, <a href="#Page_60">60</a>, <a href="#Page_96">96-97</a>, <a href="#Page_101">101</a>, <a href="#Page_107">107</a>, <a href="#Page_108">108</a>, <a href="#Page_111">111</a>, <a href="#Page_113">113</a>, <a href="#Page_285">285</a></li>
-
-<li class="indx">Anthraquinone, <a href="#Page_55">55</a>, <a href="#Page_111">111</a></li>
-
-<li class="indx">Antimony, <a href="#Page_122">122</a>, <a href="#Page_124">124</a>, <a href="#Page_146"><b>146</b></a> (i)</li>
-<li class="isub1">chloride and oxide, <a href="#Page_37">37</a></li>
-
-<li class="indx">Antipyrin, <a href="#Page_3">3</a>, <a href="#Page_4">4</a>, <a href="#Page_36">36</a>, <a href="#Page_102">102</a>, <a href="#Page_104">104</a>, <a href="#Page_114">114</a></li>
-
-<li class="indx">Argyria, <a href="#Page_45"><b>45</b></a>, <a href="#Page_152">152</a>, <a href="#Page_188">188</a>, <a href="#Page_329">329</a>. <a href="#Silver">See also Silver</a></li>
-
-<li class="indx">Aromatic series. <a href="#Hydrocarbons">See Hydrocarbons</a></li>
-
-<li class="indx" id="Arsenic">Arsenic, <a href="#Page_12">12</a>, <a href="#Page_65">65</a>, <a href="#Page_119">119</a>, <a href="#Page_122">122</a>, <a href="#Page_143"><b>143-146</b></a> (i), <a href="#Page_154">154</a>, <a href="#Page_189">189</a>, <a href="#Page_159"><b>159</b></a> (ii), <a href="#Page_257">257</a>, <a href="#Page_323">323</a>, <a href="#Page_328"><b>328-329</b></a> (iii)</li>
-
-<li class="indx">Arseniuretted hydrogen gas, <a href="#Page_12">12-14</a>, <a href="#Page_32">32</a>, <a href="#Page_113">113</a>, <a href="#Page_114">114</a>, <a href="#Page_145"><b>145-146</b></a> (i), <a href="#Page_148">148</a>, <a href="#Page_149">149</a>, <a href="#Page_188">188</a>, <a href="#Page_189">189</a>, <a href="#Page_197"><b>197</b></a> (ii), <a href="#Page_257">257</a>, <a href="#Page_279">279</a>, <a href="#Page_286">286</a>, <a href="#Page_316">316</a>, <a href="#Page_328"><b>328-329</b></a> (iii)</li>
-
-<li class="indx">Artificial manure, <a href="#Page_38">38</a>, <a href="#Page_53"><b>53</b></a> (i), <a href="#Page_54">54</a>, <a href="#Page_55">55</a>, <a href="#Page_92">92</a>, <a href="#Page_176"><b>176</b></a> (ii), <a href="#Page_261"><b>261-265</b></a> (iii)</li>
-
-<li class="indx">Artificial respiration, <a href="#Page_164">164</a>, <a href="#Page_284"><b>284</b></a> (iii)</li>
-
-<li class="indx">Asphalt, <a href="#Page_98"><b>98</b></a> (i), <a href="#Page_285">285</a></li>
-
-<li class="indx">Aspirin, <a href="#Page_102">102</a></li>
-
-<li class="indx">Azo-colours, <a href="#Page_96">96</a>, <a href="#Page_110">110</a>, <a href="#Page_214">214</a></li>
-
-<li class="ifrst">Balloon filling, <a href="#Page_145">145</a>, <a href="#Page_329">329</a></li>
-
-<li class="indx">Barium chloride, <a href="#Page_16">16</a>, <a href="#Page_66">66</a></li>
-<li class="isub1">nitrate, <a href="#Page_44">44</a></li>
-
-<li class="indx">Barometers, manufacture of, <a href="#Page_141">141</a>, <a href="#Page_142">142</a>, <a href="#Page_328">328</a></li>
-
-<li class="indx">Baryta, <a href="#Page_66">66</a>, <a href="#Page_67">67</a>, <a href="#Page_135">135</a></li>
-
-<li class="indx"><span class="pagenum"><a name="Page_356" id="Page_356">[356]</a></span>Basic slag, <a href="#Page_49">49</a>, <a href="#Page_53">53</a>, <a href="#Page_54"><b>54</b></a> (i), <a href="#Page_148">148</a>, <a href="#Page_261"><b>261-264</b></a> (iii)</li>
-
-<li class="indx">Basophil granules, <a href="#Page_178">178</a></li>
-
-<li class="indx">Baths, <a href="#Page_237">237</a>, <a href="#Page_292">292</a></li>
-
-<li class="indx">Beer brewing, <a href="#Page_65">65</a>, <a href="#Page_154">154</a>, <a href="#Page_333">333</a></li>
-
-<li class="indx">Benzalchloride, <a href="#Page_35">35</a>, <a href="#Page_110">110</a>, <a href="#Page_287">287</a></li>
-
-<li class="indx">Benzaldehyde, <a href="#Page_35">35</a>, <a href="#Page_109">109</a></li>
-
-<li class="indx" id="Benzene">Benzene (Benzene poisoning), <a href="#Page_3">3</a>, <a href="#Page_4">4</a>, <a href="#Page_69">69</a>, <a href="#Page_77">77-79</a>, <a href="#Page_85">85</a>, <a href="#Page_96">96</a>, <a href="#Page_99"><b>99-100</b></a> (i), <a href="#Page_101">101</a>, <a href="#Page_102">102-106</a>, <a href="#Page_112">112-114</a>, <a href="#Page_204"><b>204-208</b></a> (ii), <a href="#Page_285"><b>285-286</b></a> (iii), <a href="#Page_288">288</a>, <a href="#Page_330">330</a></li>
-
-<li class="indx">Benzidine, <a href="#Page_118">118</a></li>
-
-<li class="indx" id="Benzine">Benzine, <a href="#Page_34">34</a>, <a href="#Page_53">53</a>, <a href="#Page_54">54</a>, <a href="#Page_59"><b>59</b></a> (i), <a href="#Page_61"><b>61</b></a>, <a href="#Page_62">62</a>, <a href="#Page_63">63</a>, <a href="#Page_64">64</a>, <a href="#Page_68">68</a>, <a href="#Page_69">69</a>, <a href="#Page_85">85</a>, <a href="#Page_96">96</a>, <a href="#Page_156">156</a>, <a href="#Page_203">203</a>, <a href="#Page_204"><b>204</b></a> (ii), <a href="#Page_267"><b>267</b></a> (iii), <a href="#Page_268">268</a>, <a href="#Page_330">330</a></li>
-
-<li class="indx">Benzol. <a href="#Benzene">See Benzene</a></li>
-
-<li class="indx">Benzo-trichloride, <a href="#Page_35">35</a>, <a href="#Page_109">109</a>, <a href="#Page_287">287</a></li>
-
-<li class="indx">Benzoyl chloride, <a href="#Page_35">35</a>, <a href="#Page_209">209</a></li>
-
-<li class="indx">Benzyl chloride, <a href="#Page_35">35</a></li>
-
-<li class="indx">Bessemer process, <a href="#Page_148">148</a></li>
-
-<li class="indx">Beth filter, <a href="#Page_254">254</a></li>
-
-<li class="indx">Bichromate, <a href="#Page_50">50</a>, <a href="#Page_54">54</a>, <a href="#Page_55">55</a>. <a href="#Chromates">See Chromates</a></li>
-
-<li class="indx">Bladder, cancer of, <a href="#Page_114">114</a>, <a href="#Page_117">117</a>, <a href="#Page_214">214</a></li>
-
-<li class="indx">Blast furnace, <a href="#Page_146"><b>146</b></a> (i), <a href="#Page_289"><b>289</b></a> (iii)</li>
-<li class="isub1">gas, <a href="#Page_65">65</a>, <a href="#Page_82">82</a>, <a href="#Page_88">88</a>, <a href="#Page_89"><b>89</b></a> (i), <a href="#Page_146">146</a>, <a href="#Page_289"><b>289-290</b></a> (iii)</li>
-
-<li class="indx">Blasting gelatine, <a href="#Page_47">47</a></li>
-
-<li class="indx">Bleaching, <a href="#Page_156">156</a>, <a href="#Page_337">337</a></li>
-<li class="isub1" id="Bleaching_powder">powder, <a href="#Page_26"><b>26</b></a> (i), <a href="#Page_259"><b>259</b></a> (iii)</li>
-
-<li class="indx">Blood poisons, <a href="#Page_158">158</a>, <a href="#Page_164">164</a>, <a href="#Page_199">199-201</a>, <a href="#Page_211">211-214</a></li>
-
-<li class="indx">Bone extraction, <a href="#Page_68">68</a>, <a href="#Page_69">69</a>, <a href="#Page_267">267</a></li>
-
-<li class="indx">Boracic acid, <a href="#Page_138">138</a></li>
-
-<li class="indx">Bottle capsules, <a href="#Page_323">323</a></li>
-
-<li class="indx">Brass (brass-casters’ ague), <a href="#Page_152"><b>152</b></a> (i), <a href="#Page_182"><b>182</b></a> (ii), <a href="#Page_188">188</a>, <a href="#Page_325"><b>325</b></a> (iii)</li>
-
-<li class="indx">Breathing apparatus, <a href="#Page_231"><b>231-237</b></a> (iii), <a href="#Page_267">267</a>, <a href="#Page_286">286</a>, <a href="#Page_288">288</a>, <a href="#Page_290">290</a>, <a href="#Page_310">310</a></li>
-
-<li class="indx">Briquettes, <a href="#Page_96">96</a>, <a href="#Page_101">101</a></li>
-
-<li class="indx">Bromine, <a href="#Page_29"><b>29</b></a> (i), <a href="#Page_36">36</a>, <a href="#Page_52">52</a>, <a href="#Page_173"><b>173</b></a> (ii)</li>
-
-<li class="indx">Bronze, <a href="#Page_45">45</a>, <a href="#Page_139">139</a>, <a href="#Page_316">316</a></li>
-
-<li class="indx">Brunswick green, <a href="#Page_144">144</a></li>
-
-<li class="indx">Butyl alcohol, <a href="#Page_210">210</a></li>
-
-<li class="indx">Butyric acid, <a href="#Page_75">75</a></li>
-
-<li class="ifrst">Calamine, <a href="#Page_125">125</a></li>
-
-<li class="indx">Calcium carbide, <a href="#Page_52">52</a>, <a href="#Page_85"><b>85</b></a> (i), <a href="#Page_87">87</a>, <a href="#Page_90">90</a>, <a href="#Page_278">278</a></li>
-<li class="isub1">sulphide (soda waste), <a href="#Page_18">18</a></li>
-
-<li class="indx">Calomel, <a href="#Page_143"><b>143</b></a></li>
-
-<li class="indx">Camphor, <a href="#Page_49">49</a></li>
-
-<li class="indx">Cancer, <a href="#Page_64">64</a>, <a href="#Page_102">102</a>, <a href="#Page_114">114</a>, <a href="#Page_118">118</a>, <a href="#Page_203">203</a>, <a href="#Page_214">214</a></li>
-
-<li class="indx">Carbon bisulphide, poisoning by, <a href="#Page_30">30</a>, <a href="#Page_31">31</a>, <a href="#Page_34">34</a>, <a href="#Page_50">50</a>, <a href="#Page_65">65</a>, <a href="#Page_68"><b>68</b></a> (i), <a href="#Page_68">68-71</a>, <a href="#Page_74">74</a>, <a href="#Page_80">80</a>, <a href="#Page_93">93</a>, <a href="#Page_96">96</a>, <a href="#Page_104">104</a>, <a href="#Page_156">156</a>, <a href="#Page_192">192</a>, <a href="#Page_193"><b>193-195</b></a> (ii), <a href="#Page_271"><b>271-275</b></a> (iii)</li>
-<li class="isub1" id="Carbon_oxychloride">oxychloride, <a href="#Page_32"><b>32</b></a> (i), <a href="#Page_33">33</a>, <a href="#Page_294"><b>294</b></a> (iii)</li>
-<li class="isub1">tetrachloride, <a href="#Page_34"><b>34</b></a> (i), <a href="#Page_69">69</a>, <a href="#Page_208">208</a>, <a href="#Page_268">268</a>, <a href="#Page_275">275</a></li>
-
-<li class="indx">Carbonic acid gas (carbon dioxide), <a href="#Page_17"><b>17</b></a>, <a href="#Page_50">50</a>, <a href="#Page_53">53</a>, <a href="#Page_54">54</a>, <a href="#Page_68">68</a>, <a href="#Page_74">74</a>, <a href="#Page_82">82</a>, <a href="#Page_131">131</a>, <a href="#Page_149">149</a>, <a href="#Page_153">153</a>, <a href="#Page_201"><b>201-202</b></a> (ii), <a href="#Page_330">330</a>, <a href="#Page_332">332</a></li>
-<li class="isub1">oxide, <a href="#Page_17">17</a>, <a href="#Page_21">21</a>, <a href="#Page_31">31</a>, <a href="#Page_32">32</a>, <a href="#Page_50">50</a>, <a href="#Page_74">74-76</a>, <a href="#Page_80">80</a>, <a href="#Page_82">82</a>, <a href="#Page_87"><b>87-90</b></a> (i), <a href="#Page_102">102</a>, <a href="#Page_107">107</a>, <a href="#Page_119">119</a>, <a href="#Page_148">148</a>, <a href="#Page_149">149</a>, <a href="#Page_153">153</a>, <a href="#Page_154">154</a>, <a href="#Page_156">156</a>, <a href="#Page_188">188</a>, <a href="#Page_199"><b>199-200</b></a> (ii), <a href="#Page_288">288</a>, <a href="#Page_289">289</a>, <a href="#Page_323">323</a>, <a href="#Page_330">330</a>, <a href="#Page_332">332</a></li>
-
-<li class="indx">Carbonising, <a href="#Page_156">156</a>, <a href="#Page_336">336</a></li>
-
-<li class="indx">Carborundum. <a href="#Silicon_carbide">See Silicon carbide</a></li>
-
-<li class="indx">Carburetted gas, <a href="#Page_61">61</a>, <a href="#Page_83">83</a>, <a href="#Page_87">87</a></li>
-
-<li class="indx">Caustic alkali, <a href="#Page_25">25</a></li>
-<li class="isub1">potash, <a href="#Page_3">3</a>, <a href="#Page_25">25</a>, <a href="#Page_34">34</a>, <a href="#Page_176">176</a></li>
-<li class="isub1">soda, <a href="#Page_18">18</a>, <a href="#Page_19">19</a>, <a href="#Page_25">25</a>, <a href="#Page_36">36</a>, <a href="#Page_157">157</a>, <a href="#Page_176">176</a></li>
-
-<li class="indx">Celluloid, <a href="#Page_48">48</a>, <a href="#Page_49">49</a></li>
-
-<li class="indx">Cellulose, <a href="#Page_156">156</a>, <a href="#Page_336">336</a></li>
-
-<li class="indx">Chamber acid, <a href="#Page_5">5</a>, <a href="#Page_8">8</a>, <a href="#Page_53">53</a>, <a href="#Page_258">258</a></li>
-
-<li class="indx">Chance-Claus process, <a href="#Page_19">19</a></li>
-
-<li class="indx">Chemical cleaning. <a href="#Benzine">See Benzine industry</a>, <a href="#Page_1"><b>1</b></a> (i), <a href="#Page_134">134</a>, <a href="#Page_145">145</a>, <a href="#Page_256"><b>256</b></a> (iii)</li>
-
-<li class="indx">Chili saltpetre, <a href="#Page_35">35</a>, <a href="#Page_39">39</a>, <a href="#Page_41">41</a>, <a href="#Page_45">45</a>, <a href="#Page_54">54</a></li>
-
-<li class="indx">Chloral, <a href="#Page_34">34</a></li>
-
-<li class="indx" id="Chlorates">Chlorates, <a href="#Page_23"><b>23</b></a> (i), <a href="#Page_25">25</a>, <a href="#Page_26">26</a>, <a href="#Page_29">29</a>, <a href="#Page_30">30</a>, <a href="#Page_52">52</a></li>
-
-<li class="indx">Chloride of lime. <a href="#Bleaching_powder">See Bleaching powder</a></li>
-<li class="isub1">sulphur, <a href="#Page_31">31</a>, <a href="#Page_32">32</a>, <a href="#Page_68">68</a>, <a href="#Page_70">70</a>, <a href="#Page_174">174</a>, <a href="#Page_272">272-274</a></li>
-
-<li class="indx">Chlorides, <a href="#Page_30"><b>30</b></a> (i), <a href="#Page_174"><b>174</b></a> (ii)</li>
-
-<li class="indx">Chlorine, <a href="#Page_23"><b>23</b></a> (i), <a href="#Page_25">25</a>, <a href="#Page_26">26</a>, <a href="#Page_27">27</a>, <a href="#Page_30">30-32</a>, <a href="#Page_34">34</a>, <a href="#Page_35">35</a>, <a href="#Page_39">39</a>, <a href="#Page_44">44</a>, <a href="#Page_52">52</a>, <a href="#Page_58">58</a>, <a href="#Page_156">156</a>, <a href="#Page_173"><b>173</b></a> (ii), <a href="#Page_209">209</a>, <a href="#Page_259"><b>259</b></a> (iii), <a href="#Page_285">285</a></li>
-<li class="isub1">rash, <a href="#Page_28">28</a>, <a href="#Page_35">35</a>, <a href="#Page_173">173</a>, <a href="#Page_174">174</a>, <a href="#Page_209">209</a>, <a href="#Page_259">259</a></li>
-
-<li class="indx">Chlorine compounds, organic, <a href="#Page_27">27</a>, <a href="#Page_69">69</a>, <a href="#Page_209">209</a>, <a href="#Page_285">285</a></li>
-
-<li class="indx">Chloroform, <a href="#Page_26">26</a>, <a href="#Page_33">33</a>, <a href="#Page_34">34</a>, <a href="#Page_208">208</a></li>
-
-<li class="indx">Chrome colours, <a href="#Page_55">55</a>, <a href="#Page_56">56</a>, <a href="#Page_265">265</a></li>
-<li class="isub1">poisoning, <a href="#Page_52">52</a>, <a href="#Page_56"><b>56</b></a> (i), <a href="#Page_57">57</a>, <a href="#Page_58">58</a>, <a href="#Page_114">114</a>, <a href="#Page_153">153</a>, <a href="#Page_185"><b>185</b></a> (ii), <a href="#Page_265"><b>265</b></a> (iii)</li>
-<li class="isub1">tanning, <a href="#Page_55"><b>55</b></a> (i), <a href="#Page_57">57</a>, <a href="#Page_58">58</a>, <a href="#Page_266"><b>266</b></a> (iii)</li>
-<li class="isub1">yellow, <a href="#Page_44">44</a>, <a href="#Page_55">55</a>, <a href="#Page_57">57</a></li>
-
-<li class="indx" id="Chromates">Chromium (chromates), <a href="#Page_3">3</a>, <a href="#Page_52">52</a>, <a href="#Page_55"><b>55</b></a> (i)-58, <a href="#Page_114">114</a>, <a href="#Page_134">134</a>, <a href="#Page_153">153</a>, <a href="#Page_185"><b>185</b></a> (ii), <a href="#Page_265"><b>265</b></a> (iii), <a href="#Page_271">271</a></li>
-
-<li class="indx">Coal tar. <a href="#Tar">See Tar</a></li>
-
-<li class="indx">Cobalt, <a href="#Page_144"><b>144</b></a></li>
-
-<li class="indx">Coke ovens, <a href="#Page_77"><b>77</b></a> (i), <a href="#Page_78">78</a>, <a href="#Page_79">79</a>, <a href="#Page_92">92</a>, <a href="#Page_102">102</a>, <a href="#Page_104">104</a>, <a href="#Page_276"><b>276</b></a> (iii)</li>
-
-<li class="indx">Compositors. <a href="#Printing">See Printing</a></li>
-
-<li class="indx">Condensation, <a href="#Page_255"><b>255</b></a> (iii), <a href="#Page_323">323</a>, <a href="#Page_327">327</a></li>
-<li class="isub1">of mercury, <a href="#Page_141">141</a></li>
-<li class="isub1">zinc, <a href="#Page_125">125</a></li>
-
-<li class="indx">Copper, <a href="#Page_151"><b>151</b></a> (i), <a href="#Page_188"><b>188</b></a> (ii)</li>
-
-<li class="indx">Cresols, <a href="#Page_96">96</a>, <a href="#Page_101">101</a>, <a href="#Page_109">109</a></li>
-
-<li class="indx">Cumene, <a href="#Page_207">207</a></li>
-
-<li class="indx">Cyanogen, <a href="#Page_77">77</a>, <a href="#Page_93"><b>93</b></a> (i), <a href="#Page_152">152</a>, <a href="#Page_195"><b>195</b></a> (ii), <a href="#Page_261">261</a>, <a href="#Page_279">279</a>, <a href="#Page_280"><b>280</b></a> (iii)</li>
-<li class="isub1"><span class="pagenum"><a name="Page_357" id="Page_357">[357]</a></span>compounds, <a href="#Page_71">71</a>, <a href="#Page_79">79</a>, <a href="#Page_92">92</a>, <a href="#Page_93"><b>93</b></a> (i), <a href="#Page_94">94</a>, <a href="#Page_95">95</a>, <a href="#Page_103">103</a>, <a href="#Page_152">152</a>, <a href="#Page_154">154</a>, <a href="#Page_195"><b>195</b></a> (ii), <a href="#Page_196">196</a>, <a href="#Page_262">262</a>, <a href="#Page_279">279</a>, <a href="#Page_280"><b>280</b></a> (iii), <a href="#Page_289">289</a></li>
-
-<li class="ifrst">Deacon process, <a href="#Page_23">23</a>, <a href="#Page_28">28</a></li>
-
-<li class="indx">Denitration, <a href="#Page_6">6</a>, <a href="#Page_43">43</a>, <a href="#Page_47">47</a>, <a href="#Page_48">48</a>, <a href="#Page_287">287</a></li>
-
-<li class="indx">Desilverising, <a href="#Page_124">124</a>, <a href="#Page_126">126</a>, <a href="#Page_128">128</a></li>
-
-<li class="indx">Diaphragm method (chlorine), <a href="#Page_24">24</a></li>
-
-<li class="indx">Diazo-compounds, <a href="#Page_110">110</a>, <a href="#Page_286">286</a></li>
-
-<li class="indx">Diethyl sulphate, <a href="#Page_23">23</a></li>
-
-<li class="indx">Digestive tract, diseases of, <a href="#Page_76">76</a>, <a href="#Page_129">129</a>, <a href="#Page_130">130</a>, <a href="#Page_133">133</a>, <a href="#Page_179">179</a>, <a href="#Page_182">182</a>, <a href="#Page_186">186</a></li>
-
-<li class="indx">Dimethyl aniline, <a href="#Page_109">109</a></li>
-
-<li class="indx">Dinitrobenzene, <a href="#Page_35">35</a>, <a href="#Page_108">108</a>, <a href="#Page_112">112</a>, <a href="#Page_115">115</a>, <a href="#Page_116">116</a>, <a href="#Page_212">212</a></li>
-
-<li class="indx">Dinitrochlorobenzene, <a href="#Page_115">115</a>, <a href="#Page_209">209</a>, <a href="#Page_212">212</a></li>
-
-<li class="indx">Dinitrophenol, <a href="#Page_115">115</a>, <a href="#Page_212">212</a>, <a href="#Page_213">213</a></li>
-
-<li class="indx">Dinitrotoluol, <a href="#Page_108">108</a>, <a href="#Page_212">212</a></li>
-
-<li class="indx">Distillation, <a href="#Page_253">253</a>, <a href="#Page_255">255</a></li>
-<li class="isub1">of alcohol, <a href="#Page_333">333</a></li>
-<li class="isub1">petroleum. <a href="#Petroleum">See Petroleum distillation</a></li>
-<li class="isub1">tar. <a href="#Tar">See Tar distillation</a></li>
-
-<li class="indx">Dowson gas, <a href="#Page_82">82</a>, <a href="#Page_83">83</a>, <a href="#Page_87">87</a>, <a href="#Page_276">276</a></li>
-
-<li class="indx">Dräger’s oxygen apparatus, <a href="#Page_165">165-167</a></li>
-
-<li class="indx">Dry cleaning. <a href="#Benzine">See Benzine</a></li>
-
-<li class="indx">Dust removal, <a href="#Page_243"><b>243-256</b></a> (iii). <a href="#Ventilation">See also Ventilation</a></li>
-
-<li class="indx">Dye stuffs, <a href="#Page_107"><b>107-119</b></a> (i), <a href="#Page_214"><b>214</b></a> (ii), <a href="#Page_285"><b>285-288</b></a> (iii), <a href="#Page_337">337</a></li>
-
-<li class="indx">Dyeing and colouring, <a href="#Page_44">44</a>, <a href="#Page_45">45</a>, <a href="#Page_55">55</a>, <a href="#Page_57">57</a>, <a href="#Page_92">92</a>, <a href="#Page_134">134</a>, <a href="#Page_144">144</a>, <a href="#Page_156">156</a>, <a href="#Page_265">265</a>, <a href="#Page_310">310-316</a>, <a href="#Page_337">337</a></li>
-
-<li class="indx">Dynamite, <a href="#Page_43">43</a>, <a href="#Page_47">47</a></li>
-
-<li class="ifrst">Earthenware. <a href="#Pottery">See Pottery</a></li>
-
-<li class="indx">Eczema, <a href="#Page_64">64</a>, <a href="#Page_186">186</a></li>
-
-<li class="indx">Electric furnace, <a href="#Page_85">85</a></li>
-
-<li class="indx">Electroplating, <a href="#Page_196">196</a>, <a href="#Page_327">327</a>, <a href="#Page_329">329</a></li>
-
-<li class="indx">Enamel, <a href="#Page_135">135</a>, <a href="#Page_322">322</a></li>
-
-<li class="indx">Encephalopathy, <a href="#Page_181">181</a></li>
-
-<li class="indx">Etching on glass and metal, <a href="#Page_37">37</a>, <a href="#Page_40">40</a>, <a href="#Page_45">45</a>, <a href="#Page_57">57</a></li>
-
-<li class="indx">Ether, <a href="#Page_68">68</a>, <a href="#Page_69">69</a></li>
-
-<li class="indx">Ethyl alcohol, <a href="#Page_34">34</a>, <a href="#Page_210">210</a></li>
-<li class="isub1">chloride, <a href="#Page_34">34</a></li>
-
-<li class="indx">Explosives, <a href="#Page_45"><b>45</b></a> (i), <a href="#Page_49">49</a>, <a href="#Page_115">115</a>, <a href="#Page_260"><b>260</b></a> (iii)</li>
-
-<li class="indx">Extraction, <a href="#Page_54">54</a>, <a href="#Page_61">61</a>, <a href="#Page_68"><b>68</b></a> (i), <a href="#Page_68">68-69</a>, <a href="#Page_71">71</a>, <a href="#Page_100">100</a>, <a href="#Page_103">103</a>, <a href="#Page_117">117</a>, <a href="#Page_186">186</a>, <a href="#Page_253"><b>253</b></a> (iii), <a href="#Page_267">267</a>, <a href="#Page_272">272-274</a></li>
-
-<li class="indx">Eye affections, <a href="#Page_21">21</a>, <a href="#Page_23">23</a>, <a href="#Page_38">38</a>, <a href="#Page_55">55</a>, <a href="#Page_57">57</a>, <a href="#Page_65">65</a>, <a href="#Page_68">68</a>, <a href="#Page_70">70</a>, <a href="#Page_75">75</a>, <a href="#Page_93">93</a>, <a href="#Page_115">115</a>, <a href="#Page_116">116</a>, <a href="#Page_119">119</a>, <a href="#Page_171">171</a>, <a href="#Page_174">174</a>, <a href="#Page_175">175</a>, <a href="#Page_210">210</a></li>
-
-<li class="ifrst">Fans, <a href="#Page_244"><b>244-247</b></a> (iii). <a href="#Ventilation">See also Ventilation</a></li>
-
-<li class="indx">Fat extraction, <a href="#Page_34">34</a>, <a href="#Page_61">61</a>, <a href="#Page_68">68</a>, <a href="#Page_70">70</a>, <a href="#Page_71">71</a>, <a href="#Page_272">272-274</a></li>
-
-<li class="indx">Fermentation, <a href="#Page_154">154</a>, <a href="#Page_333">333</a></li>
-
-<li class="indx">Ferrosilicon, <a href="#Page_53">53</a>, <a href="#Page_85">85</a>, <a href="#Page_146">146</a>, <a href="#Page_149"><b>149-151</b></a> (i), <a href="#Page_199">199</a>, <a href="#Page_291"><b>291</b></a> (iii)</li>
-
-<li class="indx">File cutting, <a href="#Page_140"><b>140</b></a> (i), <a href="#Page_294">294</a>, <a href="#Page_322"><b>322-323</b></a> (iii)</li>
-
-<li class="indx">Fluorine. <a href="#Hydrofluoric_acid">See Hydrofluoric acid</a></li>
-
-<li class="indx">Fluorine compounds, <a href="#Page_37">37</a>, <a href="#Page_54">54</a>, <a href="#Page_153">153</a>, <a href="#Page_171">171</a>, <a href="#Page_265">265</a></li>
-
-<li class="indx">Flux, <a href="#Page_135">135</a>, <a href="#Page_149">149</a></li>
-
-<li class="indx">Frit, <a href="#Page_135">135</a>, <a href="#Page_136">136</a>, <a href="#Page_137">137</a>, <a href="#Page_138">138</a>, <a href="#Page_320">320</a></li>
-
-<li class="indx">Fuchsin, <a href="#Page_111">111</a>, <a href="#Page_113">113</a>, <a href="#Page_119">119</a>, <a href="#Page_144">144</a>, <a href="#Page_287">287</a></li>
-
-<li class="indx">Fulminate of mercury, <a href="#Page_46"><b>46</b></a> (i), <a href="#Page_143">143</a>, <a href="#Page_261">261</a></li>
-
-<li class="ifrst">Galvanising, <a href="#Page_94">94</a>, <a href="#Page_95">95</a>, <a href="#Page_152">152</a>, <a href="#Page_326">326</a>, <a href="#Page_329">329</a></li>
-
-<li class="indx">Gas engines, <a href="#Page_82">82</a>, <a href="#Page_88">88</a>, <a href="#Page_89">89</a>, <a href="#Page_100">100</a>, <a href="#Page_276"><b>276-278</b></a> (iii)</li>
-<li class="isub1">lighting, <a href="#Page_71"><b>71-89</b></a> (i), <a href="#Page_92">92</a>, <a href="#Page_93">93</a>, <a href="#Page_175">175</a>, <a href="#Page_275"><b>275</b></a> (iii)</li>
-<li class="isub1">lime, <a href="#Page_65">65</a>, <a href="#Page_94">94</a>, <a href="#Page_153">153</a>, <a href="#Page_275">275</a></li>
-<li class="isub1">purifying material, <a href="#Page_5">5</a>, <a href="#Page_65">65</a>, <a href="#Page_68">68</a>, <a href="#Page_74">74</a>, <a href="#Page_75">75</a>, <a href="#Page_93"><b>93</b></a> (i), <a href="#Page_275"><b>275</b></a> (iii), <a href="#Page_276">276</a></li>
-
-<li class="indx">Gay-Lussac tower, <a href="#Page_5">5</a>, <a href="#Page_6">6</a>, <a href="#Page_10">10</a>, <a href="#Page_11">11</a>, <a href="#Page_256">256</a>, <a href="#Page_257">257</a>, <a href="#Page_287">287</a></li>
-
-<li class="indx">Generator gas. <a href="#Producer_gas">See Producer gas</a></li>
-
-<li class="indx">Glass etching, <a href="#Page_37">37</a>, <a href="#Page_38">38</a>, <a href="#Page_153">153</a>, <a href="#Page_330">330</a></li>
-<li class="isub1">industry, <a href="#Page_19">19</a>, <a href="#Page_37">37</a>, <a href="#Page_39">39</a>, <a href="#Page_55">55</a>, <a href="#Page_58">58</a>, <a href="#Page_82">82</a>, <a href="#Page_88">88</a>, <a href="#Page_138">138</a>, <a href="#Page_143">143</a>, <a href="#Page_153"><b>153</b></a> (i), <a href="#Page_322">322</a></li>
-<li class="isub1">pearl silvering, <a href="#Page_152">152</a></li>
-
-<li class="indx">Glazing, <a href="#Page_135"><b>135-138</b></a> (i), <a href="#Page_319"><b>319-322</b></a> (iii)</li>
-
-<li class="indx">Glover acid, <a href="#Page_6">6</a>, <a href="#Page_8">8</a></li>
-<li class="isub1">tower, <a href="#Page_5">5</a>, <a href="#Page_6">6</a>, <a href="#Page_257">257</a>, <a href="#Page_287">287</a></li>
-
-<li class="indx">Gold, <a href="#Page_44">44</a>, <a href="#Page_94">94</a>, <a href="#Page_125">125</a>, <a href="#Page_152">152</a></li>
-
-<li class="indx">Gun-cotton, <a href="#Page_47">47-49</a></li>
-
-<li class="indx">Guttapercha, <a href="#Page_69">69</a></li>
-
-<li class="ifrst">Hæmolysis, <a href="#Page_158">158</a></li>
-
-<li class="indx">Halogens, <a href="#Page_31"><b>31</b></a> (i), <a href="#Page_173"><b>173-174</b></a> (ii)</li>
-
-<li class="indx">Hargreaves process, <a href="#Page_19">19</a>, <a href="#Page_28">28</a></li>
-
-<li class="indx">Hatters’ furriers’ processes, <a href="#Page_45">45</a>, <a href="#Page_141">141</a>, <a href="#Page_142">142</a>, <a href="#Page_154">154</a>, <a href="#Page_327">327</a></li>
-
-<li class="indx">Hausmannite, <a href="#Page_58">58</a></li>
-
-<li class="indx">Health register, <a href="#Page_227">227</a>, <a href="#Page_264">264</a>, <a href="#Page_274">274</a>, <a href="#Page_298">298</a>, <a href="#Page_304">304</a>, <a href="#Page_307">307</a></li>
-
-<li class="indx">Hides and skins, preparation of, <a href="#Page_142">142</a>, <a href="#Page_143">143</a>, <a href="#Page_144">144</a>, <a href="#Page_184">184</a>, <a href="#Page_327">327</a></li>
-
-<li class="indx">Hops, sulphuring of, <a href="#Page_154">154</a>, <a href="#Page_333">333</a></li>
-
-<li class="indx" id="House_painting">House painting, <a href="#Page_121">121</a>, <a href="#Page_122">122</a>, <a href="#Page_132"><b>132-133</b></a> (i), <a href="#Page_294">294</a>, <a href="#Page_314"><b>314-316</b></a> (iii)</li>
-
-<li class="indx" id="Hydrocarbons">Hydrocarbons, <a href="#Page_96">96</a>, <a href="#Page_106">106</a>, <a href="#Page_158">158</a>, <a href="#Page_286">286</a>, <a href="#Page_287">287</a>, <a href="#Page_330">330</a>, <a href="#Page_331">331</a></li>
-<li class="isub1">(aliphatic), <a href="#Page_96">96</a>, <a href="#Page_202">202</a></li>
-<li class="isub1">(aromatic), <a href="#Page_96">96</a>, <a href="#Page_108">108</a>, <a href="#Page_109">109</a>, <a href="#Page_202">202</a>, <a href="#Page_204">204</a>, <a href="#Page_330">330</a></li>
-
-<li class="indx">Hydrochloric acid, <a href="#Page_14"><b>14</b></a> (i), <a href="#Page_15">15</a>, <a href="#Page_20">20</a>, <a href="#Page_21">21</a>, <a href="#Page_23">23</a>, <a href="#Page_30">30-35</a>, <a href="#Page_39">39</a>, <a href="#Page_44">44</a>, <a href="#Page_50">50</a>, <a href="#Page_54">54</a>, <a href="#Page_59">59</a>, <a href="#Page_113">113</a>, <a href="#Page_145">145</a>, <a href="#Page_131">131</a>, <a href="#Page_170"><b>170</b></a> (ii), <a href="#Page_257"><b>257-258</b></a> (iii), <a href="#Page_286">286</a>, <a href="#Page_326">326</a></li>
-
-<li class="indx" id="Hydrofluoric_acid">Hydrofluoric acid, <a href="#Page_29"><b>29</b></a> (i), <a href="#Page_37">37</a>, <a href="#Page_38">38</a>, <a href="#Page_50">50</a>, <a href="#Page_54">54</a>, <a href="#Page_96">96</a>, <a href="#Page_153">153</a>, <a href="#Page_171"><b>171</b></a> (ii), <a href="#Page_265"><b>265</b></a> (iii)</li>
-
-<li class="indx">Hypochlorite, <a href="#Page_25">25</a>, <a href="#Page_30">30</a></li>
-
-<li class="ifrst"><span class="pagenum"><a name="Page_358" id="Page_358">[358]</a></span>Incandescent lamps, <a href="#Page_141">141</a>, <a href="#Page_327">327</a></li>
-
-<li class="indx" id="Indiarubber">Indiarubber, <a href="#Page_31">31</a>, <a href="#Page_61">61</a>, <a href="#Page_63">63</a>, <a href="#Page_68"><b>68-71</b></a> (i), <a href="#Page_100">100</a>, <a href="#Page_103">103</a>, <a href="#Page_134">134</a>, <a href="#Page_194">194</a>, <a href="#Page_267">267</a>, <a href="#Page_271"><b>271-274</b></a> (iii)</li>
-
-<li class="indx">Indigo, <a href="#Page_34">34</a>, <a href="#Page_92">92</a>, <a href="#Page_111">111</a></li>
-
-<li class="indx">Injectors, <a href="#Page_245">245</a></li>
-
-<li class="indx">Insurance, Workmen’s, <a href="#Page_224">224</a></li>
-
-<li class="indx">International Labour Bureau, <a href="#Page_219">219</a></li>
-
-<li class="indx">Iodine, <a href="#Page_30"><b>30</b></a> (i), <a href="#Page_36">36</a>, <a href="#Page_173"><b>173</b></a> (ii)</li>
-<li class="isub1">compounds and poisoning, <a href="#Page_36">36</a></li>
-
-<li class="indx">Iron, <a href="#Page_44">44</a>, <a href="#Page_124">124</a>, <a href="#Page_144">144</a>, <a href="#Page_146"><b>146-149</b></a> (i), <a href="#Page_289"><b>289-291</b></a> (iii)</li>
-
-<li class="ifrst" id="Kidney_disease">Kidney disease, <a href="#Page_57">57</a>, <a href="#Page_130">130</a>, <a href="#Page_181">181</a>, <a href="#Page_185">185</a>, <a href="#Page_215">215</a></li>
-
-<li class="ifrst">Lampblack, <a href="#Page_97">97</a></li>
-
-<li class="indx">Lead, <a href="#Page_8">8</a>, <a href="#Page_13">13</a>, <a href="#Page_29">29</a>, <a href="#Page_44">44</a>, <a href="#Page_55">55</a>, <a href="#Page_68">68</a>, <a href="#Page_69">69</a>, <a href="#Page_120"><b>120-140</b></a> (i), <a href="#Page_144">144</a>, <a href="#Page_149">149</a>, <a href="#Page_152">152</a>, <a href="#Page_156">156</a>, <a href="#Page_177"><b>177-182</b></a> (ii), <a href="#Page_329">329</a></li>
-<li class="isub1">acetate, <a href="#Page_55">55</a>, <a href="#Page_131">131</a>, <a href="#Page_134">134</a></li>
-<li class="isub1">burning, <a href="#Page_140">140</a>, <a href="#Page_323">323</a></li>
-<li class="isub1">carbonate. <a href="#White_lead">See White lead</a></li>
-<li class="isub1">chloride, <a href="#Page_55">55</a>, <a href="#Page_181">181</a></li>
-<li class="isub1">chromate, <a href="#Page_55">55</a>, <a href="#Page_57">57</a>, <a href="#Page_132">132</a>, <a href="#Page_134">134</a>, <a href="#Page_138">138</a>, <a href="#Page_310">310</a></li>
-<li class="isub1">colic, <a href="#Page_179">179</a>. <a href="#Lead_poisoning">See Lead poisoning</a></li>
-<li class="isub1">colours, <a href="#Page_131"><b>131-134</b></a> (i), <a href="#Page_293">293</a>, <a href="#Page_294">294</a>, <a href="#Page_295">295</a>, <a href="#Page_310"><b>310-316</b></a> (iii)</li>
-<li class="isub1">nitrate, <a href="#Page_50">50</a>, <a href="#Page_55">55</a></li>
-<li class="isub1">oxide, <a href="#Page_44">44</a>, <a href="#Page_45">45</a>, <a href="#Page_122">122</a>, <a href="#Page_131">131</a>, <a href="#Page_134">134</a>, <a href="#Page_135">135</a>, <a href="#Page_136">136</a>, <a href="#Page_137">137</a>, <a href="#Page_181">181</a></li>
-<li class="isub1">piping, <a href="#Page_140">140</a>, <a href="#Page_323">323</a></li>
-<li class="isub1" id="Lead_poisoning">poisoning, <a href="#Page_3">3</a>, <a href="#Page_13">13</a>, <a href="#Page_44">44</a>, <a href="#Page_69">69</a>, <a href="#Page_93">93</a>, <a href="#Page_114">114</a>, <a href="#Page_120"><b>120-122</b></a> (i), <a href="#Page_146">146</a>, <a href="#Page_149">149-152</a>, <a href="#Page_177"><b>177-182</b></a> (ii), <a href="#Page_292"><b>292-323</b></a> (iii)</li>
-<li class="isub1">silicate, <a href="#Page_135">135</a></li>
-<li class="isub1">smelting, <a href="#Page_122"><b>122-131</b></a> (i), <a href="#Page_299"><b>299-305</b></a> (iii)</li>
-<li class="isub1">sulphate, <a href="#Page_55">55</a>, <a href="#Page_122">122</a>, <a href="#Page_181">181</a></li>
-<li class="isub1">sulphide, <a href="#Page_122">122</a>, <a href="#Page_131">131</a>, <a href="#Page_136">136</a>, <a href="#Page_293"><b>293</b></a> (iii)</li>
-
-<li class="indx">Leblanc soda process, <a href="#Page_14"><b>14</b></a> (i), <a href="#Page_18">18</a>, <a href="#Page_19">19</a></li>
-
-<li class="indx">Light oils, <a href="#Page_98">98</a></li>
-
-<li class="indx">Ligroine, <a href="#Page_61">61</a></li>
-
-<li class="indx">Lime kilns, <a href="#Page_55">55</a>, <a href="#Page_153">153</a>, <a href="#Page_330">330</a></li>
-
-<li class="indx">Litharge, <a href="#Page_124">124</a>, <a href="#Page_126">126</a>, <a href="#Page_129">129</a>, <a href="#Page_131">131</a>, <a href="#Page_132">132</a>, <a href="#Page_134">134</a>, <a href="#Page_135">135</a>, <a href="#Page_138">138</a>, <a href="#Page_300">300-305</a></li>
-
-<li class="indx">Lithopone. <a href="#Zinc_white">See Zinc white</a></li>
-
-<li class="indx">Lungs, diseases of, <a href="#Page_9">9</a>, <a href="#Page_40">40</a>, <a href="#Page_54">54</a>, <a href="#Page_68">68</a>, <a href="#Page_75">75</a>, <a href="#Page_76">76</a>, <a href="#Page_106">106</a>, <a href="#Page_118">118</a>, <a href="#Page_169">169-177</a>, <a href="#Page_189">189</a>, <a href="#Page_201">201</a>, <a href="#Page_204">204</a>, <a href="#Page_213">213-216</a></li>
-
-<li class="ifrst">Mahogany, <a href="#Page_156">156</a></li>
-
-<li class="indx">Malt drying, <a href="#Page_333">333</a></li>
-
-<li class="indx">Manganese (manganese poisoning), <a href="#Page_23">23</a>, <a href="#Page_29">29</a>, <a href="#Page_58"><b>58</b></a> (i), <a href="#Page_59">59</a>, <a href="#Page_153">153</a>, <a href="#Page_179"><b>179-180</b></a> (ii)</li>
-
-<li class="indx">Meal rooms, <a href="#Page_236">236</a></li>
-
-<li class="indx">Mercaptan, <a href="#Page_22">22</a>, <a href="#Page_96">96</a></li>
-
-<li class="indx">Mercury and mercury poisoning, <a href="#Page_40">40</a>, <a href="#Page_44">44</a>, <a href="#Page_141"><b>141</b></a> (i), <a href="#Page_152">152</a>, <a href="#Page_154">154</a>, <a href="#Page_184"><b>184</b></a> (ii), <a href="#Page_326"><b>326-327</b></a> (iii), <a href="#Page_329">329</a></li>
-<li class="isub1" id="Mercury_amalgam">amalgam, <a href="#Page_141">141</a>, <a href="#Page_142">142</a>, <a href="#Page_327">327</a></li>
-
-<li class="indx">Metals, recovery of, <a href="#Page_120"><b>120</b></a> (i), <a href="#Page_176"><b>176</b></a> (ii) <a href="#Page_288"><b>288</b></a> (iii)</li>
-
-<li class="indx">Metaphenylene diamine, <a href="#Page_118">118</a></li>
-
-<li class="indx">Methyl alcohol, <a href="#Page_33">33</a>, <a href="#Page_34">34</a>, <a href="#Page_36">36</a>, <a href="#Page_37">37</a>, <a href="#Page_107">107</a>, <a href="#Page_156">156</a>, <a href="#Page_209">209</a>, <a href="#Page_210"><b>210</b></a> (ii), <a href="#Page_336">336</a></li>
-<li class="isub1">bromide and iodide, <a href="#Page_36">36</a>, <a href="#Page_209">209</a></li>
-<li class="isub1">chloride, <a href="#Page_33">33</a>, <a href="#Page_209">209</a></li>
-<li class="isub1">violet, <a href="#Page_112">112</a>, <a href="#Page_119">119</a></li>
-
-<li class="indx">Methylamine, <a href="#Page_96">96</a></li>
-
-<li class="indx">Methylene chloride, <a href="#Page_34">34</a>, <a href="#Page_208">208</a></li>
-
-<li class="indx">Mineral acids, <a href="#Page_169"><b>169-172</b></a> (ii)</li>
-
-<li class="indx">Mineral oil, <a href="#Page_59"><b>59</b></a> (i), <a href="#Page_60">60-63</a>, <a href="#Page_64">64</a>, <a href="#Page_65">65</a>, <a href="#Page_85">85</a></li>
-
-<li class="indx">Mirbane, oil of. <a href="#Nitrobenzene">See Nitrobenzene</a></li>
-
-<li class="indx">Mond gas, <a href="#Page_82">82</a>, <a href="#Page_87">87</a></li>
-
-<li class="indx">Mordants, <a href="#Page_32">32</a>, <a href="#Page_55">55</a>, <a href="#Page_337">337</a></li>
-
-<li class="indx">Muffle furnace, <a href="#Page_15">15</a>, <a href="#Page_20">20</a>, <a href="#Page_22">22</a>, <a href="#Page_125">125</a>, <a href="#Page_137">137</a>, <a href="#Page_138">138</a>, <a href="#Page_143">143</a>, <a href="#Page_258">258</a>, <a href="#Page_325">325</a></li>
-
-<li class="ifrst">Naphtha. <a href="#Petroleum">See Petroleum</a></li>
-<li class="isub1">vapour, <a href="#Page_42">42</a>, <a href="#Page_63">63</a>, <a href="#Page_267">267</a></li>
-<li class="isub1">wells, <a href="#Page_61">61</a>, <a href="#Page_62">62</a>, <a href="#Page_267">267</a></li>
-
-<li class="indx">Naphthalene, <a href="#Page_74">74</a>, <a href="#Page_96">96</a>, <a href="#Page_100">100</a>, <a href="#Page_101">101</a>, <a href="#Page_113">113</a>, <a href="#Page_208"><b>208</b></a> (ii)</li>
-
-<li class="indx">Naphthol, <a href="#Page_9">9</a>, <a href="#Page_96">96</a>, <a href="#Page_101">101</a>, <a href="#Page_109">109</a>, <a href="#Page_110">110</a></li>
-<li class="isub1">yellow, <a href="#Page_110">110</a></li>
-
-<li class="indx">Naphthylamine, <a href="#Page_103">103</a>, <a href="#Page_110">110</a>, <a href="#Page_118">118</a>, <a href="#Page_287">287</a></li>
-
-<li class="indx">Narcotic poisons, <a href="#Page_208">208</a>, <a href="#Page_209">209</a></li>
-
-<li class="indx">Nephritis. <a href="#Kidney_disease">See Kidney disease</a></li>
-
-<li class="indx">Nerve poisons, <a href="#Page_158">158</a>, <a href="#Page_192">192</a>, <a href="#Page_205">205</a></li>
-
-<li class="indx">Nervous diseases, <a href="#Page_70">70</a>, <a href="#Page_107">107</a>, <a href="#Page_163">163</a>, <a href="#Page_181">181</a>, <a href="#Page_184">184</a>, <a href="#Page_189">189</a>, <a href="#Page_190">190</a>, <a href="#Page_193">193</a>, <a href="#Page_194">194</a>, <a href="#Page_196">196</a>, <a href="#Page_197">197</a>, <a href="#Page_199">199</a>, <a href="#Page_202">202</a>, <a href="#Page_204">204</a>, <a href="#Page_205">205</a>, <a href="#Page_215">215</a></li>
-
-<li class="indx">Nickel, <a href="#Page_144">144</a>, <a href="#Page_186"><b>186</b></a> (ii)</li>
-<li class="isub1">carbonyl, <a href="#Page_186"><b>186-188</b></a> (ii)</li>
-<li class="isub1">eczema, <a href="#Page_186">186</a></li>
-
-<li class="indx">Nicotine, <a href="#Page_216">216</a></li>
-
-<li class="indx">Nitrating, <a href="#Page_41">41-43</a>, <a href="#Page_47">47</a>, <a href="#Page_49">49</a>, <a href="#Page_108"><b>108</b></a> (i), <a href="#Page_261"><b>261</b></a> (iii), <a href="#Page_286">286</a></li>
-
-<li class="indx">Nitric acid, <a href="#Page_2">2</a>, <a href="#Page_6">6</a>, <a href="#Page_9">9</a>, <a href="#Page_10">10</a>, <a href="#Page_39"><b>39</b></a> (i), <a href="#Page_43">43-49</a>, <a href="#Page_107">107</a>, <a href="#Page_116">116</a>, <a href="#Page_182">182</a>, <a href="#Page_172"><b>172</b></a> (ii), <a href="#Page_260"><b>260</b></a> (iii), <a href="#Page_261">261</a>, <a href="#Page_285">285-287</a>, <a href="#Page_326">326</a></li>
-
-<li class="indx" id="Nitrobenzene">Nitrobenzene, <a href="#Page_3">3</a>, <a href="#Page_9">9</a>, <a href="#Page_35">35</a>, <a href="#Page_40">40</a>, <a href="#Page_41">41</a>, <a href="#Page_45">45</a>, <a href="#Page_108"><b>108-115</b></a> (i), <a href="#Page_212"><b>212</b></a> (ii), <a href="#Page_285"><b>285-288</b></a> (iii)</li>
-
-<li class="indx">Nitro-cellulose, <a href="#Page_40">40</a>, <a href="#Page_42">42</a>, <a href="#Page_47">47</a>, <a href="#Page_48">48</a>, <a href="#Page_336">336</a></li>
-
-<li class="indx">Nitrochlorobenzene, <a href="#Page_116">116</a>, <a href="#Page_209">209</a></li>
-
-<li class="indx">Nitro-compounds, <a href="#Page_40">40</a>, <a href="#Page_108"><b>108</b></a> (i), <a href="#Page_109">109-112</a>, <a href="#Page_114">114</a>, <a href="#Page_115">115</a>, <a href="#Page_211"><b>211-214</b></a> (ii), <a href="#Page_286"><b>286-288</b></a> (iii)</li>
-
-<li class="indx">Nitro-glycerin, <a href="#Page_9">9</a>, <a href="#Page_40">40</a>, <a href="#Page_41">41</a>, <a href="#Page_43">43</a>, <a href="#Page_46"><b>46</b></a> (i), <a href="#Page_47">47</a>, <a href="#Page_48">48</a>, <a href="#Page_212"><b>212</b></a> (ii), <a href="#Page_261"><b>261</b></a> (iii)</li>
-
-<li class="indx">Nitronaphthalin, <a href="#Page_115">115</a>, <a href="#Page_116">116</a>, <a href="#Page_214">214</a></li>
-
-<li class="indx">Nitrophenol, <a href="#Page_3">3</a>, <a href="#Page_46">46</a>, <a href="#Page_115">115</a>, <a href="#Page_212">212</a>, <a href="#Page_288">288</a></li>
-
-<li class="indx">Nitrous fumes, <a href="#Page_10">10</a>, <a href="#Page_12">12</a>, <a href="#Page_40"><b>40-44</b></a> (i), <a href="#Page_48">48</a>, <a href="#Page_116">116</a>, <a href="#Page_171">171</a>, <a href="#Page_261"><b>261</b></a> (iii), <a href="#Page_286">286</a>, <a href="#Page_326">326</a></li>
-
-<li class="indx">Notification of poisoning, <a href="#Page_220"><b>220-225</b></a> (iii)</li>
-
-<li class="ifrst">Oil, extraction, <a href="#Page_61">61</a>, <a href="#Page_68">68</a>, <a href="#Page_69">69</a>, <a href="#Page_267">267</a></li>
-
-<li class="indx">Organ pipe making, <a href="#Page_140">140</a></li>
-
-<li class="indx"><span class="pagenum"><a name="Page_359" id="Page_359">[359]</a></span>Oxalic acid, <a href="#Page_55">55</a>, <a href="#Page_259">259</a></li>
-
-<li class="indx">Oxygen inhalation, <a href="#Page_43">43</a>, <a href="#Page_63">63</a>, <a href="#Page_64">64</a>, <a href="#Page_164"><b>164-168</b></a> (ii), <a href="#Page_188">188</a>, <a href="#Page_192">192</a>, <a href="#Page_196">196</a>, <a href="#Page_200">200-202</a>, <a href="#Page_204">204</a>, <a href="#Page_208">208</a>, <a href="#Page_227">227</a>, <a href="#Page_231"><b>231-237</b></a> (iii)</li>
-
-<li class="ifrst">Painting. <a href="#House_painting">See House painting</a></li>
-
-<li class="indx">Paints (quick-drying), <a href="#Page_330"><b>330-332</b></a></li>
-
-<li class="indx">Paper, manufacture of, <a href="#Page_336">336</a></li>
-
-<li class="indx">Paraffin, <a href="#Page_50">50</a>, <a href="#Page_59">59</a>, <a href="#Page_60">60</a>, <a href="#Page_96">96</a>, <a href="#Page_98">98</a>, <a href="#Page_101">101</a>, <a href="#Page_107">107</a>, <a href="#Page_203">203</a></li>
-<li class="isub1">eczema, <a href="#Page_27">27</a>, <a href="#Page_64">64</a>, <a href="#Page_65">65</a>, <a href="#Page_102">102</a>, <a href="#Page_203">203</a></li>
-
-<li class="indx">Paranitraniline, <a href="#Page_114">114</a>, <a href="#Page_118">118</a>, <a href="#Page_214">214</a></li>
-
-<li class="indx">Paraphenylene diamine, <a href="#Page_118">118</a>, <a href="#Page_214">214</a></li>
-
-<li class="indx">Parkes’ process, <a href="#Page_125">125</a>, <a href="#Page_127">127</a></li>
-
-<li class="indx">Pattinson process, <a href="#Page_125">125</a>, <a href="#Page_127">127</a></li>
-
-<li class="indx">Petrol ether, <a href="#Page_60">60</a>, <a href="#Page_331">331</a></li>
-
-<li class="indx" id="Petroleum">Petroleum (petroleum poisoning), <a href="#Page_59"><b>59-65</b></a> (i), <a href="#Page_202"><b>202-204</b></a> (ii), <a href="#Page_267"><b>267</b></a> (iii)</li>
-
-<li class="indx">Phenanthrene, <a href="#Page_96">96</a></li>
-
-<li class="indx">Phenol, <a href="#Page_75">75</a>, <a href="#Page_90">90</a>, <a href="#Page_96">96-100</a>, <a href="#Page_108">108</a>, <a href="#Page_109">109</a></li>
-
-<li class="indx">Phenylhydrazine, <a href="#Page_36">36</a></li>
-
-<li class="indx">Phosgene. <a href="#Carbon_oxychloride">See Carbon oxychloride</a></li>
-
-<li class="indx">Phosphor bronze, <a href="#Page_52">52</a></li>
-
-<li class="indx">Phosphoretted hydrogen gas, <a href="#Page_50">50</a>, <a href="#Page_52"><b>52</b></a> (i), <a href="#Page_86">86</a>, <a href="#Page_90">90</a>, <a href="#Page_149">149</a>, <a href="#Page_191"><b>191-192</b></a> (i)</li>
-
-<li class="indx">Phosphorus, <a href="#Page_31">31</a>, <a href="#Page_36">36</a>, <a href="#Page_49"><b>49</b></a> (i), <a href="#Page_50">50</a>, <a href="#Page_52">52</a>, <a href="#Page_148">148</a>, <a href="#Page_149">149</a>, <a href="#Page_190"><b>190-191</b></a> (ii), <a href="#Page_268"><b>268-271</b></a> (iii)</li>
-<li class="isub1">necrosis, <a href="#Page_51"><b>51</b></a> (i) <a href="#Page_52">52</a>, <a href="#Page_190"><b>190-191</b></a> (ii), <a href="#Page_268"><b>268-271</b></a> (iii)</li>
-<li class="isub1">prohibition of, <a href="#Page_51">51</a>, <a href="#Page_220">220</a>, <a href="#Page_268"><b>268-271</b></a> (iii)</li>
-
-<li class="indx">Photography, <a href="#Page_36">36</a>, <a href="#Page_45">45</a>, <a href="#Page_58">58</a>, <a href="#Page_94">94</a>, <a href="#Page_152">152</a></li>
-
-<li class="indx">Picric acid, <a href="#Page_40">40</a>, <a href="#Page_96">96</a>, <a href="#Page_100">100</a>, <a href="#Page_108">108</a>, <a href="#Page_115">115</a>, <a href="#Page_116">116</a>, <a href="#Page_213"><b>213</b></a> (ii)</li>
-
-<li class="indx">Pitch, <a href="#Page_96">96</a>, <a href="#Page_97">97</a>, <a href="#Page_107">107</a>, <a href="#Page_281">281</a>, <a href="#Page_282">282</a></li>
-
-<li class="indx">Plate towers, <a href="#Page_7">7</a>, <a href="#Page_16">16</a>, <a href="#Page_39">39</a></li>
-
-<li class="indx">Poisons, classification of, <a href="#Page_157"><b>157-163</b></a>, <a href="#Page_169"><b>169</b></a> (ii)</li>
-
-<li class="indx">Porcelain, <a href="#Page_138"><b>138</b></a> (i), <a href="#Page_322">322</a></li>
-
-<li class="indx">Potassium bichromate. <a href="#Chlorates">See Chromium chlorate</a>, <a href="#Page_26">26</a>, <a href="#Page_29">29</a>, <a href="#Page_37">37</a>, <a href="#Page_50">50</a>, <a href="#Page_52">52</a></li>
-
-<li class="indx" id="Pottery">Pottery, <a href="#Page_135"><b>135-138</b></a> (i), <a href="#Page_153">153</a>, <a href="#Page_294">294</a>, <a href="#Page_319"><b>319-321</b></a></li>
-
-<li class="indx">Power gas, <a href="#Page_80"><b>80-90</b></a> (i), <a href="#Page_277"><b>277</b></a> (iii)</li>
-
-<li class="indx" id="Printing">Printing, <a href="#Page_138"><b>138-139</b></a> (i), <a href="#Page_146">146</a>, <a href="#Page_317"><b>317-319</b></a> (iii)</li>
-
-<li class="indx" id="Producer_gas">Producer gas, <a href="#Page_80">80-82</a>, <a href="#Page_87">87-89</a>, <a href="#Page_153">153</a>, <a href="#Page_276">276-278</a></li>
-
-<li class="indx">Propyl alcohol, <a href="#Page_248">248</a>, <a href="#Page_249">249</a></li>
-
-<li class="indx">Prussic acid. See Hydrocyanic acid</li>
-
-<li class="indx">Pulmotor, <a href="#Page_167">167</a>, <a href="#Page_168">168</a></li>
-
-<li class="indx">Pyridine, <a href="#Page_59">59</a>, <a href="#Page_90">90</a>, <a href="#Page_96">96</a>, <a href="#Page_101">101</a>, <a href="#Page_152">152</a>, <a href="#Page_216"><b>216</b></a> (ii), <a href="#Page_285">285</a></li>
-
-<li class="indx">Pyrites burner, <a href="#Page_5">5</a>, <a href="#Page_6">6</a>, <a href="#Page_65">65</a>, <a href="#Page_256">256</a></li>
-
-<li class="indx">Pyroxyline, <a href="#Page_48">48</a>, <a href="#Page_261">261</a></li>
-
-<li class="ifrst">Quick-drying paints, <a href="#Page_330"><b>330-332</b></a></li>
-
-<li class="indx">Quicklime, <a href="#Page_54">54</a>, <a href="#Page_73">73</a></li>
-
-<li class="indx">Quinoline bases, <a href="#Page_110">110</a></li>
-
-<li class="ifrst">Realgar. <a href="#Arsenic">See Arsenic</a></li>
-
-<li class="indx">Refrigeration, <a href="#Page_92">92</a>, <a href="#Page_93">93</a>, <a href="#Page_154">154</a></li>
-
-<li class="indx">Regenerator firing, <a href="#Page_81">81</a>, <a href="#Page_148">148</a>, <a href="#Page_153">153</a></li>
-
-<li class="indx">Rescue appliances, <a href="#Page_164"><b>164-168</b></a> (ii), <a href="#Page_230"><b>230-235</b></a> (iii)</li>
-
-<li class="indx">Respirators, <a href="#Page_229"><b>229</b></a> (iii)</li>
-
-<li class="indx">Roasting (calcining furnaces, &amp;c.), <a href="#Page_5">5</a>, <a href="#Page_11">11</a>, <a href="#Page_65">65</a>, <a href="#Page_119">119</a>, <a href="#Page_120">120</a>, <a href="#Page_125">125-127</a>, <a href="#Page_129">129</a>, <a href="#Page_130">130</a>, <a href="#Page_131">131</a>, <a href="#Page_141">141</a>, <a href="#Page_143">143</a>, <a href="#Page_253">253</a>, <a href="#Page_288"><b>288-289</b></a> (iii), <a href="#Page_299">299</a>, <a href="#Page_323">323</a>, <a href="#Page_327">327</a></li>
-
-<li class="indx">Roburite, <a href="#Page_115">115</a>, <a href="#Page_116">116</a></li>
-
-<li class="indx">Roofing felt, <a href="#Page_96">96</a>, <a href="#Page_101">101</a>, <a href="#Page_281">281</a></li>
-
-<li class="indx">Rubber. <a href="#Indiarubber">See Indiarubber</a></li>
-
-<li class="ifrst">Salt, <a href="#Page_32">32</a>, <a href="#Page_33">33</a></li>
-
-<li class="indx">Saltcake. See Sodium sulphide</li>
-
-<li class="indx">Saltpetre, <a href="#Page_35">35</a>, <a href="#Page_42">42</a>, <a href="#Page_50">50</a>, <a href="#Page_257">257</a></li>
-
-<li class="indx">Satinwood, <a href="#Page_154">154</a>, <a href="#Page_155">155</a></li>
-
-<li class="indx">Sewer gas, <a href="#Page_66">66</a>, <a href="#Page_67">67</a>, <a href="#Page_93">93</a>, <a href="#Page_95">95</a></li>
-
-<li class="indx">Shot, <a href="#Page_121">121</a>, <a href="#Page_140">140</a>, <a href="#Page_143">143</a></li>
-
-<li class="indx" id="Silicon_carbide">Silicon carbide, <a href="#Page_85">85</a>, <a href="#Page_140">140</a>, <a href="#Page_323">323</a></li>
-
-<li class="indx">Silicofluoric acid, <a href="#Page_38">38</a>, <a href="#Page_50">50</a>, <a href="#Page_54">54</a>, <a href="#Page_171">171</a></li>
-
-<li class="indx">Silk, artificial, <a href="#Page_49">49</a></li>
-
-<li class="indx" id="Silver">Silver (argyria), <a href="#Page_45">45</a>, <a href="#Page_92">92</a>, <a href="#Page_120"><b>120</b></a> (i), <a href="#Page_122">122-125</a>, <a href="#Page_144">144</a>, <a href="#Page_152">152</a></li>
-<li class="isub1">nitrate, <a href="#Page_40">40</a>, <a href="#Page_45">45</a>, <a href="#Page_142">142</a>, <a href="#Page_188">188</a>, <a href="#Page_227">227</a></li>
-<li class="isub1">smelting, <a href="#Page_122"><b>122</b></a>, <a href="#Page_131"><b>131</b></a> (i)</li>
-
-<li class="indx">Skin diseases, <a href="#Page_27">27</a>, <a href="#Page_38">38</a>, <a href="#Page_47">47</a>, <a href="#Page_52">52</a>, <a href="#Page_55">55</a>, <a href="#Page_56">56</a>, <a href="#Page_58">58</a>, <a href="#Page_62">62</a>, <a href="#Page_64">64</a>, <a href="#Page_65">65</a>, <a href="#Page_71">71</a>, <a href="#Page_96">96</a>, <a href="#Page_102">102</a>, <a href="#Page_107">107</a>, <a href="#Page_118">118</a>, <a href="#Page_143">143</a>, <a href="#Page_144">144</a>, <a href="#Page_154">154-156</a>, <a href="#Page_171">171</a>, <a href="#Page_173">173</a>, <a href="#Page_185">185-189</a>, <a href="#Page_203">203</a>, <a href="#Page_208">208</a>, <a href="#Page_209">209</a>, <a href="#Page_265">265</a></li>
-
-<li class="indx">Smelting processes, <a href="#Page_89">89</a>, <a href="#Page_94">94</a>, <a href="#Page_119"><b>119</b></a> (i), <a href="#Page_143">143</a>, <a href="#Page_144">144</a>, <a href="#Page_182">182</a>, <a href="#Page_288"><b>288-290</b></a> (iii), <a href="#Page_299">299</a>, <a href="#Page_323">323-325</a>, <a href="#Page_326">326</a></li>
-
-<li class="indx">Smokeless powder, <a href="#Page_49">49</a>, <a href="#Page_211">211</a></li>
-
-<li class="indx">Soda, <a href="#Page_2">2</a>, <a href="#Page_14"><b>14</b></a> (i), <a href="#Page_17">17-20</a>, <a href="#Page_55">55</a>, <a href="#Page_65">65</a>, <a href="#Page_92">92</a>, <a href="#Page_95">95</a>, <a href="#Page_258"><b>258</b></a> (iii)</li>
-<li class="isub1">electrolytic, <a href="#Page_20">20</a></li>
-<li class="isub1">waste, <a href="#Page_18">18</a>, <a href="#Page_65">65</a>, <a href="#Page_258">258</a></li>
-
-<li class="indx">Sodium bichromate. <a href="#Chromates">See Chromate sulphate and sulphide</a>, <a href="#Page_14"><b>14</b></a> (i), <a href="#Page_17">17</a>, <a href="#Page_19">19-22</a>, <a href="#Page_22">22</a>, <a href="#Page_112">112</a>, <a href="#Page_258"><b>258</b></a> (iii), <a href="#Page_286">286</a></li>
-
-<li class="indx">Soldering, <a href="#Page_145">145</a>, <a href="#Page_316">316</a>, <a href="#Page_329">329</a></li>
-
-<li class="indx">Solvay method. <a href="#Ammonia_soda">See Ammonia soda</a></li>
-
-<li class="indx">Solvent naphtha, <a href="#Page_99">99-102</a>, <a href="#Page_106">106</a>, <a href="#Page_207"><b>207</b></a> (ii), <a href="#Page_330">330</a></li>
-
-<li class="indx">Spirit, denaturing of, <a href="#Page_99">99</a>, <a href="#Page_100">100</a>, <a href="#Page_210">210</a>, <a href="#Page_216">216</a></li>
-
-<li class="indx">Substitutes for poisonous materials, <a href="#Page_243"><b>243</b></a> (iii)</li>
-
-<li class="indx">Suction gas, <a href="#Page_82"><b>82</b></a> (i), <a href="#Page_83">83</a>, <a href="#Page_87">87-89</a>, <a href="#Page_276"><b>276-278</b></a> (iii)</li>
-
-<li class="indx">Sulpho-cyanide compounds, <a href="#Page_75">75</a>, <a href="#Page_90">90</a>, <a href="#Page_93">93</a></li>
-
-<li class="indx">Sulphonal, <a href="#Page_22">22</a>, <a href="#Page_259"><b>259</b></a> (iii)</li>
-
-<li class="indx"><span class="pagenum"><a name="Page_360" id="Page_360">[360]</a></span>Sulphur, <a href="#Page_31">31</a>, <a href="#Page_52">52</a>, <a href="#Page_65"><b>65</b></a> (i), <a href="#Page_65">65</a>, <a href="#Page_68">68</a>, <a href="#Page_74">74</a>, <a href="#Page_93">93</a>, <a href="#Page_122">122</a>, <a href="#Page_288">288</a></li>
-
-<li class="indx">Sulphur dioxide, <a href="#Page_5"><b>5</b></a> (i), <a href="#Page_9">9</a>, <a href="#Page_13">13</a>, <a href="#Page_14">14</a>, <a href="#Page_19">19</a>, <a href="#Page_21">21</a>, <a href="#Page_23">23</a>, <a href="#Page_31">31</a>, <a href="#Page_54">54</a>, <a href="#Page_63">63</a>, <a href="#Page_65">65</a>, <a href="#Page_119">119</a>, <a href="#Page_120">120</a>, <a href="#Page_122">122-125</a>, <a href="#Page_148">148</a>, <a href="#Page_154">154</a>, <a href="#Page_171"><b>171</b></a> (ii), <a href="#Page_257"><b>257</b></a> (iii), <a href="#Page_259">259</a>, <a href="#Page_267">267</a>, <a href="#Page_279">279</a>, <a href="#Page_288">288</a>, <a href="#Page_323">323</a>, <a href="#Page_326">326</a>, <a href="#Page_327">327</a>, <a href="#Page_333">333</a></li>
-<li class="isub1">dyes, <a href="#Page_112">112</a></li>
-<li class="isub1">soap, <a href="#Page_294">294</a></li>
-
-<li class="indx">Sulphuretted hydrogen, <a href="#Page_8">8</a>, <a href="#Page_12">12</a>, <a href="#Page_13">13</a>, <a href="#Page_16">16</a>, <a href="#Page_18">18</a>, <a href="#Page_21">21</a>, <a href="#Page_50">50</a>, <a href="#Page_52">52-54</a>, <a href="#Page_65"><b>65</b></a> (i), <a href="#Page_66">66</a>, <a href="#Page_67">67</a>, <a href="#Page_74">74</a>, <a href="#Page_79">79</a>, <a href="#Page_90">90-93</a>, <a href="#Page_95">95</a>, <a href="#Page_96">96</a>, <a href="#Page_101">101</a>, <a href="#Page_102">102</a>, <a href="#Page_103">103</a>, <a href="#Page_106">106</a>, <a href="#Page_107">107</a>, <a href="#Page_112">112</a>, <a href="#Page_114">114</a>, <a href="#Page_175">175</a>, <a href="#Page_192"><b>192</b></a> (ii), <a href="#Page_193">193</a>, <a href="#Page_258">258</a>, <a href="#Page_271">271</a>, <a href="#Page_279">279</a>, <a href="#Page_280">280</a>, <a href="#Page_285">285</a>, <a href="#Page_286">286</a>, <a href="#Page_290">290</a></li>
-
-<li class="indx">Sulphuric acid, <a href="#Page_5"><b>5</b></a> (i), <a href="#Page_9">9</a>, <a href="#Page_14">14</a>, <a href="#Page_18">18-20</a>, <a href="#Page_23">23</a>, <a href="#Page_33">33</a>, <a href="#Page_37">37-41</a>, <a href="#Page_46">46</a>, <a href="#Page_47">47</a>, <a href="#Page_49">49</a>, <a href="#Page_50">50</a>, <a href="#Page_53">53</a>, <a href="#Page_54">54</a>, <a href="#Page_60">60</a>, <a href="#Page_64">64</a>, <a href="#Page_65">65</a>, <a href="#Page_67">67</a>, <a href="#Page_92">92</a>, <a href="#Page_93">93</a>, <a href="#Page_108">108</a>, <a href="#Page_112">112</a>, <a href="#Page_119">119</a>, <a href="#Page_145">145</a>, <a href="#Page_151">151</a>, <a href="#Page_154">154</a>, <a href="#Page_156">156</a>, <a href="#Page_171"><b>171</b></a> (ii), <a href="#Page_256"><b>256-257</b></a> (iii), <a href="#Page_261">261</a>, <a href="#Page_279">279</a>, <a href="#Page_286">286</a></li>
-<li class="isub1">arsenic free, <a href="#Page_9">9</a></li>
-
-<li class="indx">Superphosphate industry, <a href="#Page_38">38</a>, <a href="#Page_53"><b>53</b></a> (i), <a href="#Page_54">54</a>, <a href="#Page_55">55</a>, <a href="#Page_92">92</a>, <a href="#Page_176"><b>176</b></a> (ii), <a href="#Page_261"><b>261-265</b></a> (iii)</li>
-
-<li class="indx">Swedish matches, <a href="#Page_50">50</a>, <a href="#Page_52">52</a>, <a href="#Page_55">55</a>, <a href="#Page_58">58</a>, <a href="#Page_265">265</a></li>
-
-<li class="ifrst">Tanning, <a href="#Page_55">55</a>, <a href="#Page_56">56</a>, <a href="#Page_58">58</a>, <a href="#Page_66">66</a>, <a href="#Page_67">67</a>, <a href="#Page_94">94</a>, <a href="#Page_143">143</a>, <a href="#Page_144">144</a>, <a href="#Page_153">153</a>, <a href="#Page_265">265</a>, <a href="#Page_329">329</a></li>
-
-<li class="indx" id="Tar">Tar, <a href="#Page_71">71</a>, <a href="#Page_77">77-80</a>, <a href="#Page_96"><b>96-107</b></a> (i), <a href="#Page_156">156</a>, <a href="#Page_275">275</a>, <a href="#Page_280"><b>280-285</b></a> (iii)</li>
-<li class="isub1">colours. <a href="#Aniline_colours">See Aniline colours</a></li>
-<li class="isub1">derivatives, <a href="#Page_40">40</a>, <a href="#Page_46">46</a>, <a href="#Page_96"><b>96-107</b></a> (i), <a href="#Page_204"><b>204-208</b></a> (ii), <a href="#Page_210">210</a>, <a href="#Page_213"><b>213-215</b></a> (iii)</li>
-
-<li class="indx">Teak wood, <a href="#Page_154">154</a></li>
-
-<li class="indx">Textile industry, <a href="#Page_134">134</a>, <a href="#Page_156"><b>156</b></a> (i), <a href="#Page_336"><b>336</b></a> (iii)</li>
-
-<li class="indx">Thermometers, manufacture of, <a href="#Page_141">141</a>, <a href="#Page_328">328</a></li>
-
-<li class="indx">Tiles, <a href="#Page_137"><b>137-138</b></a> (i). <a href="#Pottery">See also Pottery</a></li>
-
-<li class="indx">Tin, <a href="#Page_44">44</a>, <a href="#Page_138">138</a></li>
-
-<li class="indx">Tobacco industry, <a href="#Page_154"><b>154</b></a> (i), <a href="#Page_335"><b>335</b></a> (iii)</li>
-
-<li class="indx">Toluene, <a href="#Page_32">32</a>, <a href="#Page_35">35</a>, <a href="#Page_96">96</a>, <a href="#Page_108">108</a>, <a href="#Page_112">112</a>, <a href="#Page_204">204</a>, <a href="#Page_206"><b>206</b></a> (ii), <a href="#Page_285">285</a></li>
-
-<li class="indx">Toluidine, <a href="#Page_109">109</a>, <a href="#Page_111">111</a>, <a href="#Page_118">118</a>, <a href="#Page_214">214</a>, <a href="#Page_285">285</a>, <a href="#Page_287">287</a></li>
-
-<li class="indx">Treatment of poisoning, <a href="#Page_163"><b>163-127</b></a> (ii)</li>
-
-<li class="indx">Turpentine, <a href="#Page_69">69</a>, <a href="#Page_104">104</a>, <a href="#Page_215"><b>215</b></a> (ii), <a href="#Page_331">331</a></li>
-
-<li class="indx">Type casting, <a href="#Page_138">138</a>, <a href="#Page_139">139</a></li>
-
-<li class="ifrst">Ultramarine, <a href="#Page_19">19</a>, <a href="#Page_22">22</a>, <a href="#Page_259">259</a></li>
-
-<li class="indx">Ursol, <a href="#Page_118">118</a></li>
-
-<li class="ifrst">Varnish, <a href="#Page_58">58</a>, <a href="#Page_61">61</a>, <a href="#Page_101">101</a>, <a href="#Page_215">215</a>, <a href="#Page_330">330-332</a>, <a href="#Page_337">337</a></li>
-
-<li class="indx">Vaseline, <a href="#Page_60">60</a></li>
-
-<li class="indx">Vegetable food stuffs, preparation of, <a href="#Page_154"><b>154</b></a> (i), <a href="#Page_332"><b>332-336</b></a> (iii)</li>
-
-<li class="indx" id="Ventilation">Ventilation, <a href="#Page_243"><b>243-255</b></a> (iii)</li>
-<li class="isub1">artificial, <a href="#Page_244">244-247</a></li>
-<li class="isub1">localised, <a href="#Page_248">248-250</a></li>
-<li class="isub1">natural, <a href="#Page_243">243</a></li>
-
-<li class="indx">Vermilion, <a href="#Page_57">57</a></li>
-
-<li class="indx">Vulcanising, <a href="#Page_31">31</a>, <a href="#Page_68"><b>68</b></a> (i), <a href="#Page_68">68-70</a>, <a href="#Page_272"><b>272-274</b></a> (iii)</li>
-
-<li class="ifrst">Washing accommodation, <a href="#Page_237"><b>237</b></a> (iii)</li>
-
-<li class="indx">Waste sulphuric acid, <a href="#Page_43">43</a>, <a href="#Page_53">53</a></li>
-<li class="isub1">water, <a href="#Page_66">66</a></li>
-
-<li class="indx">Water gas, <a href="#Page_82">82</a>, <a href="#Page_84">84</a>, <a href="#Page_87">87</a>, <a href="#Page_88">88</a></li>
-<li class="isub1">gilding, <a href="#Page_141">141</a>, <a href="#Page_142">142</a>, <a href="#Page_327">327</a></li>
-
-<li class="indx">Weldon process, <a href="#Page_23">23</a>, <a href="#Page_29">29</a>, <a href="#Page_58">58</a>, <a href="#Page_59">59</a></li>
-
-<li class="indx" id="White_lead">White lead, <a href="#Page_55">55</a>, <a href="#Page_131"><b>131-134</b></a> (i), <a href="#Page_310"><b>310-313</b></a> (iii)</li>
-
-<li class="indx">Wood (poisonous), <a href="#Page_154"><b>154-156</b></a> (i), <a href="#Page_216"><b>216</b></a> (ii), <a href="#Page_335"><b>335</b></a> (iii)</li>
-
-<li class="indx">Workmen’s baths, <a href="#Page_237">237</a>, <a href="#Page_292">292</a></li>
-<li class="isub1">clothing, <a href="#Page_229">229</a></li>
-<li class="isub1">insurance, <a href="#Page_219">219</a></li>
-<li class="isub1">welfare, <a href="#Page_237">237-242</a></li>
-
-<li class="ifrst">Xylene, <a href="#Page_32">32</a>, <a href="#Page_99">99</a>, <a href="#Page_100">100</a>, <a href="#Page_107">107</a>, <a href="#Page_204">204</a>, <a href="#Page_206">206</a></li>
-
-<li class="ifrst">Zinc, <a href="#Page_120"><b>120</b></a> (i), <a href="#Page_121">121</a>, <a href="#Page_122"><b>122-131</b></a> (i), <a href="#Page_139">139</a>, <a href="#Page_144">144</a>, <a href="#Page_151">151</a>, <a href="#Page_182"><b>182-183</b></a> (ii), <a href="#Page_294"><b>294</b></a>, <a href="#Page_299">299-305</a>, <a href="#Page_323"><b>323-325</b></a> (iii)</li>
-<li class="isub1">ashes, <a href="#Page_125">125</a></li>
-<li class="isub1">oxide, <a href="#Page_32">32</a>, <a href="#Page_38">38</a>, <a href="#Page_125">125</a>, <a href="#Page_145">145</a>, <a href="#Page_182">182</a></li>
-<li class="isub1">poisoning, <a href="#Page_182"><b>182-183</b></a> (i), <a href="#Page_325"><b>325</b></a> (iii)</li>
-<li class="isub1">smelting, <a href="#Page_122">122-125</a>, <a href="#Page_125"><b>125-131</b></a> (i), <a href="#Page_323"><b>323-325</b></a> (iii)</li>
-<li class="isub1" id="Zinc_white">white, <a href="#Page_68">68</a>, <a href="#Page_293">293</a></li>
-
-</ul>
-
-<p class="titlepage">THE END</p>
-
-<p class="titlepage smaller">PRINTED BY<br />
-SPOTTISWOODE AND CO. LTD., COLCHESTER<br />
-LONDON AND ETON</p>
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-<pre>
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