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-The Project Gutenberg eBook of Earth Dams, A Study, by Burr Bassell
-
-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
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-using this eBook.
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-Title: Earth Dams, A Study
-
-Author: Burr Bassell
-
-Release Date: August 9, 2022 [eBook #68721]
-
-Language: English
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-Produced by: Charlene Taylor and the Online Distributed Proofreading
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-*** START OF THE PROJECT GUTENBERG EBOOK EARTH DAMS, A STUDY ***
-
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-
-
-Transcriber’s Notes:
-
-  Underscores “_” before and after a word or phrase indicate _italics_
-    in the original text.
-  Small capitals have been converted to SOLID capitals.
-  Illustrations have been moved so they do not break up paragraphs.
-  Typographical and punctuation errors have been silently corrected.
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-
-
-                              EARTH DAMS
-                               _A STUDY_
-
-                                  BY
-                    BURR BASSELL, M. Am. Soc. C. E.
-                         _Consulting Engineer_
-
-                               NEW YORK
-                THE ENGINEERING NEWS PUBLISHING COMPANY
-                                 1904
-
-                            COPYRIGHT, 1904
-                                  BY
-                  THE ENGINEERING NEWS PUBLISHING CO.
-
-
-
-
-ACKNOWLEDGMENTS.
-
-
-The writer wishes to acknowledge his appreciation of the assistance
-given him by Mr. Jas. D. Schuyler, M. Am. Soc. C. E., Consulting
-Hydraulic Engineer, in reviewing this paper, and in making suggestions
-of value. Appendix II contains a list of authors whose writings have
-been freely consulted, and to whom the writer is indebted; the numerous
-citations in the body of the paper further indicate the obligations of
-the writer.
-
-
-
-
-CONTENTS.
-
-
-                                                   PAGE
-                        CHAPTER I.
-    Introductory                                     1
-
-                        CHAPTER II.
-    Preliminary Studies and Investigations           3
-
-                        CHAPTER III.
-    Outline Study of Soils. Puddle                  12
-
-                        CHAPTER IV.
-    The Tabeaud Dam, California                     17
-
-                        CHAPTER V.
-    Different Types of Earth Dams                   33
-
-                        CHAPTER VI.
-    Conclusions                                     63
-
-                        APPENDIX I.
-    Statistical Descriptions of High Earth Dams     67
-
-                        APPENDIX II.
-    Works of Reference                              68
-
-
-
-
-ILLUSTRATIONS.
-
-
-                                                                PAGE
-    Fig. 1. Longitudinal Section of Yarrow Dam Site               10
-         2. Cross-Section of the Yarrow Dam                       10
-         3. Plan of the Tabeaud Reservoir                         17
-         4. Tabeaud Dam: Plan Showing Bed Rock Drains             18
-         5.   Details of Drains                                   18
-         6.   View of Drains                                      19
-         7.     North Trench                                      20
-         8.     South Trench                                      21
-         9.     Main Central Drain                                21
-        10.     Embankment Work                                   23
-        11.   Dimension Section                                   26
-        12.   Cross and Longitudinal Sections                     27
-        13.   View of Dam Immediately After Completion            29
-        14. Cross-Section of Pilarcitos Dam                       34
-        15.   San Andres Dam                                      34
-        16.   Ashti Tank Embankment                               35
-        17.   Typical New England Dam                             40
-        18.   Two Croton Valley Dams Showing Saturation           41
-        19. Studies of Board of Experts on the Original Earth
-              Portion of the New Croton Dam                       43
-        20. Studies of Jerome Park Reservoir Embankment           46
-        21 to 24. Experimental Dikes and Cylinder Employed
-              in Studies for the North Dike of the Wachusett
-              Reservoir                                           49
-        25. Cross-Section of Dike of Wachusett Reservoir          49
-        26. Working Cross-Section of Druid Lake Dam               53
-        27 to 29. Designs for the Bohio Dam, Panama Canal         55
-        30. Cross-Section of the Upper Pecos River Rock-Fill Dam  59
-        31. Developed Section of the San Leandro Dam              59
-
-
-
-
-EARTH DAMS
-
-
-
-
-CHAPTER I.
-
-_Introductory._
-
-
-The earth dam is probably the oldest type of dam in existence,
-antedating the Christian Era many hundreds of years. The literature
-upon this subject is voluminous, but much of it is inaccessible and
-far from satisfactory. No attempt will here be made to collate this
-literature or to give a history of the construction of earth dams,
-however interesting such an account might be. The object will rather
-be to present such a study as will make clear the application of the
-principles underlying the proper design and erection of this class
-of structures. In no way, therefore, will it assume the character or
-dignity of a technical treatise.
-
-Dams forming storage reservoirs, which are intended to impound large
-volumes of water, must necessarily be built of considerable height,
-except in a very few instances where favorable sites may exist. Recent
-discussions would indicate that a new interest has been awakened in
-the construction of high earth dams. As related to the general subject
-of storage, it is with the high structure rather than the low that
-this study has to do. To the extent that “the greater includes the
-less,” the principles here presented are applicable to works of minor
-importance.
-
-Many persons who should know better place little importance upon
-the skill required for the construction of earthwork embankments,
-considering the work to involve no scientific problems. It is far
-too common belief that any ordinary laborer, who may be able to use
-skillfully a scraper on a country road, is fitted to superintend
-the construction of an earth dam. It has been said that the art of
-constructing earth dams is purely empirical, that exact science
-furnishes no approved method of determining their internal stresses,
-and that in regard to their design experience is much more valuable
-than theory. When the question of stability is fully taken into
-consideration, it certainly requires a large amount of skill
-successfully to carry out works of this character.
-
-Extreme care in the selection of the site, sound judgment in the
-choice of materials and assiduity in superintending the work while in
-progress, are all vitally essential.
-
-
-Classification of Dams.
-
-Dams may be classified according to their purpose as diverting dams or
-weirs and as storage dams. The former may be located upon any portion
-of a stream where the conditions are favorable, and the water used for
-manifold purposes, being conveyed by means of canals, flumes, tunnels
-and pipe-lines to places of intended use. These dams are generally low
-and may be either of a temporary or permanent character, depending upon
-the uses to which the water is put. Temporary dams are made of brush,
-logs, sand bags, gravel and loose rock. The more permanent structures
-are built of stone and concrete masonry.
-
-Storage dams may be classified according to the kind of material
-entering into their structure, as follows: (1) Earth; (2) Earth and
-Timber; (3) Earth and Rock-fill; (4) Rock-fill; (5) Masonry; (6)
-Composite Structures.
-
-Low dams forming service reservoirs for domestic water supplies and
-for irrigation comprise by far the most numerous class. They are not
-designed to impound a large volume of water and therefore may be built
-across a small ravine or depression, or even upon the summit of a hill,
-by excavating the reservoir basin and using the material excavated to
-form the embankment. These reservoirs may be used in connection with
-surface or gravity systems, artesian wells, or underground supplies
-obtained by pumping. The dams forming these reservoirs being of
-moderate size and height may vary greatly in shape and dimensions.
-The form may be made to suit the configuration of the dam site. When
-the earthwork requires it, they may be lined with various materials
-to secure water-tightness. Often such dams are made composite in
-character, partly of earth and partly of masonry or some other
-material. They are also frequently accompanied by numerous accessories,
-such as settling-basins, aerating devices and covers, which present a
-diversity in form and appearance. A presentation of the different types
-of dams thus employed, with a discussion of the questions pertaining
-to utility in design and economy in construction, would be exceedingly
-valuable and of general interest. Service reservoirs will receive only
-a passing notice, with the hope expressed that some competent authority
-will discuss them in the future.
-
-
-
-
-CHAPTER II.
-
-_Preliminary Studies and Investigations._
-
-
-The preliminary studies and investigations which should be made prior
-to the construction of any dam for the storage of water have to do with
-(1) the Catchment Area, (2) the Reservoir basin, and (3) the Dam site.
-
-
-Catchment Area.
-
-It is thought desirable to define a number of terms as we proceed,
-for the purpose of correcting erroneous usage and for a clearer
-understanding of the subject. The catchment area of a reservoir is that
-portion of the country naturally draining into it. The watershed is
-the boundary of the catchment area and may be correctly defined as the
-divide between adjacent drainage systems. In regard to the catchment
-area it is necessary to determine:
-
-    1. Its extent and area in square miles.
-
-    2. Its topography or the character of its surface.
-
-    3. Its hydrography or precipitation and run-off.
-
-    4. Its geology, or the character of its soils and subsoils,
-       and the nature and dip of its rock strata.
-
-    5. Its flora, or the extent to which it is clothed with forest
-       trees or other vegetation.
-
-All of these elements affect the volumes of maximum run-off, which is
-the one important factor in the construction of earth dams that must
-not be underestimated.
-
-If the proposed dam or reservoir is to be located upon a main drainage
-line; that is, upon a river or stream, it is necessary to know both the
-flood and low-water discharge of the stream. Frequently no reliable
-data on this subject are available, and the engineer must then make
-such a study of the whole situation as will enable him to estimate the
-minimum and maximum flow with considerable accuracy.
-
-There are numerous factors entering into the solution of this first
-problem, such as the shape and length of the catchment area, its
-general elevation, the character of its surface, whether mountainous,
-hilly or flat, barren or timbered.
-
-Good topographic maps, if available, furnish valuable data on these
-subjects and it is to be regretted that only a comparatively small
-portion of the United States has been thus mapped in detail.
-
-The results of stream measurements, if any have been made in the
-catchment basin, are especially important: These are usually few in
-the high areas, on account of their inaccessibility. The year 1902
-marked a notable beginning of such measurements in California. In many
-parts of the arid region of the United States, the best storage-sites
-are situated in the upper or higher portions of the drainage systems.
-This is especially true of the streams on the Pacific Slope having
-their source in the High Sierras. As regulators of stream-flow and for
-power purposes such storage is peculiarly valuable, while storage for
-irrigation and domestic uses may be located nearer the valleys and the
-centers of population.
-
-Frequently the engineer is required to build his dam where no such
-data are available. In such instances he should endeavor to secure
-the establishment of rain gauges and make measurements of the flow of
-the main stream and its principal tributaries at various places to
-obtain the desired information. Even this may not suffice, owing to the
-limited time at his disposal, and he must resort to the use of certain
-empirical rules or formulas, and make such comparisons and deductions
-from known conditions and results as will best answer his purpose.
-
-The engineer should know, approximately at least, the normal yield of
-the catchment area, the duration of the minimum and maximum seasonal
-flow, and the floods he may have to provide against during the
-construction of his dam. These data are absolutely necessary to enable
-him to provide ample wasteways for his reservoirs. Many of the failures
-of earth dams have been the result of over-topping the embankment,
-which would have been averted by an ample wasteway. The most notable
-example of this kind in recent years was that of the South Fork Dam, at
-Conemaugh, Pennsylvania, in 1889, resulting in what is generally known
-as the “Johnstown Disaster.”
-
-There are several empirical rules and formulas for calculating the run
-off from catchment areas and for determining the size of spillways
-necessary to discharge this flow with safety to the dam. The proper
-formula to apply in any given case, with the varying coefficients
-of each, involves a thorough knowledge on the part of the designing
-engineer of the principles upon which the different factors are based.
-
-It is unwise and often hazardous to make use of any important hydraulic
-formula without knowing the history of its derivation. Experiments
-are not always properly conducted, and often the deductions therefrom
-are unreliable. A presentation and discussion of these formulas would
-require more space than can be given in this study, and the technical
-reader must therefore consult for himself, as occasion may require, the
-various authorities cited. Formulas for the discharge or run-off from
-catchment areas, as determined by Messrs. Craig, Dickens, Ryves and
-others, are given by most writers on the subject of hydraulics.
-
-
-Reservoir Basin.
-
-The next subject of inquiry relates to the reservoir basin. It is
-necessary that its area and capacity at different depths should be
-definitely known, and this information can only be obtained by having
-the basin surveyed and contoured. A map should be made showing contours
-at intervals of 2 to 10 ft., depending upon the size of the basin and
-the use to which the reservoir is to be put. Reservoir basins have been
-classified according to their location as follows:
-
-    1. Natural lakes.
-
-    2. Natural depressions on main drainage lines.
-
-    3. Natural depressions on lateral drainage lines.
-
-    4. Arbitrary and artificially constructed basins.
-
-Natural lakes may need to be investigated more or less thoroughly to
-determine the character of their waters, whether saline, alkaline
-or fresh. It may also be necessary to know their normal depth and
-capacity, and to make a study of their outlet if they have one. In some
-instances the storage capacity of a lake may be enormously increased by
-means of a comparatively low and inexpensive embankment.
-
-The area of reservoir basin, mean depth, temperature of the water,
-exposure of wind and sunshine, losses by seepage and evaporation, all
-have a bearing upon the available water supply and influence the design
-of the dam and accessories to the reservoir.
-
-In determining the character and suitability of materials for
-constructing a dam it is necessary to make a careful study of the
-soil and geological formation. This is best accomplished by digging
-numerous test pits over the basin, especially in the vicinity of the
-proposed dam site; borings alone should never be relied upon for this
-information. For such an investigation the advisability of borrowing
-material for dam construction from the reservoir basin is determined.
-The porous character of the subsoil strata, or the dip and nature of
-the bed rock, may forbid the removal of material from the floor of the
-basin, even at a remote distance from the dam site.
-
-The area to be flooded should be cleared and grubbed more or less
-thoroughly, depending again upon the use for which the water is
-impounded. In no instance should timber be left standing below the
-high-water level of the reservoir; and all rubbish liable to float and
-obstruct the outlet tunnel and spillway during a time of flood should
-be removed.
-
-The accessories to a reservoir, to which reference has been made, may
-be enumerated as follows:
-
-    1. Outlet pipes or tunnel.
-
-    2. Gate tower, screens and controlling devices.
-
-    3. Sluiceways for silt or sand.
-
-    4. Wasteway channel or weir.
-
-    5. Cover, settling basin, aerating devices, etc.
-
-Some of these are necessary and common to all classes of reservoirs,
-while others are employed only in special cases, as for domestic water
-supplies. All reservoirs formed by earth embankments must have at least
-two of these, namely a wasteway, which is its safety valve, and outlet
-pipes or outlet tunnel.
-
-It may be stated that the proper location and construction of the
-outlet for a reservoir are of vital importance, since either to
-improper location or faulty construction may be traced most of the
-failures of the past. It is almost impossible to prevent water under
-high pressure from following along pipes and culverts when placed in an
-earth dam. The pipes and culverts frequently leak, and failure ensues.
-Failure may result from one or more of the following causes:
-
-    1. By improper design and placement of the puddle around the pipes.
-
-    2. By resting the pipes upon piers of masonry without continuous
-       longitudinal support.
-
-    3. By reason of subsidence in the cuts of the embankments and
-       at the core walls, due to the great weight at these points.
-
-    4. Leakage due to inherent defects, frost, deterioration, etc.
-
-Mr. Beardsmore, the eminent English engineer who built the Dale Dyke
-embankment at Sheffield which failed in 1864, and who was afterwards
-requested to study and report upon the great reservoirs in Yorkshire
-and Lancashire, said, after examination and careful study of reservoir
-embankment construction, that “in his opinion there were no conditions
-requiring that a culvert or pipes should be carried through any portion
-of the made bank.” The writer would go even further and say that the
-only admissible outlet for a storage reservoir formed by a high earth
-dam is some form of tunnel through the natural formation at a safe
-distance from the embankment.
-
-
-Dam Site.
-
-The third preliminary study (that relating to the dam site itself) will
-be considered under three heads:
-
-    1. Location.
-
-    2. Physical features, materials, etc.
-
-    3. Foundation.
-
-LOCATION.–The location for a dam is generally determined by the use
-which is to be made of it, or by the natural advantages for storage
-which it may possess. If it be for water power it is very frequently
-located upon the main stream at the point of greatest declivity. If for
-storage it may be, as we have seen, at the head of a river system, on
-one of its tributaries, or in a valley lower down.
-
-The type of dam which should be built at any particular locality
-involves a thorough knowledge, not alone of the catchment area and
-reservoir basin, but also accurate information regarding the geology of
-the dam site itself. It would be very unwise to decide definitely upon
-any particular type of dam without first obtaining such information.
-Too frequently has this been done, causing great trouble and expense,
-if not resulting in a total failure of the dam.
-
-The conditions favorable for an earth dam are usually unfavorable for a
-masonry structure, and vice versa. Again, there may be local conditions
-requiring some entirely different type.
-
-Dams situated upon the main drainage lines of large catchment areas are
-usually built of stone or concrete masonry, and designed with large
-sluiceways and spillways for the discharge both of silt and flood
-waters. It need scarcely be remarked that, as a rule, such sites are
-wholly unsuited to earthwork construction. It is said, however, that
-“every rule has at least one exception,” and this may be true of those
-relating to dam sites, as will appear later under the head of new
-types.
-
-In a general way, the location of high earth dams is governed by the
-configuration of the ground forming the storage basin. It may not be
-possible, however, to decide upon the best available site without
-careful preliminary surveys and examinations of the geological
-formation.
-
-All earth dams must be provided with a wasteway, ample to discharge the
-maximum flood tributary to the reservoir. Whatever type of wasteway be
-adopted, no reliance should ever be put upon the outlet pipes for this
-purpose. The outlet should only figure as a factor of safety for the
-wasteway, insuring, as it were, the accuracy of the estimated flood
-discharge. The safety of the dam demands that ample provision be made
-for a volume of water in excess of normal flood discharge. This most
-necessary adjunct of earth dams may be an open channel, cut through
-the rim of the reservoir basin, discharging into a side ravine which
-enters the main drainage way some distance below the dam. It may be
-necessary and possible to pierce the rim by means of a tunnel where its
-length would not prohibit such a design. Lastly, there may be no other
-alternative than the construction of an overfall spillway, at one or
-both ends of the embankment. This last method is the least desirable of
-any and should be resorted to only when the others are impracticable;
-even then, the volume of water, local topography, geology, and
-constructive materials at hand must be favorable to such a design. If
-they are not favorable it may be asked, “what then?” Simply do not
-attempt to build an earth dam at this site.
-
-PHYSICAL FEATURES, MATERIALS, ETC.–An investigation of the location
-and the physical features of the dam site should include a careful and
-scientific examination of the materials in the vicinity, to determine
-their suitability for use in construction. An earth embankment cannot
-be built without earth, and an earth dam cannot be built with safety
-without the right kind of earth material.
-
-Test pits judiciously distributed and situated at different elevations
-will indicate whether there is a sufficient amount of suitable
-material within a reasonable distance of the dam. The type of earth
-dam best suited for any particular locality, and its estimated cost,
-are thus seen to depend upon the data and information obtained by
-these preliminary studies. Economical construction requires the use of
-improved machinery and modern methods of handling materials, but far
-more important even than these are the details of construction.
-
-FOUNDATION.–We may now assume that our preliminary studies relating to
-the location and physical features of the dam site are satisfactory.
-We must next investigate the foundation upon which the dam is to be
-built. This investigation is sometimes wholly neglected or else done in
-such a way as to be practically useless. To merely drive down iron rods
-feeling for so-called bed rock, or to make only a few bore-holes with
-an earth auger should in no instance be considered sufficient. Borings
-may be found necessary at considerable depths below the surface and
-in certain classes of material, but dug pits or shafts should always
-be resorted to for moderate depths and whenever practicable. Only by
-such means may the true character of the strata underlying the surface,
-and the nature and condition of the bed rock, if it be reached, become
-known. If a satisfactory stratum of impermeable material be found it is
-necessary also to learn both its thickness and extent. It may prove to
-be only a “pocket” of limited volume, or if found to extend entirely
-across the depression lengthwise of the dam site it may “pinch out”
-on lines transversely above or below. Shafts and borings made in the
-reservoir basin and below the dam site will determine its extent in
-this direction, knowledge of which is very important.
-
-Fig. 1, showing a longitudinal section of the site of the Yarrow Dam of
-the Liverpool Water-Works, England, illustrates the necessity of such
-investigation. A bore hole at station 2 + 00 met a large boulder which
-at first was erroneously thought to be bed rock. The hole at station 3
-+ 50 met a stratum of clay which proved to be only a pocket.
-
-The relative elevation of the different strata and of the bed rock
-formation, referred to one common datum, should always be determined.
-These elevations will indicate both the dip and strike of the rock
-formation and are necessary for estimating the quantities of material
-to be excavated and removed, including estimates of cost. They furnish
-information of value in determining the rate of percolation or
-filtration through the different classes of material and the amount
-of probable seepage, as will appear later. The cost of excavating,
-draining and preparing the floor or foundation for a dam is often very
-great, amounting to 20 or 30% of the total cost.
-
-Fig. 2 is a transverse section of the Yarrow Dam. This particular dam
-has been selected as fairly representative of English practice and
-of typical design. It is one of the most widely known earth dams in
-existence.
-
-[Illustration: FIG. 1.–LONGITUDINAL SECTION OF YARROW DAM SITE.]
-
-[Illustration: FIG. 2.–CROSS-SECTION OF YARROW DAM.]
-
-At the Yarrow dam site it was necessary to go 97 ft. below the original
-surface to obtain a satisfactory formation or one that was impermeable.
-A central trench was excavated to bed rock, parallel to the axis of the
-dam, and filled with clay puddle to form a water-tight connection with
-the rock, and prevent the water in the reservoir from passing through
-the porous materials under the body of the embankment. This interesting
-dam will be more fully described later, when the different types of
-earth dams are discussed.
-
-
-
-
-CHAPTER III.
-
-_Outline Study of Soils. Puddle._
-
-
-The following study of soils is merely suggestive and is here given
-to emphasize the importance of the subject, at the risk of being
-considered a digression. Soil formations are made in one of three ways:
-
-    1. By decomposition of exposed rocks.
-
-    2. By transportation or sedimentation of fine and coarse
-       materials worn from rocks.
-
-    3. By transformation into humus of decayed organic matter.
-
-The transforming agencies by which soils succeed rocks in geological
-progression have been classified as follows:
-
-    1. Changes of temperature.
-
-    2. Water.
-
-    3. Air.
-
-    4. Organic life.
-
-_Heat_ and its counter agent frost are the most powerful forces in
-nature, their sensible physical effects being the expansion and
-contraction of matter.
-
-_Water_ has two modes of action, physical and chemical. This agent is
-the great destroyer of the important forces, cohesion and friction.
-_Cohesion_ is a force uniting particles of matter and resists their
-separation when the motion attempted is perpendicular to the plane of
-contact. _Friction_ is a force resisting the separation of surfaces
-when motion is attempted which produces sliding. The hydrostatic
-pressure and resultant effect upon submerged surfaces need to be
-kept constantly in mind. When the surface is impermeable the line of
-pressure is normal to its plane, but when once saturated there are also
-horizontal and vertical lines of pressure. Since the strength of an
-earth dam depends upon two factors, namely, its weight and frictional
-resistance to sliding, the effect of water upon different materials
-entering into an earth structure should be most carefully considered.
-This will therefore occupy a large place in these pages. An earth
-embankment founded upon rock may become saturated by water forced up
-into it from below through cracks and fissures, reducing its lower
-stratum to a state of muddy sludge, on which the upper part, however
-sound in itself, would slide. The best preliminary step to take in such
-a case is to intersect the whole site with wide, dry, stone drains,
-their depths varying according to the nature of the ground or rock.
-
-_Air_ contains two ingredients ever active in the process of
-decomposition, carbonic acid and oxygen.
-
-_Organic Life_ accomplishes its decomposing effect both by physical
-and chemical means. The effect of organic matter upon the mineral
-ingredients of the soil may be stated as follows:
-
-    1. By their hydroscopic properties they keep the soil moist.
-
-    2. Their decomposition yields carbonic acid gas.
-
-    3. The acids produced disintegrate the mineral constituents,
-       reducing insoluble matter to soluble plant food.
-
-    4. Nitric acid results in _nitrates_, which are the most
-       valuable form of nutritive nitrogen, while ammonia and the
-       other salts that are formed are themselves direct food for
-       plants.
-
-_Vegetable Humus_ is not the end of decomposition of organic matter,
-but an intermediate state of transformation. Decay is a process almost
-identical with combustion, where the products are the same, and the end
-is the formation of water and carbonic acid, with a residue of mineral
-ash. The conditions essential to organic decomposition are also those
-most favorable to combustion or oxidation, being (1) access of air, (2)
-presence of moisture, and (3) application of heat.
-
-Now the coöperation of these chemical and physical forces, which are
-ever active, is called “weathering.” Slate rock, for instance, weathers
-to clay, being impregnated with particles of mica, quartz, chlorite and
-hornblend. Shales also weather to clay, resulting often in a type of
-earth which is little more than silicate of aluminum with iron oxide
-and sand.
-
-In the vicinity of the Tabeaud Dam, recently built under the personal
-supervision of the author, the construction of which will be described
-later, there is to be found a species of potash mica, which in
-decomposing yields a yellow clay (being ochre-colored from the presence
-of iron), mixed with particles of undecomposed mica. This material
-is subject to expansion, and by reason of its lack of grit and its
-unctuous character it was rejected or used very sparingly. Analysis of
-this material gave, Silica, 54.1 to 59.5%; potash, 1.5 to 2.3%; soda,
-2.7 to 3.7%.
-
-Soil analysis may be either mechanical or chemical. For purposes of
-earthwork, we are most interested in the former, having to deal with
-the physical properties of matter. Chemical analysis, however, will
-often afford information of great value regarding certain materials
-entering into the construction of earth dams. The most important
-physical properties are:
-
-    (1) Weight and specific gravity.
-
-    (2) Coefficient of friction and angle of repose.
-
-    (3) Structure and coloring ingredients.
-
-    (4) Behavior toward water.
-
-There are two distinct methods of mechanical analysis: (1) Granulating
-with sieves, having round holes. (2) Elutriating with water, the
-process being known as silt analysis.
-
-It would require a large volume to present the subject of soil analysis
-in any way commensurate with its importance. Experiments bearing upon
-the subjects of imbibition, permeability, capillarity, absorption and
-evaporation, of different earth materials, are equally interesting and
-important.[1]
-
-The permeability of soils will be discussed incidentally in connection
-with certain infiltration experiments to be given later.
-
-
-Puddle.
-
-_Puddle_ without qualification may be defined as clayey and gravelly
-earth thoroughly wetted and mixed, having a consistency of stiff mud
-or mortar. Puddle in which the predominating ingredient of the mixture
-is pure clay, is called _clay puddle_. _Gravel puddle_ contains a much
-higher percentage of grit and gravel than the last-named and yet is
-supposed to have enough clayey material to bind the matrix together and
-to fill all the voids in the gravel.
-
-The term _earthen concrete_ may also be applied to this class of
-material, especially when only a small quantity of water is used in
-the mixture. These different kinds of puddling materials may be found
-in natural deposits ready for use, only requiring the addition of the
-proper amount of water. It is usually necessary, however, to mix,
-artificially, or combine the different ingredients in order to obtain
-the right proportions. Some engineers think grinding in a pug-mill
-absolutely essential to obtain satisfactory results.
-
-Puddle is handled very much as cement concrete, which is so well
-understood that detailed description is hardly necessary. Instead of
-tampers, sharp cutting implements are usually employed in putting
-puddle into place. Trampling with hoofed animals is frequently resorted
-to, both for the purpose of mixing and compacting.
-
-As has been stated, clays come from the decomposition of crystaline
-rocks. The purest clay known (kaolin) is composed of alumina, silica
-and water. The smaller the proportion of silica the more water it will
-absorb and retain. Dry clay will absorb nearly one-third of its weight
-of water, and clay in a naturally moist condition 1-6 to 1-8 its weight
-of water. The eminent English engineers, Baker and Latham, put the
-percentage of absorption by clayey soils as high as 40 to 60%. Pure
-clays shrink about 5% in drying, while a mixture by weight of 1 clay
-to 2 sand will shrink about 3%. It follows, then, that the larger the
-percentage of clay there may be in a mixture the greater will be both
-the expansion and the contraction.
-
-Clay materials may be very deceptive in some of their physical
-properties, being hard to pick under certain conditions, and yet when
-exposed to air and water will rapidly disintegrate. Beds of clay,
-marl and very fine sand are liable to slip when saturated, becoming
-semi-fluid in their nature, and will run like cream.
-
-The cohesive and frictional resistances of clays becoming thus very
-much reduced when charged with water, a too liberal use of this
-material is to be deprecated. The ultimate particles forming clays,
-viewed under the microscope, are seen to be flat and scale-like, while
-those of sands are more cubical and spherical. This is a mechanical
-difference which ought to be apparent to even a superficial observer
-and yet has escaped recognition by many who have vainly attempted a
-definition of _quicksand_.
-
-Mr. Strange recommends filling the puddle trench with material having
-three parts soil and two parts sand. After the first layer next to bed
-rock foundation, which he kneads and compacts, he would put the layers
-in dry, then water and work it by treading, finally covering to avoid
-its drying out and cracking.
-
-Prof. Philipp Forchheimer, of Gratz, Austria, one of the highest
-authorities and experimentalists, affirms that if a sandy soil contains
-clay to such an extent that the clay fills up the interstices between
-the grains of sand entirely the compound is practically impervious.
-
-Mr. Herbert M. Wilson, C. E., in his “Manual of Irrigation
-Engineering,” recommends the following as an ideal mixture of materials:
-
-                       Cu. yds.
-
-    Coarse gravel        1.00
-    Fine gravel          0.35
-    Sand                 0.15
-    Clay                 0.20
-                         ––
-        Total            1.70
-
-This mixture, when rolled and compacted, should give 1.25 cu. yds. in
-bulk, thus resulting in 26½% compression.
-
-Mr. Clemens Herschel suggests the following test of “good binding
-gravel:” “Mix with water in a pail to the consistency of moist earth;
-if on turning the pail upside down the gravel remains in the pail it is
-fit for use, otherwise it is to be rejected.” For _puddling material_
-he would use such a proportion as will render the water invisible.
-
-
-
-
-CHAPTER IV.
-
-_The Tabeaud Dam, California._
-
-
-The Tabeaud Dam, in Amador County, Cal., built under the supervision
-of the author for the Standard Electric Co., is an example of the
-homogeneous earth dam. A somewhat fuller description and discussion
-will be given of this dam than of any other, not on account of its
-greater importance or interest, but because it exemplifies certain
-principles of construction upon which it is desired to put special
-emphasis. This dam was described in Engineering News of July 10, 1902,
-to which the reader is referred for more complete information than is
-given here.
-
-[Illustration: FIG. 3.–PLAN OF TABEAUD RESERVOIR, WITH CONTOURS.]
-
-[Illustration: FIG. 4.–PLAN OF TABEAUD DAM, SHOWING BED ROCK DRAINAGE
-SYSTEM.]
-
-[Illustration: FIG. 5.–DETAILS OF BED ROCK DRAINS AT THE TABEAUD DAM.]
-
-Fig. 3 is a contour map of the Tabeaud Reservoir, showing the relative
-locations of the dam, wasteway and outlet tunnel. Fig. 4 shows the bed
-rock drainage system and the letters upon the drawing will assist in
-following the explanation given in the text. The whole up-stream half
-of the dam site was stripped to bed rock. As the work of excavation
-advanced pockets of loose alluvial soil were encountered, which were
-suggestive of a refill, possibly the result of placer mining operations
-during the early mining days of California. In addition to this were
-found thin strata of sand and gravel deposited in an unconformable
-manner. The slate bed rock near the up-stream toe of the dam was badly
-fissured and yielded considerable water. A quartz vein from 1 to 2 ft.
-in thickness crossed the dam site about 150 ft. above the axis of the
-dam. The slate rock above this vein or fault line was quite variable in
-hardness and dipped at an angle of 40 degrees toward the reservoir.
-
-[Illustration: FIG. 6.–VIEW OF BED ROCK TRENCHES, TABEAUD DAM.]
-
-The rear drain terminates at a weir box (Z) outside of the down-stream
-slope at a distance of 500 ft. from the axis of the dam. This drain
-branches at the down-stream side of the central trench, (Y), one branch
-being carried up the hillside to high-water level (W) at the North end
-of the dam, and the other to the same elevation at the South end (X).
-
-Fig. 5 shows how these drains were constructed. After the removal of
-all surface soil and loose rock, a trench 5 to 10 ft. wide was cut into
-the solid rock, the depth of cutting varying with the character of the
-bed rock. Upon the floor of this trench a small open drain was made by
-notching the bed rock and by means of selected stones of suitable size
-and hardness. The stringers and cap-stones were carefully selected and
-laid, so that no undue settlement or displacement might occur by reason
-of the superincumbent weight of the dam. All crevices were carefully
-filled with spawls and the whole overlaid 18 ins. in depth with broken
-stone 1 to 3 ins. in diameter. Upon this layer of broken stone and
-fine gravel was deposited choice clay puddle, thoroughly wetted and
-compacted, refilling the trenches.
-
-[Illustration: FIG. 7.–VIEW OF NORTH TRENCH, TABEAUD DAM.]
-
-[Illustration: FIG. 8.–VIEW OF SOUTH TRENCH, TABEAUD DAM.]
-
-[Illustration: FIG. 9.–VIEW OF MAIN CENTRAL DRAIN, TABEAUD DAM.]
-
-These drains served a useful purpose during construction, in drying
-off the surface of the dam after rains. The saturation of the outer
-slope of the dam by water creeping along the line of contact should
-thus be prevented, and the integrity or freedom from saturation of the
-down-stream half should be preserved. It is believed that the puddle
-overlying these rock drains will effectually prevent any water from
-entering the body of the embankment by upward pressure and that the
-drains will thus forever act as efficient safeguards.
-
-The main drain was extended, temporarily during construction, from
-the central trench (Fig. 4), to the up-stream toe of the dam. This
-was cut 5 or 6 ft. deep into solid rock, below the general level of
-the stripped surface. Fig. 6 is reproduced from a photograph of this
-trench. An iron pipe 2 ins. in diameter was imbedded in Portland cement
-mortar and concrete, and laid near the bottom of the trench.
-
-At the point (B) where the quartz vein (already described) intersected
-this drain, two branch drains were made, following the fault well into
-the hill on both sides. Figs. 7 and 8 are views of the North and South
-trenches, respectively. These trenches were necessary to take care of
-the springs issuing along the quartz vein. This water led to a point
-(N, Fig. 4) near the up-stream toe, by means of the drain shown in Fig.
-9.
-
-The lateral drains and that portion of the main central drain extending
-from their junction (B) to a point (N) about 230 ft. from the axis
-of the dam have pieces of angle iron or wooden Y-fluming laid on the
-bottom of the trenches immediately over the 2-in. pipe, as shown in
-Figs. 7, 8 and 9. These are covered in turn with Portland cement
-mortar, concrete, clay puddle and earth fill. The water will naturally
-flow along the line of least resistance, and consequently will follow
-along the open space between the angle irons and the outside of the
-pipe until it reaches the chamber and opening in the pipe, permitting
-the water to enter and be conveyed through the imbedded pipe-line to
-the rear drain. This point of entry is a small chamber in a solid
-cross-wall of rich cement mortar, and is the only point where water
-can enter this pipe-line, the two branches entering the wells and the
-stand-pipe at their junction (soon to be described) having been closed.
-
-That portion of the foundation between the axis of the dam and the
-quartz vein, a distance of about 160 ft., was very satisfactory,
-without fissures or springs of water. In this portion the 2-in. pipe
-was imbedded in mortar and concrete without angle irons, and the
-continuity of the trench broken by numerous cross-trenches cut into
-the rock and filled with concrete and puddle. It is believed that no
-seepage water will ever pass through this portion of the dam. If any
-should ever find its way under the puddle and through the bed rock
-formation, the rear drain, with its hillside branches, will carry it
-away and prevent the saturation of the lower or down-stream half of the
-dam.
-
-[Illustration: FIG. 10.–VIEW OF TABEAUD DAM WHEN ABOUT HALF COMPLETED.]
-
-At the up-stream toe of the embankment, two wells or sumps (shown at
-“S” and “K,” Fig. 4) were cut 10 or 12 ft. deeper than the main trench,
-which received the water entering the inner toe puddle trench during
-construction. This water was disposed of partly by pumping and partly
-by means of the 2-in. branch pipes leading into and from these wells.
-At their junction (J) a 2-in. stand-pipe was erected, which was carried
-vertically up through the embankment, and finally filled with cement.
-The branch pipes from the wells were finally capped and the wells
-filled with broken stone, as previously mentioned.
-
-EMBANKMENT.–As has been said, the upper surface of the slate bed rock
-was found to be badly fissured, especially near the up-stream toe of
-the dam, and as the average depth below the surface of the ground was
-not very great, it was thought best to lay bare the bed rock over the
-entire upper half of the dam site. Had the depth been much greater,
-it would have been more economical and possibly sufficient to have
-put reliance in a puddle trench, alone, for securing a water-tight
-connection between the foundation and the body of the dam.
-
-At the axis of the dam and near the inner toe, where the puddle walls
-abutted against the hillsides, the excavation always extended to bed
-rock. Vertical steps and offsets were avoided and the cuts were made
-large enough for horses to turn in while tramping, these animals being
-used, singly and in groups, to mix and compact the puddle and thus
-lessen the labor of tamping by hand. In plan, the hillside contact
-of natural and artificial surfaces presents a series of corrugated
-lines, (as is clearly shown in Fig. 4.) After all loose and porous
-materials had been removed, the stripped surface and the slopes of all
-excavations were thoroughly wetted from time to time by means of hose
-and nozzle, the water being delivered under pressure. Fig. 10 is a view
-of the dam taken when it was about half finished and shows the work in
-progress.
-
-The face puddle shown in Fig. 11 was used merely to “make assurance
-doubly sure” and was not carried entirely up to the top of the dam.
-The earth of which the dam was constructed may be described as a
-red gravelly clay, and in the judgment of the author is almost ideal
-material for the purpose. Physical tests and experiments made with the
-materials at different times during construction gave the following
-average results:
-
-                                                               Pounds.
-    Weight of 1 cu. ft. earth, dust dry                         84.0
-      “    “  1   “     saturated earth                        101.8
-      “    “  1   “     moist loose earth                       76.6
-      “    “  1   “     loose material
-                              taken from test pits on the dam   80.0
-      “    “  1   “     earth in place
-                              taken from the borrow pits       116.5
-      “    “  1   “     earth material
-                              taken from test pits on the dam  133.0
-
-                                                            Per cent.
-    Percentage of moisture in natural earth                      19
-        “      “ voids in natural earth                          52
-        “      “ grit and gravel in natural earth                38
-        “      “ compression on dam over earth at borrow pit     16
-        “      “ compression on dam over earth in wagons         43
-
-                                                             Degrees.
-    Angle of repose of natural moist earth                       44
-    Angle of repose of earth, dust dry                           36
-    Angle of repose of saturated earth                           23
-
-CONSTRUCTION DETAILS.–The materials forming the bulk of the dam were
-hauled by four-horse teams, in dump wagons, holding 3 cu. yds. each.
-The wagons loaded weighed about six tons and were provided with two
-swinging bottom-doors, which the driver could operate with a lever,
-enabling the load to be quickly dropped while the team was in motion.
-If the material was quite dry, the load could be dumped in a long row
-when so desired.
-
-After plowing the surface of the ground and wasting any objectionable
-surface soil, the material was brought to common earth-traps for
-loading into wagons, by buck or dragscrapers of the Fresno pattern. In
-good material one trap with eight Fresno-scraper teams could fill 25
-wagons per hour. The average length of haul for the entire work was
-about 1,320 ft.
-
-The original plans and specifications were adhered to throughout, with
-the single exception that the central puddle wall was not carried above
-elevation 1,160, as shown on Figs. 11 and 12, more attention being
-given to the inner face puddle. This modification in the original plans
-was made because of the character of the materials available and the
-excellent results obtained in securing an homogeneous earthen concrete,
-practically impervious.
-
-[Illustration: FIG. 11.–DIMENSION SECTION OF TABEAUD DAM.]
-
-The top of the embankment was maintained basin-shaped during
-construction, being lower at the axis than at the outer slopes by 1-10,
-to the height below the finished crown. This gave a grade of about 1
-in 25 from the edges toward the center, resulting in the following
-advantages:
-
-(1) Insuring a more thorough wetting of the central portion of the dam;
-any excess of water in this part would be readily taken care of by the
-central cross drains.
-
-(2) In wetting the finished surface prior to depositing a new layer
-of material, water from the sprinkling wagons would naturally drain
-towards the center and insure keeping the surface wet; the layers being
-carried, as a rule, progressively outward from the center.
-
-(3) It centralized the maximum earth pressure and enabled the
-depositing of material in layers perpendicular to the slopes.
-
-(4) It facilitated rolling and hauling on lines parallel to the axis of
-the dam, and discouraged transverse and miscellaneous operations.
-
-(5) It finally insured better compacting by the tramping of teams in
-their exertions to overcome the grade.
-
-[Illustration]
-
-[Illustration: FIG. 12.–CROSS AND LONGITUDINAL SECTIONS OF TABEAUD
-DAM.]
-
-The specifications stipulated that the body of the dam should be built
-up in layers not exceeding 6 ins. in thickness for the first 60 ft.,
-and not exceeding 8 ins. above that elevation. The finished layers
-after rolling varied slightly in thickness, the daily average per month
-being as follows:
-
-    April                     4  ins.
-    May                       3½  “
-    June                      4   “
-    July                      4½  “
-    August                    5   “
-    September                 6   “
-    October                   7   “
-    November and December     8   “
-
-During the last few months more than one whole layer constituted the
-day’s work, so that a single layer was seldom as thick as the daily
-average indicates.
-
-It was stipulated in the specifications that the up-stream half of the
-dam was to be made of “selected material” and the lower half of less
-choice material, not designated “waste.” “Waste material” was described
-as meaning all vegetable humus, light soil, roots, and rock exceeding 5
-lbs. in weight, too large to pass through a 4-in. ring.
-
-It may be well to define the expression “selected material,”
-so commonly used in specifications for earth dams. In England,
-for instance, it is said to refer to materials which insure
-_water-tightness_, while in India it refers to those employed to obtain
-_stability_. It ought to mean the best material available, selected by
-the engineer to suit the requirements of the situation.
-
-The method employed in building the body of the embankment may be
-described as follows:
-
-(1) The top surface of every finished layer of material was sprinkled
-and harrowed prior to putting on a new layer. The sprinkling wagons
-passed over the older finished surface immediately before each
-wagon-row was begun. This insured a wetted surface and assisted the
-wheels of the loaded wagons, as well as the harrows, to roughen, the
-old surface prior to depositing a new layer.
-
-(2) The material was generally deposited in rows parallel to the axis
-of the dam. However, along the line of contact, at the margins of the
-embankment, the earth was often deposited in rows crosswise of the
-dam, permitting a selection of the choicest materials and greatly
-facilitating the work of graders and rollers.
-
-(3) Rock pickers with their carts were continually passing along the
-rows gathering up all roots, rocks and other waste materials.
-
-[Illustration: FIG. 13.–VIEW OF TABEAUD DAM IMMEDIATELY AFTER
-COMPLETION.]
-
-(4) The road-graders drawn by six horses leveled down the tops of
-the wagon-loads, and if the material was dry the sprinkling wagons
-immediately passed over the rows prior to further grading. When the
-material was naturally moist the grader continued the leveling process
-until the earth was evenly spread. The depth or thickness of the layer
-could be regulated to a nicety by properly spacing the rows and the
-individual loads. The grader brought the layer to a smooth surface
-and of uniform thickness, and nothing more could be desired for this
-operation.
-
-(5) After the graders had finished, the harrows passed over the new
-layer to insure the picking out of all roots and rocks, followed
-immediately by the sprinkling wagons.
-
-(6) Finally the rollers thoroughly compacted the layer of earth,
-generally passing to and fro over it lengthwise of the dam. Along the
-line of contact at the ends, however, they passed crosswise. Then again
-they frequently went around a portion of the surface until the whole
-was hard and solid.
-
-Two rollers were in use constantly, each drawn by six horses. One
-weighed five tons and the other eight tons, giving respectively 166 and
-200 lbs. pressure per lin. in. They were not grooved, but the smooth
-surface left by the rollers was always harrowed and cut up more or
-less by the loaded wagons passing over the surface previously wetted.
-The wagons when loaded gave 750 lbs. pressure per lin. in., and the
-heavy teams traveling wherever they could do the most effective work
-compacted the materials better even than the rollers.
-
-Several test pits which were dug into the dam during construction
-showed that there were no distinct lines traceable between the layers
-and no loose or dry spots, but that the whole mass was solid and
-homogeneous.
-
-A careful record is being kept of the amount of settlement of the
-Tabeaud Dam. It will be of interest to record here the fact that just
-one year after date of completion the settlement amounted to 0.2 ft.,
-with 90 ft. depth of water in the reservoir.
-
-Water was first turned into the reservoir five months after the dam was
-finished. The very small amount of settlement here shown emphasizes
-more eloquently than words the author’s concluding remarks relating to
-the importance of thorough consolidation, by artificial means, of the
-embankment. (See p. 64, Secs. 6 to 8.)
-
-OUTLET TUNNEL.–The outlet for the reservoir is a tunnel 2,903 ft. in
-length, through a ridge of solid slate rock formation, which was very
-hard and refractory. At the north or reservoir end of the tunnel, there
-is an open cut 350 ft. long, with a maximum depth of 26 ft.
-
-Near the south portal of the tunnel and in the line of pressure pipes
-connecting the “petty reservoir” above with the power-house below,
-is placed a receiver, connected with the tunnel by means of a short
-pipe-line, 60 ins. in diameter.
-
-A water-tight bulkhead of brick and concrete masonry is placed in the
-tunnel, at a point about 175 ft. distant from the receiver. In the line
-of 60-in. riveted steel pipe, which connects the reservoir and tunnel
-with the receiver, there is placed a cast iron chamber for entrapping
-silt or sand, with a branch pipe 16 ins. in diameter leading into a
-side ravine through which sand or silt thus collected can be wasted or
-washed out. By the design of construction thus described, it will be
-seen that all controlling devices, screens, gates, etc., are at the
-south end of the tunnel and easily accessible.
-
-WASTEWAY.–The wasteway for the reservoir is an open cut through its
-rim, 48 ft. in width and 300 ft. long. The sill of the spillway is 10
-ft. below the crown of the dam. The reservoir having less than two
-square miles of catchment area, and the feeding canals being under
-complete control, the dam can never be over-topped by a flood. Fig.
-3 shows the relative location of the dam, outlet tunnel and wasteway
-channel.
-
-Almost the whole of the embankment forming the Tabeaud Dam, not
-included in the foundation work, was built in less than eight months.
-The contractor’s outfit was the best for the purpose the writer has
-ever seen. After increasing his force from time to time he finally had
-the following equipment:
-
-      1 steam shovel (1½ yds. capacity),
-     37 patent dump wagons,
-     11 stick-wagons and rock-carts,
-     39 buck-scrapers (Fresno pattern),
-     21 wheel scrapers,
-      3 road-graders,
-      3 sprinkling wagons,
-      2 harrows,
-      2 rollers (5 and 8-ton),
-    233 men,
-    416 horses and mules,
-      8 road and hillside plows.
-
-STATISTICS.–The following data relating to the Tabeaud Dam Reservoir
-will conclude this description:
-
-
-DAM.
-
-    Length at crown                                            636 ft.
-    Length at base crossing ravine                       50 to 100  “
-    Height to top of crown (El. 1,258.)                        120  “
-      “    at ends above bedrock                               117  “
-      “    at up-stream toe                                    100  “
-      “    at down-stream toe                                  123  “
-    Effective head                                             115  “
-    Width at crown                                              20  “
-    Width at base                                              620  “
-                 Slopes, 2½ on 1 with rock-fill 3 to 1.
-    Excavation for foundations                          40,000 cu. yds.
-    Refill by company                                   40,000      “
-    Embankment built by contractor                     330,350      “
-    Total volume of dam                                370,350      “
-    Total weight                                          664,778 tons.
-    Length of wasteway (width)                                   48 ft.
-    Depth of spillway sill below crown                           10  “
-    Depth of spillway sill below ends                             7  “
-    Height of stop-planks in wasteway                             2  “
-    Maximum depth of water in reservoir                          92  “
-    Area to be faced with stone                          1,933 sq. yds.
-
-
-RESERVOIR.
-
-    Catchment area (approximate)                          2 sq. miles.
-    Area of water surface                                 36.75 acres.
-    Silt storage capacity below outlet tunnel        1,091,470 cu. ft.
-    Available water storage capacity                46,612,405    “
-    Elevation of outlet tunnel                               1,180 ft.
-        “      “ high-water surface                          1,250  “
-        “      “ crown of dam                                1,258  “
-
-Fig. 13 is a view of the finished dam, taken immediately after
-completion.
-
-
-
-
-CHAPTER V.
-
-_Different Types of Earth Dams._
-
-
-There are several types of earth dams, which may be described as
-follows:
-
-    1. Homogeneous earth dams, either with or without a puddle
-       trench.
-
-    2. Earth dams with a puddle core or puddle face.
-
-    3. Earth dams with a core wall of brick, rubble or concrete
-       masonry.
-
-    4. New types, composite structures.
-
-    5. Rock-fill dams with earth inner slope.
-
-    6. Hydraulic-fill dams of earth and gravel.
-
-The writer proposes to give an example of each type, with such remarks
-upon their distinctive features and relative merits as he thinks may be
-instructive.
-
-
-Earth Dams with Puddle Core Wall or Face.
-
-YARROW DAM.–The Yarrow dam of the Liverpool Water-Works is a notable
-example of the second type, (a section of which is shown in Fig. 2.)
-An excavation 97 ft. in depth was made to bed rock through different
-strata of varying thickness, and a trench 24 ft. wide was cut with
-side slopes 1 on 1 for the first 10 ft. in depth below the surface.
-The trench was then carried down through sand, gravel and boulders
-with sides sloping 1 in 12. The upper surface of the shale bed rock
-was found to be soft, seamy and water-bearing. Pumps were installed
-to keep the water out of the trench while it was being cut 4 or 5 ft.
-deeper into the shale. The lower portion was then walled up on either
-side with brickwork 14 ins. in thickness, and the trench between the
-walls was filled with concrete, made in the proportion of 1 of cement,
-1 of sand and 2 of gravel or broken stone. By so doing a dry bed was
-secured for the foundation of the puddle wall. Two lines of 6-in. pipes
-were laid on the bed rock, outside of the walls, and pipes 9 ins. in
-diameter extended vertically above the top of the brickwork some 27
-ft. These pipes were filled with concrete, after disconnecting the
-pumps. After refilling the trench with puddle to the original surface,
-a puddle wall was carried up simultaneous with the embankment, having a
-decreasing batter of 1 in 12, which gave a width of 6 ft. at the top.
-This form of construction is very common in England and Figs. 14 and 15
-show two California dams, the Pilarcitos and San Andres, of the same
-general type.
-
-[Illustration: FIG. 14.–CROSS-SECTION OF PILARCITOS DAM.]
-
-[Illustration: FIG. 15.–CROSS-SECTION OF SAN ANDRES DAM.]
-
-ASHTI EMBANKMENT.–This is not a very high embankment, but being typical
-of modern dams in British India, where the puddle is generally carried
-only to the top of the original surface of the ground, and not up
-through the body of the dam, it is thought worthy of mention. Fig. 16
-shows a section of this embankment, which is located in the Sholapur
-District, India.
-
-The central portion of this dam above the puddle trench is made of
-“selected black soil;” then on either side is placed “Brown Soil,”
-finishing on the outer slopes with “Murum.” Trap rock decomposes first
-into a friable stony material, known in India as “Murum” or “Murham.”
-This material further decomposes into various argillaceous earths, the
-most common being the “black cotton soil” mentioned above.
-
-[Illustration: FIG. 16.–CROSS-SECTION OF ASHTI TANK EMBANKMENT.]
-
-This particular dam has been adversely criticised on account of the
-lack of uniformity in the character of the materials composing the
-bank. It is claimed that the materials being of different density and
-weight, unequal settlement will result, and lines of separation will
-form between the different kinds of materials.
-
-Earth materials do not unite or combine with timber or masonry, but
-there are no such distinct lines of transition and separation between
-different earth materials themselves as Fig. 16 would seem to indicate.
-
-
-Puddle Trench.
-
-In the last three dams mentioned (Figs. 14, 15, 16) the puddle
-trenches are made with vertical sides or vertical steps and offsets.
-A wedge-shaped trench certainly has many advantages over this form.
-Puddle being plastic, consolidates as the dam settles, filling the
-lowest parts by sliding on its bed. It thus has a tendency to break
-away from the portion supported by the step, and a further tendency to
-leave the vertical side, thus forming cracks and fissures for water to
-enter. The argument advanced by those holding a different view, namely,
-that it is difficult to dress the sides of a trench to a steep batter
-and to timber it substantially, has in reality little weight when put
-to practical test. Mr. F. P. Stearns, in describing the recent work
-of excavating the cut-off trench of the North Dike of the Wachusett
-reservoir, Boston, said it was found to be both better and cheaper
-to excavate a trench with slopes than with vertical sides protected
-by sheeting. He favored this shape in case of pile-work and for the
-purpose also of wedging materials together.
-
-Mr. Wm. J. McAlpine’s “Specifications for Earth Dams,” representing the
-best practice of 25 years ago, which are frequently cited, contain the
-following description of how to prepare the up-stream floor of the dam:
-
-    Remove the pervious and decaying matter by breaking up the natural
-    soil and by stepping up the sides of the ravine; also by several
-    toothed trenches across the bottom and up the sides.
-
-One of Mr. McAlpine’s well known axioms was, “water abhors an
-angle.” The “stepping” and “toothed” trenches above specified need
-not necessarily be made with vertical planes, but should be made by
-means of inclined and horizontal planes. The writer’s experience and
-observation leads him to think that all excavations in connection with
-earth dams requiring a refill should be made wedge-shaped so that the
-pressure of the superincumbent materials in settling will wedge the
-material tighter and tighter together and fill every cavity. A paper
-by Mr. Wm. L. Strange, C. E., on “Reservoirs with high Earthen Dams
-in Western India,” published in the Proceedings of the Institution of
-Civil Engineers, Vol. 132, (1898), is one of the best contributions to
-the literature on this subject, known to the writer. Mr. Strange states
-that
-
-    the rate of filtration of a soil depends upon its porosity,
-    which governs the frictional resistance to flow, and the
-    slope and length of the filamentary channels along which the
-    water may be considered to pass. It is evident, therefore,
-    that the direct rate of infiltration in a homogeneous soil
-    must decrease from the top to the bottom of the puddle
-    trench. The best section for a puddle trench is thus a
-    wedge, such as an open excavation would give. It is true
-    that the uppermost infiltrating filaments when stopped by
-    the puddle, will endeavor to get under it, but a depth will
-    eventually be reached when the frictional resistance along
-    the natural passages will be greater than that due to the
-    transverse passage of the puddle trench, and it is when
-    this occurs that the latter may be stopped without danger,
-    as the _filtration to it_ will be less than that
-    _through_ it. This depth requires to be determined in
-    each case, but in fairly compact Indian soils 30 feet will
-    be a fair limit.
-
-
-Puddle Wall vs. Puddle Trench.
-
-There is a diversity of opinion among engineers in regard to the proper
-place for the puddle in dam construction. Theoretically, the inner
-face would be preferable to the center, for the purpose of preventing
-any water from penetrating the embankment. It is well known that all
-materials immersed in water lose weight in proportion to the volume of
-water they displace. If the upper half of the dam becomes saturated
-it must neccesarily lose both weight and stability. Its full cohesive
-strength can only be maintained by making it impervious in some way.
-The strength of an earth dam depends upon three factors:
-
-    1. Weight.
-    2. Frictional resistance against sliding.
-    3. Cohesiveness of its materials.
-
-These can be known only so long as no water penetrates the body of
-the dam. When once saturated the resultant line of pressure is no
-longer normal to the inner slope, for the reason that there is now a
-force tending to slide the dam horizontally and another due to the
-hydrostatic head tending to lift it vertically. When the water slope
-is impervious the horizontal thrust is sustained by the whole dam and
-not by the lower half alone. When once a passage is made into the body
-of the dam, the infiltration water will escape along the line of least
-resistance, and if there be a fissure it may become a cavity and the
-cavity a breach.
-
-For practical reasons, mainly on account of the difficulty of
-maintaining a puddle face on the inner slope of a dam, which would
-require a very flat slope, puddle is generally placed at the center as
-a core wall.
-
-It was thought possible at the Tabeaud dam to counteract the tendency
-of the face puddle to slough off into the reservoir by use of a broken
-stone facing of riprap. This covering will protect the puddle from the
-deteriorating effects of air and sun whenever the water is drawn low
-and also resists the pressure at the inner toe of the dam.
-
-
-Percolation and Infiltration.
-
-The earlier authorities on the subject of percolation and infiltration
-of water are somewhat conflicting in their statements, if not confused
-in their ideas. We are again impressed with the importance of a clearly
-defined and definite use of terms. The temptation and tendency to use
-language synonymously is very great, but it is unscientific and must
-result in confusion of thought. Let it be observed that _filtration_
-is the process of mechanically separating and removing the undissolved
-particles floating in a liquid. That _infiltration_ is the process
-by which water (or other liquid) enters the interstices of porous
-material. That _percolation_ is the action of a liquid passing through
-small interstices; and, finally, that _seepage_ is the amount of fluid
-which has percolated through porous materials.
-
-Many recent authorities are guilty of confusion in thought or
-expression, as will appear from the following:
-
-One says, for instance, that a
-
-    rock is water-tight when non-absorbent of water, but that a soil
-    is not water-tight unless it will absorb an enormous quantity of
-    water.
-
-This would seem to indicate that super-saturation and not pressure is
-necessary to increase the water-tightness of earth materials.
-
-Again, in a recent discussion regarding the saturation and percolation
-of water through the lower half of a reservoir embankment, it was
-remarked, that
-
-    the more compact the material of which the bank is built,
-    the steeper will be the slope of saturation.
-
-Exception was taken to this, and the statement made, that
-
-    _with compact material_, the sectional area of flow
-    is larger below a given level with porous material, and as
-    the bank slope is one determining factor of the line of
-    saturation, this line tends to approach the slope line;
-    while with porous material in a down-stream bank, the slope
-    of saturation is steeper and the area of the flow less.
-
-In reply to this, it was said,
-
-    that it is obvious that if the embankment below the core
-    wall is built of material so compact as to be impervious
-    to water, no water passing through the wall will enter it,
-    and the slope of saturation will be vertical. If it be
-    less compact, water will enter more or less according to
-    the head or pressure, and according to its compactness or
-    porosity, producing a slope of saturation whose inclination
-    is dependent on the frictional resistance encountered by
-    the water. And the bank will be tight whenever the slope of
-    saturation remains within the figure of the embankment.
-
-Further,
-
-    that it was necessary to distinguish between the slope assumed
-    by water _retained in_ an embankment and that taken by water
-    _passing through_ an embankment made of material too porous to
-    retain it; where the rule is clearly reversed and where the more
-    porous the material the steeper the slope at which water will run
-    through it at a given rate.
-
-These citations are sufficient to emphasize the importance of exact
-definition of terms and clear statement of principles.
-
-The latest experiments relating to the percolation of water through
-earth materials and tests determining the stability of soils are
-those made during the investigations at the New Croton Dam and
-Jerome Park Reservoir, New York, and those relating to the North
-Dike of the Wachusett Reservoir, Boston. These are very interesting
-and instructive, and it is here proposed to discuss the results and
-conclusions reached in these cases, after some introductory remarks
-reciting the order of events.
-
-NEW CROTON DAM.–In June, 1901, the Board of Croton Aqueduct
-Commissioners of New York requested a board of expert engineers,
-consisting of Messrs. J. J. R. Croes, E. F. Smith and E. Sweet, to
-examine the plans for the construction of the earth portion of the New
-Croton Dam, and also the core wall and embankment of the Jerome Park
-reservoir.
-
-This report was published in full in Engineering News for Nov. 28,
-1901. It was followed in subsequent issues of the said journal by
-supplemental and individual reports from each member of the board
-of experts, and by articles from Messrs. A. Fteley, who originally
-designed the works, A. Craven, formerly division engineer on this work,
-and W. R. Hill, at that time chief engineer of the Croton Aqueduct
-Commission.
-
-After describing the New Croton Dam, the board of experts preface their
-remarks on the earth embankment by saying that
-
-    it has been abundantly proven that up to a height of 60
-    or 70 ft. an embankment founded on solid material and
-    constructed of well-selected earth, properly put in place,
-    is fully as durable and safe as a masonry wall and far less
-    costly.
-
-There are, in fact, no less than 22 earth dams in use to-day exceeding
-90 ft. in height, and twice that number over 70 ft. in height. Five of
-the former are in California, and several of these have been in use
-over 25 years. The writer fails to appreciate the reason for limiting
-the safe height of earth dams to 60 or 70 ft.
-
-The New Croton Dam was designed as a composite structure of masonry
-and earth, crossing the Croton Valley at a point three miles from the
-Hudson River. The earth portion was to join the masonry portion at a
-point where the latter was 195 ft. high from the bed rock. The Board
-thought there was no precedent for such a design and no necessity
-for this form of construction. The point to be considered here was
-whether a dam like this can be made sufficiently impermeable to water
-to prevent the outer slope from becoming saturated and thus liable to
-slide and be washed out.
-
-The design of the embankment portion was similar to all the earth dams
-of the Croton Valley. In the center is built a wall of rubble masonry,
-generally founded upon solid rock, and “intended to prevent the free
-seepage of water, but not heavy enough to act alone as a retaining wall
-for either water or earth.”
-
-Fig. 17 shows a section which is typical of most New England earth
-dams; and Fig. 18, the sections of two of the Croton Valley dams, New
-York water supply. These dams all have masonry core walls, illustrating
-the third type of dams given on page 33.
-
-[Illustration: FIG. 17.–CROSS-SECTION OF A TYPICAL NEW ENGLAND DAM.]
-
-The board of experts made numerous tests by means of borings into
-the Croton Valley dams to determine the slope of saturation. The
-hydraulic laboratory of Cornell University also made tests of the
-permeability of several samples of materials taken from pits. All the
-materials examined were found to be permeable and when exposed to water
-to disintegrate and assume a flat slope, the surface of which was
-described as “slimy.”
-
-Pipe wells were driven at different places into the dams and the line
-of saturation was determined by noting the elevations at which the
-water stood in them. In all the dams the entire bank on the water side
-of the core wall appeared to be completely saturated. Water was also
-found to be standing in the embankment on the down-stream side of the
-core wall. The extent of saturation of the outer bank varied greatly,
-due to the difference in materials, the care taken in building them,
-and their ages. Fig. 19 gives the average slopes of saturation as
-determined by these borings.
-
-The experts stated
-
-    that the slope of the surface of the saturation in the bank
-    is determined by the solidity of the embankment: The more
-    compact the material of which the bank is built, the steeper
-    will be the slope of saturation.
-
-As a result of their investigations, the experts were of the opinion
-that the slope of saturation in the best embankments made of the
-material found in the Croton Valley is about 35 ft. per 100 ft., and
-that with materials less carefully selected and placed the slope may be
-20 ft. per 100 ft.
-
-Further, that taking the loss of head in passing through the core wall,
-and the slope assumed by the plane of saturation, the maximum safe
-height of an earth dam with its top 20 ft. above water level in the
-reservoir and its outside slope 2 on 1, is 63 to 102.5 ft. This is a
-remarkable finding in view of the fact that the Titicus Dam, one of the
-Croton Valley dams examined, has a maximum height above bed rock of 110
-ft. and has been in use seven years. This dam is not a fair example to
-cite in proof of their conclusion, because its _effective head_ is only
-about 46 ft.[2]
-
-[Illustration: BOG BROOK DAM.]
-
-[Illustration: MIDDLE BRANCH DAM.
-
-FIG. 18.–CROSS-SECTION OF TWO CROTON VALLEY DAMS, SHOWING SATURATION.]
-
-Mr. Fteley gave as a reason for the elevation of the water slope
-found in the outer bank of the Croton dams the fact of their being
-constructed of fine materials and stated that with comparatively porous
-materials they would have shown steeper slopes of saturation.
-
-Mr. Craven argued that all dams will absorb more or less water, and
-that porosity is merely a degree of compactness; that slope implies
-motion in water, and that there is no absolute retention of water in
-the outer bank of a dam having its base below the plane indicated by
-the loss of head in passing through the inner bank and then through a
-further obstruction of either masonry or puddle; that there is simply a
-partial retention, with motion through the bank governed by the degree
-of porosity of the material.
-
-Fig. 19 is a graphical interpretation of the conclusion reached by the
-board of experts, as already given on page 41. “A” is an ideal profile
-of a homogeneous dam with the inner slope 3 on 1 and the outer slope 2
-on 1. The top width is made 25 ft. for a dam having 90 ft. effective
-head, the high-water surface in the reservoir being 10 ft. below the
-crest of the dam. This ideal profile is a fair average of all the earth
-dams of the world. Not having a core wall to augment the loss of head,
-it fairly represents what might be expected of such a dam built of
-Croton Valley material, compacted in the usual way. It should be noted
-that the intersection of the plane of saturation with the rear slope of
-the dam at such high elevation as shown indicates an excessive seepage
-and a dangerously unstable condition.
-
-
-Preliminary Study of Profile for Dam.
-
-The preliminary calculations for designing a profile for an earth dam
-are simple and will here be illustrated by an example. Let us assume
-the following values:
-
-    a. Central height of dam, 100 ft.
-
-    b. Maximum depth of water, 90 ft., with surface 10 ft. below
-       crest of dam.
-
-    c. Effective head, 90 ft.
-
-    d. Weight of water, 62.5 lbs. per cu. ft.
-
-    e. Weight of material, 125 lbs. per cu. ft.
-
-    f. Coefficient of friction, 1.00, or equal to the weight.
-
-    g. Factor of safety against sliding, 10.
-
-    The width corresponding to the vertical pressure of 1 ft. is,
-    (62.5 × 10)/125 = 5 ft.
-
-[Illustration]
-
-[Illustration: FIG. 19.–GRAPHICAL INTERPRETATION OF STUDIES OF BOARD OF
-EXPERTS ON THE ORIGINAL EARTH PORTION OF THE NEW CROTON DAM.]
-
-The hydrostatic pressure per square foot at 90 ft. depth is, 62.5 × 90
-= 5,625 lbs.
-
-The dam, having a factor of safety of 10, must present a resistance of,
-5,625 × 10 = 56,250 lbs., or 28 tons per square foot.
-
-The theoretical width of bank corresponding to 90 ft. head and a factor
-of 10 is shown by the dotted triangle (A-B-B) to be 450 ft., (B, Fig.
-19) with slopes 2½ on 1.
-
-To this must be added the width due to the height of crest above the
-water surface in the reservoir and the width of crest.
-
-The former would be, 2 (2½ × 10) = 50 ft., and the latter by
-Trautwine’s rule, 2 + 2√100 = 22 ft., giving a total base width of 522
-ft.
-
-Let us now assume that the slope of saturation may be 35 ft. per 100
-ft. We observe that this intersects the base 40 ft. within the outer
-toe of the bank slope. If the plane of saturation was 33 ft. per 100,
-it would just reach the outer toe. It would be advisable to enlarge
-this section by adding a 10-ft. berm at the 50-ft. level, having a
-slope not less than 3 on 1 for the up-stream face, and two 15-ft. berms
-on the down-stream face, having slopes 2½ on 1. The additional width
-of base due to these modifications in our profile amounts to 65 ft.,
-giving a total base width of 587 ft., and increasing the factor of
-safety from 10 to 13. It should be remembered that if the bank becomes
-saturated this factor of safety may be reduced 50%, the coefficient of
-moist clay being 0.50.
-
-The loss of head due to a core wall of masonry, as designed for the
-New Croton Dam, was assumed by the board of experts to be 21 ft., or
-17% of the depth of water in full reservoir. It has been stated by
-several authorities that the primary object of a masonry core wall is
-to afford a water-tight cut-off to any water of percolation which may
-reach it through the upper half of the embankment. It appears that
-absolute water-tightness in the core wall is not obtained, although the
-core walls of the Croton dams are said to be “the very best quality of
-rubble masonry that can be made.”
-
-Mr. W. W. Follett, who is reported to have had considerable experience
-in building earth dams, and who has made some valuable suggestions
-thereupon, is emphatic in saying,
-
-    that the junction of earth and masonry forms a weak point, that
-    either a puddle or masonry core in an earthen dam is an element
-    of weakness rather than strength.
-
-He also thinks the usual manner of segregating and depositing
-materials different in density and weight, and thus subject to
-different amounts of settlement, as bad a form of construction as could
-be devised.
-
-Core walls may prevent “free passage of water” and “excessive seepage,”
-but are nevertheless of doubtful expediency.
-
-
-Earthwork Slips and Drainage.
-
-Mr. John Newman, in his admirable treatise on “Earthwork Slips and
-Subsidences upon Public Works,” classifies and enumerates slips as
-follows:
-
-    Natural causes, 7.
-    Artificial causes, 31.
-    Additional causes due to impounded water, 7.
-
-After describing each cause he presents 39 different means used to
-prevent such slips and describes methods of making repairs.
-
-Mr. Wm. L. Strange has had such a large and valuable experience and has
-set forth so carefully and lucidly both the principles and practice of
-earth dam construction, that the writer takes pleasure in again quoting
-him on the subject of _drainage_, of which he is an ardent advocate. He
-says that,
-
-    thorough drainage of the base of a dam is a matter of vital
-    necessity, for notwithstanding all precautions, some water will
-    certainly pass through the puddle.
-
-It is at the junction of the dam with the ground that the maximum
-amount of leakage may be expected. The percolating water should be
-gotten out as quickly as possible. The whole method of dealing with
-slips may be summed up in one word–_drainage_.
-
-The proper presentation of these two phases of our subject would in
-itself require a volume. The interested reader is therefore referred to
-the different authorities and writers cited in Appendix II.
-
-
-Jerome Park Reservoir Embankments.
-
-The Jerome Park reservoir is an artificial basin involving the
-excavation and removal of large quantities of soil, and the erection of
-long embankments with masonry core walls, partly founded on rock and
-partly on sand. The plan and specifications call for an embankment 20
-ft. wide on top, with both slopes 2 on 1, and provide for lining the
-inner slope with brick or stone laid in concrete, and for covering the
-bottom with concrete laid on good earth compacted by rolling.
-
-[Illustration: Section at Sta. 99.]
-
-[Illustration: Section at Sta. 76+20.
-
-FIG. 20.–GRAPHICAL EXHIBIT OF STUDIES OF JEROME PARK RESERVOIR
-EMBANKMENT.]
-
-Wherever bed rock was not considered too deep below the surface the
-core walls were built upon it. In other places the foundation was
-placed 8 to 10 ft. below the bottom of the reservoir and rested upon
-the sand.
-
-It appears that the plans of the Jerome Park embankment were changed
-from their original design, prior to the report of the board of
-experts, on account of two alleged defects, namely, “cracks in the core
-wall” and “foundation of quicksand,” and incidentally on account of the
-supposed instability of the inner bank.
-
-In describing the materials on which these embankments rest the experts
-remarked
-
-    that all these fine sands are unstable when mechanically
-    agitated in an excess of water, and that they all settle in
-    a firm and compact mass under the water when the agitation
-    ceases. That they are quite unlike the true quicksands whose
-    particles are of impalpable fineness and which are “quick”
-    or unstable under water.
-
-Fig. 20 is a graphic exhibit of the results of tests made at “Station
-76 + 20,” and at “Station 99,” to determine the flow line of water in
-the sand strata underlying the embankment and bottom of the Jerome Park
-reservoir.
-
-The experts reported that there was no possible danger of sliding or
-sloughing of the bank; that the utmost that could be expected would
-be the percolation of a small amount of water through the embankment
-and the earth; and that this would be carried off by the sewers in the
-adjacent avenues; that a large expenditure to prevent such seepage
-would not be warranted nor advisable.
-
-In concluding their report, however, they recommended changing the
-inner slope of 2 on 1 to 2½ on 1, and doubling the thickness of the
-concrete lining at the foot of the slope to preclude all possibility
-of the sliding or the slipping of the inner bank in case of the water
-being lowered rapidly in the reservoir.
-
-Mr. W. R. Hill, then chief engineer of the Croton Aqueduct Commission,
-favored extending the core walls to solid rock. He took exception to
-the manner of obtaining samples of sand by means of pipe and force-jet
-of water, claiming that only the coarsest sand was obtained for
-examination. He did not consider fine sand through which three men
-could run a ¾-in. rod 19 and 20 ft. to rock without use of a hammer,
-very stable material upon which to build a wall.
-
-
-North Dike of the Wachusett Reservoir, Boston.
-
-The North Dike of the Wachusett Reservoir is another large public work
-in progress at the present time. It is of somewhat unusual design
-and the preliminary investigations and experiments which led to its
-adoption are interesting in the extreme.[3]
-
-The area to be explored in determining the best location for the dike
-was great, and the preliminary investigations conducted by means of
-wash drill borings, very extensive. A total of 1,131 borings were made
-to an average depth of 83 ft., the maximum depth being 286 ft. The
-materials were classified largely by the appearance of the samples,
-though chemical and filtration tests were also made. The plane of the
-ground water was from 35 to 50 ft. below the surface, and the action of
-the water-jet indicated in a measure the degree of permeability of the
-strata.
-
-In addition to these tests experimental dikes of different materials,
-and deposited in different ways, were made in a wooden tank 6 ft. wide,
-8 ft. high and 60 ft. long. The stability of soils when in contact with
-water was experimented with, as shown in Fig. 21, in the following
-manner:
-
-An embankment (Fig. 21) was constructed in the tank of the material to
-be experimented with, 2 ft. wide on top, 6 ft. high, with slopes 2 on
-1, and water admitted on both sides to a depth of 5 ft. The top was
-covered with 4-in. planks 2 ft. long and pressure applied by means of
-two jack screws resting upon a cross beam on top of the planks.
-
-With a pressure of three tons per square foot, the 4-in. planks were
-forced down into the embankment a little more than 6 ins., resulting
-in a very slight bulging of the slopes a little below the water level.
-Immediately under the planks the soil became hard and compact. A man’s
-weight pushed a sharp steel rod, ¾-in. in diameter, only 6 to 8 ins.
-into the embankment where the pressure was applied, while outside of
-this area the rod was easily pushed to the bottom of the tank.
-
-These results corroborate in a general way the practical experience of
-the author, both in compressed embankments, where he found it necessary
-to use a pick vigorously to loosen the material of which they were
-composed, and in embankments made by merely dumping the material from
-a track, in which case the earth is so slightly compressed that an
-excavation is easily made with a shovel.
-
-[Illustration: Fig. 21.]
-
-[Illustration: Fig. 22.]
-
-[Illustration: Fig. 23.–CAN FOR DETERMINING FRICTIONAL RESISTANCE]
-
-[Illustration: Fig. 24.]
-
-[Illustration: Fig. 25.
-
-FIGS. 21 TO 24.–EXPERIMENTAL DIKES AND CYLINDER EMPLOYED IN STUDIES FOR
-THE NORTH DIKE OF THE WACHUSETT RESERVOIR; AND (FIG. 25) CROSS-SECTION
-OF THE DIKE.]
-
-The difference in the coefficient of friction of the same material
-when dry and when wet greatly modifies the form of slope. The harder
-and looser the particles, the _straighter_ will be the slope line in
-excavation and slips. The greater the cohesion of the earth, the _more
-curved_ will be the slope, assuming a parabolic curve near the top–the
-true form of equilibrium.
-
-RATE OF FILTRATION.–The rate of filtration through different soils was
-experimented with by forming a dike in the tank previously mentioned,
-as shown in Fig. 22.
-
-The dike was made full 8 ft. high, 7 ft. wide on top, with a slope on
-the up-stream side of 2 on 1, and on the down-stream side 4 on 1. This
-gave a base width of 55 ft. Immediately over the top of the dike there
-was placed 3 ft. of soil to slightly consolidate the top of the bank
-and permit the filling of the tank to the top without overflowing the
-dike. The water pressure in different parts of the dike was determined
-by placing horizontal pipes through the soil crosswise of the tank.
-These pipes were perforated and covered with wire gauze, being
-connected to vertical glass tubes at their ends. The end of the slope
-on the down-stream side terminated in a box having perforated sides and
-filled with gravel, thus enabling the water to percolate and filter out
-of the bank without carrying the soil with it.
-
-When the soil was shoveled loosely into the tank, without consolidation
-of any kind, it settled on becoming saturated and became quite compact.
-It took five days for the water to appear in the sixth gauge pipe near
-the lower end of the tank. After the pressure, which was maintained
-constant, had been on for several weeks, the seepage amounted to one
-gallon in 22 minutes. When the soil was deposited by shoveling into the
-water, the seepage amounted to one gallon in 34 minutes.
-
-The relative filtering capacities of soils and sands were thought to
-be better determined by the use of galvanized iron cylinders of known
-areas.
-
-Fig. 23 shows one of the cylinders. These latter experiments confirmed
-those previously made at Lawrence, by Mr. Allen Hazen, for the
-Massachusetts State Board of Health. They showed that the loss of head
-was directly proportioned to the quantity of water filtered and that
-the quantity filtered will vary as the square of the diameter of the
-_effective size_ of the grains of the filtering material.[4]
-
-The material classed as “permeable” at the North Dike of the Wachusett
-Reservoir has an effective diameter of about 0.20 mm. A few results are
-given in the following table:
-
-
-Amount of Filtration in Gallons per Day, Through an Area of 10,000 Sq.
-Ft., With a Loss of Head or Slope of 1 ft. in 10 ft.
-
-        Material.                Unit ratios.    U. S. gallons.
-
-    (1) Soil                            1                 510
-    (2) Very fine sand                 14               7,200
-    (3) Fine sand                     176              90,000
-    (4) Medium sand                   784             400,000
-    (5) Coarse sand                 4,353           2,200,000
-
-To be sure that the accumulation of air in the small interstices of
-the _soil_ was not the cause of the greatly reduced filtration through
-it, another series of experiments was conducted in the wooden tank, as
-shown in Fig. 24.
-
-A pair of screens was placed near each end of the tank, filled with
-porous material, sand and gravel, and the 50-ft. space between filled
-with soil. The soil was rammed in 3-in. layers, and special care taken
-to prevent water from following along the sides and bottom of the tank.
-One end was filled with water to near the top, while the other end gave
-a free outlet.
-
-After this experiment had been continued for more than a month, the
-amount of seepage averaged 1.7 gallons per 24 hours, or about 32 drops
-per minute.
-
-Filtration tests were also made through soil under 150 ft. head, or 5
-lbs. per sq. in., with results not materially different, it is stated,
-from those already given. The soil used in all these tests contained
-from 4 to 8% by weight of organic matter. This was burned and similar
-tests made with the incinerated soil, resulting in an increase of about
-20% more seepage water.
-
-PERMANENCE OF SOILS.–This last material experimented with suggests the
-subject of _permanence_ of soils. This was reported upon separately and
-independently by Mr. Allen Hazen and Prof. W. O. Crosby. These experts
-agreed in their conclusion, stating
-
-    that the process of oxidation below the line of saturation would be
-    extremely slow, requiring many thousands of years for the complete
-    removal of all the organic matter, and that the tightness of the
-    bank would not be materially affected by any changes which are
-    likely to occur.
-
-It has been remarked,
-
-    that of all the materials used in the construction of
-    dams, _earth_ is physically the least destructible of
-    any. The other materials are all subject to more or less
-    disintegration, or change in one form or another, and in
-    earth they reach their ultimate and most lasting form.
-
-In speaking of the North Dike of the Wachusett Reservoir, Mr. Stearns
-remarked that,
-
-    it was evident by the application of Mr. Hazen’s formula for
-    the flow of water through sands and gravels, that the very
-    fine sands found at a considerable depth below the surface
-    would not permit enough water to pass through them if a dike
-    of great width were constructed, to cause a serious loss of
-    water, and it was also found that the soil, which contained
-    not only the fine particles or organic matter, but also a
-    very considerable amount of fine comminuted particles, which
-    the geologist has termed “rock flour,” would be sufficiently
-    impermeable to be used as a substitute for clay puddle.
-
-Fig. 25 shows the maximum section of the North Dike with its cut-off
-trench. The quantities and estimated cost of the completed structure
-are given in the table herewith:
-
-                                               |–––   Cost   –––|
-                                                        Per cent.
-    Work.               Quantities.    Unit    Actual.    total.
-                         (cu. yds.)    Price.
-    Soil                 5,250,000     $0.05  $262,500    34.7
-    Cut-off trench         542,000       .20   108,400    19.3
-    Borrowed
-      earth and gravel     200,000       .20    40,000
-    Slope paving            50,000      2.20   110,000    14.6
-    Sheet-piling,
-      pumping, etc.                            117,000    15.5
-    Engineering and
-      preliminary investigations               120,000    15.9
-                                               –––––––   –––––
-          Total cost                          $757,900   100.0
-
-
-Druid Lake Dam, Baltimore, Md.
-
-Another very interesting and instructive example of high earth dam
-construction is that of the Druid Lake Reservoir embankment, Baltimore,
-Md.
-
-This dam was built under the supervision of Mr. Robt. K. Martin.
-Construction was begun in 1864, and the dam was finished in 1870. Mr.
-Alfred M. Quick, present chief engineer of the water-works of the
-City of Baltimore has given a very lucid description of this work in
-Engineering News of Feb. 20, 1902.
-
-Fig. 26 is a cross-section of this dam, showing the method of
-construction so clearly as to scarcely need further description. The
-banks D-D on either side of the central puddle wall were carried up in
-6-in. layers with horses and carts, and kept about 2 ft. higher than
-the puddle trench, which always contained water. The banks E-E were
-made of dumped material, after which the basins F-F were first filled
-with water and finally filled by dumping material into the water from
-tracks being moved in toward the center.
-
-[Illustration: FIG. 26–WORKING CROSS-SECTION OF DRUID LAKE DAM.]
-
-After reaching the top of this fill, banks B-B-B were built up in
-layers similar to D-D. The second set of basins C-C were then filled
-in a manner similar to F-F. The remaining portion A-A was constructed
-in layers like D-D and B-B, with the addition of compacting each layer
-with a heavy roller.
-
-Finally the inner face slope was carried up in 3-in. layers and
-thoroughly rolled, after which 2 ft. of “good puddle” was put upon the
-inner slope the latter was rip-rapped, the crown covered with gravel
-and the rear slope sodded.
-
-Some years after completion, a driveway was built along the outer
-slope, as shown, which had a tendency to strengthen the dam, though not
-designed expressly for that purpose.
-
-It is of interest to know that the influent, effluent and drain pipes
-were originally constructed through or under the embankment. These
-pipes were laid upon solid earth, and where they passed through the
-puddle wall were supported upon stone piers 6 ft. apart. As might be
-expected, they soon cracked badly and were finally abandoned, new ones
-being placed in the original ground at the south side of the lake. Mr.
-Quick states that so far as is known there has never been any evidence
-of a leak through the embankment during these 32 years of service.
-
-
-New Types of Dams; Bohio, Panama Canal.
-
-A brief description will now be given of three different dams designed
-for Bohio, on the proposed Panama Canal. Mr. George S. Morison’s paper
-before the American Society of Civil Engineers, on “The Bohio Dam,”
-and the discussion thereon, especially that by Mr. F. P. Stearns, were
-quite fully reported in Engineering News for March 13 and May 8, 1902.
-In constructing the Panama Canal it will be necessary to impound the
-waters of the Chagres River, near Bohio, to maintain the summit level
-of this canal and supply water for lockage.
-
-THE FRENCH DESIGN.–Fig. 27 is an enlarged section of the original
-design of the new French Co. This design has no core wall, but at
-the up-stream toe a concrete wall was to be built across the river
-between the two lines of sheet-piling. At the down-stream toe a large
-amount of riprap was to be placed to prevent destruction of the dam
-during construction. In this case it would be necessary to construct
-a temporary dam above and also to use the excavation for the locks
-as a flood spillway. This method would involve considerable risk to
-the work, on account of the large volume of flood waters it might be
-necessary to take care of during construction.
-
-ISTHMIAN CANAL COMMISSION.–The dam proposed by the Isthmian Canal
-Commission is shown by Fig. 28. This was designed to be an absolutely
-water-tight closure of the geological valley, by using a masonry core
-wall carried down to bed rock. The maximum depth being 129 ft., it was
-planned to rest the concrete wall on a series of pneumatic caissons
-reaching to rock. The spaces between the caissons would be closed and
-made water-tight. Both slopes of the earth embankment were to have
-horizontal benches and be revetted with loose rock.
-
-MR. MORISON’S DESIGN.–To appreciate fully the object and aim of the
-third design, Fig. 29, which may be called a new type, although similar
-in many respects to the North Dike of the Wachusett reservoir already
-illustrated and described, it should be stated that the equalized flow
-of the Chagres River is put at 1,000 cu. ft. per sec. Of this quantity
-it is estimated that 500 cu. ft. would be needed for lockage and 200
-cu. ft. for evaporation. This leaves 300 cu. ft. per sec. available for
-seepage and other losses or to be wasted.
-
-[Illustration]
-
-[Illustration]
-
-[Illustration: FIGS. 27 TO 29.–DESIGNS FOR THE BOHIO DAM, PANAMA
-CANAL.]
-
-It will thus be seen that a scarcity of water is not in this instance
-a condition demanding an absolutely water-tight dam. The amount of
-seepage permissible without endangering the stability of the structure
-is the real point now to be discussed.
-
-The third design, which was proposed by Mr. Morison, is shown by Fig.
-29. The topography and configuration of this dam site is not unlike
-that of the San Leandro Dam, California, soon to be described, while
-the general design is similar, as has been remarked, to the North Dike
-of the Wachusett Reservoir.
-
-This third design contemplates a compound structure, formed by two
-rock-fill dams situated about 2,120 ft. apart, with the intervening
-space filled with loose rock, earth and other available material.
-Immediately below the upper and higher rock-fill dam, it is proposed
-to place across the canyon a puddle wall 50 ft. in width, resting over
-two lines of sheet-piling 30 ft. apart. This piling would probably not
-reach farther than 50 ft. below tidewater, the solid rock floor being
-about 100 ft. deeper.
-
-Mr. Morison made use of Mr. Hazen’s filtration formula for estimating
-the rate and quantity of seepage through the permeable strata below the
-dam. This formula is:
-
-             h t + 10°
-    V = cd² –– ––––––
-             l   60
-
-    where
-
-    V = rate of flow in meters per day through the whole section.
-    c = constant varying from 450 to 1,200,
-        according to cleanness of the sand.
-    d = “effective size” of sand in mm.
-    h = head in feet.
-    l = length or distance water must pass.
-    t = temperature of the water (Fahr.)
-
-This formula should be used only when the _effective sizes_ of sands
-are from 0.10 to 3.0 mm. and with _uniformity coefficients_ below
-5.0[5].
-
-Mr. Morison used the following values: c = 1,000; d = 1.0 mm.; h = 90
-ft.; l = 2,500 ft.; t = 90°; for the solution of this problem, and
-obtained a velocity of 0.002 ft. per sec. The bed of sand and gravel
-was assumed to have a sectional area of 20,000 sq. ft. for 2,500 ft. in
-length. This gives a seepage of 40 cu. ft. per sec.
-
-It is believed that the above rate of 0.002 ft. per sec., equivalent to
-1⅜ ins. per minute, or 7 ft. per hour, is not sufficient to move any of
-the material. The velocity of water percolating through sand is found
-to vary directly as the head and inversely as the distance.
-
-The value of “c” in the formula is larger for sands of filters
-favorable for flow, and smaller for compacted materials and dams.
-
-Mr. Morison thought it might be nearer the actual conditions to assume
-d = 0.50 mm.; c = 500; and l = 5,000 ft.; in which case the seepage
-would only amount to 2.5 ft. per sec. In this last assumption the
-“effective size” of sand grains is 2½ times that classed as “permeable
-material” at the North Dike of the Wachusett Reservoir.
-
-Prof. Philipp Forchheimer, of Gratz, Austria, recommends the use of the
-formula,
-
-     h
-    ––– = a√ + b√²
-     l
-
-for the percolation through soils between loam and loamy sand.
-Sellheim, Masoni, Smreker, Kröber and other authorities on filtration
-use still other formulas, to which the reader and student is referred
-for further research.
-
-The writer, having had occasion in his professional practice to study
-quite carefully the subject of ground waters, and their percolation
-or flow through different classes of materials and under varying
-conditions, is of the opinion that rarely does the cross-section of
-a stream-channel, filled with sand, gravel and debris, present, even
-approximately, a homogeneous or uniform mass; and that there are,
-almost without exception, strata of material much coarser and more
-porous than the general average. In other words, that it is extremely
-difficult to arrive at a uniformity coefficient. It is unwise to place
-much reliance upon an estimated flow where this is the case. The
-formula may be used with confidence where the layers are artificially
-made, and where there is no uncertainty regarding the uniform character
-of the material. In most natural channels there are distinct lines
-of flow, and under considerable hydrostatic head or pressure these
-lines of flow would surely enlarge. There is a wide difference between
-permissible and dangerously excessive percolation through an earth
-embankment. The local features, economical considerations and magnitude
-of the risks, all bear upon this question and must be considered for
-each particular case.
-
-It is of interest to compare the estimated cost of the three designs
-proposed for the Bohio Dam, based upon the same unit prices, as follows:
-
-    French Engineers’ design              $3,500,000
-    Isthmian Canal Commissioners’ design   8,000,000
-    Mr. Morison’s design                   2,500,000
-
-No comments will be made upon these figures, further than to remark
-that the successful building of a stable dam, accomplished by the use
-of an excessive quantity of materials and at a cost beyond reasonable
-requirements, is mainly instructive as illustrating “how not to do it.”
-It is creditable to execute substantial works at a reasonable cost,
-but it reflects no credit upon any one to construct them regardless of
-expense.
-
-
-Combined Rock-fill and Earth Dam.
-
-Fig. 30 shows a section of the Upper Pecos River Dam near Eddy, N. M.
-
-This dam is quite fully described by Mr. Jas. D. Schuyler, in his
-recent book on “Reservoirs for Irrigation, Water-Power and Domestic
-Water-Supply,” and need not be mentioned in this paper, further than
-to call attention to the combination of rock-fill and earth which
-constitutes its particular type of construction. This type of dam is
-believed to be for many localities a very good one, but up to the
-present time has only been adopted for dams of moderate height, under
-60 ft.
-
-
-The San Leandro Dam, California.
-
-A section of the San Leandro Dam, near Oakland, Cal., is shown by
-Fig. 31. This section was supplied by Mr. W. F. Boardman, hydraulic
-engineer, who superintended the construction of the dam, from his own
-private notes and data. It differs materially from sections heretofore
-published, and is 5 ft. higher, thus making it rank as the highest
-earth dam in the world of which we have an authentic record.
-
-The dam was commenced in 1874, and brought up to a height of 115 ft.
-above the bed of the creek in 1898. At the present time it is 500 ft.
-in length on the crest and 28 ft. wide. The original width of the
-ravine at the base of the dam was 66 ft. The present width of base
-from toe to toe of slopes is 1,700 ft. The height of embankment above
-the original surface is 125 ft., with a puddle trench extending 30 ft.
-below.
-
-[Illustration: FIG. 30.–CROSS-SECTION OF UPPER PECOS RIVER DAM;
-COMBINED ROCK FILL AND EARTH.]
-
-[Illustration: FIG. 31.–DEVELOPED SECTION OF SAN LEANDRO DAM.]
-
-All that portion of the dam within a slope of 2½ on 1 at the rear and
-3 on 1 at the face is built of choice material, carefully selected and
-put in with great care. The portion outside of the 2½ on 1 slope line
-at the down-stream side of the dam, was _sluice in_ from the adjacent
-hills regardless of its character, and is composed of ordinary soil
-containing more or less rock.
-
-This process of sluicing was carried on during the rainy season, when
-there was an abundance of water, and it was intended to be continued
-until the canyon below the dam had been filled to an average slope of
-6.7 on 1 at the rear of the dam. It was thought that the location was
-particularly favorable for this kind of construction, the original
-intention being to raise the dam from time to time, not only to
-increase the storage as the demand for water increased, but to meet
-the annual loss in capacity caused by the silting up of the reservoir
-basin. The latter has amounted to about 1 ft. in depth per annum.
-
-METHOD OF CONSTRUCTION.–Under the main body of the dam, the surface was
-stripped of all sediment, sand, gravel and vegetable matter. Choice
-material, carefully selected, was then brought by carts and wagons and
-evenly distributed over the surface in layers about 1 ft. or less in
-thickness. This was sprinkled with just enough water to make it pack
-well, not enough to make it like mud. During construction a band of
-horses was led by a boy on horseback over the entire work, to compact
-the materials and assist in making the dam one homogeneous mass. No
-rollers were used on this dam.
-
-The central trench was cut 30 ft. below the original bed of the creek.
-In the bottom of this trench three secondary trenches, 3 ft. wide by 3
-ft. deep, were made and filled with concrete. These concrete walls were
-carried up 2 ft. above the general floor of the trench, to break the
-continuity of its surface.
-
-The original wasteway, constructed at the north end of the dam, has
-been practically abandoned, having been substituted by a tunnel of
-larger capacity. The original wasteway was excavated in the bed rock
-of the natural hillside, and although lined with masonry, is not in
-the best condition. The author considers its location an objectionable
-feature, as menacing the safety of the dam, and thinks it should be
-permanently closed.
-
-A wasteway tunnel, 1,487 ft. in length, was constructed in 1888,
-through a ridge extending north of the dam. This has a sectional area
-of about 10×10 ft., lined with brick masonry throughout, having a grade
-of 2½%.
-
-The criticism might be made of the tunnel that it is faulty in design
-at the entry or reservoir end, where the water must first fall over
-a high spillway wall, aerating the water before entering the tunnel
-proper. The water even then has not easy access to the tunnel, and no
-adequate arrangements have been made for ventilation, so as to insure
-the utilization of its maximum capacity. The maximum depth of water in
-the reservoir is about 85 ft., and the full capacity 689,000,000 cu.
-ft. of water. The catchment area is 43 square miles, and the surface
-of the reservoir when full 436 acres. The outlet pipes are placed in
-two tunnels at different elevations through the ridge north of the dam.
-There are no culverts or pipes extending through the body of the dam
-itself.
-
-
-Hydraulic-fill Dams.
-
-No discussion of earth dams would be complete without some reference
-being made to the novel type of construction developed in western
-America in recent years, by which railroad embankments and water-tight
-dams are built up by the sole agency of water. The water for this
-purpose is usually delivered under high pressure, as it is generally
-convenient to make it first perform the work of loosening the earth
-and rock in the borrow pit, as well as subsequently to transport them
-to the embankment, and there to sort and deposit them and finally part
-company with them after compacting them solidly in place, even more
-firmly than if compressed by heavy rollers. Sometimes, however, water
-is delivered to the borrow pit without pressure, in which event the
-materials must be loosened by the plow or by pick and shovel by the
-process called ground sluicing in placer mining parlance.
-
-An abundance of water delivered by gravity under high pressure is
-usually regarded as one of the essential factors in hydraulic-fill dam
-building, but it is not essential that there be a large continuous
-flow. The Lake Frances Dam, recently constructed for the Bay Counties
-Co., of California, by J. D. Schuyler, is 75 ft. high, 1,340 ft. long
-on top, and contains 280,000 cu. yds. The dam was built up by materials
-sluiced by water that was forced by a centrifugal pump through a 12-in.
-pipe and 3-in. nozzle, against a high bank, whence the materials were
-torn and conveyed by the water through flumes and pipes to the dam.
-About 6 cu. ft. per sec. of water was thus used, and at one stage of
-the work the supply stream was reduced to less than 0.1 ft. per sec.,
-the water being gathered in a pond and pumped over and over again.
-
-The chapter on hydraulic-fill dams in Mr. Schuyler’s book on
-“Reservoirs for Irrigation” will be found to contain matter on the
-subject interesting to those who desire to pursue it further, and the
-reader is again referred to that work.
-
-
-An Impervious Diaphragm in Earth Dams.
-
-As a result of the recent extended discussion concerning the design
-of the New Croton Dam and the Jerome Park Reservoir embankments,
-the Engineering News of Feb. 20, 1902, contained a very suggestive
-editorial entitled, “Concerning the Design of Earth Dams and Reservoir
-Embankments.” The opinion is given that no type of structure that man
-builds to confine water can compare in permanence with earth dams,
-after which the following pertinent questions are asked:
-
-    1. How shall an earth dam be made water-tight?
-
-    2. What is the office and purpose of the masonry core wall?
-
-    3. Would not a water-proof diaphragm of some kind be better
-       than a core wall of either masonry or puddle?
-
-The article then suggests a number of designs of diaphragm construction,
-with a special view of obtaining absolute water-tightness, by use of
-asphaltum, cement mortar, steel plates, etc. Special emphasis was put
-upon the _principle_ of constructing a water-proof diaphragm. The
-matter of relative cost is advanced as an argument in favor of the
-diaphragm principle as against the usual orthodox method. The saving in
-cost is to be accomplished by the use of inferior materials and less
-care in the handling of them, or by both. It is suggested that almost
-any kind of material available, rock, sand or gravel, will answer
-every purpose where good earth is not to be found. Further, that this
-material may be dumped from the carts, cars or cableways, or be placed
-by the hydraulic-fill method.
-
-The writer believes the diaphragm method of construction may have some
-merits, but that it is attended by the very great risk of neglecting
-principles most vitally important to the successful construction of
-high earth dams, which will now be formulated and advanced, as follows:
-
-
-
-
-CHAPTER VI.
-
-_Conclusions._
-
-
-The writer in concluding this study wishes to emphasize certain
-principles and apparently minor details of construction, which from
-observation and personal experience, seem to him of vital importance.
-
-He believes firmly in the truth contained in the following remarks by
-Mr. Desmond FitzGerald, of Boston, germane to this subject:
-
-    An engineer must be guided by local conditions and the resources at
-    his command in building reservoir embankments. His design must be
-    largely affected by the nature of the materials. There are certain
-    _general principles_, however, which must be observed and which
-    will be applied by an engineer of skill, judgment and experience to
-    whatever design he may adopt. It is in the application of these
-    principles that the services of the professional man becomes
-    valuable, and it is from a lack of them, that there have been so
-    many failures.
-
-The details and principles of construction, relating to high earth
-dams, may be summarized or stated in order of their application, as
-follows:
-
-(1) Select a firm, dry, impermeable foundation, or make it so by
-excavation and drainage. All alluvial soil containing organic matter
-and all porous materials should be excavated and removed from the
-dam site when practicable; that is, where the depth to a suitable
-impermeable foundation is not prohibitive by reason of excessive cost.
-
-Wherever springs of water appear, they must be carried outside the
-lines of the embankment by means of bed rock drains, or a system of
-pipes so laid and embedded as to be permanent and effective.
-
-The drainage system must be so designed as to prevent the infiltration
-of water upward and into the lower half of the embankment, and at the
-same time insure free and speedy outlet for any seepage water passing
-the upper half. All drains should be placed upon bed rock or in the
-natural formation selected for the foundation of the superstructure.
-They should be constructed in such a manner as to prevent the flow
-of water outside the channel provided for it, and also prevent any
-enlargement of the channel itself. To this end, cement, mortar, broken
-stone, and good gravel puddle are the materials best suited for this
-purpose.
-
-(2) Unite the body of the embankment to the natural foundation by means
-of an impervious material, durable and yet sufficiently elastic to bond
-the two together. When the depth to a suitable foundation is great,
-a central trench excavated with sloping sides, extending to bed rock
-or other impervious formation, refilled with good puddling material,
-properly compacted, will suffice.
-
-When clayey earth is scarce and expensive to obtain, a small amount of
-clay puddle confined between walls of brick, stone or concrete masonry,
-and extending well into the body of the embankment and so built as
-to avoid settlement, will prevent excessive seepage. This form of
-construction is not to be carried much above the original surface of
-the ground.
-
-(3) The continuity of surfaces should always be broken, at the same
-time avoiding the formation of cavities and lines of cleavage. No
-excavation to be refilled should have vertical sides, and long
-continuous horizontal planes should be intercepted by wedge-shaped
-offsets, enabling the dovetailing of materials together.
-
-All loose and seamy rock or other porous material should be removed,
-and where the refill is not the best for the purpose, mix the good and
-bad ingredients thoroughly, after which deposit in very thin layers.
-
-(4) Make the dimensions and profile of dam with a factor of safety
-against sliding of not less than ten. The preliminary calculations for
-designing such a profile have been given on p. 42.
-
-(5) Aim at as nearly a homogeneous mass in the body of the embankment
-as possible, thus avoiding unequal settlement and deformation. This
-manner of manipulating materials will eliminate many uncertain or
-unknown factors, but it means rigid inspection of the work and
-intelligent segregation of materials, no matter what method of
-transporting them may be adopted. The smaller the unit loads may
-be, the more easily a homogeneous distribution of materials will be
-obtained.
-
-(6) Select earthy materials in preference to organic soils, with a
-view of such combination or proportion of different materials as will
-readily consolidate. _Consolidation is the most important process
-connected with the building of an earth dam._ The judicious use of
-soil containing a small percentage of organic matter may be permitted,
-however, when there is a lack of clayey material for mixing with sandy
-and porous earth materials. Such a mixture, properly distributed and
-wetted, will consolidate well under heavy pressure and prove quite
-satisfactory.
-
-(7) Consolidation being the most important process and the only
-safeguard against permeability and instability of form, use only the
-amount of water necessary to attain this. Too much or too little are
-equally bad and to be avoided. It is believed that only by experiment
-and experience is it possible to determine just the proper quantity of
-water to use with the different classes of materials and their varying
-conditions. In rolling and consolidating the bank, all portions that
-have a tendency to quake must be removed at once and replaced with
-material that will consolidate; it _must not_ be covered up, no matter
-how small the area.
-
-(8) In an artificial embankment for impounding water it is
-impracticable to place reliance upon time for consolidation; it _must_
-be effected by mechanical means. Again we repeat, that consolidation is
-the most vitally important operation connected with the building of an
-earth dam. When this is satisfactorily attained it is proof that the
-materials are suitable and that the other necessary details have been
-in a large measure complied with. Light rollers are worse than useless,
-being a positive harm, resulting in a smoothing or “ironing process,”
-deceptive in appearance and detrimental in many ways.
-
-The matter of supreme importance in the construction of earth dams is
-that the greatest consolidation possible be specified and effected.
-To this end it is necessary that heavy rollers be employed, and that
-such materials be selected as respond best to the treatment. There
-are certain kinds of earth materials which no amount of wetting and
-rolling will compact. These must be rejected as unfit for use in any
-portion of an earth dam. Let the design of the structure be ever so
-true to correct engineering principles, it is still necessary to give
-untiring attention to the work of consolidation. It is therefore
-according to the design of a thoroughly compacted homogeneous mass,
-rather than to the suggested _diaphragm type_, to which modern practice
-should conform. This is in harmony with Nature’s own methods, and in
-conformity to correct principles.
-
-(9) Avoid placing pipes or culverts through any portion of the
-embankment. The writer considers it bad practice ever to place the
-outlet pipes through a high earth dam, and fails to see any necessity
-for so doing.
-
-(10) The surface of the dam, both front and rear, must be suitably
-protected against the deteriorating effects of the elements. This may
-include pitching the up-stream face, the riprap work at the toe of the
-inner slope, the roadway and covering of the crown, the sodding or
-other protection of the rear slope, and the construction of surface
-drains for the berms.
-
-(11) Ample provision for automatic wasteways should be made for
-every dam, so that the embankment can never under any circumstances
-be over-topped by the impounded water. Earthquakes and seismic
-disturbances will produce no disastrous effects upon an earth dam.
-Its elasticity will resist the shock of water lashing backwards and
-forwards in the reservoir.
-
-(12) Finally, provide for intelligent and honest supervision during
-construction, and insist upon proper care and maintenance ever
-afterwards.
-
-
-
-
-APPENDIX I.
-
-High Earth Dams.
-
-
-                             –Embankment–   –––  Slopes  –––   Available
-    Name of Dam                Max.   Top                        depths,
-    or Reservoir.  Location. height, width,   Water.   Bear.      ft.
-                               ft.    ft.
-
-    San Leandro   California  125     28
-    Tabeaud       California  123     20     3  on 1   2½ on 1    70
-    Druid Hill    Maryland    119     60     4  on 1   2  on 1    82
-    Dodder        Ireland     115     22     3½ on 1   3  on 1
-    Titicus Dam   New York    110     30     2  on 1   2½ on 1
-    Mudduk Tank   India       108            3  on 1   2½ on 1
-    Cummum Tank   India       102            3  on 1   1  on 1    90
-    Dale Dike     England     102     12     2½ on 1   2½ on 1
-    Marengo       Algeria     101
-    Torside       England     100                                 84
-    Yarrow        England     100     24     3  on 1   2  on 1
-    Honey Lake    California   96     20     3  on 1   2  on 1
-    Pilarcitos    California   95     25     2¾ on 1   2½ on 1
-    San Andres    California   95     25     3½ on 1   3  on 1
-    Temescal      California   95     12     3  on 1   2  on 1
-    Waghad        India        95      6     3  on 1   2  on 1    81
-    Bradfield     England      95     12     2½ on 1   2½ on 1
-    Oued Menrad   Algeria      95
-    St. Andrews   Ireland      93     25
-    Edgelaw       Scotland     93            3  on 1   2½ on 1
-    Woodhead      England      90                                 72
-    Tordoff       Scotland     85     10     3  on 1   2½ on 1
-    Naggar        India        84
-    Vahar         India        84     24     3  on 1   2½ on 1
-    Rosebery      Scotland     84
-    Atlanta       Georgia      82     40
-    Roddlesworth  England      80     16     3  on 1   2½ on 1    68
-    Gladhouse     Scotland     79     12     3  on 1   2½ on 1    68½
-    Rake          England      78            3  on 1   2  on 1
-    Silsden       England      78            3  on 1   2  on 1
-    Glencourse    Scotland     77            3  on 1              58
-    Leeshaw       England      77
-    Wayoh         England      76     22     3  on 1   2½ on 1
-    Ekruk Tank    India        76     20     3  on 1   2  on 1    65
-    Nehr          India        74      8
-    Middle Branch New York     73
-    Leeming       Ireland      73     10     3  on 1   2  on 1    50
-    South Fork    Penna.       72     20     2  on 1   1½ on 1    50
-    Anasagur      India        70     20     4  on 1
-    Pangran       India        68      8                          42
-    Harlaw        Scotland     67                                 64
-    Lough Vartry  Ireland      66     28     3  on 1   2½ on 1    60
-    La Mesa       California   66     20     1½ on 1   1½ on 1    60
-    Amsterdam     New York     65
-    Mukti         India        65     10     3  on 1   2  on 1    41
-    Snake River   California   64     12     2  on 1   1½ on 1
-    Stubken       Ireland      63     24     3  on 1   2  on 1
-    Den of Ogil   Scotland     60                                 50
-    Loganlea      Scotland     59     10     3  on 1   2½ on 1    55
-    Ashti         India        58      6     3  on 1   2  on 1    42
-    Cedar Grove   New Jersey   55     18     3  on 1   2  on 1    50
-
-
-
-
-APPENDIX--II.
-
-Works of Reference.
-
-
-      Author.                          Title.                      Date.
-    Baker, Benj.         The Actual Lateral Pressure of Earthwork   1881
-    Baker, Ira O.        Treatise on Masonry Construction           1899
-    Bell, Thos. J.       History of the Water Supply of the World   1882
-    Beloe, Chas. H.      Beloe on Reservoirs                        1872
-    Bowie, Aug. J., Jr.  A Practical Treatise on Hydraulic Mining   1898
-    Brant, Wm. J.        Scientific Examination of Soils            1892
-    Brightmore, A. M.    The Principles of Water-Works Engineering  1893
-    Buckley, Robt. B.    Irrigation Works in India and Egypt        1893
-    Cain, Wm.            Retaining Walls                            1888
-    Chittenden, H. M.    Report and Examination of Reservoir Sites
-                             in Wyoming and Colorado                1898
-    Courtney, C. F.      Masonry Dams                               1897
-    Fanning, J. T.       Water-Supply Engineering                   1889
-    Flynn, P. J.         Irrigation Canals and Other Irrigation
-                             Works                                  1892
-    Frizell, Jos. P.     Water Power                                1891
-    Gordon, H. A.        Mining and Mining Engineering              1894
-    Gould, E. S.         The Elements of Water-Supply Engineering   1899
-    Hall, Wm. Ham.       Irrigation in California                   1888
-    Hazen, Allen         The Filtration of Public Water Supplies    1895
-    Howe, M. A.          Retaining Walls for Earth                  1891
-    Hughes, Saml.        Treatise on Water-Works                    1856
-    Jackson, L. D. A.    Statistics of Hydraulic Works              1885
-    Kirkwood, J. P.      Filtration of River Waters                 1869
-    Merriman, M.         Treatise on Hydraulics, Masonry Dams
-                             and Retaining Walls                    1892
-    Newell, F. H.        Irrigation in the United States            1902
-    Newman, John         Earthwork Slips and Subsidences Upon
-                             Public Works                           1890
-    Potter, Thomas       Concrete                                   1894
-    Schuyler, J. D.      Reservoirs for Irrigation, Water Power
-                             and Domestic Water Supply              1901
-    Slagg, Chas.         Water Engineering                          1888
-    Stearns, F. P.       Metropolitan Water-Works Reports           1897
-    Stockbridge, H. E.   Rocks and Soils                            1888
-    Trautwine, J. C.     Earthwork; and Engineer’s Pocket-Book      1890
-    Turner, J. H. T.     The Principles of Water-Works Engineering  1893
-    Wilson, J. M.        Manual of Irrigation Engineering           1893
-
-
-
-
-Annual Reports.
-
-    Massachusetts State Board of Health.
-    Geological Survey of New Jersey.
-    Metropolitan Water-Works, Boston and vicinity.
-    U. S. Geological Survey.
-    Transactions American Society of Civil Engineers.
-         Vols. 3, 15, 24, 32, 34 and 35.
-    Proceedings of the Institution of Civil Engineers.
-         Vols. 59, 62, 65, 66, 71, 73, 74, 76, 80, 115 and 132.
-    Engineering News. Vols. 19 to 46.
-    Engineering Record.
-         Vols. 23 to 46.
-    Journal of the Association Engineering Societies.
-         Vol. 13.
-
-
-
-
-INDEX.
-
-
-    Analyses, soil, Tabeaud Dam, 25
-    Analyses of soils, 14
-      Tabeaud Dam, 25
-    Borings, wash drill, Wachusett Dam, 48
-
-    Catchment area, 3
-    Clay for puddle, 15
-    Contractors’ outfit, Tabeaud Dam, 31
-    Core wall, impervious diaphragm as substitute for, 62
-      necessity for, 44
-      (See puddle.)
-
-    Dam,
-      Ashti, India, 35
-      Bog Brook, 41
-      Bohio, Panama Canal, 54
-      Croton Valley, slope of saturation in, 40
-      different types of earth, 33
-      Druid Lake, Baltimore, 52
-      high earth, statistical table of, 67
-      hydraulic-fill, 61
-      hydraulic-fill, San Leandro, 60
-      ideal profile of, 42
-      Isthmian Canal Commission, 54
-      Lake Frances hydraulic-fill, 61
-      New Croton, 39
-        graphical study of original earth portion of, 43
-      New England, typical section of, 40
-      new types of, 54
-      North Dike, Wachusett Reservoir, 48
-      rock-fill and earth combined, upper Pecos River, 58
-      safe height of, 39
-      San Leandro, 58
-      site location, 7
-      Tabeaud, 13, 17
-      Titicus, 41
-      Upper Pecos River rock-fill and earth, 58
-      with puddle core wall or face, 33
-      Yarrow, Liverpool water-works, 9, 33
-    Diaphragms impervious for earth dams, 62, 65
-    Dike, north of Wachusett Reservoir (see Dam; also reservoir)
-    Drainage and slips of earthwork, 45
-      of dam sites, 63
-    Drains, bed rock, Tabeaud Dam, 19
-
-    Earthwork slips and drainage, 45
-    Embankment, Ashti, India, 35
-    Embankments, Jerome Park Reservoir, 45, 46
-
-    Factor of safety for dams, 64
-    Filtration, experiments on nitration through soils
-      at Wachusett Reservoir, 50
-      formula, Hazen’s, 56
-    Foundations, 9, 63
-
-    Gravel for puddle, 15
-
-    Infiltration and percolation, 38
-    Isthmian Canal Commission, designs of dams for, 54
-
-    Outlet pipes and tunnels, 6
-
-    Percolation, 38, 57
-    Profile, ideal for dams, 42
-    Puddle, 14
-      core wall, Ashti Dam, 35
-        or face, 33
-      trench, 37
-      wall, Druid Lake Dam, 53
-        for Yarrow Dam, 34
-        vs. puddle face, 37
-
-    Reservoir basin, 37
-      outlets, 6
-      Wachusett, 48
-    Rollers for dams, 30, 65
-
-    Sands and gravels, flow of water through, 52
-      (Also see percolation.)
-    Slips and drainage of earthwork, 45
-    Soil analyses, Tabeaud Dam, 25
-      analysis, 14
-    Soils, experiments on filtration through at Wachusett Reservoir, 50
-      outline study of, 12
-      permanence of, 51
-      selection of, for dams, 64
-      studies, Wachusett Reservoir, 50
-    Spillway or wasteway, 8
-      Tabeaud Dam, 31
-    Subsidences, earthwork, 45
-
-    Test pits, 5, 8, 9
-    Tunnel, outlet, Tabeaud Dam, 30
-    Tunnels as outlets to reservoirs, 6
-
-    Wasteway or spillway, 8, 66
-      Tabeaud Dam, 31
-
-
-FOOTNOTES:
-
-[1] The writer had intended to present a table of physical properties
-of different materials, giving their specific gravity, weight,
-coefficient of friction, angle of repose, percentage of imbibition,
-percentage of voids, etc., but found it impossible to harmonize the
-various classifications of materials given by different authorities.
-
-[2] The effective head at any point of an earth dam has been defined
-as the difference in the elevation of the high-water surface in the
-reservoir and that of the intersection of the down-stream slope with
-the natural or restored surface of the ground below the dam.
-
-[3] This work is very fully described in the Annual Reports of
-the Metropolitan Water Board of Boston; and by Mr. F. P. Stearns,
-Chief Engineer of the Metropolitan Water and Sewerage Board, in the
-Proceedings of the American Society of Civil Engineers for April, 1902.
-The latter description was reprinted, with the omission of some of the
-illustrations, in Engineering News for May 8, 1902.
-
-[4] By effective size of sand grains is meant such size of grain that
-10% by weight of the particles are smaller, and 90% larger than itself;
-or, to express it a little differently, the effective size is equal
-to a sphere the volume of which is greater than ¹/₁₀ that forming the
-weight and is less than ⁹/₁₀ that forming the weight.
-
-[5] The term “uniformity coefficient” is used to designate the ratio
-of the size of the grain which has 60% of the sample finer than itself
-to the size which has 10% finer than itself. The method of determining
-the size of sand grains and their uniformity coefficients, is fully
-explained in Appendix 3 of Mr. Hazen’s book on “The Filtration of
-Public Water Supplies.”
-
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-<p style='text-align:center; font-size:1.2em; font-weight:bold'>The Project Gutenberg eBook of Earth Dams, A Study, by Burr Bassell</p>
-<div style='display:block; margin:1em 0'>
-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
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-</div>
-
-<p style='display:block; margin-top:1em; margin-bottom:1em; margin-left:2em; text-indent:-2em'>Title: Earth Dams, A Study</p>
-<p style='display:block; margin-top:1em; margin-bottom:0; margin-left:2em; text-indent:-2em'>Author: Burr Bassell</p>
-<p style='display:block; text-indent:0; margin:1em 0'>Release Date: August 9, 2022 [eBook #68721]</p>
-<p style='display:block; text-indent:0; margin:1em 0'>Language: English</p>
-  <p style='display:block; margin-top:1em; margin-bottom:0; margin-left:2em; text-indent:-2em; text-align:left'>Produced by: Charlene Taylor and the Online Distributed Proofreading Team at https://www.pgdp.net (This file was produced from images generously made available by The Internet Archive/American Libraries.)</p>
-<div style='margin-top:2em; margin-bottom:4em'>*** START OF THE PROJECT GUTENBERG EBOOK EARTH DAMS, A STUDY ***</div>
-
-<hr class="chap x-ebookmaker-drop" />
-<h1>EARTH DAMS<br /><span class="h_subtitle"><i>A STUDY</i></span></h1>
-
-<p class="center">BY<br />
-<span class="fontsize_150">BURR BASSELL</span>, M. Am. Soc. C. E.<br />
-<span class="fontsize_120"><i>Consulting Engineer</i></span></p>
-
-<p class="center space-above2"><span class="smcap">New York</span><br />
-THE ENGINEERING NEWS PUBLISHING COMPANY<br />
-1904</p>
-
-<p class="center space-above2"><span class="smcap">Copyright, 1904<br />
-by<br />The Engineering News Publishing Co.</span></p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h2 class="nobreak">ACKNOWLEDGMENTS.</h2>
-</div>
-
-<p class="blockquot">The writer wishes to acknowledge his appreciation
-of the assistance given him by Mr. Jas. D. Schuyler, M. Am. Soc. C.
-E., Consulting Hydraulic Engineer, in reviewing this paper, and in
-making suggestions of value. <a href="#APPENDIX_II">Appendix II</a> contains a
-list of authors whose writings have been freely consulted, and to whom the writer
-is indebted; the numerous citations in the body of the paper further
-indicate the obligations of the writer.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h2 class="nobreak">CONTENTS.</h2>
-</div>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="TOC" cellpadding="0" >
-  <tbody><tr>
-      <td class="tdr" colspan="2"><small>PAGE</small></td>
-   </tr><tr>
-      <td class="tdc" colspan="2"><b>CHAPTER I.</b></td>
-   </tr><tr>
-      <td class="tdl">Introductory</td>
-      <td class="tdr"><a href="#Page_1">&nbsp;1</a></td>
-   </tr><tr>
-      <td class="tdc" colspan="2"><br /><b>CHAPTER II.</b></td>
-   </tr><tr>
-      <td class="tdl">Preliminary Studies and Investigations</td>
-      <td class="tdr"><a href="#Page_3">&nbsp;3</a></td>
-   </tr><tr>
-      <td class="tdc" colspan="2"><br /><b>CHAPTER III.</b></td>
-   </tr><tr>
-      <td class="tdl">Outline Study of Soils. Puddle</td>
-      <td class="tdr"><a href="#Page_12">12</a></td>
-   </tr><tr>
-      <td class="tdc" colspan="2"><br /><b>CHAPTER IV.</b></td>
-   </tr><tr>
-      <td class="tdl">The Tabeaud Dam, California</td>
-      <td class="tdr"><a href="#Page_17">17</a></td>
-   </tr><tr>
-      <td class="tdc" colspan="2"><br /><b>CHAPTER V.</b></td>
-   </tr><tr>
-      <td class="tdl">Different Types of Earth Dams</td>
-      <td class="tdr"><a href="#Page_33">33</a></td>
-   </tr><tr>
-      <td class="tdc" colspan="2"><br /><b>CHAPTER VI.</b></td>
-   </tr><tr>
-      <td class="tdl">Conclusions</td>
-      <td class="tdr"><a href="#Page_63">63</a></td>
-   </tr><tr>
-      <td class="tdc" colspan="2">&nbsp;</td>
-   </tr><tr>
-      <td class="tdc" colspan="2"><br /><b>APPENDIX I.</b></td>
-   </tr><tr>
-      <td class="tdl">Statistical Descriptions of High Earth Dams&emsp;&nbsp;</td>
-      <td class="tdr"><a href="#APPENDIX_I">67</a></td>
-   </tr><tr>
-      <td class="tdc" colspan="2"><br /><b>APPENDIX II.</b></td>
-   </tr><tr>
-      <td class="tdl">Works of Reference</td>
-      <td class="tdr"><a href="#APPENDIX_II">68</a></td>
-   </tr>
- </tbody>
-</table>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h2 class="nobreak">ILLUSTRATIONS.</h2>
-</div>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="LOI" cellpadding="0" >
-  <tbody><tr>
-      <td class="tdr" colspan="3"><small>PAGE</small></td>
-   </tr><tr>
-      <td class="tdr">Fig. 1.</td>
-      <td class="tdl_ws1">Longitudinal Section of Yarrow Dam Site</td>
-      <td class="tdr"><a href="#FIG_1">10</a></td>
-   </tr><tr>
-      <td class="tdr">2.</td>
-      <td class="tdl_ws1">Cross-Section of the Yarrow Dam</td>
-      <td class="tdr"><a href="#FIG_2">10</a></td>
-   </tr><tr>
-      <td class="tdr">3.</td>
-      <td class="tdl_ws1">Plan of the Tabeaud Reservoir</td>
-      <td class="tdr"><a href="#FIG_3">17</a></td>
-   </tr><tr>
-      <td class="tdr">4.</td>
-      <td class="tdl_ws1">Tabeaud Dam: Plan Showing Bed Rock Drains</td>
-      <td class="tdr"><a href="#FIG_4">18</a></td>
-   </tr><tr>
-      <td class="tdr">5.</td>
-      <td class="tdl_ws2">Details of Drains</td>
-      <td class="tdr"><a href="#FIG_5">18</a></td>
-   </tr><tr>
-      <td class="tdr">6.</td>
-      <td class="tdl_ws2">View of Drains</td>
-      <td class="tdr"><a href="#FIG_6">19</a></td>
-   </tr><tr>
-      <td class="tdr">7.</td>
-      <td class="tdl_ws3">North Trench</td>
-      <td class="tdr"><a href="#FIG_7">20</a></td>
-   </tr><tr>
-      <td class="tdr">8.</td>
-      <td class="tdl_ws3">South Trench</td>
-      <td class="tdr"><a href="#FIG_8">21</a></td>
-   </tr><tr>
-      <td class="tdr">9.</td>
-      <td class="tdl_ws3">Main Central Drain</td>
-      <td class="tdr"><a href="#FIG_9">21</a></td>
-   </tr><tr>
-      <td class="tdr">10.</td>
-      <td class="tdl_ws3">Embankment Work</td>
-      <td class="tdr"><a href="#FIG_10">23</a></td>
-   </tr><tr>
-      <td class="tdr">11.</td>
-      <td class="tdl_ws2">Dimension Section</td>
-      <td class="tdr"><a href="#FIG_11">26</a></td>
-   </tr><tr>
-      <td class="tdr">12.</td>
-      <td class="tdl_ws2">Cross and Longitudinal Sections</td>
-      <td class="tdr"><a href="#FIG_12">27</a></td>
-   </tr><tr>
-      <td class="tdr">13.</td>
-      <td class="tdl_ws2">View of Dam Immediately After Completion</td>
-      <td class="tdr"><a href="#FIG_13">29</a></td>
-   </tr><tr>
-      <td class="tdr">14.</td>
-      <td class="tdl_ws1">Cross-Section of Pilarcitos Dam</td>
-      <td class="tdr"><a href="#FIG_14">34</a></td>
-   </tr><tr>
-      <td class="tdr">15.</td>
-      <td class="tdl_ws2">San Andres Dam</td>
-      <td class="tdr"><a href="#FIG_15">34</a></td>
-   </tr><tr>
-      <td class="tdr">16.</td>
-      <td class="tdl_ws2">Ashti Tank Embankment</td>
-      <td class="tdr"><a href="#FIG_16">35</a></td>
-   </tr><tr>
-      <td class="tdr">17.</td>
-      <td class="tdl_ws2">Typical New England Dam</td>
-      <td class="tdr"><a href="#FIG_17">40</a></td>
-   </tr><tr>
-      <td class="tdr">18.</td>
-      <td class="tdl_ws2">Two Croton Valley Dams Showing Saturation</td>
-      <td class="tdr"><a href="#FIG_18">41</a></td>
-   </tr><tr>
-      <td class="tdr">19.</td>
-      <td class="tdl_ws1">Studies of Board of Experts on the Original Earth</td>
-      <td class="tdr">&nbsp;</td>
-   </tr><tr>
-      <td class="tdr">&nbsp;</td>
-      <td class="tdl_ws3">Portion of the New Croton Dam</td>
-      <td class="tdr"><a href="#FIG_19">43</a></td>
-   </tr><tr>
-      <td class="tdr">20.</td>
-      <td class="tdl_ws1">Studies of Jerome Park Reservoir Embankment</td>
-      <td class="tdr"><a href="#FIG_20">46</a></td>
-   </tr><tr>
-      <td class="tdr">21 to 24.</td>
-      <td class="tdl_ws1">Experimental Dikes and Cylinder Employed in Studies</td>
-      <td class="tdr">&nbsp;</td>
-   </tr><tr>
-      <td class="tdr">&nbsp;</td>
-      <td class="tdl_ws3">for the North Dike of the Wachusett Reservoir</td>
-      <td class="tdr"><a href="#FIG_21">49</a></td>
-   </tr><tr>
-      <td class="tdr">25.</td>
-      <td class="tdl_ws1">Cross-Section of Dike of Wachusett Reservoir</td>
-      <td class="tdr"><a href="#FIG_25">49</a></td>
-   </tr><tr>
-      <td class="tdr">26.</td>
-      <td class="tdl_ws1">Working Cross-Section of Druid Lake Dam</td>
-      <td class="tdr"><a href="#FIG_26">53</a></td>
-   </tr><tr>
-      <td class="tdr">27 to 29.</td>
-      <td class="tdl_ws1">Designs for the Bohio Dam, Panama Canal</td>
-      <td class="tdr"><a href="#FIG_27">55</a></td>
-   </tr><tr>
-      <td class="tdr">30.</td>
-      <td class="tdl_ws1">Cross-Section of the Upper Pecos River Rock-Fill Dam&emsp;&nbsp;</td>
-      <td class="tdr"><a href="#FIG_30">59</a></td>
-   </tr><tr>
-      <td class="tdr">31.</td>
-      <td class="tdl_ws1">Developed Section of the San Leandro Dam</td>
-      <td class="tdr"><a href="#FIG_31">59</a></td>
-   </tr>
- </tbody>
-</table>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_1">[Pg 1]</span></p>
-<p class="f200"><b>EARTH DAMS</b></p>
-</div>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h2 class="nobreak">CHAPTER I.<br />
-<span class="h_subtitle"><i>Introductory.</i></span></h2>
-</div>
-
-<p>The earth dam is probably the oldest type of dam in existence,
-antedating the Christian Era many hundreds of years. The literature
-upon this subject is voluminous, but much of it is inaccessible and
-far from satisfactory. No attempt will here be made to collate this
-literature or to give a history of the construction of earth dams,
-however interesting such an account might be. The object will rather
-be to present such a study as will make clear the application of the
-principles underlying the proper design and erection of this class
-of structures. In no way, therefore, will it assume the character or
-dignity of a technical treatise.</p>
-
-<p>Dams forming storage reservoirs, which are intended to impound large
-volumes of water, must necessarily be built of considerable height,
-except in a very few instances where favorable sites may exist. Recent
-discussions would indicate that a new interest has been awakened in
-the construction of high earth dams. As related to the general subject
-of storage, it is with the high structure rather than the low that
-this study has to do. To the extent that “the greater includes the
-less,” the principles here presented are applicable to works of minor
-importance.</p>
-
-<p>Many persons who should know better place little importance upon
-the skill required for the construction of earthwork embankments,
-considering the work to involve no scientific problems. It is far
-too common belief that any ordinary laborer, who may be able to use
-skillfully a scraper on a country road, is fitted to superintend
-the construction of an earth dam. It has been said that the art of
-constructing earth dams is purely empirical, that exact science
-furnishes no approved method of determining their internal stresses,
-and that in regard to their design experience is much more valuable
-than theory. When the question of stability is fully taken into
-consideration, it certainly requires a large amount of skill
-successfully to carry out works of this character.</p>
-
-<p>Extreme care in the selection of the site, sound judgment in the
-choice of materials and assiduity in superintending the work while in
-progress, are all vitally essential.
-<span class="pagenum" id="Page_2">[Pg 2]</span></p>
-
-<h3>Classification of Dams.</h3>
-
-<p>Dams may be classified according to their purpose as diverting dams or
-weirs and as storage dams. The former may be located upon any portion
-of a stream where the conditions are favorable, and the water used for
-manifold purposes, being conveyed by means of canals, flumes, tunnels
-and pipe-lines to places of intended use. These dams are generally low
-and may be either of a temporary or permanent character, depending upon
-the uses to which the water is put. Temporary dams are made of brush,
-logs, sand bags, gravel and loose rock. The more permanent structures
-are built of stone and concrete masonry.</p>
-
-<p>Storage dams may be classified according to the kind of material
-entering into their structure, as follows: (1) Earth; (2) Earth and
-Timber; (3) Earth and Rock-fill; (4) Rock-fill; (5) Masonry; (6)
-Composite Structures.</p>
-
-<p>Low dams forming service reservoirs for domestic water supplies and
-for irrigation comprise by far the most numerous class. They are not
-designed to impound a large volume of water and therefore may be built
-across a small ravine or depression, or even upon the summit of a hill,
-by excavating the reservoir basin and using the material excavated to
-form the embankment. These reservoirs may be used in connection with
-surface or gravity systems, artesian wells, or underground supplies
-obtained by pumping. The dams forming these reservoirs being of
-moderate size and height may vary greatly in shape and dimensions.
-The form may be made to suit the configuration of the dam site. When
-the earthwork requires it, they may be lined with various materials
-to secure water-tightness. Often such dams are made composite in
-character, partly of earth and partly of masonry or some other
-material. They are also frequently accompanied by numerous accessories,
-such as settling-basins, aerating devices and covers, which present a
-diversity in form and appearance. A presentation of the different types
-of dams thus employed, with a discussion of the questions pertaining
-to utility in design and economy in construction, would be exceedingly
-valuable and of general interest. Service reservoirs will receive only
-a passing notice, with the hope expressed that some competent authority
-will discuss them in the future.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_3">[Pg 3]</span></p>
-<h2 class="nobreak">CHAPTER II.<br />
-<span class="h_subtitle"><i>Preliminary Studies and<br /> Investigations.</i></span></h2>
-</div>
-
-<p>The preliminary studies and investigations which should be made prior
-to the construction of any dam for the storage of water have to do with
-(1) the Catchment Area, (2) the Reservoir basin, and (3) the Dam site.</p>
-
-<h3>Catchment Area.</h3>
-
-<p>It is thought desirable to define a number of terms as we proceed,
-for the purpose of correcting erroneous usage and for a clearer
-understanding of the subject. The catchment area of a reservoir is that
-portion of the country naturally draining into it. The watershed is
-the boundary of the catchment area and may be correctly defined as the
-divide between adjacent drainage systems. In regard to the catchment
-area it is necessary to determine:</p>
-
-<div class="blockquot">
-<p class="neg-indent">1. Its extent and area in square miles.</p>
-
-<p class="neg-indent">2. Its topography or the character of its surface.</p>
-
-<p class="neg-indent">3. Its hydrography or precipitation and run-off.</p>
-
-<p class="neg-indent">4. Its geology, or the character of its soils and subsoils,
-and the nature and dip of its rock strata.</p>
-
-<p class="neg-indent">5. Its flora, or the extent to which it is clothed with forest
-trees or other vegetation.</p>
-</div>
-
-<p>All of these elements affect the volumes of maximum run-off, which is
-the one important factor in the construction of earth dams that must
-not be underestimated.</p>
-
-<p>If the proposed dam or reservoir is to be located upon a main drainage
-line; that is, upon a river or stream, it is necessary to know both the
-flood and low-water discharge of the stream. Frequently no reliable
-data on this subject are available, and the engineer must then make
-such a study of the whole situation as will enable him to estimate the
-minimum and maximum flow with considerable accuracy.</p>
-
-<p>There are numerous factors entering into the solution of this first
-problem, such as the shape and length of the catchment area, its
-general elevation, the character of its surface, whether mountainous,
-hilly or flat, barren or timbered.
-<span class="pagenum" id="Page_4">[Pg 4]</span></p>
-
-<p>Good topographic maps, if available, furnish valuable data on these
-subjects and it is to be regretted that only a comparatively small
-portion of the United States has been thus mapped in detail.</p>
-
-<p>The results of stream measurements, if any have been made in the
-catchment basin, are especially important: These are usually few in
-the high areas, on account of their inaccessibility. The year 1902
-marked a notable beginning of such measurements in California. In many
-parts of the arid region of the United States, the best storage-sites
-are situated in the upper or higher portions of the drainage systems.
-This is especially true of the streams on the Pacific Slope having
-their source in the High Sierras. As regulators of stream-flow and for
-power purposes such storage is peculiarly valuable, while storage for
-irrigation and domestic uses may be located nearer the valleys and the
-centers of population.</p>
-
-<p>Frequently the engineer is required to build his dam where no such
-data are available. In such instances he should endeavor to secure
-the establishment of rain gauges and make measurements of the flow of
-the main stream and its principal tributaries at various places to
-obtain the desired information. Even this may not suffice, owing to the
-limited time at his disposal, and he must resort to the use of certain
-empirical rules or formulas, and make such comparisons and deductions
-from known conditions and results as will best answer his purpose.</p>
-
-<p>The engineer should know, approximately at least, the normal yield of
-the catchment area, the duration of the minimum and maximum seasonal
-flow, and the floods he may have to provide against during the
-construction of his dam. These data are absolutely necessary to enable
-him to provide ample wasteways for his reservoirs. Many of the failures
-of earth dams have been the result of over-topping the embankment,
-which would have been averted by an ample wasteway. The most notable
-example of this kind in recent years was that of the South Fork Dam, at
-Conemaugh, Pennsylvania, in 1889, resulting in what is generally known
-as the “Johnstown Disaster.”</p>
-
-<p>There are several empirical rules and formulas for calculating the run
-off from catchment areas and for determining the size of spillways
-necessary to discharge this flow with safety to the dam. The proper
-formula to apply in any given case, with the varying coefficients
-of each, involves a thorough knowledge on the part of the designing
-engineer of the principles upon which the different factors are based.
-<span class="pagenum" id="Page_5">[Pg 5]</span></p>
-
-<p>It is unwise and often hazardous to make use of any important hydraulic
-formula without knowing the history of its derivation. Experiments
-are not always properly conducted, and often the deductions therefrom
-are unreliable. A presentation and discussion of these formulas would
-require more space than can be given in this study, and the technical
-reader must therefore consult for himself, as occasion may require, the
-various authorities cited. Formulas for the discharge or run-off from
-catchment areas, as determined by Messrs. Craig, Dickens, Ryves and
-others, are given by most writers on the subject of hydraulics.</p>
-
-<h3>Reservoir Basin.</h3>
-
-<p>The next subject of inquiry relates to the reservoir basin. It is
-necessary that its area and capacity at different depths should be
-definitely known, and this information can only be obtained by having
-the basin surveyed and contoured. A map should be made showing contours
-at intervals of 2 to 10 ft., depending upon the size of the basin and
-the use to which the reservoir is to be put. Reservoir basins have been
-classified according to their location as follows:</p>
-
-<div class="blockquot">
-<p class="neg-indent">1. Natural lakes.</p>
-
-<p class="neg-indent">2. Natural depressions on main drainage lines.</p>
-
-<p class="neg-indent">3. Natural depressions on lateral drainage lines.</p>
-
-<p class="neg-indent">4. Arbitrary and artificially constructed basins.</p>
-</div>
-
-<p>Natural lakes may need to be investigated more or less thoroughly to
-determine the character of their waters, whether saline, alkaline
-or fresh. It may also be necessary to know their normal depth and
-capacity, and to make a study of their outlet if they have one. In some
-instances the storage capacity of a lake may be enormously increased by
-means of a comparatively low and inexpensive embankment.</p>
-
-<p>The area of reservoir basin, mean depth, temperature of the water,
-exposure of wind and sunshine, losses by seepage and evaporation, all
-have a bearing upon the available water supply and influence the design
-of the dam and accessories to the reservoir.</p>
-
-<p>In determining the character and suitability of materials for
-constructing a dam it is necessary to make a careful study of the
-soil and geological formation. This is best accomplished by digging
-numerous test pits over the basin, especially in the vicinity of the
-proposed dam site; borings alone should never be relied upon for this
-information. For such an investigation the advisability of borrowing
-<span class="pagenum" id="Page_6">[Pg 6]</span>
-material for dam construction from the reservoir basin is determined.
-The porous character of the subsoil strata, or the dip and nature of
-the bed rock, may forbid the removal of material from the floor of the
-basin, even at a remote distance from the dam site.</p>
-
-<p>The area to be flooded should be cleared and grubbed more or less
-thoroughly, depending again upon the use for which the water is
-impounded. In no instance should timber be left standing below the
-high-water level of the reservoir; and all rubbish liable to float and
-obstruct the outlet tunnel and spillway during a time of flood should
-be removed.</p>
-
-<p>The accessories to a reservoir, to which reference has been made, may
-be enumerated as follows:</p>
-
-<div class="blockquot">
-<p class="neg-indent">1. Outlet pipes or tunnel.</p>
-
-<p class="neg-indent">2. Gate tower, screens and controlling devices.</p>
-
-<p class="neg-indent">3. Sluiceways for silt or sand.</p>
-
-<p class="neg-indent">4. Wasteway channel or weir.</p>
-
-<p class="neg-indent">5. Cover, settling basin, aerating devices, etc.</p>
-</div>
-
-<p>Some of these are necessary and common to all classes of reservoirs,
-while others are employed only in special cases, as for domestic water
-supplies. All reservoirs formed by earth embankments must have at least
-two of these, namely a wasteway, which is its safety valve, and outlet
-pipes or outlet tunnel.</p>
-
-<p>It may be stated that the proper location and construction of the
-outlet for a reservoir are of vital importance, since either to
-improper location or faulty construction may be traced most of the
-failures of the past. It is almost impossible to prevent water under
-high pressure from following along pipes and culverts when placed in an
-earth dam. The pipes and culverts frequently leak, and failure ensues.
-Failure may result from one or more of the following causes:</p>
-
-<div class="blockquot">
-<p class="neg-indent">1. By improper design and placement of the puddle around the pipes.</p>
-
-<p class="neg-indent">2. By resting the pipes upon piers of masonry without continuous
-longitudinal support.</p>
-
-<p class="neg-indent">3. By reason of subsidence in the cuts of the embankments and
-at the core walls, due to the great weight at these points.</p>
-
-<p class="neg-indent">4. Leakage due to inherent defects, frost, deterioration, etc.</p>
-</div>
-
-<p>Mr. Beardsmore, the eminent English engineer who built the Dale Dyke
-embankment at Sheffield which failed in 1864, and who was afterwards
-requested to study and report upon the great reservoirs in Yorkshire
-<span class="pagenum" id="Page_7">[Pg 7]</span>
-and Lancashire, said, after examination and careful study of reservoir
-embankment construction, that “in his opinion there were no conditions
-requiring that a culvert or pipes should be carried through any portion
-of the made bank.” The writer would go even further and say that the
-only admissible outlet for a storage reservoir formed by a high earth
-dam is some form of tunnel through the natural formation at a safe
-distance from the embankment.</p>
-
-<h3>Dam Site.</h3>
-
-<p>The third preliminary study (that relating to the dam site itself) will
-be considered under three heads:</p>
-
-<div class="blockquot">
-<p class="neg-indent">1. Location.</p>
-
-<p class="neg-indent">2. Physical features, materials, etc.</p>
-
-<p class="neg-indent space-below1">3. Foundation.</p>
-</div>
-
-<p>LOCATION.–The location for a dam is generally determined by the use
-which is to be made of it, or by the natural advantages for storage
-which it may possess. If it be for water power it is very frequently
-located upon the main stream at the point of greatest declivity. If for
-storage it may be, as we have seen, at the head of a river system, on
-one of its tributaries, or in a valley lower down.</p>
-
-<p>The type of dam which should be built at any particular locality
-involves a thorough knowledge, not alone of the catchment area and
-reservoir basin, but also accurate information regarding the geology of
-the dam site itself. It would be very unwise to decide definitely upon
-any particular type of dam without first obtaining such information.
-Too frequently has this been done, causing great trouble and expense,
-if not resulting in a total failure of the dam.</p>
-
-<p>The conditions favorable for an earth dam are usually unfavorable for a
-masonry structure, and vice versa. Again, there may be local conditions
-requiring some entirely different type.</p>
-
-<p>Dams situated upon the main drainage lines of large catchment areas are
-usually built of stone or concrete masonry, and designed with large
-sluiceways and spillways for the discharge both of silt and flood
-waters. It need scarcely be remarked that, as a rule, such sites are
-wholly unsuited to earthwork construction. It is said, however, that
-“every rule has at least one exception,” and this may be true of those
-relating to dam sites, as will appear later under the head of new types.
-<span class="pagenum" id="Page_8">[Pg 8]</span></p>
-
-<p>In a general way, the location of high earth dams is governed by the
-configuration of the ground forming the storage basin. It may not be
-possible, however, to decide upon the best available site without
-careful preliminary surveys and examinations of the geological formation.</p>
-
-<p>All earth dams must be provided with a wasteway, ample to discharge the
-maximum flood tributary to the reservoir. Whatever type of wasteway be
-adopted, no reliance should ever be put upon the outlet pipes for this
-purpose. The outlet should only figure as a factor of safety for the
-wasteway, insuring, as it were, the accuracy of the estimated flood
-discharge. The safety of the dam demands that ample provision be made
-for a volume of water in excess of normal flood discharge. This most
-necessary adjunct of earth dams may be an open channel, cut through
-the rim of the reservoir basin, discharging into a side ravine which
-enters the main drainage way some distance below the dam. It may be
-necessary and possible to pierce the rim by means of a tunnel where its
-length would not prohibit such a design. Lastly, there may be no other
-alternative than the construction of an overfall spillway, at one or
-both ends of the embankment. This last method is the least desirable of
-any and should be resorted to only when the others are impracticable;
-even then, the volume of water, local topography, geology, and
-constructive materials at hand must be favorable to such a design. If
-they are not favorable it may be asked, “what then?” Simply do not
-attempt to build an earth dam at this site.</p>
-
-<p>PHYSICAL FEATURES, MATERIALS, ETC.–An investigation of the location
-and the physical features of the dam site should include a careful and
-scientific examination of the materials in the vicinity, to determine
-their suitability for use in construction. An earth embankment cannot
-be built without earth, and an earth dam cannot be built with safety
-without the right kind of earth material.</p>
-
-<p>Test pits judiciously distributed and situated at different elevations
-will indicate whether there is a sufficient amount of suitable
-material within a reasonable distance of the dam. The type of earth
-dam best suited for any particular locality, and its estimated cost,
-are thus seen to depend upon the data and information obtained by
-these preliminary studies. Economical construction requires the use of
-improved machinery and modern methods of handling materials, but far
-more important even than these are the details of construction.
-<span class="pagenum" id="Page_9">[Pg 9]</span></p>
-
-<p>FOUNDATION.–We may now assume that our preliminary studies relating to
-the location and physical features of the dam site are satisfactory.
-We must next investigate the foundation upon which the dam is to be
-built. This investigation is sometimes wholly neglected or else done in
-such a way as to be practically useless. To merely drive down iron rods
-feeling for so-called bed rock, or to make only a few bore-holes with
-an earth auger should in no instance be considered sufficient. Borings
-may be found necessary at considerable depths below the surface and
-in certain classes of material, but dug pits or shafts should always
-be resorted to for moderate depths and whenever practicable. Only by
-such means may the true character of the strata underlying the surface,
-and the nature and condition of the bed rock, if it be reached, become
-known. If a satisfactory stratum of impermeable material be found it is
-necessary also to learn both its thickness and extent. It may prove to
-be only a “pocket” of limited volume, or if found to extend entirely
-across the depression lengthwise of the dam site it may “pinch out”
-on lines transversely above or below. Shafts and borings made in the
-reservoir basin and below the dam site will determine its extent in
-this direction, knowledge of which is very important.</p>
-
-<p><a href="#FIG_1">Fig. 1</a>, showing a longitudinal section of
-the site of the Yarrow Dam of the Liverpool Water-Works, England,
-illustrates the necessity of such investigation. A bore hole at station
-2 + 00 met a large boulder which at first was erroneously thought to be
-bed rock. The hole at station 3 + 50 met a stratum of clay which proved
-to be only a pocket.</p>
-
-<p>The relative elevation of the different strata and of the bed rock
-formation, referred to one common datum, should always be determined.
-These elevations will indicate both the dip and strike of the rock
-formation and are necessary for estimating the quantities of material
-to be excavated and removed, including estimates of cost. They furnish
-information of value in determining the rate of percolation or
-filtration through the different classes of material and the amount
-of probable seepage, as will appear later. The cost of excavating,
-draining and preparing the floor or foundation for a dam is often very
-great, amounting to 20 or 30% of the total cost.</p>
-
-<p><a href="#FIG_2">Fig. 2</a> is a transverse section of the Yarrow
-Dam. This particular dam has been selected as fairly representative of
-English practice and of typical design. It is one of the most widely
-known earth dams in existence.
-<span class="pagenum" id="Page_10">[Pg 10]</span></p>
-
-<div class="figcenter">
-  <img id="FIG_1" src="images/image010a.jpg" alt="" width="600" height="262" />
-  <p class="center">FIG. 1.–LONGITUDINAL SECTION OF YARROW DAM SITE.</p>
-  <img id="FIG_2" src="images/image010b.jpg" alt="" width="600" height="226" />
-  <p class="center">FIG. 2.–CROSS-SECTION OF YARROW DAM.</p>
-</div>
-
-<p><span class="pagenum" id="Page_11">[Pg 11]</span>
-At the Yarrow dam site it was necessary to go 97 ft. below the original
-surface to obtain a satisfactory formation or one that was impermeable.
-A central trench was excavated to bed rock, parallel to the axis of the
-dam, and filled with clay puddle to form a water-tight connection with
-the rock, and prevent the water in the reservoir from passing through
-the porous materials under the body of the embankment. This interesting
-dam will be more fully described later, when the different types of
-earth dams are discussed.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_12">[Pg 12]</span></p>
-<h2 class="nobreak">CHAPTER III.<br />
-<span class="h_subtitle"><i>Outline Study of Soils.<br /> Puddle.</i></span></h2>
-</div>
-
-<p>The following study of soils is merely suggestive and is here given
-to emphasize the importance of the subject, at the risk of being
-considered a digression. Soil formations are made in one of three ways:</p>
-
-<div class="blockquot">
-<p class="neg-indent">1. By decomposition of exposed rocks.</p>
-
-<p class="neg-indent">2. By transportation or sedimentation of fine and
-coarse materials worn from rocks.</p>
-
-<p class="neg-indent">3. By transformation into humus of decayed
-organic matter.</p>
-</div>
-
-<p>The transforming agencies by which soils succeed rocks in geological
-progression have been classified as follows:</p>
-
-<ul class="index no-wrap">
-<li class="isub2">1. Changes of temperature.</li>
-<li class="isub2">2. Water.</li>
-<li class="isub2">3. Air.</li>
-<li class="isub2">4. Organic life.</li>
-</ul>
-
-<p><i>Heat</i> and its counter agent frost are the most powerful forces
-in nature, their sensible physical effects being the expansion and
-contraction of matter.</p>
-
-<p><i>Water</i> has two modes of action, physical and chemical. This
-agent is the great destroyer of the important forces, cohesion and
-friction. <i>Cohesion</i> is a force uniting particles of matter and
-resists their separation when the motion attempted is perpendicular
-to the plane of contact. <i>Friction</i> is a force resisting the
-separation of surfaces when motion is attempted which produces sliding.
-The hydrostatic pressure and resultant effect upon submerged surfaces
-need to be kept constantly in mind. When the surface is impermeable the
-line of pressure is normal to its plane, but when once saturated there
-are also horizontal and vertical lines of pressure. Since the strength
-of an earth dam depends upon two factors, namely, its weight and
-frictional resistance to sliding, the effect of water upon different
-materials entering into an earth structure should be most carefully
-considered. This will therefore occupy a large place in these pages. An
-earth embankment founded upon rock may become saturated by water forced
-up into it from below through cracks and fissures, reducing its lower
-<span class="pagenum" id="Page_13">[Pg 13]</span>
-stratum to a state of muddy sludge, on which the upper part, however
-sound in itself, would slide. The best preliminary step to take in such
-a case is to intersect the whole site with wide, dry, stone drains,
-their depths varying according to the nature of the ground or rock.</p>
-
-<p><i>Air</i> contains two ingredients ever active in the process of
-decomposition, carbonic acid and oxygen.</p>
-
-<p><i>Organic Life</i> accomplishes its decomposing effect both by
-physical and chemical means. The effect of organic matter upon the
-mineral ingredients of the soil may be stated as follows:</p>
-
-<div class="blockquot">
-<p class="neg-indent">1. By their hydroscopic properties they keep the
-soil moist.</p>
-
-<p class="neg-indent">2. Their decomposition yields carbonic acid
-gas.</p>
-
-<p class="neg-indent">3. The acids produced disintegrate the mineral
-constituents, reducing insoluble matter to soluble plant food.</p>
-
-<p class="neg-indent">4. Nitric acid results in <i>nitrates</i>, which
-are the most valuable form of nutritive nitrogen, while ammonia and the
-other salts that are formed are themselves direct food for plants.</p>
-</div>
-
-<p><i>Vegetable Humus</i> is not the end of decomposition of organic
-matter, but an intermediate state of transformation. Decay is a process
-almost identical with combustion, where the products are the same, and
-the end is the formation of water and carbonic acid, with a residue of
-mineral ash. The conditions essential to organic decomposition are also
-those most favorable to combustion or oxidation, being (1) access of
-air, (2) presence of moisture, and (3) application of heat.</p>
-
-<p>Now the coöperation of these chemical and physical forces, which are
-ever active, is called “weathering.” Slate rock, for instance, weathers
-to clay, being impregnated with particles of mica, quartz, chlorite and
-hornblend. Shales also weather to clay, resulting often in a type of
-earth which is little more than silicate of aluminum with iron oxide
-and sand.</p>
-
-<p>In the vicinity of the Tabeaud Dam, recently built under the personal
-supervision of the author, the construction of which will be described
-later, there is to be found a species of potash mica, which in
-decomposing yields a yellow clay (being ochre-colored from the presence
-of iron), mixed with particles of undecomposed mica. This material
-is subject to expansion, and by reason of its lack of grit and its
-unctuous character it was rejected or used very sparingly. Analysis of
-this material gave, Silica, 54.1 to 59.5%; potash, 1.5 to 2.3%; soda,
-2.7 to 3.7%.</p>
-
-<p>Soil analysis may be either mechanical or chemical. For purposes of
-<span class="pagenum" id="Page_14">[Pg 14]</span>
-earthwork, we are most interested in the former, having to deal with
-the physical properties of matter. Chemical analysis, however, will
-often afford information of great value regarding certain materials
-entering into the construction of earth dams. The most important
-physical properties are:</p>
-
-<ul class="index no-wrap">
-<li class="isub2">(1) Weight and specific gravity.</li>
-<li class="isub2">(2) Coefficient of friction and angle of repose.</li>
-<li class="isub2">(3) Structure and coloring ingredients.</li>
-<li class="isub2">(4) Behavior toward water.</li>
-</ul>
-
-<p>There are two distinct methods of mechanical analysis: (1) Granulating
-with sieves, having round holes. (2) Elutriating with water, the
-process being known as silt analysis.</p>
-
-<p>It would require a large volume to present the subject of soil analysis
-in any way commensurate with its importance. Experiments bearing upon
-the subjects of imbibition, permeability, capillarity, absorption and
-evaporation, of different earth materials, are equally interesting and
-important.<a id="FNanchor_1" href="#Footnote_1" class="fnanchor">[1]</a></p>
-
-<p>The permeability of soils will be discussed incidentally in connection
-with certain infiltration experiments to be given later.</p>
-
-<h3>Puddle.</h3>
-
-<p><i>Puddle</i> without qualification may be defined as clayey and
-gravelly earth thoroughly wetted and mixed, having a consistency of
-stiff mud or mortar. Puddle in which the predominating ingredient of
-the mixture is pure clay, is called <i>clay puddle</i>. <i>Gravel
-puddle</i> contains a much higher percentage of grit and gravel than
-the last-named and yet is supposed to have enough clayey material to
-bind the matrix together and to fill all the voids in the gravel.</p>
-
-<p>The term <i>earthen concrete</i> may also be applied to this class of
-material, especially when only a small quantity of water is used in
-the mixture. These different kinds of puddling materials may be found
-in natural deposits ready for use, only requiring the addition of the
-proper amount of water. It is usually necessary, however, to mix,
-artificially, or combine the different ingredients in order to obtain
-the right proportions. Some engineers think grinding in a pug-mill
-absolutely essential to obtain satisfactory results.
-<span class="pagenum" id="Page_15">[Pg 15]</span></p>
-
-<p>Puddle is handled very much as cement concrete, which is so well
-understood that detailed description is hardly necessary. Instead of
-tampers, sharp cutting implements are usually employed in putting
-puddle into place. Trampling with hoofed animals is frequently resorted
-to, both for the purpose of mixing and compacting.</p>
-
-<p>As has been stated, clays come from the decomposition of crystaline
-rocks. The purest clay known (kaolin) is composed of alumina, silica
-and water. The smaller the proportion of silica the more water it will
-absorb and retain. Dry clay will absorb nearly one-third of its weight
-of water, and clay in a naturally moist condition 1-6 to 1-8 its weight
-of water. The eminent English engineers, Baker and Latham, put the
-percentage of absorption by clayey soils as high as 40 to 60%. Pure
-clays shrink about 5% in drying, while a mixture by weight of 1 clay
-to 2 sand will shrink about 3%. It follows, then, that the larger the
-percentage of clay there may be in a mixture the greater will be both
-the expansion and the contraction.</p>
-
-<p>Clay materials may be very deceptive in some of their physical
-properties, being hard to pick under certain conditions, and yet when
-exposed to air and water will rapidly disintegrate. Beds of clay,
-marl and very fine sand are liable to slip when saturated, becoming
-semi-fluid in their nature, and will run like cream.</p>
-
-<p>The cohesive and frictional resistances of clays becoming thus very
-much reduced when charged with water, a too liberal use of this
-material is to be deprecated. The ultimate particles forming clays,
-viewed under the microscope, are seen to be flat and scale-like, while
-those of sands are more cubical and spherical. This is a mechanical
-difference which ought to be apparent to even a superficial observer
-and yet has escaped recognition by many who have vainly attempted a
-definition of <i>quicksand</i>.</p>
-
-<p>Mr. Strange recommends filling the puddle trench with material having
-three parts soil and two parts sand. After the first layer next to bed
-rock foundation, which he kneads and compacts, he would put the layers
-in dry, then water and work it by treading, finally covering to avoid
-its drying out and cracking.</p>
-
-<p>Prof. Philipp Forchheimer, of Gratz, Austria, one of the highest
-authorities and experimentalists, affirms that if a sandy soil contains
-clay to such an extent that the clay fills up the interstices between
-the grains of sand entirely the compound is practically impervious.
-<span class="pagenum" id="Page_16">[Pg 16]</span></p>
-
-<p>Mr. Herbert M. Wilson, C. E., in his “Manual of Irrigation
-Engineering,” recommends the following as an ideal mixture of materials:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="Materials" cellpadding="0" >
-  <tbody><tr>
-      <td class="tdl">&nbsp;</td>
-      <td class="tdr"><b>Cu. yds.</b></td>
-   </tr><tr>
-      <td class="tdl">Coarse gravel&emsp;&nbsp;</td>
-      <td class="tdr">1.00</td>
-   </tr><tr>
-      <td class="tdl">Fine gravel</td>
-      <td class="tdr">0.35</td>
-   </tr><tr>
-      <td class="tdl">Sand</td>
-      <td class="tdr">0.15</td>
-   </tr><tr>
-      <td class="tdl">Clay</td>
-      <td class="tdr">0.20</td>
-   </tr><tr>
-      <td class="tdl_ws1 bt">Total</td>
-      <td class="tdr bt">1.70</td>
-   </tr>
- </tbody>
-</table>
-
-<p class="space-above2">This mixture, when rolled and compacted, should
-give 1.25 cu. yds. in bulk, thus resulting in 26½% compression.</p>
-
-<p>Mr. Clemens Herschel suggests the following test of “good binding
-gravel:” “Mix with water in a pail to the consistency of moist earth;
-if on turning the pail upside down the gravel remains in the pail
-it is fit for use, otherwise it is to be rejected.” For <i>puddling
-material</i> he would use such a proportion as will render the water
-invisible.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_17">[Pg 17]</span></p>
-<h2 class="nobreak">CHAPTER IV.<br />
-<span class="h_subtitle"><i>The Tabeaud Dam,<br /> California.</i></span></h2>
-</div>
-
-<p>The Tabeaud Dam, in Amador County, Cal., built under the supervision
-of the author for the Standard Electric Co., is an example of the
-homogeneous earth dam. A somewhat fuller description and discussion
-will be given of this dam than of any other, not on account of its
-greater importance or interest, but because it exemplifies certain
-principles of construction upon which it is desired to put special
-emphasis. This dam was described in Engineering News of July 10, 1902,
-to which the reader is referred for more complete information than is
-given here.</p>
-
-<div class="figcenter">
-  <img id="FIG_3" src="images/image017.jpg" alt="" width="600" height="485" />
-  <p class="center">FIG. 3.–PLAN OF TABEAUD RESERVOIR, WITH CONTOURS.</p>
-</div>
-
-<p><span class="pagenum" id="Page_18">[Pg 18]</span></p>
-
-<div class="figcenter">
-  <img id="FIG_4" src="images/image018a.jpg" alt="" width="600" height="634" />
-  <p class="center">FIG. 4.–PLAN OF TABEAUD DAM, SHOWING BED ROCK DRAINAGE SYSTEM.</p>
-  <img  id="FIG_5" src="images/image018b.jpg" alt="" width="600" height="171" />
-  <p class="center space-below2">FIG. 5.–DETAILS OF BED ROCK DRAINS AT THE TABEAUD DAM.</p>
-</div>
-
-<p><span class="pagenum" id="Page_19">[Pg 19]</span>
-<a href="#FIG_3">Fig. 3</a> is a contour map of the Tabeaud Reservoir,
-showing the relative locations of the dam, wasteway and outlet tunnel.
-<a href="#FIG_4">Fig. 4</a> shows the bed rock drainage system and the
-letters upon the drawing will assist in following the explanation given
-in the text. The whole up-stream half of the dam site was stripped to
-bed rock. As the work of excavation advanced pockets of loose alluvial
-soil were encountered, which were suggestive of a refill, possibly
-the result of placer mining operations during the early mining days
-of California. In addition to this were found thin strata of sand
-and gravel deposited in an unconformable manner. The slate bed rock
-near the up-stream toe of the dam was badly fissured and yielded
-considerable water. A quartz vein from 1 to 2 ft. in thickness crossed
-the dam site about 150 ft. above the axis of the dam. The slate rock
-above this vein or fault line was quite variable in hardness and dipped
-at an angle of 40 degrees toward the reservoir.</p>
-
-<div class="figcenter">
-  <img id="FIG_6" src="images/image019.jpg" alt="" width="500" height="412" />
-  <p class="center">FIG. 6.–VIEW OF BED ROCK TRENCHES, TABEAUD DAM.</p>
-</div>
-
-<p>The rear drain terminates at a weir box (Z) outside of the down-stream
-slope at a distance of 500 ft. from the axis of the dam. This drain
-branches at the down-stream side of the central trench, (Y), one branch
-being carried up the hillside to high-water level (W) at the North end
-of the dam, and the other to the same elevation at the South end (X).
-<span class="pagenum" id="Page_20">[Pg 20]</span></p>
-
-<p><a href="#FIG_5">Fig. 5</a> shows how these drains were constructed.
-After the removal of all surface soil and loose rock, a trench 5
-to 10 ft. wide was cut into the solid rock, the depth of cutting
-varying with the character of the bed rock. Upon the floor of this
-trench a small open drain was made by notching the bed rock and by
-means of selected stones of suitable size and hardness. The stringers
-and cap-stones were carefully selected and laid, so that no undue
-settlement or displacement might occur by reason of the superincumbent
-weight of the dam. All crevices were carefully filled with spawls and
-the whole overlaid 18 ins. in depth with broken stone 1 to 3 ins. in
-diameter. Upon this layer of broken stone and fine gravel was deposited
-choice clay puddle, thoroughly wetted and compacted, refilling the
-trenches.</p>
-
-<div class="figcenter">
-  <img id="FIG_7" src="images/image020.jpg" alt="" width="500" height="444" />
-  <p class="center">FIG. 7.–VIEW OF NORTH TRENCH, TABEAUD DAM.</p>
-</div>
-
-<p><span class="pagenum" id="Page_21">[Pg 21]</span></p>
-
-<div class="figcenter">
-  <img id="FIG_8" src="images/image021a.jpg" alt="" width="600" height="446" />
-  <p class="center">FIG. 8.–VIEW OF SOUTH TRENCH, TABEAUD DAM.</p>
-  <img  id="FIG_9" src="images/image021b.jpg" alt="" width="500" height="404" />
-  <p class="center">FIG. 9.–VIEW OF MAIN CENTRAL DRAIN, TABEAUD DAM.</p>
-</div>
-
-<p><span class="pagenum" id="Page_22">[Pg 22]</span>
-These drains served a useful purpose during construction, in drying
-off the surface of the dam after rains. The saturation of the outer
-slope of the dam by water creeping along the line of contact should
-thus be prevented, and the integrity or freedom from saturation of the
-down-stream half should be preserved. It is believed that the puddle
-overlying these rock drains will effectually prevent any water from
-entering the body of the embankment by upward pressure and that the
-drains will thus forever act as efficient safeguards.</p>
-
-<p>The main drain was extended, temporarily during construction, from
-the central trench (<a href="#FIG_4">Fig. 4</a>), to the up-stream toe
-of the dam. This was cut 5 or 6 ft. deep into solid rock, below the
-general level of the stripped surface. <a href="#FIG_6">Fig. 6</a> is
-reproduced from a photograph of this trench. An iron pipe 2 ins. in
-diameter was imbedded in Portland cement mortar and concrete, and laid
-near the bottom of the trench.</p>
-
-<p>At the point (B) where the quartz vein (already described)
-intersected this drain, two branch drains were made, following the
-fault well into the hill on both sides. <a href="#FIG_7">Figs. 7</a>
-and <a href="#FIG_8">8</a> are views of the North and South trenches,
-respectively. These trenches were necessary to take care of the
-springs issuing along the quartz vein. This water led to a point
-(<a href="#FIG_4">N, Fig. 4</a>) near the up-stream toe, by means
-of the drain shown in <a href="#FIG_9">Fig. 9</a>.</p>
-
-<p>The lateral drains and that portion of the main central drain extending
-from their junction (B) to a point (N) about 230 ft. from the axis
-of the dam have pieces of angle iron or wooden Y-fluming laid on the
-bottom of the trenches immediately over the 2-in. pipe, as shown in
-<a href="#FIG_7">Figs. 7</a>, <a href="#FIG_8">8</a> and <a href="#FIG_9">9</a>.
-These are covered in turn with Portland cement mortar, concrete, clay
-puddle and earth fill. The water will naturally flow along the line of
-least resistance, and consequently will follow along the open space
-between the angle irons and the outside of the pipe until it reaches
-the chamber and opening in the pipe, permitting the water to enter and
-be conveyed through the imbedded pipe-line to the rear drain. This
-point of entry is a small chamber in a solid cross-wall of rich cement
-mortar, and is the only point where water can enter this pipe-line, the
-two branches entering the wells and the stand-pipe at their junction
-(soon to be described) having been closed.</p>
-
-<p>That portion of the foundation between the axis of the dam and the
-quartz vein, a distance of about 160 ft., was very satisfactory,
-without fissures or springs of water. In this portion the 2-in. pipe
-was imbedded in mortar and concrete without angle irons, and the
-continuity of the trench broken by numerous cross-trenches cut into
-the rock and filled with concrete and puddle. It is believed that no
-seepage water will ever pass through this portion of the dam. If any
-should ever find its way under the puddle and through the bed rock
-formation, the rear drain, with its hillside branches, will carry it away
-and prevent the saturation of the lower or down-stream half of the dam.
-<span class="pagenum" id="Page_23">[Pg 23]</span></p>
-
-<div class="figcenter">
-  <img id="FIG_10" src="images/image023.jpg" alt="" width="600" height="361" />
-  <p class="center">FIG. 10.–VIEW OF TABEAUD DAM WHEN ABOUT HALF COMPLETED.</p>
-</div>
-
-<p><span class="pagenum" id="Page_24">[Pg 24]</span>
-At the up-stream toe of the embankment, two wells or sumps (<a href="#FIG_4">shown
-at “S” and “K,” Fig. 4</a>) were cut 10 or 12 ft. deeper than the main trench,
-which received the water entering the inner toe puddle trench during
-construction. This water was disposed of partly by pumping and partly
-by means of the 2-in. branch pipes leading into and from these wells.
-At their junction (J) a 2-in. stand-pipe was erected, which was carried
-vertically up through the embankment, and finally filled with cement.
-The branch pipes from the wells were finally capped and the wells
-filled with broken stone, as previously mentioned.</p>
-
-<p>EMBANKMENT.–As has been said, the upper surface of the slate bed rock
-was found to be badly fissured, especially near the up-stream toe of
-the dam, and as the average depth below the surface of the ground was
-not very great, it was thought best to lay bare the bed rock over the
-entire upper half of the dam site. Had the depth been much greater,
-it would have been more economical and possibly sufficient to have
-put reliance in a puddle trench, alone, for securing a water-tight
-connection between the foundation and the body of the dam.</p>
-
-<p>At the axis of the dam and near the inner toe, where the puddle walls
-abutted against the hillsides, the excavation always extended to bed
-rock. Vertical steps and offsets were avoided and the cuts were made
-large enough for horses to turn in while tramping, these animals being
-used, singly and in groups, to mix and compact the puddle and thus
-lessen the labor of tamping by hand. In plan, the hillside contact
-of natural and artificial surfaces presents a series of corrugated
-lines, (<a href="#FIG_4">as is clearly shown in Fig. 4.</a>) After all loose and
-porous materials had been removed, the stripped surface and the slopes of all
-excavations were thoroughly wetted from time to time by means of hose
-and nozzle, the water being delivered under pressure. <a href="#FIG_10">Fig. 10</a>
-is a view of the dam taken when it was about half finished and shows the work
-in progress.</p>
-
-<p>The face puddle shown in <a href="#FIG_11">Fig. 11</a> was used merely to
-“make assurance doubly sure” and was not carried entirely up to the top of the dam.
-<span class="pagenum" id="Page_25">[Pg 25]</span>
-The earth of which the dam was constructed may be described as a
-red gravelly clay, and in the judgment of the author is almost ideal
-material for the purpose. Physical tests and experiments made with the
-materials at different times during construction gave the following
-average results:</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="Ground Specs." cellpadding="0" >
-  <tbody><tr>
-      <td class="tdr" colspan="3"><b>Pounds.</b></td>
-   </tr><tr>
-      <td class="tdl">Weight of 1 cu. ft.</td>
-      <td class="tdl_ws1">earth, dust dry</td>
-      <td class="tdr">84.0&nbsp;&nbsp;</td>
-   </tr><tr>
-      <td class="tdl_ws1">“<span class="ws2">“</span> 1&emsp;“</td>
-      <td class="tdl_ws1">saturated earth</td>
-      <td class="tdr">101.8&nbsp;&nbsp;</td>
-   </tr><tr>
-      <td class="tdl_ws1">“<span class="ws2">“</span> 1&emsp;“</td>
-      <td class="tdl_ws1">moist loose earth</td>
-      <td class="tdr">76.6&nbsp;&nbsp;</td>
-   </tr><tr>
-      <td class="tdl_ws1">“<span class="ws2">“</span> 1&emsp;“</td>
-      <td class="tdl_ws1">loose material taken from test pits on the dam&nbsp;&nbsp;</td>
-      <td class="tdr">80.0&nbsp;&nbsp;</td>
-   </tr><tr>
-      <td class="tdl_ws1">“<span class="ws2">“</span> 1&emsp;“</td>
-      <td class="tdl_ws1">earth in place taken from the borrow pits</td>
-      <td class="tdr">116.5&nbsp;&nbsp;</td>
-   </tr><tr>
-      <td class="tdl_ws1">“<span class="ws2">“</span> 1&emsp;“</td>
-      <td class="tdl_ws1">earth material taken from test pits on the dam</td>
-      <td class="tdr">133.0&nbsp;&nbsp;</td>
-   </tr>
- </tbody>
-</table>
-
-<table class="fontsize_110 no-wrap space-above2" border="0" cellspacing="0" summary="Ground Specs." cellpadding="0" >
-  <tbody><tr>
-      <td class="tdr" colspan="3"><b>Per cent.</b></td>
-   </tr><tr>
-      <td class="tdl">Percentage of</td>
-      <td class="tdl_ws1">moisture in natural earth</td>
-      <td class="tdr">19&nbsp;&nbsp;</td>
-   </tr><tr>
-      <td class="tdl"><span class="ws2">“</span><span class="ws2">&nbsp;“</span></td>
-      <td class="tdl_ws1">voids in natural earth</td>
-      <td class="tdr">52&nbsp;&nbsp;</td>
-   </tr><tr>
-      <td class="tdl"><span class="ws2">“</span><span class="ws2">&nbsp;“</span></td>
-      <td class="tdl_ws1">grit and gravel in natural earth</td>
-      <td class="tdr">38&nbsp;&nbsp;</td>
-   </tr><tr>
-      <td class="tdl"><span class="ws2">“</span><span class="ws2">&nbsp;“</span></td>
-      <td class="tdl_ws1">compression on dam over earth at borrow pit&emsp;&nbsp;</td>
-      <td class="tdr">16&nbsp;&nbsp;</td>
-   </tr><tr>
-      <td class="tdl"><span class="ws2">“</span><span class="ws2">&nbsp;“</span></td>
-      <td class="tdl_ws1">compression on dam over earth in wagons</td>
-      <td class="tdr">43&nbsp;&nbsp;</td>
-   </tr>
- </tbody>
-</table>
-
-<table class="fontsize_110 no-wrap space-above2" border="0" cellspacing="0" summary="Ground Specs." cellpadding="0" >
-  <tbody><tr>
-      <td class="tdr" colspan="2"><b>Degrees.</b></td>
-   </tr><tr>
-      <td class="tdl">Angle of repose of natural moist earth<span class="ws10">&nbsp;</span></td>
-      <td class="tdr">44&nbsp;&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Angle of repose of earth, dust dry</td>
-      <td class="tdr">36&nbsp;&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Angle of repose of saturated earth</td>
-      <td class="tdr">23&nbsp;&nbsp;</td>
-   </tr>
- </tbody>
-</table>
-
-<p class="space-above2">CONSTRUCTION DETAILS.–The materials forming
-the bulk of the dam were hauled by four-horse teams, in dump wagons,
-holding 3 cu. yds. each. The wagons loaded weighed about six tons and
-were provided with two swinging bottom-doors, which the driver could
-operate with a lever, enabling the load to be quickly dropped while the
-team was in motion. If the material was quite dry, the load could be
-dumped in a long row when so desired.</p>
-
-<p>After plowing the surface of the ground and wasting any objectionable
-surface soil, the material was brought to common earth-traps for
-loading into wagons, by buck or dragscrapers of the Fresno pattern. In
-good material one trap with eight Fresno-scraper teams could fill 25
-wagons per hour. The average length of haul for the entire work was
-about 1,320 ft.</p>
-
-<p>The original plans and specifications were adhered to throughout, with
-the single exception that the central puddle wall was not carried above
-elevation 1,160, as shown on <a href="#FIG_11">Figs. 11</a> and <a href="#FIG_12">12</a>,
-more attention being given to the inner face puddle. This modification
-in the original plans was made because of the character of the
-materials available and the excellent results obtained in securing an
-homogeneous earthen concrete, practically impervious.
-<span class="pagenum" id="Page_26">[Pg 26]</span></p>
-
-<div class="figcenter">
-  <img id="FIG_11" src="images/image026.jpg" alt="" width="600" height="165" />
-  <p class="center">FIG. 11.–DIMENSION SECTION OF TABEAUD DAM.</p>
-</div>
-
-<p>The top of the embankment was maintained basin-shaped during
-construction, being lower at the axis than at the outer slopes by 1-10,
-to the height below the finished crown. This gave a grade of about 1 in
-25 from the edges toward the center, resulting in the following advantages:</p>
-
-<p>(1) Insuring a more thorough wetting of the central portion of the dam;
-any excess of water in this part would be readily taken care of by the
-central cross drains.</p>
-
-<p>(2) In wetting the finished surface prior to depositing a new layer
-of material, water from the sprinkling wagons would naturally drain
-towards the center and insure keeping the surface wet; the layers being
-carried, as a rule, progressively outward from the center.</p>
-
-<p>(3) It centralized the maximum earth pressure and enabled the
-depositing of material in layers perpendicular to the slopes.</p>
-
-<p>(4) It facilitated rolling and hauling on lines parallel to the axis of
-the dam, and discouraged transverse and miscellaneous operations.</p>
-
-<p>(5) It finally insured better compacting by the tramping of teams in
-their exertions to overcome the grade.
-<span class="pagenum" id="Page_27">[Pg 27]</span></p>
-
-<div class="figcenter">
-  <img id="FIG_12" src="images/image027a.jpg" alt="" width="600" height="127" />
-  <img src="images/image027b.jpg" alt="" width="600" height="241" />
-  <p class="center">FIG. 12.–CROSS AND LONGITUDINAL SECTIONS OF TABEAUD DAM.</p>
-</div>
-
-<p><span class="pagenum" id="Page_28">[Pg 28]</span>
-The specifications stipulated that the body of the dam should be built
-up in layers not exceeding 6 ins. in thickness for the first 60 ft.,
-and not exceeding 8 ins. above that elevation. The finished layers
-after rolling varied slightly in thickness, the daily average per month
-being as follows:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
-  <tbody><tr>
-      <td class="tdl">April</td>
-      <td class="tdl_ws1">4</td>
-      <td class="tdc">ins.</td>
-   </tr><tr>
-      <td class="tdl">May</td>
-      <td class="tdl_ws1">3½</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">June</td>
-      <td class="tdl_ws1">4</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">July</td>
-      <td class="tdl_ws1">4½</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">August</td>
-      <td class="tdl_ws1">5</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">September</td>
-      <td class="tdl_ws1">6</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">October</td>
-      <td class="tdl_ws1">7</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">November and December</td>
-      <td class="tdl_ws1">8</td>
-      <td class="tdc">“</td>
-   </tr>
- </tbody>
-</table>
-
-<p>During the last few months more than one whole layer constituted the
-day’s work, so that a single layer was seldom as thick as the daily
-average indicates.</p>
-
-<p>It was stipulated in the specifications that the up-stream half of the
-dam was to be made of “selected material” and the lower half of less
-choice material, not designated “waste.” “Waste material” was described
-as meaning all vegetable humus, light soil, roots, and rock exceeding 5
-lbs. in weight, too large to pass through a 4-in. ring.</p>
-
-<p>It may be well to define the expression “selected material,”
-so commonly used in specifications for earth dams. In England,
-for instance, it is said to refer to materials which insure
-<i>water-tightness</i>, while in India it refers to those employed to
-obtain <i>stability</i>. It ought to mean the best material available,
-selected by the engineer to suit the requirements of the situation.</p>
-
-<p>The method employed in building the body of the embankment may be
-described as follows:</p>
-
-<p>(1) The top surface of every finished layer of material was sprinkled
-and harrowed prior to putting on a new layer. The sprinkling wagons
-passed over the older finished surface immediately before each
-wagon-row was begun. This insured a wetted surface and assisted the
-wheels of the loaded wagons, as well as the harrows, to roughen, the
-old surface prior to depositing a new layer.</p>
-
-<p>(2) The material was generally deposited in rows parallel to the axis
-of the dam. However, along the line of contact, at the margins of the
-embankment, the earth was often deposited in rows crosswise of the
-dam, permitting a selection of the choicest materials and greatly
-facilitating the work of graders and rollers.</p>
-
-<p>(3) Rock pickers with their carts were continually passing along the
-rows gathering up all roots, rocks and other waste materials.
-<span class="pagenum" id="Page_29">[Pg 29]</span></p>
-
-<div class="figcenter">
-  <img id="FIG_13" src="images/image029.jpg" alt="" width="600" height="352" />
-  <p class="center">FIG. 13.–VIEW OF TABEAUD DAM IMMEDIATELY AFTER COMPLETION.</p>
-</div>
-
-<p><span class="pagenum" id="Page_30">[Pg 30]</span>
-(4) The road-graders drawn by six horses leveled down the tops of
-the wagon-loads, and if the material was dry the sprinkling wagons
-immediately passed over the rows prior to further grading. When the
-material was naturally moist the grader continued the leveling process
-until the earth was evenly spread. The depth or thickness of the layer
-could be regulated to a nicety by properly spacing the rows and the
-individual loads. The grader brought the layer to a smooth surface
-and of uniform thickness, and nothing more could be desired for this
-operation.</p>
-
-<p>(5) After the graders had finished, the harrows passed over the new
-layer to insure the picking out of all roots and rocks, followed
-immediately by the sprinkling wagons.</p>
-
-<p>(6) Finally the rollers thoroughly compacted the layer of earth,
-generally passing to and fro over it lengthwise of the dam. Along the
-line of contact at the ends, however, they passed crosswise. Then again
-they frequently went around a portion of the surface until the whole
-was hard and solid.</p>
-
-<p>Two rollers were in use constantly, each drawn by six horses. One
-weighed five tons and the other eight tons, giving respectively 166 and
-200 lbs. pressure per lin. in. They were not grooved, but the smooth
-surface left by the rollers was always harrowed and cut up more or
-less by the loaded wagons passing over the surface previously wetted.
-The wagons when loaded gave 750 lbs. pressure per lin. in., and the
-heavy teams traveling wherever they could do the most effective work
-compacted the materials better even than the rollers.</p>
-
-<p>Several test pits which were dug into the dam during construction
-showed that there were no distinct lines traceable between the layers
-and no loose or dry spots, but that the whole mass was solid and
-homogeneous.</p>
-
-<p>A careful record is being kept of the amount of settlement of the
-Tabeaud Dam. It will be of interest to record here the fact that just
-one year after date of completion the settlement amounted to 0.2 ft.,
-with 90 ft. depth of water in the reservoir.</p>
-
-<p>Water was first turned into the reservoir five months after the dam was
-finished. The very small amount of settlement here shown emphasizes
-more eloquently than words the author’s concluding remarks relating to
-the importance of thorough consolidation, by artificial means, of the
-embankment. (<a href="#SECT_6">See p. 64, Secs. 6 to 8.</a>)</p>
-
-<p>OUTLET TUNNEL.–The outlet for the reservoir is a tunnel 2,903 ft. in
-length, through a ridge of solid slate rock formation, which was very
-<span class="pagenum" id="Page_31">[Pg 31]</span>
-hard and refractory. At the north or reservoir end of the tunnel, there
-is an open cut 350 ft. long, with a maximum depth of 26 ft.</p>
-
-<p>Near the south portal of the tunnel and in the line of pressure pipes
-connecting the “petty reservoir” above with the power-house below,
-is placed a receiver, connected with the tunnel by means of a short
-pipe-line, 60 ins. in diameter.</p>
-
-<p>A water-tight bulkhead of brick and concrete masonry is placed in the
-tunnel, at a point about 175 ft. distant from the receiver. In the line
-of 60-in. riveted steel pipe, which connects the reservoir and tunnel
-with the receiver, there is placed a cast iron chamber for entrapping
-silt or sand, with a branch pipe 16 ins. in diameter leading into a
-side ravine through which sand or silt thus collected can be wasted or
-washed out. By the design of construction thus described, it will be
-seen that all controlling devices, screens, gates, etc., are at the
-south end of the tunnel and easily accessible.</p>
-
-<p>WASTEWAY.–The wasteway for the reservoir is an open cut through its
-rim, 48 ft. in width and 300 ft. long. The sill of the spillway is 10
-ft. below the crown of the dam. The reservoir having less than two
-square miles of catchment area, and the feeding canals being under
-complete control, the dam can never be over-topped by a flood. <a href="#FIG_3">Fig. 3</a>
-shows the relative location of the dam, outlet tunnel and wasteway channel.</p>
-
-<p>Almost the whole of the embankment forming the Tabeaud Dam, not
-included in the foundation work, was built in less than eight months.
-The contractor’s outfit was the best for the purpose the writer has
-ever seen. After increasing his force from time to time he finally had
-the following equipment:</p>
-
-<ul class="index fontsize_120 no-wrap">
-<li class="isub2">&nbsp;&emsp;1 steam shovel (1½ yds. capacity),</li>
-<li class="isub2">&nbsp; &nbsp;37 patent dump wagons,</li>
-<li class="isub2">&nbsp; &nbsp;11 stick-wagons and rock-carts,</li>
-<li class="isub2">&nbsp; &nbsp;39 buck-scrapers (Fresno pattern),</li>
-<li class="isub2">&nbsp; &nbsp;21 wheel scrapers,</li>
-<li class="isub2">&nbsp;&emsp;3 road-graders,</li>
-<li class="isub2">&nbsp;&emsp;3 sprinkling wagons,</li>
-<li class="isub2">&nbsp;&emsp;2 harrows,</li>
-<li class="isub2">&nbsp;&emsp;2 rollers (5 and 8-ton),</li>
-<li class="isub2">233 men,</li>
-<li class="isub2">416 horses and mules,</li>
-<li class="isub2">&nbsp;&emsp;8 road and hillside plows.</li>
-</ul>
-
-<p><span class="pagenum" id="Page_32">[Pg 32]</span>
-STATISTICS.–The following data relating to the Tabeaud Dam Reservoir
-will conclude this description:</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="Dam Data." cellpadding="0" >
-  <tbody><tr>
-      <td class="tdc" colspan="3"><big><b>DAM.</b></big></td>
-   </tr><tr>
-      <td class="tdl">Length at crown</td>
-      <td class="tdr">636</td>
-      <td class="tdc">ft.</td>
-   </tr><tr>
-      <td class="tdl">Length at base crossing ravine</td>
-      <td class="tdr">50 to 100</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">Height to top of crown (El. 1,258.)</td>
-      <td class="tdr">120</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">&nbsp;&emsp;“&nbsp;&emsp;at ends above bedrock</td>
-      <td class="tdr">117</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">&nbsp;&emsp;“&nbsp;&emsp;at up-stream toe</td>
-      <td class="tdr">100</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">&nbsp;&emsp;“&nbsp;&emsp;at down-stream toe</td>
-      <td class="tdr">123</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">Effective head</td>
-      <td class="tdr">115</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">Width at crown</td>
-      <td class="tdr">20</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">Width at base</td>
-      <td class="tdr">620</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdc" colspan="3"><b>Slopes, 2½ on 1 with rock-fill 3 to 1.</b></td>
-   </tr><tr>
-      <td class="tdl">Excavation for foundations</td>
-      <td class="tdr">40,000</td>
-      <td class="tdc">cu. yds.</td>
-   </tr><tr>
-      <td class="tdl">Refill by company</td>
-      <td class="tdr">40,000</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">Embankment built by contractor</td>
-      <td class="tdr">330,350</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">Total volume of dam</td>
-      <td class="tdr">370,350</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">Total weight</td>
-      <td class="tdr">664,778</td>
-      <td class="tdc">tons.</td>
-   </tr><tr>
-      <td class="tdl">Length of wasteway (width)</td>
-      <td class="tdr">48</td>
-      <td class="tdc">ft.</td>
-   </tr><tr>
-      <td class="tdl">Depth of spillway sill below crown</td>
-      <td class="tdr">10</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">Depth of spillway sill below ends</td>
-      <td class="tdr">7</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">Height of stop-planks in wasteway</td>
-      <td class="tdr">2</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">Maximum depth of water in reservoir</td>
-      <td class="tdr">92</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">Area to be faced with stone</td>
-      <td class="tdr">1,933</td>
-      <td class="tdc">sq. yds.</td>
-   </tr><tr>
-      <td class="tdc" colspan="3">&nbsp;</td>
-   </tr><tr>
-      <td class="tdc" colspan="3"><big><b>RESERVOIR.</b></big></td>
-   </tr><tr>
-      <td class="tdl">Catchment area (approximate)</td>
-      <td class="tdr">2</td>
-      <td class="tdc">&nbsp;sq. miles.&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Area of water surface</td>
-      <td class="tdr">36.75</td>
-      <td class="tdc">acres.</td>
-   </tr><tr>
-      <td class="tdl">Silt storage capacity below outlet tunnel&emsp;&nbsp;</td>
-      <td class="tdr">1,091,470</td>
-      <td class="tdc">cu. ft.</td>
-   </tr><tr>
-      <td class="tdl">Available water storage capacity</td>
-      <td class="tdr">46,612,405</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl">Elevation of outlet tunnel</td>
-      <td class="tdr">1,180</td>
-      <td class="tdc">ft.</td>
-   </tr><tr>
-      <td class="tdl_ws1">&emsp;“<span class="ws2">“</span> high-water surface</td>
-      <td class="tdr">1,250</td>
-      <td class="tdc">“</td>
-   </tr><tr>
-      <td class="tdl_ws1">&emsp;“<span class="ws2">“</span> crown of dam</td>
-      <td class="tdr">1,258</td>
-      <td class="tdc">“</td>
-   </tr>
- </tbody>
-</table>
-
-<p><a href="#FIG_13">Fig. 13</a> is a view of the finished dam, taken
-immediately after completion.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_33">[Pg 33]</span></p>
-<h2 class="nobreak">CHAPTER V.<br />
-<span class="h_subtitle"><i>Different Types of Earth Dams.</i></span></h2>
-</div>
-
-<p>There are several types of earth dams, which may be described as follows:</p>
-
-<div class="blockquot">
-<p class="neg-indent">1. Homogeneous earth dams, either with or without a puddle
-trench.</p>
-
-<p class="neg-indent">2. Earth dams with a puddle core or puddle face.</p>
-
-<p class="neg-indent">3. Earth dams with a core wall of brick, rubble or concrete
-masonry.</p>
-
-<p class="neg-indent">4. New types, composite structures.</p>
-
-<p class="neg-indent">5. Rock-fill dams with earth inner slope.</p>
-
-<p class="neg-indent">6. Hydraulic-fill dams of earth and gravel.</p>
-</div>
-
-<p>The writer proposes to give an example of each type, with such remarks
-upon their distinctive features and relative merits as he thinks may be
-instructive.</p>
-
-<h3>Earth Dams with Puddle Core Wall or Face.</h3>
-
-<p>YARROW DAM.–The Yarrow dam of the Liverpool Water-Works is a notable
-example of the second type, (a section of which is shown in <a href="#FIG_2">Fig. 2.</a>)
-An excavation 97 ft. in depth was made to bed rock through different
-strata of varying thickness, and a trench 24 ft. wide was cut with
-side slopes 1 on 1 for the first 10 ft. in depth below the surface.
-The trench was then carried down through sand, gravel and boulders
-with sides sloping 1 in 12. The upper surface of the shale bed rock
-was found to be soft, seamy and water-bearing. Pumps were installed
-to keep the water out of the trench while it was being cut 4 or 5 ft.
-deeper into the shale. The lower portion was then walled up on either
-side with brickwork 14 ins. in thickness, and the trench between the
-walls was filled with concrete, made in the proportion of 1 of cement,
-1 of sand and 2 of gravel or broken stone. By so doing a dry bed was
-secured for the foundation of the puddle wall. Two lines of 6-in. pipes
-were laid on the bed rock, outside of the walls, and pipes 9 ins. in
-diameter extended vertically above the top of the brickwork some 27
-ft. These pipes were filled with concrete, after disconnecting the
-pumps. After refilling the trench with puddle to the original surface,
-a puddle wall was carried up simultaneous with the embankment, having a
-decreasing batter of 1 in 12, which gave a width of 6 ft. at the top.
-This form of construction is very common in England and <a href="#FIG_14">Figs. 14</a>
-and <a href="#FIG_15">15</a> show two California dams, the Pilarcitos
-and San Andres, of the same general type.
-<span class="pagenum" id="Page_34">[Pg 34]</span></p>
-
-<div class="figcenter">
-  <img id="FIG_14" src="images/image034a.jpg" alt="" width="600" height="181" />
-  <p class="center">FIG. 14.–CROSS-SECTION OF PILARCITOS DAM.</p>
-  <img id="FIG_15" src="images/image034b.jpg" alt="" width="600" height="154" />
-  <p class="center space-below2">FIG. 15.–CROSS-SECTION OF SAN ANDRES DAM.</p>
-</div>
-
-<p><span class="pagenum" id="Page_35">[Pg 35]</span>
-ASHTI EMBANKMENT.–This is not a very high embankment, but being
-typical of modern dams in British India, where the puddle is generally
-carried only to the top of the original surface of the ground, and not
-up through the body of the dam, it is thought worthy of mention. <a href="#FIG_16">Fig. 16</a>
-shows a section of this embankment, which is located in the Sholapur
-District, India.</p>
-
-<p>The central portion of this dam above the puddle trench is made of
-“selected black soil;” then on either side is placed “Brown Soil,”
-finishing on the outer slopes with “Murum.” Trap rock decomposes first
-into a friable stony material, known in India as “Murum” or “Murham.”
-This material further decomposes into various argillaceous earths, the
-most common being the “black cotton soil” mentioned above.</p>
-
-<div class="figcenter">
-  <img id="FIG_16" src="images/image035.jpg" alt="" width="600" height="242" />
-  <p class="center space-below2">FIG. 16.–CROSS-SECTION OF ASHTI TANK EMBANKMENT.</p>
-</div>
-
-<p>This particular dam has been adversely criticised on account of the
-lack of uniformity in the character of the materials composing the
-bank. It is claimed that the materials being of different density and
-weight, unequal settlement will result, and lines of separation will
-form between the different kinds of materials.</p>
-
-<p>Earth materials do not unite or combine with timber or masonry, but
-there are no such distinct lines of transition and separation between
-different earth materials themselves as <a href="#FIG_16">Fig. 16</a>
-would seem to indicate.</p>
-
-<h3>Puddle Trench.</h3>
-
-<p>In the last three dams mentioned (<a href="#FIG_14">Figs. 14</a>,
-<a href="#FIG_15">15</a>, <a href="#FIG_16">16</a>) the puddle
-trenches are made with vertical sides or vertical steps and offsets.
-<span class="pagenum" id="Page_36">[Pg 36]</span>
-A wedge-shaped trench certainly has many advantages over this form.
-Puddle being plastic, consolidates as the dam settles, filling the
-lowest parts by sliding on its bed. It thus has a tendency to break
-away from the portion supported by the step, and a further tendency to
-leave the vertical side, thus forming cracks and fissures for water to
-enter. The argument advanced by those holding a different view, namely,
-that it is difficult to dress the sides of a trench to a steep batter
-and to timber it substantially, has in reality little weight when put
-to practical test. Mr. F. P. Stearns, in describing the recent work
-of excavating the cut-off trench of the North Dike of the Wachusett
-reservoir, Boston, said it was found to be both better and cheaper
-to excavate a trench with slopes than with vertical sides protected
-by sheeting. He favored this shape in case of pile-work and for the
-purpose also of wedging materials together.</p>
-
-<p>Mr. Wm. J. McAlpine’s “Specifications for Earth Dams,” representing the
-best practice of 25 years ago, which are frequently cited, contain the
-following description of how to prepare the up-stream floor of the dam:</p>
-
-<p class="blockquot">Remove the pervious and decaying matter by
-breaking up the natural soil and by stepping up the sides of the
-ravine; also by several toothed trenches across the bottom and up the
-sides.</p>
-
-<p>One of Mr. McAlpine’s well known axioms was, “water abhors
-an angle.” The “stepping” and “toothed” trenches above specified
-need not necessarily be made with vertical planes, but should
-be made by means of inclined and horizontal planes. The writer’s
-experience and observation leads him to think that all excavations
-in connection with earth dams requiring a refill should be made
-wedge-shaped so that the pressure of the superincumbent materials
-in settling will wedge the material tighter and tighter together
-and fill every cavity. A paper by Mr. Wm. L. Strange, C. E., on
-“Reservoirs with high Earthen Dams in Western India,” published
-in the Proceedings of the Institution of Civil Engineers,
-Vol. 132, (1898), is one of the best contributions to the literature
-on this subject, known to the writer. Mr. Strange states that</p>
-
-<p class="blockquot no-indent">
-the rate of filtration of a soil depends upon its porosity,
-which governs the frictional resistance to flow, and the
-slope and length of the filamentary channels along which the
-water may be considered to pass. It is evident, therefore,
-that the direct rate of infiltration in a homogeneous soil
-must decrease from the top to the bottom of the puddle
-trench. The best section for a puddle trench is thus a
-wedge, such as an open excavation would give. It is true
-that the uppermost infiltrating filaments when stopped by
-the puddle, will endeavor to get under it, but a depth will
-eventually be reached when the frictional resistance along
-the natural passages will be greater than that due to the
-transverse passage of the puddle trench, and it is when
-this occurs that the latter may be stopped without danger,
-as the <i>filtration to it</i> will be less than that
-<i>through</i> it. This depth requires to be determined in
-each case, but in fairly compact Indian soils 30 feet will
-be a fair limit.</p>
-
-<p><span class="pagenum" id="Page_37">[Pg 37]</span></p>
-
-<h3>Puddle Wall vs. Puddle Trench.</h3>
-
-<p>There is a diversity of opinion among engineers in regard to the proper
-place for the puddle in dam construction. Theoretically, the inner
-face would be preferable to the center, for the purpose of preventing
-any water from penetrating the embankment. It is well known that all
-materials immersed in water lose weight in proportion to the volume of
-water they displace. If the upper half of the dam becomes saturated
-it must neccesarily lose both weight and stability. Its full cohesive
-strength can only be maintained by making it impervious in some way.
-The strength of an earth dam depends upon three factors:</p>
-
-<ul class="index fontsize_110">
-<li class="isub2">1. Weight.</li>
-<li class="isub2">2. Frictional resistance against sliding.</li>
-<li class="isub2">3. Cohesiveness of its materials.</li>
-</ul>
-
-<p>These can be known only so long as no water penetrates the body of
-the dam. When once saturated the resultant line of pressure is no
-longer normal to the inner slope, for the reason that there is now a
-force tending to slide the dam horizontally and another due to the
-hydrostatic head tending to lift it vertically. When the water slope
-is impervious the horizontal thrust is sustained by the whole dam and
-not by the lower half alone. When once a passage is made into the body
-of the dam, the infiltration water will escape along the line of least
-resistance, and if there be a fissure it may become a cavity and the
-cavity a breach.</p>
-
-<p>For practical reasons, mainly on account of the difficulty of
-maintaining a puddle face on the inner slope of a dam, which would
-require a very flat slope, puddle is generally placed at the center as
-a core wall.</p>
-
-<p>It was thought possible at the Tabeaud dam to counteract the tendency
-of the face puddle to slough off into the reservoir by use of a broken
-stone facing of riprap. This covering will protect the puddle from the
-deteriorating effects of air and sun whenever the water is drawn low
-and also resists the pressure at the inner toe of the dam.
-<span class="pagenum" id="Page_38">[Pg 38]</span></p>
-
-<h3>Percolation and Infiltration.</h3>
-
-<p>The earlier authorities on the subject of percolation and infiltration
-of water are somewhat conflicting in their statements, if not confused
-in their ideas. We are again impressed with the importance of a
-clearly defined and definite use of terms. The temptation and tendency
-to use language synonymously is very great, but it is unscientific
-and must result in confusion of thought. Let it be observed that
-<i>filtration</i> is the process of mechanically separating and
-removing the undissolved particles floating in a liquid. That
-<i>infiltration</i> is the process by which water (or other liquid)
-enters the interstices of porous material. That <i>percolation</i> is
-the action of a liquid passing through small interstices; and, finally,
-that <i>seepage</i> is the amount of fluid which has percolated through
-porous materials.</p>
-
-<p>Many recent authorities are guilty of confusion in thought or
-expression, as will appear from the following:</p>
-
-<p>One says, for instance, that a</p>
-
-<p class="blockquot no-indent">rock is water-tight when non-absorbent
-of water, but that a soil is not water-tight unless it will absorb an
-enormous quantity of water.</p>
-
-<p>This would seem to indicate that super-saturation and not pressure is
-necessary to increase the water-tightness of earth materials.</p>
-
-<p>Again, in a recent discussion regarding the saturation and percolation
-of water through the lower half of a reservoir embankment, it was
-remarked, that</p>
-
-<p class="blockquot no-indent">the more compact the material of which
-the bank is built, the steeper will be the slope of saturation.</p>
-
-<p>Exception was taken to this, and the statement made, that</p>
-
-<p class="blockquot no-indent"><i>with compact material</i>, the
-sectional area of flow is larger below a given level with porous
-material, and as the bank slope is one determining factor of the line
-of saturation, this line tends to approach the slope line; while with
-porous material in a down-stream bank, the slope of saturation is
-steeper and the area of the flow less.</p>
-
-<p>In reply to this, it was said,
-<span class="pagenum" id="Page_39">[Pg 39]</span></p>
-
-<p class="blockquot no-indent">that it is obvious that if the
-embankment below the core wall is built of material so compact as to be
-impervious to water, no water passing through the wall will enter it,
-and the slope of saturation will be vertical. If it be less compact,
-water will enter more or less according to the head or pressure,
-and according to its compactness or porosity, producing a slope of
-saturation whose inclination is dependent on the frictional resistance
-encountered by the water. And the bank will be tight whenever the slope
-of saturation remains within the figure of the embankment.</p>
-
-<p>Further,</p>
-
-<p class="blockquot no-indent">that it was necessary to distinguish
-between the slope assumed by water <i>retained in</i> an embankment
-and that taken by water <i>passing through</i> an embankment made of
-material too porous to retain it; where the rule is clearly reversed
-and where the more porous the material the steeper the slope at which
-water will run through it at a given rate.</p>
-
-<p>These citations are sufficient to emphasize the importance of exact
-definition of terms and clear statement of principles.</p>
-
-<p>The latest experiments relating to the percolation of water through
-earth materials and tests determining the stability of soils are
-those made during the investigations at the New Croton Dam and
-Jerome Park Reservoir, New York, and those relating to the North
-Dike of the Wachusett Reservoir, Boston. These are very interesting
-and instructive, and it is here proposed to discuss the results and
-conclusions reached in these cases, after some introductory remarks
-reciting the order of events.</p>
-
-<p>NEW CROTON DAM.–In June, 1901, the Board of Croton Aqueduct
-Commissioners of New York requested a board of expert engineers,
-consisting of Messrs. J. J. R. Croes, E. F. Smith and E. Sweet, to
-examine the plans for the construction of the earth portion of the New
-Croton Dam, and also the core wall and embankment of the Jerome Park
-reservoir.</p>
-
-<p>This report was published in full in Engineering News for Nov. 28,
-1901. It was followed in subsequent issues of the said journal by
-supplemental and individual reports from each member of the board
-of experts, and by articles from Messrs. A. Fteley, who originally
-designed the works, A. Craven, formerly division engineer on this work,
-and W. R. Hill, at that time chief engineer of the Croton Aqueduct
-Commission.</p>
-
-<p>After describing the New Croton Dam, the board of experts preface their
-remarks on the earth embankment by saying that</p>
-
-<p class="blockquot no-indent">it has been abundantly proven that up to
-a height of 60 or 70 ft. an embankment founded on solid material and
-constructed of well-selected earth, properly put in place, is fully as
-durable and safe as a masonry wall and far less costly.</p>
-
-<p>There are, in fact, no less than 22 earth dams in use to-day exceeding
-90 ft. in height, and twice that number over 70 ft. in height. Five of
-the former are in California, and several of these have been in use
-over 25 years. The writer fails to appreciate the reason for limiting
-the safe height of earth dams to 60 or 70 ft.</p>
-
-<p>The New Croton Dam was designed as a composite structure of masonry and
-<span class="pagenum" id="Page_40">[Pg 40]</span>
-earth, crossing the Croton Valley at a point three miles from the
-Hudson River. The earth portion was to join the masonry portion at a
-point where the latter was 195 ft. high from the bed rock. The Board
-thought there was no precedent for such a design and no necessity
-for this form of construction. The point to be considered here was
-whether a dam like this can be made sufficiently impermeable to water
-to prevent the outer slope from becoming saturated and thus liable to
-slide and be washed out.</p>
-
-<p>The design of the embankment portion was similar to all the earth dams
-of the Croton Valley. In the center is built a wall of rubble masonry,
-generally founded upon solid rock, and “intended to prevent the free
-seepage of water, but not heavy enough to act alone as a retaining wall
-for either water or earth.”</p>
-
-<p><a href="#FIG_17">Fig. 17</a> shows a section which is typical of most
-New England earth dams; and <a href="#FIG_18">Fig. 18</a>, the sections of
-two of the Croton Valley dams, New York water supply. These dams all have
-masonry core walls, illustrating the third type of dams given on <a href="#Page_33">page 33</a>.</p>
-
-<div class="figcenter">
-  <img id="FIG_17" src="images/image040.jpg" alt="" width="600" height="210" />
-  <p class="center space-below2">FIG. 17.–CROSS-SECTION OF A TYPICAL NEW ENGLAND DAM.</p>
-</div>
-
-<p>The board of experts made numerous tests by means of borings into
-the Croton Valley dams to determine the slope of saturation. The
-hydraulic laboratory of Cornell University also made tests of the
-permeability of several samples of materials taken from pits. All the
-materials examined were found to be permeable and when exposed to water
-to disintegrate and assume a flat slope, the surface of which was
-described as “slimy.”</p>
-
-<p>Pipe wells were driven at different places into the dams and the line
-of saturation was determined by noting the elevations at which the
-water stood in them. In all the dams the entire bank on the water side
-of the core wall appeared to be completely saturated. Water was also
-found to be standing in the embankment on the down-stream side of the
-core wall. The extent of saturation of the outer bank varied greatly,
-<span class="pagenum" id="Page_41">[Pg 41]</span>
-due to the difference in materials, the care taken in building them,
-and their ages. <a href="#FIG_19">Fig. 19</a> gives the average slopes
-of saturation as determined by these borings.</p>
-
-<p>The experts stated</p>
-
-<p class="blockquot no-indent">that the slope of the surface of the
-saturation in the bank is determined by the solidity of the embankment:
-The more compact the material of which the bank is built, the steeper
-will be the slope of saturation. </p>
-
-<p>As a result of their investigations, the experts were of the opinion
-that the slope of saturation in the best embankments made of the
-material found in the Croton Valley is about 35 ft. per 100 ft., and
-that with materials less carefully selected and placed the slope may be
-20 ft. per 100 ft.</p>
-
-<p>Further, that taking the loss of head in passing through the core wall,
-and the slope assumed by the plane of saturation, the maximum safe
-height of an earth dam with its top 20 ft. above water level in the
-reservoir and its outside slope 2 on 1, is 63 to 102.5 ft. This is a
-remarkable finding in view of the fact that the Titicus Dam, one of the
-Croton Valley dams examined, has a maximum height above bed rock of 110
-ft. and has been in use seven years. This dam is not a fair example to
-cite in proof of their conclusion, because its <i>effective head</i> is
-only about 46 ft.<a id="FNanchor_2" href="#Footnote_2" class="fnanchor">[2]</a></p>
-
-<div class="figcenter">
-  <img id="FIG_18" src="images/image041a.jpg" alt="" width="600" height="193" />
-  <p class="center">BOG BROOK DAM.</p>
-  <img src="images/image041b.jpg" alt="" width="600" height="121" />
-  <p class="center space-below2">MIDDLE BRANCH DAM.</p>
-  <p class="center space-below2">FIG. 18.–CROSS-SECTION OF TWO CROTON VALLEY DAMS,<br />
-SHOWING SATURATION.</p>
-</div>
-
-<p>Mr. Fteley gave as a reason for the elevation of the water slope found
-<span class="pagenum" id="Page_42">[Pg 42]</span>
-in the outer bank of the Croton dams the fact of their being
-constructed of fine materials and stated that with comparatively porous
-materials they would have shown steeper slopes of saturation.</p>
-
-<p>Mr. Craven argued that all dams will absorb more or less water, and
-that porosity is merely a degree of compactness; that slope implies
-motion in water, and that there is no absolute retention of water in
-the outer bank of a dam having its base below the plane indicated by
-the loss of head in passing through the inner bank and then through a
-further obstruction of either masonry or puddle; that there is simply a
-partial retention, with motion through the bank governed by the degree
-of porosity of the material.</p>
-
-<p><a href="#FIG_19">Fig. 19</a> is a graphical interpretation of the
-conclusion reached by the board of experts, as already given on <a href="#Page_41">page 41</a>.
-“A” is an ideal profile of a homogeneous dam with the inner slope 3 on
-1 and the outer slope 2 on 1. The top width is made 25 ft. for a dam
-having 90 ft. effective head, the high-water surface in the reservoir
-being 10 ft. below the crest of the dam. This ideal profile is a
-fair average of all the earth dams of the world. Not having a core
-wall to augment the loss of head, it fairly represents what might be
-expected of such a dam built of Croton Valley material, compacted in
-the usual way. It should be noted that the intersection of the plane
-of saturation with the rear slope of the dam at such high elevation
-as shown indicates an excessive seepage and a dangerously unstable
-condition.</p>
-
-<h3>Preliminary Study of Profile for Dam.</h3>
-
-<p>The preliminary calculations for designing a profile for an earth dam
-are simple and will here be illustrated by an example. Let us assume
-the following values:</p>
-
-<div class="blockquot">
-<p>a. Central height of dam, 100 ft.</p>
-
-<p>b. Maximum depth of water, 90 ft., with surface 10 ft.
-below crest of dam.</p>
-
-<p>c. Effective head, 90 ft.</p>
-
-<p>d. Weight of water, 62.5 lbs. per cu. ft.</p>
-
-<p>e. Weight of material, 125 lbs. per cu. ft.</p>
-
-<p>f. Coefficient of friction, 1.00, or equal to the weight.</p>
-
-<p>g. Factor of safety against sliding, 10.</p>
-
-<p>The width corresponding to the vertical pressure of 1 ft. is,</p>
-</div>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="Materials" cellpadding="0" >
-  <tbody><tr>
-      <td class="tdc bb">62.5 × 10</td>
-      <td class="tdc" rowspan="2">&nbsp;=&nbsp; 5 ft.</td>
-   </tr><tr>
-      <td class="tdc">125</td>
-   </tr>
- </tbody>
-</table>
-
-<p><span class="pagenum" id="Page_43">[Pg 43]</span></p>
-
-<div class="figcenter">
-  <img id="FIG_19" src="images/image043a.jpg" alt="" width="600" height="199" />
-  <img src="images/image043b.jpg" alt="" width="600" height="171" />
-  <p class="center space-below2">FIG. 19.–GRAPHICAL INTERPRETATION OF STUDIES OF BOARD OF EXPERTS<br />
-                                 ON THE ORIGINAL EARTH PORTION OF THE NEW CROTON DAM.</p>
-</div>
-
-<p><span class="pagenum" id="Page_44">[Pg 44]</span>
-The hydrostatic pressure per square foot at 90 ft. depth is,</p>
-
-<p class="f110">62.5 × 90 = 5,625 lbs.</p>
-
-<p>The dam, having a factor of safety of 10, must present a resistance of,</p>
-
-<p class="f110">5,625 × 10 = 56,250 lbs.,</p>
-
-<p class="no-indent">or 28 tons per square foot.</p>
-
-<p>The theoretical width of bank corresponding to 90 ft. head and a factor
-of 10 is shown by the dotted triangle (A-B-B) to be 450 ft., (<a href="#FIG_19">B, Fig. 19</a>)
-with slopes 2½ on 1.</p>
-
-<p>To this must be added the width due to the height of crest above the
-water surface in the reservoir and the width of crest.</p>
-
-<p>The former would be,</p>
-
-<p class="f110">2 (2½ × 10) = 50 ft.,</p>
-
-<p class="no-indent">and the latter by Trautwine’s rule,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
-  <tbody><tr>
-      <td class="tdc">&nbsp;</td>
-      <td class="tdc bb">&nbsp;</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdr">2 + 2√</td>
-      <td class="tdl">100</td>
-      <td class="tdl">&nbsp;= 22 ft.,</td>
-   </tr>
- </tbody>
-</table>
-
-<p class="no-indent">giving a total base width of <span class="fontsize_120">522 ft</span>.</p>
-
-<p>Let us now assume that the slope of saturation may be 35 ft. per 100
-ft. We observe that this intersects the base 40 ft. within the outer
-toe of the bank slope. If the plane of saturation was 33 ft. per 100,
-it would just reach the outer toe. It would be advisable to enlarge
-this section by adding a 10-ft. berm at the 50-ft. level, having a
-slope not less than 3 on 1 for the up-stream face, and two 15-ft. berms
-on the down-stream face, having slopes 2½ on 1. The additional width
-of base due to these modifications in our profile amounts to 65 ft.,
-giving a total base width of 587 ft., and increasing the factor of
-safety from 10 to 13. It should be remembered that if the bank becomes
-saturated this factor of safety may be reduced 50%, the coefficient of
-moist clay being 0.50.</p>
-
-<p>The loss of head due to a core wall of masonry, as designed for the
-New Croton Dam, was assumed by the board of experts to be 21 ft., or
-17% of the depth of water in full reservoir. It has been stated by
-several authorities that the primary object of a masonry core wall is
-to afford a water-tight cut-off to any water of percolation which may
-reach it through the upper half of the embankment. It appears that
-absolute water-tightness in the core wall is not obtained, although the
-core walls of the Croton dams are said to be “the very best quality of
-rubble masonry that can be made.”</p>
-
-<p>Mr. W. W. Follett, who is reported to have had considerable experience
-in building earth dams, and who has made some valuable suggestions
-thereupon, is emphatic in saying,</p>
-
-<p class="blockquot no-indent">that the junction of earth and masonry
-forms a weak point, that either a puddle or masonry core in an earthen
-dam is an element of weakness rather than strength.</p>
-
-<p>He also thinks the usual manner of segregating and depositing materials
-<span class="pagenum" id="Page_45">[Pg 45]</span>
-different in density and weight, and thus subject to different amounts
-of settlement, as bad a form of construction as could be devised.</p>
-
-<p>Core walls may prevent “free passage of water” and “excessive seepage,”
-but are nevertheless of doubtful expediency.</p>
-
-<h3>Earthwork Slips and Drainage.</h3>
-
-<p>Mr. John Newman, in his admirable treatise on “Earthwork Slips and
-Subsidences upon Public Works,” classifies and enumerates slips as
-follows:</p>
-
-<ul class="index fontsize_120">
-<li class="isub2">Natural causes, 7.</li>
-<li class="isub2">Artificial causes, 31.</li>
-<li class="isub2">Additional causes due to impounded water, 7.</li>
-</ul>
-
-<p>After describing each cause he presents 39 different means used to
-prevent such slips and describes methods of making repairs.</p>
-
-<p>Mr. Wm. L. Strange has had such a large and valuable experience and has
-set forth so carefully and lucidly both the principles and practice
-of earth dam construction, that the writer takes pleasure in again
-quoting him on the subject of <i>drainage</i>, of which he is an ardent
-advocate. He says that,</p>
-
-<p class="blockquot no-indent">thorough drainage of the base of a dam
-is a matter of vital necessity, for notwithstanding all precautions,
-some water will certainly pass through the puddle.</p>
-
-<p>It is at the junction of the dam with the ground that the maximum
-amount of leakage may be expected. The percolating water should be
-gotten out as quickly as possible. The whole method of dealing with
-slips may be summed up in one word–<i>drainage</i>.</p>
-
-<p>The proper presentation of these two phases of our subject would in
-itself require a volume. The interested reader is therefore referred to
-the different authorities and writers cited in <a href="#APPENDIX_II">Appendix II</a>.</p>
-
-<h3>Jerome Park Reservoir Embankments.</h3>
-
-<p>The Jerome Park reservoir is an artificial basin involving the
-excavation and removal of large quantities of soil, and the erection of
-long embankments with masonry core walls, partly founded on rock and
-partly on sand. The plan and specifications call for an embankment 20
-ft. wide on top, with both slopes 2 on 1, and provide for lining the
-inner slope with brick or stone laid in concrete, and for covering the
-bottom with concrete laid on good earth compacted by rolling.
-<span class="pagenum" id="Page_46">[Pg 46]</span></p>
-
-<div class="figcenter">
-  <img id="FIG_20" src="images/image046a.jpg" alt="" width="600" height="153" />
-  <p class="f110"><b>Section at Sta. 99.</b></p>
-  <img src="images/image046b.jpg" alt="" width="600" height="170" />
-  <p class="f110"><b>Section at Sta. 76+20.</b></p>
-  <p class="center space-below2">FIG. 20.–GRAPHICAL EXHIBIT OF STUDIES OF<br />
-                                JEROME PARK RESERVOIR EMBANKMENT.</p>
-</div>
-
-<p><span class="pagenum" id="Page_47">[Pg 47]</span>
-Wherever bed rock was not considered too deep below the surface the
-core walls were built upon it. In other places the foundation was
-placed 8 to 10 ft. below the bottom of the reservoir and rested upon
-the sand.</p>
-
-<p>It appears that the plans of the Jerome Park embankment were changed
-from their original design, prior to the report of the board of
-experts, on account of two alleged defects, namely, “cracks in the core
-wall” and “foundation of quicksand,” and incidentally on account of the
-supposed instability of the inner bank.</p>
-
-<p>In describing the materials on which these embankments rest the experts
-remarked</p>
-
-<p class="blockquot no-indent">that all these fine sands are unstable
-when mechanically agitated in an excess of water, and that they all
-settle in a firm and compact mass under the water when the agitation
-ceases. That they are quite unlike the true quicksands whose particles
-are of impalpable fineness and which are “quick” or unstable under
-water.</p>
-
-<p><a href="#FIG_20">Fig. 20</a> is a graphic exhibit of the results
-of tests made at “Station 76 + 20,” and at “Station 99,” to determine
-the flow line of water in the sand strata underlying the embankment and
-bottom of the Jerome Park reservoir.</p>
-
-<p>The experts reported that there was no possible danger of sliding or
-sloughing of the bank; that the utmost that could be expected would
-be the percolation of a small amount of water through the embankment
-and the earth; and that this would be carried off by the sewers in the
-adjacent avenues; that a large expenditure to prevent such seepage
-would not be warranted nor advisable.</p>
-
-<p>In concluding their report, however, they recommended changing the
-inner slope of 2 on 1 to 2½ on 1, and doubling the thickness of the
-concrete lining at the foot of the slope to preclude all possibility
-of the sliding or the slipping of the inner bank in case of the water
-being lowered rapidly in the reservoir.</p>
-
-<p>Mr. W. R. Hill, then chief engineer of the Croton Aqueduct Commission,
-favored extending the core walls to solid rock. He took exception to
-the manner of obtaining samples of sand by means of pipe and force-jet
-of water, claiming that only the coarsest sand was obtained for
-examination. He did not consider fine sand through which three men
-could run a ¾-in. rod 19 and 20 ft. to rock without use of a hammer,
-very stable material upon which to build a wall.
-<span class="pagenum" id="Page_48">[Pg 48]</span></p>
-
-<h3>North Dike of the Wachusett Reservoir,<br /> Boston.</h3>
-
-<p>The North Dike of the Wachusett Reservoir is another large public work
-in progress at the present time. It is of somewhat unusual design
-and the preliminary investigations and experiments which led to its
-adoption are interesting in the extreme.<a id="FNanchor_3" href="#Footnote_3" class="fnanchor">[3]</a></p>
-
-<p>The area to be explored in determining the best location for the dike
-was great, and the preliminary investigations conducted by means of
-wash drill borings, very extensive. A total of 1,131 borings were made
-to an average depth of 83 ft., the maximum depth being 286 ft. The
-materials were classified largely by the appearance of the samples,
-though chemical and filtration tests were also made. The plane of the
-ground water was from 35 to 50 ft. below the surface, and the action of
-the water-jet indicated in a measure the degree of permeability of the
-strata.</p>
-
-<p>In addition to these tests experimental dikes of different materials,
-and deposited in different ways, were made in a wooden tank 6 ft. wide,
-8 ft. high and 60 ft. long. The stability of soils when in contact with
-water was experimented with, as shown in <a href="#FIG_21">Fig. 21</a>,
-in the following manner:</p>
-
-<p>An embankment (<a href="#FIG_21">Fig. 21</a>) was constructed in the
-tank of the material to be experimented with, 2 ft. wide on top, 6 ft.
-high, with slopes 2 on 1, and water admitted on both sides to a depth
-of 5 ft. The top was covered with 4-in. planks 2 ft. long and pressure
-applied by means of two jack screws resting upon a cross beam on top of
-the planks.</p>
-
-<p>With a pressure of three tons per square foot, the 4-in. planks were
-forced down into the embankment a little more than 6 ins., resulting
-in a very slight bulging of the slopes a little below the water level.
-Immediately under the planks the soil became hard and compact. A man’s
-weight pushed a sharp steel rod, ¾-in. in diameter, only 6 to 8 ins.
-into the embankment where the pressure was applied, while outside of
-this area the rod was easily pushed to the bottom of the tank.</p>
-
-<p>These results corroborate in a general way the practical experience of
-the author, both in compressed embankments, where he found it necessary
-to use a pick vigorously to loosen the material of which they were
-composed, and in embankments made by merely dumping the material from
-a track, in which case the earth is so slightly compressed that an
-excavation is easily made with a shovel.
-<span class="pagenum" id="Page_49">[Pg 49]</span></p>
-
-<div class="figcenter">
-  <img id="FIG_21" src="images/image049a.jpg" alt="" width="600" height="198" />
-  <p class="center">Fig. 21.</p>
-  <img id="FIG_22" src="images/image049b.jpg" alt="" width="600" height="145" />
-  <p class="center space-below2">Fig. 22.</p>
-  <p class="center">Fig. 23.–CAN FOR DETERMINING<br /> FRICTIONAL RESISTANCE</p>
-  <img id="FIG_23" src="images/image049c.jpg" alt="" width="300" height="293" />
-  <img id="FIG_24" src="images/image049d.jpg" alt="" width="600" height="107" />
-  <p class="center">Fig. 24.</p>
-  <img id="FIG_25" src="images/image049e.jpg" alt="" width="600" height="192" />
-  <p class="center space-below2">Fig. 25.</p>
-  <p class="center space-below2">FIGS. 21 TO 24.–EXPERIMENTAL DIKES AND CYLINDER EMPLOYED IN STUDIES
-                                 FOR THE NORTH DIKE OF THE WACHUSETT RESERVOIR; AND (FIG. 25)
-                                 CROSS-SECTION OF THE DIKE.</p>
-</div>
-
-<p><span class="pagenum" id="Page_50">[Pg 50]</span>
-The difference in the coefficient of friction of the same material
-when dry and when wet greatly modifies the form of slope. The harder
-and looser the particles, the <i>straighter</i> will be the slope line
-in excavation and slips. The greater the cohesion of the earth, the
-<i>more curved</i> will be the slope, assuming a parabolic curve near
-the top–the true form of equilibrium.</p>
-
-<p>RATE OF FILTRATION.–The rate of filtration through different soils was
-experimented with by forming a dike in the tank previously mentioned,
-as shown in <a href="#FIG_22">Fig. 22</a>.</p>
-
-<p>The dike was made full 8 ft. high, 7 ft. wide on top, with a slope on
-the up-stream side of 2 on 1, and on the down-stream side 4 on 1. This
-gave a base width of 55 ft. Immediately over the top of the dike there
-was placed 3 ft. of soil to slightly consolidate the top of the bank
-and permit the filling of the tank to the top without overflowing the
-dike. The water pressure in different parts of the dike was determined
-by placing horizontal pipes through the soil crosswise of the tank.
-These pipes were perforated and covered with wire gauze, being
-connected to vertical glass tubes at their ends. The end of the slope
-on the down-stream side terminated in a box having perforated sides and
-filled with gravel, thus enabling the water to percolate and filter out
-of the bank without carrying the soil with it.</p>
-
-<p>When the soil was shoveled loosely into the tank, without consolidation
-of any kind, it settled on becoming saturated and became quite compact.
-It took five days for the water to appear in the sixth gauge pipe near
-the lower end of the tank. After the pressure, which was maintained
-constant, had been on for several weeks, the seepage amounted to one
-gallon in 22 minutes. When the soil was deposited by shoveling into the
-water, the seepage amounted to one gallon in 34 minutes.</p>
-
-<p>The relative filtering capacities of soils and sands were thought to
-be better determined by the use of galvanized iron cylinders of known
-areas.</p>
-
-<p><a href="#FIG_23">Fig. 23</a> shows one of the cylinders. These latter experiments
-confirmed those previously made at Lawrence, by Mr. Allen Hazen, for the
-Massachusetts State Board of Health. They showed that the loss of head
-<span class="pagenum" id="Page_51">[Pg 51]</span>
-was directly proportioned to the quantity of water filtered and that
-the quantity filtered will vary as the square of the diameter of the
-<i>effective size</i> of the grains of the filtering material.<a id="FNanchor_4" href="#Footnote_4" class="fnanchor">[4]</a></p>
-
-<p>The material classed as “permeable” at the North Dike of the Wachusett
-Reservoir has an effective diameter of about 0.20 mm. A few results are
-given in the following table:</p>
-
-<p>Amount of Filtration in Gallons per Day, Through an Area of 10,000 Sq.
-Ft., With a Loss of Head or Slope of 1 ft. in 10 ft.</p>
-
-<table class="fontsize_110 no-wrap space-above2" border="0" cellspacing="0" summary=" " cellpadding="0" >
-  <tbody><tr>
-      <td class="tdc">&nbsp;</td>
-      <td class="tdc">Material.</td>
-      <td class="tdr">&nbsp;&emsp;Unit ratios.</td>
-      <td class="tdr">&nbsp;&emsp;U. S. gallons.</td>
-   </tr><tr>
-      <td class="tdc">(1)</td>
-      <td class="tdl_ws1">Soil</td>
-      <td class="tdr">1</td>
-      <td class="tdr">510</td>
-   </tr><tr>
-      <td class="tdc">(2)</td>
-      <td class="tdl_ws1">Very fine sand</td>
-      <td class="tdr">14</td>
-      <td class="tdr">7,200</td>
-   </tr><tr>
-      <td class="tdc">(3)</td>
-      <td class="tdl_ws1">Fine sand</td>
-      <td class="tdr">176</td>
-      <td class="tdr">90,000</td>
-   </tr><tr>
-      <td class="tdc">(4)</td>
-      <td class="tdl_ws1">Medium sand</td>
-      <td class="tdr">784</td>
-      <td class="tdr">400,000</td>
-   </tr><tr>
-      <td class="tdc">(5)</td>
-      <td class="tdl_ws1">Coarse sand</td>
-      <td class="tdr">4,353</td>
-      <td class="tdr">2,200,000</td>
-   </tr>
- </tbody>
-</table>
-
-<p>To be sure that the accumulation of air in the small interstices of the
-<i>soil</i> was not the cause of the greatly reduced filtration through
-it, another series of experiments was conducted in the wooden tank, as
-shown in <a href="#FIG_24">Fig. 24</a>.</p>
-
-<p>A pair of screens was placed near each end of the tank, filled with
-porous material, sand and gravel, and the 50-ft. space between filled
-with soil. The soil was rammed in 3-in. layers, and special care taken
-to prevent water from following along the sides and bottom of the tank.
-One end was filled with water to near the top, while the other end gave
-a free outlet.</p>
-
-<p>After this experiment had been continued for more than a month, the
-amount of seepage averaged 1.7 gallons per 24 hours, or about 32 drops
-per minute.</p>
-
-<p>Filtration tests were also made through soil under 150 ft. head, or 5
-lbs. per sq. in., with results not materially different, it is stated,
-from those already given. The soil used in all these tests contained
-from 4 to 8% by weight of organic matter. This was burned and similar
-tests made with the incinerated soil, resulting in an increase of about
-20% more seepage water.</p>
-
-<p>PERMANENCE OF SOILS.–This last material experimented with suggests
-the subject of <i>permanence</i> of soils. This was reported upon
-separately and independently by Mr. Allen Hazen and Prof. W. O. Crosby.
-These experts agreed in their conclusion, stating</p>
-
-<p class="blockquot no-indent">that the process of oxidation below the
-line of saturation would be extremely slow, requiring many thousands of
-years for the complete removal of all the organic matter, and that the
-tightness of the bank would not be materially affected by any changes
-which are likely to occur.</p>
-
-<p><span class="pagenum" id="Page_52">[Pg 52]</span></p>
-
-<p>It has been remarked,</p>
-
-<p class="blockquot no-indent">that of all the materials used in
-the construction of dams, <i>earth</i> is physically the least
-destructible of any. The other materials are all subject to more or
-less disintegration, or change in one form or another, and in earth
-they reach their ultimate and most lasting form.</p>
-
-<p>In speaking of the North Dike of the Wachusett Reservoir, Mr.
-Stearns remarked that,</p>
-
-<p class="blockquot no-indent">it was evident by the application of
-Mr. Hazen’s formula for the flow of water through sands and gravels,
-that the very fine sands found at a considerable depth below the
-surface would not permit enough water to pass through them if a dike
-of great width were constructed, to cause a serious loss of water, and
-it was also found that the soil, which contained not only the fine
-particles or organic matter, but also a very considerable amount of
-fine comminuted particles, which the geologist has termed “rock flour,”
-would be sufficiently impermeable to be used as a substitute for clay
-puddle.</p>
-
-<p><a href="#FIG_25">Fig. 25</a> shows the maximum section of the North
-Dike with its cut-off trench. The quantities and estimated cost of the
-completed structure are given in the table herewith:</p>
-
-<table class="fontsize_110 no-wrap space-above2" border="0" cellspacing="0"
-summary="Estimated Costs." cellpadding="0" >
-  <thead><tr>
-      <th class="tdc" colspan="3">&nbsp;</th>
-      <th class="tdc" colspan="2">|––––– Cost –––––|</th>
-   </tr><tr>
-      <th class="tdc bb">Work.</th>
-      <th class="tdc bb">Quantities.<br />(cu. yds.)</th>
-      <th class="tdc bb">Unit<br />Price.</th>
-      <th class="tdc bb">Actual.</th>
-      <th class="tdc bb">Per cent.<br />total.</th>
-   </tr>
-  </thead>
-  <tbody><tr>
-      <td class="tdl">Soil</td>
-      <td class="tdr_ws1">5,250,000</td>
-      <td class="tdr_ws1">$0.05</td>
-      <td class="tdr_ws1">$262,500</td>
-      <td class="tdr_ws1">34.7</td>
-   </tr><tr>
-      <td class="tdl">Cut-off trench</td>
-      <td class="tdr_ws1">542,000</td>
-      <td class="tdr_ws1">.20</td>
-      <td class="tdr_ws1">108,400</td>
-      <td class="tdr_ws1">19.3</td>
-   </tr><tr>
-      <td class="tdl">Borrowed earth and gravel</td>
-      <td class="tdr_ws1">200,000</td>
-      <td class="tdr_ws1">.20</td>
-      <td class="tdr_ws1">40,000</td>
-      <td class="tdr_ws1">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Slope paving</td>
-      <td class="tdr_ws1">50,000</td>
-      <td class="tdr_ws1">2.20</td>
-      <td class="tdr_ws1">110,000</td>
-      <td class="tdr_ws1">14.6</td>
-   </tr><tr>
-      <td class="tdl">Sheet-piling, pumping, etc.</td>
-      <td class="tdr_ws1">&nbsp;</td>
-      <td class="tdr_ws1">&nbsp;</td>
-      <td class="tdr_ws1">117,000</td>
-      <td class="tdr_ws1">15.5</td>
-   </tr><tr>
-      <td class="tdl" colspan="2">Engineering and preliminary investigations</td>
-      <td class="tdr_ws1">&nbsp;</td>
-      <td class="tdr_ws1 bb">120,000</td>
-      <td class="tdr_ws1 bb">15.9</td>
-   </tr><tr>
-      <td class="tdl_ws1" colspan="3">Total cost</td>
-
-      <td class="tdr_ws1">$757,900</td>
-      <td class="tdr_ws1">100.0</td>
-   </tr>
- </tbody>
-</table>
-
-<h3>Druid Lake Dam, Baltimore, Md.</h3>
-
-<p>Another very interesting and instructive example of high earth dam
-construction is that of the Druid Lake Reservoir embankment, Baltimore, Md.</p>
-
-<p>This dam was built under the supervision of Mr. Robt. K. Martin.
-Construction was begun in 1864, and the dam was finished in 1870. Mr.
-Alfred M. Quick, present chief engineer of the water-works of the
-City of Baltimore has given a very lucid description of this work in
-Engineering News of Feb. 20, 1902.</p>
-
-<p><a href="#FIG_26">Fig. 26</a> is a cross-section of this dam, showing the
-method of construction so clearly as to scarcely need further description.
-<span class="pagenum" id="Page_53">[Pg 53]</span>
-The banks D-D on either side of the central puddle wall were carried up in
-6-in. layers with horses and carts, and kept about 2 ft. higher than
-the puddle trench, which always contained water. The banks E-E were
-made of dumped material, after which the basins F-F were first filled
-with water and finally filled by dumping material into the water from
-tracks being moved in toward the center.</p>
-
-<div class="figcenter">
-  <img id="FIG_26" src="images/image053.jpg" alt="" width="600" height="179" />
-  <p class="center space-below2">FIG. 26–WORKING CROSS-SECTION OF DRUID LAKE DAM.</p>
-</div>
-
-<p>After reaching the top of this fill, banks B-B-B were built up in
-layers similar to D-D. The second set of basins C-C were then filled
-in a manner similar to F-F. The remaining portion A-A was constructed
-in layers like D-D and B-B, with the addition of compacting each layer
-with a heavy roller.</p>
-
-<p>Finally the inner face slope was carried up in 3-in. layers and
-thoroughly rolled, after which 2 ft. of “good puddle” was put upon the
-inner slope the latter was rip-rapped, the crown covered with gravel
-and the rear slope sodded.</p>
-
-<p>Some years after completion, a driveway was built along the outer
-slope, as shown, which had a tendency to strengthen the dam, though not
-designed expressly for that purpose.</p>
-
-<p>It is of interest to know that the influent, effluent and drain pipes
-were originally constructed through or under the embankment. These
-<span class="pagenum" id="Page_54">[Pg 54]</span>
-pipes were laid upon solid earth, and where they passed through the
-puddle wall were supported upon stone piers 6 ft. apart. As might be
-expected, they soon cracked badly and were finally abandoned, new ones
-being placed in the original ground at the south side of the lake. Mr.
-Quick states that so far as is known there has never been any evidence
-of a leak through the embankment during these 32 years of service.</p>
-
-<h3>New Types of Dams;<br /> Bohio, Panama Canal.</h3>
-
-<p>A brief description will now be given of three different dams designed
-for Bohio, on the proposed Panama Canal. Mr. George S. Morison’s paper
-before the American Society of Civil Engineers, on “The Bohio Dam,”
-and the discussion thereon, especially that by Mr. F. P. Stearns, were
-quite fully reported in Engineering News for March 13 and May 8, 1902.
-In constructing the Panama Canal it will be necessary to impound the
-waters of the Chagres River, near Bohio, to maintain the summit level
-of this canal and supply water for lockage.</p>
-
-<p>THE FRENCH DESIGN.–<a href="#FIG_27">Fig. 27</a> is an enlarged
-section of the original design of the new French Co. This design has
-no core wall, but at the up-stream toe a concrete wall was to be
-built across the river between the two lines of sheet-piling. At the
-down-stream toe a large amount of riprap was to be placed to prevent
-destruction of the dam during construction. In this case it would
-be necessary to construct a temporary dam above and also to use the
-excavation for the locks as a flood spillway. This method would involve
-considerable risk to the work, on account of the large volume of flood
-waters it might be necessary to take care of during construction.</p>
-
-<p>ISTHMIAN CANAL COMMISSION.–The dam proposed by the Isthmian Canal
-Commission is shown by <a href="#FIG_28">Fig. 28</a>. This was designed
-to be an absolutely water-tight closure of the geological valley,
-by using a masonry core wall carried down to bed rock. The maximum
-depth being 129 ft., it was planned to rest the concrete wall on a
-series of pneumatic caissons reaching to rock. The spaces between the
-caissons would be closed and made water-tight. Both slopes of the earth
-embankment were to have horizontal benches and be revetted with loose rock.</p>
-
-<p>MR. MORISON’S DESIGN.–To appreciate fully the object and aim of the
-third design, <a href="#FIG_29">Fig. 29</a>, which may be called a new type,
-although similar in many respects to the North Dike of the Wachusett
-reservoir already illustrated and described, it should be stated that
-the equalized flow of the Chagres River is put at 1,000 cu. ft. per
-sec. Of this quantity it is estimated that 500 cu. ft. would be needed
-for lockage and 200 cu. ft. for evaporation. This leaves 300 cu. ft.
-per sec. available for seepage and other losses or to be wasted.
-<span class="pagenum" id="Page_55">[Pg 55]</span></p>
-
-<div class="figcenter">
-  <img id="FIG_27" src="images/image055a.jpg" alt="" width="600" height="126" />
-  <img id="FIG_28" src="images/image055b.jpg" alt="" width="600" height="206" />
-  <img id="FIG_29" src="images/image055c.jpg" alt="" width="600" height="129" />
-  <p class="center space-below2">FIGS. 27 TO 29.–DESIGNS FOR THE BOHIO DAM,<br /> PANAMA CANAL.</p>
-</div>
-
-<p><span class="pagenum" id="Page_56">[Pg 56]</span>
-It will thus be seen that a scarcity of water is not in this instance
-a condition demanding an absolutely water-tight dam. The amount of
-seepage permissible without endangering the stability of the structure
-is the real point now to be discussed.</p>
-
-<p>The third design, which was proposed by Mr. Morison, is shown by
-<a href="#FIG_29">Fig. 29</a>. The topography and configuration of
-this dam site is not unlike that of the San Leandro Dam, California,
-soon to be described, while the general design is similar, as has been
-remarked, to the North Dike of the Wachusett Reservoir.</p>
-
-<p>This third design contemplates a compound structure, formed by two
-rock-fill dams situated about 2,120 ft. apart, with the intervening
-space filled with loose rock, earth and other available material.
-Immediately below the upper and higher rock-fill dam, it is proposed
-to place across the canyon a puddle wall 50 ft. in width, resting over
-two lines of sheet-piling 30 ft. apart. This piling would probably not
-reach farther than 50 ft. below tidewater, the solid rock floor being
-about 100 ft. deeper.</p>
-
-<p>Mr. Morison made use of Mr. Hazen’s filtration formula for estimating
-the rate and quantity of seepage through the permeable strata below the
-dam. This formula is:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0"
-summary="Filtration Formula" cellpadding="0" >
-  <tbody><tr>
-      <td class="tdc" colspan="2">&nbsp;</td>
-      <td class="tdl_ws1">&nbsp;h</td>
-      <td class="tdl_ws1">t + 10°</td>
-   </tr><tr>
-      <td class="tdl">V =</td>
-      <td class="tdl_ws1">cd²</td>
-      <td class="tdl_ws1">&mdash;</td>
-      <td class="tdc">&mdash;&mdash;</td>
-   </tr><tr>
-      <td class="tdc" colspan="2">&nbsp;</td>
-      <td class="tdl_ws1">&nbsp;l</td>
-      <td class="tdc">60</td>
-   </tr>
- </tbody>
-</table>
-
-<p class="no-indent">where</p>
-
-<ul class="index fontsize_120 no-wrap">
-<li class="isub2">V = rate of flow in meters per day through the whole section.</li>
-<li class="isub2">c = constant varying from 450 to 1,200,</li>
-<li class="isub4">according to cleanness of the sand.</li>
-<li class="isub2">d = “effective size” of sand in mm.</li>
-<li class="isub2">h = head in feet.</li>
-<li class="isub2">l = length or distance water must pass.</li>
-<li class="isub2">t = temperature of the water (Fahr.)</li>
-</ul>
-
-<p>This formula should be used only when the <i>effective sizes</i> of
-sands are from 0.10 to 3.0 mm. and with <i>uniformity coefficients</i>
-below 5.0<a id="FNanchor_5" href="#Footnote_5" class="fnanchor">[5]</a>.</p>
-
-<p><span class="pagenum" id="Page_57">[Pg 57]</span>
-Mr. Morison used the following values:</p>
-
-<ul class="index fontsize_120 no-wrap">
-<li class="isub2">c = 1,000;</li>
-<li class="isub2">d = 1.0 mm.;</li>
-<li class="isub2">h = 90 ft.;</li>
-<li class="isub2">l = 2,500 ft.;</li>
-<li class="isub2">t = 90°;</li>
-</ul>
-
-<p class="no-indent">for the solution of this problem, and obtained a
-velocity of 0.002 ft. per sec. The bed of sand and gravel was assumed
-to have a sectional area of 20,000 sq. ft. for 2,500 ft. in length.
-This gives a seepage of 40 cu. ft. per sec.</p>
-
-<p>It is believed that the above rate of 0.002 ft. per sec., equivalent to
-1⅜ ins. per minute, or 7 ft. per hour, is not sufficient to move any of
-the material. The velocity of water percolating through sand is found
-to vary directly as the head and inversely as the distance.</p>
-
-<p>The value of “c” in the formula is larger for sands of filters
-favorable for flow, and smaller for compacted materials and dams.</p>
-
-<p>Mr. Morison thought it might be nearer the actual conditions to assume
-d = 0.50 mm.; c = 500; and l = 5,000 ft.; in which case the seepage
-would only amount to 2.5 ft. per sec. In this last assumption the
-“effective size” of sand grains is 2½ times that classed as “permeable
-material” at the North Dike of the Wachusett Reservoir.</p>
-
-<p>Prof. Philipp Forchheimer, of Gratz, Austria, recommends the use of the
-formula,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0"
-summary="Filtration Formula" cellpadding="0" >
-  <tbody><tr>
-      <td class="tdc">&nbsp;h&nbsp;</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl_ws1">&mdash;&nbsp;=&nbsp;</td>
-      <td class="tdl">&nbsp;a√ + b√²</td>
-   </tr><tr>
-      <td class="tdc">l</td>
-      <td class="tdc">&nbsp;</td>
-   </tr>
- </tbody>
-</table>
-
-<p class="no-indent">for the percolation through soils between loam and
-loamy sand. Sellheim, Masoni, Smreker, Kröber and other authorities on
-filtration use still other formulas, to which the reader and student is
-referred for further research.</p>
-
-<p>The writer, having had occasion in his professional practice to study
-quite carefully the subject of ground waters, and their percolation
-or flow through different classes of materials and under varying
-conditions, is of the opinion that rarely does the cross-section of
-a stream-channel, filled with sand, gravel and debris, present, even
-approximately, a homogeneous or uniform mass; and that there are,
-almost without exception, strata of material much coarser and more
-porous than the general average. In other words, that it is extremely
-difficult to arrive at a uniformity coefficient. It is unwise to place
-much reliance upon an estimated flow where this is the case. The
-formula may be used with confidence where the layers are artificially
-made, and where there is no uncertainty regarding the uniform character
-of the material. In most natural channels there are distinct lines
-of flow, and under considerable hydrostatic head or pressure these
-lines of flow would surely enlarge. There is a wide difference between
-permissible and dangerously excessive percolation through an earth
-<span class="pagenum" id="Page_58">[Pg 58]</span>
-embankment. The local features, economical considerations and magnitude
-of the risks, all bear upon this question and must be considered for
-each particular case.</p>
-
-<p>It is of interest to compare the estimated cost of the three designs
-proposed for the Bohio Dam, based upon the same unit prices, as follows:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0"
-summary="Filtration Formula" cellpadding="0" >
-  <tbody><tr>
-      <td class="tdl">French Engineers’ design</td>
-      <td class="tdr">&nbsp;&nbsp;$3,500,000</td>
-   </tr><tr>
-      <td class="tdl">Isthmian Canal Commissioners’ design</td>
-      <td class="tdr">8,000,000</td>
-   </tr><tr>
-      <td class="tdl">Mr. Morison’s design</td>
-      <td class="tdr">2,500,000</td>
-   </tr>
- </tbody>
-</table>
-
-<p>No comments will be made upon these figures, further than to remark
-that the successful building of a stable dam, accomplished by the use
-of an excessive quantity of materials and at a cost beyond reasonable
-requirements, is mainly instructive as illustrating “how not to do it.”
-It is creditable to execute substantial works at a reasonable cost,
-but it reflects no credit upon any one to construct them regardless of
-expense.</p>
-
-<h3>Combined Rock-fill and Earth Dam.</h3>
-
-<p><a href="#FIG_30">Fig. 30</a> shows a section of the
-Upper Pecos River Dam near Eddy, N. M.</p>
-
-<p>This dam is quite fully described by Mr. Jas. D. Schuyler, in his
-recent book on “Reservoirs for Irrigation, Water-Power and Domestic
-Water-Supply,” and need not be mentioned in this paper, further than
-to call attention to the combination of rock-fill and earth which
-constitutes its particular type of construction. This type of dam is
-believed to be for many localities a very good one, but up to the present
-time has only been adopted for dams of moderate height, under 60 ft.</p>
-
-<h3>The San Leandro Dam, California.</h3>
-
-<p>A section of the San Leandro Dam, near Oakland, Cal., is shown by
-<a href="#FIG_31">Fig. 31</a>. This section was supplied by Mr. W. F.
-Boardman, hydraulic engineer, who superintended the construction of the
-dam, from his own private notes and data. It differs materially from
-sections heretofore published, and is 5 ft. higher, thus making it rank
-as the highest earth dam in the world of which we have an authentic record.</p>
-
-<p>The dam was commenced in 1874, and brought up to a height of 115 ft.
-above the bed of the creek in 1898. At the present time it is 500 ft.
-in length on the crest and 28 ft. wide. The original width of the
-ravine at the base of the dam was 66 ft. The present width of base
-from toe to toe of slopes is 1,700 ft. The height of embankment above
-the original surface is 125 ft., with a puddle trench extending 30 ft. below.
-<span class="pagenum" id="Page_59">[Pg 59]</span></p>
-
-<div class="figcenter">
-  <img id="FIG_30" src="images/image059a.jpg" alt="" width="600" height="186" />
-  <p class="center space-below2">FIG. 30.–CROSS-SECTION OF UPPER PECOS RIVER DAM;<br />
-                                 COMBINED ROCK FILL AND EARTH.</p>
-  <img id="FIG_31" src="images/image059b.jpg" alt="" width="600" height="120" />
-  <p class="center space-below2">FIG. 31.–DEVELOPED SECTION OF SAN LEANDRO DAM.</p>
-</div>
-
-<p><span class="pagenum" id="Page_60">[Pg 60]</span>
-All that portion of the dam within a slope of 2½ on 1 at the rear and
-3 on 1 at the face is built of choice material, carefully selected
-and put in with great care. The portion outside of the 2½ on 1 slope
-line at the down-stream side of the dam, was <i>sluice in</i> from the
-adjacent hills regardless of its character, and is composed of ordinary
-soil containing more or less rock.</p>
-
-<p>This process of sluicing was carried on during the rainy season, when
-there was an abundance of water, and it was intended to be continued
-until the canyon below the dam had been filled to an average slope of
-6.7 on 1 at the rear of the dam. It was thought that the location was
-particularly favorable for this kind of construction, the original
-intention being to raise the dam from time to time, not only to
-increase the storage as the demand for water increased, but to meet
-the annual loss in capacity caused by the silting up of the reservoir
-basin. The latter has amounted to about 1 ft. in depth per annum.</p>
-
-<p>METHOD OF CONSTRUCTION.–Under the main body of the dam, the surface
-was stripped of all sediment, sand, gravel and vegetable matter. Choice
-material, carefully selected, was then brought by carts and wagons and
-evenly distributed over the surface in layers about 1 ft. or less in
-thickness. This was sprinkled with just enough water to make it pack
-well, not enough to make it like mud. During construction a band of
-horses was led by a boy on horseback over the entire work, to compact
-the materials and assist in making the dam one homogeneous mass. No
-rollers were used on this dam.</p>
-
-<p>The central trench was cut 30 ft. below the original bed of the creek.
-In the bottom of this trench three secondary trenches, 3 ft. wide by 3
-ft. deep, were made and filled with concrete. These concrete walls were
-carried up 2 ft. above the general floor of the trench, to break the
-continuity of its surface.</p>
-
-<p>The original wasteway, constructed at the north end of the dam, has
-been practically abandoned, having been substituted by a tunnel of
-larger capacity. The original wasteway was excavated in the bed rock
-of the natural hillside, and although lined with masonry, is not in
-the best condition. The author considers its location an objectionable
-feature, as menacing the safety of the dam, and thinks it should be
-permanently closed.
-<span class="pagenum" id="Page_61">[Pg 61]</span></p>
-
-<p>A wasteway tunnel, 1,487 ft. in length, was constructed in 1888,
-through a ridge extending north of the dam. This has a sectional area
-of about 10×10 ft., lined with brick masonry throughout, having a grade
-of 2½%.</p>
-
-<p>The criticism might be made of the tunnel that it is faulty in design
-at the entry or reservoir end, where the water must first fall over
-a high spillway wall, aerating the water before entering the tunnel
-proper. The water even then has not easy access to the tunnel, and no
-adequate arrangements have been made for ventilation, so as to insure
-the utilization of its maximum capacity. The maximum depth of water in
-the reservoir is about 85 ft., and the full capacity 689,000,000 cu.
-ft. of water. The catchment area is 43 square miles, and the surface
-of the reservoir when full 436 acres. The outlet pipes are placed in
-two tunnels at different elevations through the ridge north of the dam.
-There are no culverts or pipes extending through the body of the dam itself.</p>
-
-<h3>Hydraulic-fill Dams.</h3>
-
-<p>No discussion of earth dams would be complete without some reference
-being made to the novel type of construction developed in western
-America in recent years, by which railroad embankments and water-tight
-dams are built up by the sole agency of water. The water for this
-purpose is usually delivered under high pressure, as it is generally
-convenient to make it first perform the work of loosening the earth
-and rock in the borrow pit, as well as subsequently to transport them
-to the embankment, and there to sort and deposit them and finally part
-company with them after compacting them solidly in place, even more
-firmly than if compressed by heavy rollers. Sometimes, however, water
-is delivered to the borrow pit without pressure, in which event the
-materials must be loosened by the plow or by pick and shovel by the
-process called ground sluicing in placer mining parlance.</p>
-
-<p>An abundance of water delivered by gravity under high pressure is
-usually regarded as one of the essential factors in hydraulic-fill dam
-building, but it is not essential that there be a large continuous
-flow. The Lake Frances Dam, recently constructed for the Bay Counties
-Co., of California, by J. D. Schuyler, is 75 ft. high, 1,340 ft. long
-on top, and contains 280,000 cu. yds. The dam was built up by materials
-sluiced by water that was forced by a centrifugal pump through a 12-in.
-pipe and 3-in. nozzle, against a high bank, whence the materials were
-torn and conveyed by the water through flumes and pipes to the dam.
-<span class="pagenum" id="Page_62">[Pg 62]</span>
-About 6 cu. ft. per sec. of water was thus used, and at one stage of
-the work the supply stream was reduced to less than 0.1 ft. per sec.,
-the water being gathered in a pond and pumped over and over again.</p>
-
-<p>The chapter on hydraulic-fill dams in Mr. Schuyler’s book on
-“Reservoirs for Irrigation” will be found to contain matter on the
-subject interesting to those who desire to pursue it further, and the
-reader is again referred to that work.</p>
-
-<h3>An Impervious Diaphragm in Earth Dams.</h3>
-
-<p>As a result of the recent extended discussion concerning the design
-of the New Croton Dam and the Jerome Park Reservoir embankments,
-the Engineering News of Feb. 20, 1902, contained a very suggestive
-editorial entitled, “Concerning the Design of Earth Dams and Reservoir
-Embankments.” The opinion is given that no type of structure that man
-builds to confine water can compare in permanence with earth dams,
-after which the following pertinent questions are asked:</p>
-
-<div class="blockquot">
-<p>1. How shall an earth dam be made water-tight?</p>
-
-<p>2. What is the office and purpose of the masonry core wall?</p>
-
-<p>3. Would not a water-proof diaphragm of some kind be better
-than a core wall of either masonry or puddle?</p>
-</div>
-
-<p>The article then suggests a number of designs of diaphragm
-construction, with a special view of obtaining absolute
-water-tightness, by use of asphaltum, cement mortar, steel plates, etc.
-Special emphasis was put upon the <i>principle</i> of constructing
-a water-proof diaphragm. The matter of relative cost is advanced as
-an argument in favor of the diaphragm principle as against the usual
-orthodox method. The saving in cost is to be accomplished by the use of
-inferior materials and less care in the handling of them, or by both.
-It is suggested that almost any kind of material available, rock, sand
-or gravel, will answer every purpose where good earth is not to be
-found. Further, that this material may be dumped from the carts, cars
-or cableways, or be placed by the hydraulic-fill method.</p>
-
-<p>The writer believes the diaphragm method of construction may have some
-merits, but that it is attended by the very great risk of neglecting
-principles most vitally important to the successful construction of
-high earth dams, which will now be formulated and advanced, as follows:</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_63">[Pg 63]</span></p>
-<h2 class="nobreak">CHAPTER VI.<br />
-<span class="h_subtitle"><i>Conclusions.</i></span></h2>
-</div>
-
-<p>The writer in concluding this study wishes to emphasize certain
-principles and apparently minor details of construction, which from
-observation and personal experience, seem to him of vital importance.</p>
-
-<p>He believes firmly in the truth contained in the following remarks by
-Mr. Desmond FitzGerald, of Boston, germane to this subject:</p>
-
-<p class="blockquot">An engineer must be guided by local conditions and
-the resources at his command in building reservoir embankments. His
-design must be largely affected by the nature of the materials. There
-are certain <i>general principles</i>, however, which must be observed
-and which will be applied by an engineer of skill, judgment and
-experience to whatever design he may adopt. It is in the application
-of these principles that the services of the professional man becomes
-valuable, and it is from a lack of them, that there have been so many
-failures.</p>
-
-<p>The details and principles of construction, relating to high earth
-dams, may be summarized or stated in order of their application, as
-follows:</p>
-
-<p>(1) Select a firm, dry, impermeable foundation, or make it so by
-excavation and drainage. All alluvial soil containing organic matter
-and all porous materials should be excavated and removed from the
-dam site when practicable; that is, where the depth to a suitable
-impermeable foundation is not prohibitive by reason of excessive cost.</p>
-
-<p>Wherever springs of water appear, they must be carried outside the
-lines of the embankment by means of bed rock drains, or a system of
-pipes so laid and embedded as to be permanent and effective.</p>
-
-<p>The drainage system must be so designed as to prevent the infiltration
-of water upward and into the lower half of the embankment, and at the
-same time insure free and speedy outlet for any seepage water passing
-the upper half. All drains should be placed upon bed rock or in the
-natural formation selected for the foundation of the superstructure.
-They should be constructed in such a manner as to prevent the flow
-of water outside the channel provided for it, and also prevent any
-<span class="pagenum" id="Page_64">[Pg 64]</span>
-enlargement of the channel itself. To this end, cement, mortar, broken
-stone, and good gravel puddle are the materials best suited for this
-purpose.</p>
-
-<p>(2) Unite the body of the embankment to the natural foundation by means
-of an impervious material, durable and yet sufficiently elastic to bond
-the two together. When the depth to a suitable foundation is great,
-a central trench excavated with sloping sides, extending to bed rock
-or other impervious formation, refilled with good puddling material,
-properly compacted, will suffice.</p>
-
-<p>When clayey earth is scarce and expensive to obtain, a small amount of
-clay puddle confined between walls of brick, stone or concrete masonry,
-and extending well into the body of the embankment and so built as
-to avoid settlement, will prevent excessive seepage. This form of
-construction is not to be carried much above the original surface of
-the ground.</p>
-
-<p>(3) The continuity of surfaces should always be broken, at the same
-time avoiding the formation of cavities and lines of cleavage. No
-excavation to be refilled should have vertical sides, and long
-continuous horizontal planes should be intercepted by wedge-shaped
-offsets, enabling the dovetailing of materials together.</p>
-
-<p>All loose and seamy rock or other porous material should be removed,
-and where the refill is not the best for the purpose, mix the good and
-bad ingredients thoroughly, after which deposit in very thin layers.</p>
-
-<p>(4) Make the dimensions and profile of dam with a factor of safety
-against sliding of not less than ten. The preliminary calculations for
-designing such a profile have been given on <a href="#Page_42">p. 42</a>.</p>
-
-<p>(5) Aim at as nearly a homogeneous mass in the body of the embankment
-as possible, thus avoiding unequal settlement and deformation. This
-manner of manipulating materials will eliminate many uncertain or
-unknown factors, but it means rigid inspection of the work and
-intelligent segregation of materials, no matter what method of
-transporting them may be adopted. The smaller the unit loads may
-be, the more easily a homogeneous distribution of materials will be
-obtained.</p>
-
-<p id ="SECT_6">(6) Select earthy materials in preference to organic
-soils, with a view of such combination or proportion of different
-materials as will readily consolidate. <i>Consolidation is the most
-important process connected with the building of an earth dam.</i> The
-judicious use of soil containing a small percentage of organic matter
-may be permitted, however, when there is a lack of clayey material for
-<span class="pagenum" id="Page_65">[Pg 65]</span>
-mixing with sandy and porous earth materials. Such a mixture, properly
-distributed and wetted, will consolidate well under heavy pressure and
-prove quite satisfactory.</p>
-
-<p>(7) Consolidation being the most important process and the only
-safeguard against permeability and instability of form, use only the
-amount of water necessary to attain this. Too much or too little are
-equally bad and to be avoided. It is believed that only by experiment
-and experience is it possible to determine just the proper quantity of
-water to use with the different classes of materials and their varying
-conditions. In rolling and consolidating the bank, all portions that
-have a tendency to quake must be removed at once and replaced with
-material that will consolidate; it <i>must not</i> be covered up, no
-matter how small the area.</p>
-
-<p>(8) In an artificial embankment for impounding water it is
-impracticable to place reliance upon time for consolidation; it
-<i>must</i> be effected by mechanical means. Again we repeat, that
-consolidation is the most vitally important operation connected with
-the building of an earth dam. When this is satisfactorily attained it
-is proof that the materials are suitable and that the other necessary
-details have been in a large measure complied with. Light rollers are
-worse than useless, being a positive harm, resulting in a smoothing or
-“ironing process,” deceptive in appearance and detrimental in many ways.</p>
-
-<p>The matter of supreme importance in the construction of earth dams is
-that the greatest consolidation possible be specified and effected.
-To this end it is necessary that heavy rollers be employed, and that
-such materials be selected as respond best to the treatment. There are
-certain kinds of earth materials which no amount of wetting and rolling
-will compact. These must be rejected as unfit for use in any portion
-of an earth dam. Let the design of the structure be ever so true to
-correct engineering principles, it is still necessary to give untiring
-attention to the work of consolidation. It is therefore according to
-the design of a thoroughly compacted homogeneous mass, rather than
-to the suggested <i>diaphragm type</i>, to which modern practice
-should conform. This is in harmony with Nature’s own methods, and in
-conformity to correct principles.</p>
-
-<p>(9) Avoid placing pipes or culverts through any portion of the
-embankment. The writer considers it bad practice ever to place the
-outlet pipes through a high earth dam, and fails to see any necessity
-for so doing.
-<span class="pagenum" id="Page_66">[Pg 66]</span></p>
-
-<p>(10) The surface of the dam, both front and rear, must be suitably
-protected against the deteriorating effects of the elements. This may
-include pitching the up-stream face, the riprap work at the toe of the
-inner slope, the roadway and covering of the crown, the sodding or
-other protection of the rear slope, and the construction of surface
-drains for the berms.</p>
-
-<p>(11) Ample provision for automatic wasteways should be made for
-every dam, so that the embankment can never under any circumstances
-be over-topped by the impounded water. Earthquakes and seismic
-disturbances will produce no disastrous effects upon an earth dam.
-Its elasticity will resist the shock of water lashing backwards and
-forwards in the reservoir.</p>
-
-<p>(12) Finally, provide for intelligent and honest supervision during
-construction, and insist upon proper care and maintenance ever
-afterwards.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h2 class="nobreak" id="APPENDIX_I">APPENDIX I.<br />
-<span class="h_subtitle">High Earth Dams.</span></h2>
-</div>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0"
-summary="High Earth Dams." cellpadding="0" >
-  <thead><tr>
-      <th class="tdc">&nbsp;</th>
-      <th class="tdc">&nbsp;</th>
-      <th class="tdc" colspan="2">|–Embankment–|</th>
-      <th class="tdc" colspan="2">|–––  Slopes  –––|</th>
-      <th class="tdc bb" rowspan="3">Available<br />depths,<br />ft.</th>
-   </tr><tr>
-      <th class="tdc">Name of Dam<br />or Reservoir.</th>
-      <th class="tdc">Location.</th>
-      <th class="tdc">Max.<br />height,</th>
-      <th class="tdc">Top<br />width,</th>
-      <th class="tdc">Water.</th>
-      <th class="tdc">Bear.</th>
-   </tr><tr>
-      <th class="tdc bb" colspan="2">&nbsp;</th>
-      <th class="tdc bb">ft.</th>
-      <th class="tdc bb">ft.</th>
-      <th class="tdc bb" colspan="2">&nbsp;</th>
-   </tr>
-  </thead>
-  <tbody><tr>
-      <td class="tdl">San Leandro</td>
-      <td class="tdl_ws1">California</td>
-      <td class="tdr_ws1">125</td>
-      <td class="tdr_ws1">28</td>
-      <td class="tdr_ws1">&nbsp;</td>
-      <td class="tdr_ws1">&nbsp;</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Tabeaud</td>
-      <td class="tdl_ws1">California</td>
-      <td class="tdr_ws1">123</td>
-      <td class="tdr_ws1">20</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2½ on 1</td>
-      <td class="tdc">70</td>
-   </tr><tr>
-      <td class="tdl">Druid Hill</td>
-      <td class="tdl_ws1">Maryland</td>
-      <td class="tdr_ws1">119</td>
-      <td class="tdr_ws1">60</td>
-      <td class="tdr_ws1">4  on 1</td>
-      <td class="tdr_ws1">2  on 1</td>
-      <td class="tdc">82</td>
-   </tr><tr>
-      <td class="tdl">Dodder</td>
-      <td class="tdl_ws1">Ireland</td>
-      <td class="tdr_ws1">115</td>
-      <td class="tdr_ws1">22</td>
-      <td class="tdr_ws1">3½ on 1</td>
-      <td class="tdr_ws1">3   on 1</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Titicus Dam</td>
-      <td class="tdl_ws1">New York</td>
-      <td class="tdr_ws1">110</td>
-      <td class="tdr_ws1">30</td>
-      <td class="tdr_ws1">2  on 1</td>
-      <td class="tdr_ws1">2½ on 1</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Mudduk Tank</td>
-      <td class="tdl_ws1">India</td>
-      <td class="tdr_ws1">108</td>
-      <td class="tdr_ws1">&nbsp;</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2½ on 1</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Cummum Tank</td>
-      <td class="tdl_ws1">India</td>
-      <td class="tdr_ws1">102</td>
-      <td class="tdr_ws1">&nbsp;</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">1  on 1</td>
-      <td class="tdc">90</td>
-   </tr><tr>
-      <td class="tdl">Dale Dike</td>
-      <td class="tdl_ws1">England</td>
-      <td class="tdr_ws1">102</td>
-      <td class="tdr_ws1">12</td>
-      <td class="tdr_ws1">2½ on 1</td>
-      <td class="tdr_ws1">2½ on 1</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Marengo</td>
-      <td class="tdl_ws1">Algeria</td>
-      <td class="tdr_ws1">101</td>
-      <td class="tdc" colspan="4">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Torside</td>
-      <td class="tdl_ws1">England</td>
-      <td class="tdr_ws1">100</td>
-      <td class="tdc" colspan="3">&nbsp;</td>
-      <td class="tdc">84</td>
-   </tr><tr>
-      <td class="tdl">Yarrow</td>
-      <td class="tdl_ws1">England</td>
-      <td class="tdr_ws1">100</td>
-      <td class="tdr_ws1">24</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2  on 1</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Honey Lake</td>
-      <td class="tdl_ws1">California</td>
-      <td class="tdr_ws1">96</td>
-      <td class="tdr_ws1">20</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2  on 1</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Pilarcitos</td>
-      <td class="tdl_ws1">California</td>
-      <td class="tdr_ws1">95</td>
-      <td class="tdr_ws1">25</td>
-      <td class="tdr_ws1">2¾ on 1</td>
-      <td class="tdr_ws1">2½ on 1</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">San Andres</td>
-      <td class="tdl_ws1">California</td>
-      <td class="tdr_ws1">95</td>
-      <td class="tdr_ws1">25</td>
-      <td class="tdr_ws1">3½ on 1</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Temescal</td>
-      <td class="tdl_ws1">California</td>
-      <td class="tdr_ws1">95</td>
-      <td class="tdr_ws1">12</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2  on 1</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Waghad</td>
-      <td class="tdl_ws1">India</td>
-      <td class="tdr_ws1">95</td>
-      <td class="tdr_ws1">6</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2  on 1</td>
-      <td class="tdc">81</td>
-   </tr><tr>
-      <td class="tdl">Bradfield</td>
-      <td class="tdl_ws1">England</td>
-      <td class="tdr_ws1">95</td>
-      <td class="tdr_ws1">12</td>
-      <td class="tdr_ws1">2½ on 1</td>
-      <td class="tdr_ws1">2½ on 1</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Oued Menrad</td>
-      <td class="tdl_ws1">Algeria</td>
-      <td class="tdr_ws1">95</td>
-      <td class="tdc" colspan="4">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">St. Andrews</td>
-      <td class="tdl_ws1">Ireland</td>
-      <td class="tdr_ws1">93</td>
-      <td class="tdr_ws1">25</td>
-      <td class="tdc" colspan="3">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Edgelaw</td>
-      <td class="tdl_ws1">Scotland</td>
-      <td class="tdr_ws1">93</td>
-      <td class="tdr_ws1">&nbsp;</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2½ on 1</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Woodhead</td>
-      <td class="tdl_ws1">England</td>
-      <td class="tdr_ws1">90</td>
-      <td class="tdc" colspan="3">&nbsp;</td>
-      <td class="tdc">72</td>
-   </tr><tr>
-      <td class="tdl">Tordoff</td>
-      <td class="tdl_ws1">Scotland</td>
-      <td class="tdr_ws1">85</td>
-      <td class="tdr_ws1">10</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2½ on 1</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Naggar</td>
-      <td class="tdl_ws1">India</td>
-      <td class="tdr_ws1">84</td>
-      <td class="tdc" colspan="4">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Vahar</td>
-      <td class="tdl_ws1">India</td>
-      <td class="tdr_ws1">84</td>
-      <td class="tdr_ws1">24</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2½ on 1</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Rosebery</td>
-      <td class="tdl_ws1">Scotland</td>
-      <td class="tdr_ws1">84</td>
-      <td class="tdc" colspan="4">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Atlanta</td>
-      <td class="tdl_ws1">Georgia</td>
-      <td class="tdr_ws1">82</td>
-      <td class="tdr_ws1">40</td>
-      <td class="tdc" colspan="3">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Roddlesworth</td>
-      <td class="tdl_ws1">England</td>
-      <td class="tdr_ws1">80</td>
-      <td class="tdr_ws1">16</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2½ on 1</td>
-      <td class="tdc">68</td>
-   </tr><tr>
-      <td class="tdl">Gladhouse</td>
-      <td class="tdl_ws1">Scotland</td>
-      <td class="tdr_ws1">79</td>
-      <td class="tdr_ws1">12</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2½ on 1</td>
-      <td class="tdc">&nbsp;&nbsp;68½</td>
-   </tr><tr>
-      <td class="tdl">Rake</td>
-      <td class="tdl_ws1">England</td>
-      <td class="tdr_ws1">78</td>
-      <td class="tdr_ws1">&nbsp;</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2  on 1</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Silsden</td>
-      <td class="tdl_ws1">England</td>
-      <td class="tdr_ws1">78</td>
-      <td class="tdr_ws1">&nbsp;</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2  on 1</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Glencourse</td>
-      <td class="tdl_ws1">Scotland</td>
-      <td class="tdr_ws1">77</td>
-      <td class="tdr_ws1">&nbsp;</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">&nbsp;</td>
-      <td class="tdc">58</td>
-   </tr><tr>
-      <td class="tdl">Leeshaw</td>
-      <td class="tdl_ws1">England</td>
-      <td class="tdr_ws1">77</td>
-      <td class="tdc" colspan="4">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Wayoh</td>
-      <td class="tdl_ws1">England</td>
-      <td class="tdr_ws1">76</td>
-      <td class="tdr_ws1">22</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2½ on 1</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Ekruk Tank</td>
-      <td class="tdl_ws1">India</td>
-      <td class="tdr_ws1">76</td>
-      <td class="tdr_ws1">20</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2  on 1</td>
-      <td class="tdc">65</td>
-   </tr><tr>
-      <td class="tdl">Nehr</td>
-      <td class="tdl_ws1">India</td>
-      <td class="tdr_ws1">74</td>
-      <td class="tdr_ws1">8</td>
-      <td class="tdc" colspan="3">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Middle Branch</td>
-      <td class="tdl_ws1">New York</td>
-      <td class="tdr_ws1">73</td>
-      <td class="tdc" colspan="4">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Leeming</td>
-      <td class="tdl_ws1">Ireland</td>
-      <td class="tdr_ws1">73</td>
-      <td class="tdr_ws1">10</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2  on 1</td>
-      <td class="tdc">50</td>
-   </tr><tr>
-      <td class="tdl">South Fork</td>
-      <td class="tdl_ws1">Penna.</td>
-      <td class="tdr_ws1">72</td>
-      <td class="tdr_ws1">20</td>
-      <td class="tdr_ws1">2  on 1</td>
-      <td class="tdr_ws1">1½ on 1</td>
-      <td class="tdc">50</td>
-   </tr><tr>
-      <td class="tdl">Anasagur</td>
-      <td class="tdl_ws1">India</td>
-      <td class="tdr_ws1">70</td>
-      <td class="tdr_ws1">20</td>
-      <td class="tdr_ws1">4  on 1</td>
-      <td class="tdc" colspan="2">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Pangran</td>
-      <td class="tdl_ws1">India</td>
-      <td class="tdr_ws1">68</td>
-      <td class="tdr_ws1">8</td>
-      <td class="tdc" colspan="2">&nbsp;</td>
-      <td class="tdc">42</td>
-   </tr><tr>
-      <td class="tdl">Harlaw</td>
-      <td class="tdl_ws1">Scotland</td>
-      <td class="tdr_ws1">67</td>
-      <td class="tdc" colspan="3">&nbsp;</td>
-      <td class="tdc">64</td>
-   </tr><tr>
-      <td class="tdl">Lough Vartry</td>
-      <td class="tdl_ws1">Ireland</td>
-      <td class="tdr_ws1">66</td>
-      <td class="tdr_ws1">28</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2½ on 1</td>
-      <td class="tdc">60</td>
-   </tr><tr>
-      <td class="tdl">La Mesa</td>
-      <td class="tdl_ws1">California</td>
-      <td class="tdr_ws1">66</td>
-      <td class="tdr_ws1">20</td>
-      <td class="tdr_ws1">1½ on 1</td>
-      <td class="tdr_ws1">1½ on 1</td>
-      <td class="tdc">60</td>
-   </tr><tr>
-      <td class="tdl">Amsterdam</td>
-      <td class="tdl_ws1">New York</td>
-      <td class="tdr_ws1">65</td>
-      <td class="tdc" colspan="4">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Mukti</td>
-      <td class="tdl_ws1">India</td>
-      <td class="tdr_ws1">65</td>
-      <td class="tdr_ws1">10</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2  on 1</td>
-      <td class="tdc">41</td>
-   </tr><tr>
-      <td class="tdl">Snake River</td>
-      <td class="tdl_ws1">California</td>
-      <td class="tdr_ws1">64</td>
-      <td class="tdr_ws1">12</td>
-      <td class="tdr_ws1">2  on 1</td>
-      <td class="tdr_ws1">1½ on 1</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Stubken</td>
-      <td class="tdl_ws1">Ireland</td>
-      <td class="tdr_ws1">63</td>
-      <td class="tdr_ws1">24</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2  on 1</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">Den of Ogil</td>
-      <td class="tdl_ws1">Scotland</td>
-      <td class="tdr_ws1">60</td>
-      <td class="tdc" colspan="3">&nbsp;</td>
-      <td class="tdc">50</td>
-   </tr><tr>
-      <td class="tdl">Loganlea</td>
-      <td class="tdl_ws1">Scotland</td>
-      <td class="tdr_ws1">59</td>
-      <td class="tdr_ws1">10</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2½ on 1</td>
-      <td class="tdc">55</td>
-   </tr><tr>
-      <td class="tdl">Ashti</td>
-      <td class="tdl_ws1">India</td>
-      <td class="tdr_ws1">58</td>
-      <td class="tdr_ws1">6</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2  on 1</td>
-      <td class="tdc">42</td>
-   </tr><tr>
-      <td class="tdl">Cedar Grove</td>
-      <td class="tdl_ws1">New Jersey</td>
-      <td class="tdr_ws1">55</td>
-      <td class="tdr_ws1">18</td>
-      <td class="tdr_ws1">3  on 1</td>
-      <td class="tdr_ws1">2  on 1</td>
-      <td class="tdc">50</td>
-   </tr>
- </tbody>
-</table>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h2 class="nobreak" id="APPENDIX_II">APPENDIX–II.<br />
-<span class="h_subtitle">Works of Reference.</span></h2>
-</div>
-
-<table class="no-wrap" border="0" cellspacing="0"
-summary="References." cellpadding="0" >
-  <thead><tr>
-      <th class="tdc bb">Author.</th>
-      <th class="tdc bb">Title.</th>
-      <th class="tdc bb">&nbsp;&nbsp;Date.</th>
-   </tr>
-  </thead>
-  <tbody><tr>
-      <td class="tdl">Baker, Benj.</td>
-      <td class="tdl_ws1">The Actual Lateral Pressure of Earthwork</td>
-      <td class="tdc">1881</td>
-   </tr><tr>
-      <td class="tdl">Baker, Ira O.</td>
-      <td class="tdl_ws1">Treatise on Masonry Construction</td>
-      <td class="tdc">1899</td>
-   </tr><tr>
-      <td class="tdl">Bell, Thos. J.</td>
-      <td class="tdl_ws1">History of the Water Supply of the World</td>
-      <td class="tdc">1882</td>
-   </tr><tr>
-      <td class="tdl">Beloe, Chas. H.</td>
-      <td class="tdl_ws1">Beloe on Reservoirs</td>
-      <td class="tdc">1872</td>
-   </tr><tr>
-      <td class="tdl">Bowie, Aug. J., Jr.</td>
-      <td class="tdl_ws1">A Practical Treatise on Hydraulic Mining</td>
-      <td class="tdc">1898</td>
-   </tr><tr>
-      <td class="tdl">Brant, Wm. J.</td>
-      <td class="tdl_ws1">Scientific Examination of Soils</td>
-      <td class="tdc">1892</td>
-   </tr><tr>
-      <td class="tdl">Brightmore, A. M.</td>
-      <td class="tdl_ws1">The Principles of Water-Works Engineering</td>
-      <td class="tdc">1893</td>
-   </tr><tr>
-      <td class="tdl">Buckley, Robt. B.</td>
-      <td class="tdl_ws1">Irrigation Works in India and Egypt</td>
-      <td class="tdc">1893</td>
-   </tr><tr>
-      <td class="tdl">Cain, Wm.</td>
-      <td class="tdl_ws1">Retaining Walls</td>
-      <td class="tdc">1888</td>
-   </tr><tr>
-      <td class="tdl">Chittenden, H. M.</td>
-      <td class="tdl_ws1">Report and Examination of Reservoir Sites</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">&nbsp;</td>
-      <td class="tdl_ws1">&nbsp;&emsp;in Wyoming and Colorado</td>
-      <td class="tdc">1898</td>
-   </tr><tr>
-      <td class="tdl">Courtney, C. F.</td>
-      <td class="tdl_ws1">Masonry Dams</td>
-      <td class="tdc">1897</td>
-   </tr><tr>
-      <td class="tdl">Fanning, J. T.</td>
-      <td class="tdl_ws1">Water-Supply Engineering</td>
-      <td class="tdc">1889</td>
-   </tr><tr>
-      <td class="tdl">Flynn, P. J.</td>
-      <td class="tdl_ws1">Irrigation Canals and Other Irrigation Works</td>
-      <td class="tdc">1892</td>
-   </tr><tr>
-      <td class="tdl">Frizell, Jos. P.</td>
-      <td class="tdl_ws1">Water Power</td>
-      <td class="tdc">1891</td>
-   </tr><tr>
-      <td class="tdl">Gordon, H. A.</td>
-      <td class="tdl_ws1">Mining and Mining Engineering</td>
-      <td class="tdc">1894</td>
-   </tr><tr>
-      <td class="tdl">Gould, E. S.</td>
-      <td class="tdl_ws1">The Elements of Water-Supply Engineering</td>
-      <td class="tdc">1899</td>
-   </tr><tr>
-      <td class="tdl">Hall, Wm. Ham.</td>
-      <td class="tdl_ws1">Irrigation in California</td>
-      <td class="tdc">1888</td>
-   </tr><tr>
-      <td class="tdl">Hazen, Allen</td>
-      <td class="tdl_ws1">The Filtration of Public Water Supplies</td>
-      <td class="tdc">1895</td>
-   </tr><tr>
-      <td class="tdl">Howe, M. A.</td>
-      <td class="tdl_ws1">Retaining Walls for Earth</td>
-      <td class="tdc">1891</td>
-   </tr><tr>
-      <td class="tdl">Hughes, Saml.</td>
-      <td class="tdl_ws1">Treatise on Water-Works</td>
-      <td class="tdc">1856</td>
-   </tr><tr>
-      <td class="tdl">Jackson, L. D. A.</td>
-      <td class="tdl_ws1">Statistics of Hydraulic Works</td>
-      <td class="tdc">1885</td>
-   </tr><tr>
-      <td class="tdl">Kirkwood, J. P.</td>
-      <td class="tdl_ws1">Filtration of River Waters</td>
-      <td class="tdc">1869</td>
-   </tr><tr>
-      <td class="tdl">Merriman, M.</td>
-      <td class="tdl_ws1">Treatise on Hydraulics, Masonry Dams</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">&nbsp;</td>
-      <td class="tdl_ws1">&nbsp;&emsp;and Retaining Walls</td>
-      <td class="tdc">1892</td>
-   </tr><tr>
-      <td class="tdl">Newell, F. H.</td>
-      <td class="tdl_ws1">Irrigation in the United States</td>
-      <td class="tdc">1902</td>
-   </tr><tr>
-      <td class="tdl">Newman, John</td>
-      <td class="tdl_ws1">Earthwork Slips and Subsidences Upon</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">&nbsp;</td>
-      <td class="tdl_ws1">&nbsp;&emsp;Public Works</td>
-      <td class="tdc">1890</td>
-   </tr><tr>
-      <td class="tdl">Potter, Thomas</td>
-      <td class="tdl_ws1">Concrete</td>
-      <td class="tdc">1894</td>
-   </tr><tr>
-      <td class="tdl">Schuyler, J. D.</td>
-      <td class="tdl_ws1">Reservoirs for Irrigation, Water Power</td>
-      <td class="tdc">&nbsp;</td>
-   </tr><tr>
-      <td class="tdl">&nbsp;</td>
-      <td class="tdl_ws1">&nbsp;&emsp;and Domestic Water Supply</td>
-      <td class="tdc">1901</td>
-   </tr><tr>
-      <td class="tdl">Slagg, Chas.</td>
-      <td class="tdl_ws1">Water Engineering</td>
-      <td class="tdc">1888</td>
-   </tr><tr>
-      <td class="tdl">Stearns, F. P.</td>
-      <td class="tdl_ws1">Metropolitan Water-Works Reports</td>
-      <td class="tdc">1897</td>
-   </tr><tr>
-      <td class="tdl">Stockbridge, H. E.</td>
-      <td class="tdl_ws1">Rocks and Soils</td>
-      <td class="tdc">1888</td>
-   </tr><tr>
-      <td class="tdl">Trautwine, J. C.</td>
-      <td class="tdl_ws1">Earthwork; and Engineer’s Pocket-Book</td>
-      <td class="tdc">1890</td>
-   </tr><tr>
-      <td class="tdl">Turner, J. H. T.</td>
-      <td class="tdl_ws1">The Principles of Water-Works Engineering</td>
-      <td class="tdc">1893</td>
-   </tr><tr>
-      <td class="tdl">Wilson, J. M.</td>
-      <td class="tdl_ws1">Manual of Irrigation Engineering</td>
-      <td class="tdc">1893</td>
-   </tr>
- </tbody>
-</table>
-
-<p class="f150 space-above2"><b>Annual Reports.</b></p>
-
-<ul class="index no-wrap">
-<li class="isub2">Massachusetts State Board of Health.</li>
-<li class="isub2">Geological Survey of New Jersey.</li>
-<li class="isub2">Metropolitan Water-Works, Boston and vicinity.</li>
-<li class="isub2">U. S. Geological Survey.</li>
-<li class="isub2">Transactions American Society of Civil Engineers.</li>
-<li class="isub4">Vols. 3, 15, 24, 32, 34 and 35.</li>
-<li class="isub2">Proceedings of the Institution of Civil Engineers.</li>
-<li class="isub4">Vols. 59, 62, 65, 66, 71, 73, 74, 76, 80, 115 and 132.</li>
-<li class="isub2">Engineering News. Vols. 19 to 46.</li>
-<li class="isub2">Engineering Record. Vols. 23 to 46.</li>
-<li class="isub2">Journal of the Association Engineering Societies. Vol. 13.</li>
-</ul>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h2 class="nobreak" id="INDEX">INDEX.</h2>
-</div>
-
-<ul class="index">
-<li class="isub1">Analyses, soil, Tabeaud Dam, <a href="#Page_25">25</a></li>
-<li class="isub1">Analyses of soils, <a href="#Page_14">14</a></li>
-<li class="isub3">Tabeaud Dam, <a href="#Page_25">25</a></li>
-
-<li class="ifrst">Borings, wash drill, Wachusett Dam, <a href="#Page_48">48</a></li>
-
-<li class="ifrst">Catchment area, <a href="#Page_3">3</a></li>
-<li class="isub1">Clay for puddle, <a href="#Page_15">15</a></li>
-<li class="isub1">Contractors’ outfit, Tabeaud Dam, <a href="#Page_31">31</a></li>
-<li class="isub1">Core wall, impervious diaphragm as substitute for, <a href="#Page_62">62</a></li>
-<li class="isub3">necessity for, <a href="#Page_44">44</a></li>
-<li class="isub3">(See puddle.)</li>
-
-<li class="ifrst">Dam,</li>
-<li class="isub3">Ashti, India, <a href="#Page_35">35</a></li>
-<li class="isub3">Bog Brook, <a href="#Page_41">41</a></li>
-<li class="isub3">Bohio, Panama Canal, <a href="#Page_54">54</a></li>
-<li class="isub3">Croton Valley, slope of saturation in, <a href="#Page_40">40</a></li>
-<li class="isub3">different types of earth, <a href="#Page_33">33</a></li>
-<li class="isub3">Druid Lake, Baltimore, <a href="#Page_52">52</a></li>
-<li class="isub3">high earth, statistical table of, <a href="#APPENDIX_I">67</a></li>
-<li class="isub3">hydraulic-fill, <a href="#Page_61">61</a></li>
-<li class="isub3">hydraulic-fill, San Leandro, <a href="#Page_60">60</a></li>
-<li class="isub3">ideal profile of, <a href="#Page_42">42</a></li>
-<li class="isub3">Isthmian Canal Commission, <a href="#Page_54">54</a></li>
-<li class="isub3">Lake Frances hydraulic-fill, <a href="#Page_61">61</a></li>
-<li class="isub3">New Croton, <a href="#Page_39">39</a></li>
-<li class="isub5">graphical study of original earth portion of, <a href="#Page_43">43</a></li>
-<li class="isub3">New England, typical section of, <a href="#Page_40">40</a></li>
-<li class="isub3">new types of, <a href="#Page_54">54</a></li>
-<li class="isub3">North Dike, Wachusett Reservoir, <a href="#Page_48">48</a></li>
-<li class="isub3">rock-fill and earth combined, upper Pecos River, <a href="#Page_58">58</a></li>
-<li class="isub3">safe height of, <a href="#Page_39">39</a></li>
-<li class="isub3">San Leandro, <a href="#Page_58">58</a></li>
-<li class="isub3">site location, <a href="#Page_7">7</a></li>
-<li class="isub3">Tabeaud, <a href="#Page_13">13</a>, <a href="#Page_17">17</a></li>
-<li class="isub3">Titicus, <a href="#Page_41">41</a></li>
-<li class="isub3">Upper Pecos River rock-fill and earth, <a href="#Page_58">58</a></li>
-<li class="isub3">with puddle core wall or face, <a href="#Page_33">33</a></li>
-<li class="isub3">Yarrow, Liverpool water-works, <a href="#Page_9">9</a>, <a href="#Page_33">33</a></li>
-<li class="isub1">Diaphragms impervious for earth dams, <a href="#Page_62">62</a>, <a href="#Page_65">65</a></li>
-<li class="isub1">Dike, north of Wachusett Reservoir (see Dam; also reservoir)</li>
-<li class="isub1">Drainage and slips of earthwork, <a href="#Page_45">45</a></li>
-<li class="isub3">of dam sites, <a href="#Page_63">63</a></li>
-<li class="isub1">Drains, bed rock, Tabeaud Dam, <a href="#Page_19">19</a></li>
-
-<li class="ifrst">Earthwork slips and drainage, <a href="#Page_45">45</a></li>
-<li class="isub1">Embankment, Ashti, India, <a href="#Page_35">35</a></li>
-<li class="isub1">Embankments, Jerome Park Reservoir, <a href="#Page_45">45</a>, <a href="#Page_46">46</a></li>
-
-<li class="ifrst">Factor of safety for dams, <a href="#Page_64">64</a></li>
-<li class="isub1">Filtration, experiments on nitration through soils</li>
-<li class="isub3">at Wachusett Reservoir, <a href="#Page_50">50</a></li>
-<li class="isub3">formula, Hazen’s, <a href="#Page_56">56</a></li>
-<li class="isub1">Foundations, <a href="#Page_9">9</a>, <a href="#Page_63">63</a></li>
-
-<li class="ifrst">Gravel for puddle, <a href="#Page_15">15</a></li>
-
-<li class="ifrst">Infiltration and percolation, <a href="#Page_38">38</a></li>
-<li class="isub1">Isthmian Canal Commission, designs of dams for, <a href="#Page_54">54</a></li>
-
-<li class="ifrst">Outlet pipes and tunnels, <a href="#Page_6">6</a></li>
-
-<li class="ifrst">Percolation, <a href="#Page_38">38</a>, <a href="#Page_57">57</a></li>
-<li class="isub1">Profile, ideal for dams, <a href="#Page_42">42</a></li>
-<li class="isub1">Puddle, <a href="#Page_14">14</a></li>
-<li class="isub3">core wall, Ashti Dam, <a href="#Page_35">35</a></li>
-<li class="isub5">or face, <a href="#Page_33">33</a></li>
-<li class="isub3">trench, <a href="#Page_37">37</a></li>
-<li class="isub3">wall, Druid Lake Dam, <a href="#Page_53">53</a></li>
-<li class="isub5">for Yarrow Dam, <a href="#Page_34">34</a></li>
-<li class="isub5">vs. puddle face, <a href="#Page_37">37</a></li>
-
-<li class="ifrst">Reservoir basin, <a href="#Page_37">37</a></li>
-<li class="isub3">outlets, <a href="#Page_6">6</a></li>
-<li class="isub3">Wachusett, <a href="#Page_48">48</a></li>
-<li class="isub1">Rollers for dams, <a href="#Page_30">30</a>, <a href="#Page_65">65</a></li>
-
-<li class="ifrst">Sands and gravels, flow of water through, <a href="#Page_52">52</a></li>
-<li class="isub3">(Also see percolation.)</li>
-<li class="isub1">Slips and drainage of earthwork, <a href="#Page_45">45</a></li>
-<li class="isub1">Soil analyses, Tabeaud Dam, <a href="#Page_25">25</a></li>
-<li class="isub3">analysis, <a href="#Page_14">14</a></li>
-<li class="isub1">Soils, experiments on filtration through at Wachusett Reservoir, <a href="#Page_50">50</a></li>
-<li class="isub3">outline study of, <a href="#Page_12">12</a></li>
-<li class="isub3">permanence of, <a href="#Page_51">51</a></li>
-<li class="isub3">selection of, for dams, <a href="#Page_64">64</a></li>
-<li class="isub3">studies, Wachusett Reservoir, <a href="#Page_50">50</a></li>
-<li class="isub1">Spillway or wasteway, <a href="#Page_8">8</a></li>
-<li class="isub3">Tabeaud Dam, <a href="#Page_31">31</a></li>
-<li class="isub1">Subsidences, earthwork, <a href="#Page_45">45</a></li>
-
-<li class="ifrst">Test pits, <a href="#Page_5">5</a>, <a href="#Page_8">8</a>, <a href="#Page_9">9</a></li>
-<li class="isub1">Tunnel, outlet, Tabeaud Dam, <a href="#Page_30">30</a></li>
-<li class="isub1">Tunnels as outlets to reservoirs, <a href="#Page_6">6</a></li>
-
-<li class="ifrst">Wasteway or spillway, <a href="#Page_8">8</a>, <a href="#Page_66">66</a></li>
-<li class="isub3">Tabeaud Dam, <a href="#Page_31">31</a></li>
-</ul>
-
-<div class="footnotes">
-<p class="f150 space-below1"><b>Footnotes:</b></p>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_1" href="#FNanchor_1" class="label">[1]</a>
-The writer had intended to present a table of physical properties of
-different materials, giving their specific gravity, weight, coefficient
-of friction, angle of repose, percentage of imbibition, percentage
-of voids, etc., but found it impossible to harmonize the various
-classifications of materials given by different authorities.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_2" href="#FNanchor_2" class="label">[2]</a>
-The effective head at any point of an earth dam has been defined as the
-difference in the elevation of the high-water surface in the reservoir
-and that of the intersection of the down-stream slope with the natural
-or restored surface of the ground below the dam.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_3" href="#FNanchor_3" class="label">[3]</a>
-This work is very fully described in the Annual Reports of the
-Metropolitan Water Board of Boston; and by Mr. F. P. Stearns, Chief
-Engineer of the Metropolitan Water and Sewerage Board, in the
-Proceedings of the American Society of Civil Engineers for April, 1902.
-The latter description was reprinted, with the omission of some of the
-illustrations, in Engineering News for May 8, 1902.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_4" href="#FNanchor_4" class="label">[4]</a>
-By effective size of sand grains is meant such size of
-grain that 10% by weight of the particles are smaller, and 90% larger
-than itself; or, to express it a little differently, the effective size
-is equal to a sphere the volume of which is greater than ¹/₁₀ that
-forming the weight and is less than ⁹/₁₀ that forming the weight.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_5" href="#FNanchor_5" class="label">[5]</a>
-The term “uniformity coefficient” is used to designate the ratio of
-the size of the grain which has 60% of the sample finer than itself to
-the size which has 10% finer than itself. The method of determining
-the size of sand grains and their uniformity coefficients, is fully
-explained in Appendix 3 of Mr. Hazen’s book on “The Filtration of
-Public Water Supplies.”</p>
-</div></div>
-
-<div class="chapter">
-<div class="transnote bbox space-above2">
-<p class="f120 space-above1">Transcriber’s Notes:</p>
-<hr class="r5" />
-<p class="indent">The illustrations have been moved so that they do not break up
-                  paragraphs and so that they are next to the text they illustrate.</p>
-<p class="indent">Typographical and punctuation errors have been silently corrected.</p>
-</div></div>
-
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