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+Project Gutenberg (https://www.gutenberg.org) public repository for
+eBook #63131 (https://www.gutenberg.org/ebooks/63131)
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-The Project Gutenberg EBook of USDA Farmers' Bulletin No. 1227: Sewage and
-sewerage of farm homes, by George Warren
-
-This eBook is for the use of anyone anywhere in the United States and most
-other parts of the world at no cost and with almost no restrictions
-whatsoever.  You may copy it, give it away or re-use it under the terms of
-the Project Gutenberg License included with this eBook or online at
-www.gutenberg.org.  If you are not located in the United States, you'll have
-to check the laws of the country where you are located before using this ebook.
-
-Title: USDA Farmers' Bulletin No. 1227: Sewage and sewerage of farm homes
-
-Author: George Warren
-
-Release Date: September 5, 2020 [EBook #63131]
-
-Language: English
-
-Character set encoding: UTF-8
-
-*** START OF THIS PROJECT GUTENBERG EBOOK USDA FARMERS' BULLETIN NO. 1227 ***
-
-
-
-
-Produced by Tom Cosmas from files generously made available
-by USDA through The Internet Archive. All are placed in
-the Public Domain.
-
-
-
-
-
-
-
-
-
-Transcriber Note
-
-Text emphasis denoted by _Italics_ and =Bold=. Whole and fractional parts
-of numbers as 123-4/5.
-
-
-                     U. S. DEPARTMENT OF AGRICULTURE
-
-                        FARMERS' BULLETIN No. 1227
-
-
-                    SEWAGE AND SEWERAGE OF FARM HOMES
-
-
-DISPOSAL OF FARM SEWAGE in a clean manner is always an important problem.
-The aims of this bulletin are twofold--(1) to emphasize basic principles
-of sanitation; (2) to give directions for constructing and operating home
-sewerage works that shall be simple, serviceable, and safe.
-
-Care in operating is absolutely necessary. No installation will run
-itself. Continued neglect ends in failure of even the best-designed,
-best-built plants. If the householder is to build and neglect, he might as
-well save expense and continue the earlier practice.
-
-    Washington, D. C.   Issued January, 1922
-          Revised October, 1928
-
-
-
-
-SEWAGE AND SEWERAGE OF FARM HOMES
-
-
-George M. Warren, Hydraulic Engineer, Bureau of Public Roads
-
-
-
-
-CONTENTS
-
-
-                                                Page
-
-  Introduction                                     1
-
-  Sewage, sewers, and sewerage defined             1
-
-  Nature and quantity of sewage                    2
-
-  Sewage-borne diseases and their avoidance        2
-
-  How sewage decomposes                            5
-
-  Importance of air in treatment of sewage         7
-
-  Practical utilities                              8
-
-  Septic tanks                                    21
-
-  Grease traps                                    43
-
-  General procedure                               45
-
-
-
-
-INTRODUCTION
-
-
-The main purpose of home sewerage works is to get rid of sewage in such
-way as (1) to guard against the transmission of disease germs through
-drinking water, flies, or other means; (2) to avoid creating nuisance.
-What is the best method and what the best outfit are questions not to be
-answered offhand from afar. A treatment that is a success in one location
-may be a failure in another. In every instance decision should be based
-upon field data and full knowledge of the local needs and conditions.
-An installation planned from assumed conditions may work harm. The
-householder may be misled as to the purification and rely on a protection
-that is not real. He may anticipate little or no odor and find a nuisance
-has been created.
-
-
-
-
-SEWAGE, SEWERS, AND SEWERAGE DEFINED
-
-
-Human excrements (feces and urine) as found in closets and privy vaults
-are known as night soil. These wastes may be flushed away with running
-water, and there may be added the discharges from washbasins, bathtubs,
-kitchen and slop sinks, laundry trays, washing vats, and floor drains.
-This refuse liquid product is sewage, and the underground pipe which
-conveys it is a sewer. Since sewers carry foul matter they should be
-water-tight, and this feature of their construction distinguishes them
-from drains removing relatively pure surface or ground water. Sewerage
-refers to a system of sewers, including the pipes, tanks, disposal works,
-and appurtenances.
-
-
-
-
-NATURE AND QUANTITY OF SEWAGE
-
-
-Under average conditions a man discharges daily about 3½ ounces of moist
-feces and 40 ounces of urine, the total in a year approximating 992
-pounds.[1] Feces consist largely of water and undigested or partially
-digested food; by weight it is 77.2 per cent water.[2] Urine is about 96,3
-per cent water.[2]
-
-[1] Practical Physiological Chemistry, by Philip B. Hawk, 1916, pp. 221,
-359.
-
-[2] Agriculture, by P. H. Storer, 1894, vol. 2, p. 70.
-
-The excrements constitute but a small part of ordinary sewage. In
-addition to the excrements and the daily water consumption of perhaps
-40 gallons per person are many substances entering into the economy of
-the household, such as grease, fats, milk, bits of food, meat, fruit and
-vegetables, tea and coffee grounds, paper, etc. This complex product
-contains mineral, vegetable, and animal substances, both dissolved and
-undissolved. It contains dead organic matter and living organisms in the
-form of exceedingly minute vegetative cells (bacteria) and animal cells
-(protozoa). These low forms of life are the active agents in destroying
-dead organic matter.
-
-The bacteria are numbered in billions and include many species, some
-useful and others harmful. They may be termed tiny scavengers, which under
-favorable conditions multiply with great rapidity, their useful work
-being the oxidizing and nitrifying of dissolved organic matter and the
-breaking down of complex organic solids to liquids and gases. Among the
-myriads of bacteria are many of a virulent nature. These at any time may
-include species which are the cause of well-known infectious and parasitic
-diseases.
-
-
-
-
-SEWAGE-BORNE DISEASES AND THEIR AVOIDANCE
-
-
-Any spittoon, slop pail, sink drain, urinal, privy, cesspool, sewage
-tank, or sewage distribution field is a potential danger. A bit of spit,
-urine, or feces the size of a pin head may contain many hundred germs,
-all invisible to the naked eye and each one capable of producing disease.
-These discharges should be kept away from the food and drink of man
-and animals. From specific germs that may be carried in sewage at any
-time there may result typhoid fever, tuberculosis, cholera, dysentery,
-diarrhea, and other dangerous ailments, and it is probable that other
-maladies may be traced to human waste. From certain animal parasites or
-their eggs that may be carried in sewage there may result intestinal
-worms, of which the more common are the hookworm, roundworm, whipworm,
-eelworm, tapeworm, and seat worm.
-
-Sewage, drainage, or other impure water may contain also the causative
-agents of numerous ailments common to livestock, such as tuberculosis,
-foot-and-mouth disease, hog cholera, anthrax, glanders, and stomach and
-intestinal worms.
-
-Disease germs are carried by many agencies and unsuspectingly received by
-devious routes into the human body. Infection may come from the swirling
-dust of the railway roadbed, from contact with transitory or chronic
-carriers of disease, from green truck grown in gardens fertilized with
-night soil or sewage, from food prepared or touched by unclean hands
-or visited by flies or vermin, from milk handled by sick or careless
-dairymen, from milk cans and utensils washed with contaminated water, or
-from cisterns, wells, springs, reservoirs, irrigation ditches, brooks,
-or lakes receiving the surface wash or the underground drainage from
-sewage-polluted soil.
-
-Many recorded examples show with certainty how typhoid fever and other
-diseases have been transmitted. A few indicating the responsibilities and
-duties of people who live in the country are cited here.
-
- In August, 1889, a sister and two brothers aged 18, 21, and 23 years,
- respectively, and all apparently in robust health dwelt together in a
- rural village in Columbiana County, Ohio. Typhoid fever in particular
- virulent form developed after use of drinking water from a badly polluted
- surface source. The deaths of all three occurred within a space of 10
- days.
-
- In September and October, 1899, 63 cases of typhoid fever, resulting
- in 5 deaths, occurred at the Northampton (Mass.) insane hospital. This
- epidemic was conclusively traced to celery, which was eaten freely in
- August and was grown and banked in a plot that had been fertilized in the
- late winter or early spring with the solid residue and scrapings from a
- sewage filter bed situated on the hospital grounds.
-
- Some years ago Dr. W. W. Skinner, Bureau of Chemistry, Department of
- Agriculture, investigated the cause of an outbreak of typhoid fever in
- southwest Virginia. A small stream meandered through a narrow valley
- in which five 10-inch wells about 450 feet deep had been drilled in
- limestone formation. The wells were from 50 to 400 feet from the stream,
- from which, it was suspected, pollution was reaching the wells. In a pool
- in the stream bed approximately one-fourth mile above the wells several
- hundred pounds of common salt were dissolved. Four of the wells were cut
- off from the pump and the fifth was subjected to heavy pumping. The water
- discharged by the pump was examined at 15-minute intervals and its salt
- content determined over a considerable period of time. After the lapse of
- several 15-minute intervals the salt began to rise and continued to rise
- until the maximum was approximately seven times that at the beginning of
- the test, thus proving the facility with which pollution may pass a long
- distance underground and reach deep wells.
-
- Probably no epidemic in American history better illustrates the dire
- results that may follow one thoughtless act than the outbreak of typhoid
- fever at Plymouth, Pa., in 1885. In January and February of that year the
- night discharges of one typhoid fever patient were thrown out upon the
- snow near his home. These, carried by spring thaws into the public water
- supply, caused an epidemic running from April to September. In a total
- population of about 8,000, 1,104 persons were attacked by the disease and
- 114 died.
-
-Like plants and animals, disease germs vary in their powers of resistance.
-Some are hardy, others succumb easily. Outside the body most of them
-probably die in a few days or weeks. It is never certain when such germs
-may not lodge where the immediate surroundings are favorable to their life
-and reproduction. Milk is one of the common substances in which germs
-multiply rapidly. The experience at Northampton shows that typhoid-fever
-germs may survive several months in garden soil. Laboratory tests by the
-United States Public Health Service showed that typhoid-fever germs had
-not all succumbed after being frozen in cream 74 days. (Public Health
-Reports, Feb. 8, 1918, pp. 163-166.) Ravenel kept the spores of anthrax
-immersed for 244 days in the strongest tanning fluids without perceptible
-change in their vitality or virulence. (Annual Report, State Department of
-Health, Mass., 1916, p. 494.)
-
-=Unsafe practices.=--Upon thousands of small farms there are no privies
-and excretions are deposited carelessly about the premises. A place of
-this character is shown in figure 1. Upon thousands of other farms the
-privy is so filthy and neglected that hired men and visitors seek near-by
-sheds, fields, and woods. A privy of this character is shown in figure 2.
-These practices and conditions exist in every section of the country. They
-should be abolished.
-
-[Illustration: Fig. 1.--One of many farms lacking the simplest sanitary
-convenience]
-
-Deserving of severe censure is the old custom of conveying excrements or
-sewage into abandoned wells or some convenient stream. Such a practice is
-indecent and unsafe. It is unnecessary and is contrary to the laws of most
-of the States.
-
-Likewise dangerous and even more disgusting is the old custom of using
-human excrement or sewage for the fertilization of truck land. Under
-no circumstances should such wastes be used on land devoted to celery,
-lettuce, radishes, cucumbers, cabbages, tomatoes, melons, or other
-vegetables, berries, or low-growing fruits that are eaten raw. Disease
-germs or particles of soil containing such germs may adhere to the skins
-of vegetables or fruits and infect the eater.
-
-Upon farms it is necessary to dispose of excretal wastes at no great
-distance from the dwelling. The ability and likelihood of flies carrying
-disease germs direct to the dinner table, kitchen, or pantry are well
-known. Vermin, household pets, poultry, and live stock may spread such
-germs. For these reasons, and also on the score of odor, farm sewage never
-should be exposed.
-
-=Important safety measure.=--The farmer can do no other one thing so vital
-to his own and the public health as to make sure of the continued purity
-of the farm water supply. Investigations indicate that about three out of
-four shallow wells are polluted badly.
-
-Wells and springs are fed by ground water, which is merely natural
-drainage. Drainage water usually moves with the slope of the land. It
-always dissolves part of the mineral, vegetable, and animal matter of the
-ground over or through which it moves. In this way impurities are carried
-into the ground water and may reach distant wells or springs.
-
-The great safeguards are clean ground and wide separation of the well
-from probable channels of impure drainage water. It is not enough that
-a well or spring is 50 or 150 feet from a source of filth or that it is
-on higher ground. Given porous ground, a seamy ledge, or long-continued
-pollution of one plat of land, the zone of contamination is likely to
-extend long distances, particularly in downhill directions or when the
-water is low through drought or heavy pumping. Only when the surface of
-the water in a well or spring is at a higher level at all times than any
-near-by source of filth is there assurance of safety from impure seepage.
-Some of the foregoing facts are shown diagrammatically in Figure 3. Figure
-4 is typical of those insanitary, poorly drained barnyards that are almost
-certain to work injury to wells situated in or near them. Accumulations
-of filth result in objectionable odor and noxious drainage. Figure 5
-illustrates poor relative location of privy, cesspool, and well.
-
-[Illustration: Fig. 2.--The rickety, uncomfortable, unspeakably foul,
-dangerous ground privy. Neglected by the owner, shunned by the hired man,
-avoided by the guest, who, in preference, goes to near-by fields or woods,
-polluter of wells, meeting place of house flies and disease germs, privies
-of this character abide only because of man's indifference]
-
-Sewage or impure drainage water should never be discharged into or upon
-ground draining toward a well, spring, or other source of water supply.
-Neither should such wastes be discharged into openings in rock, an
-abandoned well, nor a hole, cesspool, vault, or tank so located that
-pollution can escape into water-bearing earth or rock. Whatever the system
-of sewage disposal, it should be entirely and widely separated from the
-water supply. Further information on locating and constructing wells is
-given in Farmers' Bulletin 1448-F, Farmstead Water Supply, copies of which
-may be had upon request to the Division of Publications, Department of
-Agriculture.
-
-Enough has been said to bring home to the reader these vital points:
-
-1. Never allow the farm sewage or excrements, even in minutest quantity,
-to reach the food or water of man or livestock.
-
-2. Never expose such wastes so that they can be visited by flies or other
-carriers of disease germs.
-
-3. Never use such wastes to fertilize or irrigate vegetable gardens.
-
-4. Never discharge or throw such wastes into a stream, pond, or abandoned
-well, nor into a gutter, ditch, or tile drainage system, which naturally
-must have outlet in some watercourse.
-
-[Illustration: Fig. 3.--How an apparently good well may draw foul
-drainage. Arrows show direction of ground water movement. _A-A_, Usual
-water table (surface of free water in the ground); _B-B_, water table
-lowered by drought and pumping from well _D_; _C-C_, water table further
-lowered by drought and heavy pumping; _E-F_, level line from surface of
-sewage in cesspool. Well _D_ is safe until the water table is lowered to
-_E_; further lowering draws drainage from the cesspool and, with the water
-table at _C-C_, from the barn. The location of well _G_ renders it unsafe
-always]
-
-[Illustration: Fig. 4.--An insanitary, poorly drained barnyard. (Board of
-Health, Milwaukee.) Liquid manure or other foul drainage is sure to leach
-into wells situated in or near barnyards of this character]
-
-
-
-
-HOW SEWAGE DECOMPOSES
-
-
-When a bottle of fresh sewage is kept in a warm room changes occur in the
-appearance and nature of the liquid. At first it is light in appearance
-and its odor is slight. It is well supplied with oxygen, since this gas
-is always found in waters exposed to the atmosphere. In a few hours the
-solids in the sewage separate mechanically according to their relative
-weights; sediment collects at the bottom, and a greasy film covers the
-surface. In a day's time there is an enormous development of bacteria,
-which obtain their food supply from the dissolved carbonaceous and
-nitrogenous matter. As long as free oxygen is present this action is
-spoken of as aërobic decomposition. There is a gradual increase in the
-amount of ammonia and a decrease of free oxygen. When the ammonia is near
-the maximum and the free oxygen is exhausted the sewage is said to be
-stale. Following exhaustion of the oxygen supply, bacterial life continues
-profuse, but it gradually diminishes as a result of reduction of its food
-supply and the poisonous effects of its own wastes. In the absence of
-oxygen the bacterial action is spoken of as anaërobic decomposition. The
-sewage turns darker and becomes more offensive. Suspended and settled
-organic substances break apart or liquefy later, and various foul-smelling
-gases are liberated. Sewage in this condition is known as septic and the
-putrefaction that has taken place is called septicization. Most of the
-odor eventually disappears, and a dark, insoluble, mosslike substance
-remains as a deposit. Complete reduction of this deposit may require many
-years.
-
-[Illustration: Fig. 5.--Poor relative locations of privy, cesspool, and
-well. (State Department of Health, Massachusetts.) Never allow privy,
-cesspool, or sink drainage to escape into the plot of ground from which
-the water supply comes]
-
-
-
-
-IMPORTANCE OF AIR IN TREATMENT OF SEWAGE
-
-
-Decomposition of organic matter by bacterial agency is not a complete
-method of treating sewage, as will be shown later under "Septic tanks." It
-is sufficient to observe here that in all practical methods of treatment
-aeration plays a vital part. The air or the sewage, or both, must be in a
-finely divided state, as when sewage percolates through the interstices
-of a porous, air-filled soil. The principle involved was clearly stated
-30 years ago by Hiram F. Mills, a member of the Massachusetts State Board
-of Health. In discussing the intermittent filtration of sewage through
-gravel stones too coarse to arrest even the coarsest particles in the
-sewage Mr. Mills said: "The slow movement of the sewage in thin films over
-the surface of the stones, with air in contact, caused a removal for some
-months of 97 per cent of the organic nitrogenous matter, as well as 99 per
-cent of the bacteria."
-
-
-
-
-PRACTICAL UTILITIES
-
-
-Previous discussion has dealt largely with basic principles of sanitation.
-The construction and operation of simple utilities embodying some of
-these principles are discussed in the following order: (1) Privies for
-excrements only; (2) works for handling wastes where a supply of water is
-available for flushing.
-
-
-PIT PRIVY
-
-Figure 6 shows a portable pit privy suitable for places of the character
-of that shown in figure 1, where land is abundant and cheap, and in such
-localities has proved practical. It provides, at minimum cost and with
-least attention, a fixed place for depositing excretions where the filth
-can not be tracked by man, spread by animals, reached by flies, nor washed
-by rain.
-
-[Illustration: Fig. 6.--Portable pit privy. For use where land is abundant
-and cheap, but unless handled with judgment can not be regarded as safe.
-The privy is mounted on runners for convenience in moving to new locations]
-
-The privy is light and inexpensive and is placed over a pit in the ground.
-When the pit becomes one-half or two-thirds full the privy is drawn or
-carried to a new location. The pit should be shallow, preferably not
-over 2½ feet in depth, and never should be located in wet ground or rock
-formation or where the surface or the strata slope toward a well, spring,
-or other source of domestic water supply. Besides standing on lower ground
-the pit should never be within 200 feet of a well or spring. Since dryness
-in the pit is essential, the ground should be raised slightly and 10 or
-12 inches of earth should be banked and compacted against all sides to
-shed rain water. The banking also serves to exclude flies. If the soil
-is sandy or gravelly, the pit should be lined with boards or pales to
-prevent caving. The standard galvanized or black enameled wire cloth
-having 14 squares to the inch. The whole seat should be easily removable
-for cleaning. A little loose absorbent soil should be added daily to the
-accumulation in the pit, and when a pit is abandoned it should be filled
-immediately with dry earth mounded to shed water.
-
-A pit privy for use in field work, consisting of a framework of ½-inch
-iron pipe for corner posts connected at the top with ¼-inch iron rods bent
-at the ends to right angles and hung with curtains of unbleached muslin,
-is described in Public Health Report of the United States Public Health
-Service, July 26, 1918.
-
-A pit privy, even if moved often, can not be regarded as safe. The danger
-is that accumulations of waste may overtax the purifying capacity of the
-soil and the teachings reach wells or springs. Sloping ground is not a
-guaranty of safety; the great safeguard lies in locating the privy a long
-distance from the water supply and as far below it as possible.
-
-
-SANITARY PRIVY
-
-The next step in evolution is the sanitary privy. Its construction must
-be such that it is practically impossible for filth or germs to be spread
-above ground, to escape by percolation underground, or to be accessible to
-flies, vermin, chickens, or animals. Furthermore, it must be cared for in
-a cleanly manner, else it ceases to be sanitary. To secure these desirable
-ends sanitarians have devised numerous types of tight-receptacle privy.
-Considering the small cost and the proved value of some of these types, it
-is to be regretted that few are seen on American farms.
-
-The container for a sanitary privy may be small--for example, a
-galvanized-iron pail or garbage can, to be removed from time to time by
-hand; it may be large, as a barrel or a metal tank mounted for moving;
-or it may be a stationary underground metal tank or masonry vault. The
-essential requirement in the receptacle is permanent water-tightness to
-prevent pollution of soils and wells. Wooden pails or boxes, which warp
-and leak, should not be used. Where a vault is used it should be shallow
-to facilitate emptying and cleaning. Moreover, if the receptacle should
-leak it is better that the escape of liquid should be in the top soil,
-where air and bacterial life are most abundant.
-
-Sanitary privies are classified according to the method used in treating
-the excretions, as dry earth, chemical, etc.
-
-
-DRY-EARTH PRIVY
-
-=Pail type.=--A very serviceable pail privy is shown in Figures 7 and 8.
-The method of ventilation is an adaptation of a system that has proved
-very effective in barns and other buildings here and abroad. A flue with
-a clear opening of 16 square inches rises from the rear of the seat and
-terminates above the ridgepole in a cowl or small roofed housing. Attached
-to this flue is a short auxiliary duct, 4 by 15 inches, for removing foul
-air from the top of the privy. In its upper portion on the long sides the
-cowl is open, allowing free movement of air across the top of the flue.
-In addition, the long sides of the cowl are open below next to the roof.
-These two openings, with the connecting vertical air passages, permit free
-upward movement of air through the cowl, as indicated by the arrows. The
-combined effect is to create draft from beneath the seat and from the top
-of the privy. The ventilating flue is 2 by 8 inches at the seat and 4 by 4
-inches 5 feet above. The taper slightly increases the labor of making the
-flue, but permits a 2-inch reduction in the length of the building.
-
-[Illustration: Fig. 7.--Pail privy. Well constructed, ventilated, and
-screened. With proper care is sanitary and unobjectionable]
-
-In plan the privy is 4 by 4½ feet. The sills are secured to durable posts
-set about 4 feet in the ground. The boarding is tight, and all vents and
-windows are screened to exclude insects. The screens may be the same as
-for pit privies or, if a more lasting material is desired, bronze or
-copper screening of 14 squares to the inch may be used. The entire seat
-is hinged, thus permitting removal of the receptacle and facilitating
-cleaning and washing the underside of the seat and the destruction of
-spiders and other insects which thrive in dark, unclean places. The
-receptacle is a heavy galvanized-iron garbage can. Heavy brown-paper bags
-for lining the can may be had at slight cost, and their use helps to keep
-the can clean and facilitates emptying. Painting with black asphaltum
-serves a similar purpose and protects the can from rust. If the contents
-are frozen, a little heat releases them. Of nonfreezing mixtures a strong
-brine made with common salt or calcium chloride is effective. Two and
-one-half to 3 pounds of either thoroughly dissolved in a gallon of water
-lowers the freezing point of the mixture to about zero. Denatured alcohol
-or wood alcohol in a 25 per cent solution has a like low freezing point
-and the additional merit of being noncorrosive of metals. The can should
-be emptied frequently and the contents completely buried in a thin layer
-by a plow or in a shallow hand-dug trench at a point below and remote from
-wells and springs. Wherever intestinal disease exists the contents of
-the can should be destroyed by burning or made sterile before burial by
-boiling or by incorporation with a strong chemical disinfectant.
-
-[Illustration: Fig. 8.--Pail privy]
-
-[Illustration: Fig. 9.--A well-ventilated privy in Montana]
-
-A privy ventilated in the manner before described is shown in Figure 9.
-The cowl, however, is open on four sides instead of two sides as shown
-in Figures 7 and 8. The working drawings (figs. 7 and 8) show that the
-construction of a privy of the kind is not difficult. Figure 10 gives
-three suggestions whereby a privy may be conveniently located and the
-approach screened or partially hidden by latticework, vines, or shrubbery.
-
-=Vault type.=--A primitive and yet serviceable three-seat dry-earth privy
-of the vault type is shown in Figure 11. This privy was constructed in
-1817 upon a farm at Westboro, Mass. The vault, made of bricks, was 6 feet
-long by 5 feet wide, and the bottom was 1 foot below the surface of the
-ground. The brickwork was laid in mortar, and the part below the ground
-surface was plastered on the inside. The outside of the vault was exposed
-to light and air on all four sides. Across the long side of the vault
-in the rear was a door swinging upward through which the night soil was
-removed two or three times a year, usually in the spring, summer, and fall
-and hauled to a near-by field, where it was deposited in a furrow, just
-ahead of the plow.
-
-Especial attention is called to the shallowness of the vault and the
-lightened labor of cleaning it out. The swinging door at the rear
-facilitated the sprinkling of dry soil or ashes over the contents of the
-vault, thus avoiding the necessity of carrying dirt and dust into the
-building and dust settling upon the seat. This privy was in use for nearly
-100 years without renewal or repairs. When last seen the original seat,
-which always was kept painted, showed no signs of decay. Modern methods
-would call for a concrete vault of guaranteed water-tightness,[3] proper
-ventilation and screening, and hinging the seat.
-
-[3] Directions for mixing and placing concrete to secure water-tightness
-are contained in Farmers' Bulletin 1279-F, "Plain concrete for farm use,"
-and Farmers' Bulletin 1572-F, "Making Cellars Dry."
-
-Working drawings for a very convenient well-built two-seat vault privy
-are reproduced in Figures 12 and 13. The essential features are shown in
-sufficient detail to require little explanation. With concrete mixtures of
-1:2:3 (1 volume cement, 2 volumes sand, 3 volumes stone) for the vault and
-1:2:4 for the posts there will be required a total of about 2 cubic yards
-of concrete, taking 3½ barrels of cement, 1 cubic yard of sand, and 1½
-cubic yards of broken stone or screened gravel. The stone or gravel should
-not exceed 1 inch in diameter, except that a few cobblestones may be
-embedded where the vault wall is thickest, thus effecting a slight saving
-of materials.
-
-[Illustration: Fig. 10.--Screening the approach to a privy. _A_, Raised
-platform with lattice sides, suitable for short distances, convenient,
-and easily cleared of snow; _B_, walk hidden by latticework; _C_, walk
-inclosed by an arbor]
-
-
-CHEMICAL CLOSET
-
-[Illustration: Fig. 11.--A primitive vault privy in Massachusetts. Note
-the tight, shallow, easily cleaned vault. _A_, Brick vault 5 by 6 feet,
-bottom about 1 foot in the ground; _B_, water-tight plastering; _C_,
-rowlock course of brick; _D_, door hinged at top; _E_, door button; _F_,
-three-pane window hinged at top; _G_, passageway]
-
-A type of sanitary privy in which the excrements are received directly
-into a water-tight receptacle containing chemical disinfectant is meeting
-with considerable favor for camps, parks, rural cottages, schools, hotels,
-and railway stations. These chemical closets,[4] as they are called, are
-made in different forms and are known by various trade names. In the
-simplest form a sheet-metal receptacle is concealed in a small metal or
-wooden cabinet, and the closet is operated usually in much the same manner
-as the ordinary pail privy. These closets are very simple and compact,
-of good appearance, and easy to install or move from place to place. In
-another type, known as the chemical tank closet, the receptacle is a
-steel tank fixed in position underground or in a basement. The tank has a
-capacity of about 125 gallons per seat, is provided with a hand-operated
-agitator to secure thorough mixing of the chemical and the excretions, and
-the contents are bailed, pumped, or drained out from time to time.
-
-[4] Among publications on chemical closets are the following: "Chemical
-closets," Reprint No. 404 from the Public Health Reports, U. S. Public
-Health Service, June 29, 1917, pp. 1017-1020: "The chemical closet,"
-Engineering Bulletin No. 5, Mich. State Board of Health, October, 1916;
-Health Bulletin, Va. Department of Health, March, 1917, PP. 214-219.
-
-Chemical closets, like every form of privy, should be well installed,
-cleanly operated, and frequently emptied, and the wastes should receive
-safe burial. With the exception of frequency of emptying, the same can
-be said of chemical tank closets. With both forms of closet thorough
-ventilation or draft is essential, and this is obtained usually by
-connecting the closet vent pipe to a chimney flue or extending it well
-above the ridgepole of the building. The contents of the container should
-always be submerged and very low temperatures guarded against.
-
-[Illustration: Fig. 12.--Two-seat vault privy]
-
-As to the germicidal results obtained in chemical closets, few data are
-available. A disinfecting compound may not sterilize more than a thin
-surface layer of the solid matter deposited. Experiments by Dr. Alvah
-H. Doty with various agents recommended and widely used for the bedside
-sterilization of feces showed "that at the end of 20 hours of exposure
-to the disinfectant but one-eighth of an inch of the fecal mass was
-disinfected."[5] Plainly, then, to destroy all bacterial and parasitic
-life in chemical closets three things are necessary: (1) A very powerful
-agent; (2) permeation of the fecal mass by the agent; (3) retention of
-its strength and potency until permeation is complete. The compounds or
-mixtures commonly used in chemical closets are of two general kinds:
-First, those in which some coal-tar product or other oily disinfectant is
-used to destroy germs and deodorize, leaving the solids little changed in
-form; second, those of the caustic class that dissolve the solids, which,
-if of sufficient strength and permeating every portion, should destroy
-most if not all bacterial life. Not infrequently the chemical solution
-is intended to accomplish disinfection, deodorization, and reduction to
-a liquid or semiliquid state. Ordinary caustic soda, costing about $1 in
-10-pound pails, has given good results.
-
-[5] Annual Report, Mass. State Board of Health, 1914, p. 727.
-
-A simple type of chemical closet is shown in Figure 14, and the essential
-features are indicated in the notation. These closets with vent pipe and
-appurtenances, ready for setting up, retail for $20 and upward. A chemical
-tank closet, retailing for about $80 per seat, is shown in Figure 15.
-
-The Department of Agriculture occasionally receives complaints from people
-who have installed chemical closets, usually on the score of odors or the
-cost of chemicals.
-
-[Illustration: Fig. 13.--Two-seat-vault privy. Note the shallow,
-water-tight, easily cleaned concrete vault]
-
-
-DISINFECTANTS AND DEODORANTS
-
-Disinfection is the destruction of disease germs. Sterilization is
-the destruction of all germs or bacteria, both the harmful and the
-useful. Antisepsis is the checking or restraining of bacterial growth.
-Deodorization is the destruction of odor. Unfortunately in practice none
-of these processes may be complete. The agent may be of inferior quality,
-may have lost its potency, or may not reach all parts of the mass treated.
-A disinfectant or germicide is an agent capable of destroying disease
-germs; an antiseptic is an agent merely capable of arresting bacterial
-growth, and it may be a dilute disinfectant; a deodorant is an agent that
-tends to destroy odor, but whose action may consist in absorbing odor or
-in masking the original odor with another more agreeable one.[6]
-
-[6] Those desiring more explicit information on disinfectants and the
-principles of disinfection are referred to U. S. Department of Agriculture
-Farmers' Bulletin 926, "Some Common Disinfectants," and 954, "The
-Disinfection of Stables." and to publications of the U. S. Public Health
-Service.
-
-Of active disinfecting agents, heat from fire, live steam, and boiling
-water are the surest. The heat generated by the slaking of quicklime has
-proved effective with small quantities of excreta. Results of tests by the
-Massachusetts State Board of Health[7] show that the preferable method
-consists in adding sufficient hot water (120° to 140° F.) to cover the
-excrement in the receptacle, then adding small pieces of fresh strong
-quicklime in amount equal to about one-third of the bulk of water and
-excrement combined, covering the receptacle, and allowing it to stand 1½
-hours or longer.
-
-[7] Annual Report, Mass. State Board of Health, 1914, pp. 727-729.
-
-[Illustration: Fig. 14.--Chemical closet. _A_, Water-tight sheet-metal
-container; _B_, metal or wooden cabinet; _C_, wooden or composition seat
-ring; _D_, hinged cover; _E_, 3 or 4 inch ventilating flue extending 18
-inches above roof or to a chimney; _F_, air inlets]
-
-[Illustration: Fig. 15.--Chemical tank closet. _A_, Tank, 2 feet 3 inches
-by 4 feet 2 inches 5/64th-inch iron, seams welded; capacity, 125 gallons;
-_B_, 14-inch covered opening for recharging and emptying tank; _C_,
-12-inch galvanized sheet-metal tube; _D_, 4-inch sheet-metal ventilating
-pipe extending above ridgepole or to a chimney; _E_, agitator or paddle]
-
-Among chemical disinfectants a strong solution of sodium hydroxide
-(caustic soda) or potassium hydroxide (caustic potash, lye) is very
-effective and is useful in dissolving grease and other organic substances.
-Both chemicals are costly, but caustic soda is less expensive than
-caustic potash and constitutes most of the ordinary commercial lyes.
-Chlorinated lime (chloride of lime, bleaching powder) either in solution
-or in powdered form is valuable. For the disinfection of stools of
-typhoid-fever patients the Virginia State Board of Health[8] recommends
-thoroughly dissolving ½ pound of best chlorinated lime in 1 gallon of
-water and allowing the solution to cover the feces for at least 1 hour.
-The solution should be kept in well-stoppered bottles and used promptly,
-certainly within 2 or 3 days. Copper sulphate (blue vitriol, bluestone)
-in a 5 per cent solution (1 pound in 2½ gallons of water) is a good but
-rather costly disinfectant. None of the formulas here given is to be
-construed as fixed and precise. Conditions may vary the proportions, as
-they always will vary the results. The reader should remember that few,
-if any, chemical disinfectants can be expected fully to disinfect or
-sterilize large masses of excrement unless the agent is used repeatedly
-and in liberal quantities or mechanical means are employed to secure
-thorough incorporation.
-
-[8] Health Bulletin, Va. State Board of Health, June, 1917, pp. 277-280.
-
-Among deodorants some of the drying powders mentioned below possess
-more or less disinfecting power. Chlorinated lime, though giving off an
-unpleasant odor of chlorine, is employed extensively. Lime in the form
-of either quicklime or milk of lime (whitewash) is much used and is an
-active disinfectant. To prepare milk of lime a small quantity of water is
-slowly added to good fresh quicklime in lumps. As soon as the quicklime
-is slaked a quantity of water, about four times the quantity of lime, is
-added and stirred thoroughly. When used as a whitewash the milk of lime is
-thinned as desired with water and kept well stirred. Liberal use of milk
-of lime in a vault or cesspool, though it may not disinfect the contents,
-is of use in checking bacterial growth and abating odor. To give the best
-results it should be used frequently, beginning when the vault or cesspool
-is empty. Iron sulphate (green vitriol, copperas) because of its affinity
-for ammonia and sulphides is used as a temporary deodorizer in vaults,
-cesspools, and drains; 1 pound dissolved in 4 gallons of water makes a
-solution of suitable strength.
-
-
-PREVENTION OF PRIVY NUISANCE
-
-The following is a summary of simple measures for preventing a privy from
-becoming a nuisance:
-
-1. Locate the privy inconspicuously and detached from the dwelling.
-
-2. Make the receptacle or vault small, shallow, easy of access, and
-water-tight.
-
-3. Clean out the vault often. Do not wait until excrement has accumulated
-and decomposition is sufficiently advanced to cause strong and foul odors.
-
-4. Sprinkle into the vault daily loose dry soil, ashes, lime, sawdust,
-ground gypsum (land plaster), or powdered peat or charcoal. These will
-absorb liquid and odor, though they may not destroy disease germs.
-
-5. Make the privy house rain-proof; ventilate it thoroughly, and screen
-all openings.
-
-
-OBJECTION TO PRIVIES
-
-All the methods of waste disposal heretofore described are open to the
-following objections:
-
-1. They do not take care of kitchen slops and liquid wastes incident to a
-pressure water system.
-
-2. They retain filth for a considerable period of time, with probability
-of odors and liability of transmission of disease germs.
-
-3. They require more personal attention and care than people generally are
-willing to give.
-
-By far the most satisfactory method yet devised of caring for sewage
-calls for a supply of water and the flushing away of all wastes as soon
-as created through a water-tight sewer to a place where they undergo
-treatment and final disposal.
-
-
-KITCHEN-SINK DRAINAGE
-
-A necessity in every dwelling is effective disposal of the kitchen-sink
-slops. This necessity ordinarily arises long before the farm home is
-supplied with water under pressure and the conveniences that go with it.
-Hence the first call for information on sewage disposal is likely to
-relate merely to sink drainage. This waste water, though it may not be
-as dangerous to health as sewage containing human excrements, is still a
-menace to the farm well and capable of creating disagreeable odor.
-
-[Illustration: Fig. 16.--How to waste kitchen-sink drainage. _A_, Sink;
-_B_, waste pipe; _C_, trap; _D_, clean-out; _E_, box filled with hay,
-straw, sawdust, excelsior, coke, or other insulating material; _F_, 4-inch
-vitrified sewer-pipe, hubs uphill, and joints made water tight for at
-least 100 feet downhill from a well; _G_, 4-inch vitrified sewer pipe,
-hubs downhill, joints slightly open, laid in an 18-inch bed of coarse
-sand, gravel, stone, broken brick, slag, cinders, or coke; _H_, strip
-of tarred paper on burlap or a thin layer of hay, straw, cornstalks,
-brush, or sods, grass side down; _I_, 12 inches of natural soil; _J_,
-stone-filled pit. As here illustrated, water is drawn by a pitcher or
-kitchen pump (_K_) through a 1¼ or 1½ inch galvanized-iron suction pipe
-(_L_) from a cistern (_M_). The suction pipe should be laid below frost
-and on a smooth upward grade from cistern to pump and be provided with a
-foot valve (_N_) to keep the pump primed. If a foot valve is used, pump
-and pipe must be safe from frost or other means than tripping the pump be
-provided for draining the system]
-
-The usual method of disposing of sink slops is to allow them to dribble
-on or beneath the surface of the ground close to the house. Such drainage
-should be taken in a water-tight carrier at least 100 feet downhill from
-the well and discharged below the surface of the ground. Every sink should
-be provided with a suitable screen to keep all large particles out of the
-waste pipe. An approved form of sink strainer consists of a brass plate
-bolted in position over the outlet and having at least 37 perforations not
-larger than one-fourth inch in diameter. Provided a sink is thus equipped
-and is given proper care and the land has fair slope and drainage,
-the waste water may be conducted away through a water-tight sewer and
-distributed in the soil by means of a short blind drain. A simple
-installation, consisting of a kitchen-sink and pump and means of disposal
-as described, is shown in Figure 16.
-
-
-CESSPOOLS
-
-Where farms have water under pressure an open or leaching cesspool is a
-common method of disposing of the sewage. Ordinary cesspools are circular
-excavations in the ground, lined with stone or brick laid without mortar.
-They vary from 5 to 10 feet in diameter and from 7 to 12 feet in depth.
-Sometimes the top is arched and capped at the ground surface by a cover of
-wood, stone, or cast-iron. At other times the walls are carried straight
-up and boards or planks are laid across for a cover, and the entire
-structure is hidden with a hedge or shrubbery.
-
-Except under the most favorable conditions the construction and use of
-a cesspool can not be condemned too strongly. They are only permissible
-where no other arrangement is possible. Leaching cesspools especially are
-open to these serious objections:
-
-1. Unless located in porous soil, stagnation is likely to occur, and
-failure of the liquid to seep away may result in overflow on the Surface
-of the ground and the creation of a nuisance and a menace.
-
-2. They retain a mass of filth in a decomposing condition deep in the
-ground, where it is but slightly affected by the bacteria and air of
-the soil. In seeping through the ground it may be strained, but there
-can be no assurance that the foul liquid, with little improvement in
-its condition, may not pass into the ground water and pollute wells and
-springs situated long distances away in the direction of underground flow.
-
-For the purpose of avoiding soil and ground-water pollution cesspools have
-been made of water-tight construction and the contents removed by bailing
-or pumping. Upon the farm, however, this type of construction has little
-to recommend it, for the reason that facilities for removing and disposing
-of the contents in a clean manner are lacking.
-
-In some instances cesspools have been made water-tight, the outflow being
-effected by three or four elbows or =T=-branches set in the masonry near
-the top, with the inner ends turned down below the water surface, the
-whole surrounded to a thickness of several feet with stone or gravel
-intended to act as a filtering medium. Tests of the soil water adjacent to
-cesspools of this type show that no reliance should be placed upon them as
-a means of purifying sewage, the fatal defects being constant saturation
-with sewage and lack of air supply. To the extent that the submerged
-outlets keep back grease and solid matters the scheme is of service in
-preventing clogging of the pores of the surrounding ground.
-
-Where the ground about a cesspool has become clogged and water-logged,
-relief is often secured by laying several lines of drain tile at shallow
-depth, radiating from the cesspool. The ends of the pipes within the
-cesspool should turn down, and it is advantageous to surround the lines
-of pipe with stones or coarse gravel, as shown in Figure 16 and discussed
-under "Septic tanks." In this way not only is the area of percolation
-extended, but aeration and partial purification of the sewage are effected.
-
-Where a cesspool is located at a distance from a dwelling and there is
-opportunity to lead a vent pipe up the side of a shed, barn, or any stable
-object it is advisable to do so for purposes of ventilation. Where the
-conditions are less favorable it may be best, because of the odor, to omit
-any direct vent pipe from the cesspool and rely for ventilation on the
-house sewer and main soil stack extending above the roof of the house.
-
-Cesspools should be emptied and cleaned at least once a year and the
-contents given safe burial or, with the requisite permission, wasted in
-some municipal sewerage system. After cleaning, the walls and bottom may
-be treated with a disinfectant or a deodorant.
-
-
-SEPTIC TANKS
-
-A tight, underground septic tank with shallow distribution of the effluent
-in porous soil generally is the safest and least troublesome method of
-treating sewage upon the farm, while at the same time more or less of the
-irrigating and manurial value of the sewage may be realized.
-
-The late Professor Kinnicutt used to say that a septic tank is "simply a
-cesspool, regulated and controlled." The reactions described under the
-captions "How sewage decomposes" and "Cesspools" take place in septic
-tanks.
-
-In all sewage tanks, whatever their size and shape, a portion of the solid
-matter, especially if the sewage contains much grease, floats as scum on
-the liquid, the heavier solids settle to form sludge, while finely divided
-solids and matter in a state of emulsion are held in suspension. If the
-sludge is retained in the bottom of the tank and converted or partly
-converted into liquids and gases, the tank is called a septic tank and the
-process is known as septicization. The process is sometimes spoken of as
-one of digestion or rotting.
-
-=History.=--Prototypes of the septic tank were known in Europe nearly 50
-years ago. Between 1876 and 1393 a number of closed tanks with submerged
-inlets and outlets embodying the principle of storage of sewage and
-liquefaction of the solids were built in the United States and Canada. It
-was later seen that many of the early claims for the septic process were
-extravagant. In recent years septic tanks have been used mainly in small
-installations, or, where employed in large installations, the form has
-been modified to secure digestion of the sludge in a separate compartment,
-thus in a measure obviating disadvantages that exist where septicization
-takes place in the presence of the entering fresh sewage.
-
-=Purposes.=--The purposes of a septic tank are to receive all the farm
-sewage, as defined on page 1, hold it in a quiet state for a time, thus
-causing partial settlement of the solids, and by nature's processes of
-decomposition insure, as fully as may be, the destruction of the organic
-matter.
-
-=Limitations.=--That a septic tank is a complete method of sewage
-treatment is a widespread but wrong impression. A septic tank does not
-eliminate odor and does not destroy all organic solids. On the contrary,
-foul odors developed, and of all the suspended matter in the sewage about
-one-third escapes with the effluent, about one-third remains in the tank,
-and about one-third only is destroyed or reduced to liquids and gases.
-The effluent is foul and dangerous. It may contain even more bacteria
-than the raw sewage, since the process involves intensive growths. As
-to the effects upon the growth and virulence of disease germs little is
-known definitely. It is not believed that such germs multiply under the
-conditions prevailing in a septic tank. If disease germs are present, many
-of their number along with other bacteria may pass through with the flow
-or may be enmeshed in the settling solids and there survive a long time.
-Hence the farmer should safeguard wells and springs from the seepage or
-discharges from a septic tank as carefully as from those of cesspools.
-
-=Further treatment of effluents.=--The effluent of a septic tank or any
-other form of sewage tank is foul and dangerous. Whether or not the
-solids are removed by screening, by short periods of rest, as in plain or
-modified forms of settling tanks, or by longer quiescence, as in septic
-tanks, the effluent generally requires further treatment to reduce the
-number of harmful organisms and the liability of nuisance. This further
-treatment usually consists of some mode of filtration. In the earliest
-example of such treatment the sewage was used to irrigate land by either
-broad flooding or furrow irrigation. By another method the sewage is
-distributed underground by means of drain tile laid with open joints, as
-illustrated in Figures 27 and 30.
-
-Artificial sewage filters are composed of coarse sand, screened gravel,
-broken stone, coke, or other material, and the sewage is applied in
-numerous ways. Since, filtration is essentially an oxidizing process
-requiring air, the sewage is applied intermittently in doses.[9]
-
-[9] Artificial filters of various types are well described and illustrated
-in Public Health Bulletin No. 101, "Studies of Methods for the Treatment
-and Disposal of Sewage--The Treatment of Sewage from Single Houses and
-Small Communities." U. S. Public Health Service, December, 1919.
-
-If properly designed and operated, filters of sand, coke, or stone are
-capable of excellent results. Under the most favorable conditions it is
-unwise to discharge the effluent of a sewage filter in the near vicinity
-of a source of water supply. Under farm conditions filters are usually
-neglected or the sewage is improperly applied, resulting in the clogging
-and befouling of sand filters and the discharge from stone filters of an
-effluent which is practically as dangerous and even more offensive than
-raw sewage. Moreover unless the filters are covered there are likely to be
-annoying odors, and there is always the possibility of disease germs being
-carried by flies where sewage is exposed in the vicinity of dwellings.
-Hence it seems more practical for the farmer, avoiding the expense of
-earth embankments or masonry sides and bottom for a filter bed, to waste
-the tank effluent beneath the surface of such area of land as is most
-suitable and available. This method of applying sewage to the soil or
-subsoil is often spoken of as subirrigation, but subsoil distribution of
-sewage is different in principle and practice from subirrigation for the
-increase of crop yields. Subirrigation is rarely successful unless the
-land is nearly level, the topsoil porous and underlaid with an impervious
-stratum to hold the water within reach of plant roots, and unless a
-relatively large quantity of water is used and the work is skillfully
-done. On the other hand, the quantity of sewage on farms being small, it
-may be wasted in hilly ground, which should be as porous, deeply drained,
-and dry as possible.
-
-=Parts of a system.=--The four parts of a septic-tank installation with
-subsurface distribution of the effluent are outlined in Figure 17: (1)
-The house sewer from house to tank; (2) the sewage tank consisting of one
-or more chambers; (3) the sewer from tank to distribution field; (4) the
-distribution field, where the sewage is distributed and wasted, sometimes
-called the absorption field. These parts will be discussed in the order
-named, although the last should have the first consideration.
-
-[Illustration: Fig. 17.--Parts of a septic-tank installation]
-
-=House sewer.=--The length will vary with the slope of the ground and
-position of buildings, well, and distribution field. Fifty to 100 feet is
-a fair length; a greater is still more sanitary. Wherever possible the
-house sewer should be laid straight in line and grade. Figure 18 shows
-how this work may be done. Suppose the distance from A to E be 100 feet;
-that grade boards be set 25 feet apart crosswise of the trench at A, B,
-C, D, and E; that the ground at A be 4 feet lower than at E; that the top
-of the sewer be 2½ feet below the surface of the ground at A and 4½ feet
-below the surface of the ground at E; the fall of the sewer between A
-and E is 2 feet (4 + 2½ - 4½ = 2). If the fall in 100 feet be 2 feet, in
-25 feet it is one-fourth as much, or 6 inches. Hence, grade board B is 6
-inches higher than grade board A, C is 6 inches higher than B, and so on
-to E. The top edges when all the boards are set with a carpenter's level
-and fastened in position should be in line. The grade thus established
-may be any convenient height above the top of the proposed sewer, and the
-measuring stick used to grade the pipe is cut accordingly. This height is
-usually a certain number of whole feet. Fixing the line of the sewer is a
-mere matter of setting nails in the top edges of boards A and E directly
-over the center of the proposed sewer and tightly stretching a fish line
-or grade cord; nails should be set where the cord crosses boards B, C, and
-D.
-
-[Illustration: Fig. 18.--Setting line and grade for house sewer. To
-the observer at A the top edges of the grade boards appear as one; the
-half-driven nails are set to line]
-
-If the cellar or basement contains plumbing fixtures, the house sewer
-should enter 1 to 2 feet below the cellar floor. If all plumbing fixtures
-are on the floors above, the sewer may enter at no greater depth than
-necessary to insure protection from frost outside the cellar wall. Digging
-the trench and laying the pipe should begin at the tank or lower end. The
-large end of the pipes, called the hub, should face uphill, and the barrel
-of each pipe should have even bearing throughout its length. Sufficient
-earth should be removed from beneath the hubs to permit the joints to be
-made in a workmanlike manner.
-
-The house sewer may be vitrified salt-glazed sewer pipe, concrete pipe, or
-cast-iron soil pipe. The latter, with poured and calked lead joints makes
-a permanently water-tight and root-proof sewer, which always should be
-used where the vicinity of a well must be passed; 4, 5, or 6-inch pipe may
-be used, depending mainly on the fall and in less degree on the quantity
-of sewage discharge. As a measure of economy the 4-inch size is favored
-for iron pipe. If vitrified pipe is used, either the 5 or 6-inch size is
-preferable, as these sizes are made straighter than the 4-inch size and
-are less liable to obstruction. Of the two the 5-inch size is preferable.
-The fall in 100 feet should never be less than 2 feet for 4-inch size, 1½
-feet for 5-inch size, 1 foot for 6-inch size.
-
-Figure 19 shows methods of making good joints. _A_, _B_, _C_, _D_, _E_,
-_F_, and _G_ are ordinary sewer pipe joints; _H_, cast-iron soil pipe.
-
-[Illustration: Fig. 19.--How to make good joints. See text for directions
-and specifications]
-
- _A_ shows the use of a yarning iron to pack a small strand of jute into
- the joint space, thus centering the pipes and preventing the joint filler
- running inside. The joint surfaces should be free of dirt and oil. The
- jute is cut in lengths to go around the pipe; a small strand is soaked
- in neat Portland cement grout, then twisted and wrapped around the small
- end of the pipe to be pushed into the hub of the last pipe laid. After
- the pipe is pushed home the jute is packed evenly to a depth of not over
- ½ inch, leaving about 1½ inches for the joint filler. Old hemp rope or
- oakum dipped in liquid cement or paper may be used, in place of jute, and
- the packing may be done with a thin file or piece of wood.
-
- _B_ shows the use of a rubber mitten or glove to force Portland cement
- mortar into the joint space. The mortar should be thoroughly and freshly
- mixed in the proportion of one volume of cement to one volume of clean
- sand and should be pressed and tamped to fill the joint completely.
-
- _C_ shows a section of finished joint. The fresh mortar should not be
- loosened or disturbed when laying the next pipe.
-
- _D_ shows method of pouring a joint with grout, which is quicker,
- cheaper, and better than using a rubber mitten. A flexible sheet-metal
- form or mold, oiled to prevent the grout sticking, is clamped tightly
- around the joint and is completely filled with grout consisting of equal
- parts of Portland cement and clean sand mixed dry, to which water is
- added to produce a creamy consistency. The pipes should not be disturbed
- and the form should not be removed for 24 hours.
-
- _E_ shows a section of grouted joint, well rounded out, strong, and tight.
-
- _F_ shows the use of a pipe jointer for pouring a hot filler. The pipe
- jointer may be an asbestos or rubber runner or collar or a piece of
- garden hose clamped around the pipe leaving a small triangular opening
- at the top. The jointer is pressed firmly against the hub, and any
- small openings between the jointer and pipe are smeared with plastic
- clay to prevent leakage of the filler. A clay dike or funnel about 3
- inches high built around the triangular opening greatly aids rapid and
- complete filling of the joint space. The filler may be a commercially
- prepared bituminous compound or molten sulphur and fine sand. The former
- makes a slightly elastic joint; the latter a hard unyielding joint. With
- good workmanship both kinds of joint are practically water-tight and
- root-proof, and cost about the same as cement mortar joints. The filler
- is heated in an iron kettle over a wood, coke, or coal fire. It should
- be well stirred, and when at a free running consistency should be poured
- with a ladle large enough to fill the joint completely at one operation.
- As soon as the compound cools the jointer is removed. Sulphur-sand
- filler is made by mixing together dry and melting equal volumes of
- ordinary powdered sulphur and very fine clean sand, preferably the finest
- quicksand. A 5-inch sewer pipe joint requires from three-tenths to
- nine-tenths of a pound (according to the kind of pipe) of sulphur, worth
- 3 to 5 cents per pound, and a like quantity of sand. From ½ to 1½ pounds
- of bituminous filler are required for a 5-inch pipe joint.
-
- _G_ shows section of finished joint.
-
- _H_ shows the use of a pouring ladle in making lead joints in cast-iron
- soil pipe. This pipe is in lengths to lay 5 feet, and the metal of the
- barrel is ¼ inch thick. The joint is yarned with dry jute or oakum, as
- described above, and is poured full with molten, soft, pig lead to be
- afterwards driven tightly with hammer and calking tools. About ¾ pound
- of lead for each inch in diameter of pipe is required. Prepared cements
- of varying composition have proved effective and, as they require no
- calking, are economical. Among the best is a finely ground, thoroughly
- mixed compound of iron, sulphur, slag, and salt.
-
- _I_ is a homemade pipe jointer or clay roll for use in pouring molten
- lead. A strand of jute long enough to encircle the pipe and the ends to
- fold back, leaving an opening at the top, is covered with clay moistened,
- rolled and worked to form a plastic rope about 1 inch in diameter. The
- jointer gives the very best results but must be frequently moistened and
- worked to keep the clay soft and pliable. The jointer shown in _F_ is
- frequently used for pouring lead joints.
-
-Obstructions in house sewers are frequent. Among the causes are broken
-pipes, grade insufficient to give cleansing velocities, newspaper, rags,
-garbage, or other solids in the sewage, congealing of grease in pipes
-and main running traps (house sewer traps), and poor joint construction
-whereby rootlets grow into the sewer and choke it. Good grade and good
-construction with particular care given to the joints, will avert or
-lessen these troubles. The sewer should be perfectly straight, with the
-interior of the joints scraped or swabbed smooth. When the joint-filling
-material has set, the hollows beneath the hubs should be filled with good
-earth free of stones, well tamped or puddled in place. It is important
-that like material be used at the sides of the pipe and above it for at
-least 1 foot. The back filling may be completed with scraper or plow. No
-running trap should be placed on the house sewer, because it is liable
-to become obstructed and it prevents free movement of air through the
-sewer and soil stack. Conductors or drains for rain or other clean water
-should never connect with the house sewer, but should discharge into a
-watercourse or other outlet.
-
-Where obstruction of a house sewer occurs, use of some of the simple tools
-shown in Figure 20 may remedy the trouble. It is not likely that farmers
-will have these appliances, except possibly some of the augers; but some
-of them can be made at home or by a blacksmith, and most of them should
-be obtainable for temporary use from a well-organized town or city sewer
-department. The purpose of the several tools shown is indicated in the
-notation.
-
-=The tank.=--The septic tank should be in an isolated location at least
-50 to 100 feet from any dwelling. This is not always possible, because of
-flat ground, but in many such instances reasonable distance and fall may
-be secured by raising both the house sewer and tank and embanking them
-with earth. Cases are known where tanks adjoin cellar or basement walls
-and the top of the tank is used as a doorstep; in other cases tanks have
-been constructed within buildings. Such practices are bad. It is difficult
-to construct an absolutely water-tight masonry tank, and still more
-difficult to make it proof against the passage of sewer odors.
-
-[Illustration: Fig. 20.--Sewer-cleaning tools--how to use them. _A_,
-Ordinary 1½ or 2 inch auger welded to a piece 1¾-inch extra strong wrought
-pipe about 5 feet long: the stem is lengthened by adding other pieces of
-pipe with screw couplings, and is fitted with a pipe handle; all cleaning
-work should proceed upstream; _B_, twist or open earth auger; _C_, ribbon
-or closed earth auger; _D_, spiral or coal auger; _E_, ship auger; _F_,
-root cutter; _G_, sewer rods, with hook coupling, usually of hickory
-or ash 1 or 1¼ inches in diameter and 3 or 4 feet long; _H_, gouge for
-cutting obstructions; _I_, scoop for removing sand or similar material;
-_J_, claw, and _K_, screw, for removing paper and rags; _L_, scraper; _M_,
-wire brush for removing grease, drawn back and forth with a wire or rope;
-_N_, homemade wire brush (for a 5-inch sewer use a 1½-inch wooden pole
-to which is securely tacked a piece of heavy rubber, canvas, or leather
-belting or harness leather 5½ by 8 inches, spirally studded, as shown,
-with ordinary wire nails 1½ inches in length)]
-
-In Northern States, particularly in exposed situations, it is desirable to
-have the top of the tank 1 to 2 feet underground, thus promoting warmth
-and uniformity of temperature in the sewage. In Southern States this
-feature is less important, and the top of the tank may be flush with the
-ground. Every tank should be tightly covered, for the reasons above stated
-and to guard against the spread of odors, the transmission of disease
-germs by flies, and accidents to children.
-
-Considerable latitude is allowable in the design and construction of
-septic tanks. No particular shape or exact dimensions can be presented for
-a given number of people. One family of 5 persons may use as much water
-as another family of 10 persons; hence the quantity of sewage rather than
-the number of persons is the better basis of design. Exact dimensions
-are not requisite, for settlement and septicization proceed whether the
-sewage is held a few hours more or a few hours less. As to materials of
-construction, some form of masonry, either brick, building tile, rubble,
-concrete, or cement block, is employed generally. Vitrified pipe, steel,
-and wood have been used occasionally.
-
-[Illustration: Fig. 21.--One-chamber septic tank--does nothing more than
-a tight cesspool. Brick construction, heavily plastered inside; size
-suitable for 180 to 280 gallons of sewage daily (nominally 4 to 7 persons)]
-
-A plant for use all year round should have two chambers, one to secure
-settlement and septicization of the solids and the other to secure
-periodic discharge of the effluent by the use of an automatic sewage
-siphon. The first chamber is known as the settling chamber, the second
-as the siphon or dosing chamber. The siphon chamber is often omitted
-and the effluent is allowed to dribble away through subsurface tile, as
-illustrated in Figure 16. The latter procedure is not generally advised,
-but may be permissible where the land slopes sharply or has long periods
-of rest, as at summer houses and camps.
-
-The septic tanks shown in this bulletin are designed to satisfy the
-following conditions:
-
-1. Water consumption of 40 gallons per person per day of 24 hours.
-
-2. A detention period of about 24 hours; that is, the capacity of the
-settling chamber below the flow line is approximately equal to the
-quantity of sewage discharged from the house in 24 hours.
-
-3. Where a siphon chamber is provided, its size is such that the dose of
-sewage shall be approximately equal to 20 gallons per person; that is, the
-capacity of the siphon chamber between the discharge and low-water lines
-is roughly equal to the quantity of sewage discharged in 12 hours.
-
-A simple one-chamber brick tank suitable for a household discharging 180
-to 280 gallons of sewage daily is shown in Figure 21. A small two-chamber
-tank constructed of 24-inch vitrified pipe, suitable for a household
-discharging about 125 gallons of sewage daily, is shown in Figure 22. A
-typical two-chamber concrete tank is shown in Figure 23. Excepting the
-submerged outlet, all pipes within the tank and built into the masonry
-are cast-iron soil pipe with cast-iron fittings. Vitrified or concrete
-sewer pipe and specials are generally used, as they are frequently more
-readily obtainable and a slight saving in first cost may be effected. Cast
-iron is less liable to be broken in handling or after being set rigidly in
-masonry, and the joints are more easily made water-tight. The submerged
-outlet is midway of the depth of liquid in the settling chamber. The
-inside depth of the siphon chamber is the drawing depth of the siphon plus
-1 foot 5 inches.
-
-The following table gives the principal dimensions with quantities of
-materials for four sizes of tank as illustrated in Figure 23:
-
-
-_Dimensions and quantities for septic tanks_
-
-  --------+--------+--------+--------------------------------------------
-          |Quantity|        |          Settling chamber.
-          |   of   |Capacity|
-  Number  | sewage | below  +-------+-------+-------+----+-------+---+---
-    of    | in 24  |  flow  |Length.| Depth.|Width. | W. |   X.  | Y.| Z.
-  persons.| hours. |  line. |       |       |       |    |       |   |
-  --------+--------+--------+-------+-------+-------+----+-------+---+---
-          | Galls. | Galls. |Ft. In.|Ft. In.|Ft. In.| In.|Ft. In.|In.|In.
-      5   | 180-280|   240  | 4   0 |  5  0 | 2   0 |  6 | 2   0 | 4 | 6
-     10   | 320-480|   420  | 5   0 |  5  6 | 2   6 |  6 | 2   3 | 4 | 6
-     15   | 520-680|   620  | 5   6 |  6  0 | 3   0 |  8 | 2   6 | 5 | 8
-     20   | 720-960|   860  | 6   0 |  6  6 | 3   6 |  8 | 2   9 | 5 | 8
-  --------+--------+--------+-------+-------+-------+----+-------+---+---
-
-  --------+----------+------------------------------------------------
-          | Quantity |              Siphon chamber.
-  Number  |of sewage +-------+--------+--------+----+----+----+-------
-    of    |  in 24   |Length.| Depth. | Width. | A. | B. | C. |  D.
-  persons.|  hours.  |       |        |        |    |    |    |
-  --------+----------+-------+--------+--------+----+----+----+-------
-          |  Galls.  |Ft. In.| Ft. In.| Ft. In.| In.| In.| In.|  In.
-      5   | 180-280  | 5   0 |  2   8 |  2   0 |  3 |  4 | 15 | 18-1/4
-     10   | 320-480  | 8   0 |  2   8 |  2   6 |  3 |  4 | 15 | 20-1/4
-     15   | 520-680  | 8   8 |  2  10 |  3   0 |  4 |  4 | 17 | 20-1/4
-     20   | 720-960  |10   0 |  2  10 |  3   6 |  4 |  4 | 17 | 20-1/4
-  --------+----------+-------+--------+--------+----+----+----+-------
-
-  --------+---------+---------+--------+--------+---------+-------------
-          |Quantity |         |        |        |         |Reinforcement
-          |   of    |         |        |        |         | in top slab
-  Number  | sewage  |         |        |        |         |  (strip of
-    of    | in 24   |Concrete.| Cement.|  Sand. | Stone.  | heavy stock
-  persons.| hours.  |         |        |        |         |   fencing).
-          |         |         |        |        |         +-------+------
-          |         |         |        |        |         |Length.|Width.
-  --------+---------+---------+--------+--------+---------+-------+------
-          |  Galls. | Cu. yds.|  Bbls. |Cu. yds.| Cu. yds.| Ft.   | In.
-      5   | 180-280 | 3       |  4-1/2 | 1-1/3  | 2-2/3   | 10    |  32
-     10   | 320-480 | 4-1/4   |  6-1/4 | 2      | 3-3/4   | 14    |  39
-     15   | 520-680 | 6-2/3   |  9-3/4 | 3      | 6       | 15-2/3|  47
-     20   | 720-960 | 8       | 12     | 3-1/2  | 7       | 17-1/2|  56
-  --------+---------+---------+--------+--------+---------+-------+------
-
-=Siphons.=--Reference has already been made to the vital importance of air
-in sewage filtration. If the spaces within a filter or soil are constantly
-filled with water, air is excluded, and the action of the filtering
-material is merely that of a mechanical strainer with its clogging
-tendency. The purpose of a siphon is twofold: (1) To secure intermittent
-discharge, thus allowing a considerable period of time for one dose to
-work off in the soil and for air to enter the soil spaces before another
-flush is received; (2) to secure distribution over a larger area and in a
-more even manner than where the sewage is allowed to dribble and produce
-the conditions of the old-fashioned sink drain--namely, a small area of
-water-logged ground.
-
-[Illustration: Fig. 22.--Two-chamber septic tank, simple and inexpensive,
-constructed of 24-inch vitrified sewer pipe, size suitable for 125 gallons
-of sewage daily (nominally 3 persons). _A_, House sewer; _B_, settling
-chamber, made of double =T= branch and one length of straight pipe, each 3
-feet long and 2 feet in diameter, supported by 4 inches of concrete, all
-joints made water-tight; _C_, submerged outlet, consisting of a metal =T=
-slipped into the sewer-pipe branch; _D_, wire screen ¼-inch mesh; _E_,
-siphon chamber made of one =T= branch 3 feet long and 2 feet in diameter;
-_F_, siphon; _G_, 3-inch overflow; _H_, sewer to distribution field; _I_,
-tight cover with lifting ring; _J_, concrete protection around sewer-pipe
-hubs]
-
-[Illustration: Fig. 23.--Typical two-chamber concrete septic tank. (See
-table for dimensions and quantities for different sizes)]
-
-Three types of sewage siphon are shown in Figure 24. In all, the essential
-principle is the same: A column of air is entrapped between two columns
-of water; when the water in the chamber rises to a predetermined height,
-called the discharge line, the pressure forces out the confined air,
-destroying the balance and causing a rush of water through the siphon to
-the sewer. The entire operation is automatic and very simple. The siphons
-shown are commercial products made of cast-iron; they have few parts and
-none that move, and the whole construction is simple and durable. The
-table (fig. 24) lists stock sizes adapted to farm use. Manufacturers
-furnish full information for setting their siphons and putting them in
-operation. For example, take type 2, Figure 24: (1) Set siphon trap
-(=U=-shaped pipe) plumb, making E (height from floor to top of long leg)
-as specified; (2) fill siphon trap with water till it begins to run out at
-B; (3) place bell in position on top of long leg, and the siphon is ready
-for service. Do not fill vent pipe on side of bell.
-
-[Illustration: Fig. 24.--Three types of sewage siphon. The table gives
-dimensions for setting standard 3 and 4 inch siphons; also the appropriate
-size and grade of the sewer to carry the siphon discharge]
-
-The overhead siphon, type 3, Figure 24, may be installed readily in a tank
-already built by addition of an outlet sump. If properly set are handled,
-sewage siphons require very little attention and flush with certainty.
-Like all plumbing fixtures they are liable to stoppage if rags, newspaper,
-and similar solids get into the sewage. If fouling of the sniffing hole
-or vent prevents the entrance of sufficient air into the bell to lock the
-siphon properly, allowing sewage to dribble through, the remedy is to
-clean the siphon. Siphons are for handling liquid; sludge if allowed to
-accumulate will choke them.
-
-=Submerged outlet.=--The purpose of a submerged outlet is to take the
-outflow from a point between the sludge at the bottom and the floating
-solids or scum. The outlet in Figure 23 may be readily made of sheet
-metal by a tinsmith. Wrought iron or steel pipe with elbows or light lead
-pipe may be used, the pipe being set in the concrete and left in place.
-Sometimes a galvanized wire screen (¼-inch mesh) is fitted over the inner
-end to prevent large solids leaving the settling chamber and possibly
-clogging the siphon or distribution tile. If a screen is used it should be
-easily removable for cleaning.
-
-=Manhole frame and cover.=--The frame and cover shown in Figure 23 are
-stock patterns made of cast-iron and weighing about 250 pounds per set.
-The cover is 21 inches in diameter; it is tight and, on account of its
-weight, is unlikely to be disturbed by small children. The frame or rim
-is about 7 inches high and 31 inches in longest diameter. If desired,
-light cast-iron cistern or cesspool covers obtainable from plumbing supply
-houses, homemade slabs of reinforced concrete (see fig. 25), or wooden
-covers (see fig. 21) may be used.
-
-[Illustration: Fig. 25.--Homemade reinforced concrete covers. (1) Slabs
-placed crosswise permit uncovering the whole tank for cleaning, but as
-inspection is somewhat difficult, cleaning is the more likely to be
-neglected; (2) manhole, 18 inches square; cover, 22 by 22 by 3 inches
-thick, easy to make and to slide or lift from the opening]
-
-=Overflow.=--The purpose of an overflow is to pass sewage to the
-distribution field should the siphon stop working. The overflow (fig. 23)
-is a 3-inch riser pipe with top 3 inches above the discharge line and the
-bottom calked or cemented into the side outlet of a =T= branch. The run of
-the =T= branch should correspond with the size of the sewer from the tank
-to the distribution field. If this sewer is 4-inch pipe, a 4 by 3 inch
-=T= branch is used, the 4-inch spigot end of the siphon being calked or
-cemented into the branch, as shown in Figure 23; if the sewer is 5-inch, a
-5 by 3 inch =T= branch is used and connected to the siphon with a 5-inch
-to 4-inch reducer (in vitrified specials the equivalent is a 4-inch to
-5-inch increaser); if the sewer is 6-inch, a 6 by 3 inch =T= branch is
-used and connected to the siphon with a 6-inch to 4-inch reducer.
-
-=Concrete work.=--Before excavation for the tank is begun, two wooden
-forms should be built for shaping the inside of the settling and siphon
-chambers. In most instances the ground is fairly firm, so that the lines
-of excavation may conform to the outside dimensions of the tank, the
-back of the walls being built against the earth. The forms may be made
-of square-edged boards, braced and lightly nailed, as shown in Figure
-26. The forms should have no bottom. If it is desired to lay the sides
-and covering slab in one operation, the top of the forms must be boarded
-over. All pipe and manhole openings should be accurately placed and cut.
-The faces of the forms may be covered with paper or smeared with soap or
-grease to facilitate removal later.
-
-
-[Illustration: Fig. 26.--Forms for concrete work--how to use them]
-
- 1 Make the forms as shown and to the dimensions required by Figure 23
- and the table on p. 29; nails to be driven from the inside and left
- projecting for drawing with a claw hammer.
-
- 2. Excavate to lines 6 or 8 inches, as may be required, outside of the
- forms and to the depths required for both chambers.
-
- 3. Pour settling chamber floor and place form thereon.
-
- 4 Pour settling chamber walls to level of siphon chamber excavation,
- inserting submerged outlet pipe at the proper height. 5. Block siphon and
- short pipes to correct line and grade, and fill with concrete around the
- trap.
-
- 6. Pour siphon chamber floor, and place the form thereon.
-
- 7 Continue pouring all walls to their full height, inserting the inlet
- pipe when the concrete reaches that elevation.
-
- 8. Do not remove forms till the concrete is hard; with favorable weather,
- forms for walls only may be removed in 1 to 2 days; forms supporting a
- cover slab should remain 1 to 2 weeks.
-
-The ground should next be excavated to the proper depth for placing the
-floors in both chambers. The settling chamber floor, being the lower,
-should be placed first. Effort should be made to secure water-tight
-work, a feature of especial importance where leakage might endanger a
-well or spring. A concrete mixture of 1:2:4 is generally preferred (1
-volume cement, 2 volumes sand, 4 volumes stone). The ingredients should
-be of best quality and thoroughly mixed. The concrete should be poured
-promptly and worked with a spade or flat shovel to make the face smooth
-and eliminate pockets or voids within the mass.[10] Before the settling
-chamber floor has hardened the form should be set upon the floor and the
-concrete work continued up the sides. The pipe form for the submerged
-outlet should be set. When the side walls of the settling chamber have
-reached the bottom of the excavation for the siphon chamber, the siphon
-trap with its connecting branch and short piece of pipe should be set to
-proper line and grade and blocked in position. The floor of the siphon
-chamber should now be poured and the form for that chamber placed thereon,
-leaving a 6-inch or 8-inch space (according to the thickness of the
-division wall) between the ends of the two forms. Pouring of all side
-walls and the top slab should continue without stop, making the entire
-structure a monolith.
-
-[10] See footnote, p. 12. For more detailed information on form and
-concrete work the reader is referred to U. S. Department of Agriculture
-Farmers' Bulletin 1480-F, "Small Concrete Construction on the Farm."
-
-=Steel reinforcement.=--To stiffen the cover slab and guard against
-cracking, a little steel should be embedded in the concrete about 1 inch
-above the inside top. For this purpose a strip of heavy stock fencing is
-convenient and inexpensive. The line wires should be not less than No.
-10 gauge (about 1/8 inch) and the stay wires not less than No. 11 gauge.
-The reinforcement should be cut at manholes and fastened around manhole
-openings. If desired a standard wire-mesh reinforcement weighing about
-one-third of a pound per square foot may be used. Another alternative is
-to use 14-inch round rods, spacing the crosswise rods 6 inches apart and
-the lengthwise rods 12 inches apart. Poultry netting should not be used,
-because of its lightness.
-
-=Sewer from tank to distribution field.=--The length of this sewer depends
-on the situation of the field and the fall to it. The size of the sewer
-depends on the fall that can be obtained and the size of siphon. The table
-in Figure 24 shows the minimum fall at which 4-inch, 5-inch, and 6-inch
-sewers should be laid to take the discharge of the 3-inch and 4-inch
-siphons specified. The line and grade should be set in the same manner
-as for the house sewer (see fig. 18) and the construction should be as
-specified under that caption.
-
-=Distribution field.=--The distribution field or area is a sewage filter,
-and its selection and the manner of preparing it largely determine the
-success of subsoil disposal of sewage. As a rule farm land is not the best
-filtering material. It is too fine grained and fertile. Its tendency is to
-hold water too long, to admit insufficient air, to clog when even small
-quantities of sewage are applied. Hence the distribution area should be
-of liberal size--on the average 500 square feet for each person served.
-It should be dry, porous, and well drained--qualities that characterize
-sandy, gravelly, and light loam soils. It should be devoid of trees and
-shrubbery, thus giving sunlight and air free access. It should be located
-at least 300 feet downhill from a well or spring used for domestic water
-supply. Preferably it should slope gently, but sharp slopes are not
-prohibitive. Subsoiling the area is always desirable.
-
-Clay and other compact, impervious soils require special treatment. Less
-sewage can be applied to them, and hence it is well to have the area
-larger than 500 square feet per person. Clay should be subsoiled as deep
-as possible with a subsoil plow. In some instances dynamite has been
-of service in opening up the ground to still greater depth. Drainage
-and aeration should be further promoted by laying tile underdrains, as
-outlined in Figure 17 and shown in more detail in Figure 29.
-
-After the construction work the distribution areas should be raked
-and seeded with thick-growing grass. Grass is a safe crop; its water
-requirement is high, and it affords considerable protection from frost.
-Suitable grasses are redtop, white clover, blue grass, and Bermuda grass.
-The area may be pastured or kept as grass land.
-
-=Distribution system.=--Poor distribution of the sewage and failure to
-protect the joints of the distribution tile account for most of the
-failures. Each flush of the siphon should be so controlled that every part
-of the field will receive its due proportion. The distribution tile must
-be so laid that loose dirt will not fall or wash into the open joints.
-
-Different methods of dividing the flush and laying out the distribution
-tile are shown in Figures 27 and 30. Layouts 1, 2, and 3, Figure 27, are
-suitable for flat or gently sloping areas and are planned for the shallow
-siphon chambers tabulated on page 29. Layout 4, Figure 27, is suitable for
-steep slopes. In all four layouts use is made of one or more =V= branches
-(not =Y= branches) to divide the flow equally among the several lines. =V=
-branches, sometimes called breeches, should be leveled with a carpenter's
-level crosswise the ends of the legs, thus insuring equal division of the
-flow.
-
-The size and length of distribution tile and the spacing of the lines
-or runs admit of considerable variation in different soils. Water sinks
-rapidly in gravels and sands, and hence larger tile and shorter length are
-permissible than in close soils. Lateral movement is slow in all soils,
-but extends farther in gravels and sands than in close soils. In average
-soils the effect on vegetation 5 feet away from the line is practically
-nil.
-
-From these considerations, with the siphon dose 20 gallons per person, it
-is usually a safe rule to provide 50 feet of 3-inch tile for each person
-served and to lay the lines 10 feet apart. Such provision gives a capacity
-within the bore of the tile lines about equal to the siphon dose, and
-as some sewage is wasted at each joint a reasonable factor of safety is
-provided. A spacing of 10 feet will, it is believed, permanently prevent
-the extension of lateral absorption from line to line, provided the area
-is fairly well drained. As between 3-inch and 4-inch tile the smaller
-size costs less and is better calculated to taper the dose to small
-proportions. Four-inch tile is less likely to get out of alignment or to
-become clogged; a length of 28 feet has the same capacity in the bore as
-50 feet of 3-inch.
-
-[Illustration: Fig. 27.--Methods of laying distribution system: Methods
-1, 2, and 3 for flat or gently sloping land; method 4 for steep slopes
-(see also fig. 30); _A_, direction of slope; _B_, contour of field; _C_,
-sewer from tank, preferably size 5 inch, though 4 or 6 inch may be used,
-depending on the fall and the size of the siphon (see table, fig. 24);
-_D_, =V=-branch set to divide the flow exactly; _E_, reducer, to 4 inches;
-_F_, 1/8 bend, 4-inch; _G_, increaser, from 4 inches; _H_, increaser, 3
-to 4 inches; _I_, reducer, 4 to 3 inches; _J_, distribution tile, 3-inch;
-_K_, distribution tile, 4-inch]
-
-Good-quality drain tile in 1-foot lengths or second-quality sewer pipe
-in 2-foot lengths may be used. The lines are generally laid in parallel
-runs, but may be varied according to the topography. Layouts 1, 2, and 3,
-Figure 27, for flat or gently sloping land, run with the slope; layout 4,
-for steep slopes, runs back and forth along the contour in a series of
-long flat sweeps and short steep curves. The grade of the runs and sweeps
-should be gentle, rarely more than 10 or 12 inches in 100 feet. In layouts
-1, 2, and 3, Figure 27 especially, it is desirable that the last 20 feet
-of each run should be laid level or given a slight upward slope, thus
-guarding against undue flow of sewage to the lowest ends of the system.
-
-The runs should be laid no deeper than necessary to give clearance when
-plowing and prevent injury from frost. Ten inches of earth above the top
-of the tile is sufficient generally throughout the southern half of the
-United States and 18 inches generally in the North, but if the field
-is exposed or lacks a thick heavy growth of grass, the cover should be
-increased to 3 to 6 feet near the Canadian line. Where frost goes down 5
-to 7 feet, it is better to lay the tile at moderate depth and cover the
-runs with hay, straw, or leaves weighted down, removing the covering in
-the spring.
-
-Making the joints of the distribution tile demands especial attention.
-For a short distance on the upper end of each run the tile should be laid
-with ends abutting; the joint opening should be increased gradually to
-one-eighth inch and this increased to one-fourth in the last 20 feet of
-the run. All joints should be protected against the entrance of loose
-dirt. Four methods are shown in Figure 28. The lower end of each run
-should be closed with a brick or flat stone; or, what is better, an elbow
-or =T= branch may be placed on the end and vented above the surface of the
-ground, improving the flow of sewage, the ventilation of pipes, and the
-aeration of the soil.
-
-If the distribution tile must be laid in clay or other close, poorly
-drained soil, special treatment is necessary. A common method is to
-subsoil and underdrain the area thoroughly, as shown in Figure 29.
-It is not always possible to run the underdrain in lines between the
-distribution lines as shown in Figures 17 and 29, but it is a desirable
-thing to do, as the sewage must then receive some filtration through
-natural soil.
-
-In some instances it is sufficient to lay the distribution tile on a
-continuous bed, 8 to 12 inches thick, of coarse gravel, broken stone, or
-brick, slag, coke, or cinders and complete the refill as shown in Figure
-16 or 29.
-
-Figure 30 shows two other methods of controlling the flow on steep slopes
-and diverting proper proportions to the several lateral distributors laid
-along the contour of the field. This work can not be effected properly
-with =T= or =Y= branches; the flow tends to shoot straight ahead,
-comparatively little escaping laterally. To overcome this difficulty
-recourse is had to diverting boxes, of which two types are shown in Figure
-30. These boxes involve expense, but permit inspection and division of the
-flow according to the needs. They may be built of brick, stone, concrete,
-or even wood.
-
-Type 1 consists of a single box, into which all the lateral distributors
-head. It will be noted that the laterals enter at slightly different
-elevations, the two opposite the inlet sewer being the highest, the next
-two slightly lower, and the next two the lowest. This staggering of the
-outlets, in a measure, offsets the tendency of the flow to shoot across
-and escape by the most direct route.
-
-[Illustration: Fig. 28.--Four methods of protecting open joints in
-distribution lines--an all-important work. Sketches show cross-section and
-longitudinal views; the depth from the surface of the ground to the top of
-the tile is about 10 inches]
-
- 1. _A_, Subsoiled ground; _B_, 3 or 4 inch drain tile; _C_, strip of
- tarred paper about 6 inches wide and extending three-fourths the distance
- around the tile, allowing sewage to escape at the bottom; _D_, coarse
- sand, gravel, broken stone or brick, slag, cinders, or coke, the coarsest
- material placed around the tile (where the ground is naturally very
- porous and well drained, special filling in the trench may be omitted);
- _E_, natural soil.
-
- 2. Drain tile covered with a board laid flat, leaving the entire joint
- open.
-
- 3. Drain tile laid in stoneware gutter pieces and the joint covered
- with stoneware caps; gutter and cap pieces are inexpensive commercial
- products; their radius is longer than that of the outside of the tile,
- thus leaving open most of the joint space; the gutter aids in keeping the
- tile in line.
-
- 4. Vitrified sewer pipe with hubs facing downhill; the spigot end should
- be centered in the hub with a few small chinks or wedges.
-
-[Illustration: Fig. 29.---Close soils should be deeply subsoiled and
-underdrained. Porous, well-drained, air-filled soil is absolutely
-necessary. _A_, Subsoiled ground; _B_, 3 or 4 inch distribution tile; _C_,
-depth variable with the climate, 1¼ to 3½ feet; _D_, 4-inch underdrain;
-_E_, depth such as would prepare land for good crop production, generally
-3½ to 4 feet; _F_, stone or other coarse material; _G_, gravel grading
-upward to coarse sand; _H_, loose soil]
-
-Type 2 calls for one or more diverting boxes, according to the number of
-lateral distributors, and readily permits of wasting sewage at widely
-separated elevations and distances. The outlet pipes enter the box at
-slightly different elevations, for the reason already stated. With either
-type, should the outlets not be set at the right elevations, partial
-plugging of the holes and a little experimenting will enable one to
-equalize or proportion the discharges.
-
-[Illustration: Fig. 30.--Two systems of distribution on steep slopes--use
-of diverting box. _A_, Direction of slope; _B_, contour of field; _C_, 4,
-5, or 6 inch sewer from tank; _D_, diverting box; _E_, 3-inch or 4-inch
-distribution tile]
-
-=Sewage switch.=--The clogging of filters and soils after long-continued
-application of sewage has been previously referred to. It is, therefore,
-desirable to arrange the distribution system in two units with a switch
-between them, so that one area may drain and become aerated while the
-other is in use. This procedure is especially desirable where the soil is
-close and the installation of considerable size. It adds to the life and
-effectiveness of the distribution area and permits use of a plant in case
-it is necessary to repair, extend, or relay the tile in either unit.
-
-Arrangement in two units does not necessarily mean doubling the amount
-of tile and the area required in a single field. However desirable that
-may be, expense or lack of suitable ground will often prevent. With open
-sands and gravels and the assumed siphon dose of 20 gallons per person,
-15 to 20 feet of 4-inch tile in each unit for each person will usually
-suffice. With more compact soil it is advisable to more nearly double the
-requirements previously described. Two simple types of switch are shown in
-Figure 31. The switch should be turned frequently, certainly as often as
-is necessary to prevent saturation or bogginess of either area.
-
-[Illustration: Fig. 31.--Two simple types of sewage switch. _A_, Sewer
-from tank; _B_, switch box; _C_, cover; _D_, blade or stop board (in the
-left-hand box the direction of flow is controlled by placing the blade in
-alternate diagonal position; in the right-hand box the stop works in iron
-guides cast integral with a short piece of light-weight pipe set in the
-masonry; if desired the guides may be wood, fastened to the masonry with
-expansion bolts); _E_, sewer to distribution area; _F_ (right-hand box),
-alternate position of outlets or additional outlets if required]
-
-=A complete installation.=--The general layout and working plans of
-a complete installation built in 1915-16 are shown in Figure 32. The
-plant is larger than those heretofore considered, and involves several
-additional features. The settling chamber below the flow line has a
-capacity of 1,000 gallons, and on a basis of 40 gallons per person per day
-would serve 25 people.
-
-For many years sewage had been discharged through two 4-inch sewers to
-a cesspool in the rear of the house. The proximity of the well made it
-unsafe, and the overflow of the cesspool dribbled over the low portion of
-the garden and barnyard, cheating nuisance.
-
-The first step was to make borings with a soil auger in the pasture 400
-or 500 feet from the house. The borings showed a heavy clay soil to a
-depth of about 4 feet, underlaid with a sandy stratum only a few inches in
-thickness. It was decided to locate the distribution area in the pasture
-and to aid the seepage of sewage by digging numerous filter wells through
-the clay to the sandy stratum. Levels were taken and a contour plan
-prepared to serve for laying out the plant and establishing the grades.
-
-[Illustration: Fig. 32.--A complete installation for a large rural
-home. General layout on a contour plan and construction drawings. Note
-abandonment of old cesspool near the well and garden and removal of sewage
-to a lower and safer location in the pasture, where the treatment is
-subsurface distribution, aided by numerous filter wells about 4 feet deep
-filled with coarse gravel. Note that sludge is removed from the bottom of
-the settling chamber by opening the gate on the sludge drain]
-
-The septic tank is built in one corner of the barnyard, and a 5-inch sewer
-connects it with the old 4-inch sewers to the cesspool. All sewer-pipe
-joints were poured with a flexible jointing compound. The settling chamber
-is of hopper shape at the bottom, and a 4-inch sludge drain with gate
-provides for the gravity removal of sludge. The lower end of the sludge
-drain is above the surface of the ground and 9 feet below the flow line.
-The end is protected by a small retaining wall, and the sludge is readily
-caught in barrels and hauled out on the land for burial. The outlet is low
-enough to drain the settling chamber completely. If it is desired merely
-to force out the sludge, the drain may be brought to the surface under a
-head of 3 to 5 feet, discharging the sludge into a trench or drying bed,
-to be applied later to the land. A 2-inch waste pipe about mid-depth of
-the settling chamber permits drawing off the cleared portion of the sewage
-to the siphon chamber and from thence through another 2-inch waste pipe
-into the 6-inch sewer leading to the distribution field.
-
-The 4-inch siphon has a drawing depth of 33 inches, and as the siphon
-chamber is 4 feet wide by 6 feet long the dose is about 500 gallons. The
-siphon cost $35. The 6-inch sewer to the switch box falls about 6 inches
-in 50 feet. The distribution field was thoroughly subsoiled, and about 800
-feet of 3-inch tile was laid in each unit. At intervals of 25 feet along
-the distribution trenches 6-inch holes were dug through the clay stratum
-with a posthole digger. These holes were filled with stone and constitute
-the filter wells previously mentioned. All tile lines are surrounded with
-stone and coarse gravel, and the ground has been trimmed to give a uniform
-cover of 12 inches. All work was done by day labor in a thorough manner.
-As the men were doing other work at the same time the actual cost is not
-known, but it is believed the installation cost about $700.
-
-=Cost data.=--Reliable cost figures are difficult to estimate. Labor,
-materials, freight, haulage, and other items vary greatly in different
-localities. The septic tank shown in Figure 21 contains about 1,000 bricks
-and is estimated to cost $60 complete. The septic tank shown in Figure
-23 for 5 persons is estimated to cost $135; for 10 persons, $170; for
-15 persons, $240; for 20 persons, $280. In Maryland, in 1916, the cost
-of installing a septic tank similar to that shown in Figure 23 (for 5
-people), including 86 feet of 5-inch house sewer (55 feet of cast-iron
-pipe passing a well, and 31 feet of vitrified pipe) and 214 feet of
-second-quality 4-inch sewer pipe in the distribution area, was as follows:
-
-  Excavation, labor                            $7.50
-  Materials delivered                          46.60
-  Three-inch siphon, including freight         15.75
-  Construction, labor                          28.00
-  Supervision                                   5.00
-                                              ------
-     Total                                    102.85
-
-
-
-The quotations in the following table will be found useful in making
-estimates of cost:
-
-               _Cost per foot of pipe and drain tile_
-
-      (Approximate retail prices, Washington, D. C., February, 1928)
-
-  ------------------------------------+-----------------------------------
-                                      |          Size, in inches.
-         Kind of pipe.                +--------+--------+--------+--------
-                                      |   3    |   4    |   5    |   6
-  ------------------------------------+--------+--------+--------+--------
-                                      |        |        |        |
-    Extra heavy cast-iron soil pipe   | $0.23  | $0.31  | $0.40  | $0.48
-    Vitrified salt-glazed sewer pipe  |   .15  |   .15  |   .22½ |   .22½
-    Clay or shale drain tile          |   .06  |   .07  |   .10  |   .13
-                                      |        |        |        |
-  ------------------------------------+--------+--------+--------+--------
-
-The cost of cast-iron fittings may be roughly estimated as follows; Bends,
-one and one-half times the price of straight pipe; =T=-branches, two times
-the price of straight pipe; reducers, average of the prices of straight
-pipe at each end. The cost of clay bends, =T=-branches, reducers, and
-increasers may be roughly estimated at four times the price of straight
-pipe.
-
-=Operation.=--Attention must be given to every plant to insure success.
-Unusual or excessive foulness should be investigated. No chemicals should
-be used in a septic tank; garbage, rags, newspaper, and other solids
-not readily soluble in water should be kept out of sewers and tanks.
-The plant should be inspected often, noting particularly if the siphon
-is operating satisfactorily. If scum forms in the settling chamber it
-should be removed, and the sludge should be bailed or pumped out yearly.
-Frequently tanks are not cleaned out for three or four years, resulting in
-large quantities of solid matter going through to the distribution system
-and clogging it. Clogging may occur in the tile or in the adjacent soil.
-In either case the tile should be dug up, cleaned, and relaid. In some
-cases it has been found advantageous to relay the tile between the former
-lines. When sewage is applied to fairly porous land at the slow rate here
-recommended and the plant is well handled the tile lines should operate
-satisfactorily for many years. Liming heavy soils tends to loosen and keep
-them sweet.
-
-=Field data.=--As a basis for outlining or designing a suitable
-installation the following data should be known:
-
-  1. State, town, and whether in or near an incorporated municipality.
-
-  2. Usual number of persons to be served.
-
-  3. Average daily consumption of water in gallons.
-
-  4. Kind and depth of well, depth to water surface.
-
-  5. Character of soil, whether sandy, gravelly, loamy, clay, or muck.
-
-  6. Condition of soil as to drainage.
-
-  7. Character of subsoil.
-
-  8. Character of underlying rock and, if known, its depth below the
-       surface.
-
-  9. Depth to ground water at both house and field where sewage is to be
-       distributed.
-
- 10. Minimum winter temperature and approximate depth to which frost goes.
-
- 11. Number and kind of buildings to be connected with the sewer.
-
- 12. Number and kind of plumbing fixtures in each building.
-
- 13. Whether plumbing fixtures are to be put in the basement.
-
- 14. Depth of basement floor below ground.
-
-A plan to scale or a sketch with dimensions showing property lines,
-buildings, wells, springs, and drainage outlets should be furnished. The
-direction of surface drainage should be indicated by arrows. The slope of
-the land (vertical fall in a stated horizontal distance) should be given
-or if possible a contour plan (showing lines of constant elevation) should
-be furnished.
-
-
-GREASE TRAPS
-
-Farm sewage may contain from 10 to 30 pounds of grease and fats per person
-per year. This grease, originating mainly in the kitchen-sink, hinders
-septic action and clogs pipes, filters, and soils. Half the grease may be
-stopped by a septic tank, but the remainder goes into the distribution
-system, interfering with its action. A grease trap is a device for
-separating the grease from other wastes. The need for it may be lessened
-by carefully depositing waste greases and fats with the garbage; but
-one should always be installed if the kitchen is carelessly managed or
-discharges quantities of greasy water as at institutions, hotels, boarding
-houses, and bakeshops.
-
-[Illustration: Fig. 33.--Three types of grease trap. _A_, Ready-made
-grease trap; vitrified, salt-glazed earthenware; stock sizes: 10-inch
-diameter by 24 inches, 12-inch diameter by 24 inches, 15-inch diameter
-by 24 inches. _B_, Homemade grease trap; concrete or well-plastered
-brickwork; elbow, cross, and increaser to be recessed drainage fittings.
-_C_, Type of grease trap used at United States Army camps]
-
-A grease trap should have several times the capacity of the greatest
-quantity of greasy water discharged into it at one time, in order that
-the entering water shall be well cooled and the grease congealed. The
-solidified grease rises to the surface of the water in the trap and is
-retained therein. A dishpan of greasy water (2½ to 3 gallons) is the
-largest quantity likely to be discharged at one time from an ordinary
-kitchen-sink, hence the grease trap should have not less capacity than 7
-or 8 gallons. Figure 33 shows three types of grease traps suitable for
-farm use. In each the outlet pipe has small clearance at the bottom. This
-feature, together with the =V=-shaped hopper bottom, tends to create a
-scouring velocity and thus prevent the accumulation of coffee grounds and
-other solid wastes in the bottom of the trap. A grease trap should be
-close to the sink it is intended to serve, but not within the kitchen, on
-account of objectionable odors when the trap is opened to remove grease.
-It is good practice to place the trap in the cellar or basement, where it
-is safe from frost yet close to the source of grease.
-
-
-GENERAL PROCEDURE
-
-Do not waste money by digging and partly constructing, afterwards seeking
-information. Prepare a plan and work from it. Get in touch with your
-county agricultural and home demonstration agents. Advice may be obtained
-also from extension workers, State agricultural colleges, State and local
-boards of health, the United States Public Health Service, and the United
-States Department of Agriculture. Do not guess distances and levels.
-Use a measuring tape and some type of level--engineer's, architect's,
-drainage, hand, or carpenter's. Study this bulletin, and design, lay
-out, and construct in accordance therewith. Remember to: (1) Isolate the
-septic tank--locate it 50 to 100 or more feet from any dwelling and, if
-practicable, to the leeward of prevailing summer breezes; (2) locate the
-cesspool or sewage-distribution field downhill from the well or spring,
-and, if possible, 300 feet therefrom; (3) select dry, porous, deeply
-drained ground for disposal of all sewage; (4) do not apply more sewage to
-a given area of land than can be thoroughly absorbed and oxidized; (5) lay
-sewers straight and below the reach of frost, ventilate them thoroughly,
-and make the joints water-tight and root-proof.
-
-Makeshift methods, materials, or devices should be avoided or used
-sparingly. Do not place a vent pipe in the top of a cesspool or septic
-tank if near a dwelling. Siphon chamber and siphon may be omitted in those
-rare instances where it is feasible to discharge into salt water or into
-a large stream already badly polluted. Disposal of sewage in a running
-stream should be a last resort. Such practice endangers water supplies
-downstream, and unless the volume and velocity of flow are good nuisance
-may be created in the vicinity. Do not neglect inspection and operation.
-Clean out settling tanks yearly or oftener. All pipe lines below ground
-should be marked with iron or stone markers to facilitate examination,
-repair, or extension of the system.
-
-There is a general but erroneous belief that the cost of sewerage is
-little in the city but almost prohibitive in the country. All personal and
-Realty properties in one eastern city represent a valuation of $10,382
-per home, which pays $355 for sewers outside the cellar wall. An average
-farm in a Middle West State represents a valuation of $17,259. Is not
-the farmer justified in the small outlay required to dispose of the farm
-sewage? Because of the issuance of bonds and the apportionment of sewer
-assessments for a series of years the city dweller may have his burden
-distributed over a long period. The farmer does not pay interest on these
-obligations, and sewer work can be done more cheaply in the country than
-in the city.
-
-Safe disposal of farm sewage is not a passing fad but a vital necessity.
-Besides being an asset a good sewerage installation greatly promotes the
-wholesomeness and healthfulness of the farm. Moreover the benefits are
-far-reaching, because farm products go into every home, and farm and urban
-populations mingle freely.
-
-
-       ORGANIZATION OF THE UNITED STATES DEPARTMENT OF AGRICULTURE
-
-
-                                                           January 6, 1930
-
-  _Secretary of Agriculture_              Arthur M. Hyde.
-
-  _Assistant Secretary_                   R. W. Dunlap.
-
-  _Director of Scientific Work_           A. F. Woods.
-
-  _Director of Regulatory Work_           Walter G. Campbell.
-
-  _Director of Extension Work_            C. W. Warburton.
-
-  _Director of Personnel and Business     W. W. Stockberger.
-    Administration._
-
-  _Director of Information_               M. S. Eisenhower.
-
-  _Solicitor_                             E. L. Marshall.
-
-  _Weather Bureau_                        Charles F. Marvin, _Chief_.
-
-  _Bureau of Animal Industry_             John R. Mohler, _Chief_.
-
-  _Bureau of Dairy Industry_              O. E. Reed, _Chief_.
-
-  _Bureau of Plant Industry_              William A. Taylor, _Chief_.
-
-  _Forest Service_                        R. Y. Stuart, _Chief_.
-
-  _Bureau of Chemistry and Soils_         H. G. Knight, _Chief_.
-
-  _Bureau of Entomology_                  C. L. Marlatt, _Chief_.
-
-  _Bureau of Biological Survey_           Paul G. Redington, _Chief_.
-
-  _Bureau of Public Roads_                Thomas H. MacDonald, _Chief_.
-
-  _Bureau of Agricultural Economics_      Nils A. Olsen, _Chief_.
-
-  _Bureau of Home Economics_              Louise Stanley, _Chief_.
-
-  _Plant Quarantine and Control           Lee A. Strong, _Chief_.
-     Administration_
-
-  _Grain Futures Administration_          J. W. T. Duvel, _Chief_.
-
-  _Food, Drug, and Insecticide            Walter G. Campbell, _Director of
-     Administration_                        Regulatory Work, in Charge_.
-
-  _Office of Experiment Stations_         --------, _Chief_.
-
-  _Office of Cooperative Extension Work_  C. B. Smith, _Chief_.
-
-  _Library_                               Claribel R. Barnett, _Librarian_.
-
-
-                  U. S. GOVERNMENT PRINTING OFFICE: 1930
-
-  For sale by the Superintendent of Documents, ---- Price 10 cents
-            Washington, D. C.
-
-
-       *       *       *       *       *
-
-
-Transcriber Note
-
-Minor typos have been corrected. Illustrations were moved to prevent
-splitting paragraphs. Figure 19 was moved adjacent to the directions and
-specifications on Page 24. Due to space considerations in the text only
-version, emphasis of column headers were sometimes eliminated and some of
-the tables were rearranged. Produced from files generously made available
-by USDA through The Internet Archive. All resultant materials are placed
-in the Public Domain.
-
-
-
-
-
-
-
-
-End of the Project Gutenberg EBook of USDA Farmers' Bulletin No. 1227:
-Sewage and sewerage of farm home, by George Warren
-
-*** END OF THIS PROJECT GUTENBERG EBOOK USDA FARMERS' BULLETIN NO. 1227 ***
-
-***** This file should be named 63131-0.txt or 63131-0.zip *****
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-<pre>
-
-The Project Gutenberg EBook of USDA Farmers' Bulletin No. 1227: Sewage and
-sewerage of farm homes, by George Warren
-
-This eBook is for the use of anyone anywhere in the United States and most
-other parts of the world at no cost and with almost no restrictions
-whatsoever.  You may copy it, give it away or re-use it under the terms of
-the Project Gutenberg License included with this eBook or online at
-www.gutenberg.org.  If you are not located in the United States, you'll have
-to check the laws of the country where you are located before using this ebook.
-
-Title: USDA Farmers' Bulletin No. 1227: Sewage and sewerage of farm homes
-
-Author: George Warren
-
-Release Date: September 5, 2020 [EBook #63131]
-
-Language: English
-
-Character set encoding: UTF-8
-
-*** START OF THIS PROJECT GUTENBERG EBOOK USDA FARMERS' BULLETIN NO. 1227 ***
-
-
-
-
-Produced by Tom Cosmas from files generously made available
-by USDA through The Internet Archive. All are placed in
-the Public Domain.
-
-
-
-
-
-
-</pre>
-
-
-
-
-<div class="figcenter illowe17_125" id="cover" style="max-width: 20em; margin-bottom: 4em;">
-  <img class="w100" src="images/cover.png"  alt="USDA Farmers' Bulletin 1227: Sewage and Sewerage of Farm Homes, by George M. Warren" />
-
-
-<div class="bbox tdc smaller">
-United States Department of Agriculture<br />
-Farmers' Bulletin No. 1227<br />
-<br />
-SEWAGE and<br />
-SEWERAGE<br />
-of FARM<br />
-HOMES</div>
-</div>
-
-
-<div class="bbox" style="max-width: 25em; padding: 6px; margin-bottom: 4em;">
-<div class="dropcap">D</div>
-
-<p><span class="hidden">D</span>ISPOSAL OF FARM SEWAGE in a clean manner
-is always an important problem. The aims
-of this bulletin are twofold&mdash;(1) to emphasize basic
-principles of sanitation; (2) to give directions for
-constructing and operating home sewerage works
-that shall be simple, serviceable, and safe.</p>
-
-<p>Care in operating is absolutely necessary. No installation
-will run itself. Continued neglect ends in
-failure of even the best-designed, best-built plants.
-If the householder is to build and neglect, he might
-as well save expense and continue the earlier practice.</p>
-
-<table class="smaller" style="width: 100%;" summary="data">
-<tr class="bdt">
-  <td class="tdl">Washington, D. C.</td>
-  <td class="tdr">January, 1922<br />Revised October, 1928</td>
-</tr>
-</table>
-
-</div>
-
-<p><span class="pagenum"><a id="Page_1"></a>[ 1 ]</span></p>
-
-
-<div class="chapter">
-<h1 class="nobreak">SEWAGE AND SEWERAGE<br />OF FARM HOMES</h1>
-
-<hr class="r20" />
-
-<p class="tdc"><span class="smcap">George M. Warren</span>,</p>
-
-<p class="tdc">Hydraulic Engineer, Bureau of Public Roads</p>
-
-<hr class="r20" />
-
-<div class="chapter">
-<h2 class="nobreak" id="CONTENTS">CONTENTS</h2>
-</div>
-
-<table class="tblcont" summary="TOC">
-<tr>
-  <td></td>
-  <td class="tdr smaller">Page.</td>
-</tr>
-<tr>
-  <td class="tdl">Introduction</td>
-  <td class="tdr"><a href="#INTRODUCTION">3</a></td>
-</tr>
-<tr>
-  <td class="tdl">Sewage, sewers, and sewerage defined</td>
-  <td class="tdr"><a href="#SEWAGE_SEWERS_AND_SEWERAGE_DEFINED">1</a></td>
-</tr>
-<tr>
-  <td class="tdl">Nature and quantity of sewage</td>
-  <td class="tdr"><a href="#NATURE_AND_QUANTITY_OF_SEWAGE">2</a></td>
-</tr>
-<tr>
-  <td class="tdl">Sewage-borne diseases and their avoidance</td>
-  <td class="tdr"><a href="#SEWAGE-BORNE_DISEASES_AND_THEIR_AVOIDANCE">2</a></td>
-</tr>
-<tr>
-  <td class="tdl">How sewage decomposes</td>
-  <td class="tdr"><a href="#HOW_SEWAGE_DECOMPOSES">5</a></td>
-</tr>
-<tr>
-  <td class="tdl">Importance of air in treatment of sewage</td>
-  <td class="tdr"><a href="#IMPORTANCE_OF_AIR_IN_TREATMENT_OF_SEWAGE">7</a></td>
-</tr>
-<tr>
-  <td class="tdl">Practical utilities</td>
-  <td class="tdr"><a href="#PRACTICAL_UTILITIES">8</a></td>
-</tr>
-<tr>
-  <td class="tdl">Septic tanks</td>
-  <td class="tdr"><a href="#SEPTIC_TANKS">21</a></td>
-</tr>
-<tr>
-  <td class="tdl">Grease traps</td>
-  <td class="tdr"><a href="#GREASE_TRAPS">43</a></td>
-</tr>
-<tr>
-  <td class="tdl">General procedure</td>
-  <td class="tdr"><a href="#GENERAL_PROCEDURE">45</a></td>
-</tr>
-</table>
-
-</div>
-
-
-<hr class="chap" />
-
-<div class="chapter">
-<h2 class="nobreak" id="INTRODUCTION">INTRODUCTION</h2>
-</div>
-
-
-<p>The main purpose of home sewerage works is to get rid of sewage
-in such way as (1) to guard against the transmission of disease
-germs through drinking water, flies, or other means; (2) to avoid
-creating nuisance. What is the best method and what the best outfit
-are questions not to be answered offhand from afar. A treatment
-that is a success in one location may be a failure in another. In
-every instance decision should be based upon field data and full
-knowledge of the local needs and conditions. An installation
-planned from assumed conditions may work harm. The householder
-may be misled as to the purification and rely on a protection that is
-not real. He may anticipate little or no odor and find a nuisance
-has been created.</p>
-
-
-<hr class="chap" />
-
-<div class="chapter">
-<h2 class="nobreak" id="SEWAGE_SEWERS_AND_SEWERAGE_DEFINED">SEWAGE, SEWERS, AND SEWERAGE DEFINED</h2>
-</div>
-
-
-<p>Human excrements (feces and urine) as found in closets and privy
-vaults are known as night soil. These wastes may be flushed away
-with running water, and there may be added the discharges from
-washbasins, bathtubs, kitchen and slop sinks, laundry trays, washing
-vats, and floor drains. This refuse liquid product is sewage,
-and the underground pipe which conveys it is a sewer. Since
-sewers carry foul matter they should be water-tight, and this feature
-of their construction distinguishes them from drains removing
-relatively pure surface or ground water. Sewerage refers to a
-system of sewers, including the pipes, tanks, disposal works, and
-appurtenances.</p>
-
-<hr class="chap" />
-
-<div class="chapter">
-<p><span class="pagenum"><a id="Page_2"></a>[ 2 ]</span></p>
-<h2 class="nobreak" id="NATURE_AND_QUANTITY_OF_SEWAGE">NATURE AND QUANTITY OF SEWAGE</h2>
-</div>
-
-
-<p>Under average conditions a man discharges daily about 3&frac12; ounces
-of moist feces and 40 ounces of urine, the total in a year approximating
-992 pounds.<a id="FNanchor_1" href="#Footnote_1" class="fnanchor">[1]</a> Feces consist largely of water and undigested or
-partially digested food; by weight it is 77.2 per cent water.[2] Urine
-is about 96,3 per cent water.<a id="FNanchor_2" href="#Footnote_2" class="fnanchor">[2]</a></p>
-
-<div class="footnote">
-
-<p><a id="Footnote_1" href="#FNanchor_1" class="label">[1]</a> Practical Physiological Chemistry, by Philip B. Hawk, 1916, pp. 221, 359.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_2" href="#FNanchor_2" class="label">[2]</a> Agriculture, by P. H. Storer, 1894, vol. 2, p. 70.</p></div>
-
-<p>The excrements constitute but a small part of ordinary sewage.
-In addition to the excrements and the daily water consumption of
-perhaps 40 gallons per person are many substances entering into
-the economy of the household, such as grease, fats, milk, bits of food,
-meat, fruit and vegetables, tea and coffee grounds, paper, etc. This
-complex product contains mineral, vegetable, and animal substances,
-both dissolved and undissolved. It contains dead organic matter
-and living organisms in the form of exceedingly minute vegetative
-cells (bacteria) and animal cells (protozoa). These low forms of
-life are the active agents in destroying dead organic matter.</p>
-
-<p>The bacteria are numbered in billions and include many species,
-some useful and others harmful. They may be termed tiny scavengers,
-which under favorable conditions multiply with great rapidity,
-their useful work being the oxidizing and nitrifying of dissolved
-organic matter and the breaking down of complex organic solids to
-liquids and gases. Among the myriads of bacteria are many of a
-virulent nature. These at any time may include species which are
-the cause of well-known infectious and parasitic diseases.</p>
-
-
-<hr class="chap" />
-
-<div class="chapter">
-<h2 class="nobreak" id="SEWAGE-BORNE_DISEASES_AND_THEIR_AVOIDANCE">SEWAGE-BORNE DISEASES AND THEIR AVOIDANCE</h2>
-</div>
-
-
-<p>Any spittoon, slop pail, sink drain, urinal, privy, cesspool, sewage
-tank, or sewage distribution field is a potential danger. A bit of
-spit, urine, or feces the size of a pin head may contain many hundred
-germs, all invisible to the naked eye and each one capable of producing
-disease. These discharges should be kept away from the food
-and drink of man and animals. From specific germs that may be
-carried in sewage at any time there may result typhoid fever, tuberculosis,
-cholera, dysentery, diarrhea, and other dangerous ailments,
-and it is probable that other maladies may be traced to human waste.
-From certain animal parasites or their eggs that may be carried in
-sewage there may result intestinal worms, of which the more common
-are the hookworm, roundworm, whipworm, eelworm, tapeworm, and
-seat worm.</p>
-
-<p>Sewage, drainage, or other impure water may contain also the
-causative agents of numerous ailments common to livestock, such as
-tuberculosis, foot-and-mouth disease, hog cholera, anthrax, glanders,
-and stomach and intestinal worms.</p>
-
-<p>Disease germs are carried by many agencies and unsuspectingly
-received by devious routes into the human body. Infection may
-come from the swirling dust of the railway roadbed, from contact
-with transitory or chronic carriers of disease, from green truck
-grown in gardens fertilized with night soil or sewage, from food
-prepared or touched by unclean hands or visited by flies or vermin,
-<span class="pagenum"><a id="Page_3"></a>[ 3 ]</span>
-from milk handled by sick or careless dairymen, from milk cans and
-utensils washed with contaminated water, or from cisterns, wells,
-springs, reservoirs, irrigation ditches, brooks, or lakes receiving the
-surface wash or the underground drainage from sewage-polluted soil.</p>
-
-<p>Many recorded examples show with certainty how typhoid fever and
-other diseases have been transmitted. A few indicating the responsibilities
-and duties of people who live in the country are cited here.</p>
-
-<p class="smaller">In August, 1889, a sister and two brothers aged 18, 21, and 23 years,
-respectively, and all apparently in robust health dwelt together in a
-rural village in Columbiana County, Ohio. Typhoid fever in particular
-virulent form developed after use of drinking water from a badly polluted
-surface source. The deaths of all three occurred within a space of 10
-days.</p>
-
-<p class="smaller">In September and October, 1899, 63 cases of typhoid fever, resulting
-in 5 deaths, occurred at the Northampton (Mass.) insane hospital. This
-epidemic was conclusively traced to celery, which was eaten freely in
-August and was grown and banked in a plot that had been fertilized in the
-late winter or early spring with the solid residue and scrapings from a
-sewage filter bed situated on the hospital grounds.</p>
-
-<p class="smaller">Some years ago Dr. W. W. Skinner, Bureau of Chemistry, Department of
-Agriculture, investigated the cause of an outbreak of typhoid fever in
-southwest Virginia. A small stream meandered through a narrow valley
-in which five 10-inch wells about 450 feet deep had been drilled in
-limestone formation. The wells were from 50 to 400 feet from the stream,
-from which, it was suspected, pollution was reaching the wells. In a pool
-in the stream bed approximately one-fourth mile above the wells several
-hundred pounds of common salt were dissolved. Four of the wells were cut
-off from the pump and the fifth was subjected to heavy pumping. The water
-discharged by the pump was examined at 15-minute intervals and its salt
-content determined over a considerable period of time. After the lapse of
-several 15-minute intervals the salt began to rise and continued to rise
-until the maximum was approximately seven times that at the beginning of
-the test, thus proving the facility with which pollution may pass a long
-distance underground and reach deep wells.</p>
-
-<p class="smaller">Probably no epidemic in American history better illustrates the dire
-results that may follow one thoughtless act than the outbreak of typhoid
-fever at Plymouth, Pa., in 1885. In January and February of that year the
-night discharges of one typhoid fever patient were thrown out upon the
-snow near his home. These, carried by spring thaws into the public water
-supply, caused an epidemic running from April to September. In a total
-population of about 8,000, 1,104 persons were attacked by the disease and
-114 died.</p>
-
-<p>Like plants and animals, disease germs vary in their powers of
-resistance. Some are hardy, others succumb easily. Outside the body
-most of them probably die in a few days or weeks. It is never certain
-when such germs may not lodge where the immediate surroundings
-are favorable to their life and reproduction. Milk is one of the common
-substances in which germs multiply rapidly. The experience at
-Northampton shows that typhoid-fever germs may survive several
-months in garden soil. Laboratory tests by the United States Public
-Health Service showed that typhoid-fever germs had not all succumbed
-after being frozen in cream 74 days. (Public Health Reports,
-Feb. 8, 1918, pp. 163-166.) Ravenel kept the spores of anthrax
-immersed for 244 days in the strongest tanning fluids without perceptible
-change in their vitality or virulence. (Annual Report, State
-Department of Health, Mass., 1916, p. 494.)</p>
-
-<p><b>Unsafe practices.</b>&mdash;Upon thousands of small farms there are no
-privies and excretions are deposited carelessly about the premises.
-A place of this character is shown in <a href="#fig1">figure 1</a>. Upon thousands of
-other farms the privy is so filthy and neglected that hired men and
-visitors seek near-by sheds, fields, and woods. A privy of this character
-<span class="pagenum"><a id="Page_4"></a>[ 4 ]</span>
-is shown in <a href="#fig2">figure 2</a>. These practices and conditions exist in
-every section of the country. They should be abolished.</p>
-
-<div class="figcenter illowp100" id="fig1" style="max-width: 29em;">
-  <img class="w100" src="images/fig1.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 1.</span>&mdash;One of many farms lacking the simplest sanitary convenience</div>
-</div>
-
-<p>Deserving of severe censure is the old custom of conveying excrements
-or sewage into abandoned wells or some convenient stream.
-Such a practice is indecent and unsafe. It is unnecessary and is
-contrary to the laws of most of the States.</p>
-
-<p>Likewise dangerous and even more disgusting is the old custom of
-using human excrement or sewage for the fertilization of truck land.
-Under no circumstances should such wastes be used on land devoted
-to celery, lettuce, radishes, cucumbers, cabbages, tomatoes, melons,
-or other vegetables, berries, or low-growing fruits that are eaten raw.
-Disease germs or particles of soil containing such germs may adhere
-to the skins of vegetables or fruits and infect the eater.</p>
-
-<p>Upon farms it is necessary to dispose of excretal wastes at no great
-distance from the dwelling. The ability and likelihood of flies
-carrying disease germs direct to the dinner table, kitchen, or pantry
-are well known. Vermin, household pets, poultry, and live stock may
-spread such germs. For these reasons, and also on the score of odor,
-farm sewage never should be exposed.</p>
-
-<p><b>Important safety measure.</b>&mdash;The farmer can do no other one thing
-so vital to his own and the public health as to make sure of the continued
-purity of the farm water supply. Investigations indicate
-that about three out of four shallow wells are polluted badly.</p>
-
-<p>Wells and springs are fed by ground water, which is merely natural
-drainage. Drainage water usually moves with the slope of the
-land. It always dissolves part of the mineral, vegetable, and animal
-matter of the ground over or through which it moves. In this way
-impurities are carried into the ground water and may reach distant
-wells or springs.</p>
-
-<div class="figright illowp44" id="fig2" style="max-width: 12.5625em;">
-  <img class="w100" src="images/fig2.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 2.</span>&mdash;The rickety, uncomfortable,
-  unspeakably foul, dangerous
-  ground privy. Neglected by the
-  owner, shunned by the hired man,
-  avoided by the guest, who, in
-  preference, goes to near-by fields
-  or woods, polluter of wells, meeting
-  place of house flies and disease
-  germs, privies of this character
-  abide only because of man's indifference</div>
-</div>
-
-<p>The great safeguards are clean ground and wide separation of the
-well from probable channels of impure drainage water. It is not
-<span class="pagenum"><a id="Page_5"></a>[ 5 ]</span>
-enough that a well or spring is 50 or 150 feet from a source of filth
-or that it is on higher ground. Given porous ground, a seamy ledge,
-or long-continued pollution of one plat of land, the zone of contamination
-is likely to extend long distances, particularly in downhill
-directions or when the water is low through drought or heavy pumping.
-Only when the surface of the
-water in a well or spring is at a
-higher level at all times than any
-near-by source of filth is there assurance
-of safety from impure seepage.
-Some of the foregoing facts are shown
-diagrammatically in <a href="#fig3">Figure 3</a>. <a href="#fig4">Figure 4</a> is typical of those insanitary,
-poorly drained barnyards that are
-almost certain to work injury to wells
-situated in or near them. Accumulations
-of filth result in objectionable
-odor and noxious drainage. <a href="#fig5">Figure 5</a>
-illustrates poor relative location of
-privy, cesspool, and well.</p>
-
-<p>Sewage or impure drainage water
-should never be discharged into or
-upon ground draining toward a well,
-spring, or other source of water supply.
-Neither should such wastes be
-discharged into openings in rock, an
-abandoned well, nor a hole, cesspool,
-vault, or tank so located that pollution
-can escape into water-bearing earth
-or rock. Whatever the system of
-sewage disposal, it should be entirely
-and widely separated from the water
-supply. Further information on locating
-and constructing wells is given in
-Farmers' Bulletin 1448-F, Farmstead
-Water Supply, copies of which may
-be had upon request to the Division
-of Publications, Department of Agriculture.</p>
-
-<p>Enough has been said to bring home to the reader these vital
-points:</p>
-
-<p class="smaller">1. Never allow the farm sewage or excrements, even in minutest quantity,
-to reach the food or water of man or livestock.</p>
-
-<p class="smaller">2. Never expose such wastes so that they can be visited by flies or other
-carriers of disease germs.</p>
-
-<p class="smaller">3. Never use such wastes to fertilize or irrigate vegetable gardens.</p>
-
-<p class="smaller">4. Never discharge or throw such wastes into a stream, pond, or abandoned
-well, nor into a gutter, ditch, or tile drainage system, which naturally must
-have outlet in some watercourse.</p>
-
-<p><span class="pagenum"><a id="Page_6"></a>[ 6 ]</span></p>
-
-<div class="figcenter illowp100" id="fig3" style="max-width: 27.9375em;">
-  <img class="w100" src="images/fig3.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 3.</span>&mdash;How an apparently good well may draw foul
-  drainage. Arrows show direction of ground water movement. <i>A-A</i>, Usual
-  water table (surface of free water in the ground); <i>B-B</i>, water table
-  lowered by drought and pumping from well <i>D</i>; <i>C-C</i>, water table further
-  lowered by drought and heavy pumping; <i>E-F</i>, level line from surface of
-  sewage in cesspool. Well <i>D</i> is safe until the water table is lowered to
-  <i>E</i>; further lowering draws drainage from the cesspool and, with the water
-  table at <i>C-C</i>, from the barn. The location of well <i>G</i> renders it unsafe
-  always.</div>
-</div>
-
-<div class="figcenter illowp100" id="fig4" style="max-width: 27.5em;">
-  <img class="w100" src="images/fig4.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 4.</span>&mdash;An insanitary, poorly drained barnyard. (Board of Health, Milwaukee.)
-  Liquid manure or other foul drainage is sure to leach into wells situated in or
-  near barnyards of this character</div>
-</div>
-
-
-
-<hr class="chap" />
-
-<div class="chapter">
-<h2 class="nobreak" id="HOW_SEWAGE_DECOMPOSES">HOW SEWAGE DECOMPOSES</h2>
-</div>
-
-
-<p>When a bottle of fresh sewage is kept in a warm room changes occur
-in the appearance and nature of the liquid. At first it is light in
-appearance and its odor is slight. It is well supplied with oxygen,
-since this gas is always found in waters exposed to the atmosphere.
-In a few hours the solids in the sewage separate mechanically according
-to their relative weights; sediment collects at the bottom, and a
-greasy film covers the surface. In a day's time there is an enormous
-development of bacteria, which obtain their food supply from the dissolved
-carbonaceous and nitrogenous matter. As long as free oxygen
-is present this action is spoken of as aërobic decomposition. There is
-a gradual increase in the amount of ammonia and a decrease of free
-oxygen. When the ammonia is near the maximum and the free oxygen
-is exhausted the sewage is said to be stale. Following exhaustion
-of the oxygen supply, bacterial life continues profuse, but it
-gradually diminishes as a result of reduction of its food supply and
-<span class="pagenum"><a id="Page_7"></a>[ 7 ]</span>
-the poisonous effects of its own wastes. In the absence of oxygen the
-bacterial action is spoken of as anaërobic decomposition. The sewage
-turns darker and becomes more offensive. Suspended and settled
-organic substances break apart or liquefy later, and various foul-smelling
-gases are liberated. Sewage in this condition is known as
-septic and the putrefaction that has taken place is called septicization.
-Most of the odor eventually disappears, and a dark, insoluble,
-mosslike substance remains as a deposit. Complete reduction of this
-deposit may require many years.</p>
-
-<div class="figcenter illowp100" id="fig5" style="max-width: 28.5625em;">
-  <img class="w100" src="images/fig5.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 5.</span>&mdash;Poor relative locations of privy, cesspool, and well. (State Department of
-  Health, Massachusetts.) Never allow privy, cesspool, or sink drainage to escape
-  into the plot of ground from which the water supply comes</div>
-</div>
-
-
-<hr class="chap" />
-
-<div class="chapter">
-<h2 class="nobreak" id="IMPORTANCE_OF_AIR_IN_TREATMENT_OF_SEWAGE">IMPORTANCE OF AIR IN TREATMENT OF SEWAGE</h2>
-</div>
-
-
-<p>Decomposition of organic matter by bacterial agency is not a
-complete method of treating sewage, as will be shown later under
-"Septic tanks." It is sufficient to observe here that in all practical
-methods of treatment aeration plays a vital part. The air or the
-sewage, or both, must be in a finely divided state, as when sewage
-percolates through the interstices of a porous, air-filled soil. The
-principle involved was clearly stated 30 years ago by Hiram F. Mills,
-a member of the Massachusetts State Board of Health. In discussing
-the intermittent filtration of sewage through gravel stones too
-coarse to arrest even the coarsest particles in the sewage Mr. Mills
-said: "The slow movement of the sewage in thin films over the
-surface of the stones, with air in contact, caused a removal for some
-months of 97 per cent of the organic nitrogenous matter, as well
-as 99 per cent of the bacteria."</p>
-
-<hr class="chap" />
-
-<div class="chapter">
-<p><span class="pagenum"><a id="Page_8"></a>[ 8 ]</span></p>
-
-<h2 class="nobreak" id="PRACTICAL_UTILITIES">PRACTICAL UTILITIES</h2>
-</div>
-
-
-<p>Previous discussion has dealt largely with basic principles of
-sanitation. The construction and operation of simple utilities embodying
-some of these principles are discussed in the following order:
-(1) Privies for excrements only; (2) works for handling wastes
-where a supply of water is available for flushing.</p>
-
-
-<h3>PIT PRIVY</h3>
-
-<p><a href="#fig6">Figure 6</a> shows a portable pit privy suitable for places of the
-character of that shown in <a href="#fig1">figure 1</a>, where land is abundant and
-cheap, and in such localities has proved practical. It provides, at
-minimum cost and with least attention, a fixed place for depositing
-excretions where the filth can not be tracked by man, spread by
-animals, reached by flies, nor washed by rain.</p>
-
-<div class="figcenter illowp93" id="fig6" style="max-width: 25.6875em;">
-  <a href="images/fig6lrg.png"><img class="w100" src="images/fig6.png"  alt="" /></a>
-  <div class="fig_caption"><span class="smcap">Fig. 6.</span>&mdash;Portable pit privy. For use where land is abundant and cheap, but unless
-  handled with judgment can not be regarded as safe. The privy is mounted on
-  runners for convenience in moving to new locations<br />Click on image to view larger size.</div>
-</div>
-
-<p>The privy is light and inexpensive and is placed over a pit in the
-ground. When the pit becomes one-half or two-thirds full the privy
-is drawn or carried to a new location. The pit should be shallow,
-preferably not over 2&frac12; feet in depth, and never should be located in
-wet ground or rock formation or where the surface or the strata slope
-toward a well, spring, or other source of domestic water supply.
-Besides standing on lower ground the pit should never be within 200
-feet of a well or spring. Since dryness in the pit is essential, the
-ground should be raised slightly and 10 or 12 inches of earth should
-be banked and compacted against all sides to shed rain water. The
-banking also serves to exclude flies. If the soil is sandy or gravelly,
-<span class="pagenum"><a id="Page_9"></a>[ 9 ]</span>
-the pit should be lined with boards or pales to prevent caving. The
-standard galvanized or black enameled wire cloth having 14 squares
-to the inch. The whole seat should be easily removable for cleaning.
-A little loose absorbent soil should be added daily to the accumulation
-in the pit, and when a pit is abandoned it should be filled
-immediately with dry earth mounded to shed water.</p>
-
-<p>A pit privy for use in field work, consisting of a framework of
-&frac12;-inch iron pipe for corner posts connected at the top with &frac14;-inch
-iron rods bent at the ends to right angles and hung with curtains of
-unbleached muslin, is described in Public Health Report of the
-United States Public Health Service, July 26, 1918.</p>
-
-<p>A pit privy, even if moved often, can not be regarded as safe.
-The danger is that accumulations of waste may overtax the purifying
-capacity of the soil and the teachings reach wells or springs.
-Sloping ground is not a guaranty of safety; the great safeguard lies
-in locating the privy a long distance from the water supply and as
-far below it as possible.</p>
-
-
-<h3>SANITARY PRIVY</h3>
-
-<p>The next step in evolution is the sanitary privy. Its construction
-must be such that it is practically impossible for filth or germs to
-be spread above ground, to escape by percolation underground, or to
-be accessible to flies, vermin, chickens, or animals. Furthermore, it
-must be cared for in a cleanly manner, else it ceases to be sanitary.
-To secure these desirable ends sanitarians have devised numerous
-types of tight-receptacle privy. Considering the small cost and the
-proved value of some of these types, it is to be regretted that few
-are seen on American farms.</p>
-
-<p>The container for a sanitary privy may be small&mdash;for example, a
-galvanized-iron pail or garbage can, to be removed from time to
-time by hand; it may be large, as a barrel or a metal tank mounted
-for moving; or it may be a stationary underground metal tank or
-masonry vault. The essential requirement in the receptacle is permanent
-water-tightness to prevent pollution of soils and wells.
-Wooden pails or boxes, which warp and leak, should not be used.
-Where a vault is used it should be shallow to facilitate emptying
-and cleaning. Moreover, if the receptacle should leak it is better
-that the escape of liquid should be in the top soil, where air and
-bacterial life are most abundant.</p>
-
-<p>Sanitary privies are classified according to the method used in
-treating the excretions, as dry earth, chemical, etc.</p>
-
-
-<h3>DRY-EARTH PRIVY</h3>
-
-<p><b>Pail type.</b>&mdash;A very serviceable pail privy is shown in Figures <a href="#fig7">7</a> and <a href="#fig8">8</a>.
-The method of ventilation is an adaptation of a system that
-has proved very effective in barns and other buildings here and
-abroad. A flue with a clear opening of 16 square inches rises from
-the rear of the seat and terminates above the ridgepole in a cowl or
-small roofed housing. Attached to this flue is a short auxiliary duct,
-4 by 15 inches, for removing foul air from the top of the privy. In
-<span class="pagenum"><a id="Page_10"></a>[ 10 ]</span>
-its upper portion on the long sides the cowl is open, allowing free
-movement of air across the top of the flue. In addition, the long
-sides of the cowl are open below next to the roof. These two openings,
-with the connecting vertical air passages, permit free upward
-movement of air through the cowl, as indicated by the arrows. The
-combined effect is to create draft from beneath the seat and from the
-top of the privy. The ventilating flue is 2 by 8 inches at the seat
-and 4 by 4 inches 5 feet above. The taper slightly increases the
-labor of making the flue, but permits a 2-inch reduction in the length
-of the building.</p>
-
-<div class="figcenter illowp100" id="fig7" style="max-width: 25.9375em;">
-  <a href="images/fig7lrg.png"><img class="w100" src="images/fig7.png"  alt="" /></a>
-  <div class="fig_caption"><span class="smcap">Fig. 7.</span>&mdash;Pail privy. Well constructed, ventilated, and screened. With proper care is sanitary
-  and unobjectionable<br />Click on image to view larger size.</div>
-</div>
-
-<p>In plan the privy is 4 by 4&frac12; feet. The sills are secured to durable
-posts set about 4 feet in the ground. The boarding is tight, and all
-vents and windows are screened to exclude insects. The screens may
-be the same as for pit privies or, if a more lasting material is desired,
-bronze or copper screening of 14 squares to the inch may be used.
-The entire seat is hinged, thus permitting removal of the receptacle
-and facilitating cleaning and washing the underside of the seat and
-the destruction of spiders and other insects which thrive in dark, unclean
-places. The receptacle is a heavy galvanized-iron garbage can.
-Heavy brown-paper bags for lining the can may be had at slight
-cost, and their use helps to keep the can clean and facilitates emptying.
-Painting with black asphaltum serves a similar purpose and
-protects the can from rust. If the contents are frozen, a little heat
-releases them. Of nonfreezing mixtures a strong brine made with
-common salt or calcium chloride is effective. Two and one-half to 3
-pounds of either thoroughly dissolved in a gallon of water lowers the
-freezing point of the mixture to about zero. Denatured alcohol or
-wood alcohol in a 25 per cent solution has a like low freezing point
-and the additional merit of being noncorrosive of metals. The can
-should be emptied frequently and the contents completely buried in
-a thin layer by a plow or in a shallow hand-dug trench at a point
-below and remote from wells and springs. Wherever intestinal disease
-exists the contents of the can should be destroyed by burning
-or made sterile before burial by boiling or by incorporation with a
-strong chemical disinfectant.</p>
-
-<p><span class="pagenum"><a id="Page_11"></a>[ 11 ]</span></p>
-
-<div class="figcenter illowp50" id="fig8" style="max-width: 26.4375em;">
-  <a href="images/fig8lrg.png"><img class="w100" src="images/fig8.png"  alt="" /></a>
-  <div class="fig_caption"><span class="smcap">Fig. 8.</span>&mdash;Pail privy<br />Click on image to view larger size.</div>
-</div>
-
-<p><span class="pagenum"><a id="Page_12"></a>[ 12 ]</span></p>
-
-<div class="figleft illowp49" id="fig9" style="max-width: 10.625em;">
-  <img class="w100" src="images/fig9.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 9.</span>&mdash;A well-ventilated privy in Montana</div>
-</div>
-
-<p>A privy ventilated in the manner before described is shown in
-<a href="#fig9">Figure 9</a>. The cowl, however, is open on four sides instead of two
-sides as shown in Figures <a href="#fig7">7</a> and <a href="#fig8">8</a>. The working drawings (figs.
-<a href="#fig7">7</a> and <a href="#fig8">8</a>) show that the construction of a privy of the kind is not
-difficult. <a href="#fig10">Figure 10</a> gives three suggestions whereby a privy may
-be conveniently located and the approach
-screened or partially hidden by
-latticework, vines, or shrubbery.</p>
-
-<p><b>Vault type.</b>&mdash;A primitive and yet
-serviceable three-seat dry-earth privy
-of the vault type is shown in <a href="#fig11">Figure 11</a>. This privy was constructed in
-1817 upon a farm at Westboro, Mass.
-The vault, made of bricks, was 6 feet
-long by 5 feet wide, and the bottom
-was 1 foot below the surface of the
-ground. The brickwork was laid in
-mortar, and the part below the ground
-surface was plastered on the inside.
-The outside of the vault was exposed
-to light and air on all four sides.
-Across the long side of the vault in
-the rear was a door swinging upward
-through which the night soil was removed
-two or three times a year,
-usually in the spring, summer, and
-fall and hauled to a near-by field,
-where it was deposited in a furrow,
-just ahead of the plow.</p>
-
-<p>Especial attention is called to the shallowness of the vault and the
-lightened labor of cleaning it out. The swinging door at the rear
-facilitated the sprinkling of dry soil or ashes over the contents of the
-vault, thus avoiding the necessity of carrying dirt and dust into the
-building and dust settling upon the seat. This privy was in use for
-nearly 100 years without renewal or repairs. When last seen the
-original seat, which always was kept painted, showed no signs of
-decay. Modern methods would call for a concrete vault of guaranteed
-water-tightness,<a id="FNanchor_3" href="#Footnote_3" class="fnanchor">[3]</a> proper ventilation and screening, and hinging
-the seat.</p>
-
-<div class="footnote">
-
-<p><a id="Footnote_3" href="#FNanchor_3" class="label">[3]</a> Directions for mixing and placing concrete to secure water-tightness are contained in
-Farmers' Bulletin 1279-F, "Plain concrete for farm use," and Farmers' Bulletin 1572-F,
-"Making Cellars Dry."</p></div>
-
-<p>Working drawings for a very convenient well-built two-seat vault
-privy are reproduced in Figures <a href="#fig12">12</a> and <a href="#fig13">13</a>. The essential features
-<span class="pagenum"><a id="Page_13"></a>[ 13 ]</span>
-are shown in sufficient detail to require little explanation. With
-concrete mixtures of 1:2:3 (1 volume cement, 2 volumes sand, 3
-volumes stone) for the vault and 1:2:4 for the posts there will be
-required a total of about 2 cubic yards of concrete, taking 3&frac12; barrels
-of cement, 1 cubic yard of sand, and 1&frac12; cubic yards of broken stone
-or screened gravel. The stone or gravel should not exceed 1 inch
-in diameter, except that a few cobblestones may be embedded where
-the vault wall is thickest, thus effecting a slight saving of materials.</p>
-
-<div class="figcenter illowp41" id="fig10" style="max-width: 18.9375em;">
-  <img class="w100" src="images/fig10.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 10.</span>&mdash;Screening the approach to a privy. <i>A</i>, Raised platform
-  with lattice sides, suitable for short distances, convenient, and easily
-  cleared of snow; <i>B</i>, walk hidden by latticework; <i>C</i>, walk inclosed by an arbor</div>
-</div>
-
-<p><span class="pagenum"><a id="Page_14"></a>[ 14 ]</span></p>
-
-
-<h3>CHEMICAL CLOSET</h3>
-
-<div class="figleft illowp43" id="fig11" style="max-width: 15.25em;">
-  <img class="w100" src="images/fig11.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 11.</span>&mdash;A primitive vault privy in Massachusetts.
-  Note the tight, shallow, easily cleaned vault. <i>A</i>,
-  Brick vault 5 by 6 feet, bottom about 1 foot in the
-  ground; <i>B</i>, water-tight plastering; <i>C</i>, rowlock
-  course of brick; <i>D</i>, door hinged at top; <i>E</i>, door
-  button; <i>F</i>, three-pane window hinged at top;
-  <i>G</i>, passageway</div>
-</div>
-
-<p>A type of sanitary privy in which the excrements are received directly
-into a water-tight receptacle containing chemical disinfectant
-is meeting with considerable favor for camps, parks, rural cottages,
-schools, hotels, and railway stations. These chemical closets,<a id="FNanchor_4" href="#Footnote_4" class="fnanchor">[4]</a> as they
-are called, are made in
-different forms and are
-known by various trade
-names. In the simplest
-form a sheet-metal receptacle
-is concealed in a
-small metal or wooden
-cabinet, and the closet is
-operated usually in much
-the same manner as the ordinary
-pail privy. These
-closets are very simple and
-compact, of good appearance,
-and easy to install or
-move from place to place.
-In another type, known as
-the chemical tank closet,
-the receptacle is a steel
-tank fixed in position underground
-or in a basement.
-The tank has a
-capacity of about 125 gallons
-per seat, is provided
-with a hand-operated agitator
-to secure thorough
-mixing of the chemical
-and the excretions, and
-the contents are bailed,
-pumped, or drained out
-from time to time.</p>
-
-<div class="footnote">
-
-<p><a id="Footnote_4" href="#FNanchor_4" class="label">[4]</a> Among publications on chemical closets are the following: "Chemical closets," Reprint
-No. 404 from the Public Health Reports, U. S. Public Health Service, June 29, 1917, pp.
-1017-1020: "The chemical closet," Engineering Bulletin No. 5, Mich. State Board of
-Health, October, 1916; Health Bulletin, Va. Department of Health, March, 1917, PP.
-214-219.</p></div>
-
-<p>Chemical closets, like
-every form of privy,
-should be well installed,
-cleanly operated, and frequently
-emptied, and the
-wastes should receive safe
-burial. With the exception
-of frequency of emptying,
-the same can be said
-of chemical tank closets. With both forms of closet thorough ventilation
-or draft is essential, and this is obtained usually by connecting
-the closet vent pipe to a chimney flue or extending it well above the
-ridgepole of the building. The contents of the container should
-always be submerged and very low temperatures guarded against.</p>
-
-<p><span class="pagenum"><a id="Page_15"></a>[ 15 ]</span></p>
-
-<div class="figcenter illowp95" id="fig12" style="max-width: 33.625em;">
-  <a href="images/fig12lrg.png"><img class="w100" src="images/fig12.png"  alt="" /></a>
-  <div class="fig_caption"><span class="smcap">Fig. 12.</span>&mdash;Two-seat vault privy<br />
-    Click on image to view larger size.</div>
-</div>
-
-<p>As to the germicidal results obtained in chemical closets, few data
-are available. A disinfecting compound may not sterilize more than
-a thin surface layer of the solid matter deposited. Experiments by
-Dr. Alvah H. Doty with various agents recommended and widely
-used for the bedside sterilization of feces showed "that at the end of
-20 hours of exposure to the disinfectant but one-eighth of an inch of
-the fecal mass was disinfected."<a id="FNanchor_5" href="#Footnote_5" class="fnanchor">[5]</a> Plainly, then, to destroy all bacterial
-and parasitic life in chemical closets three things are necessary:
-(1) A very powerful agent; (2) permeation of the fecal mass by the
-agent; (3) retention of its strength and potency until permeation is
-complete. The compounds or mixtures commonly used in chemical
-closets are of two general kinds: First, those in which some coal-tar
-product or other oily disinfectant is used to destroy germs and
-deodorize, leaving the solids little changed in form; second, those of
-the caustic class that dissolve the solids, which, if of sufficient
-strength and permeating every portion, should destroy most if not
-all bacterial life. Not infrequently the chemical solution is intended
-to accomplish disinfection, deodorization, and reduction to a liquid or
-semiliquid state. Ordinary caustic soda, costing about $1 in 10-pound pails,
-has given good results.</p>
-
-<div class="footnote">
-
-<p><a id="Footnote_5" href="#FNanchor_5" class="label">[5]</a> Annual Report, Mass. State Board of Health, 1914, p. 727.</p></div>
-
-<p><span class="pagenum"><a id="Page_16"></a>[ 16 ]</span></p>
-
-<p>A simple type of chemical closet is shown in <a href="#fig14">Figure 14</a>, and the
-essential features are indicated in the notation. These closets with
-vent pipe and appurtenances, ready for setting up, retail for $20 and
-upward. A chemical tank closet, retailing for about $80 per seat, is
-shown in <a href="#fig15">Figure 15</a>.</p>
-
-<p>The Department of Agriculture occasionally receives complaints
-from people who have installed chemical closets, usually on the score
-of odors or the cost of chemicals.</p>
-
-<div class="figcenter illowp100" id="fig13" style="max-width: 34.1875em;">
-  <a href="images/fig13lrg.png"><img class="w100" src="images/fig13.png"  alt="" /></a>
-  <div class="fig_caption"><span class="smcap">Fig. 13.</span>&mdash;Two-seat-vault privy. Note the shallow, water-tight, easily cleaned concrete vault<br />
-  Click on image to view larger size.</div>
-</div>
-
-
-<h3>DISINFECTANTS AND DEODORANTS</h3>
-
-<p>Disinfection is the destruction of disease germs. Sterilization is
-the destruction of all germs or bacteria, both the harmful and the
-useful. Antisepsis is the checking or restraining of bacterial
-growth. Deodorization is the destruction of odor. Unfortunately
-in practice none of these processes may be complete. The agent may
-be of inferior quality, may have lost its potency, or may not reach
-all parts of the mass treated. A disinfectant or germicide is an
-agent capable of destroying disease germs; an antiseptic is an agent
-merely capable of arresting bacterial growth, and it may be a dilute
-disinfectant; a deodorant is an agent that tends to destroy odor, but
-whose action may consist in absorbing odor or in masking the original
-odor with another more agreeable one.<a id="FNanchor_6" href="#Footnote_6" class="fnanchor">[6]</a></p>
-
-<div class="footnote">
-
-<p><a id="Footnote_6" href="#FNanchor_6" class="label">[6]</a> Those desiring more explicit information on disinfectants and the principles of
-disinfection are referred to U. S. Department of Agriculture Farmers' Bulletin 926, "Some
-Common Disinfectants," and 954, "The Disinfection of Stables." and to publications of
-the U. S. Public Health Service.</p></div>
-
-<p><span class="pagenum"><a id="Page_17"></a>[ 17 ]</span></p>
-
-<p>Of active disinfecting agents, heat from fire, live steam, and boiling
-water are the surest. The heat generated by the slaking of quicklime
-has proved effective with small quantities of excreta. Results
-of tests by the Massachusetts State Board of
-Health<a id="FNanchor_7" href="#Footnote_7" class="fnanchor">[7]</a> show that the preferable method consists
-in adding sufficient hot water (120° to 140°
-F.) to cover the excrement in the receptacle,
-then adding small pieces of fresh strong quicklime in amount equal
-to about one-third of the bulk of water and excrement combined,
-covering the receptacle, and allowing it to stand 1&frac12; hours or longer.</p>
-
-<div class="footnote">
-
-<p><a id="Footnote_7" href="#FNanchor_7" class="label">[7]</a> Annual Report, Mass. State Board of Health, 1914, pp. 727-729.</p></div>
-
-<table summary="Chemical Closet">
-<tr>
-  <td>
-  <div class="figcenter illowe6_5" id="fig14"><img class="w100" src="images/fig14.png"  alt="" /></div>
-  <div class="fig_caption"><span class="smcap">Fig. 14.</span>&mdash;Chemical
-  closet. <i>A</i>, Water-tight sheet-metal
-  container; <i>B</i>, metal
-  or wooden cabinet;
-  <i>C</i>, wooden or composition seat ring;
-  <i>D</i>, hinged cover; <i>E</i>,
-  3 or 4 inch ventilating
-  flue extending 18 inches above
-  roof or to a chimney;
-  <i>F</i>, air inlets</div>
-  </td>
-  <td>
-    <div class="figcenter illowe14_875" id="fig15"><img class="w100" src="images/fig15.png"  alt="" /></div>
-  <div class="fig_caption"><span class="smcap">Fig. 15.</span>&mdash;Chemical tank closet. <i>A</i>, Tank, 2 feet
-  3 inches by 4 feet 2 inches <sup>5</sup>&#8260;<sub>64</sub>th-inch iron,
-  seams welded; capacity, 125 gallons; <i>B</i>, 14-inch
-  covered opening for recharging and emptying
-  tank; <i>C</i>, 12-inch galvanized sheet-metal tube;
-  <i>D</i>, 4-inch sheet-metal ventilating pipe extending
-  above ridgepole or to a chimney; <i>E</i>, agitator
-  or paddle</div>
-  </td>
-</tr>
-</table>
-
-<p>Among chemical disinfectants a strong solution of sodium hydroxide
-(caustic soda) or potassium hydroxide (caustic potash, lye) is
-very effective and is useful in dissolving grease and other organic
-substances. Both chemicals are costly, but caustic soda is less expensive
-than caustic potash and constitutes most of the ordinary
-commercial lyes. Chlorinated lime (chloride of lime, bleaching
-powder) either in solution or in powdered form is valuable. For
-<span class="pagenum"><a id="Page_18"></a>[ 18 ]</span>
-the disinfection of stools of typhoid-fever patients the Virginia
-State Board of Health<a id="FNanchor_8" href="#Footnote_8" class="fnanchor">[8]</a> recommends thoroughly dissolving &frac12;
-pound of best chlorinated lime in 1 gallon of water and allowing
-the solution to cover the feces for at least 1 hour. The solution
-should be kept in well-stoppered bottles and used promptly, certainly
-within 2 or 3 days. Copper sulphate (blue vitriol, bluestone)
-in a 5 per cent solution (1 pound in 2&frac12; gallons of water) is a good
-but rather costly disinfectant. None of the formulas here given
-is to be construed as fixed and precise. Conditions may vary the
-proportions, as they always will vary the results. The reader should
-remember that few, if any, chemical disinfectants can be expected
-fully to disinfect or sterilize large masses of excrement unless the
-agent is used repeatedly and in liberal quantities or mechanical
-means are employed to secure thorough incorporation.</p>
-
-<div class="footnote">
-
-<p><a id="Footnote_8" href="#FNanchor_8" class="label">[8]</a> Health Bulletin, Va. State Board of Health, June, 1917, pp. 277-280.</p></div>
-
-<p>Among deodorants some of the drying powders mentioned below
-possess more or less disinfecting power. Chlorinated lime, though
-giving off an unpleasant odor of chlorine, is employed extensively.
-Lime in the form of either quicklime or milk of lime (whitewash)
-is much used and is an active disinfectant. To prepare milk of lime
-a small quantity of water is slowly added to good fresh quicklime
-in lumps. As soon as the quicklime is slaked a quantity of water,
-about four times the quantity of lime, is added and stirred thoroughly.
-When used as a whitewash the milk of lime is thinned as
-desired with water and kept well stirred. Liberal use of milk of
-lime in a vault or cesspool, though it may not disinfect the contents,
-is of use in checking bacterial growth and abating odor. To give the
-best results it should be used frequently, beginning when the vault or
-cesspool is empty. Iron sulphate (green vitriol, copperas) because
-of its affinity for ammonia and sulphides is used as a temporary
-deodorizer in vaults, cesspools, and drains; 1 pound dissolved in 4
-gallons of water makes a solution of suitable strength.</p>
-
-
-<h3>PREVENTION OF PRIVY NUISANCE</h3>
-
-<p>The following is a summary of simple measures for preventing a
-privy from becoming a nuisance:</p>
-
-<p class="smaller">1. Locate the privy inconspicuously and detached from the dwelling.</p>
-
-<p class="smaller">2. Make the receptacle or vault small, shallow, easy of access, and water-tight.</p>
-
-<p class="smaller">3. Clean out the vault often. Do not wait until excrement has accumulated
-and decomposition is sufficiently advanced to cause strong and foul odors.</p>
-
-<p class="smaller">4. Sprinkle into the vault daily loose dry soil, ashes, lime, sawdust, ground
-gypsum (land plaster), or powdered peat or charcoal. These will absorb liquid
-and odor, though they may not destroy disease germs.</p>
-
-<p class="smaller">5. Make the privy house rain-proof; ventilate it thoroughly, and screen all
-openings.</p>
-
-
-<h3>OBJECTION TO PRIVIES</h3>
-
-<p>All the methods of waste disposal heretofore described are open to
-the following objections:</p>
-
-<p class="smaller">1. They do not take care of kitchen slops and liquid wastes incident to a
-pressure water system.</p>
-
-<p class="smaller">2. They retain filth for a considerable period of time, with probability of
-odors and liability of transmission of disease germs.</p>
-
-<p class="smaller">3. They require more personal attention and care than people generally are
-willing to give.</p>
-
-<p><span class="pagenum"><a id="Page_19"></a>[ 19 ]</span></p>
-
-<p>By far the most satisfactory method yet devised of caring for
-sewage calls for a supply of water and the flushing away of all
-wastes as soon as created through a water-tight sewer to a place
-where they undergo treatment and final disposal.</p>
-
-
-<h3>KITCHEN-SINK DRAINAGE</h3>
-
-<p>A necessity in every dwelling is effective disposal of the kitchen-sink
-slops. This necessity ordinarily arises long before the farm
-home is supplied with water under pressure and the conveniences
-that go with it. Hence the first call for information on sewage disposal
-is likely to relate merely to sink drainage. This waste water,
-though it may not be as dangerous to health as sewage containing
-human excrements, is still a menace to the farm well and capable of
-creating disagreeable odor.</p>
-
-<div class="figcenter illowp100" id="fig16" style="max-width: 25.125em;">
-  <img class="w100" src="images/fig16.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 16.</span>&mdash;How to waste kitchen-sink drainage. <i>A</i>, Sink;
-  <i>B</i>, waste pipe; <i>C</i>, trap; <i>D</i>, clean-out; <i>E</i>, box filled with hay,
-  straw, sawdust, excelsior, coke, or other insulating material; <i>F</i>, 4-inch
-  vitrified sewer-pipe, hubs uphill, and joints made water tight for at
-  least 100 feet downhill from a well; <i>G</i>, 4-inch vitrified sewer pipe,
-  hubs downhill, joints slightly open, laid in an 18-inch bed of coarse
-  sand, gravel, stone, broken brick, slag, cinders, or coke; <i>H</i>, strip of tarred
-  paper on burlap or a thin layer of hay, straw, cornstalks, brush, or sods,
-  grass side down; <i>I</i>, 12 inches of natural soil; <i>J</i>, stone-filled pit.
-  As here illustrated, water is drawn by a pitcher or kitchen pump (<i>K</i>)
-  through a 1&frac14; or 1&frac12; inch galvanized-iron suction pipe (<i>L</i>) from a
-  cistern (<i>M</i>). The suction pipe should be laid below frost and on a smooth
-  upward grade from cistern to pump and be provided with a foot valve (<i>N</i>)
-  to keep the pump primed. If a foot valve is used, pump and pipe must be
-  safe from frost or other means than tripping the pump be provided for
-  draining the system</div>
-</div>
-
-<p>The usual method of disposing of sink slops is to allow them to
-dribble on or beneath the surface of the ground close to the house.
-Such drainage should be taken in a water-tight carrier at least 100
-feet downhill from the well and discharged below the surface of the
-ground. Every sink should be provided with a suitable screen to
-keep all large particles out of the waste pipe. An approved form of
-sink strainer consists of a brass plate bolted in position over the outlet
-and having at least 37 perforations not larger than one-fourth
-inch in diameter. Provided a sink is thus equipped and is given
-proper care and the land has fair slope and drainage, the waste water
-may be conducted away through a water-tight sewer and distributed
-<span class="pagenum"><a id="Page_20"></a>[ 20 ]</span>
-in the soil by means of a short blind drain. A simple installation,
-consisting of a kitchen-sink and pump and means of disposal as
-described, is shown in <a href="#fig16">Figure 16</a>.</p>
-
-
-<h3><a id="CESSPOOLS"></a>CESSPOOLS</h3>
-
-<p>Where farms have water under pressure an open or leaching cesspool
-is a common method of disposing of the sewage. Ordinary
-cesspools are circular excavations in the ground, lined with stone or
-brick laid without mortar. They vary from 5 to 10 feet in diameter
-and from 7 to 12 feet in depth. Sometimes the top is arched and
-capped at the ground surface by a cover of wood, stone, or cast-iron.
-At other times the walls are carried straight up and boards or planks
-are laid across for a cover, and the entire structure is hidden with a
-hedge or shrubbery.</p>
-
-<p>Except under the most favorable conditions the construction and
-use of a cesspool can not be condemned too strongly. They are only
-permissible where no other arrangement is possible. Leaching cesspools
-especially are open to these serious objections:</p>
-
-<p>1. Unless located in porous soil, stagnation is likely to occur,
-and failure of the liquid to seep away may result in overflow on
-the Surface of the ground and the creation of a nuisance and a
-menace.</p>
-
-<p>2. They retain a mass of filth in a decomposing condition deep in
-the ground, where it is but slightly affected by the bacteria and air
-of the soil. In seeping through the ground it may be strained, but
-there can be no assurance that the foul liquid, with little improvement
-in its condition, may not pass into the ground water and pollute
-wells and springs situated long distances away in the direction of
-underground flow.</p>
-
-<p>For the purpose of avoiding soil and ground-water pollution cesspools
-have been made of water-tight construction and the contents
-removed by bailing or pumping. Upon the farm, however, this type
-of construction has little to recommend it, for the reason that facilities
-for removing and disposing of the contents in a clean manner are
-lacking.</p>
-
-<p>In some instances cesspools have been made water-tight, the outflow
-being effected by three or four elbows or <b>T</b> branches set in the
-masonry near the top, with the inner ends turned down below the
-water surface, the whole surrounded to a thickness of several feet
-with stone or gravel intended to act as a filtering medium. Tests of
-the soil water adjacent to cesspools of this type show that no reliance
-should be placed upon them as a means of purifying sewage, the
-fatal defects being constant saturation with sewage and lack of air
-supply. To the extent that the submerged outlets keep back grease
-and solid matters the scheme is of service in preventing clogging of
-the pores of the surrounding ground.</p>
-
-<p>Where the ground about a cesspool has become clogged and water-logged,
-relief is often secured by laying several lines of drain tile
-at shallow depth, radiating from the cesspool. The ends of the pipes
-within the cesspool should turn down, and it is advantageous to surround
-the lines of pipe with stones or coarse gravel, as shown in
-<a href="#fig16">Figure 16</a> and discussed under "<a href="#SEPTIC_TANKS">Septic tanks.</a>" In this way not only
-<span class="pagenum"><a id="Page_21"></a>[ 21 ]</span>
-is the area of percolation extended, but aeration and partial purification
-of the sewage are effected.</p>
-
-<p>Where a cesspool is located at a distance from a dwelling and there
-is opportunity to lead a vent pipe up the side of a shed, barn, or any
-stable object it is advisable to do so for purposes of ventilation.
-Where the conditions are less favorable it may be best, because of
-the odor, to omit any direct vent pipe from the cesspool and rely for
-ventilation on the house sewer and main soil stack extending above
-the roof of the house.</p>
-
-<p>Cesspools should be emptied and cleaned at least once a year and
-the contents given safe burial or, with the requisite permission, wasted
-in some municipal sewerage system. After cleaning, the walls and
-bottom may be treated with a disinfectant or a deodorant.</p>
-
-
-<hr class="chap" />
-
-<div class="chapter">
-<h2 class="nobreak" id="SEPTIC_TANKS">SEPTIC TANKS</h2>
-</div>
-
-<p>A tight, underground septic tank with shallow distribution of the
-effluent in porous soil generally is the safest and least troublesome
-method of treating sewage upon the farm, while at the same time
-more or less of the irrigating and manurial value of the sewage may
-be realized.</p>
-
-<p>The late Professor Kinnicutt used to say that a septic tank is
-"simply a cesspool, regulated and controlled." The reactions described
-under the captions "<a href="#HOW_SEWAGE_DECOMPOSES">How sewage decomposes</a>" and "<a href="#CESSPOOLS">Cesspools</a>"
-take place in septic tanks.</p>
-
-<p>In all sewage tanks, whatever their size and shape, a portion of
-the solid matter, especially if the sewage contains much grease, floats
-as scum on the liquid, the heavier solids settle to form sludge, while
-finely divided solids and matter in a state of emulsion are held in
-suspension. If the sludge is retained in the bottom of the tank and
-converted or partly converted into liquids and gases, the tank is called
-a septic tank and the process is known as septicization. The process
-is sometimes spoken of as one of digestion or rotting.</p>
-
-<p><b>History.</b>&mdash;Prototypes of the septic tank were known in Europe
-nearly 50 years ago. Between 1876 and 1393 a number of closed
-tanks with submerged inlets and outlets embodying the principle of
-storage of sewage and liquefaction of the solids were built in the
-United States and Canada. It was later seen that many of the early
-claims for the septic process were extravagant. In recent years
-septic tanks have been used mainly in small installations, or, where
-employed in large installations, the form has been modified to secure
-digestion of the sludge in a separate compartment, thus in a measure
-obviating disadvantages that exist where septicization takes place in
-the presence of the entering fresh sewage.</p>
-
-<p><b>Purposes.</b>&mdash;The purposes of a septic tank are to receive all the farm
-sewage, as defined on <a href="#SEWAGE_SEWERS_AND_SEWERAGE_DEFINED">page 1</a>, hold it in a quiet state for a time, thus
-causing partial settlement of the solids, and by nature's processes
-of decomposition insure, as fully as may be, the destruction of the
-organic matter.</p>
-
-<p><b>Limitations.</b>&mdash;That a septic tank is a complete method of sewage
-treatment is a widespread but wrong impression. A septic tank
-does not eliminate odor and does not destroy all organic solids. On
-the contrary, foul odors developed, and of all the suspended matter in<span class="pagenum"><a id="Page_22"></a>[ 22 ]</span>
-the sewage about one-third escapes with the effluent, about one-third
-remains in the tank, and about one-third only is destroyed or reduced
-to liquids and gases. The effluent is foul and dangerous. It may
-contain even more bacteria than the raw sewage, since the process
-involves intensive growths. As to the effects upon the growth and
-virulence of disease germs little is known definitely. It is not believed
-that such germs multiply under the conditions prevailing in a
-septic tank. If disease germs are present, many of their number
-along with other bacteria may pass through with the flow or may be
-enmeshed in the settling solids and there survive a long time. Hence
-the farmer should safeguard wells and springs from the seepage or
-discharges from a septic tank as carefully as from those of cesspools.</p>
-
-<p><b>Further treatment of effluents.</b>&mdash;The effluent of a septic tank or any
-other form of sewage tank is foul and dangerous. Whether or not
-the solids are removed by screening, by short periods of rest, as in
-plain or modified forms of settling tanks, or by longer quiescence,
-as in septic tanks, the effluent generally requires further treatment
-to reduce the number of harmful organisms and the liability of
-nuisance. This further treatment usually consists of some mode of
-filtration. In the earliest example of such treatment the sewage
-was used to irrigate land by either broad flooding or furrow irrigation.
-By another method the sewage is distributed underground by
-means of drain tile laid with open joints, as illustrated in Figures
-<a href="#fig27">27</a> and <a href="#fig30">30</a>.</p>
-
-<p>Artificial sewage filters are composed of coarse sand, screened
-gravel, broken stone, coke, or other material, and the sewage is
-applied in numerous ways. Since, filtration is essentially an oxidizing
-process requiring air, the sewage is applied intermittently in
-doses.<a id="FNanchor_9" href="#Footnote_9" class="fnanchor">[9]</a></p>
-
-<div class="footnote">
-
-<p><a id="Footnote_9" href="#FNanchor_9" class="label">[9]</a> Artificial filters of various types are well described and illustrated in Public Health
-Bulletin No. 101, "Studies of Methods for the Treatment and Disposal of Sewage&mdash;The
-Treatment of Sewage from Single Houses and Small Communities." U. S. Public Health
-Service, December, 1919.</p></div>
-
-<p>If properly designed and operated, filters of sand, coke, or stone
-are capable of excellent results. Under the most favorable conditions
-it is unwise to discharge the effluent of a sewage filter in the
-near vicinity of a source of water supply. Under farm conditions
-filters are usually neglected or the sewage is improperly applied,
-resulting in the clogging and befouling of sand filters and the discharge
-from stone filters of an effluent which is practically as dangerous
-and even more offensive than raw sewage. Moreover unless the
-filters are covered there are likely to be annoying odors, and there
-is always the possibility of disease germs being carried by flies where
-sewage is exposed in the vicinity of dwellings. Hence it seems more
-practical for the farmer, avoiding the expense of earth embankments
-or masonry sides and bottom for a filter bed, to waste the tank
-effluent beneath the surface of such area of land as is most suitable
-and available. This method of applying sewage to the soil or subsoil
-is often spoken of as subirrigation, but subsoil distribution of
-sewage is different in principle and practice from subirrigation for
-the increase of crop yields. Subirrigation is rarely successful unless
-the land is nearly level, the topsoil porous and underlaid with an
-impervious stratum to hold the water within reach of plant roots,<span class="pagenum"><a id="Page_23"></a>[ 23 ]</span>
-and unless a relatively large quantity of water is used and the work
-is skillfully done. On the other hand, the quantity of sewage on
-farms being small, it may be wasted in hilly ground, which should be
-as porous, deeply drained, and dry as possible.</p>
-
-<p><b>Parts of a system.</b>&mdash;The four parts of a septic-tank installation with
-subsurface distribution of the effluent are outlined in <a href="#fig17">Figure 17</a>: (1)
-The house sewer from house to tank; (2) the sewage tank consisting
-of one or more chambers; (3) the sewer from tank to distribution
-field; (4) the distribution field, where the sewage is distributed and
-wasted, sometimes called the absorption field. These parts will be
-discussed in the order named, although the last should have the first
-consideration.</p>
-
-<div class="figcenter illowp100" id="fig17" style="max-width: 25.0625em;">
-  <img class="w100" src="images/fig17.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 17.</span>&mdash;Parts of a septic-tank installation</div>
-</div>
-
-<p><b>House sewer.</b>&mdash;The length will vary with the slope of the ground
-and position of buildings, well, and distribution field. Fifty to 100
-feet is a fair length; a greater is still more sanitary. Wherever possible
-the house sewer should be laid straight in line and grade. <a href="#fig18">Figure 18</a>
-shows how this work may be done. Suppose the distance from
-A to E be 100 feet; that grade boards be set 25 feet apart crosswise
-of the trench at A, B, C, D, and E; that the ground at A be 4 feet
-lower than at E; that the top of the sewer be 2&frac12; feet below the
-surface of the ground at A and 4&frac12; feet below the surface of the
-ground at E; the fall of the sewer between A and E is 2 feet
-(4 + 2&frac12; - 4&frac12; = 2). If the fall in 100 feet be 2 feet, in 25 feet it is
-one-fourth as much, or 6 inches. Hence, grade board B is 6 inches
-higher than grade board A, C is 6 inches higher than B, and so on
-to E. The top edges when all the boards are set with a carpenter's
-level and fastened in position should be in line. The grade thus
-established may be any convenient height above the top of the proposed
-sewer, and the measuring stick used to grade the pipe is cut
-accordingly. This height is usually a certain number of whole feet.
-Fixing the line of the sewer is a mere matter of setting nails in the
-top edges of boards A and E directly over the center of the proposed
-sewer and tightly stretching a fish line or grade cord; nails should
-be set where the cord crosses boards B, C, and D.</p>
-
-<p><span class="pagenum"><a id="Page_24"></a>[ 24 ]</span></p>
-
-<div class="figcenter illowp100" id="fig18" style="max-width: 24.5625em;">
-  <img class="w100" src="images/fig18.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 18.</span>&mdash;Setting line and grade for house sewer. To the observer at A the top edges of
-  the grade boards appear as one; the half-driven nails are set to line</div>
-</div>
-
-<p>If the cellar or basement contains plumbing fixtures, the house
-sewer should enter 1 to 2 feet below the cellar floor. If all plumbing
-fixtures are on the floors above, the sewer may enter at no greater
-depth than necessary to insure protection from frost outside the cellar
-wall. Digging the trench and laying the pipe should begin at the
-tank or lower end. The large end of the pipes, called the hub, should
-face uphill, and the barrel of each pipe should have even bearing
-throughout its length. Sufficient earth should be removed from beneath
-the hubs to permit the joints to be made in a workmanlike
-manner.</p>
-
-<p>The house sewer may be vitrified salt-glazed sewer pipe, concrete
-pipe, or cast-iron soil pipe. The latter, with poured and calked lead
-joints makes a permanently water-tight and root-proof sewer, which
-always should be used where the vicinity of a well must be passed;
-4, 5, or 6-inch pipe may be used, depending mainly on the fall and in
-less degree on the quantity of sewage discharge. As a measure of
-economy the 4-inch size is favored for iron pipe. If vitrified pipe is
-used, either the 5 or 6-inch size is preferable, as these sizes are made
-straighter than the 4-inch size and are less liable to obstruction. Of
-the two the 5-inch size is preferable. The fall in 100 feet should
-never be less than 2 feet for 4-inch size, 1&frac12; feet for 5-inch size, 1
-foot for 6-inch size.</p>
-
-<p><a id="fig19"></a><a href="#fig19">Figure 19</a> shows methods of making good joints. <i>A</i>, <i>B</i>, <i>C</i>, <i>D</i>, <i>E</i>,
-<i>F</i>, and <i>G</i> are ordinary sewer pipe joints; <i>H</i>, cast-iron soil pipe.</p>
-
-<div class="figleft illowp40" style="max-width: 17.1875em;">
-  <img class="w100" src="images/fig19.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 19.</span>&mdash;How to make good joints. See text for directions
-  and specifications</div>
-</div>
-
-<p class="smaller"><i>A</i> shows the use of a yarning iron to pack a small strand of jute into the
-joint space, thus centering the pipes and preventing the joint filler running
-inside. The joint surfaces should be free of dirt and oil. The jute is cut in
-lengths to go around the pipe; a small strand is soaked in neat Portland cement
-grout, then twisted and wrapped around the small end of the pipe to be pushed
-into the hub of the last pipe laid. After the pipe is pushed home the jute is
-packed evenly to a depth of not over &frac12; inch, leaving about 1&frac12; inches for the
-joint filler. Old hemp rope or oakum dipped in liquid cement or paper may be
-used, in place of jute, and the packing may be done with a thin file or piece
-of wood.</p>
-
-<p class="smaller"><i>B</i> shows the use of a rubber mitten or glove to force Portland cement mortar
-into the joint space. The mortar should be thoroughly and freshly mixed in the
-proportion of one volume of cement to one volume of clean sand and should be
-pressed and tamped to fill the joint completely.</p>
-
-<p class="smaller"><i>C</i> shows a section of finished joint. The fresh mortar should not be loosened
-or disturbed when laying the next pipe.</p>
-
-<p class="smaller"><i>D</i> shows method of pouring a joint with grout, which is quicker, cheaper, and
-better than using a rubber mitten. A flexible sheet-metal form or mold, oiled
-to prevent the grout sticking, is clamped tightly around the joint and is completely
-<span class="pagenum"><a id="Page_25"></a>[ 25 ]</span>
-filled with grout consisting of equal parts of Portland cement and clean
-sand mixed dry, to which water is added to produce a creamy consistency. The
-pipes should not be disturbed and the form should not be removed for 24 hours.</p>
-
-<p class="smaller"><i>E</i> shows a section of grouted joint, well rounded out, strong, and tight.</p>
-
-<p class="smaller"><i>F</i> shows the use of a pipe jointer for pouring a hot filler. The pipe jointer
-may be an asbestos or rubber runner or collar or a piece of garden hose clamped
-around the pipe leaving a small triangular opening at the top. The jointer is
-pressed firmly against the hub, and any small openings between the jointer and
-pipe are smeared with plastic clay to prevent leakage of the filler. A clay dike
-or funnel about 3 inches high built around the triangular opening greatly aids
-rapid and complete filling of the joint space. The filler may be a commercially
-prepared bituminous compound or molten sulphur and fine sand. The former
-makes a slightly elastic joint; the latter a hard unyielding joint. With good
-workmanship both kinds of joint are practically water-tight and root-proof,
-and cost about the same as cement mortar joints. The filler is heated in an iron
-kettle over a wood, coke, or coal fire. It should be well stirred, and when at a
-free running consistency should be poured with a ladle large enough to fill the
-joint completely at one operation. As soon as the compound cools the jointer
-is removed. Sulphur-sand filler is made by mixing together dry and melting
-equal volumes of ordinary powdered sulphur and very fine clean sand, preferably
-the finest quicksand. A 5-inch sewer pipe joint requires from three-tenths
-to nine-tenths of a pound (according to the kind of pipe) of sulphur,
-worth 3 to 5 cents per pound, and a like quantity of sand. From &frac12; to 1&frac12;
-pounds of bituminous filler are required for a 5-inch pipe joint.</p>
-
-<p class="smaller"><i>G</i> shows section of finished joint.</p>
-
-<p class="smaller"><i>H</i> shows the use of a pouring ladle in making lead joints in cast-iron soil pipe.
-This pipe is in lengths to lay 5 feet, and the metal of the barrel is &frac14; inch thick.
-The joint is yarned with dry jute or oakum, as described above, and is poured
-full with molten, soft, pig lead to be afterwards driven tightly with hammer and
-calking tools. About &frac34; pound of lead for each inch in diameter of pipe is
-required. Prepared cements of varying composition have proved effective and,
-as they require no calking, are economical. Among the best is a finely ground,
-thoroughly mixed compound of iron, sulphur, slag, and salt.</p>
-
-<p class="smaller"><i>I</i> is a homemade pipe jointer or clay roll for use in pouring molten lead. A
-strand of jute long enough to encircle the pipe and the ends to fold back, leaving
-an opening at the top, is covered with clay moistened, rolled and worked to form
-a plastic rope about 1 inch in diameter. The jointer gives the very best results
-but must be frequently moistened and worked to keep the clay soft and pliable.
-The jointer shown in <i>F</i> is frequently used for pouring lead joints.</p>
-
-<p>Obstructions in house sewers are frequent. Among the causes
-are broken pipes, grade insufficient to give cleansing velocities, newspaper,
-rags, garbage, or other solids in the sewage, congealing of
-grease in pipes and main running traps (house sewer traps), and
-poor joint construction whereby rootlets grow into the sewer and
-choke it. Good grade and good construction with particular care
-given to the joints, will avert or lessen these troubles. The sewer
-should be perfectly straight, with the interior of the joints scraped
-or swabbed smooth. When the joint-filling material has set, the
-hollows beneath the hubs should be filled with good earth free of
-stones, well tamped or puddled in place. It is important that like
-material be used at the sides of the pipe and above it for at least
-1 foot. The back filling may be completed with scraper or plow.
-No running trap should be placed on the house sewer, because it
-is liable to become obstructed and it prevents free movement of air
-through the sewer and soil stack. Conductors or drains for rain
-or other clean water should never connect with the house sewer,
-but should discharge into a watercourse or other outlet.</p>
-
-<p>Where obstruction of a house sewer occurs, use of some of the
-simple tools shown in <a href="#fig20">Figure 20</a> may remedy the trouble. It is not
-likely that farmers will have these appliances, except possibly some
-<span class="pagenum"><a id="Page_26"></a>[ 26 ]</span>
-of the augers; but some of them can be made at home or by a blacksmith,
-and most of them should be obtainable for temporary use from
-a well-organized town or city sewer department. The purpose of
-the several tools shown is indicated in the notation.</p>
-
-<p><b>The tank.</b>&mdash;The septic tank should be in an isolated location at least
-50 to 100 feet from any dwelling. This is not always possible,
-because of flat ground, but in many such instances reasonable distance
-and fall may be secured by raising both the house sewer and
-tank and embanking them with earth. Cases are known where tanks
-<span class="pagenum"><a id="Page_27"></a>[ 27 ]</span>
-adjoin cellar or basement walls and the top of the tank is used as a
-doorstep; in other cases tanks have been constructed within buildings.
-Such practices are bad. It is difficult to construct an absolutely
-water-tight masonry tank, and still more difficult to make it proof
-against the passage of sewer odors.</p>
-
-<div class="figcenter illowp72" id="fig20" style="max-width: 26.125em;">
-  <img class="w100" src="images/fig20.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 20.</span>&mdash;Sewer-cleaning tools&mdash;how to use them. <i>A</i>, Ordinary 1&frac12; or 2 inch auger
-  welded to a piece 1&frac34;-inch extra strong wrought pipe about 5 feet long: the stem
-  is lengthened by adding other pieces of pipe with screw couplings, and is fitted
-  with a pipe handle; all cleaning work should proceed upstream; <i>B</i>, twist or open
-  earth auger; <i>C</i>, ribbon or closed earth auger; <i>D</i>, spiral or coal auger; <i>E</i>, ship
-  auger; <i>F</i>, root cutter; <i>G</i>, sewer rods, with hook coupling, usually of hickory or
-  ash 1 or 1&frac14; inches in diameter and 3 or 4 feet long; <i>H</i>, gouge for cutting obstructions;
-  <i>I</i>, scoop for removing sand or similar material; <i>J</i>, claw, and <i>K</i>, screw, for
-  removing paper and rags; <i>L</i>, scraper; <i>M</i>, wire brush for removing grease, drawn
-  back and forth with a wire or rope; <i>N</i>, homemade wire brush (for a 5-inch sewer
-  use a 1&frac12;-inch wooden pole to which is securely tacked a piece of heavy rubber,
-  canvas, or leather belting or harness leather 5&frac12; by 8 inches, spirally studded, as
-  shown, with ordinary wire nails 1&frac12; inches in length)</div>
-</div>
-
-<p>In Northern States, particularly in exposed situations, it is desirable
-to have the top of the tank 1 to 2 feet underground, thus promoting
-warmth and uniformity of temperature in the sewage. In
-Southern States this feature is less important, and the top of the
-tank may be flush with the ground. Every tank should be tightly
-covered, for the reasons above stated and to guard against the spread<span class="pagenum"><a id="Page_28"></a>[ 28 ]</span>
-of odors, the transmission of disease germs by flies, and accidents to
-children.</p>
-
-<p>Considerable latitude is allowable in the design and construction
-of septic tanks. No particular shape or exact dimensions can be
-presented for a given number of people. One family of 5 persons
-may use as much water as another family of 10 persons; hence the
-quantity of sewage rather than the number of persons is the better
-basis of design. Exact dimensions are not requisite, for settlement
-and septicization proceed whether the sewage is held a few hours
-more or a few hours less. As to materials of construction, some form
-of masonry, either brick, building tile, rubble, concrete, or cement
-block, is employed generally. Vitrified pipe, steel, and wood have
-been used occasionally.</p>
-
-<div class="figleft illowp100" id="fig21" style="max-width: 17.3125em;">
-  <img class="w100" src="images/fig21.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 21.</span>&mdash;One-chamber septic tank&mdash;does nothing more
-  than a tight cesspool. Brick construction, heavily
-  plastered inside; size suitable for 180 to 280 gallons
-  of sewage daily (nominally 4 to 7 persons)</div>
-</div>
-
-<p>A plant for use all year round should have two chambers, one to
-secure settlement and septicization of the solids and the other to
-secure periodic discharge
-of the effluent
-by the use of an automatic
-sewage siphon.
-The first chamber is
-known as the settling
-chamber, the second as
-the siphon or dosing
-chamber. The siphon
-chamber is often omitted
-and the effluent is
-allowed to dribble away
-through subsurface tile,
-as illustrated in <a href="#fig16">Figure
-16</a>. The latter procedure
-is not generally
-advised, but may be
-permissible where the
-land slopes sharply or has long periods of rest, as at summer houses
-and camps.</p>
-
-<p>The septic tanks shown in this bulletin are designed to satisfy the
-following conditions:</p>
-
-<p>1. Water consumption of 40 gallons per person per day of 24
-hours.</p>
-
-<p>2. A detention period of about 24 hours; that is, the capacity of the
-settling chamber below the flow line is approximately equal to the
-quantity of sewage discharged from the house in 24 hours.</p>
-
-<p>3. Where a siphon chamber is provided, its size is such that the
-dose of sewage shall be approximately equal to 20 gallons per person;
-that is, the capacity of the siphon chamber between the discharge
-and low-water lines is roughly equal to the quantity of sewage discharged
-in 12 hours.</p>
-
-<p>A simple one-chamber brick tank suitable for a household discharging
-180 to 280 gallons of sewage daily is shown in <a href="#fig21">Figure 21</a>. A
-small two-chamber tank constructed of 24-inch vitrified pipe, suitable
-for a household discharging about 125 gallons of sewage daily, is
-shown in <a href="#fig22">Figure 22</a>. A typical two-chamber concrete tank is shown
-in <a href="#fig23">Figure 23</a>. Excepting the submerged outlet, all pipes within the
-tank and built into the masonry are cast-iron soil pipe with cast-iron
-<span class="pagenum"><a id="Page_29"></a>[ 29 ]</span>
-fittings. Vitrified or concrete sewer pipe and specials are generally
-used, as they are frequently more readily obtainable and a slight
-saving in first cost may be effected. Cast iron is less liable to be
-broken in handling or after being set rigidly in masonry, and the
-joints are more easily made water-tight. The submerged outlet is
-midway of the depth of liquid in the settling chamber. The inside
-depth of the siphon chamber is the drawing depth of the siphon
-plus 1 foot 5 inches.</p>
-
-<p>The following table gives the principal dimensions with quantities
-of materials for four sizes of tank as illustrated in <a href="#fig23">Figure 23</a>:</p>
-
-
-<p class="caption3nb"><a id="Dimensions_Table"></a>
-  <i>Dimensions and quantities for septic tanks.</i></p>
-
-<table class="smaller" summary="data">
-<tr>
-  <td class="bdt bdb" rowspan="2">Number of persons.</td>
-  <td class="bdl bdt bdb" rowspan="2">Quantity of sewage in 24 hours.</td>
-  <td class="bdl bdt" colspan="12">Settling chamber.</td>
-</tr>
-<tr>
-  <td class="bdl bdt bdb">Capacity below flow line.</td>
-  <td class="bdl bdt bdb" colspan="2">Length.</td>
-  <td class="bdl bdt bdb" colspan="2">Depth.</td>
-  <td class="bdl bdt bdb" colspan="2">Width.</td>
-  <td class="bdl bdt bdb">W.</td>
-  <td class="bdl bdt bdb" colspan="2">X.</td>
-  <td class="bdl bdt bdb">Y.</td>
-  <td class="bdl bdt bdb">Z.</td>
-</tr>
-<tr>
-  <td></td>
-  <td class="bdl"><i>Galls.</i></td>
-  <td class="bdl"><i>Galls.</i></td>
-  <td class="bdl"><i>Ft.</i></td>
-  <td><i>In.</i></td>
-  <td class="bdl"><i>Ft.</i></td>
-  <td><i>In.</i></td>
-  <td class="bdl"><i>Ft.</i></td>
-  <td><i>In.</i></td>
-  <td class="bdl"><i>In.</i></td>
-  <td class="bdl"><i>Ft.</i></td>
-  <td><i>In.</i></td>
-  <td class="bdl"><i>In.</i></td>
-  <td class="bdl"><i>In.</i></td>
-</tr>
-<tr>
-  <td>5</td>
-  <td class="bdl">180-280</td>
-  <td class="bdl">240</td>
-  <td class="bdl">4</td>
-  <td>0</td>
-  <td class="bdl">5</td>
-  <td>0</td>
-  <td class="bdl">2</td>
-  <td>0</td>
-  <td class="bdl">6</td>
-  <td class="bdl">2</td>
-  <td>0</td>
-  <td class="bdl">4</td>
-  <td class="bdl">6</td>
-</tr>
-<tr>
-  <td>10</td>
-  <td class="bdl">320-480</td>
-  <td class="bdl">420</td>
-  <td class="bdl">5</td>
-  <td>0</td>
-  <td class="bdl">5</td>
-  <td>6</td>
-  <td class="bdl">2</td>
-  <td>6</td>
-  <td class="bdl">6</td>
-  <td class="bdl">2</td>
-  <td>3</td>
-  <td class="bdl">4</td>
-  <td class="bdl">6</td>
-</tr>
-<tr>
-  <td>15</td>
-  <td class="bdl">520-680</td>
-  <td class="bdl">620</td>
-  <td class="bdl">5</td>
-  <td>6</td>
-  <td class="bdl">6</td>
-  <td>0</td>
-  <td class="bdl">3</td>
-  <td>0</td>
-  <td class="bdl">8</td>
-  <td class="bdl">2</td>
-  <td>6</td>
-  <td class="bdl">5</td>
-  <td class="bdl">8</td>
-</tr>
-<tr>
-  <td class="bdb">20</td>
-  <td class="bdl bdb">720-960</td>
-  <td class="bdl bdb">860</td>
-  <td class="bdl bdb">6</td>
-  <td class="bdb">0</td>
-  <td class="bdl bdb">6</td>
-  <td class="bdb">6</td>
-  <td class="bdl bdb">3</td>
-  <td class="bdb">6</td>
-  <td class="bdl bdb">8</td>
-  <td class="bdl bdb">2</td>
-  <td class="bdb">9</td>
-  <td class="bdl bdb">5</td>
-  <td class="bdl bdb">8</td>
-</tr>
-</table>
-
-<div class="vsmall">&nbsp;</div>
-
-<table class="smaller" summary="data">
-<tr>
-  <td class="bdt bdb" rowspan="2">Number of persons.</td>
-  <td class="bdl bdt bdb" rowspan="2">Quantity of sewage in 24 hours.</td>
-  <td class="bdl bdt" colspan="10">Siphon chamber.</td>
-  <td class="bdl bdt bdb" rowspan="2">Concrete.</td>
-  <td class="bdl bdt bdb" rowspan="2">Cement.</td>
-  <td class="bdl bdt bdb" rowspan="2">Sand.</td>
-  <td class="bdl bdt bdb" rowspan="2">Stone.</td>
-  <td class="bdl bdt bdb" colspan="2">Reinforcement in top slab (strip of heavy stock fencing).</td>
-</tr>
-<tr>
-  <td class="bdl bdt bdb" colspan="2">Length.</td>
-  <td class="bdl bdt bdb" colspan="2">Depth.</td>
-  <td class="bdl bdt bdb" colspan="2">Width.</td>
-  <td class="bdl bdt bdb">A.</td>
-  <td class="bdl bdt bdb">B.</td>
-  <td class="bdl bdt bdb">C.</td>
-  <td class="bdl bdt bdb">D.</td>
-  <td class="bdl bdt bdb">Length.</td>
-  <td class="bdl bdt bdb">Width.</td>
-</tr>
-<tr>
-  <td></td>
-  <td class="bdl"><i>Galls.</i></td>
-  <td class="bdl"><i>Ft.</i></td>
-  <td><i>In.</i></td>
-  <td class="bdl"><i>Ft.</i></td>
-  <td><i>In.</i></td>
-  <td class="bdl"><i>Ft.</i></td>
-  <td><i>In.</i></td>
-  <td class="bdl"><i>In.</i></td>
-  <td class="bdl"><i>In.</i></td>
-  <td class="bdl"><i>In.</i></td>
-  <td class="bdl"><i>In.</i></td>
-  <td class="bdl"><i>Cu. Yd.</i></td>
-  <td class="bdl"><i>Bbls.</i></td>
-  <td class="bdl"><i>Cu. Yd.</i></td>
-  <td class="bdl"><i>Cu. Yd.</i></td>
-  <td class="bdl"><i>Ft.</i></td>
-  <td class="bdl"><i>In.</i></td>
-</tr>
-<tr>
-  <td>5</td>
-  <td class="bdl">180-280</td>
-  <td class="bdl">5</td>
-  <td>0</td>
-  <td class="bdl">2</td>
-  <td>8</td>
-  <td class="bdl">2</td>
-  <td>0</td>
-  <td class="bdl">3</td>
-  <td class="bdl">4</td>
-  <td class="bdl">15</td>
-  <td class="bdl">18&frac14;</td>
-  <td class="bdl">3</td>
-  <td class="bdl">4&frac12;</td>
-  <td class="bdl">1&#8531;</td>
-  <td class="bdl">2&#8532;</td>
-  <td class="bdl">10</td>
-  <td class="bdl">32</td>
-</tr>
-<tr>
-  <td>10</td>
-  <td class="bdl">320-480</td>
-  <td class="bdl">8</td>
-  <td>0</td>
-  <td class="bdl">2</td>
-  <td>8</td>
-  <td class="bdl">2</td>
-  <td>6</td>
-  <td class="bdl">3</td>
-  <td class="bdl">4</td>
-  <td class="bdl">15</td>
-  <td class="bdl">20&frac14;</td>
-  <td class="bdl">4&frac14;</td>
-  <td class="bdl">6&frac14;</td>
-  <td class="bdl">2</td>
-  <td class="bdl">3&frac34;</td>
-  <td class="bdl">14</td>
-  <td class="bdl">39</td>
-</tr>
-<tr>
-  <td>15</td>
-  <td class="bdl">520-680</td>
-  <td class="bdl">8</td>
-  <td>8</td>
-  <td class="bdl">2</td>
-  <td>10</td>
-  <td class="bdl">3</td>
-  <td>0</td>
-  <td class="bdl">4</td>
-  <td class="bdl">4</td>
-  <td class="bdl">17</td>
-  <td class="bdl">20&frac14;</td>
-  <td class="bdl">6&#8532;</td>
-  <td class="bdl">9&frac34;</td>
-  <td class="bdl">3</td>
-  <td class="bdl">6</td>
-  <td class="bdl">15&#8532;</td>
-  <td class="bdl">47</td>
-</tr>
-<tr>
-  <td class="bdb">20</td>
-  <td class="bdl bdb">720-960</td>
-  <td class="bdl bdb">10</td>
-  <td class="bdb">0</td>
-  <td class="bdl bdb">2</td>
-  <td class="bdb">10</td>
-  <td class="bdl bdb">3</td>
-  <td class="bdb">6</td>
-  <td class="bdl bdb">4</td>
-  <td class="bdl bdb">4</td>
-  <td class="bdl bdb">17</td>
-  <td class="bdl bdb">20&frac14;</td>
-  <td class="bdl bdb">8</td>
-  <td class="bdl bdb">12</td>
-  <td class="bdl bdb">3&frac12;</td>
-  <td class="bdl bdb">7</td>
-  <td class="bdl bdb">17&frac12;</td>
-  <td class="bdl bdb">56</td>
-</tr>
-</table>
-
-
-<p><b>Siphons.</b>&mdash;Reference has already been made to the vital importance
-of air in sewage filtration. If the spaces within a filter or soil are
-constantly filled with water, air is excluded, and the action of the
-filtering material is merely that of a mechanical strainer with its
-clogging tendency. The purpose of a siphon is twofold: (1) To secure
-intermittent discharge, thus allowing a considerable period of
-time for one dose to work off in the soil and for air to enter the soil
-spaces before another flush is received; (2) to secure distribution
-over a larger area and in a more even manner than where the sewage
-is allowed to dribble and produce the conditions of the old-fashioned
-sink drain&mdash;namely, a small area of water-logged ground.</p>
-
-<p><span class="pagenum"><a id="Page_30"></a>[ 30 ]</span></p>
-
-<div class="figcenter illowp100" id="fig22" style="max-width: 25.375em;">
-  <img class="w100" src="images/fig22.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 22.</span>&mdash;Two-chamber septic tank, simple and inexpensive, constructed of 24-inch
-  vitrified sewer pipe, size suitable for 125 gallons of sewage daily (nominally 3
-  persons). <i>A</i>, House sewer; <i>B</i>, settling chamber, made of double <b>T</b> branch and
-  one length of straight pipe, each 3 feet long and 2 feet in diameter, supported by 4
-  inches of concrete, all joints made water-tight; <i>C</i>, submerged outlet, consisting of a
-  metal <b>T</b> slipped into the sewer-pipe branch; <i>D</i>, wire screen &frac14;-inch mesh; <i>E</i>, siphon
-  chamber made of one <b>T</b> branch 3 feet long and 2 feet in diameter; <i>F</i>, siphon;
-  <i>G</i>, 3-inch overflow; <i>H</i>, sewer to distribution field; <i>I</i>, tight cover with lifting ring;
-  <i>J</i>, concrete protection around sewer-pipe hubs</div>
-</div>
-
-<div class="figcenter illowp100" id="fig23" style="max-width: 24.875em;">
-  <img class="w100" src="images/fig23.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 23.</span>&mdash;Typical two-chamber concrete septic tank. (See table for dimensions and
-  quantities for different sizes)</div>
-</div>
-
-<p><span class="pagenum"><a id="Page_31"></a>[ 31 ]</span></p>
-
-<p>Three types of sewage siphon are shown in <a href="#fig24">Figure 24</a>. In all, the
-essential principle is the same: A column of air is entrapped between
-two columns of water; when the water in the chamber rises to a
-predetermined height, called the discharge line, the pressure forces
-out the confined air, destroying the balance and causing a rush of
-water through the siphon to the sewer. The entire operation is automatic
-and very simple. The siphons shown are commercial products
-made of cast-iron; they have few parts and none that move, and the
-whole construction is simple and durable. The table (<a href="#fig24">fig. 24</a>) lists
-stock sizes adapted to farm use. Manufacturers furnish full information
-for setting their siphons and putting them in operation. For
-example, take type 2, <a href="#fig24">Figure 24</a>: (1) Set siphon trap (<b>U</b>-shaped
-pipe) plumb, making E (height from floor to top of long leg) as
-specified; (2) fill siphon trap with water till it begins to run out at
-B; (3) place bell in position on top of long leg, and the siphon is
-ready for service. Do not fill vent pipe on side of bell.</p>
-
-<div class="figcenter illowp100" id="fig24" style="max-width: 25.1875em;">
-  <img class="w100" src="images/fig24.png"  alt="" />
-
-<table class="smaller" summary="data">
-<tr>
-  <td></td>
-  <td class="bdb" colspan="5">Type 2<br />INCHES</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Diameter of siphon</i></td>
-  <td class="bdl">A</td>
-  <td class="bdl">3</td>
-  <td class="bdl">3</td>
-  <td class="bdl">4</td>
-  <td class="bdl bdr">4</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Diameter of outlet</i></td>
-  <td class="bdl">B</td>
-  <td class="bdl">4</td>
-  <td class="bdl">4</td>
-  <td class="bdl">4</td>
-  <td class="bdl bdr">4</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Drawing depth</i></td>
-  <td class="bdl">C</td>
-  <td class="bdl">13</td>
-  <td class="bdl">15</td>
-  <td class="bdl">14</td>
-  <td class="bdl bdr">17</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Depth to floor</i></td>
-  <td class="bdl">D</td>
-  <td class="bdl">16&frac14;</td>
-  <td class="bdl">18&frac14;</td>
-  <td class="bdl">17&frac14;</td>
-  <td class="bdl bdr">20&frac14;</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Height above floor</i></td>
-  <td class="bdl">E</td>
-  <td class="bdl">7&frac14;</td>
-  <td class="bdl">9&frac14;</td>
-  <td class="bdl">8&frac34;</td>
-  <td class="bdl bdr">11&frac34;</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Clearance under bell</i></td>
-  <td class="bdl">F</td>
-  <td class="bdl">2</td>
-  <td class="bdl">2</td>
-  <td class="bdl">2</td>
-  <td class="bdl bdr">2</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Inside bottom of outlet, to discharge line</i></td>
-  <td class="bdl">G</td>
-  <td class="bdl">20&frac12;</td>
-  <td class="bdl">22&frac12;</td>
-  <td class="bdl">22&frac34;</td>
-  <td class="bdl bdr">25&frac34;</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Discharge line, to top of wall</i></td>
-  <td class="bdl">H</td>
-  <td class="bdl"></td>
-  <td class="bdl"></td>
-  <td class="bdl"></td>
-  <td class="bdl bdr"></td>
-</tr>
-<tr>
-  <td class="tdl"><i>Depth of outlet sump</i></td>
-  <td class="bdl">I</td>
-  <td class="bdl"></td>
-  <td class="bdl"></td>
-  <td class="bdl"></td>
-  <td class="bdl bdr"></td>
-</tr>
-<tr>
-  <td class="tdl"><i>Length and width of outlet sump</i></td>
-  <td class="bdl bdb">J</td>
-  <td class="bdl bdb"></td>
-  <td class="bdl bdb"></td>
-  <td class="bdl bdb"></td>
-  <td class="bdl bdb bdr"></td>
-</tr>
-<tr>
-  <td rowspan="6"><i>Diameter of carrier (R),<br />and  minimum fall (S)<br />in feet per 100 feet</i><br />
-    <div class="figcenter illowe12_875" id="fig24t">
-      <img class="w100" src="images/fig24t.png"  alt="" />
-    </div>  </td>
-  <td class="bdl bdt">R</td>
-  <td class="bdl bdt">4</td>
-  <td class="bdl bdt">4</td>
-  <td class="bdl bdt">4</td>
-  <td class="bdl bdt bdr">4</td>
-</tr>
-<tr>
-  <td class="bdl">S</td>
-  <td class="bdl">2 ft.</td>
-  <td class="bdl">2 ft.</td>
-  <td class="bdl">7 ft.</td>
-  <td class="bdl bdr">8 ft.</td>
-</tr>
-<tr>
-  <td class="bdl bdt">R</td>
-  <td class="bdl bdt">5</td>
-  <td class="bdl bdt">5</td>
-  <td class="bdl bdt">5</td>
-  <td class="bdl bdt bdr">5</td>
-</tr>
-<tr>
-  <td class="bdl">S</td>
-  <td class="bdl">1&frac12;&nbsp;ft.</td>
-  <td class="bdl">1&frac12;&nbsp;ft.</td>
-  <td class="bdl">2 ft.</td>
-  <td class="bdl bdr">2&frac12;&nbsp;ft.</td>
-</tr>
-<tr>
-  <td class="bdl bdt">R</td>
-  <td class="bdl bdt">6</td>
-  <td class="bdl bdt">6</td>
-  <td class="bdl bdt">6</td>
-  <td class="bdl bdt bdr">6</td>
-</tr>
-<tr>
-  <td class="bdl bdb">S</td>
-  <td class="bdl bdb">1 ft.</td>
-  <td class="bdl bdb">1 ft.</td>
-  <td class="bdl bdb">1 ft.</td>
-  <td class="bdl bdb bdr">1 ft.</td>
-</tr>
-</table>
-
-
-<table class="smaller" summary="data">
-<tr>
-  <td></td>
-  <td class="bdb" colspan="5">Type 3<br />INCHES</td>
-  <td></td>
-  <td class="bdb">Type 1<br />INCHES</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Diameter of siphon</i></td>
-  <td class="bdl">A</td>
-  <td class="bdl">3</td>
-  <td class="bdl">3</td>
-  <td class="bdl">4</td>
-  <td class="bdl bdr">4</td>
-  <td>&nbsp;</td>
-  <td class="bdl bdr">4</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Diameter of outlet</i></td>
-  <td class="bdl">B</td>
-  <td class="bdl"></td>
-  <td class="bdl"></td>
-  <td class="bdl"></td>
-  <td class="bdl bdr"></td>
-  <td></td>
-  <td class="bdl bdr"></td>
-</tr>
-<tr>
-  <td class="tdl"><i>Drawing depth</i></td>
-  <td class="bdl">C</td>
-  <td class="bdl">13</td>
-  <td class="bdl">15</td>
-  <td class="bdl">14</td>
-  <td class="bdl bdr">17</td>
-  <td></td>
-  <td class="bdl bdr">5</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Depth to floor</i></td>
-  <td class="bdl">D</td>
-  <td class="bdl">17</td>
-  <td class="bdl">17</td>
-  <td class="bdl">19</td>
-  <td class="bdl bdr">22</td>
-  <td></td>
-  <td class="bdl bdr">15</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Height above floor</i></td>
-  <td class="bdl">E</td>
-  <td class="bdl">13</td>
-  <td class="bdl">13</td>
-  <td class="bdl">15</td>
-  <td class="bdl bdr">18</td>
-  <td></td>
-  <td class="bdl bdr">19</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Clearance under bell</i></td>
-  <td class="bdl">F</td>
-  <td class="bdl"></td>
-  <td class="bdl"></td>
-  <td class="bdl"></td>
-  <td class="bdl bdr"></td>
-  <td></td>
-  <td class="bdl bdr"></td>
-</tr>
-<tr>
-  <td class="tdl"><i>Inside bottom of outlet, to discharge line</i></td>
-  <td class="bdl">G</td>
-  <td class="bdl">19</td>
-  <td class="bdl">21</td>
-  <td class="bdl">20</td>
-  <td class="bdl bdr">25</td>
-  <td></td>
-  <td class="bdl bdr"></td>
-</tr>
-<tr>
-  <td class="tdl"><i>Discharge line, to top of wall</i></td>
-  <td class="bdl">H</td>
-  <td class="bdl">6</td>
-  <td class="bdl">6</td>
-  <td class="bdl">8</td>
-  <td class="bdl bdr">8</td>
-  <td></td>
-  <td class="bdl bdr"></td>
-</tr>
-<tr>
-  <td class="tdl"><i>Depth of outlet sump</i></td>
-  <td class="bdl">I</td>
-  <td class="bdl">13</td>
-  <td class="bdl">13</td>
-  <td class="bdl">11</td>
-  <td class="bdl bdr">12</td>
-  <td></td>
-  <td class="bdl bdr"></td>
-</tr>
-<tr>
-  <td class="tdl"><i>Length and width of outlet sump</i></td>
-  <td class="bdl bdb">J</td>
-  <td class="bdl bdb">18</td>
-  <td class="bdl bdb">19</td>
-  <td class="bdl bdb">19</td>
-  <td class="bdl bdb bdr">18</td>
-  <td></td>
-  <td class="bdl bdb bdr"></td>
-</tr>
-</table>
-
-<div class="pmt2 pmb2 smaller">[Transcriber Note: The data for Type 1 Siphon has been added to the table.]</div>
-
-  <div class="fig_caption"><span class="smcap">Fig. 24.</span>&mdash;Three types of sewage siphon. The table gives dimensions for setting standard
-  3 and 4 inch siphons; also the appropriate size and grade of the sewer to carry
-  the siphon discharge</div>
-</div>
-
-<p>The overhead siphon, type 3, <a href="#fig24">Figure 24</a>, may be installed readily in
-a tank already built by addition of an outlet sump. If properly set
-<span class="pagenum"><a id="Page_32"></a>[ 32 ]</span>
-are handled, sewage siphons require very little attention and flush
-with certainty. Like all plumbing fixtures they are liable to stoppage
-if rags, newspaper, and similar solids get into the sewage. If
-fouling of the sniffing hole or vent prevents the entrance of sufficient
-air into the bell to lock the siphon properly, allowing sewage to
-dribble through, the remedy is to clean the siphon. Siphons are for
-handling liquid; sludge if allowed to accumulate will choke them.</p>
-
-<p><b>Submerged outlet.</b>&mdash;The purpose of a submerged outlet is to take
-the outflow from a point between the sludge at the bottom and the
-floating solids or scum. The outlet in <a href="#fig23">Figure 23</a> may be readily made
-of sheet metal by a tinsmith. Wrought iron or steel pipe with elbows
-or light lead pipe may be used, the pipe being set in the concrete and
-left in place. Sometimes a galvanized wire screen (&frac14;-inch mesh) is
-fitted over the inner end to prevent large solids leaving the settling
-chamber and possibly clogging the siphon or distribution tile. If a
-screen is used it should be easily removable for cleaning.</p>
-
-<p><b>Manhole frame and cover.</b>&mdash;The frame and cover shown in <a href="#fig23">Figure 23</a>
-are stock patterns made of cast-iron and weighing about 250 pounds
-per set. The cover is 21 inches in diameter; it is tight and, on account
-of its weight, is unlikely to be disturbed by small children.
-The frame or rim is about 7 inches high and 31 inches in longest
-diameter. If desired, light cast-iron cistern or cesspool covers obtainable
-from plumbing supply houses, homemade slabs of reinforced
-concrete (see <a href="#fig25">Figure 25</a>), or wooden covers (see <a href="#fig21">Figure 21</a>) may be used.</p>
-
-<div class="figcenter illowp100" id="fig25" style="max-width: 24.8125em;">
-  <img class="w100" src="images/fig25.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 25.</span>&mdash;Homemade reinforced concrete covers. (1) Slabs placed crosswise permit uncovering
-  the whole tank for cleaning, but as inspection is somewhat difficult, cleaning is the
-  more likely to be neglected; (2) manhole, 18 inches square; cover, 22 by 22 by 3 inches
-  thick, easy to make and to slide or lift from the opening</div>
-</div>
-
-<p><b>Overflow.</b>&mdash;The purpose of an overflow is to pass sewage to the distribution
-field should the siphon stop working. The overflow (<a href="#fig23">fig.
-23</a>) is a 3-inch riser pipe with top 3 inches above the discharge line
-and the bottom calked or cemented into the side outlet of a <b>T</b> branch.
-The run of the <b>T</b> branch should correspond with the size of the sewer
-from the tank to the distribution field. If this sewer is 4-inch pipe,
-a 4 by 3 inch <b>T</b> branch is used, the 4-inch spigot end of the siphon
-being calked or cemented into the branch, as shown in <a href="#fig23">Figure 23</a>; if
-the sewer is 5-inch, a 5 by 3 inch <b>T</b> branch is used and connected to
-the siphon with a 5-inch to 4-inch reducer (in vitrified specials the
-equivalent is a 4-inch to 5-inch increaser); if the sewer is 6-inch, a
-6 by 3 inch <b>T</b> branch is used and connected to the siphon with a 6-inch
-to 4-inch reducer.</p>
-
-<p><b>Concrete work.</b>&mdash;Before excavation for the tank is begun, two
-wooden forms should be built for shaping the inside of the settling
-and siphon chambers. In most instances the ground is fairly firm,
-so that the lines of excavation may conform to the outside dimensions
-of the tank, the back of the walls being built against the earth.
-<span class="pagenum"><a id="Page_33"></a>[ 33 ]</span>
-The forms may be made of square-edged boards, braced and lightly
-nailed, as shown in <a href="#fig26">Figure 26</a>. The forms should have no bottom.
-If it is desired to lay the sides and covering slab in one operation,
-the top of the forms must be boarded over. All pipe and manhole
-openings should be accurately placed and cut. The faces of the
-forms may be covered with paper or smeared with soap or grease to
-facilitate removal later.</p>
-
-
-<div class="figcenter illowp67" id="fig26" style="max-width: 24.875em;">
-  <a href="images/fig26lrg.png"><img class="w100" src="images/fig26.png"  alt="" /></a>
-  <div class="fig_caption"><span class="smcap">Fig. 26.</span>&mdash;Forms for concrete work&mdash;how to use them<br />
-    Click on image to view larger size.</div>
-</div>
-
-<div style="width: 30em; margin: 0 auto;">
-<p class="smaller hanging">1 Make the forms as shown and to the dimensions required by <a href="#fig23">Figure 23</a>
-    and the table on p. 29; nails to be driven from the inside and left
-    projecting for drawing with a claw hammer.</p>
-
-<p class="smaller hanging">2. Excavate to lines 6 or 8 inches, as may be required, outside of the
-    forms and to the depths required for both chambers.</p>
-
-<p class="smaller hanging">3. Pour settling chamber floor and place form thereon.</p>
-
-<p class="smaller hanging">4 Pour settling chamber walls to level of siphon chamber excavation,
-    inserting submerged outlet pipe at the proper height. 5. Block siphon
-    and short pipes to correct line and grade, and fill with concrete
-    around the trap.</p>
-
-<p class="smaller hanging">6. Pour siphon chamber floor, and place the form
-    thereon.</p>
-
-<p class="smaller hanging">7 Continue pouring all walls to their full height, inserting the inlet
-    pipe when the concrete reaches that elevation.</p>
-
-<p class="smaller hanging">8. Do not remove forms till the concrete is hard; with favorable
-    weather, forms for walls only may be removed in 1 to 2 days; forms
-    supporting a cover slab should remain 1 to 2 weeks.</p>
-</div>
-
-<p><span class="pagenum"><a id="Page_34"></a>[ 34 ]</span></p>
-
-<p>The ground should next be excavated to the proper depth for
-placing the floors in both chambers. The settling chamber floor,
-being the lower, should be placed first. Effort should be made to
-secure water-tight work, a feature of especial importance where
-leakage might endanger a well or spring. A concrete mixture of
-1:2:4 is generally preferred (1 volume cement, 2 volumes sand, 4
-volumes stone). The ingredients should be of best quality and thoroughly
-mixed. The concrete should be poured promptly and worked
-with a spade or flat shovel to make the face smooth and eliminate
-pockets or voids within the mass.<a id="FNanchor_10" href="#Footnote_10" class="fnanchor">[10]</a> Before the settling chamber floor
-has hardened the form should be set upon the floor and the concrete
-work continued up the sides. The pipe form for the submerged
-outlet should be set. When the side walls of the settling chamber
-have reached the bottom of the excavation for the siphon chamber,
-the siphon trap with its connecting branch and short piece of pipe
-should be set to proper line and grade and blocked in position. The
-floor of the siphon chamber should now be poured and the form for
-that chamber placed thereon, leaving a 6-inch or 8-inch space (according
-to the thickness of the division wall) between the ends of
-the two forms. Pouring of all side walls and the top slab should
-continue without stop, making the entire structure a monolith.</p>
-
-<div class="footnote">
-
-<p><a id="Footnote_10" href="#FNanchor_10" class="label">[10]</a> See footnote, p. 12. For more detailed information on form and concrete work the
-reader is referred to U. S. Department of Agriculture Farmers' Bulletin 1480-F, "Small
-Concrete Construction on the Farm."</p></div>
-
-<p><b>Steel reinforcement.</b>&mdash;To stiffen the cover slab and guard against
-cracking, a little steel should be embedded in the concrete about 1
-inch above the inside top. For this purpose a strip of heavy stock
-fencing is convenient and inexpensive. The line wires should be not
-less than No. 10 gauge (about &#8539; inch) and the stay wires not less
-than No. 11 gauge. The reinforcement should be cut at manholes and
-fastened around manhole openings. If desired a standard wire-mesh
-reinforcement weighing about one-third of a pound per square foot
-may be used. Another alternative is to use 14-inch round rods,
-spacing the crosswise rods 6 inches apart and the lengthwise rods
-12 inches apart. Poultry netting should not be used, because of
-its lightness.</p>
-
-<p><b>Sewer from tank to distribution field.</b>&mdash;The length of this sewer
-depends on the situation of the field and the fall to it. The size of
-the sewer depends on the fall that can be obtained and the size of
-siphon. The table in <a href="#fig24">Figure 24</a> shows the minimum fall at which
-4-inch, 5-inch, and 6-inch sewers should be laid to take the discharge
-of the 3-inch and 4-inch siphons specified. The line and grade
-should be set in the same manner as for the house sewer (see <a href="#fig18">fig. 18</a>)
-and the construction should be as specified under that caption.</p>
-
-<p><b>Distribution field.</b>&mdash;The distribution field or area is a sewage filter,
-and its selection and the manner of preparing it largely determine
-the success of subsoil disposal of sewage. As a rule farm land is
-not the best filtering material. It is too fine grained and fertile.
-Its tendency is to hold water too long, to admit insufficient air, to
-clog when even small quantities of sewage are applied. Hence the
-distribution area should be of liberal size&mdash;on the average 500 square
-feet for each person served. It should be dry, porous, and well
-drained&mdash;qualities that characterize sandy, gravelly, and light loam
-<span class="pagenum"><a id="Page_35"></a>[ 35 ]</span>
-soils. It should be devoid of trees and shrubbery, thus giving sunlight
-and air free access. It should be located at least 300 feet downhill
-from a well or spring used for domestic water supply. Preferably
-it should slope gently, but sharp slopes are not prohibitive.
-Subsoiling the area is always desirable.</p>
-
-<p>Clay and other compact, impervious soils require special treatment.
-Less sewage can be applied to them, and hence it is well to
-have the area larger than 500 square feet per person. Clay should
-be subsoiled as deep as possible with a subsoil plow. In some instances
-dynamite has been of service in opening up the ground to
-still greater depth. Drainage and aeration should be further promoted
-by laying tile underdrains, as outlined in <a href="#fig17">Figure 17</a> and shown
-in more detail in <a href="#fig29">Figure 29</a>.</p>
-
-<p>After the construction work the distribution areas should be raked
-and seeded with thick-growing grass. Grass is a safe crop; its water
-requirement is high, and it affords considerable protection from frost.
-Suitable grasses are redtop, white clover, blue grass, and Bermuda
-grass. The area may be pastured or kept as grass land.</p>
-
-<p><b>Distribution system.</b>&mdash;Poor distribution of the sewage and failure to
-protect the joints of the distribution tile account for most of the
-failures. Each flush of the siphon should be so controlled that every
-part of the field will receive its due proportion. The distribution
-tile must be so laid that loose dirt will not fall or wash into the open
-joints.</p>
-
-<p>Different methods of dividing the flush and laying out the distribution
-tile are shown in Figures <a href="#fig27">27</a> and <a href="#fig30">30</a>. Layouts 1, 2, and 3,
-<a href="#fig27">Figure 27</a>, are suitable for flat or gently sloping areas and are
-planned for the shallow siphon chambers tabulated on <a href="#Dimensions_Table">page 29</a>.
-Layout 4, <a href="#fig27">Figure 27</a>, is suitable for steep slopes. In all four layouts
-use is made of one or more <b>V</b> branches (not <b>Y</b> branches) to divide
-the flow equally among the several lines. <b>V</b> branches, sometimes
-called breeches, should be leveled with a carpenter's level crosswise
-the ends of the legs, thus insuring equal division of the flow.</p>
-
-<p>The size and length of distribution tile and the spacing of the lines
-or runs admit of considerable variation in different soils. Water
-sinks rapidly in gravels and sands, and hence larger tile and shorter
-length are permissible than in close soils. Lateral movement is slow
-in all soils, but extends farther in gravels and sands than in close
-soils. In average soils the effect on vegetation 5 feet away from the
-line is practically nil.</p>
-
-<p>From these considerations, with the siphon dose 20 gallons per
-person, it is usually a safe rule to provide 50 feet of 3-inch tile for
-each person served and to lay the lines 10 feet apart. Such provision
-gives a capacity within the bore of the tile lines about equal
-to the siphon dose, and as some sewage is wasted at each joint a
-reasonable factor of safety is provided. A spacing of 10 feet will,
-it is believed, permanently prevent the extension of lateral absorption
-from line to line, provided the area is fairly well drained. As between
-3-inch and 4-inch tile the smaller size costs less and is better
-calculated to taper the dose to small proportions. Four-inch tile is
-less likely to get out of alignment or to become clogged; a length
-of 28 feet has the same capacity in the bore as 50 feet of 3-inch.</p>
-
-<p><span class="pagenum"><a id="Page_36"></a>[ 36 ]</span></p>
-
-<div class="figcenter illowp49" id="fig27" style="max-width: 25.625em;">
-  <img class="w100" src="images/fig27.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 27.</span>&mdash;Methods of laying distribution system: Methods 1, 2, and 3 for
-  flat or gently sloping land; method 4 for steep slopes (see also <a href="#fig30">Figure 30</a>);
-  <i>A</i>, direction of slope; <i>B</i>, contour of field; <i>C</i>, sewer from tank,
-  preferably size 5 inch, though 4 or 6 inch may be used, depending on
-  the fall and the size of the siphon (see table, <a href="#fig24">fig. 24</a>); <i>D</i>, <b>V</b>-branch
-  set to divide the flow exactly; <i>E</i>, reducer, to 4 inches; <i>F</i>, &#8539; bend,
-  4-inch; <i>G</i>, increaser, from 4 inches; <i>H</i>, increaser, 3 to 4 inches; <i>I</i>,
-  reducer, 4 to 3 inches; <i>J</i>, distribution tile, 3-inch; <i>K</i>, distribution
-  tile, 4-inch</div>
-</div>
-
-<p><span class="pagenum"><a id="Page_37"></a>[ 37 ]</span></p>
-
-<p>Good-quality drain tile in 1-foot lengths or second-quality sewer
-pipe in 2-foot lengths may be used. The lines are generally laid in
-parallel runs, but may be varied according to the topography. Layouts
-1, 2, and 3, <a href="#fig27">Figure 27</a>, for flat or gently sloping land, run with
-the slope; layout 4, for steep slopes, runs back and forth along the
-contour in a series of long flat sweeps and short steep curves. The
-grade of the runs and sweeps should be gentle, rarely more than
-10 or 12 inches in 100 feet. In layouts 1, 2, and 3, <a href="#fig27">Figure 27</a> especially,
-it is desirable that the last 20 feet of each run should be laid
-level or given a slight upward slope, thus guarding against undue
-flow of sewage to the lowest ends of the system.</p>
-
-<p>The runs should be laid no deeper than necessary to give clearance
-when plowing and prevent injury from frost. Ten inches of earth
-above the top of the tile is sufficient generally throughout the southern
-half of the United States and 18 inches generally in the North,
-but if the field is exposed or lacks a thick heavy growth of grass, the
-cover should be increased to 3 to 6 feet near the Canadian line.
-Where frost goes down 5 to 7 feet, it is better to lay the tile at
-moderate depth and cover the runs with hay, straw, or leaves
-weighted down, removing the covering in the spring.</p>
-
-<p>Making the joints of the distribution tile demands especial attention.
-For a short distance on the upper end of each run the tile
-should be laid with ends abutting; the joint opening should be increased
-gradually to one-eighth inch and this increased to one-fourth
-in the last 20 feet of the run. All joints should be protected against
-the entrance of loose dirt. Four methods are shown in <a href="#fig28">Figure 28</a>.
-The lower end of each run should be closed with a brick or flat
-stone; or, what is better, an elbow or <b>T</b> branch may be placed on the
-end and vented above the surface of the ground, improving the flow
-of sewage, the ventilation of pipes, and the aeration of the soil.</p>
-
-<p>If the distribution tile must be laid in clay or other close, poorly
-drained soil, special treatment is necessary. A common method is
-to subsoil and underdrain the area thoroughly, as shown in <a href="#fig29">Figure 29</a>.
-It is not always possible to run the underdrain in lines between the
-distribution lines as shown in Figures <a href="#fig17">17</a> and <a href="#fig29">29</a>, but it is a desirable
-thing to do, as the sewage must then receive some filtration through
-natural soil.</p>
-
-<p>In some instances it is sufficient to lay the distribution tile on a continuous
-bed, 8 to 12 inches thick, of coarse gravel, broken stone, or
-brick, slag, coke, or cinders and complete the refill as shown in Figure
-<a href="#fig16">16</a> or <a href="#fig29">29</a>.</p>
-
-<p><a href="#fig30">Figure 30</a> shows two other methods of controlling the flow on steep
-slopes and diverting proper proportions to the several lateral distributors
-laid along the contour of the field. This work can not be
-effected properly with <b>T</b> or <b>Y</b> branches; the flow tends to shoot
-straight ahead, comparatively little escaping laterally. To overcome
-this difficulty recourse is had to diverting boxes, of which two types
-are shown in <a href="#fig30">Figure 30</a>. These boxes involve expense, but permit
-inspection and division of the flow according to the needs. They may
-be built of brick, stone, concrete, or even wood.</p>
-
-<p>Type 1 consists of a single box, into which all the lateral distributors
-head. It will be noted that the laterals enter at slightly different
-elevations, the two opposite the inlet sewer being the highest,
-<span class="pagenum"><a id="Page_38"></a>[ 38 ]</span>
-the next two slightly lower, and the next two the lowest. This staggering
-of the outlets, in a measure, offsets the tendency of the flow
-to shoot across and escape by the most direct route.</p>
-
-<div class="figcenter illowp100" id="fig28" style="max-width: 26em;">
-  <img class="w100" src="images/fig28.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 28.</span>&mdash;Four methods of protecting open joints in distribution lines&mdash;an all-important
-  work. Sketches show cross-section and longitudinal views; the depth from the surface
-  of the ground to the top of the tile is about 10 inches</div>
-</div>
-
-<div style="width: 30em; margin: 0 auto;">
-<p class="smaller hanging">1. <i>A</i>, Subsoiled ground; <i>B</i>, 3 or 4 inch drain tile; <i>C</i>, strip of tarred paper about 6
-inches wide and extending three-fourths the distance around the tile, allowing sewage
-to escape at the bottom; <i>D</i>, coarse sand, gravel, broken stone or brick, slag, cinders, or
-coke, the coarsest material placed around the tile (where the ground is naturally very
-porous and well drained, special filling in the trench may be omitted); <i>E</i>, natural soil.</p>
-
-<p class="smaller hanging">2. Drain tile covered with a board laid flat, leaving the entire joint open.</p>
-
-<p class="smaller hanging">3. Drain tile laid in stoneware gutter pieces and the joint covered with stoneware caps;
-gutter and cap pieces are inexpensive commercial products; their radius is longer than
-that of the outside of the tile, thus leaving open most of the joint space; the gutter aids
-in keeping the tile in line.</p>
-
-<p class="smaller hanging">4. Vitrified sewer pipe with hubs facing downhill; the spigot end should be centered in
-the hub with a few small chinks or wedges.</p>
-</div>
-
-<div class="figcenter illowp100" id="fig29" style="max-width: 25.1875em;">
-  <img class="w100" src="images/fig29.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 29.</span>&mdash;-Close soils should be deeply subsoiled and underdrained. Porous, well-drained,
-  air-filled soil is absolutely necessary. <i>A</i>, Subsoiled ground; <i>B</i>, 3 or 4 inch distribution
-  tile; <i>C</i>, depth variable with the climate, 1&frac14; to 3&frac12; feet; <i>D</i>, 4-inch underdrain; <i>E</i>, depth
-  such as would prepare land for good crop production, generally 3&frac12; to 4 feet; <i>F</i>, stone
-  or other coarse material; <i>G</i>, gravel grading upward to coarse sand; <i>H</i>, loose soil</div>
-</div>
-
-<p>Type 2 calls for one or more diverting boxes, according to the number
-of lateral distributors, and readily permits of wasting sewage at
-widely separated elevations and distances. The outlet pipes enter
-the box at slightly different elevations, for the reason already stated.
-<span class="pagenum"><a id="Page_39"></a>[ 39 ]</span>
-With either type, should the outlets not be set at the right elevations,
-partial plugging of the holes and a little experimenting will enable
-one to equalize or proportion the discharges.</p>
-
-<div class="figcenter illowp71" id="fig30" style="max-width: 26.3125em;">
-  <img class="w100" src="images/fig30.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 30.</span>&mdash;Two systems of distribution on steep slopes&mdash;use of diverting box. <i>A</i>, Direction
-  of slope; <i>B</i>, contour of field; <i>C</i>, 4, 5, or 6 inch sewer from tank; <i>D</i>, diverting
-  box; <i>E</i>, 3-inch or 4-inch distribution tile</div>
-</div>
-
-<p><b>Sewage switch.</b>&mdash;The clogging of filters and soils after long-continued
-application of sewage has been previously referred to. It
-is, therefore, desirable to arrange the distribution system in two units
-with a switch between them, so that one area may drain and become
-aerated while the other is in use. This procedure is especially desirable
-where the soil is close and the installation of considerable
-size. It adds to the life and effectiveness of the distribution area and
-permits use of a plant in case it is necessary to repair, extend, or
-relay the tile in either unit.</p>
-
-<p>Arrangement in two units does not necessarily mean doubling the
-amount of tile and the area required in a single field. However desirable
-that may be, expense or lack of suitable ground will often
-prevent. With open sands and gravels and the assumed siphon dose
-<span class="pagenum"><a id="Page_40"></a>[ 40 ]</span>
-of 20 gallons per person, 15 to 20 feet of 4-inch tile in each unit for
-each person will usually suffice. With more compact soil it is advisable
-to more nearly double the requirements previously described.
-Two simple types of switch are shown in <a href="#fig31">Figure 31</a>. The switch
-should be turned frequently, certainly as often as is necessary to prevent
-saturation or bogginess of either area.</p>
-
-<div class="figcenter illowp97" id="fig31" style="max-width: 25.625em;">
-  <img class="w100" src="images/fig31.png"  alt="" />
-  <div class="fig_caption"><span class="smcap">Fig. 31.</span>&mdash;Two simple types of sewage switch. <i>A</i>, Sewer from tank; <i>B</i>, switch box;
-  <i>C</i>, cover; <i>D</i>, blade or stop board (in the left-hand box the direction of flow is controlled
-  by placing the blade in alternate diagonal position; in the right-hand box the stop
-  works in iron guides cast integral with a short piece of light-weight pipe set in the
-  masonry; if desired the guides may be wood, fastened to the masonry with expansion
-  bolts); <i>E</i>, sewer to distribution area; <i>F</i> (right-hand box), alternate position of outlets
-  or additional outlets if required</div>
-</div>
-
-<p><b>A complete installation.</b>&mdash;The general layout and working plans of
-a complete installation built in 1915-16 are shown in <a href="#fig32">Figure 32</a>.
-The plant is larger than those heretofore considered, and involves
-several additional features. The settling chamber below the flow line
-has a capacity of 1,000 gallons, and on a basis of 40 gallons per
-person per day would serve 25 people.</p>
-
-<p>For many years sewage had been discharged through two 4-inch
-sewers to a cesspool in the rear of the house. The proximity of the
-well made it unsafe, and the overflow of the cesspool dribbled over
-the low portion of the garden and barnyard, cheating nuisance.</p>
-
-<p>The first step was to make borings with a soil auger in the pasture
-400 or 500 feet from the house. The borings showed a heavy clay
-soil to a depth of about 4 feet, underlaid with a sandy stratum only
-a few inches in thickness. It was decided to locate the distribution
-area in the pasture and to aid the seepage of sewage by digging
-numerous filter wells through the clay to the sandy stratum. Levels
-<span class="pagenum"><a id="Page_41"></a>[ 41 ]</span>
-were taken and a contour plan prepared to serve for laying out the
-plant and establishing the grades.</p>
-
-<div class="figcenter illowp58" id="fig32" style="max-width: 25.1875em;">
-  <a href="images/fig32lrg.png"><img class="w100" src="images/fig32.png"  alt="" /></a>
-  <div class="fig_caption"><span class="smcap">Fig. 32.</span>&mdash;A complete installation for a large rural home. General layout on a contour
-  plan and construction drawings. Note abandonment of old cesspool near the well and
-  garden and removal of sewage to a lower and safer location in the pasture, where the
-  treatment is subsurface distribution, aided by numerous filter wells about 4 feet deep
-  filled with coarse gravel. Note that sludge is removed from the bottom of the settling
-  chamber by opening the gate on the sludge drain<br />
-    Click on image to view larger size</div>
-</div>
-
-<p>The septic tank is built in one corner of the barnyard, and a 5-inch
-sewer connects it with the old 4-inch sewers to the cesspool. All
-sewer-pipe joints were poured with a flexible jointing compound.
-The settling chamber is of hopper shape at the bottom, and a 4-inch
-sludge drain with gate provides for the gravity removal of sludge.
-The lower end of the sludge drain is above the surface of the ground
-<span class="pagenum"><a id="Page_42"></a>[ 42 ]</span>
-and 9 feet below the flow line. The end is protected by a small retaining
-wall, and the sludge is readily caught in barrels and hauled
-out on the land for burial. The outlet is low enough to drain the
-settling chamber completely. If it is desired merely to force out the
-sludge, the drain may be brought to the surface under a head of 3 to
-5 feet, discharging the sludge into a trench or drying bed, to be applied
-later to the land. A 2-inch waste pipe about mid-depth of the
-settling chamber permits drawing off the cleared portion of the sewage
-to the siphon chamber and from thence through another 2-inch
-waste pipe into the 6-inch sewer leading to the distribution field.</p>
-
-<p>The 4-inch siphon has a drawing depth of 33 inches, and as the
-siphon chamber is 4 feet wide by 6 feet long the dose is about 500
-gallons. The siphon cost $35. The 6-inch sewer to the switch box
-falls about 6 inches in 50 feet. The distribution field was thoroughly
-subsoiled, and about 800 feet of 3-inch tile was laid in each unit. At
-intervals of 25 feet along the distribution trenches 6-inch holes were
-dug through the clay stratum with a posthole digger. These holes
-were filled with stone and constitute the filter wells previously mentioned.
-All tile lines are surrounded with stone and coarse gravel,
-and the ground has been trimmed to give a uniform cover of 12
-inches. All work was done by day labor in a thorough manner. As
-the men were doing other work at the same time the actual cost is not
-known, but it is believed the installation cost about $700.</p>
-
-<p><b>Cost data.</b>&mdash;Reliable cost figures are difficult to estimate. Labor,
-materials, freight, haulage, and other items vary greatly in different
-localities. The septic tank shown in <a href="#fig21">Figure 21</a> contains about 1,000
-bricks and is estimated to cost $60 complete. The septic tank shown
-in <a href="#fig23">Figure 23</a> for 5 persons is estimated to cost $135; for 10 persons,
-$170; for 15 persons, $240; for 20 persons, $280. In Maryland, in
-1916, the cost of installing a septic tank similar to that shown in
-<a href="#fig23">Figure 23</a> (for 5 people), including 86 feet of 5-inch house sewer
-(55 feet of cast-iron pipe passing a well, and 31 feet of vitrified pipe)
-and 214 feet of second-quality 4-inch sewer pipe in the distribution
-area, was as follows:</p>
-
-<table summary="data">
-<tr>
-  <td class="tdl">Excavation, labor</td>
-  <td class="tdr">$7.50</td>
-</tr>
-<tr>
-  <td class="tdl">Materials delivered</td>
-  <td class="tdr">46.60</td>
-</tr>
-<tr>
-  <td class="tdl">Three-inch siphon, including freight</td>
-  <td class="tdr">15.75</td>
-</tr>
-<tr>
-  <td class="tdl">Construction, labor</td>
-  <td class="tdr">28.00</td>
-</tr>
-<tr>
-  <td class="tdl">Supervision</td>
-  <td class="tdr">5.00</td>
-</tr>
-<tr>
-  <td class="tdl">&nbsp;&nbsp;&nbsp;Total</td>
-  <td class="tdr bdt">102.85</td>
-</tr>
-</table>
-
-<p>The quotations in the following table will be found useful in
-making estimates of cost:</p>
-
-<p class="tdc"><i>Cost per foot of pipe and drain tile</i></p>
-
-<p class="tdc">(Approximate retail prices, Washington, D. C., February, 1928)</p>
-
-<table summary="data">
-<tr>
-  <td class="bdt bdb" rowspan="2">Kind of pipe.</td>
-  <td class="bdt bdb bdl tdc" colspan="4">Size, in inches.</td>
-</tr>
-<tr>
-  <td class="bdb bdl tdc">3</td>
-  <td class="bdb bdl tdc">4</td>
-  <td class="bdb bdl tdc">5</td>
-  <td class="bdb bdl tdc">6</td>
-</tr>
-<tr>
-  <td><p class="hanging">Extra heavy cast-iron soil pipe</p></td>
-  <td class="bdl">$0.23</td>
-  <td class="bdl">$0.31</td>
-  <td class="bdl">$0.40</td>
-  <td class="bdl">$0.48</td>
-</tr>
-<tr>
-  <td>Vitrified salt-glazed sewer pipe</td>
-  <td class="bdl">&nbsp;&nbsp;.15</td>
-  <td class="bdl">&nbsp;&nbsp;.15</td>
-  <td class="bdl">&nbsp;&nbsp;.22&frac12;</td>
-  <td class="bdl">&nbsp;&nbsp;.22&frac12;</td>
-</tr>
-<tr>
-  <td class="bdb">Clay or shale drain tile</td>
-  <td class="bdl bdb">&nbsp;&nbsp;.06</td>
-  <td class="bdl bdb">&nbsp;&nbsp;.07</td>
-  <td class="bdl bdb">&nbsp;&nbsp;.10</td>
-  <td class="bdl bdb">&nbsp;&nbsp;.13</td>
-</tr>
-</table>
-
-
-<p><span class="pagenum"><a id="Page_43"></a>[ 43 ]</span></p>
-
-<p>The cost of cast-iron fittings may be roughly estimated as follows;
-Bends, one and one-half times the price of straight pipe; <b>T</b>-branches,
-two times the price of straight pipe; reducers, average of the prices
-of straight pipe at each end. The cost of clay bends, <b>T</b>-branches,
-reducers, and increasers may be roughly estimated at four times the
-price of straight pipe.</p>
-
-<p><b>Operation.</b>&mdash;Attention must be given to every plant to insure success.
-Unusual or excessive foulness should be investigated. No
-chemicals should be used in a septic tank; garbage, rags, newspaper,
-and other solids not readily soluble in water should be kept out of
-sewers and tanks. The plant should be inspected often, noting particularly
-if the siphon is operating satisfactorily. If scum forms
-in the settling chamber it should be removed, and the sludge should
-be bailed or pumped out yearly. Frequently tanks are not cleaned
-out for three or four years, resulting in large quantities of solid
-matter going through to the distribution system and clogging it.
-Clogging may occur in the tile or in the adjacent soil. In either
-case the tile should be dug up, cleaned, and relaid. In some cases
-it has been found advantageous to relay the tile between the former
-lines. When sewage is applied to fairly porous land at the slow
-rate here recommended and the plant is well handled the tile lines
-should operate satisfactorily for many years. Liming heavy soils
-tends to loosen and keep them sweet.</p>
-
-<p><b>Field data.</b>&mdash;As a basis for outlining or designing a suitable installation
-the following data should be known:</p>
-
-<p class="smaller">&nbsp;1. State, town, and whether in or near an incorporated municipality.</p>
-
-<p class="smaller">&nbsp;2. Usual number of persons to be served.</p>
-
-<p class="smaller">&nbsp;3. Average daily consumption of water in gallons.</p>
-
-<p class="smaller">&nbsp;4. Kind and depth of well, depth to water surface.</p>
-
-<p class="smaller">&nbsp;5. Character of soil, whether sandy, gravelly, loamy, clay, or muck.</p>
-
-<p class="smaller">&nbsp;6. Condition of soil as to drainage.</p>
-
-<p class="smaller">&nbsp;7. Character of subsoil.</p>
-
-<p class="smaller">&nbsp;8. Character of underlying rock and, if known, its depth below the
-surface.</p>
-
-<p class="smaller">&nbsp;9. Depth to ground water at both house and field where sewage is to
-be distributed.</p>
-
-<p class="smaller">10. Minimum winter temperature and approximate depth to which frost
-goes.</p>
-
-<p class="smaller">11. Number and kind of buildings to be connected with the sewer.</p>
-
-<p class="smaller">12. Number and kind of plumbing fixtures in each building.</p>
-
-<p class="smaller">13. Whether plumbing fixtures are to be put in the basement.</p>
-
-<p class="smaller">14. Depth of basement floor below ground.</p>
-
-
-<p>A plan to scale or a sketch with dimensions showing property lines,
-buildings, wells, springs, and drainage outlets should be furnished.
-The direction of surface drainage should be indicated by arrows.
-The slope of the land (vertical fall in a stated horizontal distance)
-should be given or if possible a contour plan (showing lines of
-constant elevation) should be furnished.</p>
-
-
-<hr class="chap" />
-
-<div class="chapter">
-<h2 class="nobreak" id="GREASE_TRAPS">GREASE TRAPS</h2>
-</div>
-
-<p>Farm sewage may contain from 10 to 30 pounds of grease and fats
-per person per year. This grease, originating mainly in the kitchen-sink,
-hinders septic action and clogs pipes, filters, and soils. Half
-the grease may be stopped by a septic tank, but the remainder goes
-into the distribution system, interfering with its action. A grease
-trap is a device for separating the grease from other wastes. The
-<span class="pagenum"><a id="Page_44"></a>[ 44 ]</span>
-need for it may be lessened by carefully depositing waste greases and
-fats with the garbage; but one should always be installed if the
-kitchen is carelessly managed or discharges quantities of greasy
-water as at institutions, hotels, boarding houses, and bakeshops.</p>
-
-<div class="figcenter illowp77" id="fig33" style="max-width: 26.1875em;">
-  <a href="images/fig33lrg.png"><img class="w100" src="images/fig33.png"  alt="" /></a>
-  <div class="fig_caption"><span class="smcap">Fig. 33.</span>&mdash;Three types of grease trap. <i>A</i>, Ready-made grease trap; vitrified, salt-glazed
-  earthenware; stock sizes: 10-inch diameter by 24 inches, 12-inch diameter by 24 inches,
-  15-inch diameter by 24 inches. <i>B</i>, Homemade grease trap; concrete or well-plastered
-  brickwork; elbow, cross, and increaser to be recessed drainage fittings. <i>C</i>, Type of
-  grease trap used at United States Army camps<br />
-    Click on image to view larger size</div>
-</div>
-
-<p>A grease trap should have several times the capacity of the greatest
-quantity of greasy water discharged into it at one time, in order
-that the entering water shall be well cooled and the grease congealed.
-The solidified grease rises to the surface of the water in the trap and
-is retained therein. A dishpan of greasy water (2&frac12; to 3 gallons) is
-the largest quantity likely to be discharged at one time from an ordinary
-kitchen-sink, hence the grease trap should have not less capacity
-than 7 or 8 gallons. <a href="#fig33">Figure 33</a> shows three types of grease traps
-suitable for farm use. In each the outlet pipe has small clearance
-at the bottom. This feature, together with the <b>V</b>-shaped hopper bottom,
-tends to create a scouring velocity and thus prevent the accumulation
-of coffee grounds and other solid wastes in the bottom of the
-trap. A grease trap should be close to the sink it is intended to serve,
-but not within the kitchen, on account of objectionable odors when
-<span class="pagenum"><a id="Page_45"></a>[ 45 ]</span>
-the trap is opened to remove grease. It is good practice to place the
-trap in the cellar or basement, where it is safe from frost yet close
-to the source of grease.</p>
-
-
-<hr class="chap" />
-
-<div class="chapter">
-<h2 class="nobreak" id="GENERAL_PROCEDURE">GENERAL PROCEDURE</h2>
-</div>
-
-
-<p>Do not waste money by digging and partly constructing, afterwards
-seeking information. Prepare a plan and work from it. Get
-in touch with your county agricultural and home demonstration
-agents. Advice may be obtained also from extension workers, State
-agricultural colleges, State and local boards of health, the United
-States Public Health Service, and the United States Department of
-Agriculture. Do not guess distances and levels. Use a measuring
-tape and some type of level&mdash;engineer's, architect's, drainage, hand,
-or carpenter's. Study this bulletin, and design, lay out, and construct
-in accordance therewith. Remember to: (1) Isolate the septic tank&mdash;
-locate it 50 to 100 or more feet from any dwelling and, if practicable,
-to the leeward of prevailing summer breezes; (2) locate the cesspool
-or sewage-distribution field downhill from the well or spring, and, if
-possible, 300 feet therefrom; (3) select dry, porous, deeply drained
-ground for disposal of all sewage; (4) do not apply more sewage to a
-given area of land than can be thoroughly absorbed and oxidized; (5)
-lay sewers straight and below the reach of frost, ventilate them thoroughly,
-and make the joints water-tight and root-proof.</p>
-
-<p>Makeshift methods, materials, or devices should be avoided or used
-sparingly. Do not place a vent pipe in the top of a cesspool or
-septic tank if near a dwelling. Siphon chamber and siphon may be
-omitted in those rare instances where it is feasible to discharge into
-salt water or into a large stream already badly polluted. Disposal
-of sewage in a running stream should be a last resort. Such practice
-endangers water supplies downstream, and unless the volume and
-velocity of flow are good nuisance may be created in the vicinity.
-Do not neglect inspection and operation. Clean out settling tanks
-yearly or oftener. All pipe lines below ground should be marked
-with iron or stone markers to facilitate examination, repair, or
-extension of the system.</p>
-
-<p>There is a general but erroneous belief that the cost of sewerage
-is little in the city but almost prohibitive in the country. All personal
-and Realty properties in one eastern city represent a valuation
-of $10,382 per home, which pays $355 for sewers outside the cellar
-wall. An average farm in a Middle West State represents a valuation
-of $17,259. Is not the farmer justified in the small outlay required
-to dispose of the farm sewage? Because of the issuance of
-bonds and the apportionment of sewer assessments for a series of
-years the city dweller may have his burden distributed over a long
-period. The farmer does not pay interest on these obligations, and
-sewer work can be done more cheaply in the country than in the city.</p>
-
-<p>Safe disposal of farm sewage is not a passing fad but a vital necessity.
-Besides being an asset a good sewerage installation greatly
-promotes the wholesomeness and healthfulness of the farm. Moreover
-the benefits are far-reaching, because farm products go into
-every home, and farm and urban populations mingle freely.</p>
-
-<p><span class="pagenum"><a id="Page_46"></a>[ 46 ]</span></p>
-
-<p class="caption3">ORGANIZATION OF THE<br />
-UNITED STATES DEPARTMENT OF AGRICULTURE</p>
-
-<p class="tdc">January 6, 1930</p>
-
-<hr class="r20" />
-
-<table summary="list">
-<tr>
-  <td class="tdl"><i>Secretary of Agriculture</i></td>
-  <td class="tdl"><span class="smcap">Arthur M. Hyde.</span></td>
-</tr>
-<tr>
-  <td class="tdl"><i>Assistant Secretary</i></td>
-  <td class="tdl"><span class="smcap">R. W. Dunlap.</span></td>
-</tr>
-<tr>
-  <td class="tdl"><i>Director of Scientific Work</i></td>
-  <td class="tdl"><span class="smcap">A. F. Woods.</span></td>
-</tr>
-<tr>
-  <td class="tdl"><i>Director of Regulatory Work</i></td>
-  <td class="tdl"><span class="smcap">Walter G. Campbell.</span></td>
-</tr>
-<tr>
-  <td class="tdl"><i>Director of Extension Work</i></td>
-  <td class="tdl"><span class="smcap">C. W. Warburton.</span></td>
-</tr>
-<tr>
-  <td class="tdl"><i>Director of Personnel and Business Administration.</i></td>
-  <td class="tdl"><span class="smcap">W. W. Stockberger.</span></td>
-</tr>
-<tr>
-  <td class="tdl"><i>Director of Information</i></td>
-  <td class="tdl"><span class="smcap">M. S. Eisenhower.</span></td>
-</tr>
-<tr>
-  <td class="tdl"><i>Solicitor</i></td>
-  <td class="tdl"><span class="smcap">E. L. Marshall.</span></td>
-</tr>
-<tr>
-  <td class="tdl"><i>Weather Bureau</i></td>
-  <td class="tdl"><span class="smcap">Charles F. Marvin</span>, <i>Chief</i>.</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Bureau of Animal Industry</i></td>
-  <td class="tdl"><span class="smcap">John R. Mohler</span>, <i>Chief</i>.</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Bureau of Dairy Industry</i></td>
-  <td class="tdl"><span class="smcap">O. E. Reed</span>, <i>Chief</i>.</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Bureau of Plant Industry</i></td>
-  <td class="tdl"><span class="smcap">William A. Taylor</span>, <i>Chief</i>.</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Forest Service</i></td>
-  <td class="tdl"><span class="smcap">R. Y. Stuart</span>, <i>Chief</i>.</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Bureau of Chemistry and Soils</i></td>
-  <td class="tdl"><span class="smcap">H. G. Knight</span>, <i>Chief</i>.</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Bureau of Entomology</i></td>
-  <td class="tdl"><span class="smcap">C. L. Marlatt</span>, <i>Chief</i>.</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Bureau of Biological Survey</i></td>
-  <td class="tdl"><span class="smcap">Paul G. Redington</span>, <i>Chief</i>.</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Bureau of Public Roads</i></td>
-  <td class="tdl"><span class="smcap">Thomas H. MacDonald</span>, <i>Chief</i>.</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Bureau of Agricultural Economics</i></td>
-  <td class="tdl"><span class="smcap">Nils A. Olsen</span>, <i>Chief</i>.</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Bureau of Home Economics</i></td>
-  <td class="tdl"><span class="smcap">Louise Stanley</span>, <i>Chief</i>.</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Plant Quarantine and Control Administration</i></td>
-  <td class="tdl"><span class="smcap">Lee A. Strong</span>, <i>Chief</i>.</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Grain Futures Administration</i></td>
-  <td class="tdl"><span class="smcap">J. W. T. Duvel</span>, <i>Chief</i>.</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Food, Drug, and Insecticide Administration</i></td>
-  <td class="tdl"><span class="smcap">Walter G. Campbell</span>, <i>Director of Regulatory Work, in Charge</i>.</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Office of Experiment Stations</i></td>
-  <td class="tdl">&mdash;&mdash;&mdash;&mdash;, <i>Chief</i>.</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Office of Cooperative Extension Work</i></td>
-  <td class="tdl"><span class="smcap">C. B. Smith</span>, <i>Chief</i>.</td>
-</tr>
-<tr>
-  <td class="tdl"><i>Library</i></td>
-  <td class="tdl"><span class="smcap">Claribel R. Barnett</span>, <i>Librarian</i>.</td>
-</tr>
-</table>
-
-
-<p class="tdc pmt4 bdb">U. S. GOVERNMENT PRINTING OFFICE: 1930</p>
-
-<table style="width: 100%; padding-bottom: 4em;" summary="data">
-<tr>
-  <td><div class="tdl">For sale by the Superintendent of Documents, Washington, D. C.</div></td>
-  <td><div class="tdc">&mdash;&mdash;</div></td>
-  <td><div class="tdr">Price 10 cents</div></td>
-</tr>
-</table>
-
-
-<hr class="full" />
-
-
-<div class="transnote">
-
-<p class="caption3">Transcriber Note</p>
-
-<p>Minor typos have been corrected. Illustrations were moved to prevent
-splitting paragraphs. <a href="#fig19">Figure 19</a> was moved adjacent to the directions and
-specifications on <a href="#fig19">Page 24</a>. Due to space considerations in the text only
-version, emphasis of column headers were sometimes eliminated and some of
-the tables were rearranged. Produced from files generously made available
-by USDA through The Internet Archive. All resultant materials are placed
-in the Public Domain.</p>
-
-</div>
-
-
-
-
-
-
-
-
-
-<pre>
-
-
-
-
-
-End of the Project Gutenberg EBook of USDA Farmers' Bulletin No. 1227:
-Sewage and sewerage of farm home, by George Warren
-
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