UNIT-5
Water
System
There are three main sources of water :
1- Rain
2- Surface water : Oceans, Rivers and streams , tanks , ponds & lakes
3- ground water : shallow wells, Deep wells , Springs
1. Rain
Rain is the prime source of all water. A part of the rain water sinks into the ground to form ground water; part of it evaporates back into atmosphere, and some runs off to form streams and rivers which flow ultimately into the sea.
Some of the water in the soil is taken up by the plants and is evaporated in turn by the leaves. These events are spoken of as "water cycle".
Characteristics of rain water:-
Rain water is the purest water in nature. Physically, it is clear, bright and sparkling. Chemically, it is very soft water containing only traces of dissolved solids (0.0005 percent).
Being soft, it has a corrosive action on lead pipes. Bacteriologically, rain water from clean districts is free from pathogenic agents.
Impurities of rain water:
Rain water tends to become impure as it passes through the atmosphere. It picks up suspended impurities from the atmosphere such as dust, soot and microorganisms and gases such as carbon dioxide, nitrogen, oxygen and ammonia.
Gaseous sulphur and nitrogen oxides are emitted from power plants that use fossil fuels. These gases react with atmospheric water, forming dilute solution of sulphuric and nitric acid. The precipitation of these acids (acid rain) has begun to have serious impacts on surface water quality and on plants etc..
2. Surface water
Surface water originates from rain water. It is the main source of water supply in many areas. Examples of surface water include rivers, tanks, lakes, man-made reservoirs and sea water.
Surface water is prone to contamination from human and animal sources. As such it is never safe for human consumption unless subjected to sanitary protection and purification before use.
Characteristics of surface water:
Surface water picks up the characteristics of the surface over which it passes. If water flows across a parking lot, gasoline, oil, and other contaminants may be carried by or dissolved into the water.
Water may pick up fertilizers, road salts, radioactivity, and biological contaminant from farms, as well as countless other biological, physical, and chemical pollutants.
Rivers:
Many rivers furnish a dependable supply of water. The chief drawback of river water is that it is always grossly polluted and is quite unfit for drinking without treatment.
Characteristics of river water:
River water is turbid during rainy season; it may be clear in other seasons. Clarity of water is no guarantee that the river water is safe for drinking. River water contains dissolved and suspended impurities of all kinds. The bacterial count, including the human intestinal organisms may be very high.
Impurities of river water:
The impurities of river water are derived from surface washings, sewage and sullage water, industrial and trade wastes, and drainage from agricultural areas.
Self-purification of river water:
Certain amount of self-purification occur in river water by natural forces of purification such as dilution, sedimentation, aeration, oxidation, sunlight, plant and animal life ,but these agencies are not sufficient to render the water potable. River water needs purification before it can be used for drinking purposes.
Sea water:
Though this source is plentiful, it has great many limitations. It contains 3.5 percent of salts in solution. Desalting and demineralization process involves heavy expenditure. It adopted in places where sea water is the only source available.
3. Ground water
Rain water percolating into ground constitutes ground water. Water used by humans comes mainly from land. It is now realised that there is a limit to ground water in the world.
Ground water is the cheapest and most practical means of providing water to small communities. Ground water is superior to surface water, because the ground itself provides an effective filtering medium.
The advantages of ground water are:-
(1) It is likely to be free from
pathogenic agents;
(2) It usually requires no treatment;
(3) The supply is likely to be certain
even during dry season;
(4) It is less subject to contamination than surface water.
The disadvantages of ground water are:
(1) It is high in mineral content, e.g.,
salts of calcium and magnesium which increase the water hard;
(2) It requires pumping or some arrangement to lift the water.
Wells:
Traditionally wells are an important source of water supply. Even today, they are an important source of water supply in many communities. Technically, wells are of two kinds-shallow and deep.
(1) Shallow wells:
shallow wells tap subsoil water i.e. the water from above the first impervious layer in the ground. They provide limited quantities of water, and the water is easy to be polluted unless care is taken in well construction.
(2) Deep wells:
A deep well is one which taps water from the water-bearing stratum below the first impervious layer in the ground. Deep wells are usually machine-dug and may be several hundred meters deep. Deep wells furnish the safest water, and are often the most satisfactory sources of water supply.
Springs:
When ground water comes to the surface and flows freely under natural pressure, it is called a "spring". Springs may be of two types------shallow springs and deep springs. Shallow springs dry up quickly during summer months, whereas deep springs do not show seasonal fluctuations in the flow of water.
In some geographic areas, springs constitute an important source of water. Springs are simpler to exploit, as no pumping is needed to bring the water to the surface. Springs are exposed to contamination.
Method Of Removing Hardness
One
of the common methods of removing hardness is by means of soap. When a soap,
which is made with potash and soda as a base, is added to the water containing calcium
and magnesium salts the soap is
decomposed, and the fatty acid is set free in an insoluble state. It is upon
this reaction that the old method of determining hardness, known as Clark's
method, was based. This process has been varied in many ways by chemists in
different countries, but the original principle has not been departed from.
and magnesium salts the soap is
decomposed, and the fatty acid is set free in an insoluble state. It is upon
this reaction that the old method of determining hardness, known as Clark's
method, was based. This process has been varied in many ways by chemists in
different countries, but the original principle has not been departed from.
The
hardness is usually estimated in the number of milligrams of calcium carbonate
in a standard volume of water - usually 100,000 parts. In England and America
it is usually determined by the number of grains of calcium carbonate in an
imperial gallon in England and a United States gallon in America, which means,
in England, the number of grains of calcium carbonate in 70,000 parts, and, in
America, in 58,381 parts.
Removal of Hardness
By boiling the hard water
On boiling calcium / magnesium
bicarbonate decompose salts, which are normally present in portable water. These are called hard salts due to two
factors
1.
When hard water is heated, salts will
frequently precipitate out causing a lime build within pipes and around
plumbing fixtures or deposits on items being washed.
2.
When water containing these salts is
mixed with natural soap and some synthetic cleaners, the salts ombine with
cleaner chemicals and precipitate onto and within the products being washed.
The resulting mixture is called soap curd, a sticky substance that is difficult
to remove from washed products.
calcium/magnesium carbonate, which
is insoluble in water. Therefore, it precipitates out.
In Clark's process, slaked lime,
Ca(OH)2 is added to temporary hard water. Insoluble calcium carbonate
precipitate out and no longer produce hardness.
The methods used to remove permanent
hardness given in the next section can also be employed to remove the temporary
hardness. However, the above methods cannot be used to remove the permanent
hardness.
Calcium and magnesium ions present
in hard water react with sodium carbonate to produce insoluble carbonates. The
water now contains soluble and harmless sodium salts.
Calgon is a trade name of a complex
salt, sodium hexametaphosphate
(NaPO3)6. It is used for softening
hard water. Calgon ionizes to give a complex anion:
The addition of Calgon to hard water
causes the calcium and magnesium ions of hard water to displace sodium ions
from the anion of Calgon.
This results in the removal of
calcium and magnesium ions from hard water in the form of a complex with
Calgon. The water is softened and sodium ions are released into water.
By the ion-exchange process
(Permutit process)
Permutit or sodium aluminium
silicate is a complex chemical compound, which occurs as a natural mineral
called Zeolite. Permutit or zeolites are insoluble in water and have the
property of exchanging ions present in them with the ions present in the
solution.
Permutit or zeolites are packed in a
suitable container and a slow stream of hard water is passed through this
material. As a result, calcium and magnesium ions present in hard water are
exchanged with sodium ions in the permutit (Na+Al-Silicate). The outgoing water
contains sodium salts, which do not cause hardness.
Over a period of time permutit gets converted into a mixture
of calcium and magnesium aluminium-silicates and permutit has to be regenerated
for further use. This is done by packing brine - a concentrated solution of
sodium chloride, through the column packed with spent permutit. The following
reactions take place.
The resulting calcium chloride and magnesium chloride
produced, are washed out through a tap at the bottom. The regenerated permutit
is reused for softening water.
Giant organic molecules having acidic or basic groups are
known as Ion-exchange resins. Acid resins contain the acid group (- COOH).
Basic
resins contain the basic group [(-NH
)OH-],
i.e., substituted ammonium hydroxide group. Acid and basic ion exchange resins
are represented as RCOO-H+ and RNH +
OH- respectively.
)OH-],
i.e., substituted ammonium hydroxide group. Acid and basic ion exchange resins
are represented as RCOO-H+ and RNH +
OH- respectively.
Acid resins exchange their H+ ions with other cations such
as Ca2+, Mg2+, etc., present in hard water. Acid resins are, therefore known as
base-exchange resins.
Basic resins exchange their OH-ions with the other anions
such as HCO3-, Cl-, SO42-, present in hard water. Basic resins, therefore, are
also known as acid exchange resins.
Ion-exchange process for water softening
In the ion exchange process, hard water is passed through
two tanks
'A' and 'B'. Tank- A contains acid resin and tank- B is
filled with basic resin. All the cations present in hard water (except H+) are
removed by the acid resin present in Tank- A, and the basic resin present in
Tank- B removes all the anions (except OH-) present in hard water. Water
obtained after passage through both the tanks is free from all the cations and
anions that make it hard. The water obtained after passing through the
ion-exchangers is called deionised water or demineralised water. This is as
good as distilled water. The water becomes soft after this process.
Regeneration
After some time, the resins require
regeneration as they become ineffective. Adding a strong acid regenerates acid
resin and the basic resin is regenerated by treating it with a solution of a
strong base.
The regenerated resins are washed to
remove Ca2+, Na+, SO
, Cl-etc. The resins can be used again. The water treated by
ion-exchange process not only becomes soft but also free from all dissolved
mineral impurities. It gets completely demineralized.
, Cl-etc. The resins can be used again. The water treated by
ion-exchange process not only becomes soft but also free from all dissolved
mineral impurities. It gets completely demineralized.
4. Given that a sample of water has
degree of hardness equal to 40 ppm. If the entire hardness is due to MgSO4. How
much MgSO4 is present per kg of water?
The degree of hardness of water is
defined as the number of parts by mass of calcium carbonate, equivalent to
various calcium and magnesium present in one million parts of mass of water. It
is expressed in ppm.
Now, 106 g of water contains CaCO3 =
44 mg
By definition, 1 mol of CaCO3 = 1
mol of MgSO4
Or, 100 mg of CaCO3 = 120 mg of
MgSO4
Therefore 48 mg of MgSO4 is present
in 1 kg of water.
Hot And Cold-Water System
Hot and cold-water supplies from the engine room in the cellar, as shown in the accompanying view of the valve board,
heater, and main connections, the pipes and valves being set to meet previous conditions, and
conveniently and compactly arranged with symmetry on the walls and low ceiling.
HOT AND COLD-WATER SYSTEM IN
A HOTEL.
Hot Water Supply. Cylinder System
In the cylinder system the principal difference from the tank
system lies in the fact that the cylinder or reservoir of hot
water lies beneath the draw-off pipes and not above them, as with the tank system.
This being the case it is impossible to empty the reservoir unknowingly or
accidentally, should the cold water supply be shut off.
From the top of the boiler is
carried the expansion pipe. This also should rise 1 inch in 10 feet from the
boiler to its highest point. The highest point can be above the cold water
cistern or through the roof.
The cold water supply to the system
is a pipe direct from a cistern, as shown. This pipe must not be branched for
any other purpose.
It is of the highest importance that
the cold water supply pipe should be of full size, and not choked or reduced in
bore anywhere. The outflow at the hot water faucet is exactly in ratio with the down-flow of water through
this pipe, less friction, therefore everything possible must be done to give
the water full and free passage and lessen the friction. This is done by having
the pipe of good size, using bends and not elbows, or lead pipe, and seeing
that the stop-cock, if there be one, has a straight full way through it. The
stop-cock should be put near the boiler, so that the man who cleans the
waterback, or effects repairs, does not have to traverse the house to shut the
water off and afterwards to turn it on. A tee should be put on the cold water
supply connection, inside the boiler to spread the inflowing cold water over
the bottom of the boiler. If this is not done the inflowing cold water will
bore its way up through the hot water above, unless the pressure be quite low.
An emptying cock should be put
somewhere beneath the boiler, but this cock must be provided with a loose key,
so that only an authorised person can withdraw the water from the boiler.
The draw-off pipes are all taken
from the expansion pipe as shown. This pipe should therefore be carried up by
the best route to touch at the points where the faucets are, otherwise long
single branches must be run. The expansion pipe, being a single tube, has no
active or useful circulation in it.
It must never be forgotten that, on
opening a faucet, on a secondary circulation, water will proceed from both
directions to reach that faucet. The circulatory movements all cease, and quite
a new action takes place. Water will come up from the top of the boiler and
this will be hot.
Fig. 315. - Hot-Water Supply
for Office or Apartment Building.
Section of Double Boiler.
In selecting the proper system of
hot-water supply for a large building, as much judgment is needed as in the
selection of the proper system of heating.
While one system under certain
circumstances and conditions will perforin excellent service, another will fail
entirely. If the plumber is well grounded in the principles of circulation, and
a man of practical experience, he will usually be able to determine what system
of supply under the given conditions will give the best results.
Hot Water Supply from Double Boiler.
The double boiler is a device which
finds an important application in the hot-water supply systems of many high
buildings in the large cities. It is very seldom used, however, in any but the
largest cities.
Sectional view of the double boiler,
from which it will be seen that it consists of two boilers, one inside the
other. The outer boiler is heated in the usual manner, and the inner boiler is
heated by contact with the heated water of the outer boiler. The outer boiler
is under direct pressure, and the inner boiler under tank pressure. It will be
readily considered that in high buildings, running up many stories, the upper
floors are sometimes above the height at which water under city pressure can
reach. Even though this condition is not permanent, it often happens that
during certain times of day the pressure which at other times is sufficient is
so reduced that it cannot force water to the higher floors. It is under these
conditions that the double boiler is made use of,
Simple Form of Cut-off.
The inner boiler supplies
hot water to the upper floors under tank pressure, and the outer boiler
supplies the lower floors under street pressure.
- Automatic Cut-off.
The cross connection between the two
boilers allows both to be fed with street pressure when the latter is high
enough to reach the upper floors. At night when the pressure is high, this course
may be adopted, thus saving the expense of pumping to the tank.
simple form of cut-off, a device
often employed on double boiler work for the purpose of delivering into the
distributing pipes a supply of water under either tank pressure or direct pressure,
as the case may be.
The successful operation of this
cut-off is entirely dependent on the attention and caution of the attendant in
the opening and closing of the proper valves, and the occasional lack of care
has resulted in casting this device away for automatic cut-offs, such as the
one of Fig. 319.
In the latter, each of the four
valves is rigidly attached to a system of levers, operated by a handle, the
throwing of which either opens or closes the proper valves, thus obviating any
mistakes.
The same work that is accomplished
by the double boiler may be performed by two single boilers connected in the
proper manner, as seen in Fig. 320.
In order to run the two boilers
under different pressures the water front of each must be entirely separate from
that of the other. Separate coils in the same heater may be used for this
purpose. Special heaters having two separate heating surfaces may also be used.
The general connections for this system are quite similar to those of Fig. 317.
One boiler supplies the upper floors, and is therefore under tank pressure,
while the other supplies the lower floors under street pressure.
It may be stated that double-boiler
work is taken up by the author in his work entitled "Modern Plumbing
Illustrated."
A very common difficulty that is
encountered in many sections of the country, especially in the West, is the
accumulation of lime in the range connections and piping. This trouble is
serious enough in connection with the procuring of hot-water supplies for
residences and dwellings, but in the case of larger work, such as public or
semipublic buildings, its existence results in much greater annoyance.
In some localities the only natural
supply of water that can be obtained is hard water, strongly impregnated with
lime, which it takes up in its passage through the soil. The depositing of lime
takes place principally in hot-water pipes, although it also occurs in the
cold-water pipes. When the lime has once begun to accumulate on the interior of
a pipe, the accumulation increases rapidly, and often in a comparatively short
time the pipe will become entirely filled. This condition is not only a source
of much annoyance, but a source also of danger.
Many attempts have been made to
clear pipes thus filled with various substances, but even though sometimes
partially successful, such a cure does not produce permanent results. It is
usually more satisfactory to replace the filled pipe with new pipe rather than
to attempt to clean out the lime deposit.
Hot And Cold Water Supply
How high can water be raised by
atmospheric pressure?
Theoretically, a
little more than thirty-three feet, but practically, the friction of the pipes,
bends, etc., tends to reduce this height, so that it is not usually safe to
count on more than twenty-eight feet, and sometimes not more than twenty-five
feet. .
Describe the method of supplying a
cistern hot water boiler.
This style of boiler
receives its supply from a tank situated above the boiler, usually in the
attic.
Describe the method of supplying a
pressure hot water boiler.
This boiler is supplied
directly from the city water
main. Being usually under a very heavy pressure, it must be made
extra strong.
Which hot water boiler is more
susceptible to syphonage, and why?
The pressure boiler is more
likely to syphon, and for the following reason: The boiler is always at a point
higher than the street main.
What is a vacuum valve?
A valve placed upon the
supply pipe to the boiler, which is made tight from internal pressure, but upon
the pressure being withdrawn, as would be the case if the boiler was being
syphoned, the atmospheric pressure from without would open the valve, and by
admitting air break the syphon.
Where there is no vacuum valve, what
should be done?
A small hole should be
drilled through the cold water pipe within the boiler, near the top.
What is an expansion pipe and its
use?
In plumbing, it is a pipe
taken from the highest point on the circulation and led above the source of
supply, with its end over the tank, or above the roof. Its object is to relieve
the boiler from any undue pressure that may arise.
Tank Supply System For
Residence, With Circulation And Keyboard.
Why does a boiler collapse?
By letting cold water
suddenly into a hot boiler, a sudden contraction of
the water takes place, leaving a partial vacuum, and with the resistance within
removed, the, pressure of the atmosphere from without crushes in the sides.
What is the advantage of a
circulating system on the hot water?
By a continuous circulation
the water in passing the fixtures is hot. Otherwise the cold water would have
to be drawn out of the pipes whenever a faucet was opened, before hot water
could be secured.
At what intervals should half-inch
pipes be clipped up where there is no other support?
Name different ways of securing a
water supply in the country.
For what reason is compression work
preferable to self-closing or Fuller work?
By the slow closing of
compression work there is less danger of water hammer than in the quick closing
of self-closing and Fuller work.
Hot-Water Supply
In connection with the supply
work shown in Plate 51 there is also shown a system of hot-water supply, in
which the kitchen-range
boiler is heated both by the kitchen range and by a coil in the
furnace. This is a very common practice not only in country work, but in the
city also. Very often a small bath-room radiator may be heated from the hot-water
supply.
The hot-water supply system
is represented by the single heavy lines. There are several methods of heating
a range boiler from the kitchen range and another heating source below it, and
the method shown is probably the most satisfactory. It will be noted that in
this method the course of the circulation of hot water is continuous, the hot
water from the furnace passing through the range water-front, thence to the
boiler and to the fixtures, and, when it has cooled, returning to the furnace
coil. Two lines of circulation are shown, each being brought together on the
return.
The use of circulating
pipes, if properly installed, insures a constant supply of hot water close to
the fixtures supplied, and naturally obviates the necessity of drawing off
a long line of cold water before the water will run hot, as must be done in
work unprovided with circulation.
This saving in the use of
water is a matter of importance wherever water is metered or limited in amount.
Whenever the house
supply is from an attic tank the hot-water supply must be under tank pressure,
in the use of which system an expansion pipe is necessary.
Traps
A trap is a device or
fitting used to allow the free passage through it of liquids and solids, and
still prevent the passage of air or gas in either direction. There are two
kinds of traps used on plumbing fixtures
known as syphon traps and anti-syphon traps. The simplest trap is the syphon
trap - a horizontal pipe bent as shown in
known as syphon traps and anti-syphon traps. The simplest trap is the syphon
trap - a horizontal pipe bent as shown in
Fig. This forms a pocket which will retain enough
liquid to prevent air or gas from passing. The dip or loop is called the seal,
and should never be less than one and one-half inches. This type of trap is
what is known as a running-trap. This is not a good trap to use, and it is only
capable of withstanding a very low back pressure.
The trap most generally used
is what is known as the S trap, as shown in Fig 15. When this trap is subjected
to a back-pressure, the water backs up into the vertical pipe, and naturally
will withstand a greater pressure than the running-trap type - about twice as
much.
Fig.
The trap shown in Fig 16 is
what is known as a P trap, and in Fig 17 as three-quarter S trap, and has the
same resisting power as the S trap.
A trap may lose its seal either
by evaporation, self-syphonage or by suction. There is no danger of a trap
losing its seal in an occupied house from evaporation, as it would take a
number of week's time, under ordinary conditions, to evaporate enough water to
destroy the seal.
Fig. 16.
Fig. 17.
A trap can be syphoned when
connected to an unvented stack, and then only when the waste pipe from the trap
to the stack extends below the dip, so as to form the long leg of the syphon as
in Fig. 18.
Fig
When two fixtures are
installed one above the other, with nnvented traps and empty into one stack,
the lower trap can be syphoned by aspiration. The water emptying into the stack
at the higher point in passing to the trap inlet of the lower fixture, creates
a partial vacuum which sucks the water out of the trap at the lower point. To
prevent this, what is known as back-venting is resorted to, back-venting not
only protects the trap against syphonage, but relieves the seal from
back-pressure, by equalizing the pressure on both sides of the seal. All revent
pipes must be connected to vent pipes at such a point that the vent opening
will be above the level of the water in the trap.
In Fig. 19 two basins are
shown connected to soil pipe with S traps and back - vented into the air-vent
pipe, both connecting into the attic into an increaser, which projects through
the roof. This drawing is given to illustrate the proper back-venting to
prevent syphonage of basin traps, and when it is necessary to run separate
stacks for wash basins, such as are sometimes installed in bedrooms, the main
waste stack must be two inches in diameter and the vent pipe one and one-half
inches, either cast iron or galvanized wrought iron.
Non-syphon traps are those
in which the seal cannot be broken under any reasonable conditions. Some water
can be syphoned from the best of non-syphon traps made, but not enough to
destroy their seal. The commonest non-syphoning trap is known as a drum trap,
which is four inches in diameter and ten inches deep. Sufficient water always remains
in this trap to maintain its seal, even when subjected to the severest of
tests.
Fig. 19.
Fig. 20 shows a trap, which
is the type generally used to trap the bathtub.
This trap is provided with a brass trap-screw top for clean-out purposes, made
gas and water tight against a rubber gasket. A trap of this kind would not be
suitable for a lavatory, its principal fault being that owing to the enlarged
body they are not self-cleaning, affording a lodging place for the depositing
of sediment.
Fig. 20.
The non-syphon trap to be
used is one in which the action of the water is rotary, as it thoroughly scours
the trap and keeps it clean, such as is shown in Fig. 21. This trap depends
upon an inner partition to effect this rotary movement, and is so constructed
that its seal cannot be broken by syphonic action and is permitted by health
and sanitary departments, where it is impossible to run a separate vent pipe to
the roof.
Fig. 21.
Fig. 23.
One of the oldest traps is
the Cudell trap, as shown in Fig. 22. The rubber ball being of slightly greater
specific gravity than water rests on the seat and forms a seal when the water
is not flowing through the trap. This ball prevents the seal of the trap being
forced by back-pressure, and acts as a check against back flow of sewerage
should drain stop up, and provides a seal if water is evaporated.
Fig. 23 shows the old Bower
trap. The water seal is maintained by the inlet leg, extending down into the
body below the outlet. The bottom of this trap is glass, brass or lead, whichever
is desired, and can be unscrewed from trap and thoroughly cleaned.
Fig. 22.
Water Closets In General
Water closets should be in all
houses that make any pretentions towards convenience. That they are a vast
improvement over the old-fashioned, offensive privy vault in the back yard,
everybody will acknowledge. But it is equally true that, unless of a good
pattern, properly fitted up, properly used, carefully watched and frequently
cleansed, they may become not only the sources of foul smell but also the cause
of disease.
Leaving aside the question of the
pollution of the soil and of well waters, of which the privy vault must sooner or
later be the cause, it is in itself a nuisance and an abomination. In cold
weather and during rain storms persons are liable not to use it when they ought
to, and trouble of the digestive organs is sure to follow, as every physician
knows. This is especially the case with females and with delicate children.
Sick persons and invalids may suffer severely from exposure to the weather. Add
to this the often unbearable stench emanating in hot weather from such vaults,
and it will be readily seen how superior in point of convenience, health and
cleanliness an indoor water closet is.
There are other improved devices for
receiving faecal matters, such as earth closets, ash closets, tubs or pails,
which are far preferable to privies, and should be recommended wherever water
is scarce; but these do not properly belong to my subject, which refers only to
the "water carriage" system.
There is an endless list of water
closets, and each year increases the number of newly invented and patented
articles. It is, of course, impossible, nor is it even desirable, that my paper
should give a complete description of all of them. I shall limit myself to
describing the chief features of the various types of closets, mentioning a few
examples of each type.
After reviewing the different
patterns of water closets in use we shall speak of the general arrangement of
the water closet apartment with respect to light and air.
The essential points to be
considered in examining water closets are: the shape of the bowl or vessel
receiving faecal matter; the apparatus for discharging the contents of the
bowl; the manner of trapping the water closet; the manner of flushing the bowl
and the trap; and the ventilation of the water closet.
The less surface a water closet has
exposed to fouling, the cleaner and better will it be. All foul discharges
should pass into water as quickly as possible. Thus the fouling of the sides of
the vessel will be efficiently prevented and the water will have a tendency to
deodorize the excrements. All water closets holding a large body of water in
the bowl (valve and plunger closets, wash-out closets and latrines) have this advantage. In other closets, where the body of
water is in the trap (hoppers), this latter should be as near as possible to
the bowl (short hoppers are preferable on this account), and the rear side of
the vessel should be designed nearly vertical and straight to prevent foul
matter from soiling the bowl before passing into water.
A further requirement is durability
and simplicity of the working apparatus The less moving parts a water closet
has the better will it be. We must have regard to the rough usage to which such
fixtures are sometimes subjected, especially in public places. Complicated or
delicate mechanisms frequently get out of order, or fail to work properly under
children's or servants' hands. Nobody can deny that, so far as this point is concerned,
hopper and wash-out closets are vastly superior to pan, valve and plunger
closets.
A water closet should have a copious
supply of water completely to wash at each use the bowl and trap as well as all
surfaces coming in contact with foul matter. I do not, however, wish to be
understood as favoring reckless waste, for it is well known that allowing the
water to run continuously through a water closet cannot be regarded as
flushing. Two or three gallons properly applied at each use will cleanse a water
closet more thoroughly than an uninterrupted trickling flow of water. In order
to be efficient the flushing water should come down "in a sudden
dash" To make the flush effective the supply pipe from cistern to bowl
should be of large diameter, never less than one inch, and increasing up to 1
1/2 inches as the head (or height of bottom of cistern over the bowl)
diminishes. The force of the flush largely depends upon the shape of the bowl
and upon the head of water available in each With closet bowls, circular in
shape, a flush introduced in the direction of the tangent will whirl around its
circumference, losing its force without effecting much cleansing. An oval bowl
provided with a fan flush is a vast improvement. The best bowls are those
provided around the upper edge with a proper "flushing rim," into
which the water from the supply pipe enters simultaneously at all sides, and is
directed to rush vertically downward, thoroughly washing the sides of the
closet and retaining sufficient force to expel the foul contents of the water
closet trap.
The mode of flushing a water closet
from the main supply pipe of the house is decidedly objectionable, especially
with closets located in upper stories of city houses. If water is drawn from a
faucet in the basement the pressure is often reduced so much as to create a
slight vacuum in the upper part of the pipe. If the valve of a water closet
happens to be opened at such times, air, if not foul matter, rushes into the
pipe from the bowl. Thus the purity of the drinking water is endangered, while
the closet remains without a flush. This risk can be partially avoided by the
use of a check valve on the supply pipe to the closet valve. Such check valves,
however, are not reliable and often fail to shut properly.
Closets, holding water in the bowl
(pan, valve, plunger and washout closets) require an "after flush" to refill the bowl, and
the cisterns should be provided for such purpose, with a service box, holding a
certain quantity of water. The outlet from the cistern to the service-box must
be closed by a large sized valve in order to secure a quick filling of the
service-box.
Cisterns, arranged with a view to
prevent the waste of water, are desirable wherever the water supply is apt to
become scanty during the hottest and coldest months of the year. They have, in
this case, three compartments, a large tank, supplied by a ball-cock, a
measuring cistern, holding the quantity of water fixed for each flush, and a
service-box for the after flush.
Water waste preventers for hoppers,
however, require only two compartments, the receiving tank and the measuring
cistern.
Water closet cisterns are operated
either by the common pull-up arrangement, a handle being connected to one end
of a lever, the fulcrum of which is firmly secured to the floor, while the
other end of the lever is connected by a brass safety chain to the lever
operating the cistern valve. Such an arrangement is common for pan, valve and plunger closets. Or else the lever and valve is operated directly by a
chain, with tassel or ebony handle, which arrangement seems best adapted to
hoppers and washout closets (and slop sinks).
Tvpes C
A Pan closet. B Valve closet. C Pit
D Lo
C is a plunger closet with improved
flushing rim bowl, supplied with water from a cistern, the outlet of the closet
being on one side and closed by a plunger working in a chamber and to be
operated by knob and pull. The trap is above the floor and provided with a hub
to attach a vent pipe.
While these three closets
are operated by more or less complicated machinery, the three following types
are free from any movable parts.
D is a long flushing rim
hopper having an S-trap under the floor.
E is a short flushing rim
hopper with S-trap above the floor.
F is a washout closet,
holding water in the basin, which also serves as a trap.
Fig. 5 shows the general
characteristics of a trough closet (latrine).
Fig.8
Fig. 200.
"S"-Pattern Trap..
Fig. 201. A Bag Trap..
In buildings where the
plumbing may be left unused for weeks from time to time, as is likely in rented
houses, deep-seal traps, or those with
mechanical seals also, should be used.
This point is not so important in detached houses or those rented to one family
only at a time, since, when a family moves out, there is no one to suffer. But
in flat buildings, where some of the flats may be vacant for a time sufficient
for an ordinary seal to be broken while
other families are living in the house, deep-seal
traps are more essential.
Fig. 201 shows what is
termed a bag trap, made to bring the inlet and outlet in the same vertical
line. These traps are inter-clvangeable with any others with straight-line
outlet - for instance, as shown in Fig. 204.
An open-wall trap partly
cast and partly tubing, generally made of brass, is shown in Fig. 202, the vent
connection to wall being at A. This form of trap generally has a swivel-joint
at B, which is below the water line, so that the body may be swiveled to meet
roughing-in openings in any direction within two diameters of the line of
fixture outlet. The bag form shown is most convenient for D-shape or standing
waste bowls
which present the outlet comparatively near the wall. The regular "S"
of this type suits bowls with center outlet, and will reach a wider range of
variation in roughing-in.
Fig. 202. Open-Wall Trap.
Partly Cast..
Fig. 203 shows a common lead
drum or pot trap, most convenient to the plumber. It is furnished without
openings, and the plumber makes bends, and wipes-in his inlet and outlet at
points in the circumference most convenient to reach the fixture opening. A is
the screw-top clean-out; and B, the wrench-face for turning it. The trap is
furnished, when desired, with nickel-plated brass flanged cover, as shown at C,
to screw on at the floor-level. F is ordinarily the outlet, the inlet being
wiped-in near the bottom to
give it the water-lock. This is not proper, however, as it puts the sewer air
against the clean-out cover, which might leak gases into the building without
betraying any evidence of its defectiveness by water leakage. To be strictly
correct, F should be the inlet; and the outlet, in the shape of an offset, or
that of an inverted P-trap without the trap-screw, should be wiped-in near the
bottom in a way to retain the proper seal
and thus bring the sewer air against the water-seal
instead of the clean-out cover.
Traps that retain their seals by means of interior weirs are of
doubtful character, even at their best; none but well-tested cast-brass traps
of such a pattern should ever be installed. Fig. 204 is a section of a flask or
Atlas trap, with vent, usually made of cast brass and depending upon two
interior weirs to form the seal, one
retaining the water, and the other dipping into the water to prevent sewer air
from getting into the house through the fixture. If the water weir of such a
trap becomes defective, there is no evidence except odors by which the
occupants may discover it. If the dipping weir is defective the value of the
water seal is nil. In either case the
trap is no barrier to the admission of drain air to the house.
Fig. 203. Common Lead Drum
or Pot Trap..
Fig. 204. Section of Flask
or Atlas Trap with Two Interior Weirs..
Fig. 205 illustrates a form
of trap suitable for use with baths. It has a submerged inlet connection which
is expanded so that the flow enters the trap at a dipping angle which produces
a swirl with cleansing effect. The extension collar A is made so that the
screw-cover B forms the gasket joint below the water-level. The method of
providing the outlet in this trap makes it open to the same objection raised in
connection with Fig. 203. This form, however, has the merit of being accessible
for inspection without disturbing its service, which is impossible with the
flask pattern shown in Fig. 204.
Various Types Of W.C.'s, And Water-Waste Preventers. Part 3
Urinals are of two types,
the lipped basin and the circular back. The lipped basin (Fig. 209) is trapped
in itself, but the circular-backed (Fig. 210) discharges into a channel with a
perforated grating on top, which is easily cleansed. This channel is trapped at
the end with a gulley,
and the trap
ventilated before its connection to the drain.
Fig. 208.
Fig. 209.
Fig. 210.
Sinks And Their Wastes
They are usually about 3
feet by 2 feet, and about 2 feet 6 inches from the floor to
the top edge (see Fig. 211). They may be supported on half-brick walls
rendered in Portland
cement, or on cast-iron
brackets, or on glazed pedestals. The sink should have a good fall to
the outlet, which should be arranged in the corner on the side next the outer
wall. The outlet should be fitted with a 3 1/2-inch bell-mouthed
cobweb grating, and the waste trapped with a trap at least 2 inches internal
diameter, with inspection screw cap as shown in Fig. 212.
Fig. 211.
Fig. 212.
Housemaid's Sink
This is usually in
connection with the slop-sink, but it is more usual to empty the slops down the
water-closet. Fig. 213 shows a Doulton's combined wash-up and slop-sink. The
basin and trap are in earthenware, and there are valves for
hot and cold water. The wooden grating on the wash-up side is to prevent
crockery from being broken by contact with the stoneware. The trap and waste
should be ventilated and connected to a soil
pipe
outside.
Butler's sinks are usually
15 inches deep, in lead, with 10-lb. bottom, and 7-lb. sides; the joints at the
angles and
bottom being made by means of welts.
Where a large amount of hot
water is used it is found that the expansion and contraction crack the joint on
the lead trap. To prevent this an expansion joint, as shown by Fig. 215, is
used. The expansion and contraction are taken up by a solid rubber ring passing
round the outside of the upper pipe, and allowing it to move up and down.
Another method is to use cast - brass traps; but, although they are not liable
to so great expansion and contraction, being rough inside from the core sand,
they catch and retain the grease, and are therefore not so cleanly as the lead
traps.
Fig. 216.
Taps And Fittings
The regulations of Water
Companies cause these fittings to
vary in different localities, so that what may be legally used in one part of
the country is forbidden in another.
Fig. 216 shows a section
through Lord Kelvin's bib tap. This avoids the use of washers, and the turning
of the tap grinds the valve on its seating.
Fig. 217.
Fig. 217 shows a stop
cock
for connection to a lead pipe. It will be noticed that the joint is made by a
brass-screwed collar, and not by the wiped joint as in ordinary practice.
Fig. 218 shows a quick-turn
full-way cock which can be used as a stop cock.
A quarter-turn bib valve is
shown by Fig. 219.
Where the pressure is low, a
clear-way wheel valve may be used, as shown by Fig. 220. This valve does not
diminish the force of the flow.
If the water supply is
limited, a spring valve is used for lavatory basins, as shown by Fig. 221. It
is actuated by pressing the knob at the top, which springs back, shutting off
the water when the pressure is released.
Fig. 218.
Fig. 219.
Fig. 220.
To prevent birds, dirt,
etc., entering overflows,
and the ingress of cold air in winter, a flap valve is used, as shown by Fig.
222.
In storage cisterns and
water-waste preventers, a full-way ball valve, as shown on Fig. 223, is used.
It permits the water free egress, and automatically closes when the tank is
full.
Fig. 221.
Where quick closing taps,
such as the spring valve, are used, an air chamber should always be fixed, to stop the
noise made by the sudden closing of the tap. This noise is known by the name of
"water-hammer," and is caused by suddenly stopping the flow of water
shows an air chamber on an ascending pipe, Fig. 225 on a descending pipe, and
Fig. 226 when the tap is on a rising main.
Fig. 224.
(taking place through the
whole of the pipes) when a tap is closed. With a screw-down tap, however, the
water is shut off gradually, and no appreciable concussion occurs. The use of
an air chamber is to act as a buffer when sudden pressure is put on. Fig. 224
Drainage
When the main line of drains has
been laid the trenches can be continued in a similar manner to the gulleys or soil
pipes. Right-angled junctions should never be permitted, but
special pipes
with easy bends should be used (see Fig. 185). Connections should be made at
the sides and
not top of the pipes.
Fig. 186 shows a method of
carrying stoneware drains on marshy or silty ground. 12 by 6-inch piles are
driven about 6 feet apart and two 12 by 4-inch runners secured to each side of
these piles with coach screws. The bottom of the trench is then made firm by
clay puddling, the concrete
foundations put in, and the pipes laid in the usual way.
Fig. 184.
Fig. 185.
Cast-Iron Pipes
When it is found necessary
to carry a line of mains through a house, cast-iron
pipes should be used and completely covered with concrete. These are made in
9-feet lengths, and weigh as follows:-
|
3
|
inches
|
1/4-in.
|
metal,
|
no
|
lbs.
|
per
|
9-ft.
|
length.
|
|
4
|
"
|
3/8
|
"
|
160
|
"
|
"
|
||
|
5
|
"
|
3/8
|
"
|
190
|
"
|
"
|
||
|
6
|
"
|
3/8
|
"
|
230
|
"
|
"
|
Rust joints are
sometimes used for iron pipes, but caulked joints are preferable, as the
expansion of the rust cement
when setting has
a tendency to burst and crack the sockets of the pipes. The usual way is to
make the joints with lead wire or
molten lead and caulk them afterwards. Turned and
bored pipes have been used, and it has been found that they readily adjust
themselves to slight settlements.
The inside surfaces of pipes
should either be coated with Dr. Angus Smith's
solution, or glass
enamel. The former is more generally used, the latter being costly and liable
to chip and crack.
Fig. 186.
Fig. 187.
All junctions and bends
should be arranged with cast-iron
access pipes fitted with air-tight covers secured with brass screws.
Intercepting And Inspection Chambers
Fig. 187 shows an
Intercepting Chamber. These should be built in cement, on a concrete bed at
least 9 inches thick, and finished on top with a double or single seal
cast-iron manhole cover. The concrete foundation having been put in, the
disconnecting trap is placed in position and set perfectly level. There are
many varieties of intercepting traps in the market, but a satisfactory one
should have a 3-inch weir action and 1 1/2-inch water seal and sweeping arm.
All half-channel pipes and
bends should have 1-inch fall in their length in addition to the general gradient, to
compensate for the loss of head due
to friction.
Should the sewer be at a
great depth, ramps may
be used to save the expense of laying deep drains. These have a short arm with
stopper fixed in same carried through the wall of
manhole for rodding the drains.
Another form of ramp is that
shown by dotted lines, the main pipe being continued full bore direct into the
chamber, and a galvanised cast-iron flap valve fixed at the chamber end, to
enable the sewage to flow
into the chamber should the ramp become blocked.
The minimum internal dimensions
of chambers should be 3 feet 0 inches by 2 feet 3 inches. In deep drains,
however, they may be as large as 4 feet 1 1/2 inch by 2 feet 7 1/2 inches, and
be gathered over at a height of 5 feet 6 inches above invert of drain, and
continued to ground level with a shaft 1
foot 10 1/2 inches by 1 foot 10 1/2 inches inside dimensions.
Where the distance between
two inspection chambers exceeds 100 feet, sweeping eyes may be constructed, as
shown by Fig. 188. These should be finished with a stopper bedded in soft soap
and covered by a slab of York stone and
a small hinged cast-iron cover. Inspection chambers are similar in construction
to intercepting chambers, but the fresh-air inlet and intercepter are omitted.
Fig. 189
.
Elevators:-
Hydraulic Elevators And Motors
Hydraulic Elevators And Motors. Part 2
Whether this plan is
practicable or not must be left to elevator manufacturers, but it seems to me
that with the Hale-Otis elevator for instance (which is conceded to be one of
the best) it could easily be accomplished. Certainly some such arrangement would
effect a great saving of water, and perhaps bring water bills to a point that
this class of consumers could afford to pay.
Hydraulic
elevators where the water is used over and over again, by being
pumped from the discharge to elevated tanks, cut little or no figure in
connection with a city's water supply. When fuel, first cost,
attendance of an engineer, and the poor economy of the class of pumps usually
employed to perform this work are considered, the cost of operating such
elevators is greatly in excess of what it would be if power were supplied
direct from water mains, at any reasonable rate. The following remarks will
then relate almost exclusively to that class of hydraulic elevators supplied
with power directly from the water mains.
The "water hammer"
produced by the quick acting valves of elevators has always been objectionable,
both in its effect at the pumping-house and upon water mains and connections.
To obviate this, Engineer G. W. Pearson has suggested the use of very large air
chambers on the elevator supply, and still smaller openings in the mains, his
theory being that the air chambers would not only materially decrease the
concussion or "water hammer," but that they would also act as
accumulators of power (or water under pressure) to be drawn from at each trip
of the elevator, and replaced when it was at rest. This plan I have never seen
put to actual test, but believe it to be entirely practicable, and that we will
have to ultimately adopt it.
All things considered, the
plan of operating elevators from tanks in the top of buildings, supplied by a
small pipe connected with the water-mains and arranged with a float valve to
keep the tank filled, I believe to be the best manner of supply, except for the
great additional cost of putting up such apparatus. By this arrangement the amount
of water consumed is no less, in fact it would ordinarily be more than with a
direct connection with the mains, but it has the advantage of taking the water
in the least objectionable manner. Still, if this mode of supply were generally
enforced, the large first cost, an additional expense of operating, would
undoubtedly deter many from using elevators.
