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If a rotary pump leaks, the efficiency is not impaired so much as in a piston or plunger pump, all that is necessary being to run the pump at a high speed.
[Ill.u.s.tration: Fig. 3323.]
The principles of action of a pump may be understood from Fig. 3323, which represents a single acting plunger pump shown in section, and with the suction pipe in a tank of water, the pump being empty.
The surface of the water in the tank has the pressure of the atmosphere resting upon it, and as the pump is filled with air, the surface of the water within the pipe is also under atmospheric pressure.
Now suppose the plunger to move to the right, and as no more air can get into the pump, that already within it will expand, and will therefore become lighter, hence there will be less pressure on the surface of the water within the suction pipe than there is on the outside of it, and as a result the water will rise up the pipe, not because the plunger draws it, but because the air outside the pipe presses it up within the pipe.
[Ill.u.s.tration: Fig. 3324.]
The water inside the pipe will rise above that outside in proportion to the amount to which it is relieved of the pressure of the air, so that if the first outward stroke of the plunger reduces the pressure within the pump from 15 lbs. to 14 lbs. per square inch (15 lbs. per square inch being a.s.sumed to be its normal pressure), the water will be forced up the suction pipe to a distance of about 2-1/4 feet, because a column of water an inch square and 2-1/4 feet high is equal to 1 lb. in weight.
In Fig. 3324 the pump plunger is shown to have moved enough to have permitted the water to rise above the suction valve, and it will continue to rise and enter the pump barrel as long as the plunger moves to the right.
When the plunger stops, the suction valve will fall back to its seat and enclose the water in the pump; but as soon as the plunger moves back to the left hand and enters the barrel pump further, the delivery valve will rise, and the plunger will expel from the pump a body of air or water equal in volume to the cubical contents of the plunger, or rather of that part of it that is within the barrel, and displaces water.
If the plunger was at the end of its first stroke to the right and the pump half filled with air, then this air will be expelled from the pump before any water is; whereas if the pump was filled with water, the latter only will be delivered.
Now suppose the first plunger stroke reduces the air pressure from 15 to 14 lbs., and that the second drawing stroke of the plunger reduces the air pressure in the pipe to 13 pounds per inch, the water will rise up it another 2-1/4 feet, and so on until such time as the rise of a column of water within the pipe is sufficient to be equal in weight to the pressure of the air upon the surface of the water without; hence it is only necessary to determine the height of a column of water that will weigh 15 lbs. per square inch of area at the base of the column to ascertain how far a suction pump will cause water to rise, and this is found by calculation or measurement to be a column nearly 34 feet high.
It is clear then, that however high the pump may be above the level of the water, the water cannot rise more than 34 feet up the suction pipe, even though all the air be excluded from it and a perfect vacuum formed, because the propelling force, that is, the atmospheric pressure, can only raise a column of water equal in weight to itself, and it is found in practice to be an unusually good pump that will lift water thirty feet.
[Ill.u.s.tration: Fig. 3325.]
Fig. 3325 shows the plunger making a delivery stroke, the suction valve being closed, and the delivery valve open where it will remain until the plunger stops.
To regulate the quant.i.ty of water the pump will deliver in cases where it is necessary to restrict its capacity, as in the case of maintaining a constant boiler feed without pumping too much water in the boiler, the height to which the suction valves can lift must be restricted, so as to limit the amount of water that can enter the pump at each drawing stroke.
The delivery valve should lift no more than necessary to give a free discharge without causing the valve to seat with a blow; but if the pump has a positive motion, the delivery valve must open wide enough to let the water out, or pressure enough may be got up in the pump to break it.
A check valve is merely a second delivery valve placed close to the boiler and serving to enable the pump to be taken apart if occasion should arise, without letting the water out of the boiler.
The lift and fall of both valves act to impair the capacity of the pump.
Thus, while the suction valve is falling to its seat, the water already in the pump pa.s.ses back into the suction pipe, and similarly, while the delivery valve is closing, the delivery water pa.s.ses back.
A foot valve is virtually a second suction valve placed at the bottom or foot of the suction pipe.
The capacity of a pump is from 70 to 85 per cent. of the displacement of the plunger or piston, and varies with the speed at which the plunger or piston runs.
If a pump runs too fast, the water has not sufficient time to follow the piston or plunger, especially if the suction pipe has bends in it, as these bends increase the friction of the water against the bore of the pipe.
The speed of the piston or plunger should not exceed such as will require the water to pa.s.s through the suction pipe at a speed not greater than 500 feet per minute, and better results will be obtained at 350 feet per minute.
An air chamber placed above the suction pipe of any pump causes a better supply of water to the pump by holding a body of water close to it, and by making the supply of water up the suction pipe more uniform and continuous. Air chambers should be made as long in the neck as convenient, so that the water in pa.s.sing through the pump barrel to the delivery pipe could not be forced up into the chamber, as, if such be the case, the air in the chamber is soon absorbed by the water.
Belt pumps are more economical than independent steam pumps, because the power they utilize is more nearly the equivalent of the power it takes to drive them, whereas in steam pumps there is a certain amount of steam, and therefore of power, expended in tripping the valves and in filling the clearance s.p.a.ces in the cylinder. Furthermore, the main engine uses the steam expansively, whereas the steam pump does not.
[Ill.u.s.tration: _VOL. II._ =AMERICAN FREIGHT LOCOMOTIVE.= _PLATE XXIX._
Fig. 3326.]
CHAPTER x.x.xVIII.--THE LOCOMOTIVE.
In Fig. 3326 is shown a modern freight locomotive, the construction being as follows:
For generating the steam we have the boiler, which at the front end is firmly bolted to the engine cylinders, which are in turn bolted to the frames, while at the back end the boiler is suspended by the links B (one at each end of the fire box on each side of the engine).
The starting bar is shown in position to start the engine, and it is seen that the rod _a_ and bell crank _b_ are in such a position as to open the valve T, and thus admit steam from the dome to the pipe _e_, whence it pa.s.ses through pipes _f_, _g_ and _r_ into the steam chest _i_, the slide valve V distributing the steam to the cylinder. The exhaust occurs through the exhaust port _d_, whence it pa.s.ses up the exhaust pipe and out at the smoke stack.
The boiler is fed with water as follows:
The _feed pipe from the tender_ supplies water to the injector, which is forced by the injector through the _feed pipe to boiler_ and into the latter.
In the figure the parts are shown in position for the engine to go ahead, hence the reversing gear is in the extreme forward notch of the sector, and the valve gear is in full gear for the forward motion.
The lever _m_ is for opening and closing the cylinder c.o.c.ks, which are necessary to let the water of condensation out of the cylinder when the engine is first started and the cold cylinder condenses the steam.
To supply steam to the injectors (of which there are two, one on each side of the engine) and to the steam cylinder of the pump, there is a steam pipe leading from the dome to the steam drum, the pipe K supplying steam to the injector, and pipe J supplying steam to the steam cylinder of the air pump. The pipe for supplying oil to the slide valve and cylinder is furnished with a sight feed oil cup, the oil being carried by steam from the steam drum.
This pipe pa.s.ses beneath the lagging until it reaches the smoke box, which is done to keep it warm and prevent the oil from freezing, while the steam pressure enables the oil to feed against the steam pressure in the steam chest.
The slide valve is balanced by means of strips let into its back, and bearing against a plate fixed to the steam chest cover.
The frame on the side of the engine shown in the engraving is shown broken away from the yoke A to the fire box, so as to expose the link motion to full view, the shaded portion of the frame being that on the other side of the engine.
The yoke or brace A carries one end of the guide bars. The safety valve S may be raised to see that it is in working order, or to regulate the steam pressure, by the lever O, which has a ratchet tongue engaging with the notches at _l_.
[Ill.u.s.tration: Fig. 3326_a_.]
[Ill.u.s.tration: Fig. 3326_b_.]
In addition to the safety valve with spring balance, however, a pop safety valve is employed on the part of the dome that is shown broken away, the construction of this pop valve being shown in the outside view, Fig. 3326_a_, and a sectional view, Fig. 3326_b_, the casing being removed from the latter. In the valve seat B is a recess _a_, and upon the circ.u.mference of the valve is a threaded ring C'. When the valve lifts, the steam is somewhat confined in the annular recess of the valve, and the extra valve area thus receiving pressure causes the valve to lift promptly and the steam to escape freely. The degree of this action is governed as follows:
The sleeve C' is threaded upon the upper part of the valve, so that by s.c.r.e.w.i.n.g it up or down upon the valve the amount of opening between the annular recess _a_ _a_, and the lower edge of the sleeve C' C', is increased or diminished at will; the less this opening, the more promptly the valve will rise after lifting from its seat.
To secure the sleeve or ring in its adjusted position, the ends of the screws L, L seat in notches cut in the upper edge of the sleeve. In many engines pop valves alone are used, and in some cases levers are provided by means of which the pop valve can be raised from its seat to test if it is in working order.
Referring again to Fig. 3326, H is the handle for operating the injector, and _w_ a rod for opening the injector overflow.
We now come to the automatic air brake; steam for the steam cylinder of which, is received from the steam drum through the pipe J, pa.s.sing through the pump governor, or regulator G. The exhaust pipe for the steam cylinder of the air pump pa.s.ses into the smoke box. The air cylinder receives its supply of air through the small holes at _k_, _k_, and delivers it through the pipe C into the air reservoir or tank, from which it pa.s.ses through the tank pipe up to the threeway c.o.c.k or engineer's brake valve, whose handle is shown at M. The brakes are kept free from the wheels and out of action so long as there is air pressure in the air reservoir and in the train pipe, hence the normal position of the handle M is such as to let the air pa.s.s from the air reservoir up the pipe _x_ and into the train pipe. When the brakes are to be applied, handle M is moved so that there is an open connection made between the train pipe and the _pipe to open_ air, which releases the air pressure and then puts on the brakes not only on each car, but also on the engine, because the engine brake cylinders receive their air pressure from the pipe shown leading to the train pipe. From the tank pipe _x_ a pipe _h_ leads to the top of the pump governor G, whose action is to shut off the steam from the steam cylinder of the air pump whenever the pressure in the air reservoir or tank exceeds 70 lbs. per square inch. A small pipe leads up from pipe _h_ to the air pressure gauge.
For regulating the draught of the fire there is a damper door at each end of the ash pan, and to increase the draught, a pipe leads from the steam drum into the smoke box, where it pa.s.ses up alongside of the exhaust pipe, its end being shown at Z. This is called the _blower_, and its pipe is on the other side of the engine. The plate shown at P, P in the smoke box checks the draught in the upper tubes, and therefore distributes it more through the lower ones.
[Ill.u.s.tration: Fig. 3327.]