p.r.o.ny Brake.
A device for measuring the power applied to a rotating shaft. It consists of a clamping device to be applied more or less rigidly to the shaft or to a pulley upon it. To the clamp is attached a lever carrying a weight. The cut shows a simple arrangement, the shaft A carries a pulley B to which the clamp B1 B2 is applied. The nuts C1 C2 are used for adjustment.
A weight is placed in the pan E attached to the end of the lever D. The weight and clamp are so adjusted that the lever shall stand horizontally as shown by the index E. If we call r the radius of the pulley and F the friction between its surface and the clamp, it is evident that r F, the moment of resistance to the motion of the pulley, is equal to the weight multiplied by its lever arm or to W*R, where W indicates the weight and R the distance of its point of application from the centre of the pulley or r*F = R*W. The work represented by this friction is equal to the distance traveled by the surface of the wheel multiplied by the frictional resistance, or is 2*PI*r*n*F, in which n is the number of turns per minute. But this is equal to 2*PI*R*W. These data being known, the power is directly calculated therefrom in terms of weight and feet per minute.
Proof-plane.
A small conductor, usually disc shaped, carried at the end of an insulating handle. It is used to collect electricity by contact, from objects electrostatically charged. The charge it has received is then measured (see Torsion Balance) or otherwise tested. (See Prime Conductor.)
Proof-sphere.
A small sphere, coated with gold-leaf or other conductor, and mounted on an insulated handle. It is used instead of a proof-plane, for testing bodies whose curvature is small.
Fig. 275. BOX BRIDGE.
437 STANDARD ELECTRICAL DICTIONARY.
Proportionate Arms. In general terms the arms of a Wheatstone bridge whose proportion has to be known to complete the measurement. There is a different system of naming them. Some designate by this t.i.tle the two arms in parallel with each other branching at and running from one end of the bridge to the two galvanometer connections. In the cut of the Box Bridge, A C and A B are the proportionate arms. The third arm is then termed the Rheostat arm. (Stewart & Gee.)
Others treat as proportionate arms the two side members of the bridge in parallel with the unknown resistance and third or rheostat arm.
Synonym--Ratio Arms.
Prostration, Electric.
Too great exposure to the voltaic arc in its more powerful forms causes symptoms resembling those of sunstroke. The skin is sometimes affected to such a degree as to come off after a few days. The throat, forehead and face suffer pains and the eyes are irritated. These effects only follow exposure to very intense sources of light, or for very long times.
[Transcriber"s note: Arcs emit ultraviolet rays.]
Protector, Comb.
A lightning arrester, q. v., comprising two toothed plates nearly touching each other.
Protector, Electric.
A protective device for guarding the human body against destructive or injurious electric shocks. In one system, Delany"s, the wrists and ankles are encircled by conducting bands which by wires running along the arms, back and legs are connected. A discharge it is a.s.sumed received by the hands will thus be short circuited around the body and its vital organs. India rubber gloves and shoe soles have also been suggested; the gloves are still used to some extent.
Pull.
A switch for closing a circuit when pulled. It is used instead of a push b.u.t.ton, q.v., in exposed situations, as its contacts are better protected than those of the ordinary push b.u.t.ton.
Pump, Geissler.
A form of mercurial air pump. It is used for exhausting Geissler tubes, incandescent lamp bulbs and similar purposes.
Referring to the cut, A is a reservoir of mercury with flexible tube C connected to a tube at its bottom, and raised and lowered by a windla.s.s b, the cord from which pa.s.ses over a pulley a. When raised the mercury tends to enter the chamber B, through the tube T. An arrangement of stopc.o.c.ks surmounts this chamber, which arrangement is shown on a larger scale in the three figures X, Y and Z. To fill the bulb B, the c.o.c.ks are set in the position Z; n is a two way c.o.c.k and while it permits the escape of air below, it cuts off the tube, rising vertically from it.
This tube, d in the full figure connects with a vessel o, pressure gauge p, and tube c, the latter connecting with the object to be exhausted.
The bulb B being filled, the c.o.c.k m is closed, giving the position Y and the vessel A is lowered until it is over 30 inches below B.
438 STANDARD ELECTRICAL DICTIONARY.
This establishes a Torricellian vacuum in B. The c.o.c.k n is now turned, giving the position X, when air is at once exhausted from the vessel connected to C. This process is repeated until full exhaustion is obtained. In practice the first exhaustion is often effected by a mechanical pump. By closing the c.o.c.k on the outlet tube c but little air need ever find its way to the chambers o and B.
Fig. 276. GEISSLER AIR PUMP.
439 STANDARD ELECTRICAL DICTIONARY.
Pumping.
In incandescent lamps a periodical recurring change in intensity due to bad running of the dynamos, or in arc lamps to bad feeding of the carbons.
Fig. 277. SPRENGEL AIR PUMP.
Pump, Sprengel.
A form of mercurial air pump. A simple form is shown in the cut. Mercury is caused to flow from the funnel A, through c d to a vessel B. A side connection x leads to the vessel R to be exhausted. As the mercury pa.s.ses x it breaks into short columns, and carries air down between them, in this way exhausting the vessel R. In practice it is more complicated. It is said to give a better vacuum than the Sprengel pump, but to be slower in action.
440 STANDARD ELECTRICAL DICTIONARY.
Pump, Swinburne.
A form of mechanical air pump for exhausting incandescent lamp bulbs.
Referring to the cut, A is a bulb on the upper part of a tube G; above A are two other bulbs C and D. From the upper end a tube runs to the bulb E. Through the c.o.c.k L, and tube F connection is made with a mechanical air pump. The tube H leads to a drying chamber I, and by the tube J connects with the lamp bulbs or other objects to be exhausted. The tube G enters the bottle B through an airtight stopper, through which a second tube with stopc.o.c.k K pa.s.ses. In use a vacuum is produced by the mechanical pumps, exhausting the lamp bulbs to a half inch and drawing up the mercury in G. The bent neck in the bulb E, acts with the bulb as a trap to exclude mercury from F. When the mechanical pumps have produced a vacuum equal to one half inch of mercury, the c.o.c.k L is closed and K is opened, and air at high pressure enters. This forces the mercury up to the vessel D, half filling it. The high pressure is now removed and the mercury descends. The valve in D closes it as the mercury falls to the level G. Further air from the lamps enters A, and by repet.i.tion of the ascent of the mercury, is expelled, through D. The mercury is again lowered, producing a further exhaustion, and the process is repeated as often as necessary.
Fig. 278. SWINBURNE"S AIR PUMP.
Push-b.u.t.ton.
A switch for closing a circuit by means of pressure applied to a b.u.t.ton.
The b.u.t.ton is provided with a spring, so that when pushed in and released it springs back. Thus the circuit is closed only as long as the b.u.t.ton is pressed. The electric connection may be made by pressing together two flat springs, each connected to one of the wires, or by the stem of the b.u.t.ton going between two springs, not in contact, forcing them a little apart to secure good contact, and thereby bridging over the s.p.a.ce between them.
441 STANDARD ELECTRICAL DICTIONARY.
Pyro-electricity.
A phenomenon by which certain minerals when warmed acquire electrical properties. (Ganot.) The mineral tourmaline exhibits it strongly. It was originally observed in this mineral which was found to first attract and then to repel hot ashes.
The phenomenon lasts while any change of temperature within certain limits is taking place. In the case of tourmaline the range is from about 10? C. (50? F.) to 150? C. (302? F.) Above or below this range it shows no electrification.
The effect of a changing of temperature is to develop poles, one positive and the other negative. As the temperature rises one end is positive and the other negative; as the temperature becomes constant the polarity disappears; as the temperature falls the poles are reversed.