US639459A

US639459A - Electric ground-detector for constant-current arc-light circuits.

Info

Publication number: US639459A
Application number: US73156999A
Authority: US
Inventors: John Franklin Stevens
Original assignee: Individual
Current assignee: Individual
Priority date: 1899-09-25
Filing date: 1899-09-25
Publication date: 1899-12-19
Anticipated expiration: 1916-12-19

Description

Patented nec. I9, 1399.

.L F. STEVENS. l ELECTRIC GROUND DETECTOR FOR CONSTANT CURRENT ARC LIGHT CIRCUITS.

(Application led. Sept. 25, 1899-) (No Model.)

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JOHN FRANKLINSTEVENS, OF PHILADELPHIA, PENNSYLVANIA..

SPECIFICATION forming part of Letters Patent No. 639,459, dated December 19, 1899.

Application filed September Z5, 1899. Serial No. 731,569. (No model.)

To all whom t may concern:

Be it known that I, JOHN FRANKLIN STE- VENS, a citizen of the United States, residing at Philadelphia, in the county of Philadelphia and State of Pennsylvania, have invented a new and useful Electric Ground-Detector for Constant-Current Arc-Light Circuits,ot` which the following is a specification.

My invention relates to electric ground-detectors for constant-current arc-light circuits; and my object is to provide an improved method whereby such indications may be observed and whereby the extent of the ground, together with its location on the line, may be readily determined by means of one self-contained indicating instrument located at or near the source of power. I attain this object by the mechanism illustrated in the accompanying drawings, in which- Figure 1 is a plan view of my device. Fig. 2 is a cross-sectionon line wreef Fig. 1 of the fixed coil and pivoted magnetic vane. Fig 3 is a diagrammatic view of the paths of the current.

Similar numerals refer to similar throughout the several views.

Upon the spools of non-conducting material are wound the coils 1 and 2, said coils being so wound and connected as to form a single solenoid or fixed coil. In cross-section this solenoid is elliptical-that is, about eight times as wide as it is high, as shown in Fig. 2, while its length from pole to pole is about equal to its largest dimension. I do not mean to confine myself to these ratios absolutely, but have found that with the relative proportions given the strength of field due to a given number of ampere-turns of the energizingwire is greater than with any other ratio I have tried, this by reason of the field being concentrated and the magnetic circuit through the air short. Within this solenoid isa magnetized steel vane 3, mounted on an axis 4', which passes through suitable holes in the sides of the solenoid, carrying jeweled bearings properly supported from the frame of the solenoid. This steel vane is made from highlytempered steel magnetized in a strong magnetic field while hot and tempered glass-hard in mercury while still under the inuence of parts the field. The action of the solenoid on this vane when the instrument is in circuit is such i that its original magnetization is reinforced and there is no tendency for it to weaken and so change the calibration of the instrument. To this axis 4 is rigidly attached a pointer 5, which is free to move with said axis and vane and to sweep the scale 6, which is marked off in divisions of a volt or multiples thereof. This pointer carries with it an aluminium blade moving in a dash-box 7, whereby the oscillations of the pointer are damped. Attached also to the same axis is a bent counterpoise 8, with weights 9 threaded thereon, Whose position on the counterpoise may be varied at will, forming an adjustable gravity control for the system.

In series with the solenoid formed by 1 and 2 is a non-inductively-wound resistance lO on the insulated spool.

All of the above-described mechanism is mounted` in an iron containing-case 11, provided with lugs 12 at the back, by means of which it can be secured to the wall or switchboard. This case, in addition to forming a cover and support for the mechanism of the instrument, also acts as a magnetic shield, preventing the instrument from being affected by external fields. In the bottom and outside of the case are mounted three rubber-covered binding-posts 13, 14, and 15, set in insulated bushings. These bindingposts serve to receive the leads from the circuit and the ground connections. Set in the front plate of the instru ment-case is a switchboard or block 16, of hard rubber, in which are mounted the receptacles 17, 1S, and 19, connected inside the case by means of insulated wires with the aforementioned bindingposts 13, 14, and l5, respectively. In this switchboard 16 is also mounted the two plugreceptacles 20 and 2l, to which are attached the flexible conductors and

plugs

22 and 23. All of these plug connectors andreceptacles are sunk below the surface of the rubber block to obviate any danger to the user by a possible touching of two terminals at the same time.

The operation of the instrument is as follows: Assume that the binding-post 13 is connected to P, the plus side of the line, and the binding-post 15 to M, the minus side of the line, while the binding-post 14 is connected to ground. Then, since 13 is connected with ICO 17, let connected with 1S, and 15 connected with 16, if we place the plug 22 in 17 and in 16, current will iiow from the line through 13 to 17, thence to 20, then, by the wire 24, to resistance 10, thence, through wire 25, to coils 1 2 of solenoid to 21, to 19, to binding-post 15, and then back to the minus side of the line. Now the solenoid 1 2 being energized by the current flow will endeavor to draw the vane 3 into a position at right angles to that shown-that is, the lines of force in the vane and solenoid will endeavor to place themselves in parallel by the Well-known actions of solenoids on magnetized vanos. The angular movement of the vane will be proportional to the impressed electromotive force of the circuit, and the pointer will indicate directly, assuming the instrument to have been properly calibrated, the total electromotive force at the terminals of the generating-dynamo. In the same wayif the plug 22 isputin 17 and 23in 18 the plus side of the line will be connected to ground through the instrument, and if there is any ground on the plus side of the line theinstru ment will measure the drop between the point where 18 is connected tothe line and the point which is grounded, indicating by the movement of the pointer across the scale the extent of the dropin volts to which the ground corresponds. By placing the plug 22 in 1S and 23 in 19 the same indication may be had for the minus side of the line.

The method of reading and operating the instrument is as follows: The instrument is first set up and secured to the wall or switchboard, the pointer standing at zero on the scale. The plus side of the line is connected to 13, the minus side to 15, and the bindingpost 14: to ground, line connections being made between the dynamo and first lamp. Now put plug 22 in 17 and 28 in 18. If there is no deflection of the pointer, there is no current flowing through the instrument and no ground. This may be checked by putting 22 in 17^and 23 in 19, and if there was no deflection with the first set of connections there should be none with the second. Suppose, however, that when 22 is placed in 17 and 23 in 18 there is a detlection. Note the deflection in Volts, calling it V. Then place 22 in 18 and 23 in 19 and note the second deflection. Callit V1. Now place 22 in 17 and 23 in 19 and note the deflection. (This will be the voltage across the terminals of the dynamo.) Call this V2. Now in so much as V was the drop between the dynamo and the groundpoint on the plus side and V1 the drop from the grounded point back to the minus side of the dynamo, while V2 measured the total eleot'romotive force of the dynamo, the sum of V-l-V1 will equal V2 if there is a deadground, and the location of the ground may be found by dividing V, the drop from the plus terminal of the dynamo to the grounded point by V3, which is assumed as the drop through one lamp, so that this quotientis the number of lam ps out from the plus side of the dynamo, just beyond which the ground is located. This operation, expressed mathematically, is that when V -l- Vl z: V2 there is a dead-ground on the line and if we call N the number of the lamp beyond which the ground is to befound, counting out from the plus terminal of the dynamo, N I

To insert numerical values in the above, let us assume a line with ten arc-lamps in series each having a drop of fifty volts, (V3.) Suppose we test the plus side and get a deliection of one hundred volts (V) and on the minus side a deflection of four hundred volts, (VD) while V2 equals five hundred from the conditions stated. Then 100 -i- 400 500, and we know there is a dead-ground, so we divide V z 100 by V3 50 and we get 2 as a result, which means that the ground is between the second and third lamp out from the plus side of the dynamo. Now suppose V -l- V1 is less than V2. Then we know that there is not a dead-ground, but merely a ground through a resistance,which resistance is great or small, as the sum of V-l- V1 is much less than or nearly equal to V2. This is because the instrument in this case has in series with it when connected to the ground on either side the resistance of the ground, which operates to change the calibration of the instrument by the ratio of the sum of the resistance of the ground and the resistance of the instrum ent to the resistance of the instrument alone. At the same time the reading across the terminals of the dynamo is not affected, since no extra resistance is interposed in this circuit. Then we have for N the following relation and value:

N VV2 www As will be noted, this becomes the general equation of a ground, whether dead or partial, for when the ground is dead V -l- V1 V2, and this factor' cancels, leaving the original fvfyzfl being the resistance factor, which modifies the true value of V in the original calibration of the instrument.

To assume a numerical example of the above, consider the same plant that was used in the illustration of a dead-ground condition and assume a partial ground through ten thousand ohms between the second and third lamp, and, further, assume the resistance of the instrument to be ten thousand ohms. Now when V is measured the total resistance in the instrument-circuit will be twenty thousand ohms andthe values of the readings will be halved, or five hundred volts will read only two hundred and fifty, so the drop to the point of ground being normally one hundred will only register fifty and from the ground back to the minus side of the dynamo only two hundred in place of four hundred, while, since there is no extra resistance in circuit IOO IOS

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when the instrument is across the terminals of the dynamo, V2 reads five hundred, as before. Now taking the equation and substituting the readings V: 50,V,= 200,

V2 500, and V3 50 We have (V V V1) R1 v Inserting the values used above, we have (5OO5O-2OO)`1O,O00(250)` mtv 250 *@000- So, as claimed above, by the use of the instru ment described a station-manager can, by

taking three readings on the instrument by the use of the two plugs and three receptacles provided, determine from the station the presence of a ground, its character and location on the line, and by knowing the resistance of the instrument can determine its ohmic value.

1. In an instrument for the detection of grounds on constant-current arc-light circuits, a fixed coil, a permanent magnet rotatable and pivoted therein, a pointer secured to the axis of the magnet, a resistance in series with the fixed coil, a switchboard containing three sockets, each electrically connected with a separate binding-post, two movable plugs adapted to fit the sockets, one plug electrically connected with one end of the fixed coil and the other electrically connected through the resistance with the other end ofthe fixed coil, as adjustable means for changing the connection between the instrument and the line and ground, substantially as and for the purpose specified.

In an instrument for the detection of grounds on constant-current arc-light circuits, a fixed coil having elliptical cross-section, a permanent magnet rotatable and pivoted therein, a pointer secured to the axis of the magnet, a resistance in series with the fixed coil, a switchboard containing three sockets, each electrically connected with a separate binding-post, two movable plugs adapted to fit the sockets, one plug electrically connected with one end of the iixed coil and the other electrically connected through the resistance with the other end of the xed coil, as adjustable means for changing the connection between the instrument and the line and ground, substantially as and for the purpose specified.

B. In an instrument for the detection of grounds on constant-current arc-light circuits,

a fixed coil havin g,in crosssection dimensions, a width of about eight times its height, a permanent magnet rotatable and pivoted therein, a pointer secured to the axis of the magnet, a resistance in series with the fixed coil,

a switchboard containing three sockets, each electrically connected with a separate binding-post, two movable plugs adapted to fit the sockets, one plug electrically connected with one end of the fixed coil and the other electrically con nected through the resistance with the other end of the fixed coil, as adjustable means for changing the connection between the instrument and the line and ground, substantially as and for the purpose specified.

4. In an instrument for the detection of grounds on constant-currentarc-light circuits, a fixed coil having, in cross-section dimensions, a width of about eight times its height and a length from pole to pole equal to its greatest dimensions a permanent magnet rotatable and pivoted therein, a pointer secured to the axis of the magnet, a resistance in series with the fixed coil, a switchboard containing three sockets, each electrically connected with a separate binding-post, two movable plugs adapted to tit the sockets, one

`plug electrically connected with one end of the fixed coil and the other electrically connected through the resistance with the other end of the fixed coil, as adjustable means for changing the connection between the instrument and the line and ground, substantially as and for the purpose specified.

5. In a ground-detector, a fixed coil, a permanent magnet, a non-inductivelywound resistance in series with the fixed coil, a switchboard containing three sockets, each electrically connected with a separate binding-post, two movable plugs, adapted to fit the sockets, one electrically connected with one end of the fixed coil and the other electrically connected through the resistance with the other end of the fixed coil, said plugs adapted to fit said sockets as adjustable means for varying the method of connection between the instrument and the line and ground, substantially as and for the purpose specified.

6. In a ground-detector, a fixed coil, a permanent magnet pivoted therein and carrying a pointer secured to its axis, said pointer adapted to sweep a scale suitably located with respect thereto, a bent counterpoise also secured to said axis with weights threaded thereon as adjustable gravity control for said pivoted magnet, a switchboard containing three sockets each electrically connected with a separate external binding-post, two movable plugs one connected with one end of' the xed coil, and the other connected through the resistance with the otherend of the lixed coil, said plugs adapted to fit said sockets as adjustable means for connecting the instrument with the line and ground, all contained in an iron casing forming a magnetic shield from external fields, substantially as and for the purpose specified.

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coil, said plugs adapted to fit said sockets as adjustable means for connecting the instrument with the line and ground, and an iron casing adapted to contain all of said mechanisrn, and to support said external bindingpost, as a support and cover and also a magnetic shield to prevent the instrument from being affected by external fields, substantially as and for the purpose specied.

JOHN FRANKLIN STEVENS.

Vitnesses:

J No. SToKEs ADAMS, MAE HOFFMANN.