DE252651C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- M 252651 CLASS 201 GROUP

EUDORE FRANCHIMONT and VITAL CESAR in BRUSSELS

Patented in the German Empire on January 27, 1910.

The invention relates to a monitoring device for switches and signal interlockings with a monitoring magnet carrying two independent windings. The essence of the invention is to make ineffective that in the orderly condition of the plant through the windings continuously oppositely directed streams converge and Electromagnetic '■ th for locking the adjusting lever in resistance changes the other hand, in the one of the circuits, the associated winding the electromagnet to Locking the control lever makes effective.

The device is shown on the drawing in Fig. Ι to 7 in different phases Darge-i represents.

i, 2, 3 is a point electric motor with double Direction of rotation.

ι is the armature, 2 is the one and 3 the other field winding. The anchor 1 is on the one hand connected to earth and on the other hand connected to 2 and 3 at ο. 4 and 5 are current-closing devices, one of which is moved at the beginning and the other at the end of the rotational movement of the motor, as will be indicated later. 6 and 7 are current connection devices which are directly controlled by the switch blades. 8 is a resistor that switches on alternately in one or the other control circuit of the point machine. 9, 10 are current closers that are moved by the adjusting lever or the like. 11 is an electromagnet that only attracts its armature when it is excited by that part of the motor current that returns to the signal box after it has passed through the windings of motor 2, 3, which takes place when motor 1, 2, 3 has started to rotate and the power circuit device 4 has moved. Ec is a compensated electromagnet with the windings 12, 13, each of which is switched on in one of the two control circuits for the switch blade position. 14, 15 are current closing devices that are controlled at the same time and by the same control lever as the current closing devices 9, 10, but which then automatically return to their basic position as soon as the motor current no longer flows through the electromagnet 11. 16 is a circuit breaker which works under the same conditions as the circuit breakers 14, 15. It is a compensated electromagnet, the windings 17, 18 of which are each switched into one of the control circuits of an insulated rail RJ . The winding 18 is connected to earth at 19, while the winding 17 is connected to the insulated rail RJ , which in turn is connected to earth at 21 via a resistor 20. 22 is an automatic rheostat connected to a self-induction coil. It is connected to the circuit of the winding 18 and has the purpose of the natural and slow resistance fluctuations of the

Winding circuit of 17 to compensate for fluctuations resulting from changes in the insulation conditions of the rail RJ. The self-induction coil 23 is connected to the circuit of the winding 18 and is intended to prevent a sudden grounding of the winding from being compensated for by the play of the rheostat. 24 is a resistor which "is intended to" compensate for the effects of the resistor 8 in the signal box, specifically in the winding 13, which is connected to the circuit of the winding 12. f is a source of electricity, 25 to 36 are lines, which connect the different parts of the arrangement together.

The mode of action results from. below:

Fig. Ι shows the different parts of the device in the basis:

The circuits are run by a relatively low voltage current. flow through, which is used to monitor the switch blades and the insulating rail. This current comes from the electricity source P, passes through the conductor 31 and then divides into two branches. One part goes to earth via 6, 27, 4, 25, 32, 15, 24, 13 (Ec). The other. Part goes through 7, 28, 8, 5, 26, 35, 10, 14 (Ec) 12 also to earth. In addition, a part goes to earth and takes its way over 5, 3, 0, I. This current has no influence on the action of the motor, as it has to flow through resistor 8. As long as the monitoring current is distributed in the two circuits to the same extent, the windings 12, 13 of the compensated electromagnet Ec are traversed by currents whose effects cancel each other out. Under these conditions, the armature of this electromagnet is not attracted, which allows the setting of a signal that covers the switch in question. If these conditions were not met, the armature would be tightened and block the control lever for the signal in question.

The weak current used to monitor the insulated rail comes from P, flows into conductor 36 and then divides into two branches. One circuit goes through winding 17 (Er), rail RJ and resistor 20 to earth. The second circuit runs through the winding 22 of the automatic rheostat, the self-induction coil 23 and the winding 18 of the compensated electromagnet Er.

If there is no carriage axis on the insulating rail and all other conditions (insulation, good connection of the lines, etc.) are met, the effects of the currents flowing through the windings 17, 18 of the compensated electromagnet Er cancel each other out. The armature of this compensated electromagnet is then not attracted, so that the control lever for the switch in question can be turned over. If the insulation conditions of the insulated rail change slowly due to moisture or for any other reason, i.e. not suddenly, as would happen with a carriage axle driving onto the insulating rail, the compensation by the rheostat 22 takes place at any time and remains ineffective for the control lever . . ·

When a carriage axis is passed and the insulated rail is suddenly grounded, the self-induction coil 23 comes into action to counteract this sudden change in the currents in question, and in this way prevents the automatic rheostat from operating effectively. Under these circumstances, the armature of the electromagnet Er is attracted because the current effects in the windings 17 and 18 do not cancel each other out, and it sets the control lever for the switch in question.

On the control circuit of the insulating rail, which can be used either as an electrical hold-open, latte or to automatically block signals or as an auxiliary pedal and then can be connected to a mechanical contact pedal, will not be discussed further will.

Fig. 2 shows that the circuits during the adjustment of the control lever and the associated switch (9, 10) are interrupted.

Fig. 3 shows that the control movement has ended and a high-voltage current goes through P, 15, 9> 33, 26, 5, 3, ο, ι, with the result that the motor starts to run. As a result of the high resistance in FIG. 8, the shunt 5, 8, 28, 7, 6, 27, 4, 25, 34, 10, 14, 11 has no influence on the mode of operation of the electromagnet 11.

When the engine starts, the shift lever 4 is switched over, as can be seen from FIG. 5, and the current can flow through winding 2 to over 25, 34, 10, 14, 11 and return the earth after the signal box. This scheme is shown in FIG. At the Flowing through the winding 11, the motor current causes the temporary determination of the Current closers 14, 15 and the breaker 16 emerge. This position is maintained so long until the point motor has reached the end of its movement.

Fig. 6 shows that the current closer 5 then interrupts the motor current, what because no more current flows through the electromagnet 11, the triggering of the current short-circuit

apparatus 14, 15 and the breaker 16 for Which then automatically return to their basic position, thus the motor current interrupt and close the control stream (Fig. 7).

Claims (2)

Patent Claims: i. Monitoring device for turnout and signal interlockings with a monitoring magnet carrying two independent windings, characterized in that in the proper state of the system through the windings continuously oppositely directed currents run and the electromagnet for locking make the control lever ineffective, in the case of ■ changes in resistance, however, in the one of the circuits the associated winding makes the electromagnet for locking the control lever effective. 2. Monitoring device according to claim i, characterized in that by isolation or other slow Changes caused inequalities in the resistance of the two circuits be compensated by automatic resistance regulators, whose effect in the event of sudden large changes in resistance is prevented by an upstream self-induction coil. 1 sheet of drawings.