RU52800U1 - DEVICE FOR TURNING ON THE EXECUTIVE RELAY OF RAILWAY AUTOMATION - Google Patents

Abstract

The utility model relates to the field of control of railroad switches and signals, and can be used in various electrical centralization systems. The objective of the utility model is to increase the reliability of the device by reducing the number of stages of the multiplier with increasing voltage supplied to the inputs of the switching elements. The technical result is achieved by the fact that in the device for switching on the executive relay of railway automation, containing the first and second switching blocks, one of the inputs of which are connected to the outputs of the pulse signal generation block, the other input of the first switching block is connected to the positive pole of the power source, and the other input of the second switching block to the negative pole of another power source, and the negative pole of one power source is connected to the positive pole of another source and the power supply, and the inputs of the switching blocks are connected to the input of the voltage multiplier, to the output of which the executive relay is connected, an own tee contact of the executive relay and a resistor are additionally introduced, while the common relay contact is connected to the output of the voltage multiplier, the rear contact is connected to the relay winding, and the front the contact is connected to one terminal of the resistor, the second terminal of which is connected to the relay winding.

Description

The utility model relates to the field of control of railroad switches and signals, and can be used in various electrical centralization systems.

A device is known for activating an executive relay of railway automation, comprising a pulse signal generating unit, power sources, a switching device connecting a storage capacitor to executive relays (SU, No. 401557, B 61 L 23/16, 1973).

In this device, there is a cyclic charge of the storage capacitor and its subsequent discharge to the coil of the executive relay, which is turned on when the switching device is pulsed. However, the known device has low reliability, which makes it impossible to use it in critical circuits of railway automation and telemechanics.

The closest in technical essence to the claimed is a device for activating an executive relay of railway automation, containing the first and second switching units, one of the inputs of which are connected to the outputs of the pulse signal generation unit, the other input of the first switching element is connected to the positive pole of the power source, and the other input of the second switching unit to the negative pole of another power source, and the negative pole of one power source is connected to the positive a different power supply, and the outputs of the switching units are connected to the input of the voltage multiplier, the output of which is connected to an executive relay (SU, No. 1017570, B 61 L

23/16, 1981). However, the disadvantage of this device is the large number of stages of the multiplier, made on diodes and capacitors.

The objective of the utility model is to increase the reliability of the device by reducing the number of stages of the multiplier with increasing voltage supplied to the inputs of the switching elements.

The technical result is achieved by the fact that in the device for switching on the executive relay of railway automation, containing the first and second switching blocks, one of the inputs of which are connected to the outputs of the pulse signal generation block, the other input of the first switching block is connected to the positive pole of the power source, and the other input of the second switching block to the negative pole of another power source, and the negative pole of one power source is connected to the positive pole of another source and the power supply, and the inputs of the switching blocks are connected to the input of the voltage multiplier, to the output of which the executive relay is connected, an own tee contact of the executive relay and a resistor are additionally introduced, while the common relay contact is connected to the output of the voltage multiplier, the rear contact is connected to the relay winding, and the front the contact is connected to one terminal of the resistor, the second terminal of which is connected to the relay winding.

The own contact of the executive relay is introduced in order to initially create a power circuit passing directly from the output of the voltage multiplier unit through the rear contact to the relay coil, and after the relay is energized, the power circuit will pass from the output of the voltage multiplier unit through the front contact of the relay and a resistor. The resistor is necessary in order to reduce the voltage on the relay to a value less than the release voltage in the case when, due to damage to the elements of the device, the voltage of the power source goes to the output of the voltage multiplier. It should be noted that the quantity

the voltage of the power source must be less than the voltage of the relay.

The drawing shows a functional diagram of a device consisting of a unit for generating pulse signals 1, the outputs of which are connected to the inputs of the first 2 and second 3 switching blocks. Another input of the first switching unit 2 is connected to the positive pole of the power source 4, and the other input of the second switching unit 3 is connected to the negative pole of the other power source 5.

The inputs of the first and second switching blocks 2 and 3 are connected to the input of the voltage multiplier 6, one output of which is connected to the common contact of the tee 7 of the executive relay 8, the front contact of the tee 7 is connected to one output of the resistor 9, the other output of which is connected to the rear contact of the tee 7 and to one terminal of the winding of the executive relay 8, the other output of the voltage multiplier 6 is connected to the second terminal of the winding of the executive relay 8.

The voltage multiplier 6 contains two stages. The first stage of the voltage multiplication unit 6 contains diodes 10, 11 and capacitors 12, 13. The cathode of the diode 10 is connected to the anode of the diode 11 and the input of the voltage multiplier 6. The cathode of the diode 11 is connected to one of the plates of the capacitor 12, the second plate of which is connected to the top plate of the capacitor 13, another lining of which is connected to the anode of the diode 10. The second stage is constructed in a similar way and contains diodes 14, 15 and capacitors 16, 17. The device operates as follows.

In the initial state, the Executive relay 8 is off. To turn it on, the pulse signal forming unit 1 generates voltage pulses that are fed to the inputs of the switching blocks 2 and 3, operating in antiphase. The second switching unit 3, connected to the negative pole of the power source 5, delivers negative pulses to the input of the voltage multiplier 6, and the first switching unit 2, connected to the positive pole

a power source 4, provides positive pulses to the input of a voltage multiplier 6. As a result of this, when a positive pulse arrives, the storage capacitor 12 is charged, and when the next negative pulse arrives, the storage capacitor 13 is charged, each is charged almost to the voltage of the power source. When the next positive pulse arrives, the capacitor 17 of the second stage of the voltage multiplier 6 is charged, almost to the double voltage of the power source, since the voltage at the input of block 6 and the capacitor 13 are turned on according to. When the next negative pulse arrives, the capacitor 16 is also charged almost to a double voltage of the power source, because at this time, the voltages at the input of block 6 and capacitor 12 are also included according to. Thus, the voltage received at the output of block 6 exceeds the original 4 times. Given the loss of energy in the switching blocks and in the voltage multiplier, the voltage at the output of block 6 is 24 V in steady state. Initially, while relay 8 is off, it receives power through the closed rear contact of the tee 7. When the voltage at the output of the voltage multiplier 6 reaches the operating voltage, the relay 8 will pull its armature and the front contact of the tee 7 will be closed, connecting the resistor 9 in series with the relay 8 winding. and lowering the voltage on the relay coil 8.

If the elements of the voltage multiplier 6 are damaged, the voltage of the power supply (8 V) may appear at its output. If at the time of the occurrence of such damage, relay 8 was turned on, then the voltage of the power source is supplied to the resistor 9 and the relay winding 8 connected in series. The value of the resistance of resistor 9 is selected so that if the voltage multiplier 6 on the relay 8 winding is damaged than the release voltage of relay 8, and when the device is working properly, the voltage on relay 8 should

be significantly higher than the release voltage of the relay. Thus, the introduction of the own contact of the Executive relay and the resistor can increase the voltage of the power sources and reduce the number of stages of the voltage multiplier.

The use of the utility model is assumed in control devices for executive objects of electronic, computer centralized systems of arrows and signals, as well as in telecontrol and telealarm systems. Relays for switching signals and translating arrows can serve as control devices. The use of a device for activating executive relays of railway automation will improve the operational reliability of facility management systems while ensuring train safety.

The proposed device is constructed in such a way that, in case of any damage to its elements, the executive relays are switched off and a dangerous failure is excluded, i.e. false commands to turn on railway automation devices are prevented.

Claims (1)

A device for activating an executive relay of railway automation and telemechanics systems, comprising first and second switching units, one input of which is connected to the outputs of the pulse signal generating unit, another input of the first switching unit is connected to the positive pole of the power source, and another input of the second switching unit to the negative the pole of another power source, and the negative pole of one power source is connected to the positive pole of another power source, and the outputs are mutating blocks are connected to the input of the voltage multiplier, the output of which is connected to an executive relay, characterized in that its own tee contact and a resistor are introduced into the switching circuit of the executive relay, and the common relay contact is connected to the output of the voltage multiplier, the rear contact is connected to the relay winding, and the front contact is connected to one terminal of the resistor, the second terminal of which is connected to the relay winding.