SU1588615A1 - Apparatus for switching on actuator relay of railway automatic system - Google Patents

Abstract

The invention relates to railway automation, in particular to devices for controlling a relay. The purpose of the invention is to increase reliability. From the outputs of the redundant sources 1-3 pulsed signals to the inputs of blocks 6 and 7 of the output, inverters 4 and 5 receive pulse signals to control the executive relay 29 of the execution unit 8. The input and passage of these signals is controlled in blocks 6 and 7 of isolation with the help of capacitors 9, 14 and 20 and diodes 10, 15, 17, 21 and 22, as well as optocouplers 13 and 19. With periodic synchronous receipt of pulse signals from any two of the three sources 1-3, relay 29 is energized. In case of malfunction of the elements of blocks 6 and 7 of the junction, the false activation of the relay 29 is excluded. 1 sludge.

Description

The invention relates to railway automation, and in particular to devices for controlling a relay of railway automation ..

The purpose of the invention is to increase reliability.

The drawing shows a schematic diagram of a device.

The device contains sources 1.2 and 3 of pulse signals, inverters 4 and 5, isolation blocks 6 and 7, and an executive unit 8. An input connected to the outputs of blocks 6 and 7. Input 1 is connected to one of the inputs of blocks 6 and 7, source 2 through an inverter 5 - to another input of block 7. source 3 through an inverter 4 - to another input of block 6 and the third input of block 7. The inputs of block 6 are formed by the serial connection of the capacitor 9 and diode 10, to which the optocoupler LED 12 is connected via resistor 11. Two of the inputs of block 7 are formed by series-connected con the capacitor 14 and the diode 15, to which the optocoupler LED 18 is connected via an additional resistor 16 and the diode 17 19. The third input of the block 7 is formed by the capacitor 20 and the diode 21 connected in series, to which the optocoupler LED 18 is connected via the resistor 16 and another additional diode 22, phototransistors 23 and 24 optocouplers 13 and 19 are formed respectively outputs of blocks 6 and 7 of the isolation. The Executive unit 8 is made in the form of a rectifier with doubling the voltage across the capacitors 25 and 26 and diodes 27 and 28, and one of the windings of the executive relay 29 is connected in parallel to the capacitor 26, the other winding of which is connected to the power supply 30.

The device operates as follows.

From sources of pulsed signals 1,2 and 3, information is received in the form of a sequence of logical signals 0 and 1 alternating in time. When signals from any two of the three sources of pulsed signals are synchronized, at the inputs of isolation blocks 6 and 7, an inverter is generated using inverters 4 and 5 squared voltage. At the same time, at the outputs of isolation blocks 6 and 7, a pulse voltage of positive polarity appears, which is converted by block 8 to a constant voltage of negative polarity, in this case, an actuated polarized relay 29 is triggered. For example, when signals from sources 1 and 2 are synchronously received at the time of signal arrival logical 1 (logical 1 corresponds to a positive voltage), the capacitor 14 is charged through the diode 15 and the open transistor of the inverter 5. When a signal appears at the outputs of blocks 1 and 2, the logical o 0, a positive voltage (logical 'T') appears at the inverter 5 output, which is fed through a resistor 16 to the anode of the LED 18 of the optocoupler 19, to the cathode of which a negative voltage (relative to the common wire) is supplied from the pre-charged capacitor 14, t. e. when the device elements are in good condition and in the pause between pulses from sources 1 and 2, a voltage twice as high as the voltage of pulse signals coming from sources 1,2 and applied to the LED 18 of the optocoupler 19 and the resistor 16 is connected in series

3. At the time of the discharge of the capacitor 14, the transistor 24 of the optocoupler 19 is opened. Then, the signal 1 again comes from sources 1 and 2 and the capacitor 14 is charged again, at this time the phototransistor 24 of the optocoupler 19 is closed, etc.

When the phototransistors 23 and 24 of the optocouplers 13 and 19 are closed, the capacitor 25 is charged through the diode 27, and at the moment when one of the phototransistors 23 and 24 of the optocouplers 13 and 19 opens, the capacitor 25 is discharged through the diode 28 to the parallel connected capacitor 26 and relay 29. When the optocouplers 13 or 19 of the isolation blocks 6 and 7 are periodically switched over, a sufficient energy is accumulated on the capacitor 26 of block 8 to actuate the polarized actuator relay 29. When pulses of positive polarity arrive at the input of block 8, the relay coil 29 receives a constant negative voltage, i.e. a rectifier with voltage doubling converts the polarity of the voltage supplied to its input. If the rectifier elements are damaged (for example, breakdown of the capacitor 25, diode 28 and open circuit of the diode 27), a positive voltage is applied to the first winding of the relay 29 and the relay switches off reliably, i.e. the receiving unit is protected against false switching of the relay if its elements are damaged. Similarly, if the elements of isolation blocks 6 and 7 are damaged or there are no pulse signals at the outputs of blocks 1,2 and 3 or inverters 4 and 5, the optocouplers 13 and 19 corresponding to the damaged elements do not switch.

Thus, the proposed device is protected from false activation of the actuating relay 29 in case of damage to the elements of the device.

Claims (1)

Claim A device for activating an executive relay of railway automation, containing pulse signal sources, inverters, an executive unit, to the input of which isolation units are connected to the outputs, each of which has a capacitor and a diode connected in series, one of the plates of which and the output of the isolation blocks are formed, one of which through inverters are connected to one of the outputs, and others to other outputs of the pulse signal sources, characterized in that, in order to increase the reliability. ^, isolation blocks equipped with optocouplers, the LED of one of which through a resistor / connected parallel to the diode of one of the isolation blocks, and the other isolation block has additional diodes and a capacitor connected in series with one of the 5 diodes, one of the terminals connected to the other terminal of the first diode of its isolation block, and the other through the second additional diode to one of the terminals the optocoupler LED connected through 10 a third additional diode and another resistor parallel to the first diode, another plate of the additional capacitor forms the third input of this isolation unit, which connected to one of the pulse signal sources, which is connected to the inverter of the first isolation unit, and their outputs are formed by phototransistors of the isolation units.