SU1034091A1 - Relay switching device - Google Patents

Description

The invention relates to automation and can be used to create relay circuits with high reliability in various automatic devices.

A relay-contact device is known, which contains the main and backup relays, the windings of which are connected in parallel, and the contacts on the bridge circuit C1.

A disadvantage of the known device is that when it is switched. x there is a switching of the contacts of both the main and backup relays, which leads to its premature wear and decrease in the reliability of the device as a whole. A relay contact device is known that contains main and backup relays, into which, in order to increase reliability, blocking elements and relays are introduced that work by disconnecting the redundant relays to: prevent or repair E2J. The disadvantage of this device is that it possesses insufficient scheduling, since it does not allow to determine the moment of failure of the reserved backups and to perform automatic connection of the reserve. The purpose of the invention is to increase the reliability of the device. This goal is achieved by the fact that the relay-contact device containing the main and backup two winding relays with one switch; each contact; two pulse selectors are entered in duration by a current sensor, an inverter and two circuits, and the fixed contacts of the main contacts are. the backup double-winding relay are pairwise combined, the moving contact of the switching contact of the main double-winding relay is connected to the signal input of the device, the moving contact of the switching contact of the backup motor A smart winding relay is connected to the OUTPUT of the device and to the input of the current sensor, whose 9THRODUCT is connected to one of the inputs of one of the And circuits directly and to one of the inputs of another And through the inverter circuit connected to the off winding of the main two-winding relay directly and through one of the pulse collectors in duration to the winding ON18 of the backup two-winding relay, the output of the other circuit I is connected to the winding of the main two-winding full-time relay nepos backhoes and through other -selector pulse duration - with a winding turn off the backup dvuhobmo-. exact bzele

The drawing shows a structural diagram of the proposed relay-contact device.

The device contains the main relay 1 and the backup relay 2. The movable contact 3 of the main relay 1 is connected to the signal input 4 of the device. The opening contact 5 of the main relay 1 is connected to the closing contact b of the backup relay 2, and the closing contact 7 of the main relay 1 is connected to the opening contact 8 of the backup relay 2. The moving contact 9 of the backup relay 2 is connected to the output of the device 10 and to the sensor input.11 of the current, the output of which is connected to the first input of the first circuit And 12 directly, and to the first input of the second circuit And 13 through an inverter 14. The second input of the first circuit And 12 is connected to the input 5 of the device and the second input of the second circuit And .13 - with input 16 turn on the device. The output of the first circuit And 12 is connected to the switching off winding of the main relay 1 And through the first pulse selector 17 of duration, consisting of the integrating RC-chain 18 and Schmitt trigger 19, to the switching winding of the backup relay 2. The output of the second circuit 13 is connected to the winding switching on: the main relay 1 and through the second selector 20 pulses in duration, made similar to the selector 17, to the off winding of the backup relay 2. The device operates as follows. The turn-on signal is fed to the input of the second circuit AND 13. The output potential of the inverter 14 arrives at the other input of this circuit. The device passes to its output 10, where it is sensed by the current sensor 11. An opto-switch can be used as a current sensor 11, for example, a 249LP1 microcircuit. With the appearance of voltage at the output of current sensor 11, the voltage at the output of inverter 14 disappears, the voltage at output of circuit 13 also disappears with it. The time constant of integrating RC. Circuit 18, which is part of selector 17 duration, is chosen so that the voltage rise time at its output to a value equal to the trigger threshold 19 (Shitta is longer than the time required for switching the main relay 1. Thus, the selector 17 passes only pulses to the output of Acheni / what takes place in case of: failure of the main relay 1. Similarly

The device also turns off: the signal to the circuit through circuit AND 12 acts on the switching off winding of the main relay 1 until the contacts 3 and 5 are open and the voltage at the output of current sensor 11 arrives at the second input of circuit 12. The selector 20 pulses work in the same way as the selector 17 and, when the main relay 1 is normally triggered, a voltage pulse from the circuit output I 12 to the backup relay 2 winding does not pass. Thus, during normal operation of the main relay 1, the pulse duration at the circuit outputs12 and 13 are not sufficient to enable them to pass through the selectors 17 and 20 to the windings of the backup relay 2. In the event that, when a corresponding signal arrives, the main relay 1 does not switch, the signal goes through one of the selectors 17 or 20 to the backup winding CQ relay 2, which produces the required switching circuit 4T-10.

The proposed device has a higher reliability compared with the known similar devices. ;; this is due to the fact that before the main relay fails, the backup relay does not switch, and therefore its contacts are not worn out. If the main relay fails in the on position, the signal circuit will be switched using a backup relay, and it will automatically start up without the operator. In the known relay-contact device, the windings and the corresponding contacts of the main and backup relays are connected in pairs in parallel, i.e. There is a simultaneous switching of both the main and backup relays. In this case, the average uptime of the device will be 1 ,, where TQ is the average uptime of the relay, while for the proposed device the average uptime will be 2To. The failure rate of the logical part of the 1-pin device relay can be neglected here, since when it is performed on integrated circuits, its reliability is 2–3 times higher than the reliability of electromagnetic relays.

Claims (1)

(54] RELAY-CONTACT DEVICE, containing the main and backup Two-winding <$ any relay with one switching contact each, distinguishing with the fact that, in order to increase its reliability in operation, two pulse selectors are introduced into the device in duration, a current sensor, the inverter and two circuits And, moreover, the fixed contacts of the switching contacts of the main and backup two-winding relays are pairwise combined, the moving contact of the switching contact of the main two-winding relay is connected to the signal input of the device, the moving contact t of the switching contact of the backup two-winding relay is connected to the output of the device and to the input of the current sensor, the output of which is connected to one of the inputs of one of the circuits AND directly and to one of the inputs of the other circuit AND through an inverter, the other input of one circuit AND is connected to the turn-off input of the device, another input of another circuit And is connected to the input of the device, the output of one circuit And is connected to the turn-off winding of the main double-winding relay directly and through one of the pulse selectors in duration to the turn-on winding two winding backup relay, the other output of the AND circuit is connected to the primary winding two winding switching relays directly and through another winding of the pulse selector po.dlitelnostis two winding off backup relay.