RU186567U1 - The control device for the electromagnets of the air gates of the passive heat removal system - Google Patents

Abstract

The utility model relates to techniques for relay protection and automation and can be used in control systems for electromagnets of air gates of the system of passive heat removal of nuclear power plants. The device contains power buses of positive and negative potentials, a remote switch and a first, second and third relay, an isolation transformer, the input terminals of which are connected to the input terminals of a remote switch configured to perform the functions of an input circuit breaker of the mains supply, a first indicator, first and second terminals which are connected, respectively, with the first and second output terminals of the equalizing transformer and with the first and second terminals of the first relay, the second, third, fourth, fifth and sixth indicators, the first and second resistors, the power supply, the first and second output terminals of which are respectively the busbars of the positive and negative potentials, switch, capacitor, measuring voltmeter, fuse, millivoltmeter, diode and damping diode. The device achieves the required technical result, which consists in increasing the operational reliability. 1 ill.

Description

The utility model relates to techniques for relay protection and automation and can be used in control systems for electromagnets of air gates of the system of passive heat removal of nuclear power plants.

Structurally, the device runs on a board in a single housing.

A device is known [RU 2495778, C2, B61L 21/04, 10/20/2013], containing a microprocessor control unit for monitoring the status of outdoor devices connected to a two-channel device for processing information and generating control actions through two identical serial ports, and to each two-channel device processing of information and generation of control actions through two additional serial interfaces, a second microprocessor control unit for monitoring and monitoring the status of outdoor devices is connected, outputs the first and second control and monitoring units of the floor devices are connected according to the logical “OR” circuit through an additional relay circuit and through the relay circuit, the linkages are connected to the same floor devices.

The disadvantage of this device is the relatively narrow functionality, because, although the known device performs logical signal processing, it cannot be used as a device for controlling electromagnets of air gates of a passive heat removal system.

Another analogue of the proposed device is [RU 285679, C2, H03K 19/003, 06/20/2013], containing the power bus “-” and “+”, n of the same type of redundant relay cells, consisting of four relays and four isolation diodes, the first one the second, third switched “+” power buses, the fourth “+” switched power bus, four remote switches with two normally closed contacts, five current sensors, a controller, the second windings in each cell are connected respectively to the first, second, third, fourth switched power bus "+", the first, second, third, fourth current sensors are installed respectively on the first, second, third, fourth switched power buses "+", which are connected through the first normally closed contact, respectively, of the first, second, third, fourth remote switch with a common power bus "+", and the fifth current sensor is installed on the power bus "-", the outputs of the current sensors are connected to the information inputs of the controller, in which the signal inputs through the second normally closed contacts respectively th, second, third, fourth remote switch connected to a common signal input of the controller.

The disadvantage of this device is the relatively narrow functionality, because although it performs logical signal processing, it does not allow generating control signals for the electromagnetic air gates of the passive heat removal system.

The closest in technical essence to the proposed is a device for controlling electromagnets of air gates of a passive heat removal system [RU 150648, U1, G21D 3/00, G21D 3/14, B61L 21/04, 02/20/2015], containing power buses of positive and negative potentials , a remote switch, a first, second and third relay, an isolation transformer, the input terminals of which are connected to the input terminals of a remote switch configured to perform the functions of an input circuit breaker of the mains supply, the first indicator, the first and second terminals of which are connected, respectively, with the first and second output terminals of the equalizing transformer and with the first and second terminals of the first relay, the second, third, fourth, fifth and sixth indicators, the first and second resistors, power supply, the first and the second output terminals of which are, respectively, the power buses of positive and negative potentials, a switch, a capacitor, a measuring voltmeter, a fuse, a millivoltmeter, and a diode, moreover, the second relay is a sensor relay Temperature indicator, the third relay is an insulation control relay on the electromagnets of the air gates of the passive heat removal system, the first and second terminals of the fifth indicator are connected respectively to the first output terminal of the isolation transformer and to the first output terminal of the third relay, the first and second glues of the sixth indicator are connected, respectively, with the first output terminal of the isolation transformer and with the second output terminal of the third relay, the first and second input terminals of the third relay are connected, respectively, the first and second output terminals of the isolation transformer, the first terminal of the second relay is connected to the first terminal of the isolation transformer and to the direct terminal of the normally open contact of the second relay, the second terminal of which is connected through the first resistor to the second terminal of the second relay and to the second terminal of the isolation transformer, the first terminal of the third indicator connected to the first output terminal of the isolation transformer, and the second terminal through normally open contacts of the relay opening the air The control cabinet is connected to the second output terminal of the isolation transformer, the first terminal of the fourth indicator is connected to the first output terminal of the isolation transformer, and the second terminal is connected to the third output terminal of the third relay through the normally open contacts of the air gate open relay of the control system, the first and second terminals of the second resistor connected, respectively, to the first and second terminals of the second indicator, the first terminal of the capacitor is connected to the first terminals of the second resistor, a measuring voltmeter, a fuse and a positive power supply potential bus, the second terminal of the second resistor is connected via a switch to the second terminals of the capacitor, a measuring voltmeter, a negative potential power supply bus and the third input terminal of the third relay, the second fuse terminal is connected through normally connected contacts in series first relay, normally closed contacts of the shutter opening relay of the control system, normally closed contacts the logic cabinet air shutter opening relay and a millivoltmeter are connected to the fourth input terminal of the third relay, the fourth and fifth output terminals of which are connected, respectively, to the first and second terminals of the normally open fuse contacts and normally open contacts of the remote switch of the mains, and the input and output terminals of the diode connected, respectively, with the third and fourth input terminals of the third relay.

The disadvantage of the closest technical solution is its relatively low noise immunity, caused by the formation of jamming pulses on the power buses of positive and negative potentials arising due to spurious inductances in the conductors connected, practically, with all the circuits of the device. This reduces the operational reliability of the device.

The task to which the utility model is directed is to create a device with increased operational reliability.

The required technical result is to increase operational reliability by reducing the possibility of occurrence and influence on the operation of the device of interference pulses.

The problem is solved, and the required technical result is achieved by the fact that, in a device containing power supply buses of positive and negative potentials, a remote switch, a first, second and third relay, an isolation transformer, the input terminals of which are connected to the input terminals of the remote switch, configured to performing the functions of the input circuit breaker of the mains, the first indicator, the first and second terminals of which are connected, respectively, with the first and second outputs one terminals of the equalizing transformer and with the first and second terminals of the first relay, the second, third, fourth, fifth and sixth indicators, the first and second resistors, the power source, the first and second output terminals of which are, respectively, the power buses of positive and negative potentials, switch , a capacitor, a measuring voltmeter, a fuse, a millivoltmeter, and a diode, moreover, the second relay is a temperature sensor relay, the third relay is an insulation control relay on electromagnets of air shutters passive heat removal system, the first and second terminals of the fifth indicator are connected, respectively, with the first output terminal of the isolation transformer and with the first output terminal of the third relay, the first and second glues of the sixth indicator are connected, respectively, with the first output terminal of the isolation transformer and with the second output terminal of the third relay, the first and second input terminals of the third relay are connected, respectively, with the first and second output terminals of the isolation transformer, the first terminal of the second relay connected to the first terminal of the isolation transformer and to the first terminal of the normally open contact of the second relay, the second terminal of which through the first resistor is connected to the second terminal of the second relay and to the second terminal of the isolation transformer, the first terminal of the third indicator is connected to the first output terminal of the isolation transformer, the second terminal through normally open contacts of the relay for opening the air gates of the logic cabinet are connected to the second output terminal of the isolation transformer, the first the fourth indicator terminal is connected to the first output terminal of the isolation transformer, and the second terminal is connected via the normally open contacts of the control gate open relay to the third output terminal of the third relay, the first and second terminals of the second resistor are connected, respectively, to the first and second terminals of the second indicator, the first terminal of the capacitor is connected to the first terminals of the second resistor, measuring voltmeter, fuse and power supply bus of the positive potential of the source power supply, the second terminal of the second resistor through the switch is connected to the second terminals of the capacitor, measuring voltmeter, with the power bus of the negative potential of the power source and the third input terminal of the third relay, the second terminal of the fuse through the normally connected contacts of the first relay in series, normally closed contacts of the system shutter opening relay control, normally closed contacts of the relay for opening the air gates of the logic cabinet and a millivoltmeter are connected to the fourth input to the third relay, the fourth and fifth output terminals of which are connected, respectively, to the first and second terminals of the normally open fuse contacts and the normally open contacts of the remote switch of the mains, and the input and output terminals of the diode are connected, respectively, with the third and fourth input terminals of the third relay , according to a utility model, a damping diode is introduced, the input and output terminals of which are connected, respectively, to the power buses of negative and positive potentials.

The drawing shows an electrical block diagram of a device for controlling electromagnets of air gates of a passive heat removal system.

The device for controlling electromagnets of the air gates of the passive heat removal system contains buses 1 for supplying positive and negative potentials, a remote switch 2 and a first 3, a second 4 and a third 5 relays.

In addition, the control device of the electromagnet air gates of the passive heat removal system contains an isolation transformer 6, the input terminals of which are connected to the input terminals of the remote switch 2, configured to perform the functions of the input circuit breaker of the mains, the first indicator 7, the first and second terminals of which are connected, respectively, with the first and second output terminals of the equalizing transformer bis the first and second terminals of the first relay 3, second 8, third 9, even erty 10, fifth 11 and sixth 12 indicators, the first 13 and second 14 resistors, the power source 15, the first and second output terminals are MDM, respectively, the tires 1 positive and negative supply potentials.

The device for controlling electromagnets of air gates of the passive heat removal system also includes a switch 16, a capacitor 17, a measuring voltmeter 18, a fuse 19, a millivoltmeter 20.

In the device for controlling the electromagnets of the air gates of the passive heat removal system, the second relay 4 is a temperature sensor relay, the third relay 5 is an insulation control relay for the electromagnets of the air gates of the passive heat system, the first and second terminals of the fifth indicator 11 are connected, respectively, to the first output terminal of the decoupling transformer bis the first output terminal of the third relay 5, the first and second glues of the sixth indicator 12 are connected, respectively, with the first output terminal decoupling transformer 6 and with the second output terminal of the third relay 5, the first and second input terminals of the third relay 5 are connected, respectively, with the first and second output terminals of the isolation transformer 6, the first terminal of the second relay 4 is connected to the first terminal of the isolation transformer bis straight terminal of the normally open contact 21 of the second relay 4, the second terminal of which is connected through the first resistor 13 to the second terminal of the second relay 4 and to the second terminal of the isolation transformer 6, the first terminal of the third indicator 9 is connected it is connected to the first output terminal of the isolation transformer 6, and the second terminal is connected through the normally open contacts 22 of the air lock gate open relay of the logic cabinet (not shown in the drawing) to the second output terminal of the isolation transformer 6, the first terminal of the fourth indicator 10 is connected to the first output terminal of the isolation transformer 6, and the second terminal is connected through the normally open contacts 23 of the relay for opening the air locks of the control system (not shown in the drawing) to the third output terminal relay 5, the first and second terminals of the second resistor 14 are connected, respectively, to the first and second terminals of the second indicator 8, the first terminal of the capacitor 17 is connected to the first terminals of the second resistor 14, the measuring voltmeter 18, the fuse 19 and the bus 1 of the power supply of the positive potential of the source 15 power supply, the second terminal of the second resistor 14 through the switch 16 is connected to the second terminals of the capacitor 17, the measuring voltmeter 18, with the power bus 1 of the negative potential of the power source 15 and the third input terminal t its relay 5, the second terminal of the fuse 19 through the normally connected contacts 24 of the first relay 3, the normally closed contacts 25 of the shutter opening relay of the control system, the normally closed contacts 26 of the logic valve openings of the logic cabinet and the millivoltmeter 20 is connected to the fourth input terminal of the third relay 5 , the fourth and fifth output terminals of which are connected, respectively, with the first and second terminals of the normally open contacts 27 of the fuse and the normally open contacts 28 of the distance mains switch.

In addition, the device for controlling electromagnets of air gates of the passive heat removal system contains a diode 29, the input and output terminals of which are connected, respectively, to the third and fourth input terminals of the third relay 5, as well as the damping diode 30, the input and output terminals of which are connected, respectively, with power buses of negative and positive and potentials.

The device controls the electromagnets of the air gates of the passive heat removal system as follows.

When you turn on the input AC voltage of 220 V using a circuit breaker 1, it is through an isolation transformer 5, which provides, in particular, protection of the device from interference and possible power surges, is fed to indicator 6, indicating the presence of input AC voltage, and to the input of the source 15, which serves to convert the input voltage of 220 V 50 Hz to the output voltage of direct current 48 V and is a power source for electromagnets of the air gates of the passive heat removal and recharging system olekulyarnogo energy storage.

The input voltage of the power supply unit 15 is controlled by the remote switch 2. When the remote switch 2 is turned off when the built-in protections are triggered, the normally open contact 28 is turned on and is included in the generalized signal generation circuit of the electromagnet control device for the air gates of the passive heat removal system.

The capacitor 17 serves as a power source for the electromagnets for 30 s after blackout. The first relay 3 is a delay time relay with a shutter speed of 30 seconds when the input voltage is turned off, which eliminates false triggering due to possible short-term shutdowns. Therefore, the normally open contact 24 enters the closed state only after a time delay, which ensures the supply of a positive potential from the power source 15 to the input terminals of the third relay 5, the negative potential from which is fed to the input of the third relay 5 constantly. The positive and negative potentials constantly recharge the large capacitor 17 of the order of 6-8 farads. Therefore, when the power is turned off, a sufficiently long supply is provided for the gates of the passive heat removal system from this capacitor.

Fuse 19 serves to protect the 48 V circuits from short circuits. A normally open contact 27 of the fuse signals a fuse trip and when it is fused, a generalized fault signal is generated.

The third relay 5 of the insulation control is used to measure the insulation resistance of the coils of electromagnets and its supply lines. Its fourth and fifth output terminals are terminals of the output normally open contact and serve to signal a decrease in the insulation resistance of the electromagnet coils and power lines in the circuit for generating a generalized fault signal.

The second relay 4, with its normally open contacts 21, controls the on and off of the first resistor 13, which performs the function of a heating resistance to eliminate excessive moisture in the device.

The second resistor 14 and switch 16 provide manual forced discharge of the capacitor 17 when servicing the device. Indication of the discharge of the capacitor 17 is carried out by the second indicator 8.

Millivoltmeter 20 with an ohmic scale is used to control the resistance of the shutter electromagnet coils.

The measuring voltmeter 18 provides control of the charge level of the capacitor 17.

The first 7, third 9, fourth 10, fifth 11 and sixth 12 indicators serve to visually view the status of the device.

An important role in the device is played by a diode 29, which protects the device, in particular, the power supply 15, from high currents resulting from the emf itself. in electromagnets of air gates when the voltage is turned off, as well as a damping diode 30, which removes interference pulses arising from spurious inductors in the conductors, in the normal state it is closed, but if due to spurious inductances at the output of source 15 a spurious (interference) reverse pulse is generated polarity, the current flows through the damping diode 30, and not through the power source 15, which leads to increased noise immunity and operational reliability of the device and ensures that the required Wow technical result.

Claims (1)

A device for controlling electromagnets of air gates of a passive heat removal system, comprising positive and negative potential power supply buses, a remote switch, a first, second, and third relay, an isolation transformer, the input terminals of which are connected to the input terminals of a remote switch that is designed to perform the functions of an input automatic power switch network, the first indicator, the first and second terminals of which are connected, respectively, with the first and second output and terminals of the equalizing transformer and with the first and second terminals of the first relay, the second, third, fourth, fifth and sixth indicators, the first and second resistors, the power supply, the first and second output terminals of which are, respectively, the power buses of positive and negative potentials, switch , a capacitor, a measuring voltmeter, a fuse, a millivoltmeter, and a diode, moreover, the second relay is a temperature sensor relay, the third relay is an insulation control relay on electromagnets of air gates passive heat removal systems, the first and second terminals of the fifth indicator are connected, respectively, with the first output terminal of the isolation transformer and with the first output terminal of the third relay, the first and second glues of the sixth indicator are connected, respectively, with the first output terminal of the isolation transformer and with the second output terminal the third relay, the first and second input terminals of the third relay are connected, respectively, with the first and second output terminals of the isolation transformer, the first terminal of the second relay is connected inena with the first terminal of the isolation transformer and with the direct terminal of the normally open contact of the second relay, the second terminal of which is connected through the first resistor to the second terminal of the second relay and the second terminal of the isolation transformer, the first terminal of the third indicator is connected to the first output terminal of the isolation transformer, and the second terminal through normally open contacts of the relay for opening the air gates of the logic cabinet connected to the second output terminal of the isolation transformer, the first terminal the fourth indicator is connected to the first output terminal of the isolation transformer, and the second terminal is connected through the normally open contacts of the air gate open relay of the control system to the third output terminal of the third relay, the first and second terminals of the second resistor are connected, respectively, to the first and second terminals of the second indicator, the first the capacitor terminal is connected to the first terminals of the second resistor, measuring voltmeter, fuse and power supply bus of the positive potential of the power source second terminal of the second resistor is connected via a switch to the second terminals of the capacitor, measuring voltmeter, to the negative power supply bus and the third input terminal of the third relay, the second fuse terminal through the normally connected contacts of the first relay in series, the normally closed contacts of the system shutter open relay control, normally closed contacts of the relay of opening the air gates of the logic cabinet and a millivoltmeter are connected to the fourth input terminal of the third relay, the fourth and fifth output terminals of which are connected, respectively, to the first and second terminals of the normally open fuse contacts and the normally open contacts of the remote switch of the mains, and the input and output terminals of the diode are connected, respectively, with the third and fourth input terminals of the third relay characterized in that a damping diode is introduced, the input and output terminals of which are connected, respectively, to the power buses of negative and positive potentials.

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