RU2759638C1 - Maximum current protection device - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: invention relates to electrical engineering. The device contains a reed switch with switching, closing and opening contacts and a current-carrying bus. The switching contact of the reed switch is connected to the positive pole of the DC operational current source, and the first and second intermediate relays with windings are connected to the negative pole. The device also contains the first and second time relays, the first, second and third indicator relays, the opening contact of the second intermediate relay and the circuit of disconnecting the switch of the electrical installation. The control unit with a microprocessor is connected to the positive and negative poles of the DC operating current source. The reed switch control winding is connected to the positive and negative outputs of the control unit.EFFECT: provision of remote monitoring of the serviceability of the device with simultaneous monitoring of the sticking of the reed switch contacts.1 cl, 1 dwg

Description

The invention relates to electrical engineering, namely to relay protection technology, and can be used to protect various electrical installations from short-circuit currents.

Known is a current protection device containing a reactive relay connected to a current transformer, in turn connected to the cut of the current-carrying bus, an executive body whose input is connected to a reactive relay, and the output to a circuit breaker tripping circuit (Andreev V.A., Relay protection and Automation of power supply systems / V.A.Andreev. - Moscow: Higher School, 2008. - S. 205-2013).

The disadvantage of this device is the impossibility of detecting a malfunction, since information about the current in the phases is carried out with the help of bulky current transformers in terms of weight and size parameters, which leads to a failure of the protection operation on the protected electrical installation in case of short circuits before they occur, which in turn leads to the failure of the current protection in case of damage on the protected electrical installation.

Closest to the claimed invention in terms of the technical essence and the achieved result (prototype) is a device for current protection of electrical installations [RU No. 2704792, Н02Н 3/08, publ. 10/31/2019], containing a reed switch with changeover, make and break contacts, installed in the magnetic field of the current-carrying bus of the electrical installation, the first and second intermediate relays with windings, the break contact of the second intermediate relay, the first, second, third, fourth and fifth time relays, logical AND gate, NOT logic gate, OR logic gate, first, second, third, fourth and fifth memory devices, protection unit, circuit breaker tripping circuit, direct current source with a positive pole, to which the reed switch changeover contact is connected, and a negative pole, connected to the first end of the control winding of the first intermediate relay. The opening contact of the reed switch is connected to the first input of the AND logic element, as well as to the input of the NOT logic element, the output of which is connected to the first input of the first memory device, the output of which is connected to the input of the first time relay and to the second input of the AND logic element, the output of which is connected to the first the input of the second memory device, the output of which is connected to the input of the second time relay, to the first input of the OR logic element, and also to the first end of the control winding of the second intermediate relay. The output of the first time relay is connected to the second input of the first storage device. The output of the second time relay is connected to the second input of the second memory and to the first input of the third memory, the output of which is connected to the input of the third time relay, the output of which is connected to the second input of the third memory and to the first input of the fourth memory. The output of the fourth memory device is connected to the third input of the AND logic element and to the input of the fourth time relay, the output of which is connected to the second input of the fourth memory device. The closing contact of the reed switch is connected to the first input of the fifth memory device, the output of which is connected to the input of the fifth time relay, the output of which is connected to the second input of the fifth memory device, to the second input of the OR logic element, the output of which is connected to the input of the protection unit. The output of the protection unit is connected to the second end of the control winding of the first intermediate relay. The opening contact of the second intermediate relay is connected through a contact with a time delay for closing the first intermediate relay in the circuit breaker of the electrical installation. A contact with a time delay for closing the second intermediate relay is connected through a contact for opening the first intermediate relay in the signaling circuit. The start button is connected to the third input of the logical element I. To the positive pole of the direct current source, the start button, the contact with a time delay for closing and the opening contact of the second intermediate relay are connected, and the second end of the control winding of the second intermediate relay is connected to the negative pole of the direct operating current source. (patent RU 2704792, IPC Н02Н 3/08 (2006.01)).

The disadvantages of this device are the lack of remote control of its serviceability and the increased labor intensity of production due to the content in its composition of a significant number of used elements.

The technical problem, the solution of which is provided by the implementation of the invention, is to create a device for overcurrent protection with remote monitoring of health, that is, with self-diagnosis, by automatically supplying a test signal with simultaneous control of the sticking of the reed switch contacts.

The solution to this technical problem is achieved by the fact that in an overcurrent protection device containing a reed switch with switching, closing and opening contacts, a current-carrying bus, a direct operating current source with a positive pole, to which the reed switch switching contact is connected, and a negative pole, the first and second intermediate relay with windings, a circuit breaker for an electrical installation, the first and second time relays, an opening contact of the second intermediate relay, according to the invention, a control unit with a microprocessor installed inside it is introduced, connected to the positive and negative poles of a direct operating current source, a reed switch control winding connected to a positive and the negative outputs of the control unit, the first, second and third indicator relays. The first terminal of the winding of the first time relay is connected to the closing contact of the reed switch, the contact for closing the first time relay is connected to the first terminal of the winding of the first intermediate relay. The opening contact of the second intermediate relay and the first terminal of the winding of the second time relay are connected to the contact for closing the first intermediate relay. The first terminal of the winding of the third indicator relay is connected to the contact for closing the second time relay. The first output of the winding of the second indicating relay is connected to the opening contact of the second intermediate relay, to the closing contact of which the first output of the winding of the coil of the circuit breaker of the electrical installation is connected. The first output of the winding of the first indicator relay is connected to the opening contact of the reed switch. The first output of the winding of the second intermediate relay is connected to the positive output of the control unit. The second terminal of the winding of the first, second and third indicator relays, the first and second intermediate relays, the first and second time relays, as well as the winding of the coil of the trip circuit of the electrical installation switch are connected to the negative pole of the direct operating current source.

The given drawing (Fig. 1) shows a block diagram of an overcurrent protection device.

In addition, the drawing additionally indicates:

- IP - source of constant operating current;

- BU - control unit;

- RU1 - the first indicating relay;

- RU2 - second indicating relay;

- RU3 - third indicating relay;

- РВ1 - the first time relay;

- РВ2 - second time relay;

- PR1 - the first intermediate relay;

- PR2 - the second intermediate relay;

- KO V - coil disconnecting the switch of the electrical installation.

The overcurrent protection device contains a reed switch 1 with a switching contact 2, an opening contact 3 and an opening contact 4, a control winding 5 of a reed switch 1, a current-carrying bus 6, a direct current source 7, a control unit 8, with a microprocessor installed inside it (not shown in the drawing ), the first indicator relay 9, the second indicator relay 10 and the third indicator relay 11, the first time relay 12 and the second time relay 13, the first intermediate relay 14 and the second intermediate relay 15, the trip coil 16 of the electrical installation switch, the opening contact 17 of the second intermediate relay 15 ...

The control unit 8 is connected to the positive and negative poles of the direct operating current source 7. The switching contact 2 of the reed switch is connected to the positive pole of the direct operating current source 7. The control winding 5 of the reed switch 1 is connected to the positive and negative outputs of the control unit 8. To the open contact 4 of the reed switch 1, the first terminal of the winding of the first indicator relay 9 is connected.

The first terminal of the winding of the first time relay 12 is connected to the closing contact 3 of the reed switch 1, the contact for closing the first time relay 12 is connected to the first terminal of the winding of the first intermediate relay 14. The opening contact of the second intermediate relay 15 and the first terminal are connected to the contact for closing the first intermediate relay 14 the winding of the second time relay 13. The first terminal of the winding of the third indicator relay is connected to the contact for closing the second time relay 13. The first terminal of the winding of the second indicator relay 10 is connected to the open contact of the second intermediate relay 15, to the closing contact of which the first terminal of the winding of the circuit coil is connected disconnecting the 16 switch of the electrical installation.

The first winding terminal of the second intermediate relay 15 is connected to the positive output of the control unit 8. The second winding terminal of the first indicator relay 9, the second winding terminal of the second indicator relay 10 and the second winding terminal of the third indicator relay 11, the second winding terminal of the first intermediate relay 14 and the second winding terminal of the second intermediate relay 15, the second terminal of the winding of the first time relay 12 and the second terminal of the winding of the second time relay 13, as well as the second terminal of the winding of the coil of the trip circuit 16 of the electrical installation switch are connected to the negative pole of the direct operating current source 7.

The overcurrent protection device works as follows. In normal operation, at the reed switch 1, the closing contact 3 does not work, since it is configured not to work when the maximum load current of the electrical installation flows in the busbar 6. In this regard, the overcurrent protection does not work, and there is no signal at the output of the first time relay 12.

In the event of a short circuit on the protected electrical installation near the reed switch 1 under the influence of the current flowing in the busbar 6 more than the maximum, the open contact 4 and the open contact 3 are simultaneously triggered, while the open contact 3 gives a signal to the input of the first time relay 12. The first time relay 12, having triggered, counts a time delay equal to 0.02, s and sends a signal to the input of the first intermediate relay 14. The first intermediate relay 14, having triggered, through the opening contact 17 of the second intermediate relay 15 sends a signal through the second indicating relay 10 to the trip coil 16 of the electrical installation switch. When the opening contact 4 of the reed switch 1 is triggered, the first indicating relay 9 is triggered due to loss of power. The first indicator relay 9 and the second indicator relay 10 send a signal about the protection actuation to the operating personnel, and, as a result, the protected electrical installation is turned off. If after that the first indicator relay 9 does not return to its original state - the "On" blinker does not fall out, then this indicates that the switching contact 2 and the closing contact 3 of the reed switch 1 are stuck, and the maintenance personnel must replace this reed switch 1 with a serviceable one.

For the reliable operation of the overcurrent protection device, its operability is continuously monitored by means of a test signal. This control is carried out using the control unit 8. In unit 8, a microprocessor is installed, which, with the help of the program recorded in it, with a predetermined time delay - 90 seconds - supplies a direct operating current to the control winding 5 of the reed switch 1. After that, the NO contact 3 and the NC contact are triggered contact 4 of reed switch 1 - a test signal appears. At the same time, the first indicating relay 9 is triggered, since it loses power, and the second intermediate relay 15, powered by the control unit 8, this relay 15 opens its contact 17, as a result of which the shutdown signal is not sent to the trip coil 16 of the Electrical installation switch. When the closing contact 3 of the reed switch 1 is triggered, the first time relay 12 is started with a time delay of 0.02 seconds, after which the output signal from this time relay 12 goes to the first intermediate relay 14, it works and sends a signal to the second time relay 13, which has time delay equal to 0.03 seconds. The second time relay 13, having triggered, gives a signal to the third indicator relay 11, signaling the operation of the self-diagnosis circuit of the device to the service personnel. If any element of the device is damaged, then at the output of the first intermediate relay 14 there is no test signal, and the third indicating relay 11 does not work.

If at the same time the indicator relay 11 does not return to its original state - the "On" blinker has fallen out, then this indicates a sticking of the switching contact 2 and the closing contact 3 of the reed switch 1. If the first time relay 12 and the first intermediate relay 14 do not turn on, this indicates sticking switching contact 2 and opening contact 4 of the reed switch 1. In both cases, the maintenance personnel, paying attention to the dropped out blinkers of the first indicator relay 9, the second indicator; relay 10 and the third indicator relay 11, replaces the failed reed switch 1 with a serviceable one.

The overcurrent protection device allows remote monitoring of its serviceability by automatically submitting a test signal while simultaneously monitoring the sticking of the reed switch contacts; complies with relay protection issues, such as cybersecurity - complete immunity to cyber attacks, due to the lack of an Internet connection; does not use bulky in terms of weight and size parameters and expensive in cost current transformers with ferromagnetic cores, which together makes it possible to use this device for the implementation of maximum current protection of any electrical installation.

Claims (1)

An overcurrent protection device containing a reed switch with changeover, make and break contacts, a current-carrying bus, a direct operating current source with a positive pole, to which a reed switch changeover contact is connected, and a negative pole, first and second intermediate relays with windings, a trip circuit for an electrical installation switch, the first and second time relays, the opening contact of the second intermediate relay, characterized in that a control unit with a microprocessor installed inside it is inserted into it, connected to the positive and negative poles of a direct operating current source, a reed switch control winding connected to the positive and negative outputs of the control unit , the first, second and third indicating relays, wherein the first winding terminal of the first time relay is connected to the closing contact of the reed switch, the closing contact of the first time relay is connected to the first winding terminal of the first intermediate relay, to the closing contact the first intermediate relay is connected to the opening contact of the second intermediate relay and the first output of the winding of the second time relay, the first output of the winding of the third indicator relay is connected to the contact to close the second time relay, the first output of the winding of the second indicator relay is connected to the opening contact of the second intermediate relay, to the contact on the closure of which is connected to the first output of the winding of the coil of the circuit breaker of the electrical installation switch, the first output of the winding of the first indicator relay is connected to the opening contact of the reed switch, the first output of the winding of the second intermediate relay is connected to the positive output of the control unit, the second output of the winding of the first, second and third indicator relays, the first and the second intermediate relay, the first and second time relays, as well as the coils of the trip circuit of the electrical installation switch are connected to the negative pole of the direct operating current source.

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