RU2745155C1 - Multi-contact switching system with independent control of two power contact groups with redundant power circuits - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: invention relates to the field of electrical engineering, in particular to devices for sectioning power lines, and is intended for switching, protecting the electrical network, electricity metering, monitoring the quality of electricity, monitoring the amount and time of voltage outages in distribution networks of three-phase current, automation of electrical networks. Technical results are achieved due to the fact that the multi-contact switching system, which has independent control of two power contact groups with redundant power circuits, consists of an input switching element for manual control, the first switching element for remote control, the second switching element for remote control, the first output switching element for manual control, the second output switching element of manual control, a control unit of the first switching element of remote control, a control unit of the second switching element of remote control, a control unit of multi-contact switching system, a unit of receiving and transmitting data, an uninterruptible power supply unit, the first changeover switching element of manual control, the second changeover switching element manual control, the first and second circuit breakers.EFFECT: expanding the functionality and scope of its use as well as increasing the reliability and efficiency of consumer power supply systems.1 cl, 1 dwg

Description

The invention relates to the field of electrical engineering, in particular, to devices for sectioning power lines and is intended for switching, protecting the electrical network, metering electricity, monitoring the quality of electricity, monitoring the amount and time of voltage outages in distribution networks of three-phase current.

The closest in technical essence to the proposed invention is a sectioning point for switching and protecting power lines, which includes a high-voltage module and a low-voltage control and protection unit fixed on one support, located in separate cases and connected by a cable, the high-voltage module contains on the cover and side wall high-voltage bushings for connection to power lines, current transformers and a vacuum circuit breaker, and the low-voltage control and protection unit contains controls for a vacuum switch, relay or microprocessor protection and automation devices and a storage battery (RF patent No. 52276, class Н02В 11/00, publ. 10.03.2006, Bulletin No. 7).

The disadvantage of the known device is its limited scope and, accordingly, the impossibility of its use for switching, protection of the electrical network, electricity metering, power quality control, monitoring the amount and time of voltage cut-off in three-phase distribution networks, the impossibility of independent control of two power contact groups for implementation sectioning of two sections of the power transmission line and the impossibility of redundancy of power circuits to prevent unreasonable interruptions in the power supply to consumers when servicing the device.

The objective of the proposed invention is to increase the functionality and scope of its use through the use for switching, protection of the electrical network, electricity metering, power quality control, monitoring the amount and time of voltage cut-off in three-phase distribution networks with the possibility of independent control of two power contact groups for sectioning two sections of the power transmission line and the possibility of redundancy of power circuits to prevent unreasonable interruptions in the power supply to consumers when servicing the device.

As a result of using the proposed invention, it becomes possible to carry out the functions of switching, protection of the electrical network, electricity metering, power quality control, voltage control in three-phase distribution networks with the possibility of independent control of two power contact groups for sectioning two sections of a power transmission line due to independent control of contact groups a multicontact switching system and control of its operating modes and modes of the network in which it is installed. It also allows to reduce the undersupply of electricity to consumers, reduce losses of energy supplying organizations and, thus, increase the reliability and efficiency of consumer power supply systems. Redundancy of power circuits allows you to prevent unjustified interruptions in the power supply to consumers when servicing the device.

The above technical result is achieved by the fact that the proposed multi-contact switching system having independent control of two power contact groups with redundancy of power circuits, including switching elements and a control and protection unit, according to the invention, contains an input manual switching element installed in the power circuit and intended for its manual switching at the input of a multi-contact switching system, the first remote control switching element installed in the power circuit after the manual control input switching element and intended for switching the first power circuit using remote control means, the second remote control switching element installed in the power circuit after the input switching element of manual control and intended for switching the second power circuit using remote controls, the first output to manual switching element connected to the power circuit after the first remote control switching element and intended for manual switching of the first power circuit at the first terminal of the multi-contact switching system, the second manual switching output switching element connected to the power circuit after the second remote control switching element and intended for manual switching of the second power circuit at the second output of the multi-contact switching system, the first changeover switching element of manual control installed in the first power circuit in front of the first switching element of remote control and switching to the first power circuit, or to the first backup power circuit, the second changeover switching element of manual control control, installed in the second power circuit in front of the second switching element of the remote control and switching to the second power circuit, or to the second backup power circuit, the first circuit breaker installed in the first backup power circuit and designed to protect it from overloads and short circuits, the second circuit breaker installed in the second backup power circuit and designed to protect it from overloads and short circuits, the control unit first remote control switching element, which is connected to the first remote control switching element and transmits to it the on and off commands, is also connected to the control unit of the multi-contact switching system, the control unit to the second remote control switching element, which is connected to the second remote control switching element and transmits to on and off commands, is also connected to the control unit of the multi-contact switching system, the unit for receiving and transmitting data, which is connected to the control unit of the multi-contact switching system and an uninterruptible power supply unit, a multi-contact switching system control unit, which is connected to each of the remote control switching elements and controls their position, is connected to each of the remote control switching elements control units and transmits commands to them to turn on and off the corresponding remote control switching element, is connected with power circuits of a multi-contact system between all switching elements of remote and manual control and monitors the current and voltage in these power circuits, monitors the consumption of electricity in these circuits and controls the quality of electricity in them, is connected to the data transmission unit and transfers data about the work to it multi-contact switching system and receives commands from it to control the switching elements of remote control, connected to the uninterruptible power supply unit to receive power when disconnected, e.g. voltage in all power circuits, archives the operating modes of the device, ensures the implementation of device automation algorithms, an uninterruptible power supply unit, which is connected to the control unit of the multi-contact switching system and the unit for receiving and transmitting data to ensure their power supply.

The essence of the invention is illustrated by a drawing, which shows a block diagram of a multi-contact switching system having independent control of two power contact groups with redundant power circuits.

A multi-contact switching system with independent control of two power contact groups with redundancy of power circuits contains an input switching element of manual control (VKERU 1), a first switching element for remote control (KEDU 2), a second switching element for remote control (KEDU 3), a first output switching element manual control unit (VYKERU 4), the second output switching element of manual control (VYKERU 5), the control unit for the first switching element of remote control (BUKEDU 6), the control unit for the second remote control switching element (BUKEDU 7), the control unit for the multi-contact switching system (BUMKS 8 ), unit for receiving and transmitting data (BPD 9), uninterruptible power supply unit (BPU 10); cross-over switching element of manual control PKERU11; cross-over switching element of manual control PKERU12; automatic circuit breaker BA13; automatic circuit breaker BA14.

VKERU 1 is installed in the power circuit. PKERU11 is installed in the first power circuit after VKERU1 and before KEDU2. PKERU12 is installed in the second power circuit after VKERU1 and before KEDU3. KEDU 2 is installed in the first power circuit after PKERU11. KEDU 3 is installed in the second power circuit after PKERU12. VyKERU 4 is installed in the first power circuit after KEDU 2. VYKERU 5 is installed in the second power circuit after KEDU 3. BUKEDU 6 is connected to KEDU 2. BUKEDU 7 is connected to KEDU 3. BPD 9 is connected to BUMKS 8 and to BBP 9. BUMKS 8 is connected with KEDU 2, with KEDU 3, with VKERU 1, with VYKERU 4, with VYKERU 5, connected with BUKEDU 6, with BUKEDU 7, PKERU11, PKERU12, VA13, VA14, connected to the power circuits of the multicontact system between VKERU1 and PKERU11, PKERU12, between PKERU11 and KEDU 2, between PKERU12 and KEDU 3, between KEDU 2 and VYKERU 4 and between KEDU 3 and VYKERU 5, connected to BPD 9, connected to BPP 10. BPP 10 is connected to BUMKS 8 and to BPD 9.

The device works as follows.

Voltage can be supplied from any of the device outputs to the power circuit, the first power circuit, or the second power circuit, depending on the location of the power source. In this case, power is supplied to the BBP10 and through it to the control unit of the multi-contact switching system (BUMKS 8), as a result of which they automatically send a command to the control units of the first and second remote control switching elements (BUKEDU 6 and BUKEDU 7) to turn on the first remote control switching element (KEDU 2) and the second remote control switching element (KEDU 3), respectively. KEDU 2 and KEDU 3 turn on and close the corresponding power circuits in which they are installed. When the first output switching element of manual control is turned on (VYKERU 4), if PKERU 11 is in the position where it closes the first power circuit with its contacts, the first power circuit of the device will be closed. When the second output switching element of manual control is turned on (VYKERU 5), if PKERU12 is in the position when it closes the second power circuit with its contacts, the second power circuit of the device will be closed. When VKERU1 is turned on, the power circuit of the device will be closed. Manual disconnection of the power circuits of the multi-contact switching system is carried out by opening VKERU1, VYKERU4, or VYKERU5, respectively. With local control of a multicontact switching system, the command to disconnect the first power circuit can also be given using the BUMKS 8. In this case, the commands to disconnect the corresponding power circuits are sent from BUMKS 8 to BUKEDU 6 and BUKEDU 7, which, in turn, turn off KEDU 2 and KEDU 3 by stopping the power supply to their electromagnets. Also, the switching off of the multicontact switching system can be carried out using the commands sent to the BUKEDU 6 and BUKEDU 7 from the unit for receiving and transmitting data (BPD 9), processed using the BUMKS 8. Using this unit, you can remotely switch on the multicontact switching system. BPD 9 receives commands to turn on or off the multi-contact switching system using a coded signal transmitted over the power network using existing signal transmission technologies or using a coded sequence for turning on and off the voltage in it, or receives commands to turn on or off the multi-contact switching system with using a signal received through a communication channel, for example, JPS, JPRS, Glonass, radio or other channel.

BUMKS8 monitors the current and voltage in the power circuits of the device, monitors the electricity in the power circuits, controls the quality of electricity, controls the amount and time of voltage disconnection in the power circuits of the device and in external power networks. Data on current, voltage, electricity consumption, voltage outages, and the quality of electrical energy are transmitted to the data transmission unit and through it to the dispatcher of the company servicing the equipment of the multi-contact switching system. If an overload current or short-circuit current occurs in the power network behind the multi-contact switching system, or in the power circuit of the device, the BUMKS 8 will send a signal to the BUKEDU 6 or to the BUKEDU 7, respectively, to turn off the KEDU 2 or KEDU 3, depending on which power the circuit is fixed by an overload current, or short circuit. In this case, if the logic of the device's operation includes an algorithm for automatic reclosing (AR) of KEDU 2 (KEDU 3), then after the time delay, the AR will be carried out KEDU 2 or ARC KEDU 3 and, if it is unsuccessful, that is, in the first or accordingly, in the second power network behind the multi-contact switching system, or inside it after KEDU 2 or after KEDU 3, the overload current or short-circuit current will reappear, then BUMKS 8 will re-send a signal to BUKEDU 6 or BUKEDU 7 to disconnect KEDU 2 or KEDU 3. In this case, the possibility of remote switching on of the multicontact switching system will be blocked until the damage in the power circuit behind KEDU 2 or KEDU 3 is eliminated. Also, a message about the damage in the corresponding power circuit or network will be sent. If the automatic reclosure is successful, the multi-contact switching system will continue to operate normally.

The position of the switching elements of the multi-contact switching system is monitored using the multi-contact switching system control unit (BUMKS 8), which, when the position of the switching elements KEDU 2, KEDU 3, VKERU 1, VIKERU 4, VIKERU 5, PKERU11, PKERU12, VA13, VA14 is changed into the data transmission unit (BPD 9).

If it is necessary to service the first power circuit of the device, for example, if it is necessary to replace KEDU2, PKERU11 is moved to the position in which the first power circuit is opened and the first backup power circuit of the device is closed, in which VA13 is installed. When VA13 is on, the first backup power circuit will be closed and, when VYKERU4 is turned off, KEDU2 can be replaced, there will be no voltage at KEDU2. In this case, consumers will be powered through the first backup power circuit, which will prevent an unreasonable interruption in their power supply when servicing the first power circuit of the device. In this case, VA13 will perform the functions of protecting the first backup power circuit from overloads and short circuits. Similarly, if it is necessary to service the second power circuit of the device, for example, if it is necessary to replace KEDU3, PKERU12 is transferred to the position in which the first power circuit opens and the first backup power circuit of the device is closed, in which VA14 is installed. When VA14 is on, the second backup power circuit will be closed and, when VYKERU5 is turned off, KEDU3 can be replaced, there will be no voltage at KEDU3. In this case, the consumers will be powered through the second backup power circuit, which will prevent an unreasonable interruption in their power supply when servicing the second power circuit of the device. In this case, VA14 will perform the functions of protecting the first backup power circuit from overloads and short circuits.

The proposed device allows to carry out switching and protection of power lines, electricity metering, power quality control, voltage control simultaneously in two power networks. Its application prevents the development of an emergency and allows to reduce the undersupply of electricity to consumers, to reduce losses of energy supplying organizations and, thus, to increase the reliability and efficiency of consumer power supply systems. Due to the redundancy of power circuits, it prevents unjustified interruptions in the power supply to consumers when servicing the switching elements of the device.

Claims (1)

Multi-contact switching system with independent control of two power contact groups with redundant power circuits, including switching elements and a control and protection unit, characterized in that it contains an input manual switching element installed in the power circuit and intended for its manual switching at the input of a multi-contact of the switching system, the first remote control switching element installed in the power circuit after the manual input switching element and intended for switching the first power circuit using remote control means, the second remote control switching element installed in the power circuit after the manual manual input switching element and intended for switching the second power circuit using remote controls, the first output switching element of manual control connected to the power circuit n after the first remote control switching element and intended for manual switching of the first power circuit at the first terminal of the multi-contact switching system, the second manual switching output switching element connected to the power circuit after the second remote control switching element and intended for manual switching of the second power circuit at the second multi-contact terminal of the switching system, the first manual changeover switching element installed in the first power circuit in front of the first remote control switching element and switching to the first power circuit or to the first backup power circuit, the second manual changeover switching element installed in the second power circuit before the second switching a remote control element and switching over to the second power circuit or to the second backup power circuit, the first circuit breaker, installed installed in the first backup power circuit and designed to protect it from overloads and short circuits, the second circuit breaker installed in the second backup power circuit and designed to protect it from overloads and short circuits, the control unit by the first switching element of remote control, which is connected to the first remote control switching element and transmits to it the on and off commands, is also connected to the control unit of the multi-contact switching system, the control unit of the second remote control switching element, which is connected to the second remote control switching element and transmits the on and off commands to it, is also connected to control unit for the multi-contact switching system, the unit for receiving and transmitting data, which is connected to the control unit for the multi-contact switching system and the uninterruptible power supply unit, the control unit for the multi-contact switching system ionic system, which is connected to each of the remote control switching elements and controls their position, is connected to each of the control units of the remote control switching elements and transmits commands to them to turn on and off the corresponding remote control switching element, is connected to the power circuits of the multi-contact system between all switching elements of remote and manual control and monitors the current and voltage in these power circuits, monitors the consumption of electricity in these circuits and controls the quality of electricity in them, is connected to the data transmission unit and transmits data to it about the operation of the multi-contact switching system and receives from it commands to control the switching elements of remote control, connected to the uninterruptible power supply unit to receive power when the voltage is disconnected in all power circuits, archives the operating modes of the device device, provides the implementation of algorithms for the automation of the device, an uninterruptible power supply unit, which is connected to the control unit of the multi-contact switching system and the unit for receiving and transmitting data to ensure their power supply.

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