RU2755656C1 - Multicontact switching system with three power contact groups and dc link - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to the field of electrical engineering, in particular, to devices for sectioning and redundancy of power lines and is intended for switching, protecting the electrical network from emergency modes of operation and switching and atmospheric overvoltages, electricity metering, monitoring the quality of electricity, monitoring the amount and time of voltage outages in distribution electrical networks, sectioning and redundancy of distribution electrical networks, power lines, including those containing power sources that are not synchronized with each other. The effect is achieved by the fact that a multi-contact switching system with three power contact groups and a direct current insert contains three output switching elements of manual control, three switching elements of remote control, three control units of switching elements of remote control, a unit for receiving and transmitting data, a rectifying and inverting unit, multi-contact switching system control unit, uninterruptible power supply unit, three surge suppressors.

EFFECT: increasing reliability of the multicontact switching system, reducing the undersupply of electricity to consumers, increasing the reliability and efficiency of power supply systems for consumers, including those to which various sources of electricity are connected, including those that are not synchronized with each other.

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Description

The invention relates to the field of electrical engineering, in particular, to devices for sectioning and redundancy of power lines and is intended for switching, protecting the electrical network from emergency modes of operation and switching and atmospheric overvoltages, electricity metering, monitoring the quality of electricity, monitoring the amount and time of voltage outages in distribution electrical networks, sectioning and redundancy of distribution electrical networks, power lines, including those containing power sources that are not synchronized with each other.

The closest in technical essence to the proposed invention is a multi-contact switching system having independent control of three power contact groups having a common connection point, intended for switching, protecting the electrical network, electricity metering, monitoring the quality of electricity, monitoring the amount and time of voltage outages in distribution electrical three-phase current networks, including output switching elements of manual control, switching elements of remote control, control units of switching elements of remote control, a block of remote control of power circuits of a multi-contact switching system, a block of local control of power circuits of a multi-contact switching system, a current control unit, an electricity metering unit with a power quality control function, a unit for monitoring the position of switching elements, a data transmission unit, a voltage monitoring unit (US Pat. RF Entity No. 2732182, IPC H02B 13/00, publ. 09/14/2020, Bul. No. 26).

The disadvantage of the known multicontact switching system is the impossibility of protecting the elements of the multicontact switching system installed and connected to the first, second and third power circuits from switching and atmospheric overvoltages, as well as the absence of an uninterruptible power supply unit, which makes it possible to supply power to the multicontact switching system in the event of a power outage and the complexity of the circuit containing separate units for electricity metering, current and voltage monitoring, monitoring power quality indicators, and others. Also, the disadvantage is that the device cannot be used for sectioning and backing up power lines to which power sources are connected that are not synchronized with each other.

The objective of the proposed invention is to increase the functionality and expand the scope for switching, protecting the electrical network and elements of the multicontact switching system from emergency modes of operation and switching and atmospheric overvoltages, electricity metering, power quality control, monitoring the amount and time of voltage outages in distribution electrical networks with the possibility of independent control of three power contact groups, for the implementation of sectioning and redundancy of three power networks (sections of power transmission lines), including those to which different power sources are connected, including those that are not synchronized with each other, with the provision of uninterruptible power supply to the nodes of the multicontact switching system ...

As a result of using the proposed invention, it becomes possible to carry out the functions of switching, protecting the electrical network and elements of the multicontact switching system from emergency operating modes and switching and atmospheric overvoltages, electricity metering, power quality control, voltage control in distribution electrical networks with the ability to independently control three power contact groups , for the implementation of sectioning and redundancy of three power networks (sections of power lines), including those to which different sources of electricity are connected, including those that are not synchronized with each other, to ensure uninterrupted power supply of the nodes of the multi-contact switching system from the uninterruptible power supply unit when power lines are disconnected due to the independent control of the contact groups of the multicontact switching system and control of the modes of its operation and the modes of the network in which it is installed, the installation and a rectifier and inverter unit that provides isolation between power circuits by inserting a DC current, installing surge suppressors and an uninterruptible power supply. Application of the invention makes it possible to increase the reliability of the multicontact switching system, reduce the undersupply of electricity to consumers, reduce losses of power supply organizations and, thus, improve the reliability and efficiency of power supply systems for consumers, including those to which various sources of electricity are connected, including those that are not synchronized with each other. ...

The above technical result is achieved by the fact that the proposed multicontact switching system with three power contact groups and a direct current insert, including switching elements and a control and protection unit, according to the invention, contains three output switching elements of manual control installed in power circuits and intended for their manual switching at the terminals of the multicontact switching system, three remote control switching elements, which are power contact groups with independent control, installed in the power circuits between the manual control output switching elements and the rectifying and inverting unit, and intended for switching power circuits using remote means control units, three control units for remote control switching elements connected to the corresponding remote control switching elements and transmitting coma to them On and off switches, data receiving and transmitting unit connected to the control unit of the multi-contact switching system and the uninterruptible power supply unit, rectifying and inverting unit installed in the power circuit between the remote control switching elements and designed to separate power circuits through a DC link, control unit multi-contact switching system, connected to each of the manual and remote control switching elements and controlling their position, connected to each of the control units of the remote control switching elements and transmitting the on and off commands of the corresponding remote control switching element, connected to the power circuits of the multi-contact system and monitoring current and voltage in these power circuits, accounting for the consumption of electricity in these circuits and monitoring the quality of electricity in them, carrying out archives data communication, connected to the data transmission unit and transmitting to it data on the operation of the multicontact switching system and receiving commands from it for remote control of the remote control switching elements, connected to the uninterruptible power supply unit to receive power in case of voltage outage in all power circuits, uninterruptible power supply unit connected to power networks up to the multi-contact switching system, connected to the control unit of the multi-contact switching system and the unit for receiving and transmitting data to provide their power supply, three surge suppressors connected to the power networks at the outputs of the multi-contact switching system and providing overvoltage protection.

The essence of the invention is illustrated by drawings, where Fig. 1 shows a block diagram of a multicontact switching system with three power contact groups and a direct current insert, FIG. 2 shows a block diagram of the rectifying and inverting unit.

The multi-contact switching system with three power contact groups and a direct current insert contains the first output switching element for manual control (VYKERU 1), the first switching element for remote control (KEDU 2), the second switching element for remote control (KEDU 3), the third switching element for remote control ( KEDU 4), the second output switching element of manual control (VYKERU 5), the third output switching element of manual control (VYKERU 6), the control unit of the first switching element of remote control (BUKEDU 7), the control unit of the second switching element of remote control (BUKEDU 8), control unit for the third remote control switching element (BECEDU 9), control unit for the multi-contact switching system (BUMKS 10), data reception and transmission unit (BPD 11), uninterruptible power supply unit (BPU 12), the first surge suppressor (SPN 13), the second limiter transfer voltage (arrester 14), the third overvoltage arrester (arrester 15), rectifying and inverting unit (BVIN 16).

The rectifier and inverter unit (BWIN 16) contains the first active rectifier, which also operates in the modes of an active inverter with a control unit (AV-AINSBU 17), a second active rectifier, also operating in the modes of an active inverter (AV-AINSBU 18), a third active rectifier, operating also in the modes of an active inverter (AV-AINSBU 19).

VyKERU 1 is installed in the first power circuit. KEDU 2 is installed in the first power circuit between VKERU 1 and BVIN 16. VYKERU 5 is installed in the second power circuit, KEDU 3 is installed in the second power circuit between VYKERU 5 and BVIN 16. VYKERU 6 is installed in the third power circuit. KEDU 4 is installed in the power circuit between VYKERU 6 and BVIN 16. BWIN 16 is installed in the power circuit between KEDU 2, KEDU 3, KEDU 4. BUKEDU 7 is connected to KEDU 2. BUKEDU 8 is connected to KEDU 3. BUKEDU 9 is connected to KEDU 4. BPD 11 is connected with BUMKS 10 and with BBP 12. BUMKS 10 is connected with KEDU 2, with KEDU 3, with KEDU 4 with VyKERU 1, with VyKERU 5, with VYKERU 6, connected with BUKEDU 7, with BUKEDU 8, with BUKEDU 0, connected to the power circuits of the multi-contact system between all elements of remote and manual control, connected to the BPD 11, connected to the BPD 12. The BPU 11 is connected to the BUMKS 10 and to the BPD 12. The surge arrester 13 is connected to the first power circuit to VYKERU 1 at the first terminal of the multi-contact switching systems. Surge arrester 14 is connected to the second power circuit to VYKERU 5 at the second output of the multicontact switching system. Surge arrester 15 is connected to the third power circuit to VYKERU 6 at the third output of the multicontact switching system.

In the structure of BVIN 16, active rectifiers, which also operate in the modes of an active inverter AV-AINSBU 17, AV-AINSBU 18, AV-AINSBU 19, are connected so that their common point of connection together with the conductors forms a DC link between the AC circuits.

The device works as follows.

The voltage is supplied to the power circuit of the multi-contact switching system using manual output switching elements (VYKERU 1, VYKERU 5, VYKERU 6) installed in the power circuit depending on which side of the power network the power source is located on. In this case, power is supplied to the control unit for the multi-contact switching system (BUMKS 10). Depending on the built-in operation algorithm, BUMKS 10 generates control signals transmitted to the control units by the first, second, third and fourth remote control switching elements (BUKEDU 7, BUKEDU 8, BUKEDU 9) to turn on or off the first remote control switching element (CEDU 2 ), the second remote control switching element (KEDU 3), the third remote control switching element (KEDU 4), the fourth remote control switching element (KEDU 5), respectively.

When the first output switching element of manual control (VYKERU1) is switched on, the voltage will be applied to the first power network behind the multi-contact switching system (if the power source is not located in the first power network). When you turn on the second output switching element of manual control (VYKERU 5), the voltage will be applied to the second power network behind the multi-contact switching system (if the power source is not located in the second power network). When the third output switching element of manual control is turned on (VYKERU 6), the voltage will be applied to the third power network behind the multi-contact switching system (if the power source is not located in the third power network). With local control of a multicontact switching system, the command to turn on / off the first, second and third power circuits is given by means of BUMKS 10. In this case, the commands to turn off the corresponding power circuits are sent from BUMKS10 to BUKEDU 7, BUKEDU 8, BUKEDU 9, which, in turn, switch off KEDU 2, KEDU 3 and KEDU 4 by stopping the power supply to their electromagnets. Also, disabling / enabling KEDU2, KEDU 3 and KEDU 4 of the multicontact switching system can be carried out using commands processed by means of BUMKS 10, sent to BUKEDU 7, BUKEDU 8 and BUKEDU 9 from the data receiving and transmitting unit (BPD 11). BPD 11 receives commands to turn on or off the corresponding KEDU multi-contact switching system using a coded signal transmitted over the power network using existing technologies for transmitting signals on it 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 systems using a signal received through a communication channel, for example, JPS, JPRS, Glonass, radio or other channel. When an overload current or short-circuit current occurs in the power circuit behind the multicontact switching system to KEDU 2, KEDU 3 or KEDU 4, the control unit of the multi-contact switching system (BUMKS 10) will send a signal to a certain BUKEDU 7, BUKEDU 8, BUKEDU 9, respectively, to disconnect KEDU 2 , KEDU 3 or KEDU 4. In this case, if in the logic of operation of BUKEDU 7, BUKEDU 8 and BUKEDU 9 there is an algorithm for automatic reclosing (AR) of KEDU 2 (KEDU 3, KEDU 4), then after a time delay the corresponding AR will be carried out KEDU 2, APV KEDU 3 or APV KEDU 4 and, if it is unsuccessful, that is, in the first, in the second or, respectively, in the third power network behind the multicontact switching system to KEDU 2, KEDU 3 or KEDU 4, the overload current or current will reappear short circuit, BUMKS 10 will re-send a signal to BUKEDU 7, BUKEDU 8 or BUKEDU 9 to disconnect KEDU 2, KEDU 3 or KEDU 4. This will block the remote switching on the multicontact switching system until damage is eliminated in the power circuit behind KEDU 2, KEDU 3 or KEDU 4. Also, a message about the damage will be sent to KEDU 2, KEDU 3 or KEDU4. 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 10), which, when the position of the switching elements KEDU 2, KEDU 3, KEDU 4, VYKERU 1, VYKERU4, VYKERU 5 is changed, transmits the corresponding data to the data transmission unit (BPD eleven). The control unit for the multi-contact switching system (BUMKS 10) measures the electricity transmitted through the first, second and third power circuits of the multi-contact switching system, and also monitors the quality indicators of electrical energy at the point of their connection. Data on electricity consumption and 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. BUMKS 10 monitors the voltage in the power circuits of the multi-contact switching system between VYKEDU 1 and KEDU 2, between KEDU 3 and VYKERU 5, between KEDU 4 and VYKERU 6 and transmits information about the presence or absence of voltage on the BPD 11 and to BUKEDU 7, BUKEDU 8, BUKEDU 9 The uninterruptible power supply unit ББП 12 supplies power to BUMKS 10 and BPD 11 both from power networks and from an independent power source contained in it, for example, a battery, a capacitor or other source. BVIN 16 consists of three switched on counter-active rectifiers with control units for them. In this case, each active rectifier operates either in the rectifier mode or in the inverter mode, depending on the direction of the power flow flowing through the multi-contact switching system. The presence of three switched on counter-active rectifiers in BVIN 16 allows decoupling of power circuits before and after the multi-contact switching system, since a direct current insert is formed between these power networks. Due to this, it is possible to operate a multi-contact switching system in power lines, to which electricity sources are connected from different sides of the multi-contact switching system, including those that are not synchronized with each other, for example, a renewable source of electricity and a centralized network, or renewable sources of electricity of various types, gas piston, diesel power plants, etc., or sources of the same type, but not synchronized with each other.

When a switching or atmospheric overvoltage occurs in the first power circuit, the first surge arrester of the arrester 13 ensures that the overvoltage is reduced to a level that is safe for the protected power line and equipment of the multi-contact switching system. When a switching or atmospheric overvoltage occurs in the second power circuit, the second surge arrester of the arrester 14 ensures that the overvoltage is reduced to a level that is safe for the protected power line and equipment of the multicontact switching system. When a switching or atmospheric overvoltage occurs in the third power circuit, the third surge arrester of the arrester 15 ensures that the overvoltage is reduced to a level that is safe for the protected power line and equipment of the multicontact switching system.

The proposed device allows for switching and protection of power lines and equipment of a multicontact switching system from emergency modes of operation and switching and atmospheric overvoltages, electricity metering, power quality control, voltage control in three power networks simultaneously. When the voltage disappears in one of the power networks and appears in the other, the device allows the automatic switching on of the reserve by switching on the corresponding KEDU. Also, the device allows you to section the electrical network, including those containing power sources that are not synchronized with each other, by dividing it into sections by disconnecting the corresponding power contact groups in case of damage in power networks connected to a multi-contact switching system. 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. At the same time, the reliability and functionality of the device is higher than that of the prototype due to the provision of uninterruptible power supply to the nodes of the multi-contact switching system by including an uninterruptible power supply unit in its circuit, as well as simplifying the device circuit due to the performance of most functions by one control unit of the multi-contact switching system, by installing limiters overvoltage.

Claims (1)

Multi-contact switching system with three power contact groups and a DC link, including switching elements and a control and protection unit, characterized in that it contains three output switching elements of manual control installed in the power circuits and intended for their manual switching at the outputs of the multi-contact switching systems, three remote control switching elements, which are power contact groups with independent control, installed in the power circuits between the output switching elements of manual control and the rectifying and inverting unit, and intended for switching power circuits using remote control means, three control units for switching elements remote control connected to the corresponding switching elements of the remote control and transmitting to them the commands for switching on and off, the unit for receiving and transmitting data are connected with a multi-contact switching system control unit and an uninterruptible power supply unit, a rectifying and inverting unit installed in the power circuit between the remote control switching elements and designed to separate power circuits through a DC link, a multi-contact switching system control unit connected to each of the manual switching elements and remote control and monitoring their position, connected to each of the control units by the remote control switching elements and transmitting the commands for switching on and off the corresponding remote control switching element, connected to the power circuits of the multi-contact system and monitoring the current and voltage in these power circuits, accounting for consumption electricity in these circuits and monitoring the quality of electricity in them, performing data archiving, connected to the data transmission unit and performing transmission to it of data on the operation of a multicontact switching system and receiving commands from it for remote control of switching elements of remote control, connected to an uninterruptible power supply unit to receive power in case of voltage outage in all power circuits, an uninterruptible power supply unit connected to power networks to a multicontact switching system, connected to the control unit of the multicontact switching system and the unit for receiving and transmitting data to ensure their power supply, three surge suppressors connected to power networks at the outputs of the multicontact switching system and providing overvoltage protection.

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