RU2728768C1 - Multicontact switching system having independent control of two power contact groups - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to electrical engineering, in particular to power transmission sectioning devices, and is intended for switching, protection of electric network. System allows switching and protection of power transmission lines, accounting of electric power, control of electric energy quality, control of voltage by independent control of two power contact groups and includes input manual switching element, vacuum switching elements of remote control, output switching elements of manual control, switching elements control units, units of remote and local control of power circuits of the system, current control units, data transmission unit, switching elements position monitoring unit and voltage control unit.

EFFECT: reduction of losses at power supply to consumers, improvement of reliability and efficiency of power supply systems for consumers.

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, electricity metering, 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 vacuum circuit breaker controls, relay or microprocessor protection and automation devices and a storage battery (RF patent for utility model No. 52276, class Н02В 11 / 00, publ. 10.03.2006, Bulletin No. 7).

The disadvantage of the known sectioning point for switching and protecting power lines is its limited scope and, accordingly, the impossibility of its use for switching, protecting the electrical network, electricity metering, power quality control, monitoring the amount and time of voltage outages in three-phase distribution networks, the impossibility of independent control of two power contact groups for sectioning two sections of the power transmission line.

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 disconnection in three-phase distribution networks with the possibility of independent control of two power contact groups for sectioning two sections of the power line.

The technical result of the invention is to provide the ability to perform the functions of switching, protection of the electrical network, electricity metering, power quality control, voltage control in three-phase distribution networks with the ability to independently control two power contact groups for sectioning two sections of the power transmission line. This is achieved due to the independent control of the contact groups of the multi-contact switching system and control of the modes of its operation and the modes of the network in which it is installed. It also 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.

The above technical result is achieved by the fact that the proposed multicontact switching system, which has independent control of two power contact groups, including a switching element 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 vacuum switching element of remote control installed in the power circuit after the input switching element of manual control and intended for switching the first power circuit using remote control means, the second vacuum switching element of remote control installed in the power circuit after the input switching element of manual control and intended for switching the second power circuit using remote control means, the first output switching a manual control element connected to the power circuit after the first vacuum switching element of remote control and intended for manual switching of the first power circuit at the first output of the multi-contact switching system, the second output manual switching element connected to the power circuit after the second vacuum switching element of remote control and intended for manual switching of the second power circuit at the second terminal of the multi-contact switching system, the control unit for the first vacuum switching element of the remote control connected to the first vacuum switching element of the remote control and transmitting to it the on and off commands, the control unit for the second vacuum switching element of the remote control, connected with the second vacuum switching element of remote control and transmitting to it the ON and OFF commands, the remote control unit control of power circuits of a multi-contact switching system, connected to the power circuit between the input switching element of manual control and vacuum switching elements of remote control, also connected to control units of vacuum switching elements of remote control and transmitting commands received via the power network or through communication channels to control units the first and second vacuum switching element of remote control, the local control unit of the first power circuit of the multi-contact switching system connected to the first power circuit and to the control unit of the first vacuum switching element of the remote control and transmitting manual control commands to the control unit of the first vacuum switching element of the remote control, the unit local control of the second power circuit of the multi-contact switching system, connected to the second power circuit and to the control unit of the second vacuum switch remote control unit and transmitting manual control commands to the control unit of the second vacuum switching element of remote control, a current control unit connected to the first power circuit of the multi-contact switching system between the first vacuum switching element of remote control and the first output switching element of manual control, also connected to the unit control of the first vacuum switching element of remote control and transmitting shutdown commands to the control unit of the first vacuum switching element of remote control when the current in the first power circuit exceeds a predetermined current value, taken as overload current or short-circuit current, and also connected to the data transmission unit for transmission current values in the first power circuit on request, a current monitoring unit connected to the second power circuit of the multi-contact switching system between the second vacuum switching system the remote control element and the second output switching element of manual control, also connected to the control unit of the second vacuum switching element of remote control and transmitting the shutdown commands to the control unit of the second vacuum switching element of remote control when the current in the second power circuit exceeds the set value of the current taken as the current overload or short-circuit current, and also connected to the data transmission unit for transmitting current values in the second power circuit upon request, a data transmission unit that transmits information about the operation of the multi-contact switching system to the dispatcher of the company servicing the electrical network in which the multi-contact switching system is installed, a unit for monitoring the position of the switching elements, connected to the data transmission unit and switching elements installed in the multi-contact switching system, monitoring the position of the lead-in manual switching element, the first vacuum switching element for remote control, the second vacuum switching element for remote control, the first output switching element for manual control and the second output switching element for manual control, transmitting data about their position to the data transmission unit, the first electricity metering unit with control function quality of electrical energy, connected to the first power circuit between the first vacuum switching element of remote control and the first output switching element of manual control, also connected to the data transmission unit, which records the electricity consumption and the power quality control functions in the first power circuit and transmits data to the transmission unit data, the second electricity metering unit with the function of quality control of electrical energy, connected to the second power circuit between the second vacuum switching element dist control unit and the second output switching element of manual control, also connected to the data transmission unit, which records the electricity consumption and the power quality control function in the second power circuit and transmits data to the data transmission unit, the voltage control unit connected to the first power circuit between the first vacuum remote control switching element and the first manual control output switching element, also connected to the second power circuit between the second remote control vacuum switching element and the second manual manual control output switching element, connected to the power circuit between the manual control input switching element and the remote control vacuum switching elements and connected to the control unit of the first vacuum switching element of the remote control, to the control unit of the second vacuum switching element of the remote control with a data transmission unit and monitors the voltage in the power circuits of the multicontact switching system and transmits data about the voltage in them to the data transmission unit and to the control units of the remote control vacuum switching elements.

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.

A multi-contact switching system with independent control of two power contact groups contains an input manual switching element (VKERU 1), a first vacuum switching element for remote control (VKEDU 2), a second vacuum switching element for remote control (VKEDU 3), a first output switching element of manual control (VYKERU 4), the second output switching element of manual control (VYKERU 5), the control unit for the first vacuum switching element of remote control (BUVKEDU 6), the control unit for the second vacuum switching element of remote control (BUVKEDU 7), the unit for remote control of the power circuits of the multi-contact switching system (BDUMKS 8), a local control unit for the first power circuit of a multi-contact switching system (BMUMS 9), a local control unit for the second power circuit of a multi-contact switching system (BMUMS 10), a current control unit (BKT 11), a block for current control (BKT 12), the first electricity metering unit with the function of controlling the quality of electrical energy (BUE 13), the second electricity metering unit with the function of controlling the quality of electrical energy (BUE 14), the unit for monitoring the position of the switching elements (BKPKE 15), the data transmission unit (BPD 16), voltage control unit (BKN 17).

VKERU 1 is installed in the power circuit. VKEDU 2 is installed in the power circuit after VKERU. VKEDU 3 is installed in the second power circuit after VKEDU 1. VYKERU 4, connected to the power circuit after VKEDU 2. VKERU 5, connected to the power circuit after VKEDU 3. BUVKEDU 6 is connected to VKEDU 2. BUVKEDU 7 is connected to VKEDU 3. BDUMKS 8 is connected with a power circuit between VKERU 1 and VKEDU2 and VKEDU 3, also connected to BUVKEDU 6 and BUVKEDU 7. BMUMKS 9 is connected to the first power circuit and to BUVKEDU 6. BMUMKS 10 is connected to the second power circuit and to BUVKEDU 7. BKT 11 is connected to the first a power circuit between VKEDU 2 and VIKERU 4, is also connected to BUVKEDU 6, and also connected to BPD 16. BKT 12 is connected to the second power circuit between VKEDU 7 and VIKERU 5, also connected to BUVKEDU 7, and also connected to BPD 16. BKPKE 15 is connected to BPD 16, with VKERU 1, with VKEDU 2, with VKEDU 3, with VYKERU 4, with VYKERU 5. BUE 13 is connected to the first power circuit between VKEDU 2 and VYKERU 4, also connected to BPD 16. BUE 14 is connected to the second power circuit between VKEDU 3 and VIKERU 5, is also connected to the BPD 16. BKN 17 is connected to the first power circuit between VKEDU 2 and VyKERU 4, is also connected to the second power circuit between VKEDU 3 and VYKERU 5, also connected to the power circuit between VKERU 1 and VKEDU 2, VKEDU 3, and also connected to BUVKEDU 6, to BUVKEDU 7, to BPD 16.

The device works as follows.

The voltage is supplied to the power circuit of the multi-contact switching system using an input manual switching element (VKERU 1) installed in the power circuit. In this case, power is supplied to the local control units of the multi-contact switching system (BMUMKS 9 and BMUMKS 10), as a result of which they automatically send a command to the control units of the first and second vacuum switching elements of remote control (BUVKEDU 6 and BUVKEDU 7) to turn on the first vacuum switching element remote control (VKEDU 2) and the second vacuum switching element of remote control (VKEDU 3), respectively. VKEDU 2 and VKEDU 3 turn on and supply power to the first and second power circuits of the multi-contact switching system. When the first output switching element of manual control (VYKERU 4) is switched on, the voltage will be applied to the first power network behind the multi-contact switching system. When the second output switching element of manual control (VYKERU 5) is switched on, the voltage will be applied to the second power network behind the multi-contact switching system. With local control of the multicontact switching system, the command to turn off the first power circuit is given using BMUMKS 9, and the second power circuit - BMUMKS 10. In this case, the commands for disconnecting the corresponding power circuits are sent from BMUMKS 9 to BUVKEDU 6, and from BMUMKS 10 to BUVKEDU 7, which , in turn, switch off VKEDU 2 and VKEDU 3 by stopping the power supply to their electromagnets. Also, the disconnection of the multi-contact switching system can be carried out using the commands sent to BUVKEDU 6 and BUVKEDU 7 from the remote control unit of the multi-contact switching system (BDUMKS 8). With the help of this unit, it is also possible to remotely switch on a multi-contact switching system. BDUMKS 8 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. If an overload current or short-circuit current occurs in the power circuit behind the multi-contact switching system, or inside it after VKEDU 2 or VKEDU 3, the corresponding current control unit (BKT 11 or BKT12) will send a signal to BUVKEDU 6 or BUVKEDU 7, respectively, to disconnect VKEDU 2 or VKEDU 3. In this case, if the logic of operation of BUVKEDU 6 and BUVKEDU 7 includes an algorithm for automatic reclosing (AR) VKEDU 2 (VKEDU 3), then after a time delay, ARV VKEDU 2 or ARV VKEDU 3 and, if it is unsuccessful, that is, in the first or, respectively, in the second power network behind the multi-contact switching system, or inside it after VKEDU 2 or after VKEDU 3, the overload current or short-circuit current will reappear, then BKT 11 or BKT 12 will re-send a signal to BUVKEDU 6 or BUVKEDU 7 to turn off VKEDU 2 or VKEDU 3. This will block the ability to remotely turn on the multi-contact switching system until the damage in the power circuit is eliminated behind VKEDU 2 or VKEDU 3. Also, a message about the damage will be sent for VKEDU 2 or VKEDU 3. If the automatic reclosure is successful, the multi-contact switching system will continue to work in normal mode. The position of the switching elements of the multicontact switching system is monitored using the switching element position control unit (BKPKE 15), which, when the position of the switching elements VKEDU 2, VKEDU 3, VKERU 1, VYKERU 4, VIKERU 5 changes, transmits the corresponding data to the data transmission unit (BPD 16) ... Electricity consumption metering units with the function of controlling the quality of electrical energy (BUE 13 and BUE 14) account for the electricity transmitted through the first and second power circuits of the multi-contact switching system, and also monitor 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 multicontact switching system. The voltage control unit (BKN 17) monitors the voltage in the power circuits of the multicontact switching system between VKERU 1 and VKEDU 2 and VKEDU 3, between VKEDU 2 and VKERU 4 and between VKEDU 3 and VIKERU 5 and transmit information about the presence or absence of voltage on the BPD 16 and on BUVKEDU 6 and BUVKEDU 7.

The proposed device allows for switching and protection of power lines, electricity metering, power quality control, voltage control in two power networks simultaneously. Its use 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.

Claims (1)

A multi-contact switching system with independent control of two power contact groups, including a switching element 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 switching system, the first vacuum switching element of remote control, installed in the power circuit after the input switching element of manual control and intended for switching the first power circuit using remote controls, the second vacuum switching element of remote control, 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 switching element of manual control connected to the power circuit after the first vacuum switching element of remote control and intended for manual switching of the first power circuit at the first output of the multi-contact switching system, the second output switching element of manual control connected to the power circuit after the second vacuum switching element of remote control and intended for manual switching of the second power circuit at the second output multi-contact switching system, the control unit of the first vacuum switching element of remote control, connected to the first vacuum switching element of the remote control and transmitting to it the ON and OFF commands, the control unit of the second vacuum switching element of the remote control, connected to the second vacuum switching element of the remote control and transmitting to on and off commands, remote control unit for power circuits of a multi-contact switching system, connected with a power circuit between the input switching element of manual control and vacuum switching elements of remote control, also connected to the control units of vacuum switching elements of remote control and transmitting commands received via the power network or via communication channels to the control units of the first and second vacuum switching elements of the remote control unit, a local control unit for the first power circuit of a multi-contact switching system, connected to the first power circuit and with a control unit for the first vacuum switching element of remote control and transmitting manual control commands to the control unit for the first vacuum switching element of remote control, a local control unit for the second power circuit of a multi-contact switching system system, connected to the second power circuit and to the control unit of the second vacuum switching element of remote control and transmitting the commands p control unit to the control unit of the second vacuum switching element of remote control, a current control unit connected to the first power circuit of the multi-contact switching system between the first vacuum switching element of remote control and the first output switching element of manual control, also connected to the control unit of the first vacuum switching element of remote control and transmitting shutdown commands to the control unit of the first vacuum switching element of remote control when the current in the first power circuit exceeds a predetermined current value taken as an overload current or short-circuit current, and is also connected to the data transmission unit for transmitting current values in the first power circuit along on request, a current monitoring unit connected to the second power circuit of the multi-contact switching system between the second vacuum switching element of the remote control and the second output switching m by a manual control element, also connected to the control unit of the second vacuum switching element of remote control and transmitting the shutdown commands to the control unit of the second vacuum switching element of remote control when the current in the second power circuit exceeds the set value of the current taken as the overload current or short-circuit current, and also connected to the data transmission unit for transmitting current values in the second power circuit upon request, a data transmission unit that transmits information about the operation of the multi-contact switching system to the dispatcher of the company servicing the electrical network in which the multi-contact switching system is installed, the unit for monitoring the position of the switching elements, connected to a data transmission unit and switching elements installed in a multi-contact switching system, monitoring the positions of the input manual switching element, the first vacuum switch remote control element, the second vacuum switching element of remote control, the first output switching element of manual control and the second output switching element of manual control, transmitting data about their position to the data transmission unit, the first electricity metering unit with the function of quality control of electrical energy connected to the first power circuit between the first vacuum switching element of remote control and the first output switching element of manual control, also connected to the data transmission unit, which records electricity consumption and power quality control functions in the first power circuit and transmits data to the data transmission unit, the second electricity metering unit with function of quality control of electrical energy, connected to the second power circuit between the second vacuum switching element of remote control and the second output switching element manually control unit, also connected to the data transmission unit, which records electricity consumption and power quality control functions in the second power circuit and transmits data to the data transmission unit, a voltage monitoring unit connected to the first power circuit between the first vacuum switching element of the remote control and the first output manual switching element, also connected to the second power circuit between the second vacuum switching element of remote control and the second outgoing switching element of manual control, connected to the power circuit between the input switching element of manual control and vacuum switching elements of remote control and connected to the control unit by the first vacuum switching element a remote control element, with a control unit for the second vacuum switching element of a remote control, with a data transmission unit and monitoring the voltage I am in the power circuits of a multi-contact switching system and transmitting data about the voltage in them to the data transmission unit and to the control units of the vacuum switching elements of the remote control.

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