RU2798867C1 - Multi-contact switching system with independent control of six power contact groups having a common connection point - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to devices for sectioning and redundant power lines, and is intended for switching, protecting the electrical network, metering electricity, monitoring the quality of electricity, controlling the amount and time of voltage shutdown in three-phase current distribution networks. 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 current distribution networks with the ability to independently control six power contact groups having a common connection point, for partitioning and redundancy of six sections of the transmission lines. A multi-contact switching system with independent control of six power contact groups having a common connection point, contains six output switching elements for manual control, six switching elements for remote control, six control units for switching elements for remote control, a control unit for a multi-contact switching system, a unit for receiving and transmitting data, uninterruptible power supply. The proposed device allows switching and protecting power lines, electricity metering, power quality control, voltage control simultaneously in six power networks. In the event of a voltage failure in one of the power networks and its appearance in another, the device allows you to perform the functions of automatic switching on of the reserve by switching on the corresponding power contact groups. Also, the device allows you to partition the electrical network by dividing it into sections by disconnecting the corresponding power contact groups in case of damage in the power networks connected to the multi-contact switching system. Its application prevents the development of an emergency and allows to reduce the undersupply of electricity to consumers, reduce the losses of energy supply organizations and, thus, increase the reliability and efficiency of consumer power supply systems.

EFFECT: ability to perform the functions of switching, protection of the electrical network, electricity metering, power quality control, voltage control in three-phase current distribution networks with the ability to independently control six power contact groups having a common connection point, for partitioning and redundancy of six sections of the transmission lines.

1 cl, 1 dwg

Description

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

The closest in technical essence to the proposed invention is a sectional point for switching and protecting power lines, including a high-voltage module and a low-voltage control and protection unit mounted on one support, located in separate housings and connected by a cable, the high-voltage module contains on the cover and side high-voltage bushings for connecting to a power line, current transformers and a vacuum circuit breaker, and a low-voltage control and protection unit contains vacuum circuit breaker controls, relay or microprocessor protection and automation devices and a battery (RF patent for utility model No. 52276, class H02V 11 /00, published on March 10, 2006, Bulletin No. 7).

The disadvantage of the well-known sectioning point for switching and protecting power lines is its limited scope and, accordingly, the impossibility of using it for switching, protecting the electrical network, metering electricity, monitoring the quality of electricity, controlling the amount and time of disconnection of voltage in distribution networks of three-phase current, the impossibility of independent management of six power contact groups having a common connection point for sectioning and redundancy of six sections of power lines.

The objective of the invention is to increase the functionality and scope of its use through the application for switching, protection of the electrical network, electricity metering, power quality control, control of the amount and time of voltage outage in three-phase current distribution networks with the possibility of independent control of six power contact groups having a common connection point for sectioning and redundancy of six sections of power lines.

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 current distribution networks with the ability to independently control six power contact groups having a common connection point, for partitioning and redundant six sections power lines. This is achieved due to the independent control of the contact groups of the multicontact switching system and the control of its operation modes and the modes of the network in which it is installed. It also makes it possible to reduce the undersupply of electricity to consumers, reduce the losses of energy supply organizations and, thus, increase the reliability and efficiency of the functioning of consumer power supply systems.

The above technical result is achieved by the fact that the proposed multi-contact switching system, which has independent control of six power contact groups having a common connection point, including a switching element and a control and protection unit, according to the invention, contains the first manual control output switching element installed in the first power circuit and intended for its manual switching, the first remote control switching element, which is the first power contact group with independent control, installed in the first power circuit between the first output switching element of manual control and the common point of the multi-contact switching system and intended for switching the first power circuit using remote controls, the second manual control output switching element installed in the second power circuit and intended for its manual switching, the second remote control switching element, which is a second power contact group with independent control, installed in the second power circuit between the second output switching manual control element and a common point of the multi-contact switching system and intended for switching the second power circuit using remote controls, the third manual control output switching element installed in the third power circuit and intended for its manual switching, the third remote control switching element, which is the third power contact group with independent control, installed in the power circuit between the third switching element of manual control and the common point of the multi-contact switching system and intended for switching the third power circuit using remote controls, the fourth output switching element of manual control, installed in the fourth power circuit and intended for its manual switching, the fourth remote control switching element, which is the fourth power contact group with independent control, installed in the power circuit between the fourth manual control switching element and the common point of the multi-contact switching system and intended for switching the fourth power circuit using remote controls, the fifth manual control output switching element installed in the fifth power circuit and intended for its manual switching, the fifth remote control switching element, which is the fifth power contact group with independent control, installed in the power circuit between the fifth manual control switching element and the common point of the multi-contact switching of the system and intended for switching the fifth power circuit using remote controls, the sixth manual control output switching element installed in the sixth power circuit and intended for its manual switching, the sixth remote control switching element, which is the sixth power contact group with independent control, installed into the sixth power circuit between the sixth output switching element of manual control and the common point of the multicontact switching system and intended for switching the sixth power circuit using remote controls, the control unit of the first switching element of the remote control connected to the first switching element of the remote control and transmitting commands to it switch on and off, the control unit of the second switching element of the remote control, connected to the second switching element of the remote control and transmitting commands on and off to it, the control unit of the third switching element of the remote control, connected to the third switching element of the remote control and transmitting commands to it on and off shutdown, the control unit of the fourth remote control switching element connected to the fourth remote control switching element and transmitting on and off commands to it, the control unit of the fifth remote control switching element connected to the fifth remote control switching element and transmitting on and off commands to it, the control unit of the sixth switching element of the remote control connected to the sixth switching element of the remote control and transmitting commands to it on and off; switching elements of the remote control and controls their position, is connected to each of the control units of the switching elements of the remote control and transmits commands to them to turn on and off the corresponding switching element of the remote control, is connected to the power circuits of the multicontact system between all the switching elements of remote and manual control and controls current and voltage in these power circuits, metering the consumption of electricity in these circuits and monitoring the quality of electricity in them, is connected to the data transmission unit and transfers data on the operation of the multi-contact switching system to it and receives commands from it to control the switching elements of the remote control, is connected with an uninterruptible power supply unit to receive power when the voltage is turned off in all power circuits, the uninterruptible power supply unit is connected to the control unit of the multi-contact switching system and the data reception and transmission unit to provide their power supply.

The essence of the invention is illustrated in the drawing, which shows a block diagram of a multi-contact switching system with independent control of six power contact groups having a common connection point.

A multi-contact switching system with independent control of six power contact groups having a common connection point contains the first manual control output switching element (VKERU 1), the first remote control switching element (KEDU 2), the second remote control switching element (KEDU 3), the third switching remote control element (KEDU 4), fourth switching element of remote control (KEDU 5), fifth switching element of remote control (KEDU 6), sixth switching element of remote control (KEDU 7), second output switching element of manual control (VyKERU 8), third output switching element of manual control (VyKERU 9), fourth output switching element of manual control (VyKERU 10), fifth output switching element of manual control (VyKERU 11), sixth output switching element of manual control (VyKERU 12), control unit of the first switching element of remote control (BUKEDU 13), the control unit of the second switching element of the remote control (BUKEDU 14), the control unit of the third switching element of the remote control (BEKEDU 15), the control unit of the fourth switching element of the remote control (BEKEDU 16), the control unit of the fifth switching element of the remote control (BEKEDU 17), a control unit for the sixth switching element of the remote control (BUKEDU 18), a control unit for a multi-contact switching system (BUMKS 19), an uninterruptible power supply unit (BBP 20), a data reception and transmission unit (BPD 21).

VKERU 1 is installed in the first power circuit. KEDU 2 is installed in the first power circuit between VKERU 1 and the common point of the multicontact switching system. VyKERU 8 is installed in the second power circuit. KEDU 3 is installed in the second power circuit between VKERU 8 and the common point of the multicontact switching system. VyKERU 9 is installed in the third power circuit. KEDU 4 is installed in the power circuit between VKERU 9 and the common point of the multicontact switching system. VKERU 10 is installed in the fourth power circuit. KEDU 5 is installed in the fourth power circuit between VKERU 10 and the common point of the multicontact switching system. VKERU 11 is installed in the fifth power circuit. KEDU 6 is installed in the fifth power circuit between VKERU 11 and the common point of the multicontact switching system. VKERU 12 is installed in the sixth power circuit. KEDU 6 is installed in the sixth power circuit between VKERU 12 and the common point of the multicontact switching system. BUKEDU 13 is connected to KEDU 2. BUKEDU 14 is connected to KEDU 3. BUKEDU 15 is connected to KEDU 4. BUKEDU 16 is connected to KEDU 5. BUKEDU 17 is connected to KEDU 6. BUKEDU 18 is connected to KEDU 7. BPD 21 is connected to BUMKS 19 and with BBP 20. BUMKS 19 is connected to KEDU 2, to KEDU 3, to KEDU 4, to KEDU 5, to KEDU 6, to KEDU 7, to VyKERU 1, to VyKERU 8, to VyKERU 9, to VyKERU 10, to VyKERU 11, with VyKERU 12, connected with BUKEDU 13, with BUKEDU 14, with BUKEDU 15, with BUKEDU 16, with BUKEDU 17, with BUKEDU 18, connected to the power circuits of the multicontact system between all switching elements of remote and manual control, connected to BPD 21, connected with BBP 20. BBP 20 is connected to BUMKS 19 and to BPD 21.

The device works as follows.

Voltage supply to the power circuit of the multicontact switching system is carried out using output switching elements of manual control (VyKERU 1, VyKERU 8, VyKERU 9, VyKERU 10, VyKERU 11, VyKERU 12) installed in the power circuit, depending on which side of the power network the power supply is located. In this case, power is supplied to the control unit of the multi-contact switching system (BUMKS 19), as a result of which they automatically send a command to the control units of the first, second, third, fourth, fifth and sixth switching elements of the remote control (BUKEDU 13, BUKEDU 14, BUKEDU 15, BUKEDU 16, BUKEDU 17, BUKEDU 18) to turn on the first switching element of the remote control (KEDU 2), the second switching element of the remote control (KEDU 3), the third switching element of the remote control (KEDU 4), the fourth switching element of the remote control (KEDU 5) , the fifth switching element of the remote control (KEDU 6), the sixth switching element of the remote control (KEDU 7), respectively. When the first output switching element of manual control (VKERU 1) is turned on, 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 the second output switching element of manual control (VKERU 8) is turned on, 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 (VKERU 9) is turned on, 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). When the fourth output switching element of manual control (VKERU 10) is turned on, voltage will be applied to the fourth power network behind the multi-contact switching system (if the power source is not located in the fourth power network). When the fifth output switching element of manual control (VKERU 11) is turned on, voltage will be applied to the fifth power network behind the multi-contact switching system (if the power source is not located in the fifth power network). When the sixth output switching element of manual control (VKERU 12) is turned on, voltage will be applied to the sixth power network behind the multi-contact switching system (if the power source is not located in the sixth power network). With local control of a multi-contact switching system, the command to turn on / off the first, second, third, fourth, fifth and sixth power circuits is given using BUMKS 19. In this case, the commands to turn off the corresponding power circuits are given from BUMKS 19 to BUKEDU 13, BUKEDU 14, BUKEDU 15 , BUKEDU 16, BUKEDU 17, BUKEDU 18, which, in turn, turn off KEDU 2, KEDU 3, KEDU 4, KEDU 5, KEDU 6 and KEDU 7 by cutting off the power supply to their electromagnets. Also, turning off / on KEDU2, KEDU 3, KEDU 4, KEDU 5, KEDU 6 and KEDU 7 of the multicontact switching system can be carried out using commands processed using BUMKS 19, given to BUKEDU 13, BUKEDU 14, BUKEDU 15, BUKEDU 16, BUKEDU 17 and BUKEDU 18 from the data receiving and transmitting unit (BPD 21). BPD 21 receives commands to turn on or turn off the corresponding KEDU of the multi-contact switching system using an encoded signal transmitted over the power network using existing signal transmission technologies over it or using a coded sequence of turning on and off the voltage in it, or receives commands to turn on or off the multi-contact switching system using a signal received through a communication channel, such as JPS, JPRS, Glonass, radio or another channel.

If an overload current or a short circuit current occurs in the power circuit behind the multicontact switching system up to KEDU 2, KEDU 3, KEDU 4, KEDU 5, KEDU 6 or KEDU 7 14, BUKEDU 15, BUKEDU 16, BUKEDU 17, BUKEDU 18, respectively, to disable KEDU 2, KEDU 3, KEDU 4, KEDU 5, KEDU 6 or KEDU 7. In this case, if in the operation logic of BUKEDU 13, BUKEDU 14, BUKEDU 15 , BUKEDU 16, BUKEDU 17 and BUKEDU 18, an algorithm for performing automatic reclosing (AR) of KEDU 2 (KEDU 3, KEDU 4, KEDU 5, KEDU 6, KEDU 7) is laid down, then after a time delay, the corresponding AR of KEDU 2, or AR will be carried out KEDU 3, or AR KEDU 4, or AR KEDU 5, or AR KEDU 6, or AR KEDU 7, and if it is unsuccessful, that is, in the first, second, third, fourth, fifth power circuit, or, accordingly, in the sixth power circuit behind the multi-contact switching system up to KEDU 2, or KEDU 3, or KEDU 4, or KEDU 5, or KEDU 6, or KEDU 7, an overload current or a short circuit current will reappear, then BUMKS 19 will re-send a signal to BUKEDU 13, or BUKEDU 14, or BUKEDU 15, or BUKEDU 16, or BUKEDU 17, or BUKEDU 18, to turn off KEDU 2, or KEDU 3, or KEDU 4, or KEDU 5, or KEDU 6 or KEDU 7. In this case, there will be the ability to remotely turn on the multi-contact switching system is blocked until damage is eliminated in the power circuit behind KEDU 2, or KEDU 3, or KEDU 4, or KEDU 5, or KEDU 6, or KEDU 7. Also, a message will be sent about the damage behind KEDU 2, or KEDU 3, or KEDU 4, or KEDU 5, or KEDU 6, or KEDU 7. If automatic reclosure is successful, the multicontact switching system will continue to operate in normal mode. The position of the switching elements of the multi-contact switching system is controlled by the control unit of the multi-contact switching system (BUMKS 19), which, when changing the position of the switching elements KEDU 2, KEDU 3, KEDU 4, KEDU 5, KEDU 6, KEDU 7, VyKERU 1, VyKERU 8, VyKERU 9, VEKRU 10, VEKRU 11, VEKRU 12 transmits the corresponding data to the data transmission unit (DTU 21). The control unit of the multicontact switching system (BUMKS 19) performs metering of electricity transmitted through the first, second, third, fourth, fifth and sixth power circuits of the multicontact switching system, and also controls the quality of electric energy at the point of their connection. Data on electricity consumption and on 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 multicontact switching system. The multicontact switching system control unit (BUMKS 19) controls the voltage in the power circuits of the multicontact switching system between VKERU 1 and KEDU 2, between KEDU 3 and VyKERU 8, between KEDU 4 and VyKERU 9, between KEDU 5 and VyKERU 10, between KEDU 6 and VyKERU 11, between KEDU 7 and VyKERU 12 and transmits information about the presence or absence of voltage to BPD 21 and to BUKEDU 13, BUKEDU 14, BUKEDU 15, BUKEDU 16, BUKEDU 17, BUKEDU 18.

The proposed device allows switching and protecting power lines, electricity metering, power quality control, voltage control simultaneously in six power networks. In the event of a voltage failure in one of the power networks and its appearance in another, the device allows you to perform the functions of automatic switching on of the reserve by switching on the corresponding power contact groups. Also, the device allows you to partition the electrical network by dividing it into sections by disconnecting the corresponding power contact groups in case of damage in the power networks connected to the multi-contact switching system. Its application prevents the development of an emergency and allows to reduce the undersupply of electricity to consumers, reduce the losses of energy supply organizations and, thus, increase the reliability and efficiency of consumer power supply systems.

Claims (1)

Multi-contact switching system with independent control of six power contact groups having a common connection point, including switching elements and a control and protection unit, characterized in that it contains the first output switching element for manual control installed in the first power circuit and intended for its manual switching element, the first remote control switching element, which is the first power contact group with independent control, installed in the first power circuit between the first output switching element of manual control and the common point of the multi-contact switching system and intended for switching the first power circuit using remote controls, the second output switching element of manual control installed in the second power circuit and intended for its manual switching, the second switching element of remote control, which is the second power contact group with independent control, installed in the second power circuit between the second output switching element of manual control and the common point of the multicontact switching system and intended for switching the second power circuit using remote controls, the third output switching element of manual control installed in the third power circuit and intended for its manual switching, the third switching element of the remote control, which is a third power contact group with independent control, installed in the power circuit between the third switching element of manual control and the common point of the multi-contact switching system and intended for switching the third power circuit using remote controls, the fourth output switching element of manual control installed in the fourth power circuit and intended for its manual switching, the fourth switching remote control element, which is the fourth power contact group with independent control, installed in the power circuit between the fourth switching element of manual control and the common point of the multi-contact switching system and intended for switching the fourth power circuit using remote controls, the fifth output switching element of manual control, installed in the fifth power circuit and intended for its manual switching, the fifth remote control switching element, which is the fifth power contact group with independent control, installed in the power circuit between the fifth manual control switching element and the common point of the multicontact switching system and intended for switching the fifth power circuit using remote controls, the sixth manual control output switching element installed in the sixth power circuit and intended for its manual switching, the sixth remote control switching element, which is the sixth power contact group with independent control, installed in the sixth power circuit between the sixth output switching element of manual control and a common point of the multi-contact switching system and designed for switching the sixth power circuit using remote controls, the control unit of the first switching element of the remote control connected to the first switching element of the remote control and transmitting commands to turn on and off to it, the control unit of the second remote control switching element connected to the second remote control switching element and transmitting on and off commands to it, the control unit of the third remote control switching element connected to the third remote control switching element and transmitting on and off commands to it, the fourth switching element control unit remote control connected to the fourth remote control switching element and transmitting on and off commands to it, the control unit of the fifth remote control switching element connected to the fifth remote control switching element and transmitting on and off commands to it, the control unit of the sixth remote control switching element connected to the sixth switching element of the remote control and transmitting on and off commands to it, the data receiving and transmitting unit is connected to the control unit of the multi-contact switching system and the uninterruptible power supply unit, the control unit of the multi-contact switching system is connected to each of the switching elements of the remote control and controls them position, is connected to each of the control units of the switching elements of the remote control and transmits commands to them to turn on and off the corresponding switching element of the remote control, is connected to the power circuits of the multicontact system between all the switching elements of the remote and manual control and controls the current and voltage in these power circuits , performs accounting of electricity consumption in these circuits and controls the quality of electricity in them, is connected to the data transmission unit and transfers data on the operation of the multi-contact switching system to it and receives commands from it to control the switching elements of the remote control, is connected to the uninterruptible power supply unit to receive power when the voltage is turned off in all power circuits, the uninterruptible power supply unit is connected to the control unit of the multicontact switching system and the unit for receiving and transmitting data to provide their power supply.

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