RU2755654C1 - Sectioning and redundancy point - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to the field of electrical engineering. The sectioning and redundancy point contains the first output switching element of manual control, the switching element of remote control, the second output switching element of manual control, the control unit of the switching element of remote control, the control unit of the universal point of sectioning and redundancy, the unit for receiving and transmitting data, the uninterruptible power supply unit, the unit rectifying and inverting, two surge suppressors. The device allows switching, protection of the electrical network, metering of electricity, metering the quality of electricity, monitoring the amount and time of voltage outages in distribution electrical networks, sectioning and backing up power lines, including those to which electricity sources are connected, including those that are not synchronized with each other, as well as protection of his equipment from atmospheric and switching overvoltages.

EFFECT: increasing 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 and redundancy of power lines and is intended for switching, protecting the electrical network, electricity metering, metering the quality of electricity, monitoring the amount and time of power outages, sectioning and redundancy of distribution electrical networks, power lines, in including those containing power sources that are not synchronized with each other.

The closest in technical essence to the proposed invention is a sectioning point up to 1 kV, combined with an electricity metering point and electricity quality control, monitoring the amount and time of voltage outages, including a switching element and a control and protection unit (RF patent No. 2736542, IPC Н02В 7/06, publ. 18.11.2020, bull. No. 32).

The disadvantage of the known sectioning point is its limited functionality and scope, since it cannot be used for sectioning and backing up power transmission lines to which electricity sources are connected that are not synchronized with the centralized electrical network, or with each other, is not intended to perform redundancy functions, and also the fact that its equipment is not protected from atmospheric and switching overvoltages.

The objective of the present invention is to increase the functionality and expand the scope of its application for switching, protecting the electrical network, metering electricity, metering the quality of electricity, monitoring the amount and time of voltage outages in distribution electrical networks, for sectioning and backing up power lines, including those for which are connected to power sources, including those that are not synchronized with each other, as well as to protect its equipment from atmospheric and switching overvoltages.

As a result of using the proposed invention, it becomes possible to carry out the functions of switching, protecting the electrical network, electricity metering, metering the quality of electricity, monitoring the amount and time of voltage outages in distribution electrical networks, sectioning and backing up power lines, including those to which power sources are connected, including those that are not synchronized with each other, as well as in the protection of its equipment from atmospheric and switching overvoltages. This is achieved due to the fact that the sectioning and redundancy point contains the first output switching element of manual control, the switching element of remote control, the second output switching element of manual control, the control unit of the switching element of remote control, the control unit of the sectioning and redundancy point, the unit for receiving and transmitting data , uninterruptible power supply unit, rectifier and inverter unit, two surge suppressors. Application of the invention allows to reduce the undersupply of electricity to consumers, to reduce losses of power supply organizations and, thus, to increase the reliability and efficiency of power supply systems for consumers.

The above technical result is achieved by the fact that the proposed sectioning and redundancy point, which includes a switching element and a control and protection unit, according to the invention, contains a first input manual switching element installed in the power circuit and intended for its manual switching at the first output of the sectioning point and redundancy, a remote control switching element installed in the power circuit after the input manual control switching element and intended for its switching using remote controls, a rectifying and inverting unit installed in the power circuit after the remote control switching element and designed to separate the power circuits through DC insert, the second output switching element of manual control, connected to the power circuit after the rectifying and inverting unit, intended for its manual switching on the output of the sectioning and redundancy point, the control unit of the remote control switching element, connected to the remote control switching element and transmitting to it the ON and OFF commands, also connected to the control unit of the sectioning and redundancy point, the data reception and transmission unit connected to the control unit of the point sectioning and redundancy and an uninterruptible power supply unit, which transfers information about the operation of the sectioning and redundancy point to the dispatcher of the company serving the electrical network in which the sectioning and redundancy point is installed, the control unit of the sectioning and backup point connected to the input switching element of manual control, output switching element manual control, a remote control switching element, controlling their position, connected to the control unit with a remote control switching element and transmitting to it the commands for turning on and off the remote control switching element, taking into account the specified operating algorithms and incoming local and remote control commands, connected to the power circuit of the sectioning point between the remote control switching element and the first manual control switching elements, between the remote control switching element and rectifying and inverting unit, between the rectifying and inverting unit and the second output switching elements of manual control, connected to the power networks before and after the sectioning and redundancy point, and controlling the current and voltage in the power circuit and power networks, accounting for the electricity consumption in this circuit and power quality control in it, connected to the data transmission unit and transmitting to it data on the operation of the sectioning and redundancy point and receiving commands from it control of a remote control switching element 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 before and after the sectioning and redundancy point, connected to the sectioning point control unit and the data receiving and transmitting unit to ensure their power supply, two surge suppressors connected to power networks before and after the sectioning and redundancy point and providing protection against atmospheric and switching overvoltages.

The essence of the invention is illustrated by the drawing, which shows a block diagram of the sectioning and redundancy point.

The sectioning and redundancy point contains the first output switching element for manual control (VYKERU 1), a switching element for remote control (KEDU 2), a second output switching element for manual control (VYKERU 3), a control unit for the switching element of remote control (BUKEDU 4), a control unit for the point sectioning and redundancy (BUUPSIR 5), data receiving and transmitting unit (BPD 6), uninterruptible power supply unit (BPP 7), rectifying and inverting unit (BVIN 8), the first surge arrester (SPN 9), the second surge arrester (SPN 10) ...

VyKERU 1 is installed in the power circuit. KEDU 2 is installed in the power circuit after VYKERU 1. BVIN8 is installed in the power circuit after KEDU 2, VYKERU 3 is installed in the power circuit after VKEDU 2. BUKEDU 4 is connected to KEDU 2 and to BUUPSIR 5. BUUPSIR 5 is connected to VYKERU 1, KEDU 2, VYKERU 3, BUKEDU 4, BVIN 8, connected to the power circuits of the sectioning point, connected to the BPD 6, connected to the BBP 7. The BBP 7 is connected to the BUUPSIR 5 and to the BPD 6, as well as to the power networks before and after the sectioning and redundancy point. Surge arrester 9 is connected to the power network up to the sectioning point. Surge arrester 10 is connected to the mains after the sectioning point.

The device works as follows.

The voltage is supplied to the power circuit of the sectioning and redundancy point using the first or second output switching element of manual control (VYKERU 1, or VYKERU 3) installed in the power circuit depending on the location of the main power supply in relation to the sectioning and redundancy point. In this case, power is supplied to the control unit of the sectioning point (BUUPSIR 5), which, depending on the built-in operation algorithm, local or remote control commands, switches off and on KEDU 2, supplying the control unit with a vacuum switching element of remote control (BUKEDU 4). When switched on, KEDU 2 supplies power to the power circuit behind it. With local control of the sectioning point, the command to turn it off, or turn on KEDU 2 is given using BUUPSIR 5. In this case, the command to turn off, or turn on the sectioning and redundancy point is sent from BUUPSIR 5 to BUKEDU 4, which, in turn, turns off KEDU 2 at the expense of cessation of power supply to the KEDU coil. In this case, voltage disappears in the circuit behind KEDU 2. Also, the disconnection and activation of the sectioning and redundancy point can be carried out using the commands sent to the BUKEDU 4 from the data reception and transmission unit (BPD 6), processed using the BUPSIR 5. Using this block, you can also remotely activate the sectioning and redundancy point. BPD 6 receives commands to turn on or off the sectioning and redundancy point 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. BPD 6 receives commands to enable or disable the sectioning and redundancy point 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 appears in the power circuit behind the sectioning point, or inside it after VKEDU 2, an overload current or a short-circuit current, then BUUPSIR 5 will send a signal to BUKEDU 4 to disconnect CEDU 2. In this case, if the logic of operation of BUKEDU 4 contains an algorithm for automatic reclosing (AR) of KEDU 2, then after a time delay, the AR of KEDU 2 will be carried out and if it is unsuccessful, that is, in the power network behind the sectioning and redundancy point, or inside it after KEDU 2, the overload current or short-circuit current will reappear, then BUUPSIR 5 will re-send a signal to BUKEDU 4 to disconnect CEDU 2, while the possibility of remote switching on of the sectioning and redundancy point will be blocked until the damage in the power circuit behind CEDU 2 is eliminated. successful, the partitioning and redundancy point will continue to operate normally.

The algorithms for the operation of the sectioning and redundancy point (in BUPSIR 5) also include the functions of two-way automatic switching on of the reserve (ATS), algorithms for prohibiting the ATS in prescribed cases, and algorithms for protection against emergency modes.

The position of the switching elements of the sectioning point is controlled by the sectioning point control unit (BUUPSIR 5), which, when the position of the switching elements KEDU 2, VYKERU 1, VYKERU 3 changes, transmits the corresponding data to the data reception and transmission unit (BPD 6). The control unit of the sectioning and redundancy point (BUUPSIR 5) also monitors the electricity transmitted through the sectioning and redundancy point, and also monitors the quality indicators of electrical energy at the point where the sectioning point is installed. Data on electricity consumption and the quality of electrical energy are transmitted to the data transmission unit and through it to the dispatcher of the power company or company, on whose balance the equipment of the sectioning and redundancy point is located. The control unit of the sectioning and redundancy point (BUUPSIR 5) controls the voltage before and after the sectioning point and the current at these points. When the voltage disappears before or after the sectioning point, the countdown of the time of the absence of voltage at the corresponding point begins, and information is also transmitted to the BPD 6 about the disconnection of the voltage in it. Current monitoring with the help of BUPSIR 5 allows you to determine the presence of damage at the sectioning point or behind it and transfer this information to the BPD 6. The uninterruptible power supply unit BPU 7 supplies power to the UPSIR 5 and BPD 6 both from power networks and from an independent power source contained in it such as a battery, capacitor or other source. BVIN 8 consists of two switched on counter-active rectifiers with a control unit 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 sectioning and redundancy point. The presence of two switched on counter-active rectifiers in BVIN 8 allows decoupling of power networks before and after the point of sectioning and redundancy, since a DC link is formed between these power networks. Due to this, it is possible to operate the sectioning and redundancy point in power lines, to which electricity sources are connected from different sides of the sectioning and redundancy point, 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 different species, or one species, but not synchronized with each other.

Surge arrester 9 and arrester 10 provide protection of the equipment of the sectioning and redundancy point from atmospheric and switching overvoltages.

The proposed device makes it possible to carry out switching, protection of the electrical network, metering of electricity, metering the quality of electricity, monitoring the amount and time of voltage outages in distribution electrical networks, sectioning and backing up power lines, including those to which electricity sources are connected, including those that are not synchronized. with a friend, as well as protecting his equipment from atmospheric and switching overvoltages.

Claims (1)

Sectioning and redundancy point, which includes a switching element and a control and protection unit, characterized by which contains the first input manual switching element installed in the power circuit and intended for its manual switching at the first output of the sectioning and redundancy point, a remote control switching element installed in the power circuit after the manual input switching element and intended for its switching using remote control means, a rectifying and inverting unit installed in the power circuit after the remote control switching element and designed to separate power circuits through a DC link, a second manual output switching element connected to the power circuit after the rectifying and inverting unit, designed for manual switching at the second output of the sectioning and redundancy point, the control unit for the remote control switching element, connected to the remote control switching element and transmitting to it, turn on and off commands, also connected to the control unit of the sectioning and redundancy point, the data reception and transmission unit, connected to the control unit of the sectioning and redundancy point and the uninterruptible power supply unit, transmitting information about the operation of the sectioning and redundancy point to the dispatcher of the company servicing the electrical the network in which the sectioning and redundancy point is installed, the control unit of the sectioning and redundancy point, connected to the input switching element of manual control, the output switching element of manual control, the switching element of remote control, controlling their position, connected to the control unit of the switching element of remote control and performing transmitting to it commands for switching on and off the remote control switching element, taking into account the specified operating algorithms and incoming local and remote control commands connection, connected to the power circuit of the sectioning point between the remote control switching element and the first output switching element of manual control, between the switching element of the remote control and the rectifying and inverting unit, between the rectifying and inverting unit and the second output switching element of manual control, connected to the power networks up to and after the point of sectioning and redundancy, and monitoring the current and voltage in the power circuit and power networks, accounting for the consumption of electricity in this circuit and monitoring the quality of electricity in it, connected to the data transmission unit and transmitting to it data on the operation of the sectioning and redundancy point and receiving commands from it to control the remote control switching element, connected to the uninterruptible power supply unit to receive power when the voltage is disconnected in all power circuits, the uninterruptible power supply unit connected with power networks before and after the sectioning and redundancy point, connected to the control unit of the sectioning point and the data receiving and transmitting unit to ensure their power supply, two surge arresters connected to the power networks before and after the sectioning and redundancy point and protecting against atmospheric and switching overvoltage.

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