RU2828825C1 - Method of protecting electrical network from short circuits, including with low currents, and wire breaks - Google Patents

Abstract

FIELD: automation of electric networks.

SUBSTANCE: setting the characteristic sequences of changing the values of parameters on the outputs of the electrical network objects for emergency situations of different types, setting which of the switching devices should be disconnected when one or another given sequence of changing the parameters is detected, values of parameters, sequence of their change in control points are monitored and compared with specified characteristic ones; when the monitored sequence coincides with one or another given characteristic one, corresponding switching devices are switched off.

EFFECT: protection of network sections from short-circuit currents, including those with low currents, as well as from wire breaks, increased reliability of power supply to consumers and electrical safety.

1 cl, 1 dwg

Description

The invention relates to the automation of electrical networks and is intended to control the configuration and protect the electrical network from short circuits, including low-current ones, and wire breaks, increasing the reliability of power supply and electrical safety.

A method is known for expanding the sensitivity zone of a protective switching device to short-circuit currents, which consists of monitoring the current in a power transmission line and determining the distance from the protective switching device installed at the beginning of the line to the maximum remote short-circuit point at which the sensitivity of this protective switching device to short circuits is ensured (RU Patent No. 2744513, IPC H02H 3/10, G01R 31/52, 2021).

A method is known for protecting a power transmission line from a remote short circuit and informing the network dispatcher about the disconnection of a protective switching device due to a short circuit, or for another reason, consisting of monitoring the current in the power transmission line and determining the maximum distance from the protective switching device installed at the beginning of the line to the maximum remote point of the short circuit, in which the sensitivity of this protective switching device to short circuits is ensured, characterized in that at this or a slightly smaller distance, a protective switching device is installed in the power transmission line, sensitive to short-circuit currents from the installation point to the end of the power transmission line, the protective switching device is equipped with current and voltage sensors, a position sensor, with the help of which the current flowing through the protective switching device and the voltage on both sides of the protective switching device are monitored, as well as the position of the protective switching device, when a short circuit occurs behind the installation point of the protective switching device the device disconnects the short-circuit current with this protective switching device, thus protecting the power transmission line from remote short circuits, when a short-circuit current flows through the protective switching device and the voltage subsequently disappears behind the point of installation of the protective switching device, the fact of disconnection of the protective switching device is recorded using a position sensor, a conclusion is made about the disconnection of the protective switching device due to the short-circuit current and a message about this is sent via a communication channel to the network dispatcher, if there is no fact of short-circuit current flowing through the protective switching device, but when the voltage disappears behind the protective switching device and the disconnection of the protective switching device is recorded by the position sensor, a conclusion is made that the disconnection of the protective switching device occurred not due to a short circuit, but, for example, manually, a message about this is sent via a communication channel to the network dispatcher (patent No. 2763036 Russian Federation, IPC H02B 1/00, H02В 13/00, Н02J 4/00, 2021).

The closest in technical essence to the proposed invention is a method and device for determining the causes of disconnection of consumers of a sectioned power transmission line, in which the voltage and current are monitored at network control points, at consumer inputs, the facts of voltage disappearance at different network points and its presence at other points are compared, the facts of the appearance of overload and short-circuit currents at control points are compared and, based on the comparison of these facts, a conclusion is made on the causes of disconnection of consumers in the sectioned power transmission line. The method is implemented using a device containing current sensors, voltage sensors, an information processing and display unit (Patent No. 2767519 Russian Federation, IPC H02J 13/00, H02J 3/06, G06Q 50/06. 2022).

The presence of distributed generation facilities in the network, which may include, among other things, low-power consumer generating units, photovoltaic installations and others, as well as energy storage devices, leads to the feeding of short-circuit currents by these facilities. This, in turn, leads to a decrease in the short-circuit current at the terminals of the centralized power supply source and the insufficiency of the sensitivity of the protective switching device installed there to such currents. Thus, the protection of network sections from short circuits is not ensured. Also, in cases of exceeding the length of lines, small cross-section of the wire, the short-circuit current at the end of the line may be lower than the setting of the protective switching device at the beginning of the line. Also, if the wire breaks, a short circuit may not occur and the protective device at the beginning of the line, or in the sectioning device will not disconnect the network section with the wire break. Also, if the wire breaks and falls to the ground, the short-circuit current is so small that it does not lead to disconnection of the protective switching device. All this leads to the danger of electric shock to people and animals and the danger of fires.

The disadvantage of the known methods is their insufficient functionality, due to the fact that they do not allow for the protection of network sections from short circuits with small currents, including due to their supply from distributed generation facilities, and also do not allow for the disconnection of network sections in the event of wire breaks on them, and, therefore, the disadvantage is also the insufficient reliability of the power supply and electrical safety.

The technical task of the proposed invention is to increase the functionality of the methods by providing the ability to protect network sections from short circuits with low currents, including when they are fed from distributed generation facilities, as well as the ability to disconnect network sections in the event of wire breaks on them, increasing the reliability of power supply to consumers and increasing electrical safety.

The technical result is achieved in that in the proposed method for protecting an electric network from short circuits, including low-current short circuits, and wire breaks, consisting in monitoring the current and voltage at the control points of the network, according to the invention, characteristic sequences of changes in the values of currents and voltages are set at the terminal of the centralized power supply source, at the terminal of the distributed generation facility, at the terminals of the multi-contact switching system, at the end of sections of the electric network for cases of short circuits of different types, including low-current short circuits and for wire breaks, which of the switching devices of the centralized power supply source, the distributed generation facility, or which of the contact groups of the multi-contact switching system should be disconnected when a particular specified sequence of changes in currents and voltages is detected, the values of currents and voltages, the sequences of their changes at the said control points are monitored and compared with the specified characteristic ones, and if the monitored sequence coincides with a particular specified characteristic one, disconnection is performed, respectively, the switching device of a centralized power supply source, or a distributed generation facility, or a contact group of a multi-contact switching system, or several of them, thus protecting sections of the electrical network from short circuits with small currents and from wire breaks, while disconnecting only the damaged sections, thereby increasing the reliability of the power supply and electrical safety.

The essence of the proposed method is explained by the drawing (Fig. 1), which shows a block diagram of a device for implementing a method for seasonal backup of electricity supply to consumers connected to one power transmission line (network).

The block diagram contains: terminals of the multi-contact switching system B1, B2, B3; control unit of the multi-contact switching system BUMKS4; contact groups of the multi-contact switching system KG5, KG6, KG7; network control unit BUS8; control unit of the centralized power supply source BUCE9; centralized power supply source CE10; switching device of the centralized power supply source KACE11; control unit of the distributed generation facility BOORG12; distributed generation facility ORG13; switching device of the distributed generation facility KAORG14; current and voltage monitoring units BKTN15, BKTN17; consumers P16, P18; short circuit or wire break points T19, T20; multi-contact switching system MKS21.

The method is implemented as follows using the proposed device.

In BUS8, characteristic sequences of changes in the values of currents and voltages are specified at the terminal of the centralized power supply source, at the terminal of the distributed generation facility, at the terminals of the multi-contact switching system, at the end of sections of the electrical network for cases of short circuits of various types, including short circuits with small currents and for wire breaks, and they specify which of the switching devices, the centralized power supply source, the distributed generation facility, or which of the contact groups of the multi-contact switching system should be disconnected upon detection of one or another specified sequence of changes in currents and voltages.

In BUMKS4, the settings for short-circuit currents of three-phase, two-phase and single-phase are set, upon exceeding which the current at terminals B1, B2, or B3 of the MKS21 must disconnect the contact groups KG5, KG6, or KG7 of the MKS21 upon command from BUMKS4 without waiting for the BUS8 command.

In BOORG12, the settings for short-circuit currents of three-phase, two-phase and single-phase are set, upon exceeding which the current at the terminal of ORG13 must disconnect the switching device KAORG14 on command from BOORG12 without waiting for the command from BUS8.

In BUCE9, the settings for short-circuit currents of three-phase, two-phase and single-phase are set, upon exceeding which the current at the terminal CE10 must disconnect the switching device KACE11 on command from BUCE9 without waiting for the command from BUS8.

Using BUMKS4, the currents and voltages are monitored at terminals B1, B2, or B3 of the MKS21; using BOORG12, the currents and voltages are monitored at terminal ORG13; using BUTSE9, the currents and voltages are monitored at terminal CE10; using BKTN15, the currents and voltages are monitored at the end of the network section between the MKS21 and P16; using BKTN17, the currents and voltages are monitored at the end of the network section between the MKS21 and P18. The monitored values of currents and voltages are transmitted to BUS8. Using BUS8, the sequences of changes in currents and voltages at the specified control points are monitored and compared with the specified characteristic ones.

For example, in case of a single-phase short circuit on the section between MKS21 and P16 (for example, at point T19), the current value in one of the phases on B3, the ORG13 output (short-circuit feeder current), and the CE10 output will simultaneously increase. However, if the short-circuit current is small, less than the single-phase short-circuit current setting specified in BUMKS4, including due to its feeder by ORG13, BUMKS4 will not react to it and will not disconnect KG7. Also, KAORG14 will not disconnect. At the same time, the voltage on one of the phases at the end of the network section between MKS21 and P16 will disappear and a voltage drop of the same phase on B3 and the ORG13 output will occur, the voltage of the same phase at the CE10 output will decrease. Simultaneous increase of current in the same phase on B3, terminal ORG13, terminal CE10, disappearance of voltage of one of the phases at the end of the network section between MKS21 and P16, voltage drop of the same phase on B3 and terminal ORG13, decrease of voltage of the same phase at terminal CE10 are characteristic signs of a single-phase short circuit in the network section between MKS21 and P16 (for example, at point T19). When BUS8 detects such a sequence, it will generate and transmit a command to disconnect KG7 MKS21 and KAORG14 ORG13. The network section between MKS21 and P16 will be disconnected. In this case, P18 will not lose power supply from CE10 due to the on state of KG5 and KG6. Thus, the network section between MKS21 and P16 will be protected from a single-phase short circuit with low current and the reliability of the power supply to P18 will be ensured.

In case of a short circuit of any type (single-, two-, or three-phase) at point T19 the current will be higher than the setting in BUMKS4, then the KG7 will be disconnected by the BUMKS4 command immediately, without waiting for the command from BUS8. Also, KAORG14 will be disconnected, since after KG7 is disconnected, ORG13 will be connected to a short circuit, the KAORG14 disconnection setting specified in BOORG12 will be exceeded.

In case of a break in the wire of one phase in the section between MKS21 and P16 (for example, at point T19), if the break does not lead to a short circuit, the following sequence will be typical: a decrease in the current of one phase on B3, B1, the current of the same phase on the terminal ORG13, the terminal CE10, the disappearance of the voltage of the same phase at the end of the network section between MKS21 and P16 without a decrease in the voltage on this phase on B3, B1 on the terminal ORG13, the terminal CE10. If it is detected, BUS8 will give a command to BUMKS4 to disconnect KG7 and BOORG12 to disconnect KAORG14. This will protect the network section between MKS21 and P16 from a wire break and ensure the reliability of the power supply to P18.

In case of a break in the wire of one phase in the section between MKS21 and P18 (for example, at point T20), if the break does not lead to a short circuit, the following sequence will be typical: a decrease in the current of one phase at B2, B1, terminal CE10, disappearance of the voltage of the same phase at the end of the network section between MKS21 and P18 without a decrease in the voltage on this phase at B3, B1, terminal CE10. If it is detected, BUS8 will give a command to BUMKS4 to disconnect KG6. This will protect the network section between MKS21 and P18 from a wire break and ensure the reliability of the power supply to P16.

In a similar manner, other characteristic sequences of current and voltage changes are set at control points when one, two, or all wires of network sections are broken. When the controlled sequence coincides with one or another specified characteristic sequence, BUS8 generates and transmits a command to BUCE9, BOORG12, or BUMKS4 to disconnect, respectively, KACE11, or KAORG14, or KG5, or KG6, or KG7, or several of the specified switching devices.

In this way, sections of the electrical network are protected from short circuits with small currents and from wire breaks.

The use of the proposed method and device will ensure the protection of network sections from short-circuit currents, including low-current ones, as well as from wire breaks, and will increase the reliability of power supply to consumers and electrical safety.

Claims (1)

A method for protecting an electric network from short circuits, including low-current short circuits, and wire breaks, consisting of monitoring the current and voltage at control points of the network, characterized in that characteristic sequences of changes in the values of currents and voltages are specified at the terminal of a centralized power supply source, at the terminal of a distributed generation facility, at the terminals of a multi-contact switching system, at the end of sections of the electric network for cases of short circuits of different types, including low-current short circuits, and for wire breaks, which of the switching devices of the centralized power supply source, distributed generation facility, or which of the contact groups of the multi-contact switching system should be disconnected when a particular specified sequence of changes in currents and voltages is detected, the values of currents and voltages, the sequences of their changes at the specified control points are monitored and compared with the specified characteristic ones, and if the monitored sequence coincides with a particular specified characteristic one, the switching device of the centralized power supply source, or distributed generation facility, or a contact group of a multi-contact switching system, or several of them, thus protecting sections of the electrical network from short circuits with low currents and from wire breaks, while disconnecting only the damaged sections, thereby increasing the reliability of the power supply and electrical safety.