RU2508585C1 - Protection device against short circuits in dead zone of open distributing devices of electric power engineering sites of high or ultrahigh voltage - in sections between current transformers and switches - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: on a potential of high or ultrahigh voltage for each phase there are two transmitting modules installed on ends of the protected section and connected between themselves with a fibre-optic communication line. On the earth potential there is a retransmission module connected by means of radio channels to both transmitting modules and connected by means of a fibre-optic communication line to a combined control station. Each of the transmitting modules includes a power supply unit, a measuring converter, a modem, a comparison unit and a radio transmitter. The retransmission module is common for transmitting modules of all the phases of the protected section.

EFFECT: simplifying the device and improving its reliability.

11 cl, 1 dwg

Description

The invention relates to relay protection (RE) against short circuits (KZ) in the “dead zones” (MZ) (RZMZ) between current transformers and circuit breakers in open switchgears (outdoor switchgear) of power plants and substations with outgoing high-voltage power transmission lines of high (110, 220 ) and ultrahigh (330 ÷ 750 kV) voltage (VN and VVN).

Known technical solutions for the implementation of RE from short-circuit in power transmission areas using actuators included in the differential circuit using non-traditional current transformers, in particular optoelectronic current transformers based on Faraday elements, which transform the angle of rotation of the plane of polarization of light under the influence of the magnetic field of current and signal generation to turn off the damaged area with a sharp change in the resulting angle of rotation of the plane of polarization of light in the optical path (JP 60236073 A, G01R 31/08, 11/22/1985; JP 60013262 A, G01R 15/24, 01/23/1985; JP 60236073 A, G01R 31/08, 11/22/1985; EP 0452218 A2, G01R 31 / 08.16.10.1991; DE 19630989 A1, G01R 15/24, 02/05/1998).

Of the technical solutions with the indicated principle of operation, the closest to the proposed one is a device adapted for protection against short circuit in the MV of the open switchgear of electric power facilities of high voltage or high voltage, according to patent RU 2446534 C1, H02H 3/28, 03/27/2012. The known device contains on the ground potential for each phase of each protected section a local module, which includes a polarized light source and a current differential protection block installed on different sides of the optical path, as well as a command and blocking signal generation unit, the input of which is connected to the outputs of the current block differential protection, a central protection module, the inputs of which are connected to the outputs of the local modules of all sections of the MV, and the outputs are connected to the tripping circuits of the corresponding circuit breakers, blocking high-speed protection of adjacent elements and the start of the device failover redundancy circuit breakers. There are two Faraday elements at the HV or IH potential, which are included at the beginning and end of the protected transmission section with the possibility of rotation of the plane of polarization of light in the optical path with opposite signs with a unidirectional current. Moreover, the said current differential protection unit is capable of converting the resulting angle of rotation of the plane of polarization into a voltage value, its analog-to-digital conversion, and comparison with the current setting.

The known device provides an acceleration of disconnection of short circuit in the MOH while maintaining the dynamic stability of power units and the power system as a whole. However, its drawback is associated with the need to use optical isolators, the installation of which in all MHs in the amount of three pieces per MH determines a significant decrease in the overall reliability of the primary switchgear circuit.

The objective of the invention is to improve such a protective device with a simplification of its design and ensuring the reliable operation of outdoor switchgear.

To solve this problem and achieve the specified technical result, a device is proposed for protection against high-voltage or extra-high voltage electric power facilities in the MOH outdoor switchgear - in the areas between current transformers and circuit breakers, containing on the potential of a HV or IHV for each phase two transmitting modules installed at the ends of the protected section and interconnected by the first fiber-optic communication line (FOCL), and on the ground potential - the receiver module, connected by radio channels with both transmitting module and a second FOCL connected to a combined control center, each of the transmitting modules comprising a power supply unit, a measuring transducer consisting of a current sensor and a zero indicator connected in series, a modem consisting of an electro-optical transducer and an optical-electric transducer, a comparison unit and a radio transmitter moreover, the current sensor is configured to receive signals of instantaneous values of the phase current, and a zero indicator - with the possibility of fixing their positive or negative s aka, the output of the null indicator is connected to the input of the electro-optical converter and the first input of the comparison unit, the output of the opto-electric converter is connected to the second input of the comparison unit, and the output of the comparison unit is connected to the input of the radio transmitter, the first FOCL is multi-core and has one core at each of its ends connected to the output of the electro-optical converter, and other wires to the input of the optical-electric converter of the corresponding modem, the retransmission module is common to the transmitting modules of all AZ of the protected area and contains a power supply unit and a series-connected radio receiver and electro-optical converter, the second FOCL is connected between the output of the electro-optical converter of the retransmission module and the matching module of the combined control center.

The solution of the problem and the achievement of the specified technical result contribute to the private essential features of the invention.

The transmitting module is designed to maintain operability under electromagnetic influences at the installation site, characteristic of currents and voltages, for which the primary equipment of open switchgears and its isolation are designed, including fields created by corona discharges, and fields created by pulsed currents during thunderstorms and switching overvoltages.

The power supply unit of each of the transmitting modules includes a power take-off transformer from the phase wire, an energy storage element, a stabilizing unit, and is made with a ready-to-use time t _{goth. A power supply unit} ≤2 ms when a current appears with an effective value ≥200 A.

In the measuring transducer, the null indicator is designed as a comparator that works when the current sign changes through the current sensor.

The electro-optical converter of each of the transmitting modules includes an LED light source.

The comparison unit for each of the transmitting modules is configured to generate a command signal "short circuit in the" dead "zone if the signals at its inputs characterizing the instantaneous current values have different signs for a time greater than 2.0-3.0 ms

The first FOCL is made with four fiber optic cores, while the signals of positive and negative current polarity generated by each of the electro-optical converters are transmitted through different cores. The first FOCL is laid inside the conductor, performing the functions of a lightning protection cable.

The re-reception module is located on the ground potential under the wires of the “dead” zone in the area of the local circuit breaker control cabinet.

The power supply unit of the receiver module is connected to the operational direct current network of the SOPT and includes an energy storage element and a stabilizing unit.

The coordination module of the integrated control room is configured to coordinate the operation of the device with the traditional relay protection and automation system (RPA), as well as to determine the shutdown logic for several “dead” zones of the open switchgear and is a cabinet mounted on the relay panel of the integrated control center.

Figure 1 presents the functional diagram of the proposed device for protection against short circuit in the Ministry of Health of the outdoor switchgear of power facilities VN or IHV - in the areas between current transformers and switches.

The diagram shows a switch (Q) 1, a current transformer (TA) 2, and a protected section 3 with a split phase wire. The device contains at the HV or SRS potential for each phase transmitting modules 4.1 and 4.2, installed at the ends of the protected section 3 and interconnected by the first FOCL 5, and at the ground potential - a receiving module 6, connected by radio channels to the transmitting modules 4.1 and 4.2 and connected to the second FOCL 7 with a combined control point 8. Each of the transmitting modules 4.1 (4.2) contains a power supply unit 9.1 (9.2), a measuring transducer 10.1 (10.2), consisting of a series-connected current sensor 11.1 (11.2) and a null indicator 12.1 (12.2), a modem 13.1 (13.2), consisting of an electro-optical transducer 14.1 (14.2) and an electro-optical transducer 15.1 (15.2), a comparison unit 16.1 (16.2) and a transmitter (radio or ultrasound) 17.1 (17.2). The current sensor 11.1 (11.2) is configured to receive signals of instantaneous values of the phase current, and a null indicator 12.1 (12.2) - with the possibility of fixing their positive or negative sign. The output of the null indicator 12.1 (12.2) is connected to the input of the electro-optical converter 14.1 (14.2) and the first input of the comparison unit 16.1 (16.2). The output of the optoelectric transducer 15.1 (15.2) is connected to the second input of the comparison unit 16.1 (16.2), and the output of the comparison unit 16.1 (16.2) is connected to the input of the transmitter (radio or ultrasound) 17.1 (17.2). FOCL 5 is multicore and at each of its ends it is connected by one core to the output of the electro-optical converter 14.1 (14.2), and by other wires - to the input of the optical-electrical converter 15.1 (15.2) of the modem 13.1 (13.2). Reception module 6 is common for transmitting modules 4.1 and 4.2 of all phases of the protected section 3 and contains a power supply unit 18 and serially connected receiver (radio or ultrasound) 19 and an electro-optical converter 20. The second FOCL 7 is connected between the output of the electro-optical converter 20 of the re-reception module 5 and module 21 approval of the combined paragraph 8 of the control.

Each of the transmitting modules 4.1 and 4.2 is made with the possibility of maintaining operability under electromagnetic influences at the installation site, characteristic of currents and voltages for which the primary switchgear equipment and its isolation are designed, including fields created by corona discharges, and fields created by pulsed currents during lightning and switching overvoltages. All the components of the transmitting modules 4.1 and 4.2 are located in a special housing that protects them from environmental influences and electromagnetic fields.

The power supply unit 9.1 (9.2) of the transmitting module 4.1 (4.2) includes a power take-off transformer from a phase wire, an energy storage element, a stabilizing unit (not shown) and is made with a ready-to-use time t _{goth. A power supply unit} ≤2 ms when a current appears with an effective value ≥200 A.

In the measuring transducer 10.1 (10.2) of the transmitting module 4.1 (4.2) there is a current sensor 11.1 (11.2), and the zero indicator 12.1 (12.2) is designed as a comparator that works when the current sign flows through the current sensor 11.1 (11.2).

The electro-optical converter 14.1 (14.2) of the transmitting module 4.1 (4.2) includes an LED light source (not shown).

Block 16.1 (16.2) comparing the transmitting module 4.1 (4.2) is made with the possibility of generating a signal-command "KZ in MZ" in the event that the signals at its inputs characterizing the instantaneous current values have different signs for a time greater than 2.0 - 3 , 0 ms.

The first FOCL 5 is made with four fiber optic cores, while the signals of positive and negative polarity of the current generated by each of the electro-optical converters 14.1 and 14.2 are transmitted through different cores. FOCL 5 is laid outside or inside one of the conductors of the protected "dead" zone.

Reception module 6 is located on the ground potential under the wires of the “dead” zone in the area of the local control cabinet of circuit breaker 1. In the case of using an ultrasonic communication channel, the ultrasonic receivers are mounted on the design of the electrical apparatus of the circuit breaker (1) and current transformer (2) on the ground potential and are connected to re-reception module (6) conductors.

The power supply unit 18 of the re-reception module 6 is connected to the SOPT network and includes an energy storage element and a stabilizing unit (not shown).

The coordination module 21 of the integrated control point 8 is configured to coordinate the operation of this device with a traditional relay protection and automation system, as well as determine the shutdown logic for several MOH outdoor switchgears and is a cabinet installed on the relay panel of the combined control point 8.

The operation of the proposed device is based on the principle of differential-phase protection, where the manipulation values are the fact that the phase of the primary current passes through "0".

In the event of a fault outside the protected zone, signals from current sensors 11.1 and 11.2 show the same direction of currents. Zero indicators 12.1 and 12.2 generate unipolar signals, which are converted by means of electro-optical converters 14.1 and 14.2 into optical signals transmitted via FOCL 5 to optical-electric converters 15.1 and 15.2. The electrical signals from the outputs of the null indicators 12.1 and 12.2 and the optoelectric converters 15.1 and 15.2 also have the same signs, and therefore no signals are issued at the outputs of the comparison units 16.1 and 16.2. With a fault inside the protected zone, signals from current sensors 11.1 and 11.2 show different phases of currents. Blocks 16.1 and 16.2 comparing the transmitting modules 4.1 and 4.2 are formed, and radio transmitters 17.1 and 17.2, equipped with directional antennas, transmit informative signals to the ground potential about the presence of a fault in the area limited by the installation locations of the transmitting modules 4.1 and 4.2. Note that the protection generates a “short circuit to MZ” signal when the manipulation values do not match more than 3 ms. After this time, a signal is formed to turn off the damaged element. The specified time delay also allows you to rebuild the protection against noise in the used radio channels.

If the short circuit is powered on only one side, then the key point is the sign of an emergency current and / or the corresponding signal from the RE of adjacent elements - a secondary sign in the operation of the REZ together with the REA complex of the electric power facility.

The non-selective operation of the RZMZ in operating modes is prevented by the choice of the device operation settings.

Reception module 6 by means of the radio 19 collects information from the radio transmitters 17.1 and 17.2 of all transmitting modules 4.1 and 4.2 MOH (2 pcs. Per phase, only 6 pcs.). After conversion in the electro-optical converter 20, information is transmitted via FOCL 7 to the receiving terminal, namely to the coordination module 21 of the combined control point 8. The coordination module 21 determines the shutdown logic for several MOH outdoor switchgear.

It is recommended to integrate the proposed RZMZ device into the existing RZ complex in several stages, the main of which in the following sequence are:

1. The effect of rare-earth metals on the signal during short-circuit in the "dead" zone. The current flowing through adjacent current transformers is also monitored by means of protective measuring elements of adjacent elements.

2. RZMZ works to accelerate the shutdown of the damaged element, while the undamaged non-selectively disconnected element is also turned off. The current flowing through adjacent current transformers is also monitored by means of protective measuring elements of adjacent elements. In fact, the protection acts as an accelerator of a circuit breaker failure reservation device (CBD).

3. RZMZ disconnects the damaged element, while the protection of the adjacent intact element is blocked. The shutdown signal is generated only if there is a short-circuit current through the measuring organs of the protection of adjacent intact elements.

4. RZMZ disconnects the damaged element, while blocking the protection of the adjacent intact element. The trip signal is generated independently of the adjacent protections. RZMZ takes on the form of independent defense.

The minimum requirements for solving the problem are associated with ensuring the functioning of the RZMZ at the second stage of the above, which ensures the preservation of dynamic stability by reducing the time of elimination of faults.

Claims (12)

1. Device for protection against short circuits in the "dead" zone of open switchgear of high or extra-high voltage electric power facilities - in the areas between current transformers and circuit breakers, containing at the potential of high or extra-high voltage for each phase two transmitting modules installed at the ends of the protected area and interconnected by a first fiber-optic communication line, and on the ground potential, a re-reception module connected by radio or ultrasonic channels to both transmitting modules and connected by a second fiber-optic communication line to the integrated control center, each of the transmitting modules contains a power supply unit, a measuring transducer consisting of a series-connected current sensor and a zero indicator, a modem consisting of an electro-optical transducer and an optical-electric transducer , a comparison unit and a radio or ultrasonic transmitter, wherein the current sensor is configured to receive signals of instantaneous phase current values, and a null indicator p - with the possibility of fixing their positive or negative sign, the output of the null indicator is connected to the input of the electro-optical converter and the first input of the comparison unit, the output of the opto-electric converter is connected to the second input of the comparison unit, and the output of the comparison unit is connected to the input of the radio transmitter, the first the optical communication line is multi-strand and at each of its ends it is connected by some wires to the output of the electro-optical converter, and by other wires - to the input of the electro-optical converter of the corresponding modem, the re-reception module is common for transmitting modules of all phases of the protected area and contains a power supply unit and a radio- or ultrasonic receiver and an electro-optical transducer connected in series, a second fiber-optic communication line is connected between the output of the electro-optical converter of the re-reception module and the matching module of the combined control center . 2. The device according to claim 1, characterized in that each of the transmitting modules is configured to maintain operability under electromagnetic influences at the installation site, characteristic of currents and voltages, for which the primary equipment of open switchgears and its isolation are designed, including fields created by corona discharges, and fields created by pulsed currents during lightning and switching overvoltages. 3. The device according to claim 1, characterized in that the power supply unit of each of the transmitting modules includes a power take-off transformer from a phase wire, an energy storage element, a stabilizing unit, and is made with a ready-to-use time t _{goth. A power supply unit} ≤2 ms when current with effective value ≥200 A. 4. The device according to claim 1, characterized in that in the measuring transducer of each of the transmitting modules there is a zero indicator, designed as a comparator, working when the current sign changes through the current sensor. 5. The device according to claim 1, characterized in that the electro-optical converter of each of the transmitting modules includes an LED light source. 6. The device according to claim 1, characterized in that the unit for comparing each of the transmitting modules is configured to generate a command signal "short circuit in the" dead "zone if the signals at its inputs characterizing the instantaneous current values have different characters for a time greater than 3.0 ms. 7. The device according to claim 1, characterized in that the first fiber-optic communication line is made with four optical fiber cores, while the signals of positive and negative current polarity generated by each of the electro-optical converters are transmitted through different cores. 8. The device according to claim 7, characterized in that the first fiber-optic communication line is laid inside a conductor that performs the functions of a lightning protection cable. 9. The device according to claim 1, characterized in that the re-reception module is located on the ground potential under the wires of the "dead" zone in the area of the local switch cabinet. 10. The device according to claim 1, characterized in that the power supply unit of the receiver module is connected to the network operating direct current (SOPT) and includes an energy storage element and a stabilizing unit. 11. The device according to claim 1, characterized in that the coordination module of the combined control point is configured to coordinate the operation of the device with the traditional relay protection and automation system, as well as to determine the shutdown logic for several "dead" zones of the open switchgear, and is a cabinet mounted on the relay panel of the integrated control center. 12. The device according to claim 1, characterized in that the transmitters and receivers of the ultrasonic channels are located under the potential of the HV or SRS and under the ground potential, respectively.