JP2019213352A - Protection control device - Google Patents

Abstract

To provide a protection control device capable of changing from 2 out of 3 configuration to 1 out of 2 configuration more easily, upon occurrence of abnormality in one of three protective relays.SOLUTION: A protection control device comprises first through third protective relays for protecting a power system, and an output circuit outputting a command signal for opening a circuit breaker, on the basis of control signals from the first through third protective relays. The output circuit includes first through third circuits connected in parallel with one another. When at least two out of the first through third protective relays operate, any one of the first through third circuits outputs a command signal. Even if abnormality occurs in the first protective relay, any one of the second and third circuits outputs the command signal, when at least one of the second and third protective relays operates.SELECTED DRAWING: Figure 5

Description

  The present disclosure relates to a protection control device for protecting a power system.

  Conventionally, a protection control device that detects an accident or abnormality occurring in a power system has been used. In order to improve the reliability of the protection control device, for example, a protection control device having a 2 out of 3 configuration is often used in which an output is determined by performing a majority process of three protection relay calculation results. The majority process such as 2 out of 3 configuration is also used for inspection of a reactor protection system that requires high reliability.

  For example, Japanese Patent Laid-Open No. 62-228979 (Patent Document 1) discloses an inspection device for a reactor protection system. The logic circuit included in the reactor protection system performs, for example, 2 out of 3 logic processing, and when a real signal is input to two of the three input terminals, the logic signal is output to the next stage 1 out of N circuit.

JP-A-62-228979

  However, Patent Document 1 relates to a multiplexing circuit inspection device, and when one of the three devices realizing a 2 out of 3 logic circuit becomes defective, the remaining normal devices are used. Thus, there is no teaching or suggestion of a configuration for realizing a 1 out of 2 logic circuit.

  An object of an aspect of the present disclosure is to provide a protection control device that can be more easily changed from a 2 out of 3 configuration to a 1 out of 2 configuration when an abnormality occurs in one of the three protection relays. Is to provide.

  According to an embodiment, a protection control device for protecting a power system is provided. The protection control device uses a quantity of electricity acquired from the power system, and controls signals from the first to third protection relays that perform a protection operation for protecting the power system, and the first to third protection relays. And an output circuit for outputting a command signal for opening a circuit breaker provided in the power system. The output circuit includes first to third circuits connected in parallel to each other. When at least two protection relays of the first to third protection relays are operated, any one of the first to third circuits is configured to output a command signal. Even if an abnormality has occurred in the first protective relay, if at least one of the second and third protective relays operates, one of the second and third circuits This circuit is configured to output a command signal.

  According to the present disclosure, when an abnormality occurs in one of the three protection relays, it is possible to more easily change from the 2 out of 3 configuration to the 1 out of 2 configuration.

It is a figure which shows the structural example of the protection control system according to Embodiment 1. FIG. FIG. 3 is a diagram showing an example of a hardware configuration of a protective relay according to the first embodiment. It is a figure which shows the output circuit according to a comparative example. It is a figure which shows the switching control system of a contact according to a comparative example, and b contact. FIG. 3 is a diagram showing an output circuit according to the first embodiment. FIG. 6 is a diagram showing an output circuit according to a second embodiment. It is a figure which shows the opening / closing control system of a contact according to Embodiment 2, and b contact. It is a figure for demonstrating the function structure of the protection relay according to Embodiment 2. FIG. It is a figure for demonstrating the output state of the control signal at the time of giving an operation signal to the protection relay according to Embodiment 2. FIG. It is a figure which shows the open / close state of each contact according to the output state in FIG. FIG. 10 is a diagram showing an output circuit according to a third embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following description, the same parts are denoted by the same reference numerals. Their names and functions are also the same. Therefore, detailed description thereof will not be repeated.

Embodiment 1 FIG.
<Overall configuration>
FIG. 1 is a diagram showing a configuration example of a protection control system 1000 according to the first embodiment. The protection control system 1000 is a system for protecting a power system (for example, a transmission line) using the protection control device 150.

  Referring to FIG. 1, protection control system 1000 includes a protection control device 150, a circuit breaker 50, and a power supply 80.

  The circuit breaker 50 is provided in the power system, and is opened to protect the power system when an accident occurs in the power system. Specifically, the circuit breaker 50 is opened by receiving a voltage input from the power supply 80. The voltage input from the power supply 80 corresponds to a command signal for opening the circuit breaker 50 (that is, a trip command).

  The protection control device 150 is a digital type protection relay device, and is installed, for example, inside an electric station. The protection control device 150 collects a current and a voltage (that is, an amount of electricity) related to electrical equipment such as a power transmission line, a bus, and a transformer, and protects and controls the power system based on the collected amount of electricity. Typically, in addition to the protection control device 150, a transformer, an instrument current transformer, an instrument transformer, and the like are installed inside the electric station.

  The protection control device 150 includes three protection relays 101, 102, 103 and an output circuit 40. In the following, when a configuration and a function common to each of the protective relays 101, 102, and 103 are described, they are collectively referred to as a “protective relay 100”.

  The protective relay 100 acquires the current measured by the instrument current transformer and the voltage measured by the instrument transformer. The protection relay 100 executes a protection calculation (for example, relay calculation) necessary for protecting the power system using the collected amount of electricity, and determines whether a system fault has occurred. When it is determined that an accident has occurred in the power system, the protective relay 100 causes the output circuit 40 to output a trip command. When only one of the current and the voltage is used for the protection calculation, the protection relay 100 may be configured to capture a current or voltage necessary for the protection calculation.

  The output circuit 40 includes a plurality of contacts that are controlled to open and close based on a control signal from each protection relay 100. The output circuit 40 outputs a trip command for opening the circuit breaker 50 based on a control signal from each protective relay 100 when an accident occurs in the power system. Specifically, the output circuit 40 provides a voltage input (that is, a trip command) from the power supply 80 to the circuit breaker 50 by closing a plurality of contacts in accordance with a control signal from each protection relay 100. A specific configuration of the output circuit 40 will be described later.

<Hardware configuration>
FIG. 2 is a diagram showing an example of a hardware configuration of protection relay 100 according to the first embodiment. Referring to FIG. 2, the protective relay 100 includes an auxiliary transformer 70, an AD (Analog to Digital) converter 72, a CPU 91, a RAM 92, a ROM 93, a DI circuit 94, and an input interface (IF) 95. , A communication interface (IF) 96 and a DO unit 98. These are connected by a bus 99.

  The auxiliary transformer 70 converts the amount of electricity taken from the instrument current transformer and the instrument transformer into a voltage suitable for the relay internal circuit and outputs it to the protective relay 100.

  The AD converter 72 takes in the voltage output from the auxiliary transformer 70 and converts it into digital data. Specifically, the AD conversion unit 72 includes an analog filter, a sample and hold circuit, a multiplexer, and an AD converter.

  The analog filter removes high-frequency noise components from the current and voltage waveform signals output from the auxiliary transformer 70. The sample-and-hold circuit samples the current and voltage waveform signals output from the analog filter at a predetermined sampling period. Based on the timing signal input from the CPU 91, the multiplexer sequentially switches the waveform signal input from the sample hold circuit in time series and inputs it to the AD converter. The AD converter converts the waveform signal input from the multiplexer from analog data to digital data. The AD converter outputs the digitally converted waveform signal (digital data) to the CPU 91.

  The CPU 91 controls the protective relay 100 by reading and executing a program stored in the ROM 93 in advance. The ROM 93 stores various information used by the CPU 91. The CPU 91 is, for example, a microprocessor. The hardware may be an FPGA (Field Programmable Gate Array) other than the CPU, an ASIC (Application Specific Integrated Circuit), a circuit having other arithmetic functions, or the like.

  The CPU 91 sequentially stores digital data from the AD conversion unit 72 in the RAM 92 via the bus 99. The CPU 91 reads necessary digital data from the RAM 92 according to a program stored in the ROM 93, performs a protection operation using the read digital data, and determines whether or not there is an accident in a protection section (for example, a power transmission line). That is, the CPU 91 performs the operation determination of the protective relay 100.

  In a certain situation, when the CPU 91 detects an accident (for example, when the calculated value exceeds the set value), the CPU 91 applies a contact to the contact of the output circuit 40 via the DO unit 98 to protect the protection section. Output a control signal.

  For example, the DI circuit 94 receives a signal indicating the open / close state of the circuit breaker 50. In the example of FIG. 2, a configuration with one DI circuit 94 will be described, but the configuration is not limited thereto. The protective relay 100 may have a configuration having a plurality of DI circuits.

  The DO unit 98 includes DO circuits 98_1 to 98_N. The DO circuits 98_1 to 98_N give (ie, output) the control signals D1 to Dn to the plurality of contacts included in the output circuit 40, respectively. In other words, each of the DO circuits 98_1 to 98_N outputs a control signal to a contact associated with the DO circuit.

  The input interface 95 is typically various buttons and receives various operations from the system operator. Further, the CPU 91 transmits / receives various information to / from other protective relay 100 or other external devices via the communication interface 96.

<Configuration of output circuit>
(Comparative example)
A comparative example of the output circuit 40 will be described with reference to FIGS. 3 and 4. FIG. 3 is a diagram showing an output circuit 40 according to the comparative example. Specifically, FIG. 3A shows the output circuit 40 when the three protective relays 100 are normal. FIG. 3B shows the output circuit 40 when the protective relay 101 is abnormal and the protective relays 102 and 103 are normal. FIG. 4 is a diagram illustrating an a / b contact switching control system according to a comparative example.

  Referring to FIG. 3, output circuit 40 according to the comparative example includes a contact circuit 200 and a contact circuit 300. The contact circuit 200 and the contact circuit 300 are connected in parallel.

  Contact circuit 200 includes series circuits 201, 202, and 203 connected in parallel to each other. Series circuit 201 includes a contact 11a and a contact 21a connected in series with each other. Series circuit 202 includes a contact 22a and a contact 31a connected in series with each other. Series circuit 203 includes a contact 32a and a contact 12a connected in series with each other.

  Contact circuit 300 includes series circuits 301, 302, and 303 connected in parallel to each other. The series circuit 301 includes a parallel circuit 311 in which the b contact 21 b and the b contact 31 b are connected in parallel, and an a contact 13 a connected in series to the parallel circuit 311. The series circuit 302 includes a parallel circuit 312 in which the b contact 11 b and the b contact 32 b are connected in parallel, and an a contact 23 a connected in series to the parallel circuit 312. The series circuit 303 includes a parallel circuit 313 in which the b contact 12 b and the b contact 22 b are connected in parallel, and an a contact 33 a connected in series to the parallel circuit 313.

  The DO unit 98 of the protective relay 101 closes these a contacts by giving a control signal to the a contacts 11a, 12a, and 13a. The DO unit 98 of the protective relay 101 opens these b contacts by giving a control signal to the b contacts 11b and 12b.

  The DO unit 98 of the protective relay 102 closes these a contacts by supplying a control signal to the a contacts 21a, 22a, and 23a. The DO unit 98 of the protective relay 102 opens these b contacts by giving a control signal to the b contacts 21b and 22b.

  The DO unit 98 of the protective relay 103 closes these a contacts by giving a control signal to the a contacts 31a, 32a, 33a. The DO unit 98 of the protective relay 103 opens these b contacts by giving a control signal to the b contacts 31b and 32b.

  Specifically, each protection relay 100 controls the opening and closing of the a contact and the b contact as shown in FIG. Referring to FIG. 4, when protective relay 100 is normal and operates, contact a is closed and contact b is opened. When the protective relay 100 is normal and is not operating, the contact a and contact b are opened. When the protective relay 100 is abnormal, the contact a is opened and the contact b is closed.

  Specifically, the protection relay 100 outputs a control signal to the contact a when it is determined that an accident has occurred in the power system by a protection calculation in a normal state (for example, the apparatus power supply is normal). Therefore, the contact a is in a closed state (corresponding to “Close” in FIG. 4).

  On the other hand, the protection relay 100 does not output a control signal to the contact a when it is determined that no accident has occurred in the power system at the normal time (that is, when it is determined that the protection relay 100 is not operated). Therefore, the contact a is in an open state (corresponding to “Open” in FIG. 4). Further, since the control signal is not output when the protective relay 100 is abnormal (for example, the apparatus power supply is abnormal), the contact a is opened.

  Note that the protective relay 100 normally outputs a control signal to the b contact regardless of the result of the protection operation (that is, regardless of whether the protective relay 100 operates or not), so that the b contact is opened. To. On the other hand, since the control signal is not output when the protective relay 100 is abnormal, the b-contact is closed.

  With reference to FIG. 3 again, the flow in which the trip command is output from the output circuit 40 will be described. Referring to FIG. 3A, when the three protective relays 100 are normal, each b contact 11b, 12b, 21b, 22b, 31b, 32b is always supplied with a control signal, and each b The contact is opened. Therefore, the trip command is not output from the contact circuit 300. In this case, the contact circuit 200 constitutes a 2 out of 3 circuit that outputs a trip command when at least two of the three protective relays 100 operate.

  Specifically, when the protective relays 101 and 102 operate, the series circuit 201 outputs a trip command (that is, the trip command is given to the circuit breaker 50), and when the protective relays 102 and 103 operate. When the series circuit 202 outputs a trip command and the protective relays 103 and 101 operate, the series circuit 203 outputs a trip command.

  Here, when an abnormality occurs in the protective relay 101, as shown in FIG. 3B, the a contacts 11a, 12a, 13a are opened, and the b contacts 11b, 12b are closed. In this case, the contact circuit 300 constitutes a 1 out of 2 circuit that outputs a trip command when at least one of the protective relays 102 and 103 operates. Specifically, when the protective relay 102 operates, the series circuit 302 outputs a trip command, and when the protective relay 103 operates, the series circuit 303 outputs a trip command. When protective relays 102 and 103 are operated, series circuit 202, series circuit 302, and series circuit 303 output a trip command.

(Configuration example according to Embodiment 1)
According to the comparative example described above, the contact circuit 200 that is a 2 out of 3 circuit and the contact circuit 300 that is a 1 out of 2 circuit when an abnormality occurs in one of the three protective relays 100 are simply arranged in parallel. It has a connected configuration. Therefore, the number of contacts provided in the output circuit 40 increases. In the configuration example according to the first embodiment, a configuration in which the number of contacts is reduced as compared with the comparative example will be described.

  FIG. 5 shows output circuit 40 according to the first embodiment. Specifically, FIG. 5A shows the output circuit 40 when the three protective relays 100 are normal. FIG. 5B shows the output circuit 40 when the protective relay 101 is abnormal and the protective relays 102 and 103 are normal. The switching control method for the a contact and the b contact in the configuration example according to the first embodiment is the same as the switching control method shown in FIG.

  Referring to FIG. 5, output circuit 40 according to the first embodiment includes a contacts 11a and 12a and b contacts 11b and 12b that are controlled to be opened and closed by protective relay 101, and a contacts 21a that are controlled to be opened and closed by protective relay 102. 22a and b contacts 21b and 22b, and a contacts 31a and 32a and b contacts 31b and 32b controlled to be opened and closed by the protective relay 103.

  The output circuit 40 includes series circuits 401, 402, and 403 connected in parallel to each other. The series circuit 401 includes a parallel circuit 411 in which the a contact 22a, the b contact 21b, and the b contact 31b are connected in parallel, and an a contact 11a connected in series to the parallel circuit 411. Series circuit 402 includes a parallel circuit 412 in which a contact 32a, b contact 32b and b contact 11b are connected in parallel, and a contact 21a connected in series to parallel circuit 412. Series circuit 403 includes a parallel circuit 413 in which a-contact 12a, b-contact 12b and b-contact 22b are connected in parallel, and a-contact 31a connected in series to parallel circuit 413.

  Referring to FIG. 5A, when the three protective relays 100 are normal, the b contacts 11b, 12b, 21b, 22b, 31b, and 32b are opened. In this case, the output circuit 40 constitutes a 2 out of 3 circuit. Specifically, when at least two of the three protective relays 100 are operated, any one of the series circuits 401 to 403 is configured to output a trip command.

  Specifically, when each protection relay 101, 102 is operated, each a contact 21a, 22a is closed, so that the series circuit 401 outputs a trip command. When the protective relays 102 and 103 are operated, the a contacts 21a and 32a are closed, and the series circuit 402 outputs a trip command. When the protective relays 103 and 101 are operated, the a contacts 31a and 12a are closed, so that the series circuit 403 outputs a trip command. When each protection relay 101-103 operates, each a contact 12a, 21a, 31a is closed, so that each series circuit 401-403 outputs a trip command.

  If the protective relay 100 is normal at the time of occurrence of an accident in the power system, the CPU 91 determines that an accident has occurred in the power system by the protection calculation (that is, determines that the protective relay 100 is to be operated). ), And output a control signal to the contact a. Therefore, when at least two protection relays of the three protection relays 100 can be normally determined when a power system fault occurs, any one of the series circuits 401 to 403 is tripped. Outputs a command.

  On the other hand, when an abnormality has occurred in the protective relay 101, as shown in FIG. 5B, the a contacts 11a and 12a are opened, and the b contacts 11b and 12b are closed. In this case, the output circuit 40 constitutes a 1 out of 2 circuit. Specifically, even when an abnormality has occurred in the protective relay 101, if at least one protective relay of the two protective relays 102 and 103 is activated, the series circuits 402 and 403 Is configured to output a trip command.

  Specifically, since the contact a 21a is closed when the protective relay 102 is operated, the series circuit 402 outputs a trip command, and when the protective relay 103 is operated, the contact a 31a is closed. Therefore, the series circuit 403 outputs a trip command. When the protective relays 102 and 103 are operated, the series circuits 402 and 403 output a trip command.

  According to the first embodiment, when an abnormality occurs in one of the three protection relays, the protection control device 150 can be automatically changed from the 2 out of 3 configuration to the 1 out of 2 configuration. In the comparative example, three a contacts and three b contacts are required for each protective relay 100. However, in Embodiment 1, the number of a contacts is two and b contacts for each protective relay 100. Two is sufficient. Therefore, in Embodiment 1, the number of contacts can be reduced as compared with the comparative example.

Embodiment 2. FIG.
In the second embodiment, a configuration example of the output circuit 40 different from the first embodiment will be described. Specifically, in the second embodiment, a configuration in which the number of contacts is further reduced than the configuration of the output circuit 40 according to the first embodiment will be described. <Overall configuration> and <Hardware configuration> according to the second embodiment are the same as those in the first embodiment.

<Configuration of output circuit>
FIG. 6 shows an output circuit 40 according to the second embodiment. Specifically, FIG. 6A shows the output circuit 40 when the three protective relays 100 are normal. FIG. 6B shows the output circuit 40 when the protective relay 101 is abnormal and the protective relays 102 and 103 are normal. FIG. 7 is a diagram showing an a-contact and b-contact open / close control method according to the second embodiment.

  Referring to FIG. 6, output circuit 40 according to the second embodiment includes a contact 11a and b contacts 11b and 12b that are controlled to open / close by protective relay 101, and a contact 21a and b contact that is controlled to open / close by protective relay 102. 21b and 22b, and a contact 31a and b contacts 31b and 32b controlled to be opened and closed by the protective relay 103.

  The output circuit 40 includes series circuits 501, 502, and 503 connected in parallel to each other. The series circuit 501 includes a parallel circuit 511 in which the b contact 21b and the b contact 31b are connected in parallel, and an a contact 11a connected in series to the parallel circuit 511. Series circuit 502 includes a parallel circuit 512 in which b contact 32b and b contact 11b are connected in parallel, and a contact 21a connected in series to parallel circuit 512. The series circuit 503 includes a parallel circuit 513 in which the b contact 12b and the b contact 22b are connected in parallel, and an a contact 31a connected in series to the parallel circuit 513.

  Each protection relay 100 controls the opening and closing of the a contact and the b contact as shown in FIG. The a-contact opening / closing control method shown in FIG. 7 is the same as the a-contact opening / closing control method shown in FIG. That is, when the protective relay 100 is normal, the protective relay 100 outputs a control signal to the a contact during operation, closes the a contact, and opens a contact without outputting a control signal to the a contact during non-operation. Let When the protective relay 100 is abnormal, no control signal is output, so the contact a is open.

  On the other hand, the b contact open / close control method is different from the control method described in FIG. When the protective relay 100 is normal and operates, the b contact is closed, and when the protective relay 100 is normal and non-operating, the b contact is open. When the protective relay 100 is abnormal, the b contact is closed.

  Specifically, the protection relay 100 outputs the control signal b even when it is determined that an accident has occurred in the power system by the protection calculation (that is, when it is determined that the protection relay 100 is to be operated) during normal operation. Does not output to the contact. Thereby, b contact will be in a closed state. On the other hand, the protection relay 100 outputs a control signal to the b-contact when it is determined that an accident has not occurred in the power system by the protection calculation at the normal time. Thereby, b contact will be in an open state. In addition, since the control signal is not output when the protective relay 100 is abnormal, the b-contact is closed.

  In the second embodiment, when the protective relay 100 is normal, the b contact is closed during operation, and the b contact is opened during non-operation. Therefore, the output circuit 40 shown in FIG. 6A constitutes a 2 out of 3 circuit that outputs a trip command when at least two of the three protective relays 100 are operated, It is composed.

  Specifically, when the protective relays 101 and 102 operate, the a contact 11a and the b contact 21b are closed, and the series circuit 501 outputs a trip command. When the protective relays 102 and 103 are operated, the a contact 21a and the b contact 32b are closed, and the series circuit 502 outputs a trip command. When the protective relays 103 and 101 are operated, the a contact 31a and the b contact 12b are closed, and the series circuit 503 outputs a trip command. When the protective relays 101, 102, and 103 operate, the series circuits 501 to 503 output a trip command.

  If the protective relay 100 is normal when an accident occurs in the power system, the CPU 91 determines that an accident has occurred in the power system by the protection calculation, and outputs a control signal to the contact a. No control signal is output to the contact. Therefore, when at least two of the three protective relays 100 are normal when an accident occurs in the power system, one of the series circuits 501 to 503 outputs a trip command. .

  On the other hand, when an abnormality has occurred in the protective relay 101, as shown in FIG. 6B, the a contact 11a is opened and the b contacts 11b and 12b are closed. In this case, the output circuit 40 constitutes a 1 out of 2 circuit. Specifically, when at least one of the two protective relays 102 and 103 is activated, one of the series circuits 502 and 503 is configured to output a trip command. The

  Specifically, when the protective relay 102 is operated, the contact a 21a is closed, so the series circuit 502 outputs a trip command, and when the protective relay 103 is operated, the contact 31a is closed. Series circuit 503 outputs a trip command. When the protective relays 102 and 103 operate, the series circuits 502 and 503 output a trip command.

<Control method>
FIG. 8 is a diagram for describing a functional configuration of protective relay 100 according to the second embodiment. Referring to FIG. 8, protection relay 100 includes OR gates 701, 703, 706, AND gate 705, and NOT gate 708. The functions of these logic gates are mainly realized by the CPU 91.

  The relay abnormality detection signal is a signal indicating whether or not the protective relay 100 is abnormal. When the protective relay 100 is abnormal (for example, when the power of the protective relay 100 is abnormal or when any abnormality is detected by the CPU 91), the output value of the relay abnormality detection signal is “1”, and the protective relay 100 is normal. In some cases, the output value of the relay abnormality detection signal is “0”.

  The relay operation signal is a signal indicating whether or not the protective relay 100 is operating. When the protective relay 100 operates, the output value of the relay operation signal becomes “1”, and when the protective relay 100 does not operate, the output value of the relay operation signal becomes “0”.

  The operation signal is a signal indicating whether or not the system operator has performed an operation for forcibly operating the protective relay 100. When the system operator performs the operation, the output value of the operation signal is “1”, and when the operation is not performed, the output value of the operation signal is “0”. The operation signal is also output to the other protective relay 100.

  An operation signal in another relay (hereinafter, also referred to as “another relay operation signal”) is a signal indicating whether or not the system operator has performed an operation for forcibly operating the other protective relay 100. When the system operator performs the operation, the output value of the other relay operation signal is “1”, and when the operation is not performed, the output value of the other relay operation signal is “0”. The reason for using the other relay operation signal will be described later.

  The OR gate 701 performs an OR operation on the output values of the two other relay operation signals. The OR gate 701 outputs the operation value to the OR gate 706.

  The OR gate 703 performs an OR operation on the output values of the relay operation signal and the operation signal. The OR gate 703 outputs the operation value to the AND gate 705 and the OR gate 706.

  The AND gate 705 performs an AND operation on the value obtained by inverting the logic level of the output of the relay abnormality detection signal and the operation value of the OR gate 703. When the value calculated by the AND gate 705 is “1”, a control signal is output to the contact “a”, and the contact “a” is closed. When the calculated value is “0”, no control signal is output to the contact a, and the contact a is opened.

  The OR gate 706 performs an OR operation on the output value of the relay abnormality detection signal, the operation value of the OR gate 703, and the operation value of the OR gate 701. The OR gate 706 outputs the calculated value to the NOT gate 708. The NOT gate 708 outputs a value obtained by inverting the operation value of the OR gate 706. When the value calculated by the NOT gate 708 is “1”, a control signal is output to the b contact, and the b contact is opened. When the calculated value is “0”, no control signal is output to the b contact, and the b contact is closed.

  The opening / closing control method shown in FIG. 7 is realized by the above function. Specifically, when the protective relay 100 is normal and the protective relay 100 operates, the CPU 91 outputs a control signal to the contact a and does not output a control signal to the contact b. Thereby, a contact and b contact will be in a closed state.

  When the protective relay 100 is normal and the protective relay 100 is not operating, the CPU 91 does not output a control signal to the a contact and outputs a control signal to the b contact. As a result, the contact “a” is opened and the contact “b” is closed. In addition, when the protective relay 100 is abnormal, no control signal is output, so that the contact a is open and the contact b is closed.

  Further, as described above, the protective relay 100 is configured to forcibly operate in response to an operation from the grid operator. For example, the system operator applies an operation signal to the protective relay 100 during an operation test or when the power system is interrupted to forcibly operate the protective relay 100.

  Here, when the protective relay 100 is normal and when it does not operate, the contact b is opened. Therefore, in order to give a trip command to the circuit breaker 50, it is necessary to operate two of the three protective relays 100 simultaneously. Specifically, the system operator needs to select two protection relays 100 and operate these protection relays 100. The operation signal is output only for a certain period (for example, 1 second). For this reason, in order to operate the two simultaneously, it may be necessary to separately set, for example, to extend the output time width of the operation signal.

  Therefore, as illustrated in FIG. 8, the protection relay 100 performs processing using the operation signal received by the other protection relay 100 and transmits the operation signal to the other two protection relays 100. Hereinafter, a specific description will be given with reference to FIGS. 9 and 10.

  FIG. 9 is a diagram for describing an output state of a control signal when an operation signal is given to protective relay 102 according to the second embodiment. FIG. 10 is a diagram showing an open / close state of each contact according to the output state in FIG. It is assumed that the protective relays 101 and 102 are normal.

  Referring to FIG. 9, when the system operator gives the protection relay 102 an operation for forcibly operating the protection relay, the output value “1” of the operation signal is input to the OR gate 703 of the protection relay 102. , And input to the OR gate 701 of the protective relay 101. The OR gate 703 of the protective relay 102 outputs the output value “1” to the AND gate 705. Since the protective relay 102 is normal, the operation value of the AND gate 705 of the protective relay 102 is “1”. As a result, a control signal is output to the contact a, so that the contact a 21a is closed as shown in FIG.

  On the other hand, the OR gate 701 of the protective relay 101 outputs the output value “1” to the OR gate 706 of the protective relay 101. In the protection relay 101, the OR gate 706 outputs the output value “1” to the NOT gate 708, so that the operation value of the NOT gate 708 becomes “0”. Thereby, since a control signal is not output to b contact, b contact 11b and 12b will be in a closed state as shown in FIG.

  In summary, when the CPU 91 of the protective relay 102 receives a forced operation operation from the system operator, the CPU 91 closes the a contact 21a according to the operation and transmits an operation signal indicating the operation to the protective relay 101. When the CPU 91 of the protective relay 101 receives the operation signal, the b contacts 11b and 12b are closed. As a result, the a contact 21a and the b contact 11b are closed, and the series circuit 502 outputs a trip command.

  The protective relay 102 may transmit an operation signal to the protective relay 103. In this case, when the CPU 91 of the protective relay 103 receives the operation signal, the b contacts 31b and 32b are closed. As a result, the a contact 21a and the b contact 32b are closed, and the series circuit 502 outputs a trip command. Therefore, the protective relay 102 may transmit an operation signal to at least one of the protective relays 101 and 103.

  Thus, the system operator can output a trip command to the circuit breaker 50 only by operating the protective relay 102. Therefore, the operability of the protection control device 150 can be improved.

  Typically, the CPU 91 receives an input of an operation signal via the input interface 95. The CPU 91 transmits an operation signal to the other protective relay 100 via the communication interface 96. In this case, the CPU 91 of the other protective relay 100 receives the operation signal via the communication interface 96. Note that the CPU 91 may transmit an operation signal to another protective relay 100 via the DO unit 98. In this case, the CPU 91 of the other protective relay 100 receives the input of the operation signal via the DI circuit 94.

Embodiment 3 FIG.
In the third embodiment, a configuration example of the output circuit 40 different from the first and second embodiments will be described. <Overall configuration> and <hardware configuration> according to the third embodiment are the same as those in the first embodiment.

  FIG. 11 shows an output circuit 40 according to the third embodiment. Specifically, FIG. 11A shows the output circuit 40 when the three protective relays 100 are normal. FIG. 11B shows the output circuit 40 when the protective relay 101 is abnormal and the protective relays 102 and 103 are normal.

  Referring to FIG. 11, output circuit 40 according to the third embodiment includes a contact 11a and b contact 11b that are controlled to open / close by protective relay 101, and a contact 21a and b contact 21b that is controlled to open / close by protective relay 102. The a contact 31a and the b contact 31b that are controlled to be opened and closed by the protective relay 103 are included.

  The output circuit 40 includes series circuits 601, 602, and 603 connected in parallel to each other. Series circuit 601 includes a contact 11a and b contact 21b connected in series with each other. Series circuit 602 includes a contact 21a and b contact 31b connected in series with each other. Series circuit 603 includes a contact 31a and b contact 11b connected in series with each other.

  Note that the switching control system of the protective relay 100 according to the third embodiment is the same as the switching control system of the second embodiment. Therefore, the contact a and contact b are closed when the protective relay 100 is operated. When the three protective relays 100 are normal, the output circuit 40 constitutes a 2 out of 3 circuit. Specifically, when at least two of the three protective relays 100 are operated, one of the series circuits 601 to 603 is configured to output a trip command.

  Specifically, when the protective relays 101 and 102 are operated, the a contact 11a and the b contact 21b are closed, and the series circuit 601 outputs a trip command. When the protective relays 102 and 103 are operated, the a contact 21a and the b contact 31b are closed, and the series circuit 602 outputs a trip command. When the protective relays 103 and 101 are operated, the a contact 31a and the b contact 11b are closed, and the series circuit 603 outputs a trip command.

  On the other hand, when an abnormality has occurred in the protective relay 101, as shown in FIG. 11B, the a contact 11a is opened and the b contact 11b is closed. At this time, when the protective relays 102 and 103 operate, or when only the protective relay 103 operates, one of the series circuits 602 and 603 outputs a trip command. Specifically, when protective relays 102 and 103 operate, series circuit 602 outputs a trip command, and when only protective relay 103 operates, series circuit 603 outputs a trip command.

  Note that when only the protective relay 102 operates, the trip command is not output. However, if an abnormality occurs in the protective relay 103, the b contact 31b is closed, so that a trip command is output from the series circuit 602 even when only the protective relay 102 operates.

  Thus, according to the configuration of the output circuit 40 shown in FIG. 11, when an abnormality occurs in the protective relay 101, the series circuit 603 outputs a trip command by the output signal of only the protective relay 103, and the series circuit 602. The top command is output by the output signals of the protective relay 102 and the protective relay 103. Although the series circuits 601 to 603 do not completely match the 1 out of 2 configuration, it can be said that the series circuits 601 to 603 substantially match the 1 out of 2 operation in view of the above-described response. In the third embodiment, for each protection relay 100, the number of a contacts may be one and the number of b contacts may be one. Therefore, the 2 out of 3 configuration and the 1 out of 2 configuration can be realized semi-equivalently while simplifying the configuration of the output circuit 40.

  In the third embodiment, the operation signal described with reference to FIG. 9 may be used. Specifically, when the CPU 91 of the protective relay 102 receives a forced operation operation from the system operator, the CPU 91 closes the a contact 21a according to the operation and transmits an operation signal indicating the operation to the protective relay 103. . When the CPU 91 of the protective relay 103 receives the operation signal, the CPU 91 closes the b contact 31b. Thereby, since the a contact 21a and the b contact 31b are closed, the series circuit 602 outputs a trip command.

Other embodiments.
The configuration illustrated as the above-described embodiment is an example of the configuration of the present invention, and can be combined with another known technique, and a part of the configuration is omitted without departing from the gist of the present invention. It is also possible to change the configuration.

  In the above-described embodiment, the processing and configuration described in the other embodiments may be adopted as appropriate.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  11a-13a, 21a-23a, 31a-33a contact a, 11b-12b, 21b-22b, 31b-32b contact b, 40 output circuit, 50 circuit breaker, 70 auxiliary transformer, 72 AD converter, 80 power supply, 91 CPU, 92 RAM, 93 ROM, 94 DI circuit, 95 input interface, 96 communication interface, 98 DO unit, 99 bus, 100, 101, 102, 103 protection relay, 150 protection control device, 200, 300 contact circuit, 1000 protection Control system.

Claims (7)

A protection control device for protecting a power system,
Using the amount of electricity acquired from the power system, first to third protection relays that perform a protection operation for protecting the power system;
An output circuit that outputs a command signal for opening a circuit breaker provided in the power system based on a control signal from each of the first to third protective relays;
The output circuit includes first to third circuits connected in parallel to each other,
When at least two protection relays of the first to third protection relays are operated, any one of the first to third circuits is configured to output the command signal,
Even when an abnormality occurs in the first protective relay, if at least one protective relay of the second and third protective relays operates, the second and third circuits The protection control device is configured to output the command signal. The output circuit includes two first a contacts and two first b contacts that are controlled to be opened and closed by the first protective relay, and two second a contacts that are controlled to be opened and closed by the second protective relay. Two second b contacts, and two third a contacts and two third b contacts controlled to be opened and closed by the third protective relay,
The first circuit includes a first parallel circuit in which the second a contact, the second b contact, and the third b contact are connected in parallel, and the first circuit connected in series to the first parallel circuit. a contact,
The second circuit includes a second parallel circuit in which the third a contact, the third b contact, and the first b contact are connected in parallel, and the second circuit connected in series to the second parallel circuit. a contact,
The third circuit includes a third parallel circuit in which the first a contact, the first b contact, and the second b contact are connected in parallel, and the third circuit connected in series to the third parallel circuit. a contact,
2. The protection control device according to claim 1, wherein each of the first to third protection relays closes a contact corresponding to the protection relay and opens a contact b corresponding to the protection relay during operation. . The output circuit includes one first a contact and two first b contacts that are controlled to be opened and closed by the first protective relay, and one second a contact that is controlled to be opened and closed by the second protective relay, and Including two second b contacts, one third a contact and two third b contacts controlled to be opened and closed by the third protective relay,
The first circuit includes a first parallel circuit in which the second b contact and the third b contact are connected in parallel, and the first a contact connected in series to the first parallel circuit,
The second circuit includes a second parallel circuit in which the third b contact and the first b contact are connected in parallel, and the second a contact connected in series to the second parallel circuit,
The third circuit includes a third parallel circuit in which the first b contact and the second b contact are connected in parallel, and the third a contact connected in series to the third parallel circuit,
2. The protection control device according to claim 1, wherein each of the first to third protection relays closes an a contact and a b contact corresponding to the protection relay during operation. Each of the first to third protective relays is configured to receive an operation for operating the protective relay from a user,
When the second protection relay receives the operation from the user, the second protection relay closes the second a contact according to the operation and sends a signal indicating the operation to at least one of the first and third protection relays. Send
When the first protection relay receives the signal, the first protection relay closes the first b contact included in the second parallel circuit,
The protection control device according to claim 3, wherein the third protection relay closes the third b-contact included in the second parallel circuit when the signal is received. A protection control device for protecting a power system,
Using the amount of electricity acquired from the power system, first to third protection relays that perform a protection operation for protecting the power system;
An output circuit that outputs a command signal for opening a circuit breaker provided in the power system based on a control signal from each of the first to third protective relays;
The output circuit includes first to third circuits connected in parallel to each other,
When at least two protection relays of the first to third protection relays are operated, any one of the first to third circuits is configured to output the command signal,
Even when an abnormality occurs in the first protective relay, when the second and third protective relays operate, or when the third protective relay operates, the second circuit and the Any one of the third circuits is a protection control device configured to output the command signal. The output circuit includes a first a contact and a first b contact that are controlled to be opened and closed by the first protective relay, and a second a contact and a second b contact that are controlled to be opened and closed by the second protective relay. A third a contact and a third b contact controlled to be opened and closed by the third protective relay,
The first circuit includes the first a contact and the second b contact connected in series;
The second circuit includes the second a contact and the third b contact connected in series,
The third circuit includes the third a contact and the first b contact connected in series,
6. The protection control device according to claim 5, wherein each of the first to third protection relays closes an a contact and a b contact corresponding to the protection relay during operation. Each of the first to third protective relays is configured to receive an operation for operating the protective relay from a user,
When the second protection relay receives the operation from the user, the second protection relay closes the second contact a according to the operation, and transmits a signal indicating the operation to the third protection relay.
The protection control device according to claim 6, wherein the third protection relay closes the third b-contact when the signal is received.

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