JP2013172635A - Electric power system protection control system and method thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electric power system protection control system capable of shortening a total periodic inspection time by decreasing the number of times of periodic inspection on a merging unit (MU), and a method thereof.SOLUTION: An electric power system protection control system is constituted by coupling a plurality of merging units (MU) relaying control equipment, a protection controller performing protection control over the MUs, an MU inspection device inspecting the MUs, and a centralized monitoring controller monitoring and controlling the protection controller through a bus. The centralized monitoring controller, protection controller, or MU inspection device includes a reception part 100 which receives digital values transmitted from the plurality of MUs respectively, and an inspection command determination part 103 which sets a reference value based upon a plurality of pieces of measured value information obtained by converting the plurality of digital values, and detects a merging unit sending a digital value corresponding to measured value information exceeding the reference value by a predetermined quantity as a merging unit which needs to be inspected in such a case.

Description

  Embodiments of the present invention provide a system and method for reducing the number of periodic inspections of the merging unit (MU) and reducing the total periodic inspection time in a power system protection control system in which a plurality of merging units (MU) are arranged. About.

  In order to realize a protection control system for control equipment at electric power stations in the power system, it is necessary to measure the main circuit electricity (ie current or voltage) of the control equipment body and monitor the operating status of the control equipment. Become. Conventionally, after converting to a current value or voltage value suitable for measurement by an instrument transformer attached to the main body of the control device, the protection control device or centralized monitoring control device separated from the main body of the control device by a large amount of electric cables Information was sent and the operating status of the control equipment was monitored.

  On the other hand, with the development of communication and digital control technologies in recent years, application of a process bus has been started as a method for acquiring current or voltage data. In the process bus application system, a merging unit (MU) is arranged in the vicinity of the control device, and the amount of electricity from a plurality of instrument transformers is temporarily input to the merging unit (MU). The merging unit (MU) transmits a plurality of electric quantities as digital electric quantities to a higher-level protection control device or the like via serial communication called a process bus. Thereby, reduction of the wiring amount of electric cables, reduction of the secondary side burden of the instrument transformer, and standardization of the power system protection control system can be achieved.

  Conventionally, the secondary rated current of an instrument transformer has been standardized, for example, 1A or 5A. Similarly, in the merging unit (MU), serial communication on the process bus is standardized and standardized, and the process bus is applied according to the standard, so that the merging unit (MU) of different manufacturers and the protection control device However, it is possible to share digital electricity, that is, to realize interoperability.

International Electrotechnical Commission (IEC) Standard IEC61850-9-2 “SpecificCommunication Service Mapping (SCSM) For Process Bus”

  As a means for detecting the deterioration of the performance of the merging unit (MU), it is common to perform preventive maintenance by periodic inspection. However, since the merging unit (MU) applied to the protection control system of the control device is arranged for each control device, the number of the merging units (MU) is enormous and widely arranged, so that the regular inspection takes a great number of times and time. In power system facilities that operate over a long period of time, the issue is how to reduce the number of periodic inspections and shorten the total periodic inspection time.

  Therefore, an object of the embodiment of the present invention is to provide a power system protection control system and method that can reduce the number of periodic inspections of the merging unit (MU) and reduce the total periodic inspection time.

  To achieve the above object, an embodiment of the present invention includes a plurality of merging units that relay control equipment, a protection control device that protects and controls the merging unit, and a centralized monitoring and control device that monitors and controls the protection control device. In the power system protection control system coupled by a bus, the centralized monitoring control device or the protection control device converts a digital value transmitted from each of the plurality of merging units and a plurality of the digital values. A merging unit that needs to check a merging unit that sets a reference value based on a plurality of pieces of measurement value information and generates a digital value corresponding to the measurement value information when each measurement value information exceeds a predetermined amount from the reference value. And an inspection command determination unit that detects as a unit.

  The method executed in the embodiment as described above is also one embodiment of the present invention.

The lineblock diagram of the electric power system protection control system of a 1st embodiment. The data figure of the measured value information of a merging unit (MU). The block diagram of the centralized monitoring control apparatus of 1st Embodiment. The block diagram of the MU inspection apparatus and protection control apparatus of 1st Embodiment. The flowchart which shows the procedure which checks the performance degradation of the merging unit (MU) in 1st Embodiment. The block diagram of the centralized monitoring control apparatus of 2nd Embodiment. The block diagram of the MU inspection apparatus and protection control apparatus of 2nd Embodiment. The flowchart which shows the procedure which checks the performance degradation of the merging unit (MU) in 2nd Embodiment. The block diagram of the MU inspection apparatus and protection control apparatus of 3rd Embodiment. Explanatory drawing which shows the procedure which checks the performance fall of the merging unit (MU) in 3rd Embodiment. The block diagram of the MU inspection apparatus and protection control apparatus of 4th Embodiment. Explanatory drawing which shows the procedure which checks the performance fall of the merging unit (MU) in 4th Embodiment. The block diagram of the MU inspection apparatus and protection control apparatus of 5th Embodiment. Explanatory drawing which shows the procedure which checks the performance fall of the merging unit (MU) in 5th Embodiment.

Embodiments of the present invention will be specifically described below with reference to the drawings.
[First Embodiment]
(Basic configuration)
FIG. 1 shows a basic configuration of a power system protection control system according to the first embodiment. The power system protection control system 10 is installed in an electric station of the power system. In this power system protection control system 10, a centralized monitoring control device 1 that monitors and controls the inside of an electric station, a MU inspection device 2-1 that performs a process for detecting a deterioration in the performance of a merging unit (MU), and a facility are distributed. The protection control devices 4-1, 4-2, 4-3,..., 4-n are connected by a LAN via the Ethernet switches 3-1, 3-2, 3-n of the station bus 30. Further, the protection control devices 4-1, 4-2, 4-3,... 4-n, merging units (MU) 6-1, 6-2, 6-3,. Inspection devices 2-2,..., 2-n are connected via a LAN via Ethernet switches 5-1,.

  The merging units (MU) 6-1, 6-2, 6-3,..., 6-n are circuit breakers 11-1, 11-2, 11-3,. Information such as the device status and the secondary value of the instrument transformer is transmitted and received from -n and the instrument transformers 12-1, 12-2, 12-3, ... 12-n.

(Measured value information of merging unit (MU))
FIG. 2 is a data diagram of measurement value information of the merging unit (MU). The merging units (MU) 6-1, 6-2, 6-3,... 6 -n convert the secondary value of the instrument transformer into the digital measurement value 111 and send it to the process bus 31. . Further, in order to discriminate the target device of the measurement value, measurement device information 110 containing information on merging units (MU) 6-1, 6-2, 6-3,. . The protection control devices 4-1, 4-2, 4-3,... 4-n receive the measurement device information 110 and the digital measurement values 111 from the process bus 31 and transmit information to the station bus 30.

(Configuration of centralized monitoring control device 1)
FIG. 3 is a block diagram illustrating the configuration of the centralized monitoring control device 1 in the power system protection control system 10 according to the present embodiment.
The centralized monitoring control apparatus 1 includes a receiving unit 100, a measurement calculation processing unit 101, measured value recording units 102-1, 102-2, 102-3,... 102-n, an inspection command determining unit 103, and a warning display unit. 104 is provided.

  The receiving unit 100 receives transmission data from the station bus 30 as an apparatus interface. The measurement calculation processing unit 101 performs calculation processing for converting the digital electricity quantity of the control device, which is transmission data from the reception unit 100, into measurement value information. The measurement value recording units 102-1, 102-2, 102-3,... 102-n are respectively sent from the measurement calculation processing unit 101 to merging units (MU) 6-1, 6-2 corresponding to the numbers. 6-3... 6-n measurement value information is received and recorded in merging unit (MU) units.

  The inspection command determination unit 103 determines a reference value based on the majority rule from the measurement values of a plurality of merging units (MU) 6-1, 6-2, 6-3,. Further, the inspection command determination unit 103, when exceeding a predetermined amount from the reference value among the measured values of the plurality of merging units (MU) 6-1, 6-2, 6-3, ... 6-n, The merging unit (MU) of the measurement value is determined to be inspected, and inspection command information is output to the warning display unit 104. When receiving the inspection command information from the inspection command determination processing unit 103, the warning display unit 104 displays a warning on the monitoring screen 7 of the centralized monitoring control device 1.

(Configurations of MU inspection devices 2-1, 2-2, ... 2-n and protection control devices 4-1, 4-2, 4-3, ... 4-n)
4 shows the MU inspection devices 2-1, 2-2,..., 2-n and the protection control devices 4-1, 4-2, 4-3 in the power system protection control system 10 according to the present embodiment. ... is a block diagram illustrating the configuration of 4-n.

  All of the MU inspection devices 2-1, 2-2,..., 2-n and the protection control devices 4-1, 4-2, 4-3,. Similarly, a receiving unit 100, a measurement calculation processing unit 101, measurement value recording units 102-1, 102-2, 102-3,... 102-n, and an inspection command determination unit 103 are provided.

  The MU inspection devices 2-1, 2-2,... 2-n and the protection control devices 4-1, 4-2, 4-3,. -1, 105-2, 105-3,... 105-n. The inspection command information transmission units 105-1, 105-2, 105-3,... 105-n transmit the inspection command information from the inspection command determination processing unit 103 to the station bus 30 or the process bus 31. The centralized monitoring control device 1 can display a warning on the monitoring screen 7 by receiving the inspection command information via the station bus 30.

(Procedure for checking performance degradation of merging unit (MU))
The merging unit (MU) 6-1 receives the secondary value of the instrument transformer from the instrument transformer 12-1 shown in FIG. 1, and stores information in the measurement device information 110 and the digital measurement value 111 shown in FIG. Is sent to the process bus 31. The MU inspection device 2-2 and the protection control device 4-1 connected to the process bus 31 receive the measurement device information 110 and the digital measurement value 111 information via the process bus 31. Next, the protection control device 4-1 transmits the measurement device information 110 and the digital measurement value 111 information to the station bus 30. The centralized monitoring and control device 1 and the MU inspection device 2-1 connected to the station bus 30 receive the measurement device information 110 and the digital measurement value 111 via the station bus 30.

  FIG. 5 is a flowchart illustrating a procedure for checking the performance degradation of the merging unit (MU) in the centralized monitoring control device 1, the MU checking device 2-1, or the protection control device 4-1.

  In any of the centralized monitoring control device 1, the MU inspection device 2-1, and the protection control device 4-1, the receiving unit 100 receives transmission data from the station bus 30 or the process bus 31 as an interface of the device (S11). . Next, the measurement calculation processing unit 101 performs calculation processing for converting the digital electricity quantity of the control device, which is transmission data from the reception unit 100, into measurement value information (S12). Furthermore, the measurement value recording units 102-1, 102-2, 102-3,... 102-n are sent from the measurement calculation processing unit 101 to a plurality of merging units (MU) 6-1, 6-2, 6-. The measurement value information for every 3, ... 6-n is received and recorded in merging unit (MU) units (S13).

  The inspection command determination unit 103 determines a reference value based on the majority rule from the measurement values of the plurality of merging units (MU) 6-1, 6-2, 6-3, 6-n (S14). Further, the inspection command determination unit 103 determines whether or not the measured value exceeds a predetermined amount from the reference value among the plurality of merging units (MU) 6-1, 6-2, 6-3, and 6-n. (S15) If it exceeds (Y in S15), it is determined that the merging unit (MU) is inspected, and inspection command information is output to the warning display unit 104. When receiving the inspection command information from the inspection command determination processing unit 103, the warning display unit 104 displays a warning on the monitoring screen 7 of the centralized monitoring control device 1 (S16). The predetermined amount can be arbitrarily determined in consideration of the frequency of inspection.

  In the MU inspection device 2-1 or the protection control device 4-1, other than the centralized monitoring control device 1, the inspection command information transmission units 105-1, 105-2, 105-3, ... 105-n determine the inspection command. Inspection command information from the processing unit 103 is transmitted to the station bus 30 (S16). The centralized monitoring control apparatus 1 displays that the merging unit (MU) 6-1 needs to be inspected on the monitoring screen 7 by receiving the inspection command information via the station bus 30.

  With the above-described method, it is possible to detect in advance the performance degradation of the merging units (MU) 6-1, 6-2, 6-3, 6-n before failure. Therefore, according to this embodiment, the number of periodic inspections of the merging unit (MU) can be greatly reduced, and the total periodic inspection time can be shortened.

[Second Embodiment]
(Configuration of centralized monitoring control device 1)
FIG. 6 is a block diagram illustrating the configuration of the centralized monitoring control device 1 in the power system protection control system according to the present embodiment.

  The centralized monitoring control apparatus 1 includes a receiving unit 200, a measurement calculation processing unit 201, trend recording units 202-1, 202-2, 202-3,... 202-n, an inspection command determination unit 203, and a warning display unit 204. I have.

  The receiving unit 200 receives information on the digital measurement value 111 from the station bus 30 as an interface of the apparatus. The measurement calculation processing unit 201 performs calculation processing for converting the digital electricity quantity of the control device, which is transmission data from the reception unit 200, into measurement value information.

  The trend recording units 202-1, 202-2, 202-3,... 202-n record information of the digital measurement values 111 that regularly change under certain conditions as a result of processing by the measurement calculation processing unit 201. To do.

  The inspection command determination unit 203 calculates the reference value based on the average principle from the past information of the merging unit (MU) 6-1 recorded by the trend recording units 202-1, 202-2, 202-3, ... 202-n. And the degree of degradation of the measured value is determined. Further, when the current digital measurement value 111 exceeds a predetermined amount from the reference value, the inspection command determination unit 203 determines that the merging unit (MU) needs to be inspected, and sends the inspection command information to the warning display unit 204. Output. When the warning display unit 204 receives the inspection command information from the inspection command determination unit 203, the warning display unit 204 displays a warning on the monitoring screen 7 of the centralized monitoring control device 1.

(Configurations of MU inspection devices 2-1, 2-2, ... 2-n and protection control devices 4-1, 4-2, 4-3, ... 4-n)
7 shows MU inspection devices 2-1, 2-2,..., 2-n and protection control devices 4-1, 4-2, 4-3,... In the power system protection control system according to the present embodiment. It is a block diagram explaining the structure of 4-n.

  All of the MU inspection devices 2-1, 2-2,..., 2-n and the protection control devices 4-1, 4-2, 4-3,. Similarly, a receiving unit 200, a measurement calculation processing unit 201, trend recording units 202-1, 202-2, 202-3,... 202-n, and an inspection command determination unit 203 are provided.

  The MU inspection devices 2-1, 2-2,... 2-n and the protection control devices 4-1, 4-2, 4-3,. -1, 205-2, 205-3,... 205-n. The inspection command information transmission units 205-1, 205-2, 205-3,... 205-n transmit inspection command information from the inspection command determination processing unit 203 to the station bus 30 or the process bus 31. The centralized monitoring control device 1 can display a warning on the monitoring screen 7 by receiving the inspection command information via the station bus 30.

(Procedure for checking performance degradation of merging unit (MU))
FIG. 8 is a flowchart showing a procedure for checking the performance degradation of the merging unit (MU) in the centralized monitoring control device 1, the MU checking device 2-1, and the protection control device 4-1.

  In the centralized monitoring control device 1, the MU inspection device 2-1, and the protection control device 4-1, the receiving unit 200 receives transmission data from the station bus 30 or the process bus 31 as the device interface (S21). Next, the measurement calculation processing unit 201 performs calculation processing for converting the digital electricity quantity of the control device, which is transmission data from the reception unit 200, into measurement value information (S22). Furthermore, the trend recording units 202-1, 202-2, 202-3,... 202-n record information (trend measurement values) of the digital measurement values 111 that regularly change under certain conditions (S23). ).

  The inspection command determination unit 203 calculates the reference value based on the average principle from the past information of the merging unit (MU) 6-1 recorded by the trend recording units 202-1, 202-2, 202-3, ... 202-n. Is determined (S24). Further, the inspection command determination unit 203 determines whether or not the current digital measurement value 111 exceeds a predetermined amount from the reference value (S25). If it exceeds (Y in S25), the merging unit (MU). The inspection command information is output to the warning display unit 204.

  When receiving the inspection command information from the inspection command determination unit 203, the warning display unit 204 displays a warning on the monitoring screen 7 of the centralized monitoring control apparatus 1 (S26).

  In the MU inspection device 2-1 or protection control device 4-1 other than the centralized monitoring control device 1, the inspection command information transmitting units 205-1, 205-2, 205-3,. Inspection command information from the unit 203 is transmitted to the station bus 30 (S26). The centralized monitoring control apparatus 1 displays that the merging unit (MU) 6-1 needs to be inspected on the monitoring screen 7 by receiving the inspection command information via the station bus 30.

  By the above method, it is possible to detect in advance the performance degradation of the merging units (MU) 6-1, 6-2, 6-3,. Therefore, according to this embodiment, the number of periodic inspections of the merging unit (MU) can be greatly reduced, and the total periodic inspection time can be shortened.

[Third Embodiment]
(Configuration of protection control device 4-1 and MU inspection device 2-2)
FIG. 9 is a block diagram illustrating the configuration of the protection control device 4-1 and the MU inspection device 2-2 in the power system protection control system according to the present embodiment.

  The protection control device 4-1 and the MU inspection device 2-2 include a reception unit 300, a Next Goose time recording unit 301, a Goose reception time recording unit 302, an inspection command determination unit 303, and an inspection command information transmission unit 304. .

  The receiving unit 300 receives failure diagnosis goose information and next goose time information from the merging unit (MU) 6-1. The Next Goose time recording unit 301 records the Next Goose time information. The Goose reception time recording unit 302 records the reception time of the next failure diagnosis Goose information transmitted by the merging unit (MU) 6-1.

  The inspection command determination unit 303 performs a comparison process between the Next Goose time and the Goose reception time, and determines that the merging unit (MU) needs to be inspected when the time difference between them exceeds an arbitrarily set interval time. Then, the inspection command information of the merging unit (MU) 6-1 is output to the inspection command information transmission unit 304. The inspection command information transmission unit 304 transmits the inspection command information from the inspection command determination unit 303 to the station bus 30. The centralized monitoring control device 1 can display a warning on the monitoring screen 7 by receiving the inspection command information via the station bus 30.

(Procedure for checking performance degradation of merging unit (MU))
FIG. 10 is an explanatory diagram showing a procedure for checking performance degradation of a merging unit (MU) alone in the protection control device 4-1 and the MU checking device 2-2.

  The merging unit (MU) 6-1 of the power system is configured to check a failure of the merging unit (MU) 6-1 at an arbitrary transmission interval (300-1, 300-2,... 300- n) Send information to the process bus 31. Here, for example, the failure diagnosis Goose (300-1) information is added with information called Next Goose time (301-1) indicating the time information of the failure diagnosis Goose (300-2) to be transmitted next time. Sent to.

  The receiving unit 300 of the protection control device 4-1 or the MU inspection device 2-2 receives the failure diagnosis Goose (300-1, 300-2,... 300 -n) information and the Next Goose time ( 301-1, 301-2,... 301-n) Information is received.

  Next, when the Next Goose time recording unit 301 records the Next Goose time (301-1), the Goose reception time recording unit 302 correspondingly sends the next message to the merging unit (MU) 6-1. The reception time of failure diagnosis Goose (300-2) is recorded as the Goose reception time (302-2).

  The inspection command determination unit 303 performs a comparison process between the Next Goose time (301-1) and the Goose reception time (302-2), and if the time difference between these exceeds an arbitrarily set interval time, the merging unit (MU) The inspection command information of 6-1 is output to the inspection command information transmission unit 304. The inspection command information transmission unit 304 transmits the inspection command information from the inspection command determination unit 303 to the station bus 30 or the process bus 31.

  For example, the inspection command information output from the MU inspection device 2-2 is transmitted to the protection control device 4-1 via the process bus 31. The protection control device 4-1 transmits inspection command information to the station bus 30. The centralized monitoring control device 1 receives the inspection command information via the station bus 30 and displays on the monitoring screen 7 that the merging unit (MU) 6-1 needs to be inspected. The centralized monitoring control device 1 displays this warning on the monitoring screen 7 by receiving this inspection command information via the station bus 30.

  With the above method, it is possible to detect in advance the performance degradation of the merging unit (MU) before it fails. Therefore, according to this embodiment, the number of periodic inspections of the merging unit (MU) can be greatly reduced, and the total periodic inspection time can be shortened.

[Fourth Embodiment]
(Configuration of protection control devices 4-1, 4-2 and MU inspection device 2-2)
FIG. 11 is a block diagram illustrating the configurations of the protection control devices 4-1, 4-2 and the MU inspection device 2-2 in the power system protection control system according to the present embodiment.

  The protection control devices 4-1 and 4-2 and the MU inspection device 2-2 include a reception unit 400, a MU 6-1 GOOSE recording unit 401, a MU 6-2 GOOSE recording unit 402, a MU 6-1 operation unit 403, and a MU 6-2 operation unit. 404, an inspection command determination unit 405, and an inspection command information transmission unit 406.

  The receiving unit 400 receives failure diagnosis Goose information, Next Goose time information from the merging unit (MU) 6-1, and failure diagnosis Goose information and Next Goose time information from the merging unit (MU) 6-2. The MU 6-1 Goose recording unit 401 records the reception time of the Next Goose time information from the merging unit (MU) 6-1 and the next failure diagnosis Goose information transmitted by the merging unit (MU) 6-1. On the other hand, the MU 6-2 Goose recording unit 402 records the reception time of the Next Goose time information from the merging unit (MU) 6-2 and the next failure diagnosis Goose information transmitted by the merging unit (MU) 6-2. .

  The MU 6-1 calculation unit 403 calculates the time difference between the Next Goose time information from the merging unit (MU) 6-1 and the reception time of the next failure diagnosis Goose information transmitted by the merging unit (MU) 6-1. To do. On the other hand, the MU6-2 arithmetic unit 404 calculates the time difference between the Next Goose time information from the merging unit (MU) 6-2 and the reception time of the next failure diagnosis Goose information transmitted by the merging unit (MU) 6-2. Is calculated.

  The inspection command determination unit 405 compares the time difference of the merging unit (MU) 6-1 and the time difference of the merging unit (MU) 6-2 to determine a reference value based on the majority rule. Next, when the time difference of the merging unit (MU) 6-1 and the time difference of the merging unit (MU) 6-2 exceed a predetermined amount from the reference value, the inspection command determination unit 405 determines the merging unit (MU). The inspection command information of the 6-1 or merging unit (MU) 6-2 is output to the inspection command information transmission unit 406. The inspection command information transmission unit 406 transmits inspection command information from the inspection command determination unit 405 to the station bus 30. The centralized monitoring control device 1 can display a warning on the monitoring screen 7 by receiving the inspection command information via the station bus 30.

(Procedure for checking performance degradation of merging unit (MU))
FIG. 12 is an explanatory diagram illustrating a procedure for inspecting performance degradation of a plurality of merging units (MUs) in the MU checking device 2-2 and the protection control devices 4-1, 4-2.

  The merging unit (MU) 6-1 of the power system is configured to check a failure of the merging unit (MU) 6-1 at an arbitrary transmission interval (300-1a, 300-2a,... 300- n) Send information to the process bus 31. Here, for example, the failure diagnosis Goose (300-1a) information is added with information called Next Goose time (301-1a) indicating the time information of the failure diagnosis Goose (300-2a) to be transmitted next time, and the process bus 31. Sent to.

  On the other hand, the merging unit (MU) 6-2 of the power system has a failure diagnosis Goose (300-1b, 300-2b,...) For confirming a failure of the merging unit (MU) 6-2 at an arbitrary transmission interval. 300 -m) Send information to the process bus 31. Also in this case, for example, information of Next Goose time (301-1b) indicating the time information of the fault diagnosis Goose (300-2b) to be transmitted next time is added to the fault diagnosis Goose (300-1b) information, and the process bus 31.

  When the receiving unit 400 receives the information of the Next Goose time (301-1a) and (301-1b) via the process bus 31, the MU 6-1 Goose recording unit 401 receives the information from the merging unit (MU) 6-1. The Next Goose time 301-1a is recorded, and the reception time of the failure diagnosis Goose 300-2a transmitted next time by the merging unit (MU) 6-1 is recorded as the Goose reception time 302-2a. On the other hand, the MU 6-2 Goose recording unit 402 records the Next Goose time 301-1b from the merging unit (MU) 6-2, and the failure diagnosis Goose 300-2b transmitted next time by the merging unit (MU) 6-2. The reception time is recorded as a GOOSE reception time 302-2b.

  The MU 6-1 calculation unit 403 receives the next goose time 301-1a from the merging unit (MU) 6-1 and the reception time 302-2a of the next failure diagnosis goose information transmitted by the merging unit (MU) 6-1. And calculate the time difference. On the other hand, the calculation unit 404 receives the next goose time 301-1b from the merging unit (MU) 6-2, and the reception time 302-2b of the next failure diagnosis goose information transmitted by the merging unit (MU) 6-2. The time difference is calculated.

  The inspection command determination unit 405 compares the time difference of the merging unit (MU) 6-1 and the time difference of the merging unit (MU) 6-2 to determine a reference value based on the majority rule. Next, when the time difference of the merging unit (MU) 6-1 and the time difference of the merging unit (MU) 6-2 exceed a predetermined amount from the reference value, the inspection command determination unit 405 determines the merging unit (MU). The inspection command information of the 6-1 or merging unit (MU) 6-2 is output to the inspection command information transmission unit 406. The inspection command information transmission unit 406 transmits the inspection command information from the inspection command determination unit 405 to the station bus 30 or the process bus 31.

  For example, the inspection command information output from the MU inspection device 2-2 is transmitted to the protection control device 4-1 or 4-2 via the process bus 31. The protection control device 4-1 or 4-2 transmits inspection command information to the station bus 30. The centralized monitoring control device 1 receives the inspection command information via the station bus 30 and displays on the monitoring screen 7 that the merging unit (MU) 6-1 needs to be inspected.

  With the above method, it is possible to detect in advance the performance degradation of the merging unit (MU) before it fails. Therefore, according to this embodiment, the number of periodic inspections of the merging unit (MU) can be greatly reduced, and the total periodic inspection time can be shortened.

[Fifth Embodiment]
(Configuration of protection control devices 4-1, 4-2 and MU inspection device 2-2)
FIG. 13 is a block diagram illustrating the configurations of the protection control devices 4-1, 4-2 and the MU inspection device 2-2 in the power system protection control system according to the present embodiment.

  The protection control devices 4-1 and 4-2 and the MU inspection device 2-2 include a transmission unit 500, a reception unit 501, a recording unit 502, an inspection command determination unit 503, and an inspection command information transmission unit 504.

  In order to confirm the reaction from each merging unit (MU) 6-1 and 6-2, the transmission unit 500 sends reaction check Goose information to each merging unit (MU) 6-1 and 6-2 at regular intervals. Send to. The receiving unit 501 receives a response Goose as a reply from each merging unit (MU) 6-1 and 6-2. The recording unit 502 records the reaction goose information received by the receiving unit 501.

  The inspection command determination unit 503 includes a time difference from when the transmission unit 500 transmits reaction check Goose information to the merging unit (MU) 6-1 until it receives the reaction Goose, and the transmission unit 500 receives the reaction check Goose information from the merging unit. (MU) The time difference from the transmission to 6-2 to the reception of the response “Goose” is compared, and the reference value is determined based on the majority rule. In addition, when the time difference exceeds a predetermined amount from the reference value, the inspection command determination unit 503 sends the inspection command information of the merging unit (MU) 6-1 or the merging unit (MU) 6-2 to the inspection command information transmission unit. Output to 504. The inspection command information transmission unit 504 transmits the inspection command information from the inspection command determination unit 503 to the station bus 30. The centralized monitoring control device 1 can display a warning on the monitoring screen 7 by receiving the inspection command information via the station bus 30.

(Procedure for checking performance degradation of merging unit (MU))
FIG. 14 is an explanatory diagram illustrating a procedure for inspecting performance degradation of a plurality of merging units (MUs) in the MU checking device 2-2 and the protection control devices 4-1, 4-2.

  In order to confirm the reaction from each merging unit (MU) 6-1 and 6-2, the transmission unit 500 performs a reaction check Goose (303-1, 303-2,... 303-n) at regular intervals. Information is transmitted to the process bus 31. These reaction check Goes (303-1, 303-2,... 303-n) information is received by each merging unit (MU) 6-1 and 6-2 connected on the process bus 31. The merging unit (MU) 6-1 sends a response Goose (304-1a, 304-2a,..., 304-n) as a reply, and the merging unit (MU) 6-2 answers as a reaction Goose. (304-1b, 304-2b,... 304-m) are transmitted.

  The receiving unit 501 receives the reaction Goose (304-1a, 304-2a,... 304-n) and the reaction Goose (304-1b, 304-2b,... 304-m).

  Here, when the reception unit 501 receives the reaction GOOSE 304-1a from the merging unit (MU) 6-1 and receives the reaction GOSE 304-1b from the merging unit (MU) 6-2 to 304-1b, the recording unit 502 stores these pieces of information respectively. It records as reaction Goose reception time 305-1a, 305-1b.

  The inspection command determination unit 503 transmits the reaction check Goose 303-1 and then receives the reaction Goose reception time 305-1a, and the time difference between the transmission of the reaction check Goose 303-1 and the reaction Goose reception time 305-1b. And determine the reference value based on the majority rule. In addition, when the time difference exceeds a predetermined amount from the reference value, the inspection command determination unit 503 sends the inspection command information of the merging unit (MU) 6-1 or the merging unit (MU) 6-2 to the inspection command information transmission unit. Output to 504. The inspection command information transmission unit 504 transmits the inspection command information from the inspection command determination unit 503 to the station bus 30 or the process bus 31.

  For example, the inspection command information output from the MU inspection device 2-2 is transmitted to the protection control device 4-1 or 4-2 via the process bus 31. The protection control device 4-1 or 4-2 transmits inspection command information to the station bus 30. The centralized monitoring control device 1 receives the inspection command information via the station bus 30 and displays on the monitoring screen 7 that the merging unit (MU) 6-1 or the merging unit (MU) 6-2 needs to be inspected. .

  With the above method, it is possible to detect in advance the performance degradation of the merging unit (MU) before it fails. Therefore, according to this embodiment, the number of periodic inspections of the merging unit (MU) can be greatly reduced, and the total periodic inspection time can be shortened.

[Other embodiments]
(1) In the first and second embodiments described above, the merging units (MU) 6-1 and 6- 6 are taken as an example of the centralized monitoring control device 1, the MU inspection device 2-1, and the protection control device 4-1. 2-6,..., 6-n have been described in advance as to the method of detecting performance degradation, but the MU inspection devices 2-2,..., 2-n, protection control devices 4-2, 4-3 ,..., 4-n can be detected in advance by the same method before failure.

(2) In the third embodiment, the merging unit (MU) 6-1 has been described as an example. However, the merging units (MU) 6-2 to 6-n may also be failed by the same method. It can be detected in advance.

(3) In the fourth and fifth embodiments, the merging unit (MU) 6-1 and the merging unit (MU) 6-2 have been described as examples. However, the merging units (MU) 6-1 to 6- Any combination of n may be used.

(4) Although several embodiments of the present invention have been described above, these embodiments are presented as examples and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1 ... Centralized monitoring control apparatus 2-1, 2-2, ... 2-n ... Merging unit (MU) inspection apparatus 3-1, 3-2, ... 3-n ... Ethernet switch 4-1, 4 -2, 4-3, ... 4-n ... protection control devices 5-1, ... 5-n ... Ethernet switches 6-1, 6-2, 6-3, ... 6-n ... merging Unit (MU)
7 ... Monitoring screens 11-1, 11-2, 11-3, ... 11-n ... Circuit breaker (control device)
12-1, 12-2, 12-3, ... 12-n ... Instrument transformer 30 ... Station bus 31 ... Process bus 100 ... Receiving unit 101 ... Measurement arithmetic processing units 102-1 to 102-n ... Measurement Value recording unit 103 ... inspection command determination unit 104 ... warning display units 105-1 to 105-n ... inspection command information transmission unit 200 ... reception unit 201 ... measurement calculation processing units 202-1 to 202-n ... trend recording unit 203 ... Inspection command determination unit 204 ... warning display units 205-1 to 205-n ... inspection command information transmission unit 300 ... reception unit 301 ... Next Goose time recording unit 302 ... Goose reception time recording unit 303 ... inspection command determination unit 304 ... inspection command Information transmitting unit 400 ... receiving unit 401 ... MU6-1 GOOSE recording unit 402 ... MU6-2 GOOSE recording unit 403 ... MU6-1 calculating unit 404 ... MU6-2 calculating Unit 405 ... Inspection command determination unit 406 ... Inspection command information transmission unit 500 ... Transmission unit 501 ... Reception unit 502 ... Recording unit 503 ... Inspection command determination unit 504 ... Inspection command information transmission unit

Claims (12)

In a power system protection control system in which a plurality of merging units that relay control equipment, a protection control device that protects and controls the merging unit, and a centralized monitoring control device that monitors and controls the protection control device are connected by a bus.
The centralized monitoring control device or the protection control device includes a receiving unit that receives digital values respectively transmitted from the plurality of merging units;
A reference value is set based on a plurality of pieces of measurement value information converted from the plurality of digital values, and when each measurement value information exceeds a predetermined amount from the reference value, a digital value corresponding to the measurement value information is emitted. An inspection command determination unit that detects the merging unit as a merging unit that requires inspection;
A power system protection control system comprising:   The power system protection control system according to claim 1, further comprising a merging unit inspection device that inspects the merging unit, the merging unit inspection device including the receiving unit and the inspection command determination unit. .   The power system protection control system according to claim 1, wherein the measurement value information is long-term trend information that changes with time in an arbitrary merging unit.   The measured value information is a time between the scheduled transmission time of the failure diagnosis Goose information transmitted from an arbitrary merging unit and the time when the protection control device or the merging unit inspection device actually received the failure diagnosis Goose information. The power system protection control system according to claim 1, wherein the power system protection control system is a difference.   The power system protection control system according to claim 4, wherein the measurement value information is the time difference in a plurality of merging units.   The measurement value information is transmitted by the plurality of merging units in response to the transmission time of the Goose information transmitted from the protection control device or the merging unit inspection device to the plurality of merging units, and as a response after receiving the Goose information. 3. The power system protection control system according to claim 1, wherein the response system information is a time difference from a reception time at which the protection control device or the merging unit inspection device receives the response Goose information. A power system protection control method for a power system protection control system in which a plurality of merging units that relay control equipment, a protection control device that protects and controls the merging unit, and a centralized monitoring control device that monitors and controls the protection control device are connected by a bus In
The centralized monitoring control device or the protection control device receives digital values respectively transmitted from the plurality of merging units, and the received reference value is based on a plurality of pieces of measurement value information converted from the plurality of digital values. And a merging unit that emits a digital value corresponding to the measured value information when each measured value information exceeds a predetermined amount from the reference value is detected as a merging unit that requires inspection. System protection control method.   A merging unit inspection device for inspecting the merging unit is coupled to the bus, the merging unit inspection device receives digital values respectively transmitted from the plurality of merging units, and the received device receives a plurality of the digital values. A reference value is set based on a plurality of pieces of measurement value information converted from the above, and when each measurement value information exceeds a predetermined amount from the reference value, a merging unit that emits a digital value corresponding to the measurement value information is inspected. 8. The power system protection control method according to claim 7, wherein the power system protection control method is detected as a necessary merging unit.   9. The power system protection control method according to claim 7, wherein the measurement value information is long-term trend information that changes with time in an arbitrary merging unit.   The measured value information is a time between the scheduled transmission time of the failure diagnosis Goose information transmitted from an arbitrary merging unit and the time when the protection control device or the merging unit inspection device actually received the failure diagnosis Goose information. The power system protection control method according to claim 7 or 8, wherein the power system protection control method is a difference.   The power system protection control method according to claim 10, wherein the measurement value information is the time difference in a plurality of merging units. The measurement value information is transmitted by the plurality of merging units in response to the transmission time of the Goose information transmitted from the protection control device or the merging unit inspection device to the plurality of merging units, and as a response after receiving the Goose information. The power system protection control method according to claim 7 or 8, wherein the response Goose information is a time difference from a reception time at which the protection control device or the merging unit inspection device has received.

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