JP2012253839A - Equipment management device, power equipment management system and equipment management method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To automate the management of an electric equipment management system at low cost.SOLUTION: A second CPU 21 of an equipment management device 20 reads out, from a management data memory section 13 in a protection relay apparatus 10, as management data, at least one datum of a measurement value inputted to a first CPU 11 and manipulated signals outputted from the first CPU 11. Then, the second CPU 21 checks the read out management data against a management rule stored in storage means of the equipment management apparatus 20, determines whether the read out management data should be notified or not and notifies a power system management device 43 of the management data determined to be notified.

Description

  The present invention relates to a facility management apparatus, a power facility management system, and a facility management method.

  In power equipment such as a substation system, a protection relay device for protecting an electric circuit from an overvoltage or the like is provided. When the voltage value measured by the current transformer becomes an overvoltage, the protection relay device transmits a trip command to the circuit breaker to cut off electricity and protect the electric circuit.

  As each device of the substation system such as a protection relay device, a device corresponding to the international standard IEC 61850 for substation communication is beginning to be widely used for the purpose of remote monitoring (Non-patent Document 1, etc.). Supporting the realization of substation management automation (automated operation, etc.) by directly transmitting a control signal from a monitoring device installed in a central control room or the like to a protection relay device compatible with IEC 61850.

"IEC61850-Communication networks and systems for power utility automation"

  To make a protection relay device not compatible with IEC61850 already in operation compatible with IEC61850, add the function of IEC61850 to the already operating protection relay device (built-in addition), or separately from the protection relay device, There is a method of adding another device (external addition) having the function of IEC61850.

  First, when the built-in addition is performed, it is necessary for the CPU in the protection relay device to simultaneously perform not only the relay calculation processing that is the original function of the protection relay device but also the communication processing with the monitoring device corresponding to IEC 61850. The processing capacity of will be insufficient. Since the period for performing the relay calculation is a very short period (for example, a period of every 30 electrical degrees), if the calculation of IEC61850 is interrupted during the relay calculation, the relay calculation process cannot catch up. Sometimes.

  On the other hand, when adding externally, there are a large number of protection relay devices that are already in operation. Therefore, a large-scale system configuration change that replaces these protection relay devices with another device should be avoided as much as possible. It is. That is, even after complying with IEC61850, it is required to reduce the cost of the system by diverting the protection relay device that is already in operation as much as possible.

  Therefore, the main object of the present invention is to solve the above-described problems and to automate the management of the power equipment management system at a low cost.

In order to solve the above problems, the present invention provides a protection relay device having a first control unit that outputs an operation signal to a power facility based on a measured value from the power facility, and power for managing the power facility. A facility management device used in a power management system configured to include a grid management device, a facility management device that relays management data between the protection relay device and the power grid management device,
The second control unit included in the facility management apparatus is
At least one of the measured value input to the first control unit and the operation signal output from the first control unit from the management data storage unit in the protection relay device is used as management data. reading,
The read management data and the management rules stored in the storage means in the facility management device are collated to determine whether or not the read management data is to be notified, and the notification The management data determined to be the target is notified to the power system management device.
Other means will be described later.

  According to the present invention, the power equipment management system can be automated and managed at low cost.

It is a block diagram which shows the electric power equipment management system regarding one Embodiment of this invention. It is a block diagram which shows another example of the electric power equipment management system regarding one Embodiment of this invention. It is explanatory drawing which shows the relay calculation regarding one Embodiment of this invention. It is a flowchart which shows the independent operation | movement of the protection relay apparatus regarding one Embodiment of this invention. It is a flowchart which shows the cooperation operation | movement with the protection relay apparatus and equipment management apparatus regarding one Embodiment of this invention.

  Hereinafter, an embodiment of the present invention will be described in detail with reference to FIGS.

FIG. 1 is a configuration diagram showing a power equipment management system.
The power transmission line 30 as a power facility has a current transformer 32 that measures a power parameter (voltage value, current value, etc.) near the terminal 31 for each terminal 31 that is an end point thereof, and a cutoff that cuts off power near the terminal 31. A vessel 34 is provided.
FIG. 1 shows an example in which one power transmission line 30 has two terminals 31. The protection relay device 10 is connected to a left terminal 31 (a set of a current transformer 32 and a breaker 34 in the vicinity) of the two terminals 31 via a first network 41.
The right terminal 31 of the two terminals 31 (a set of the current transformer 32 and the breaker 34 in the vicinity) is omitted from the illustration, but similarly, the protection relay is connected via the first network 41. A device 10 is connected.

The current transformer 32 continues to measure the power parameter of the attached power transmission line 30 and continues to transmit the measured value as a measurement signal from the measurement signal line 33 to the first communication unit 12 via the first network 41. .
When the circuit breaker 34 receives a cut-off signal (also called a trip command) as an operation signal from the operation signal line 35 via the first network 41, the circuit breaker 34 cuts off the power of the attached power transmission line 30.
When the circuit breaker 34 receives a closing signal as an operation signal from the operation signal line 35 via the first network 41, the circuit breaker 34 releases the power interruption of the attached power transmission line 30 (makes electricity flow).

  Thus, the signal exchanged via the first network 41 needs to be transmitted in a short time between the protection relay device 10 and the power equipment (current transformer 32, circuit breaker 34). The one network 41 is preferably a high-speed (particularly low delay) network capable of real-time communication.

The protection relay device 10 is a device that detects an accident in the power system from information obtained by measuring (sampling) power parameters (such as AC power of the power system), and includes a first CPU (Central Processing Unit) 11, 1 communication unit 12, management data storage unit 13, first CPU bus 14, communication bus 15, and first connector 16.
The first CPU 11 (first control unit) is configured as, for example, a built-in CPU that can perform processing in real time. The first CPU 11 directly performs exchange (relay calculation) with the power equipment (current transformer 32, circuit breaker 34), but does not directly exchange with the power system management device 43 (calculation related to substation automation), which will be described later. The second CPU 21 is substituted. The relay calculation is, for example, an operation for transmitting a cutoff signal to the operation signal line 35 when the voltage value received from the measurement signal line 33 is equal to or higher than the overvoltage threshold.

The first communication unit 12 is a communication interface that relays communication data between the first CPU 11 and the first network 41 via the first CPU bus 14. The first CPU bus 14 connects the first CPU 11, the first communication unit 12, and the management data storage unit 13.
The communication bus 15 connects the management data storage unit 13 and the first connector 16. The first connector 16 is connected to the second connector 26 via the inter-device network 44. The inter-device network 44 may be configured as, for example, a LAN (Local Area Network) such as Ethernet (registered trademark), or a bus corresponding to a parallel interface in a computer such as a PCI (Peripheral Component Interconnect) bus. It may be configured.

The management data storage unit 13 is a memory in which management data for substation automation is stored. The management data storage unit 13 includes a dual-port RAM (Random Access Memory) that separately configures a first port for accessing from the first CPU bus 14 and a second port for accessing from the communication bus 15. It is desirable to use it. Thus, only the first port is used when the protection relay device 10 operates alone, and the first port and the second port are used when the protection relay device 10 and the facility management device 20 operate in parallel, respectively.
Furthermore, as shown in FIG. 1, the management data storage unit 13 may be configured as a memory card that can be attached to and detached from the protection relay device 10 instead of the configuration built in the protection relay device 10. It is good also as a structure incorporated in the equipment management apparatus 20. FIG.

The facility management apparatus 20 includes a second CPU 21, a second communication unit 22, a second CPU bus 23, and a second connector 26. The second CPU bus 23 connects the second CPU 21, the second communication unit 22, and the second connector 26.
The second CPU 21 (second control unit) has data access (data read, data write) means for the management data storage unit 13 and also manages the power system based on the management data in the management data storage unit 13. Control signals related to substation automation are exchanged with the device 43.
The second communication unit 22 is connected to the power system management device 43 via the second network 42. The second network 42 is not required to be as fast as the first network 41. For example, general-purpose serial transmission such as Ethernet on an IP (Internet Protocol) network or a field bus from the viewpoint of versatility and low cost. Consists of means.

  The power system management device 43 is a device that manages each power device (current transformer 32, circuit breaker 34) by transmitting a data acquisition request or a data write request to the protection relay device 10. . The power system management device 43 is configured as a monitoring device corresponding to IEC 61850, for example.

FIG. 2 is a configuration diagram illustrating another example of the power equipment management system. Comparing FIG. 1 with FIG. 2, in FIG. 1, one facility management device 20 is connected to one protection relay device 10, whereas in FIG. 2, three protection relay devices 10 are connected. In this configuration, one equipment management device 20 is connected.
In this way, one facility management device 20 is connected to a plurality of protection relay devices 10, and one facility management device 20 collects management data of each protection relay device 10 connected to the power system. By relaying to the management device 43, a power equipment management system compatible with IEC 61850 can be realized with a small number of devices, and system introduction costs and operation costs can be reduced.

FIG. 3 is an explanatory diagram showing the relay calculation. 3A is a time series graph of a measurement signal (voltage value) input to the protection relay device 10 via the measurement signal line 33, and FIG. 3B is protected via the operation signal line 35. It is a time series graph of the operation signal (indicating that ON is not interrupted and indicating that OFF is interrupted) output from the relay device 10.
For example, the measured voltage value exceeds the overvoltage threshold in the time period from time t1 to time t2 in FIG. Therefore, the first CPU 11 outputs an operation signal for shutting off as shown in FIG. 3B in the time period from time t1 to time t2.

  FIG. 4 is a flowchart showing a single operation of the protection relay device. The operation of FIG. 4 is performed when the protection relay device 10 is not connected to the facility management device 20 (in FIG. 1, when the first connector 16 cannot communicate with the second connector 26 via the inter-device network 44). The first CPU 11 is the operation subject.

As S <b> 11, the first CPU 11 receives a measurement signal from the current transformer 32 via the measurement signal line 33.
As S12, the first CPU 11 determines whether or not the value of the measurement signal received in S11 satisfies a predetermined condition (for example, whether or not the measured voltage value exceeds the overvoltage threshold in FIG. 3A). )).
As S13, the first CPU 11 creates an operation signal to the circuit breaker 34 based on the determination result of S12. For example, when the voltage value measured in S12 exceeds the overvoltage threshold value, the first CPU 11 creates an operation signal to cut off (see FIG. 3B).
As S <b> 14, the first CPU 11 notifies the circuit breaker 34 of the operation signal created in S <b> 13 via the operation signal line 35.

  As described above, the relay calculation described in S11 to S14 is repeatedly performed on the latest measurement signal because the measurement signal is continuously measured in time series. Thus, even when the protection relay device 10 is not connected to the facility management device 20, it operates as a single device.

  FIG. 5 is a flowchart showing the cooperative operation of the protection relay device and the facility management device. Since the operation of the relay calculation (S11 to S14) in the protection relay device 10 is the same as that in FIG. 4, it will be omitted from the description of FIG.

  In S15, the first CPU 11 stores the measurement signal received in S11, the operation signal created in S13, and the like as management data for its own device (protection relay device 10) via the first CPU bus 14. Part 13 is recorded. The first CPU 11 also records information (such as the CPU usage rate of the first CPU 11 and the CPU temperature) related to its own device (the protection relay device 10) as other management data in the management data storage unit 13. May be.

The recording process of management data in the management data storage unit 13 is realized by a communication process as exemplified below.
The first CPU 11 transmits to the first CPU bus 14 a signal that explicitly instructs the management data storage unit 13 to record the management data.
The device driver of the management data storage unit 13 monitors the management data signal flowing on the first CPU bus 14, reads it when it flows, and records it in its management data storage unit 13 .
The signal transmitted and received by the first communication unit 12 with the first CPU 11 is copied and transmitted not only to the first CPU 11 but also to the management data storage unit 13 for the transmission / reception destination of the signal.

  Hereinafter, the operation (operation for making it correspond to IEC61850) in which the second CPU 21 of the facility management apparatus 20 in the operation of FIG.

As S21, the second CPU 21 receives the management rule and stores it in its own storage means (not shown). This management rule is, for example, “when the period during which the circuit breaker 34 cuts off the power of the transmission line 30 exceeds 3 minutes, notifies the power system management device 43 to that effect”. This is a rule used by the system management device 43 to manage power facilities.
As a management rule setting method, the power system management device 43 that is the notification destination may transmit via the second network 42, or the manager of the substation directly manages the management rules to the facility management device 20. May be input (setting file, DIP switch, etc.).

As S <b> 22, the second CPU 21 receives the management data recorded in the management data storage unit 13 in S <b> 15 from the protection relay device 10. Specifically, the second CPU 21 transmits a data read instruction through a route of the second CPU bus 23 → the second connector 26 → the inter-device network 44 → the first connector 16 → the communication bus 15 → the management data storage unit 13. The protection relay device 10 reads out the corresponding data from the management data storage unit 13 in accordance with the received data read instruction, and replies to the second CPU 21 by following the path of the data acquisition request in the reverse direction.
The second CPU 21 includes a memory access unit that can handle a large memory space in the management data storage unit 13 in order to read desired management data from the management data storage unit 13.

As S23, the second CPU 21 collates the management rule of S21 with the management data of S22, and determines whether or not the management data corresponds to the management rule. If Yes in S23, the process proceeds to S24, and if No, the process returns to S22. For example, the following combinations are determined to be applicable (S23, Yes).
Management rule “When the period during which the circuit breaker 34 cuts off the power of the power transmission line 30 exceeds 3 minutes, this is notified to the power system management device 43”
Management data “The operation signal remains OFF from 11:00 am to 11:10 am”

  As S <b> 24, the second CPU 21 notifies the management data of S <b> 22 to the power system management device 43 via the second network 42. As a result, the power system management device 43 can access the data in the management data storage unit 13 via the facility management device 20 without directly controlling the protection relay device 10.

  The second CPU 21 may perform not only data reading in the management data storage unit 13 but also data writing in the management data storage unit 13 as S24. For example, when the data transmitted from the power system management device 43 to the facility management device 20 is an “emergency cut-off signal”, the second CPU 21 has an operation signal indicating cut-off with respect to the circuit breaker 34 in the management data storage unit 13. Write out. Then, the first CPU 11 transmits the operation signal indicating the interruption written in the management data storage unit 13 to the circuit breaker 34 regardless of whether or not the measurement value measured by the current transformer 32 is normal. .

In this embodiment described above, the power management system is configured such that the equipment management device 20 is added to the protection relay device 10. Since the protection relay device 10 has an interface (first connector 16) for connecting to the facility management device 20, the facility management device 20 can be easily attached and detached.
Thereby, since the existing protection relay apparatus 10 can be utilized, a power equipment management system can be managed and automated at a low cost.

10 protection relay device 11 first CPU (first control unit)
12 1st communication part 13 Management data storage part 14 1st CPU bus 15 Communication bus 16 1st connector 20 Equipment management device 21 2nd CPU (2nd control part)
22 2nd communication part 23 2nd CPU bus 26 2nd connector 30 Power transmission line 31 Terminal 32 Current transformer 33 Measurement signal line 34 Circuit breaker 35 Operation signal line 41 1st network 42 2nd network 43 Power system management apparatus 44 Network between apparatuses

Claims (5)

A protection relay device having a first control unit that outputs an operation signal to the power facility based on a measurement value from the power facility, a power system management device that manages the power facility, the protection relay device, and the power A facility management device used in a power facility management system including a facility management device that relays management data to and from a system management device,
The second control unit included in the facility management apparatus is
At least one of the measured value input to the first control unit and the operation signal output from the first control unit from the management data storage unit in the protection relay device is used as management data. reading,
The read management data and the management rules stored in the storage means in the facility management device are collated to determine whether or not the read management data is to be notified, and the notification The management data determined to be a target is notified to the power system management device. The said 2nd control part which the said equipment management apparatus has reads the said management data from the said management data storage part of each of the said several protection relay apparatus connected, The said management data are characterized by the above-mentioned. Equipment management device. The equipment management apparatus according to claim 1, wherein the management data storage unit is built in the equipment management apparatus instead of being built in the protection relay apparatus.   A power equipment management system comprising the equipment management apparatus according to any one of claims 1 to 3, the power system management apparatus, and the protection relay device. A protection relay device having a first control unit that outputs an operation signal to the power facility based on a measurement value from the power facility, a power system management device that manages the power facility, the protection relay device, and the power A facility management method executed by the facility management device used in a power facility management system including a facility management device that relays management data to and from a system management device,
The second control unit included in the facility management apparatus is
At least one of the measured value input to the first control unit and the operation signal output from the first control unit from the management data storage unit in the protection relay device is used as management data. reading,
The read management data and the management rules stored in the storage means in the facility management device are collated to determine whether or not the read management data is to be notified, and the notification The management data determined to be the target is notified to the power system management device.

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