JP2017034751A - Monitoring control system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a monitoring control system capable of creating a procedure table without any error.SOLUTION: A monitoring control system comprises a monitoring control device 10 for performing monitoring control on a power system. The monitoring control device 10 includes: a creation unit 11a for creating a procedure table for instructing operation including planned stop of a facility in the power system and change of the power system; and a control unit 11b for executing the operation on the basis of the procedure table created by the creation unit 11a.SELECTED DRAWING: Figure 14

Description

  The present invention relates to a monitoring control system that monitors and controls a power system.

  In the power grid, the power generated at the power station is supplied to the primary transmission line, the power transmitted through the primary transmission line is stepped down at the power transmission substation and supplied to the secondary power transmission line, and then at the distribution substation. The voltage is stepped down and supplied to the distribution line. A monitoring control system is known as a system for monitoring and controlling such a power system. For example, Patent Document 1 below discloses a system control system that monitors and controls a power transmission system (such as a switching substation for a power transmission substation) in a power system, and a power distribution system (such as a distribution substation and a distribution line) in the power system. A monitoring and control system comprising a power distribution control system that monitors and controls the open / close facilities of equipment, and a facility state monitoring system that monitors the state of equipment at substations in the power system (transmission system, distribution system) and supports maintenance work Have been described.

  In this monitoring control system, the system control system, the power distribution control system, and the equipment state monitoring system are each directly connected by a control communication line. In addition, facilities (substation equipment, etc.) that are already installed in a plurality of substations (transmission substations, distribution substations) are connected via remote monitoring and control devices (TC: telecontrol units) and signal conversion devices. Connected directly to the control communication line. In addition, equipment newly installed in a plurality of substations is directly connected to a control communication line via a transmission device.

JP 2009-65778 A

  In the monitoring and control system in Patent Document 1, the system control system performs operations such as scheduled stop of equipment in the power system (for example, power transmission system) and change of the power system based on the procedure table. However, if an incorrect procedure table that does not correspond to an operation such as a scheduled stop is created at the time of creating the procedure table, an incorrect operation will be executed, causing an accident or the like.

  The present invention has been made in view of the above-described circumstances, and an object thereof is to provide a monitoring control system capable of creating a procedure table without mistakes.

  In order to achieve the above object, the present invention is a supervisory control system including a supervisory control device that supervises and controls a power system, and the supervisory control device is an operation that includes scheduled shutdown of equipment and a change of the power system in the power system. A monitoring control system is provided that includes a creation unit that creates a procedure table for instructing and a control unit that executes an operation based on the procedure table created by the creation unit.

  Moreover, the structure which equips and memorize | stores the operation procedure of an equipment and a subject may be provided, and a preparation part may produce the procedure table | surface based on the operation procedure corresponding to the subject of the operation object memorize | stored in the database. In addition, the monitoring and control device monitors the charge / power failure state of the facility in the power system, and manages the first information for managing the charge / power failure state of the facility to be monitored and the information of the facility to be monitored in the power failure state. The information transmission part which transmits 2nd information of this to the terminal of an electric power station may be sufficient.

  Moreover, the structure which performs control of this installation on condition that the control part has acquired the control right with respect to the installation in an electric power grid | system may be sufficient. Moreover, the structure which has the accident information transmission part which produces the information regarding the accident including the power failure in an electric power grid | system, and transmits the information regarding the created accident to the relevant location containing a power station may be sufficient as a monitoring control apparatus. In addition, the monitoring and control apparatus may have a configuration including a power failure information posting unit that creates power failure information in the power system and posts the created power failure information on the Web.

  In the present invention, a creation unit that creates a procedure table for instructing operations including planned shutdown of the facility in the power system and a change in the power system, and a control unit that performs the operation based on the procedure table created by the creation unit, Therefore, it is possible to create a procedure table for instructing an operation without mistake and execute the operation based on the created procedure table.

It is a system configuration figure showing the composition of the supervisory control system concerning a 1st embodiment of the present invention. It is a figure which shows arrangement | positioning of the data center shown in FIG. It is a block diagram which shows the 1st example of a connection of GW and FGW shown in FIG. It is a block diagram which shows the 2nd example of connection of GW and FGW shown in FIG. It is a figure which shows the application structure of the monitoring control system which concerns on 1st Embodiment of this invention. It is a figure which shows the system monitoring control application. It is a figure which shows the application of power distribution monitoring control. It is a figure which shows the application of integrated network equipment management. It is a figure which shows an example of a data format structure. It is a sequence diagram which shows the transmission control procedure of the information between the system side and the substation side. It is a flowchart which shows the process which GW and TC perform. It is a flowchart which shows the process which FGW performs. It is a figure which shows the network structure of the monitoring control system which concerns on 1st Embodiment of this invention. It is a block diagram which shows the structure of the system monitoring control subsystem of a feeding station and a monitoring control apparatus. It is a figure which shows an example of the transformer in a substation. It is a figure which shows the example of the operation command procedure table in the transformer shown in FIG. 15, and an apparatus separate operation procedure table. It is a system configuration figure showing the composition of the supervisory control system concerning a 2nd embodiment of the present invention. It is a block diagram which shows the structure of the monitoring control system which concerns on 3rd Embodiment of this invention. It is a block diagram which shows the structure of the monitoring control system which concerns on 3rd Embodiment of this invention.

  Embodiments of the present invention will be described below with reference to the drawings. However, the present invention is not limited to this. Further, in the drawings, in order to describe the embodiment, the scale may be appropriately changed and expressed, for example, partly enlarged or emphasized.

<First Embodiment>
FIG. 1 is a system configuration diagram showing a configuration of a monitoring control system SYS-A according to the first embodiment of the present invention. A supervisory control system SYS-A shown in FIG. 1 is a system that monitors and controls a power system. As shown in FIG. 1, the supervisory control system SYS-A includes a supervisory controller 10, front end processors 15a and 15b (hereinafter referred to as FEP), gateways 31, 41 and 51 (hereinafter referred to as GW), TC61, and so on. 71 (TC: telecontrol unit, remote monitoring and control device), field gateways 62 and 72 (hereinafter referred to as FGW), relay device 55, power network model database 91 (hereinafter referred to as power NW model DB), procedure and subject A database 92 (hereinafter referred to as “procedure / subject DB”), a data warehouse 93, a DX link 94, and an external system 100 are provided. Note that the supervisory control system SYS-A includes a plurality of substation equipment 63, 64, 73, and 74, which are control target equipment in a substation, etc. It may be defined that the configuration includes (22 kV line selection).

  The power system is monitored and controlled by the data center 1. FIG. 2 is a diagram showing an arrangement of the data center 1 shown in FIG. In the example shown in FIG. 2, three data centers 1 </ b> A, 1 </ b> B, and 1 </ b> C are provided as three locations as the data center 1. FIG. 1 shows only the data center 1A. The data center 1A is a main data center that monitors and controls the power system during normal times. The first sub-data center 1B and the second sub-data center 1C are emergency backups for continuously executing power system monitoring control when an abnormality such as a failure occurs in the monitoring control device 10 of the data center 1A. Time is the data center. The three data centers 1A, 1B, and 1C are provided at different locations (geographically separated locations), respectively (see server bases 300, 310, and 320 in FIG. 13 described later). In the present embodiment, the three data centers 1A, 1B, and 1C may be collectively referred to as the data center 1.

  The monitoring control device 10, the real-time service bus 14, the FEPs 15a and 15b, the operation service bus 110, and the system operation service bus 111 are installed in the data centers 1A, 1B, and 1C, respectively. That is, any data center 1A, 1B, 1C is provided with a monitoring control device, a real-time service bus, an FEP, an operation service bus, and a system operation service bus having the same configuration. In the present embodiment, the power NW model DB 91, the procedure / subject DB 92, the data warehouse 93, the DX linkage 94, and the external system 100 are provided only in the data center 1A.

  When an abnormality occurs in the monitoring control device 10 of the data center 1A, the first sub data center 1B becomes the main data center, and the monitoring control device of the first sub data center 1B monitors and controls the power system. Further, when an abnormality occurs in the monitoring control devices of the data center 1A and the first sub data center 1B, the second sub data center 1C becomes the main data center, and the monitoring control device of the second sub data center 1C uses the power system. Monitor and control. In this embodiment, since the two sub data centers 1B and 1C are provided, when the test of the monitoring control device of the first sub data center 1B is performed, the monitoring control device of the second sub data center 1C is used. Backup of the monitoring control device 10 of the data center 1A can be performed. Similarly, when the monitoring control device of the second sub data center 1C is being tested, the monitoring control device 10 of the data center 1A can be backed up by the monitoring control device of the first sub data center 1B. In the present embodiment, information from the monitoring control device to the substation and distribution equipment is sent from the main data center monitoring control device, and information from the substation and distribution equipment to the monitoring control device is , Sent to the supervisory control unit of all data centers (main and sub data centers).

  The monitoring control device 10 is a device for monitoring and controlling the power system. As shown in FIG. 1, the monitoring control device 10 is connected to a real-time service bus 14, an operation service bus 110, and a system operation service bus 111. As shown in FIG. 1, the monitoring control device 10 includes a system monitoring control subsystem 11, a power distribution monitoring control subsystem 12, and an integrated network facility management subsystem 13 (hereinafter referred to as an integrated NW facility management subsystem). It is configured. The current supervisory control system is a collection of a plurality of systems such as system control, power distribution control, and equipment state monitoring, which are installed at different locations. In the supervisory control system SYS-A of this embodiment, each sub The systems 11, 12, and 13 operate as an integrated system.

  The system monitoring control subsystem 11, the power distribution monitoring control subsystem 12, and the integrated NW facility management subsystem 13 are subsystems configured for different purposes in order to execute monitoring control of the power system. The system monitoring control subsystem 11, the power distribution monitoring control subsystem 12, and the integrated NW facility management subsystem 13 are configured by one or a plurality of servers. Although not shown in FIG. 1, each of the system monitoring control subsystem 11, the power distribution monitoring control subsystem 12, and the integrated NW facility management subsystem 13 includes a database for managing information. A database common to each subsystem 11, 12, 13 may be provided.

  The system monitoring and control subsystem 11 includes substation devices 63 and 64 (for example, transformers, circuit breakers, and protection relays) of the power transmission substation 60 in a power transmission system (for example, a system of 66,000 V or more) in the power system. ) And other subsystems. This system supervisory control subsystem 11 has a supervisory control function (Supervisory Control And Data Acquisition: SCADA), an energy management system function (Energy Management System: EMS), other functions, and a power network model (power NW model) management function. It is configured as an integrated supervisory control system. Each of these functions has the following functions, for example.

(A) Functions provided as SCADA;
The system monitoring control subsystem 11 uses SCADA as “data transmission / reception”, “data acquisition from a communication device (device corresponding to GW31)”, “automatic acquisition of information according to setting and automatic control based on acquisition information” , “Remote error detection”, “Time synchronization”, “Access from control center (thin client)”, “Various data processing (analog / digital data, calculated data, topology, manual data, external registration data, etc.) "Sequence management of multiple events", "Monitoring control of various devices (isolator, earth switch, breaker, volt amper reactive power (VAR) control, tap change control, setpoint control, etc.)", "Monitoring information Accumulation and recovery (circuit breaker shape Includes real-time snapshot, regular snapshot, event data, fault information, history, features such as message log, etc.) ".

(A) Functions provided as EMS;
The grid supervisory control subsystem 11 is an EMS that states “state evaluation (real-time measurement of voltage, etc. and state prediction / evaluation based on it, evaluation of various states based on operator instructions)”, “route calculation”, “ Tingency analysis (function for deriving the most stable operation plan based on various assumptions. Used for planned power outages, etc.), “Analysis to stabilize voltage”, “Short-circuit calculation”, “Power optimization , Security analysis, and contingency dispatch (providing proposals to achieve optimization goals based on various measurements such as power flow and voltage, etc.) Analyze, determine the most effective remedy to avoid constraints.) "," Voltage scheduler (minimize system control loss (reactive power) Supports the optimal device setting to make it easier.) ”.

(C) Other functions;
The system monitoring control subsystem 11 includes other functions such as “switch analysis”, “switch sequence instruction management”, “failure location detection and service recovery”, “planned power failure management”, “unplanned power failure management”, “prediction function” (Functional short-term, medium-term, long-term) "," various analysis, reporting (legal forms, reports for performance and quality analysis, etc.) ".

(D) Power network model (CIM model) management function;
The grid monitoring control subsystem 11 has a “grid monitoring control model management” function as a power network model (CIM model) management function.

  The distribution monitoring control subsystem 12 includes substation equipment 73 and 74 (for example, transformers, circuit breakers) of the distribution substation 70 in a distribution system (for example, 22,000 V or 6,000 V system) in the power system. , Protection relays) and distribution line switching facilities. The power distribution monitoring control subsystem 12 is an integrated monitoring control function having a monitoring control function (SCADA), a distribution management system function (Distribution Management System: DMS), other functions, and a power network model (CIM model) management function. Configured as a system. Each of these functions has the following functions, for example.

(A) Functions provided as SCADA;
The power distribution monitoring control subsystem 12 uses SCADA as “data transmission / reception”, “data acquisition from a communication device (device corresponding to the gateway 41)”, “automatic acquisition of information according to settings and automatic control based on the acquisition information” ”,“ Remote error detection ”,“ Time synchronization ”,“ Access from control center (thin client) ”,“ Various data processing (analog / digital data, calculated data, topology, manual data, external registration data, etc.) ) ”,“ Sequence management of multiple events ”,“ Monitoring control of various devices (isolator, earth switch, breaker, volt amper reactive power (VAR) control, tap change control, setpoint control, etc.) ”,“ various monitoring information Storage and recovery (circuit blurring) Equipped car state, real-time snapshot, regular snapshot, event data, fault information, history, features such as message log, etc.) ".

(A) Functions provided as DMS;
The power distribution monitoring and control subsystem 12 includes, as DMSs, “failure location detection and service recovery”, “switch analysis”, “switch sequence instruction management”, “volt ampere reactive power (VAR) optimization”, “unbalanced load flow”. , “Short-circuit analysis function”, “Power optimization (provides suggestions for achieving optimization targets based on various measured values such as power flow and voltage, etc.)”, “Voltage scheduler (Distribution control loss ( Supports the optimal device setting to minimize the reactive power))).

(C) Other functions;
The power distribution monitoring control subsystem 12 has other functions such as a “planned power outage management function” and an “unplanned power outage management function”.

(D) Power network model (CIM model) management function;
The power distribution monitoring control subsystem 12 has a function of “power distribution monitoring control model management” as a power network model (CIM model) management function.

  The integrated NW equipment management subsystem 13 is a system that supports the maintenance work by monitoring the state of the substation equipment (substation equipment 63, 64, 73, 74) in the power transmission / distribution system (transmission system, distribution system). This integrated NW facility management subsystem 13 is configured as a subsystem having a power network model management function that defines the configuration of facility equipment and IT equipment that span both system monitoring control and power distribution monitoring control.

  By managing the power network model of the supervisory control system SYS-A with the integrated NW equipment management subsystem 13, "maintenance of power network model consistency" and "reduction of manual work by creating a workflow of power network model management" , "Improvement of analysis speed when changing power network model", "Correlation of power network model on a CIM basis to reduce future cooperation cost of external system 100", "Improvement of power network model analysis ability" The effect that can be obtained. The “power network model management function” in the integrated NW facility management subsystem 13 includes the following functions, for example.

(A) Power network model (CIM model) management function;
The integrated NW equipment management subsystem 13 has a “power data model (CIM model) management function”, “collection function of existing data necessary for CIM model construction”, “CIM model management function (edit / verify / update function, model status) Management function, repository function, management of CIM model derived by subsystem, history management function (security function)), “CIM model cooperation function with system monitoring control subsystem 11, distribution monitoring control subsystem 12, and external system 100 (Validation check at the time of model import / export, format (style) management, workflow, model consistency management) "," providing data necessary for various analyzes ", etc.

  The system monitoring control subsystem 11, the power distribution monitoring control subsystem 12, and the integrated NW facility management subsystem 13 are each connected to a real-time service bus 14 that transmits information. The FEPs 15a and 15b are arranged in the data center 1 and connected to a real-time service bus 14 and a WAN 20 (Wide Area Network). The FEPs 15a and 15b perform aggregation and transmission / reception of information between the subsystems 11, 12, and 13 and the communication devices (GWs 31 and 41). Note that FEPs 15a and 15b are compatible with the various protocols described above, hardware is componentized to improve maintainability, component parts are redundant to ensure reliability, monitoring A security countermeasure function based on various security standards of the control system SYS-A, a time synchronization function, and the like are required.

  In the data center 1 (between the servers of the subsystems 11, 12, and 13), the ICCP (The Inter-Control Center Communications Protocol (ICCP or IEC 60870-6 /), which is a communication protocol (contract, data format) compliant with international standards. 2))) and IEC 60870-5-104, IEC 61850, IEC 61970, IEC 61968, and IEC 62351, information is communicated. Specifically, information is communicated between FEP 15a and FEP 15b according to ICCP, and information is communicated according to IEC 60870-5-104, IEC 61850, IEC 61970, IEC 61968, and IEC 62351 on real-time service bus 14.

  The GWs 31 and 41 are installed in the control stations 30 and 40 units. In the example shown in FIG. 1, a GW 31 is installed in the control station 30 and a GW 41 is installed in the control station 40. The GWs 31 and 41 are each connected to the WAN 20. The GWs 31 and 41 are connected only to the TCs 61 and 71 installed in the substations 60 and 70 (see the first connection example shown in FIG. 3), or both the TCs 61 and 71 and the FGWs 62 and 72 are connected. (See the second connection example shown in FIG. 4). That is, the FGWs 62 and 72 may be directly connected to the FEPs 15a and 15b, and the FGWs 62 and 72 may be connected to the FEPs 15a and 15b via the GWs 31 and 41.

  FIG. 3 is a block diagram showing a first connection example of the GWs 31 and 41 and the FGWs 62 and 72 shown in FIG. In the first connection example shown in FIG. 3, the GWs 31 and 41 installed in the control stations 30 and 40 are connected to the WAN 20 via the communication lines 150 of IEC60870-5-104 and IEC61850, which are communication protocols compliant with international standards, respectively. Has been. The GWs 31 and 41 are connected to the TCs 61 and 71 via communication lines 160 of HDLC (High Level Data Link Control) and CDT (Cyclic Data Transfer), which are communication protocols that do not comply with international standards, respectively. The FGWs 62 and 72 are connected to the WAN 20 via communication lines 170 of IEC 60870-5-104 and IEC 61850, which are communication protocols compliant with international standards.

  FIG. 4 is a block diagram showing a second connection example of the GWs 31 and 41 and the FGWs 62 and 72 shown in FIG. In the second connection example shown in FIG. 4, the GWs 31 and 41 installed in the control stations 30 and 40 are connected to the WAN 20 via communication lines 150 of IEC60870-5-104 and IEC61850, which are communication protocols compliant with international standards, respectively. Has been. The GWs 31 and 41 are connected to the TCs 61 and 71 via HDLC and CDT communication lines 160, which are communication protocols that do not comply with international standards, respectively. The FGWs 62 and 72 are connected to the GWs 31 and 41 via the communication line 180 of IEC 61850, which is a communication protocol compliant with international standards.

  Returning to the description of FIG. 1, the GWs 31 and 41 receive various information transmitted from the TCs 61 and 71 (or / and the FGWs 62 and 72), perform protocol conversion of the received information, and then return to the monitoring control device 10 side. Send. The GWs 31 and 41 receive information transmitted from the monitoring control apparatus 10 side, perform protocol conversion of the received information, and transmit the information to the TCs 61 and 71 (or / and FGWs 62 and 72). In FIG. 1, only two control stations 30 and 40 are shown, but actually, a plurality of control stations (for example, about 50 control stations) are provided, and a GW is installed at each control station. .

  The power transmission substation 60 is provided with a TC 61, an FGW 62, and substation equipment 63 and 64. For example, about 1200 power transmission substations 60 are provided. The TC 61 is connected to the GW 31 of the control station 30 through the communication line 160 shown in FIG. 3, and is connected to the substation equipment 63 through wiring. As shown in FIGS. 3 and 4, the substation equipment 63 includes a plurality of devices (substation equipment 63-1 to 63-n shown in FIGS. 3 and 4) connected to the TC 61. The TC 61 collects information from the substation equipment 63, converts the collected information into information (HDLC or CDT information) that can be transmitted through the communication line 160, and transmits the information to the GW 31. The TC 61 converts information (HDLC or CDT information) that can be transmitted through the communication line 160 from the GW 31 into information corresponding to the substation device 63 and transmits the information to the substation device 63.

  The FGW 62 is connected to the WAN 20 (that is, one of the FEPs 15a and 15b) via the communication line 170 in the first connection example shown in FIG. 3, or to the GW 31 of the control station 30 via the communication line 180 in the second connection example shown in FIG. It is connected. The FGW 62 is connected to the substation equipment 64 by wiring. As shown in FIGS. 3 and 4, the substation equipment 64 includes a plurality of devices (substation equipment 64-1 to 64-n shown in FIGS. 3 and 4) connected to the FGW 62. The FGW 62 collects information from the substation equipment 64, converts the collected information into information (IEC 61850 information) that can be transmitted through the communication line 170 or 180, and transmits the information to the WAN 20 or GW 31. In addition, the FGW 62 converts information (IEC 61850 information) that can be transmitted through the communication line 170 or 180 from the GW 31 into information corresponding to the substation device 64 and transmits the information to the substation device 64. When the FGW 62 transmits / receives information of the communication protocol (IEC61850) to / from the substation equipment 64, it is not necessary to convert the information when transmitting / receiving information to / from the WAN 20 or the GW 31. The FGW 62 includes a SAS (Substation Automation System) and an RTU (Remote Terminal Units).

  The substation devices 63 and 64 are devices (equipment) provided on the premises of the substation 60 and include devices such as a transformer, a circuit breaker, and a protection relay. Information on the substation equipment 63 and 64 includes on / off information on transformers and circuit breakers.

  Similarly to the power transmission substation 60, the distribution substation 70 is also provided with a TC 71, an FGW 72, and substation equipment 73 and 74. For example, about 1500 distribution substations 70 are provided. The TC 71 is connected to the GW 31 of the control station 30 through the communication line 160 shown in FIG. 3, and is connected to the substation equipment 73 through wiring. As shown in FIGS. 3 and 4, the substation equipment 73 includes a plurality of devices (substation equipment 73-1 to 73-n shown in FIGS. 3 and 4) connected to the TC 71. The TC 71 collects information from the substation equipment 73, converts the collected information into information (HDLC or CDT information) that can be transmitted through the communication line 160, and transmits the information to the GW 31. Further, the TC 71 converts information (HDLC or CDT information) that can be transmitted through the communication line 160 from the GW 31 into information corresponding to the substation equipment 73 and transmits the information to the substation equipment 73.

  The FGW 72 is connected to the WAN 20 (that is, one of the FEPs 15a and 15b) via the communication line 170 in the first connection example shown in FIG. 3, or to the GW 31 of the control station 30 via the communication line 180 in the second connection example shown in FIG. It is connected. The FGW 72 is connected to the substation equipment 74 by wiring. As shown in FIGS. 3 and 4, the substation equipment 74 includes a plurality of devices (substation equipment 74-1 to 74-n shown in FIGS. 3 and 4) connected to the FGW 72. The FGW 72 collects information from the substation equipment 74, converts the collected information into information (information of IEC 61850) that can be transmitted through the communication line 170 or 180, and transmits the information to the WAN 20 or the GW 31. Further, the FGW 72 converts information (information of IEC 61850) that can be transmitted through the communication line 170 or 180 from the GW 31 into information corresponding to the substation equipment 74 and transmits the information to the substation equipment 74. Note that when the FGW 72 transmits / receives communication protocol (IEC 61850) information to / from the substation equipment 74, it is not necessary to convert the information when transmitting / receiving information to / from the WAN 20 or the GW 31. The FGW 72 includes a SAS (Substation Automation System) and an RTU (Remote Terminal Units).

  The substation equipment 73 and 74 are also equipment (equipment) provided in the premises of the substation 70 and include equipment such as a transformer, a circuit breaker, and a protection relay. Information on the substation equipment 73 and 74 includes on / off information on transformers and circuit breakers.

  In the present embodiment, the GWs 31 and 41, the TCs 61 and 71, and the FGWs 62 and 72 constitute a “relay device”. In the case of the first connection example shown in FIG. 3, the GWs 31 and 41 and the TCs 61 and 71 constitute a “first relay unit”, and the FGWs 62 and 72 constitute a “second relay unit”. The FGWs 62 and 72 constitute a “gateway”. In the case of the second connection example illustrated in FIG. 4, the GWs 31 and 41 and the TCs 61 and 71 constitute a “first relay unit”, and the GWs 31 and 41 and the FGWs 62 and 72 constitute a “second relay unit”. That is, the GWs 31 and 41 are shared by the “first relay unit” and the “second relay unit”. Further, the GWs 31 and 41 constitute a “first gateway” in the second relay unit, and the FGWs 62 and 72 constitute a “second gateway” in the second relay unit.

  Although not shown in FIG. 1, substation equipment (for example, equipment connected to other than TC71 of distribution substation 70, equipment of outdoor distributed substation) is not connected to TC or FGW, but via an interface. Some are connected to the GWs 31 and 41. In this case, the interface transmits information on the communication protocol of the outdoor distributed system from the substation equipment to the GWs 31 and 41 via a communication line (LAN: Local Area Network). Then, the GWs 31 and 41 perform protocol conversion on the information from the interface, and transmit the information after the protocol conversion to one of the FEPs 15a and 15b via the WAN 20. Note that the interface may be directly connected to the WAN 20 via a communication line. In this case, the interface transmits information on the communication protocol of the outdoor distributed system from the substation equipment to the WAN 20 (a shift between the FEPs 15a and 15b). One of the FEPs 15 a and 15 b converts the information of the outdoor distributed communication protocol from the power distribution device 81 into the information of the international standard protocol, and transmits the converted information to the monitoring control device 10.

  In the current monitoring and control system, information is transmitted and received by TCs 61 and 71 which are existing facilities in the substations 60 and 70. However, TCs 61 and 71 are sequentially replaced with FGWs 62 and 72 which are international standard facilities. It is done. Currently, for example, thousands of TCs 61 and 71 are provided.

  The TCs 61 and 71 and the FGWs 62 and 72 are compatible with the above-described various protocols, the hardware has redundant components to ensure reliability, and is sufficient for connecting multiple TCs and substation equipment. Secure ports, automatic recovery after power failure (return to the initial state based on startup / configuration control), error information can be transmitted to the server side at the time of recovery, Can be operated both remotely from the remote and directly through the port, remote operation, providing tools for direct operation, holding a battery to retain data and time in case of power failure, monitoring Having security countermeasure function based on various security standards of control system, self, connected TC, and substation equipment Monitor the operation to detect the failure, to be able to store the error information, the server (the monitoring control device 10) can be transmitted error information to the side, that there is a time synchronization function, etc. are required.

  In addition to the above-described substation devices 63 and 64 of the power transmission substation 60 and the substation devices 73 and 74 of the distribution substation 70, the distribution target devices (equipment) in the monitoring control system SYS-A 81, distribution tower equipment 82, IT switch 83, and 22kV line selection 84. These power distribution equipment 81, power distribution tower equipment 82, IT switch 83 and 22 kV line selection 84 are referred to as power distribution equipment 80. The power distribution facility 80 is already connected by a dedicated control line or the like, and it is difficult to unify it into an international standard communication network.

  As shown in FIG. 1, the power distribution equipment 81 and the power distribution tower equipment 82 are connected to a relay equipment 55 provided at the relay station. The relay device 55 is connected to a GW 51 provided in the control station 50 through an HDLC communication line. The relay device 55 converts the information from the power distribution device 81 and the power distribution tower facility 82 into information of the HDLC communication protocol, and transmits the converted information to the GW 51 provided in the control center 50. The GW 51 transmits the information transmitted from the relay device 55 to one of the FEPs 15a and 15b via the WAN 20. One of the FEPs 15 a and 15 b converts the HDLC communication protocol information from the GW 51 into international standard protocol information, and transmits the converted information to the monitoring control device 10.

  As shown in FIG. 1, the IT switch 83 is an automatic switch with a built-in sensor. The IT switch 83 is connected to the GW 51 via a communication line of SC-D communication protocol, for example. The IT switch 83 transmits information indicating the open / close state to the GW 51, and the GW 51 transmits information from the IT switch 83 to one of the FEPs 15a and 15b via the WAN 20. The 22 kV line selection 84 is a transformer (22 kV line selection type transformer) that selects the 22 kV line. The 22 kV line selection 84 is connected to the GW 51 by a communication line of a line selection type communication protocol, for example. The 22 kV line selection 84 transmits information indicating the selection state to the GW 51, and the GW 51 transmits information from the 22 kV line selection 84 to one of the FEPs 15 a and 15 b via the WAN 20.

  As shown in FIG. 1, the WAN 20 is connected to an operation service bus 110 and a system operation service bus 111 provided in each data center 1A, 1B, 1C. In the operation service bus 110 and the system operation service bus 111, information is communicated using a communication protocol such as IEC 61970, IEC 61968, and IEC 62235, for example.

  The operation service bus 110 is connected to the system monitoring control subsystem 11, the power distribution monitoring control subsystem 12, and the integrated NW facility management subsystem 13, and transmits and receives information between the subsystems 11, 12, and 13. In addition, each subsystem 11, 12, 13 does not pass through the real-time service bus 14 and the FEPs 15a, 15b, but through the operation service bus 110 and the WAN 20, GWs 31, 41, 51 (substations 60, 70 and distribution facilities 80). Device) can send and receive information.

  The system operation service bus 111 is connected to the power NW model DB 91, the procedure / subject DB 92, and the data warehouse 93. The power NW model DB 91 is a database that stores a power NW model. The procedure / subject DB 92 is a database that stores operation procedures and subtitles associated with substations, distribution line switching facilities, and the like in association with each other. The data warehouse 93 is a device that stores various data. Each of the subsystems 11, 12, and 13 of the monitoring control device 10 can receive information on the power NW model DB 91, the procedure / subject DB 92 and the data warehouse 93 via the system operation service bus 111. In addition, the data storage unit (the power NW model DB 91, the procedure / subject DB 92, and the data warehouse 93) stores information on the devices of the power transmission substation 60, the power distribution substation 70, and the power distribution facility 80 in the WAN 20 and the system operation service bus 111. Can be obtained and stored via

  The real-time service bus 14 and the system operation service bus 111 are connected to the external system 100, respectively. The external system 100 includes inter-application linkages 101 and 102, an enterprise service bus 103, and a tool 104. The inter-application cooperation 101 is connected to the real-time service bus 14 and the enterprise service bus 103 and cooperates between the applications of the subsystems 11, 12, and 13 and the application of the tool 104. As a result, information can be exchanged between the subsystems 11, 12, and 13 and the tool 104. In addition, the inter-application cooperation 102 is connected to the system operation service bus 111 and the enterprise service bus 103, and the application of the tool 104 and the application of the data storage unit (the power NW model DB 91, the procedure / subject name DB 92, and the data warehouse 93). Link between. As a result, information can be exchanged between the tool 104 and the data storage unit.

  The tool 104 uses information handled by the monitoring control device 10 and information stored in the data storage units 91, 92, and 93 to store and manage information, design a power network model, analyze information, and plan (plan) ), Market operations, asset management, etc. The tool 104 can acquire information stored in the monitoring control apparatus 10 via the real-time service bus 14, the inter-application cooperation 101, and the enterprise service bus 103. Further, the tool 104 can acquire information stored in the data storage units 91, 92, and 93 via the system operation service bus 111, the inter-application cooperation 102, and the enterprise service bus 103. In the enterprise service bus 103, information communication is performed using communication protocols of IEC61970, IEC61968, and IEC62235.

  As shown in FIG. 1, the monitoring and control apparatus 10 includes a DX network (not shown) that is a communication line that does not conform to the international standard via the system operation service bus 111, the DX cooperation 94, and the DX-GW apparatus 105. It cooperates with an external system (external system different from the external system 100) existing on (DX: Data Exchanger). The DX network is a non-Internet protocol transmission network for transmitting and receiving information between external systems installed at a power supply station and a control station. The DX cooperation 94 is connected to the system operation service bus 111 and the DX-GW apparatus 105. The DX-GW apparatus 105 converts non-international standard communication protocol information and IP communication protocol information in the DX network.

  Although not shown in FIG. 1, a system control thin client, a power distribution control thin client, and an integrated NW facility management thin client, which are executed as monitoring and control tasks by a user (user) of the monitoring control system SYS-A, Is provided. The thin client executes monitoring control work processing in the monitoring control system SYS-A, and concentrates and executes almost all processing on the server (monitoring control device 10). The thin client for system control, the thin client for power distribution control, and the thin client for integrated NW facility management are the monitoring control system SYS-A according to any of the communication protocols of ICA (IndependenTC Client Architecture), PC Over IP, and RDP (Remote Desktop Protocol). (That is, the server of the monitoring control device 10) is configured to be able to execute information communication.

  Next, an application configuration of the monitoring control system SYS-A will be described. FIG. 5 is a diagram showing an application configuration of the supervisory control system SYS-A according to the first embodiment of the present invention. The monitoring control system SYS-A shown in FIG. 5 includes, as applications, a system monitoring control 201, a power distribution monitoring control 202, a comprehensive NW facility management 203, a user interface (user IF) 210, an external system linkage 220, and a front end processor (FEP). 230 and a gateway 240.

  The system monitoring control 201 is an application for configuring the system monitoring control subsystem 11, and provides functions necessary for the control work of the power transmission system and the maintenance work of the control target equipment (substation equipment 63, 64) of the power transmission system. To do. The functions of the system monitoring control 201 are divided into a monitoring control function (SCADA), an energy management system function (EMS), other functions, and a power NW model management function.

  FIG. 6 is a diagram illustrating an application of the system monitoring control 201. As shown in FIG. 6, the application of the monitoring control function of the system monitoring control 201 includes monitoring, operation procedure table creation / confirmation, control (manual / automatic), detection / notification, stop plan management, power optimization, system diagram management System monitoring control application configuration management, training simulator, CC recording statistics, CIM model, system board display function, multipurpose display function, and telephone function.

Monitoring;
・ The application captures various data (equipment information / measurement information) transmitted from field devices that are subject to transmission system control, and provides real-time information necessary for status change / accident detection, power outage monitoring, and accident facility judgment. Edit with and display to the user.
・ This application edits information for monitoring each of current, voltage, current, equipment abnormality, water level, flow rate, etc. in real time and displays it to the user.
-Switch display contents and view based on user instructions.
・ This application stores information such as status changes and accidents based on user instructions or automatically.

Operation procedure table creation and confirmation;
This application provides functions for the user to create / update, apply / approve, store, and output an operation procedure table (system operation operation procedure) related to the power transmission system operation function.
This application automatically generates and stores an operation procedure table (control record) for direct control that is not based on an approved operation procedure table, based on the control results.
-The user creates, updates, and stores the operation procedure table template in the application. An individual procedure table can be created based on the stored operation procedure table template.

Control (manual / automatic);
-The user controls the power transmission system using the application. There are both control based on the operation procedure table and direct control (individual operation).
・ Application performs some automatic control based on monitoring information.

Detection / reporting;
-Upon detection of a transmission system fault in the monitoring application, this application edits accident-related information and displays it to the user. Integrated NW equipment management subsystem 13: Link accident information to accident record management.
-The user uses the alarm device in this application to make a report (voice report) to the relevant places.
-The user creates a maintenance request using this application and notifies the maintenance staff.
-The user creates power outage accident information using this application and notifies the relevant places (intranet, etc.).

Stop plan management;
The user registers, edits, stores, and outputs the stop plan created by the work stop adjustment system, which is an external system, using the application.
-An application notifies a stop plan to various places based on a user's instruction.
・ The application stores the results of the outage plan.

Power optimization;
-This application is based on monitoring information and based on user instructions or automatically, various operation calculations for power optimization (power flow calculation / voltage calculation / short circuit calculation, optimal system configuration calculation, power plant usage water volume calculation, etc.) )I do.

System diagram management;
・ This application manages various chart data (system overview diagram, main system diagram, single line connection diagram, partial system diagram, power flow diagram, water system overview diagram, etc.) required for transmission system monitoring and control work.
Create and edit chart data manually or automatically based on the network facility information and map information acquired / stored by the integrated NW facility management subsystem 13 internally or from an external system.
-The user inquires and outputs the system diagram using the application.

System monitoring and control application configuration management;
• This application monitors that the grid monitoring and control subsystem is operating correctly.
-This application manages various option settings (operation mode switching, network switching, area-by-area control enable / disable setting for command board, etc.) of the grid monitoring control subsystem.

Training simulator;
-The user performs simulation training for various monitoring controls using the training environment provided by the application from the system control thin client.
-The user collects and outputs data for the training center system (external system) using the application.

CC record statistics;
The CC user creates and outputs various records and graphs (standard forms) necessary for transmission system monitoring control based on the monitoring information in the application. Record statistics;

CIM model;
In this application, the integrated NW facility management subsystem 13: derives and manages the CIM model necessary for the system monitoring control subsystem 11 based on the CIM model managed by the CIM model management application.

System board display function;
・ Display equipment information / measurement information and monitoring results on the system board to monitor the status of major power systems.

Multi-purpose display function;
-Use the projector screen to display various images such as disaster prevention terminal information (lightning observation, typhoon information, snowfall information, etc.) and command board screen.

Telephone function;
・ To perform system operation, it is necessary to make multiple calls to many other parties such as control stations and customers of special high-voltage power, so use telephone devices that simplify incoming and outgoing calls. The main functions include analog / digital / CB line transmission from the monitor, and functions such as answering / restoring / holding / recording / transfer / bargeing / simultaneous / caller display / automatic message response.

  As shown in FIG. 6, the application of the energy management system function includes functional configurations such as state prediction, power supply analysis, power generation surplus analysis, contingency analysis, voltage stability analysis, short circuit analysis, power optimization, and the like.

State prediction;
Provide various information necessary for stable operation of the power grid, such as real-time measurement, power generation prediction, load prediction, and set voltage.

Feeding analysis;
・ It is an analysis function related to power flow in the grid network. Verify various conditional hypotheses and find conditions for stable network operation.

Generation capacity analysis;
・ It is an analysis function related to power flow in the grid network. Verify various conditional hypotheses and find conditions for stable network operation.

Contingency analysis;
-This function supports the measurement of network reliability under a specific contingency. Simulate a steady state power flow solution and let the operator check the network when out of service. This function must be possible even during scheduled outages during analysis.

Voltage stability analysis;
• Help operators identify voltage stability issues and scrutinize the effects of conditions to stabilize the voltage.

Short circuit analysis;
・ A function that identifies the currents that are faulty on the power network by analyzing potentially problematic currents that may exceed the circuit breaker rating under current operating conditions or network topology. . It is also necessary to check the circuit breaker capability and protection settings. By coordinating with circuit breaker operation, it ensures that the operator can close circuit breakers that may exceed the short-circuit capacity limit.

Power optimization and security analysis, contingency dispatch;
A function for enhancing system operation and a function for presenting options related to control in order to achieve an optimization target.
-It is a function that supports contingency as a constraint and supports the planning of an appropriate and preventive control strategy.
-It is a function to determine the most effective and low-cost corrective action from power generation to repowering in order to suppress violation of active power operation constraints.

  As shown in FIG. 6, the application of other functions includes functional configurations such as switch analysis, failure point recovery, power failure management, prediction (short term / medium term / long term), and grid performance report.

Switch analysis;
-Appropriate warning to the operator when there is a potential risk such as load interruption, system instability, etc.-Creation of switching sequence command by the operator, and internal approval process.

Restoration of faulty parts;
-Supports the following three modes for fault location isolation and recovery functions.
Closed loop mode: Generates a switching order to switch service to a normal location. This switching order is automatically executed via SCADA.
Advisory mode: Generates a switching order to switch services to normal locations. This switching order is executed by being displayed and approved on the operator screen.
-Study mode: A manually adjusted and stored response method is activated by the operator, and a switching order is generated under the operating conditions specified by the operator.

Blackout management;
・ Power outage inquiry management: The power outage inquiry system provides customers with information on the details of power outages and recovery prospects.
・ Power failure analysis: It is possible to analyze the location of a power failure, the type of power failure, the number of affected customers (possibly affected), and the customers requiring notification.
・ Multiple options for automatic switching analysis can be displayed. In addition, the operator can confirm the analysis result and execute the switching operation based on the analysis result. If the operator approves the analysis results and selects an action plan, a switching sequence can be generated and modified.

Forecast (short term / medium term / long term);
・ Predict demand using meteorological data, weather forecast, consumption data, power loss calculation, and other supplementary information.

Grid performance report;
-A function for acquiring commercial and technical data using API or the like.
This is a report creation function that integrates the processing executed by the grid monitoring control system / distribution monitoring control system and SCADA data.
• Standard report templates according to the rules.

  Also, as shown in FIG. 6, the application of the power NW model management function includes a functional configuration of power NW model transmission / reception.

Power NW model transmission / reception;
In this application, the power NW model necessary for the grid monitoring control subsystem 11 is derived and managed based on the power NW model managed by the power NW model management application of the integrated NW facility management subsystem 13.

  Returning to the description of FIG. 5, the distribution monitoring control 202 is an application for configuring the distribution monitoring control subsystem 12, and controls the distribution system control work and maintenance of the distribution system control target equipment (substation equipment 73 and 74). Provide functions necessary for business. The functions of the power distribution monitoring control 202 are divided into a monitoring control function (SCADA), a power distribution management system (DMS), other functions, and a power NW model management function.

  FIG. 7 is a diagram illustrating an application of the power distribution monitoring control 202. As shown in FIG. 7, the application of the monitoring control function of the power distribution monitoring control 202 includes monitoring, operation procedure table creation / confirmation, control (manual / automatic), detection / reporting, stop plan management, power optimization (operation plan) , Distribution diagram management, distribution monitoring control application configuration management, training simulator, CC recording statistics, CIM model, system board display function, multi-purpose display function, and telephone function.

Monitoring;
・ This application captures various data (equipment information / measurement information) transmitted from the field devices subject to distribution system control, information necessary for status change / accident detection, power outage monitoring, and accident equipment judgment. Edit in real time and display to the user.
・ This application edits information for each monitoring of power flow, voltage, current, equipment abnormality, etc. in real time and displays it to the user.
-Switch display contents and views such as various skeletons, street maps, system diagrams, and lists based on user instructions.
・ This application stores information such as status changes and accidents based on user instructions or automatically.
・ Records, prints, sounds, and alarms are performed based on various operations during a change or accident.
・ Manage and update the status of equipment and tracks.
-Perform processing corresponding to the format of each field device.
-Monitor in the test system status separately from the online status.
-Perform transmission / reception in cooperation with other systems.

Operation procedure table creation and confirmation;
-This application provides functions for users to create / update, apply / approve, store, and output operation procedure tables (substation operation procedures, distribution line device operations, various confirmation procedures) related to distribution system operation functions.
-This application automatically generates and stores an operation procedure table based on the registered outage plan (distribution line work stop plan, planned power outage, substation work stop plan).
-Users can create and modify individual operation procedure tables.
The procedure table is sent in advance to another system or received in advance from another system, and it is determined whether or not it can be executed.
・ This application automatically generates, displays, and stores a recovery procedure table based on detected accident information.
-The user creates, updates, and stores the operation procedure table template in the application. An individual procedure table can be created based on the stored operation procedure table template.

Control (manual / automatic);
-The user controls the distribution system using the application. There are both control based on the operation procedure table and direct control (individual operation).
・ Application performs some automatic control based on monitoring information. The scope of automation is determined based on the system function list.
-Implement remote setting of contracted values and set values for power distribution equipment.
-Implement various status management / updates associated with control.
-Perform processing corresponding to the format of each field device.
・ Control is performed in the test system status separately from the online status.

Detection / reporting;
-Upon detection of a power distribution system accident in the monitoring application, the application edits the accident related information and displays it to the user. Integrated NW equipment management subsystem 13: Link accident information to accident record management.
-The user uses the alarm device in the application to make a report (speech / alarm report) to relevant places.
-The user creates a maintenance request using the application and notifies the maintenance staff.
-The user creates power outage accident information with the application or periodically, and notifies the related places (power outage information providing system, etc.).

The outage plan management / user registers, edits, stores, and outputs outage plans (distribution line work outage plan, planned power outage, substation work outage plan) using the application.
-This application notifies a stoppage plan to various places based on a user's instruction.
・ This application stores the results of outage planning.

Power optimization;
This application performs various operation calculations (voltage calculation / current calculation, calculation at the time of accident recovery, load model, etc.) for power optimization based on monitoring information based on user instructions or automatically.
・ Use a distribution substation voltage tap, distribution line voltage regulator (SVR), sensor built-in switch, line impedance, etc., to calculate the system so that the voltage is appropriate, and implement automatic control.

Distribution chart management;
・ This application provides various chart data necessary for distribution system monitoring and control work (general supervisory board, substation skeleton, distribution line skeleton, street map, 22 kV system diagram, 22 kV line selection transformer connection diagram, and various display drawings) Manage.
-The integrated NW equipment management subsystem manages chart data created manually or automatically during maintenance based on the NW equipment information and map information acquired and stored internally or from an external system.
-The application reflects and displays the equipment, measured values, and track status in real time.
・ Users use relationship charts to monitor, control and create procedures.

Distribution monitoring control application configuration management;
This application monitors that the power distribution monitoring control subsystem 12 is operating correctly.
This application manages various option settings of the power distribution monitoring control subsystem 12 (operation mode switching, setting of control availability by area for the console, substation operation item setting, automatic recovery setting, etc.).

Training simulator;
-The user performs various monitoring controls, accident recovery, procedure manual creation, and maintenance simulation using the training environment provided by the application from the thin client for power distribution control.
・ Scenarios such as accident scenarios (training environment / data setting, simulation training, training result data query) can be created automatically or manually.

CC record statistics;
The user creates, refers to, and outputs various states, records, and graphs (standard forms) necessary for distribution system monitoring and control based on the monitoring information and control acquisition information.
・ In addition to the control operator, provide information on various statuses, records, graphs, etc.
-Perform transmission / reception in cooperation with other systems.

Automatic creation of accident investigation drawings;
・ This application automatically generates an accident investigation map from the distribution contents of the distribution line.
The user inquires / updates / outputs the automatically generated accident investigation map.

Electric power NW model;
In this application, necessary maintenance is performed on the power distribution monitoring control subsystem 12 based on the power NW model managed by the CIM model management application of the integrated NW facility management subsystem 13.
-Perform transmission / reception in cooperation with other systems.

  As shown in FIG. 7, the application of the power distribution management system function includes functional configurations such as state prediction, voltage stability analysis, power flow optimization, imbalanced current detection, voltage scheduler, and short circuit analysis.

State prediction;
・ Provide various information necessary for stable operation of the power grid, such as real-time measurement and load prediction.

Voltage stability analysis;
-Provide support so that the user is aware of problems related to voltage appropriateness in supervisory control and can recognize various conditions for maintaining voltage appropriateness.

Optimization of power flow;
-Provide support so that the user can recognize the tidal direction in supervisory control.

Detection of unbalanced current;
-Help the user to recognize the unbalanced current in supervisory control.

Voltage scheduler;
・ Support is provided so that the user can recognize the occurrence of overload at the appropriate voltage and overload at the branch in monitoring control.

Short circuit analysis;
-Provide support so that the user can recognize the possibility of exceeding the short-circuit capacity of the circuit breaker and switch according to the current operating conditions in supervisory control.

  Further, as shown in FIG. 7, the application of other functions includes functional configurations such as detection and recovery of a failure location, power failure management, prediction, and various indicators / reporting.

Detection and recovery of failure points;
・ Detection and identification of faulty parts, and automatic restoration of sound power outages.

Blackout management;
・ Manage planned work stoppage plans.
・ Manage accidental power outages.

prediction;
・ Uses weather data, weather forecasts, and other supplementary information to make short-, medium- and long-term demand forecasts hourly, daily, weekly, and monthly to support monitoring and control.

Various indicators and reporting;
・ Create technical data using API.
・ Create standard reports according to the rules.

  Also, as shown in FIG. 7, the application of the power NW model management function includes a functional configuration of power NW model transmission / reception.

Power NW model transmission / reception;
In this application, necessary information is transmitted and received in the power distribution monitoring control subsystem 12 for the power NW model managed by the power NW model management application of the integrated NW facility management subsystem 13.

  The monitoring control system shown in FIG. 5 includes two subsystems, the system monitoring control 201 and the power distribution monitoring control 202, but the application configuration is as common as possible. 6 and 7, monitoring, operation procedure table creation / confirmation, control (manual / automatic), detection / notification, stop plan management, power optimization, system diagram / distribution diagram management, system / distribution Functions of the monitoring control application configuration management, training simulator, CC recording statistics, and power NW model are shared. Thereby, the duplication development of a function is prevented and development cost can be suppressed.

  Returning to the description of FIG. 5, the integrated NW facility management 203 is an application for configuring the integrated NW facility management subsystem 13, and includes a power transmission system / distribution system and control target facilities (substation equipment 63, 64, 73). , 74), the system functions necessary for the management work are provided. The functions of the integrated NW model facility management 203 are divided into a power NW device management function, a power NW model management function, and other functions.

  FIG. 8 is a diagram showing an application of the integrated network facility management 203. As shown in FIG. 8, the application of the power NW equipment management function includes functional configurations of power NW equipment status data collection, power NW equipment status data inquiry, configuration / setting management, and security management (device / user).

Power NW equipment status data collection;
This application collects and manages various data (detailed data) transmitted from field devices on the power network that is managed by the supervisory control system.
-This application analyzes various data collected and managed in combination, detects abnormalities in field devices on the power network, and notifies the user. (Health check function)

Power NW equipment status data query;
The user inquires about the power NW facility status data collected by the power NW facility status data collection application.

Configuration / setting management;
The user manages the configuration (inventory list) and individual settings of facilities (including field devices) on the power network managed by the monitoring and control system using the application. (Setting of mode, option, threshold, etc .. Setting of effective period, and analysis of influence accompanying setting change)

Security management (device / user);
-This application sets and manages the security of equipment on the power network (remote control / direct control availability, etc.).
• This application sets and manages user authentication and permissions. It also manages authentication information (password, etc.).
This application manages documents (files) stored in the monitoring control system.
This application manages the security on the supervisory control system and the network used by the supervisory control system. (Fraud detection, malware countermeasures, etc.)

  As shown in FIG. 8, the application of the power NW model management function includes functional configurations of configuration verification, accident record management, management record statistics, chart management, and power NW model management.

Configuration verification;
-The user performs a facing test on the result of data maintenance performed by the configuration / setting management application.
・ In the opposite test, 1) “internal test” that is closed in the system, and 2) transmission and reception of simulated information such as monitoring control information and operation information between each system such as the transmission destination system / device that performs data linkage. However, there are two types of "external test" to be performed.

Accident record management;
-This application manages records of power transmission system and distribution system faults based on information from the system monitoring control and distribution monitoring control detection and notification applications.
-Accident notification with high speed is performed from the detection / notification application of system monitoring control and distribution monitoring control. The user can edit and store detailed accident records and make inquiries using this application. Also notify the related external system.

Administrative record statistics;
-The user creates and outputs various records and graphs (standard forms) necessary for management work with the application.

Chart management;
・ This application manages various chart data (various skeletons, system diagrams, charging unit confirmation charts, etc.) necessary for management work.
This application acquires NW facility information and map information from an external system (such as a power distribution information management system) and manages it.
-The user inquires and outputs various charts using the application.

Electric power NW model management;
This application manages the power NW model (CIM model) data of the entire supervisory control system. The system is managed as a parent of the power NW model individually managed by the system monitoring control subsystem 11 and the power distribution monitoring control subsystem 12.

  As shown in FIG. 8, the application of other functions includes functional configurations such as maintenance data management, maintenance procedure manual creation / confirmation, and business system linkage.

Maintenance data management;
-This application manages maintenance work history information for each device. The user creates, updates, stores, and outputs periodic maintenance work results using the application.

Preparation and confirmation of maintenance procedures;
-This application provides functions for users to create / update, apply / approve, store, and output procedure manuals (local procedure table) for periodic maintenance work.

Business system linkage;
-For substation equipment information and outage subject information managed by the power company's business system, inquires for registration information, reflects it in input data, and outputs it in cooperation with the monitoring and control system application.

  In the supervisory control system, the power NW model is managed based on the CIM (Common Information Model) defined by IEC 61970 and IEC 61968. The integrated NW facility management subsystem 13 takes charge of the power NW model management of the entire monitoring control system. The system monitoring control subsystem 11 and the power distribution monitoring control subsystem 12 manage the power NW model to be monitored and controlled while cooperating with the integrated NW facility management subsystem 13.

  Since the integrated NW facility management subsystem 13 manages the integrated power NW model, the management load of the power NW model can be reduced. For example, it is possible to reduce the trouble of individually duplicating and verifying a model in a system (SCADA / DMS / OMS / EMS, planning tool, protection analysis tool, etc.). In addition, by maintaining a consistent power NW model, the accuracy and reliability of topology data can be ensured. In addition, manual work can be reduced by creating a workflow for power NW model management. Moreover, the analysis speed when changing the power NW model can be improved. Further, by unifying the power NW model on a CIM basis, it is possible to reduce future external system cooperation costs. Furthermore, it is possible to improve the power NW model analysis capability by querying the switch state history of the power network.

  Returning to the description of FIG. 5, the user interface 210 is an interface for exchanging information between the monitoring control system SYS-A and the user. The monitoring control system SYS-A provides a menu that matches the user role based on the user's authority set at the time of authentication. Further, the supervisory control system SYS-A limits the menus and system functions that can be inquired and used according to the authority of each user. The user authority set is managed by the security management (device / user) application of the integrated NW facility management subsystem 13.

  The user interface 210 is provided with a menu for system control, a menu for power distribution control, and other role-specific (role-specific) menus. For example, the menu for each user role includes “system monitoring control control center menu (command console menu)”, “power distribution monitoring control control menu menu (operator console menu)”, “maintenance center menu”, “system monitoring” “Control Facility Data Maintenance Menu”, “Distribution Completion Control Facility Data Maintenance Menu”, “System Manager Menu”, and “Training Menu” may be provided. The user interface 210 is made as common as possible in the monitoring control system SYS-A.

  The external system cooperation 220 is an application for the monitoring control system SYS-A to cooperate with the external system 100. As described above, the monitoring control system SYS-A and the external system 100 are linked through the real-time service bus 14 or the system operation service bus 111 adopting IEC 61970/61968/62235. If the external system 100 cannot support these protocols, an individual gateway (GW) function is constructed. Further, the cooperation between the existing external system on the DX network and the monitoring control system SYS-A is performed through the DX cooperation HTIF IF (UDP / IP).

DX linkage function;
Information is linked with the existing monitoring control system through the DX network using the HTIF IF.
ICCP information linkage function;
Coordinate information with external systems that can cooperate through ICCP.

  The front-end processor 230 (communication device cooperation) performs the cooperation between the monitoring control system SYS-A and the communication device side, the cooperation between the monitoring control system SYS-A and the control center (CC), and the cooperation between subsystems. Bear. The front end processor 230 corresponds to the front end processors 15a and 15b (FEP) shown in FIG. The front end processor 230 has the following functions.

Data transmission / reception function;
Data transmitted / received to / from a communication device (gateway: may include a field gateway) is aggregated and distributed.

Server base linkage (data center linkage) function;
Link information between server bases (between data centers) and subsystems. As a communication protocol, IEC 61970, IEC 61968, or ICCP (Inter Control Center Protocol) is used. For example, when the subordinate control station operator has a backup of the power station system control function, the control station operator controls the target communication device from the power distribution monitoring control side 202 to the system monitoring control 201 side using the inter-data center linkage function. Request and acquire rights.

Format conversion;
Information from the communication device (GW31, 41) is converted into an international standard transmission protocol (IEC61970 / IEC61968). In addition, the control information from each subsystem 11, 12, 13 is converted into a predetermined transmission protocol and transmitted to the target communication device.

  The gateway (communication device) 240 corresponds to the GWs 31 and 41 shown in FIG. The communication device 240 collects information from the connected TCs and transmits the information to the server side (system monitoring control 201, power distribution monitoring control 202, integrated NW facility management 203) through the front-end processor (communication device cooperation) 230. Further, the gateway 240 transmits (controls) the information to the subordinate TC based on the control information from the server side. The main functions of the gateway 240 are shown below.

Transmission aggregation function;
Information transmission from a plurality of TCs is aggregated and converted, and transmitted to the supervisory control system SYS-A (the supervisory control device 10).

Data transmission / reception;
-Information from the connected TC is transmitted to the supervisory control system SYS-A (supervisory control apparatus 10).
The control information is transmitted to the connected TC based on the control information from the monitoring control system SYS-A (monitoring control device 10).

Transmission format conversion;
The information from the connected TC is converted into an international standard transmission protocol. Also, the control information from the server base (data center) side is converted into a TC transmission protocol and transmitted to the target TC.

Communication device configuration control;
・ Controls the configuration of communication devices.
・ When the communication device is abnormal or malfunctions, it automatically switches to the healthy side.

Communication device failure management;
When the communication device fails, an abnormality report is sent to the host monitoring control system (monitoring control device 10).

Resend request management;
When information is not normally transmitted to the monitoring control system (monitoring control device 10), it is retransmitted.

Field device route management;
-When two routes are transmitted from TC, route management is performed on the communication device side.
In the case of transmitting control information from the communication device side to the TC, if the TC is receiving two routes, it is transmitted to both routes.

Field device configuration control;
Manage configuration control of communication devices and connected TCs.
-Update the configuration based on the configuration control information from the server side.

Field device failure management;
The failure information of the communication device and the connected TC is notified to the monitoring control system (monitoring control device 10).

Maintenance support;
The maintenance staff provides the functions necessary when operating the communication device directly using the maintenance tool. For example, information necessary for maintenance (transmission data, facility information / measurement information) is displayed, and remote control is disabled by selection.

Other;
Security functions and time synchronization functions are also provided.

  In FIG. 5, the application of the field gateway (FGWs 62 and 72 in FIG. 1) is not shown. However, the field gateway collects information from connected substation equipment such as circuit breakers and protection relays, and passes it to the server side (system monitoring control / distribution monitoring control / integrated NW facility management) through the front-end processor and gateway. Based on the transmission function and the control information from the server side, it has a function of transmitting (controlling) information to subordinate substation equipment. The field gateway is also called a substation communication device. The field gateway (substation communication device) has the following applications.

Data transmission / reception function;
-Collect information from connected substation equipment such as circuit breakers and protection relays, and periodically send it to the server in the specified format (protocol is IEC60870-5-104 / IEC61850).
-Based on the control information from the server side, transmit the control information to connected substation equipment such as circuit breakers and protection relays.

Format conversion;
・ Converts information from connected substation equipment such as circuit breakers and protective relays to the specified format. It also converts the format of information from the server side to the target substation equipment such as circuit breakers and protection relays.

Field device failure management;
-Monitor the operation of connected substation equipment such as circuit breakers and protective relays, detect faults, and store error information. Also, error information is transmitted to the server side.

Maintenance support;
・ Provides functions necessary for maintenance personnel to operate substation communication devices directly using maintenance tools.

  Next, information transmitted and received on the communication network of the supervisory control system SYS-A will be described. Information transmitted and received on the communication network of the monitoring control system SYS-A includes monitoring control information, operation information, and other information. The monitoring control information is information for acquiring the status of the equipment 63, 64, 73, 74 and distribution line equipment in the substations 60, 70 and controlling the equipment, and the system monitoring information and control information. There is.

  The system monitoring information is used for monitoring TM information measured in the substations 60 and 70, and states of the substation devices 63, 64, 73, and 74 in the substations 60 and 70 (for example, failure, state change, etc.). There is SV information. The control information includes substation control information (switch on / off information that can be remotely controlled between the monitoring controller 10 and the substations 60 and 70, use / lock information of protection relays, etc.), distribution device monitoring control Information (such as on / off information of a target switch that can be remotely monitored and controlled from the integrated NW facility management subsystem 13), substation state setting information (status setting for the target substations 60 and 70 from the monitoring control device 10) Information to be performed), substation equipment status request information (information for requesting monitoring information and status setting status from the monitoring control device 10 to the target substation 50), and the like.

  The operation information is information for linking between the subsystems 11, 12, and 13. The other information is information other than the monitoring control information and the operation information, such as initial processing information at the time of starting the system, reception confirmation information to the information transmission source, and the like.

  Next, the format configuration of information conforming to the international standard communication protocol transmitted and received on the communication network in the supervisory control system SYS-A will be described. FIG. 9 is a diagram illustrating an example of a data format configuration. As shown in FIG. 9, the information includes a transmission header part, a data part, an authentication part, and an FCS (Frame Check Sequence). The configuration of the transmission header part conforms to an international standard communication protocol. The data in the data part has a maximum of 1266 bytes. Authentication data is stored in the authentication unit. FCS is data for detecting a frame error.

  Next, information transmission control procedures between the system side and the substations 60 and 70 side will be described. FIG. 10 is a sequence diagram showing a transmission control procedure of information between the system side (monitoring control device 10) and the substations 60 and 70 side. In the processing shown in FIG. 10, when the subsystem of the supervisory control device 10 transmits control information (selection command) for instructing selection of a control target to the substations 60 and 70 (step S1), the GW 31, 41 or FGW 62, When the control information is normally received, 72 returns reception confirmation information (Ok-Ack) indicating that reception of the control information has been confirmed to the subsystem (step S2). The GWs 31 and 41 transmit the received control information to the TCs 61 and 71, and the TCs 61 and 71 transmit the control information from the GWs 31 and 41 to the substation equipment 63 and 73. In addition, the FGWs 62 and 72 transmit the received control information to the substation equipment 64 and 74.

  When the GWs 31 and 41 receive control information (selection completion) from the TCs 61 and 71 for instructing completion of selection of a control target, the GWs 31 and 41 transmit control information (selection completion) to the subsystem that has transmitted the control information (selection instruction). Further, after the FGWs 62 and 72 themselves complete selection of the control target, the FGWs 62 and 72 transmit control information (selection completion) to that effect to the subsystem (step S3). When the subsystem receives the control information normally, the subsystem returns reception confirmation information (Ok-Ack) indicating that the reception of the control information has been confirmed to the GWs 31 and 41 or the FGWs 62 and 72 (step S4).

  Upon receiving the system monitoring information (SV information) transmitted from the substation equipment 63, 64, 73, 74, the GW 31, 41 or the FGW 62, 72 transmits the system monitoring information (SV information) to the target subsystem. (Step S5). When the GW 31, 41 or the FGW 62, 72 receives the system monitoring information (TM information) transmitted from the substation equipment 63, 64, 73, 74, the system monitoring information (TM information) is transmitted to the target subsystem. Transmit (step S6). When the subsystem receives the system monitoring information, the subsystem does not return the reception confirmation information.

  Note that the GWs 31 and 41 or the FGWs 62 and 72 and each subsystem do not transmit the reception confirmation information when the control information cannot be normally received. In this case, if the reception confirmation information is not received even after a predetermined time has elapsed since the transmission of the control information, the GWs 31 and 41 or the FGWs 62 and 72 and the subsystems transmit the control information again.

  Next, operations of the GWs 31 and 41 and the TCs 61 and 71 will be described. FIG. 11 is a flowchart showing processing executed by the GWs 31 and 41 and the TCs 61 and 71. The process shown in FIG. 11 is a process in the case where system monitoring information is transmitted from the substations 60 and 70 side to the system side. First, the TCs 61 and 71 periodically collect system monitoring information from the substation devices 63 and 73, for example (step S11). Next, the TCs 61 and 71 convert the collected system monitoring information into information that can be transmitted to the communication line 160 (TC line) (CDT or HDLC transmission format information) (step S12). At this time, if the TCs 61 and 71 are devices compatible with CDT, they are converted into the CDT transmission format, and if the TCs 61 and 71 are devices compatible with HDLC, they are converted into the HDLC transmission format. Then, the TCs 61 and 71 transmit the converted system monitoring information to the GWs 31 and 41 via the communication line 160 (step S13).

  Upon receiving the system monitoring information in the CDT or HDLC transmission format transmitted from the TCs 61 and 72, the GWs 31 and 41 convert the received system monitoring information into information in the transmission format of the international standard communication protocol (step S14). ). Then, the GWs 31 and 41 transmit the converted system monitoring information to the target FEPs 15a and 15b (that is, subsystems) via the WAN 20 (step S15).

  In addition, when control information is transmitted from the system side to the substations 60 and 70 side, a process reverse to the information conversion process shown in FIG. 11 is performed. That is, the GWs 31 and 41 convert the control information in the data format of the international standard communication protocol into the information in the CDT or HDLC transmission format, and the TCs 61 and 71 convert the data format (CDT or HDLC) of the communication line 160 (TC line). The transmission format) control information is converted into control information for the substation equipment 63 and 73.

  Next, the operation of the FGWs 62 and 72 will be described. FIG. 12 is a flowchart showing processing executed by the FGWs 62 and 72. Note that the process shown in FIG. 12 is a process in the case where system monitoring information is transmitted from the substations 60 and 70 side to the system side. First, the FGWs 62 and 72 periodically collect system monitoring information from the substation equipment 64 and 74, for example (step S21). Next, the FGWs 62 and 72 convert the collected system monitoring information into information in the transmission format format of the international standard communication protocol (step S22). Then, the FGWs 62 and 72 transmit the system monitoring information after the data conversion to the FEPs 15a and 15b (that is, the GWs 31, 41, or the WAN 20) via the communication line 170 or 180 (see FIGS. 3 and 4) (step S23).

  In addition, when control information is transmitted from the system side to the substations 60 and 70, a process reverse to the information conversion process shown in FIG. 12 is performed. That is, the FGWs 62 and 72 convert the control information in the transmission format format of the international standard communication protocol into information for controlling the substation equipment 64 and 74.

  Next, the network configuration of the supervisory control system SYS-A will be described. FIG. 13 is a diagram showing a network configuration of the supervisory control system SYS-A according to the first embodiment of the present invention. As shown in FIG. 13, the network configuration of the supervisory control system SYS-A is composed of duplicated power control IP networks (wide area IP networks) 400 and 410. The power control IP networks 400 and 410 include three server bases 300, 310, and 320, a store power station 330 (a store power station is also referred to as a local power station), and a plurality of control stations 340, An IP network that connects to the network 350, for example, is constructed with a ring-shaped optical fiber line.

  The server base 300 corresponds to the data center 1A in FIGS. 1 and 2, the server base 310 corresponds to the first sub data center in FIG. 2, and the server base 320 corresponds to the second sub data center in FIG. Further, the server 301 corresponds to a server constituting the monitoring control apparatus 10 provided in the data center 1A in FIG. 1, and the server 311 is a server constituting the monitoring control apparatus provided in the first sub data center 1B in FIG. The server 321 corresponds to a server constituting a monitoring control device provided in the second sub data center 1C of FIG. Further, the control station 340 corresponds to the control station 30 in FIG. 1, and the control station 350 corresponds to the control station 40 in FIG. Further, the gateway (GW) 343 corresponds to the GW 31 provided in the control station 30 in FIG. 1, and the gateway (GW) 353 corresponds to the GW 41 provided in the control station 40 in FIG. In FIG. 1, the GW 31 is connected to the TC 61 and the like of the power transmission substation 60, and the GW 41 is connected to the TC 71 and the like of the power distribution substation 70. However, the GW 343 in FIG. The GW 353 in FIG. 13 is connected to the transmission device 371 of the power transmission substation and the transmission device 372 of the distribution substation.

  On the first optical line 400 (ring-shaped outer optical fiber line) in the power control IP networks 400 and 410, the server base 300 is provided with a router 302a, the server base 310 is provided with 312a, and the server base 320 is provided with A router 322a is provided, and the routers 302a, 312a, and 322a are connected to the servers 301, 311, and 321 respectively. Further, on the second optical line 410 (ring-shaped inner optical fiber line) in the power control IP networks 400 and 410, the server base 300 is provided with a router 302b, the server base 310 is provided with a router 312b, and the server A router 322b is provided at the base 320, and the routers 302b, 312b, and 322b are connected to the servers 301, 311, and 321 respectively.

  As described above, the network between the server bases 300 and 310 is a redundant network in consideration of a line failure and a line stop due to work. The servers 301, 311, and 321 necessary for the monitoring control system SYS-A may be configured to be redundant (redundant) by providing a 1-system server and a 2-system server, respectively.

  On the first optical line 400, a router 331 a is provided at the store power supply station 330, a 341 a is provided at the control station 340, and a router 351 a is provided at the control station 350. These routers 331a, 341a, and 351a are connected to thin clients 332a, 342a, and 352a, respectively. The routers 341a and 351a of the control stations 340 and 350 are connected to the GWs 343 and 353, respectively. On the second optical line 410, a router 331b is provided at the store power supply station 330, a 341b is provided at the control station 340, and a router 351b is provided at the control station 350. The routers 331b, 341b, and 351b are connected to the thin clients 332b, 342b, and 352b, respectively. The routers 341b and 351b of the control stations 340 and 350 are connected to the GWs 343 and 353, respectively.

  The GW 343 is connected to the transmission device 361 of the power transmission substation and the transmission device 362 of the distribution substation. The GW 353 is connected to the transmission device 371 of the power transmission substation and the transmission device 372 of the distribution substation. The transmission devices 361, 362, 371, and 372 are measures corresponding to TC and FGW. The existing communication network is used between the control stations 340 and 350 and the transmission substation and distribution substation.

  Although not shown in FIG. 13, information necessary for an emergency disaster is transmitted by a backup route using a microwave radio line.

  Next, characteristic system monitoring control executed by the system monitoring control subsystem 11 of the present invention will be described.

  FIG. 14 is a block diagram illustrating the configuration of the grid monitoring control subsystem 11 of the power supply stations 700, 710, 720 and the monitoring control device 10. The power supply station (also referred to as a power supply command station) shown in FIG. 14 is an organization responsible for the task of comprehensively and efficiently operating the power system in order to stably supply power to consumers. There are two types of power station operations: supply and demand operations that adjust supply capacity so as to maintain a balance between supply and demand, and grid operations that maintain and properly maintain voltage and power flow conditions. As shown in FIG. 14, the power supply station is divided into a central power supply station 700 (also referred to as a central power supply command station), a main system power supply station 710 (also referred to as a main system power supply command station), and a city center depending on the business classification and voltage class. It is hierarchized into a system power supply station 720 (also referred to as a city center power supply command station). The central power station 700 is mainly in charge of supply and demand operations, and supervises the subordinate power stations 710 and 720. The main system power supply station 710 and the city center system power supply station 720 are mainly in charge of system operation, and the command ranges are classified by the voltage class or the like.

  Further, as shown in FIG. 14, the system monitoring control subsystem 11 of the monitoring control device 10 includes a creation unit 11a, a control unit 11b, an information transmission unit 11c, an accident information transmission unit 11d, and a power failure information posting unit 11e. And. In addition, about the structure of the power distribution monitoring control subsystem 12, the integrated NW equipment management subsystem 13, etc., it is the same as that of the structure shown in FIG.

  The creating unit 11a creates a procedure table for instructing operations including planned stoppage of facilities and changes in the power system. That is, the creation unit 11a uses the stop subject determined to be stopped in the stop planning work, and generates an operation command procedure table and a device individual operation procedure table for performing a stop operation, a system change, and the like with a certain algorithm of the computer (server) Create or modify manually or manually. Here, the operation command procedure table defines rough procedures for operations such as work stoppage, and the device individual operation procedure table defines detailed operation procedures for each device corresponding to the procedures in the operation command procedure table. Yes.

  The power supply system (for example, the power supply system 711 or 721) provided in the power supply station (for example, the main system power supply station 710 or the city center system power supply station 720), The device individual operation procedure table and the initial system on the day of operation are displayed on the terminal monitor. The created operation command procedure table and device individual operation procedure table are stored in a database or procedure / subject DB 92 provided in the monitoring control apparatus 10. In addition, the power station system can perform simulated execution such as scheduled stop for each operation command procedure step and each device individual operation procedure step corresponding to this operation command procedure. The created procedure is approved when the operator selects approval.

  There are four operation command procedure creation methods: a manual method, a file method, a daily method, and a logical method. In the manual method, an operator / device and an operation term are selected and input using a single line diagram displayed on the monitor by the operator, and created for each operation command procedure. The file method is created by copying an operation command procedure registered and stored in advance. The daily method is created by copying the approved operation command procedure. In the logical method, an operation command procedure is automatically created by a certain algorithm based on the stop subject data.

  There are two methods for creating a device individual operation procedure: a pre-registration method and a logic creation method. The pre-registration method is a method in which device individual operation procedures for facilities / devices that perform special operations are registered in advance, and the corresponding device individual operation procedure is called up from a file at the time of automatic creation. The logic creation method rearranges the device deployment information from the operation command procedure (equipment, purpose command terminology) and the device deployment content using a certain algorithm, creates the device individual operation procedure, and adds the device individual operation procedure and the confirmation procedure. It is a method to create.

  FIG. 15 is a diagram illustrating an example of a transformer in a substation. FIG. 16 is a diagram illustrating an example of an operation command procedure table and a device individual operation procedure table in the transformer illustrated in FIG. 15. The transformer (No. 1 transformer) shown in FIG. 15 includes switches # 1 to # 3 (also referred to as circuit breakers). Further, when commanding the work stop of the No. 1 transformer shown in FIG. 15, as shown in FIG. 16, for example, a procedure of “work stop of No. 1 transformer” is described in the operation command procedure table. The device individual operation procedure table corresponding to the table describes the device individual operation procedure of “switch # 1 open”, “switch # 2 open”, “switch # 3 open” and the confirmation procedure of “no current check”. Has been.

  The control unit 11b transmits a command based on the procedure described in the operation command procedure table and the device individual operation procedure table to a substation device such as a switch in the substation, thereby performing the operation described in the procedure table. Run.

  Moreover, the control part 11b performs simultaneous control with respect to the same substation apparatus in the same substation from the power station system of several power stations (main system power station 710, a city center power station 720, other local power stations, etc.). In order to avoid this, the control right given to each power station is managed. In other words, the control unit 11b performs management so that the same control target control right is not given to the other power stations when the control right for the substation equipment of the predetermined substation is given to the predetermined power station. As a result, the control for the same control target is exclusive.

  The information transmission unit 11c monitors the charge / power failure state of the facility in the power system, and manages the first information for managing the charge / power failure state of the monitored facility and the information of the facility to be monitored in the power failure state. The second information is transmitted to the terminal of the power supply station. Specifically, the information transmission unit 11c monitors the charging / discharging state of the equipment registered as a monitoring target from the current state of the power system (for example, the state of which power transmission line is interrupted). Create cut-off transmission line aggregate information related to cut-off transmission lines. The cut-off transmission line aggregation information includes load transmission list information (first information) for managing the charge / power failure state of the monitored equipment, and target equipment list information for managing information on the monitored equipment at the power failure location ( Second information). The information transmission unit 11c transmits the cut-off transmission line aggregation information to the power supply system of the power supply station (the central power supply station 700 and the backbone power supply station 710). The load power transmission list information is transmitted to the power feeding system at regular intervals (for example, every 10 minutes). The power feeding system displays the cut-off transmission line aggregate information transmitted from the information transmission unit 11c on a monitor or the like.

  The accident information transmission unit 11d automatically creates information on accidents including power outages in the power system (information on accident contents, locations, etc.), and transmits the created information on accidents to related locations including power stations. As a result, when an accident such as a power outage occurs, the relevant location can immediately confirm the content and location of the accident. The power failure information posting unit 11e automatically creates power failure information in the power system, and automatically registers and posts the created power failure information on, for example, the power company's Web. Thereby, power failure information can be immediately notified.

  Next, a list of business functions in the monitoring control system is shown below.

  The following tasks are listed as tasks (system operation tasks) of the grid monitoring control subsystem 11 in the monitoring control system.

System monitoring;
The operator (operator) uses the display information of the equipment status displayed on the grid monitoring panel and monitor, and measurement information such as active power, etc., to check the power system connection status, work status, power flow status, voltage maintenance status, power failure, Monitor for equipment abnormalities.

  The operator inputs and manages the VQC pattern, OLR settling, and per-equipment allowable values from the monitor in order to monitor the operation target value and the excess rating.

  When the transmission line JP is opened / connected, the operator sets the JP open mark and the tower number of the system monitoring panel and monitor. In addition, when the offline device status is changed, the device status is reflected.

  The operator performs comprehensive monitoring of the entire water system, status monitoring for each water system, and status monitoring of the dam reservoir from the monitor screen.

System operation;
The operator creates a scheduled stop operation, a system change operation, an operation command procedure for system operation, and an individual device operation procedure according to the purpose. The examiner / approver confirms the operation procedure table using the exercise function, and performs the examination / approval.

  The operator transmits the stop subject and the operation procedure in the approved procedure table to the substation system and the monitoring control device 10 (the power distribution monitoring control subsystem 12 and the integrated NW facility management subsystem 13) at the relevant location, and makes a meeting.

  For the scheduled stop operation, the system change operation, and the system operation operation, the operator associates the previously transmitted operation procedure table with the command board, and performs the operation. For those that do not have a procedure table, such as operations that occur suddenly, perform the operations as needed. Here, it is possible to monitor and control the facilities of the substation from a plurality of power stations. However, from the viewpoint of operational safety, in order to avoid simultaneous control of the same substation, the grid monitoring and control subsystem 11 includes a city center power station, other local power stations (store power stations, backbone system power stations), and control stations. Control right and control exclusion.

  When the operator needs to quickly adjust the voltage, the operator performs the operation as needed.

Record;
Display information and measurement information collected by system monitoring work are automatically saved for a certain period. The operator displays the saved information as a graph on the monitor for confirmation.
Arbitrary data is acquired and processed in CSV format.

  The operator sets the secondary power plant that can be collected online and a predetermined screen of the monitor. The total generated power of the set power plant is obtained every minute and transmitted to the central power station at a predetermined cycle.

  Processing is performed based on the active power value at the measurement location determined by the operator, and the total demand in the area under the jurisdiction of the power station is obtained. If online input is not possible due to work or trouble, a preset offline value is used. Further, the operator calculates and sets the total demand correction factor in order to adjust the self-power station demand not included in the obtained total demand or the demand of other power stations that are included.

  The operator communicates necessary information to other companies and the central power supply station based on the information displayed on the monitor at a predetermined time.

  The operator inputs necessary items on the power supply overview screen of the monitor, creates and saves the power supply overview for the day, and sends it to the intranet in a predetermined format.

  The operator outputs and manages the detected extra high customer stop results.

System failure;
When a system fault occurs, the operator grasps the operation relay, trip CB, and power failure equipment from the information displayed on the system monitoring panel and the monitor. In addition, the power outage is calculated from the pre-accident system diagram and the post-accident system diagram.

  The operator performs the operation as needed to recover from a power failure when an accident occurs.

  The operator describes necessary items in a predetermined format, or automatically creates information automatically created by the monitoring control device 10 (system monitoring control subsystem 11) by fax. It is automatically transmitted from the monitoring control device 10 (system monitoring control subsystem 11) to the central power station. A serious accident bulletin automatically created by the system monitoring and control subsystem 11 is automatically transmitted to the relevant part.

  Information necessary in the event of an accident is automatically transmitted to the substation system, monitoring and control device 10 (distribution monitoring and control subsystem 12, integrated NW facility management subsystem 13), and underground line terminal. In addition, based on the information stored as an accident record, it is automatically transmitted to the intra and power outage information providing system as a system accident bulletin. The operator manually registers general information (for example, information such as a power outage) in a power outage information providing system (a system that provides and posts information on a Web page). Also, it is possible to automatically register the summary information manually registered by the operator in the power failure information providing system.

  When there is a wide range of power outages and accidents, UFRs, etc. are mixed, the operator confirms whether the power outage type (accident, UFR, etc.) of the power lines that are out of power is correct on the cut-off transmission line aggregation screen, and enters whether transmission is possible And transmit to the central power station.

Outage plan;
When performing scheduled work stop operation, operation stop operation, and system change operation, the operator enters necessary items in the stop work plan table and creates a stop subject.

Training;
The operator is divided into a trainer and a trainer, and performs training using the training simulator function of the monitoring control device 10 (system monitoring control subsystem 11). Pre-registered training cases are executed on one trainer table, and accident recovery training is performed using the trainer table (n table).

  The operator collects online setting data, operation calculation data, and training case data for the training center system from the data collection menu for the training center system from the PC for the day shifter terminal and stores them in the DAT. The training center inputs the power station data to the training center system by DAT.

Data maintenance;
When new facilities are added or removed, the operator plans to perform data maintenance, and performs data design and maintenance. Check that the data is correct after switching data.

  When a new system is introduced, the operator conducts a data confirmation test with related parties and substations using the system as a test series before switching the data operation.

  The operator extracts past measurement data of the self-feeding station from the supervisory control device 10 (system supervisory control subsystem 11), and creates a monthly maximum predicted tidal current chart for each month up to 20 months ahead. After that, we will coordinate with those created at other power stations and perform stop adjustment work based on the tidal current diagram reflecting the data measured at other power stations. In the same way, the summer maximum expected tidal current diagram, the tidal current diagram for a specific period, etc. are prepared, and system operation measures during the period are planned. The operator automatically designates past measurement data to be referred to, and automatically creates a tidal current chart based on the past results of his own power station and other power stations.

  The operator captures the scheduled stop work plan table data and the system change plan table data created by the work stop adjustment system (LJ1) into the stop subject registration PC using an external storage medium, and monitors the control device 10 (system monitoring control). Register to subsystem 11).

  The operator uses the past performance data and examines the VQC settling value so that an appropriate voltage can be maintained. After the setting is changed, the set value is input to the monitoring control device 10 (system monitoring control subsystem 11) to perform voltage monitoring.

System monitoring;
The operator monitors the occurrence of an abnormality in the information transmission path between the devices through the monitor.

  The operator monitors the state of various hardware such as computers (servers) and peripheral devices constituting the monitoring control device 10 (system monitoring control subsystem 11) through the monitor.

Trouble response / information communication;
The operator performs the operation by operation at any time as necessary when there is a trouble in the power facility.
In addition, an abnormality information message is edited by the monitoring control device 10 (system monitoring control subsystem 11), and the information transmitted to the related part is notified by telephone when transmission fails.

  When an abnormality occurs, the operator switches the operation mode of each device and starts backup operation from the monitor as necessary. In addition, when a problem occurs in information transmitted / received between the power supply station and the control station, the operator checks the analyzed trace data and responds.

  If the device information to be transmitted is not normal, the operator locks the transmission information. If missing measurement information is recognized, set an offline value if necessary, and perform record interpolation.

Other duties;
The operator performs power flow calculation, voltage calculation, and short circuit calculation using the operation calculation function in order to confirm the system status after the operation is performed. In addition, when a new customer is created, the system data for the newly installed system is input, and the optimal system configuration calculation is performed so that the power transmission loss is minimized to determine the power receiving line.

  The operator selects an optimal NL tap and LS LS operation pattern that compensates for the charging current due to the ground capacitance of the cable system, corresponding to various system configurations by system operation.

  The following tasks are listed as tasks of the power distribution monitoring control subsystem 12 in the monitoring control system.

Monitoring;
The operator grasps the connection of the registered substations and the overall state of the substations with the general monitoring panel. The operator grasps the distribution line system from the distribution line skeleton, distribution line street map, 22 kV system diagram, and the like.

  The operator monitors the substation equipment necessary for system operation, such as substation switch status, voltage / current status, system, facility accident, charging, power outage, etc. through the monitor.

  Operators can monitor the distribution equipment (6kV distribution line equipment, distribution tower equipment, 22kV line selection type transformer, etc.) switch status, voltage / current status, system, facility accident, charging, power outage, etc. through the monitor. Monitor power distribution equipment necessary for electric wire operation.

  The operator monitors the 22 kV customer equipment necessary for 22 kV system operation through the monitor, such as grasping the switch state of the 22 kV customer equipment, the voltage / current state, the system, the facility accident, the charging, and the power failure.

  The operator monitors the state of the substation under the control of the other control station to which the distribution line of the own control station is connected through the monitor for items necessary for the status of the distribution equipment of the own control station, accident detection, and the like.

  The operator connects and conducts the test before the start of operation associated with the establishment or replacement of the TC in the test system state.

control;
The operator individually operates the substation equipment within the control G operation range.

  The operator performs individual operations of 22 kV line selection type transformer equipment, distribution tower, and 6 kV distribution line equipment.

  The operator shall set the status of the substation's remote control and non-distant control devices during operation, testing, operation prohibition, and on / off status.

  Operators are working on 22kV line selection type transformer equipment, distribution tower, 6kV distribution line equipment, working on non-distance equipment, testing, prohibiting operation, accident power failure, construction power failure, healthy power failure, on / off, etc. Perform state setting.

  The operator performs status settings such as during work, testing, on / off of the 22 kV customer equipment.

  The operator operates a substation of 275 kV or less in response to a command from the power station as a backup when the monitoring control apparatus 10 is down.

  The operator individually operates the substation equipment within the substation maintenance G operation range.

  The operator creates and executes a plan / procedure manual for stopping / restoring a planned power outage.

  The operator grasps whether the abnormality or state of the distribution line automatic switch is different from the system by executing the collective monitoring operation.

  On behalf of the operator, the system automatically and periodically acquires the status of 22kV line selection type equipment, various sensor information and records of the sensor built-in switch.

  The operator sets the set value and set value of the on-site sensor built-in device far away.

  On behalf of the operator, the system automatically monitors and operates the taps of the distribution substation banks and the SVR taps with built-in sensors installed in the distribution lines, and the distribution line voltage is within the legal range. Voltage control is performed so that

Scheduled operation work;
The operator creates a plan for stopping / switching the equipment of 22 kV or less at the substation.

  The operator creates a procedure manual based on the plan for stopping / switching the equipment of 22kV or less at the substation.

  The operator performs the scheduled operation according to the procedure manual based on the plan for stopping / switching the equipment of 22kV or less at the substation.

  The operator requests the operation of the substation under the jurisdiction of another control station in accordance with the distribution equipment stoppage plan.

  The operator performs the operation of the substation requested by another control station according to the distribution equipment stoppage plan based on the request.

  The operator creates a procedure manual based on a plan for stopping / switching distribution towers and 6kV distribution equipment.

  The operator creates a procedure manual based on a plan for stopping / switching 22 kV and 6 kV distribution equipment.

  The operator performs a scheduled operation according to a procedure manual based on a stop / switch plan for 22 kV and 6 kV power distribution equipment.

  The system automatically uses the scheduled system creation function / distribution device procedure automatic creation function in response to a request to switch the construction subject that is linked from the distribution system information linkage system, and determines whether the distribution line can be switched on the scheduled construction date. ,respond.

Work at the time of the accident;
The system automatically operates distribution line equipment on behalf of the operator and restores the healthy power outage section.

  The operator grasps the operation relay, trip CB, and power failure range of the substation.

  The operator knows the substation, distribution tower, 22kV customer equipment operation relay, trip CB, distribution line switch status, power failure range, and accident section. The operator knows the number of customer power outages.

  The operator recovers by individual operation based on the on-site accident investigation.

System design;
Operators can monitor the operation of the substation through the monitor (voltage monitoring, heavy overload monitoring, switching destination at bank switching, operation order, operation takeover report creation, substation equipment response time, connection with distribution automation system (Automatic status confirmation transmission, simultaneous operation exclusion items, etc.)

  The operator performs settings related to the operation of distribution equipment (heavy overload monitoring, various settings at the time of procedure creation, distribution line skeleton display method, street map display method, adjacent substation, etc.) through the monitor.

  The operator performs settings related to the operation of the 22 kV system (IPP power and display switching) through the monitor.

  The operator sets when to perform automatic confirmation in the system whether the pre-creation procedure of the substation / distribution equipment can be used as it is on the day of implementation. The operator sets at what timing the contents are automatically deleted from the system after the termination of the stop plan and the procedure manual.

  The operator sets which type of alarm and sound are output to the alarm sound device installed in the control room, the guestroom, the power distribution maintenance G floor, and the like.

  The operator performs security settings such as a user and password for using the system.

  The operator sets various support functions for operating the system alone.

  The operator performs various print settings (procedure table, load record, power outage customer list, message panel, etc.).

  Set whether to automatically restore distribution lines in the event of a substation accident or distribution line accident. Set the current value for each distribution line section assuming the renewable energy for distribution line accident recovery.

Data maintenance;
The operator carries out maintenance such as substation equipment data, skeleton, general supervision chart, and SV / TM status list.

  The operator performs maintenance automatically or manually on the facility data, skeleton, and street map (MAP) of the 6 kV distribution facility by linking with the business system. Maintenance such as 22 kV system diagram, line selection type connection diagram, customer connection diagram is implemented.

  The operator performs maintenance for connecting to other systems such as a substation system, a power distribution system, an IPM, and an underground terminal.

Training;
Operators train substation operations and accidents in simulation mode.

  In the simulation mode, the operator carries out training on accidents such as operation of power distribution equipment, accidents, planned power outages, and accident countermeasures.

  Operators will operate substations, conduct accident training and competitions in online mode at the training center.

  Operators operate distribution equipment, conduct accident training and competitions in online mode at the training center.

Cooperation with other systems;
The operator transmits / receives the stop plan and the procedure manual to / from the monitoring control device 10 (system monitoring control subsystem 11, integrated NW facility management subsystem 13) and other systems (for example, external system). Sends and receives the status of non-distance control equipment to / from substation systems, distribution automation systems, etc. The system automatically notifies abnormal information and accident information to the underground terminal and distribution automation system on behalf of the operator.

  The operator sets whether to transmit the accident information to the power failure information providing system for each substation, each bank, and each distribution line. The system automatically sends the information of the power distribution accident to the power failure information providing system on the behalf of the operator by setting, and discloses the information of the accident power outage range outside the company.

  On behalf of the operator, the system automatically links with the construction plan of the power distribution equipment and the equipment data, and performs automatic maintenance of the power distribution equipment data in the control system. In addition, the system automatically sends the system configuration, records, etc. of the distribution system to the distribution information management system side, and the G operator separate from the control performs each distribution task (accident statistical analysis, distribution facility planning task, construction management task) Etc.).

  The system automatically obtains information from the lightning information provision system on behalf of the operator, and plots the time and place on the distribution line street map and accident investigation map.

Control support;
Not only the operator of the control G but also the distribution maintenance G, branch facility general G, branch office, another G member in the head office, substation, distribution system configuration, status, recovery status in case of an accident, lightning strike point, and records Check statistics. Get information in CSV format.

  The operator automatically creates and manages the accident investigation drawings necessary for the field switching operation, the field investigation at the time of the accident, and the recovery at the power distribution maintenance G and the construction company.

  The operator manages the three-phase voltage, current, phase angle, power factor, harmonics, various waveforms, recordings, etc. of the sensor built-in device, and performs the tasks of accident analysis, accident sign analysis, and voltage management.

  The operator creates a business takeover form between the direct manager and the trainee.

  The operator manages the tap value of the pole transformer in order to manage the appropriate voltage.

Record statistics;
The operator manages substation measurement records.

  The operator manages the measurement records of the power distribution equipment.

  A load model is created for future system load prediction either manually by the operator or automatically by the system.

System monitoring;
The operator manages the state of the control system (for each function such as facing, monitoring control, and console, connected LAN state, presence / absence of server abnormality, presence / absence of abnormal state of CVCF).

  The operator manages the transmission state with the system and equipment connected to the WAN 20 and the communication line.

system management;
The operator replaces the application after function improvement or failure repair according to the corresponding contents.

  The operator backs up the data in the system and stores it in the control G and at the system management location.

  The following operations can be given as operations (including maintenance operations) of the integrated NW facility management subsystem 13 in the monitoring control system.

Driving takeover;
The person in charge of equipment operation prepares a transfer book and uses it when the person in charge of the facility changes.

Equipment monitoring;
Based on the SV / TM information, the status and status of substation equipment are monitored.

Operation procedure table creation;
Provided is a function for supporting the management of the stop plan information of the scheduled stop operation linkage information and the device individual operation procedure information received from the monitoring control device 10 (system monitoring control subsystem 11, power distribution monitoring control subsystem 12). Provide a support function for maintenance staff to create a local procedure table.

Accident / failure handling operations;
It is grasped by reversing the state (display color change) together with the alarm sound and flicker of the device symbol in the skeleton part.

Record work;
Edit information required for maintenance of substation equipment generated by each function. The contents edited by the request are output to the printer.

Request function;
Requests the information stored in the signal converter, and displays and records the return information on the screen.

Setting value change function;
Set the setting value data for heavy overload monitoring and voltage monitoring.

State setting;
The person in charge of the system and the person in charge of the system communicate with each other, and in order to match the state of the local device with the state of the device on the skeleton screen, the non-distance control device / ground state is set. In addition, in order to protect the safety of local staff, settings are made during work and during testing.

Work subject management;
When the stop schedule is confirmed, a work subject is automatically created from the information of the stop schedule.

  The received stop schedule or the stop schedule created by the monitoring control device 10 (integrated NW facility management subsystem 13) is changed and registered.

  Next, a list of system functions in the supervisory control system is shown below.

  First, a specific example of the system function of the system monitoring control subsystem 11 is shown below.

System monitoring;
-The CB, LS open / closed state, power flow (active power), and grounding attachment / detachment state of the main power system in the local power system in charge of the power station are displayed on the system board. Moreover, all the measured values such as all device states such as CB, LS, and relay, and active power, reactive power, and voltage are correctly displayed on the monitor.
・ When the status of the collected CB, LS, relay, etc. changes, this content is displayed on the monitor, when requested by the operator to the system board, or constantly.

-Check whether the received information is the contents specified in the transmission / reception protocol, and notify the operator of the contents when an abnormality is detected.
・ After the notification, the received abnormality content is displayed on the monitor according to the operator's request.

-Monitor the status of information transmission with each computer system and terminal device installed at the control center, branch office, etc., and the substation TC, and immediately notify the operator when an abnormality is detected.
-Also, the transmission status of each device is displayed on the monitor according to the operator's request.
・ Information transmission to each system and terminal can be used / locked.

-Based on the status change such as CB, UVR, etc., the power failure and charging facilities are identified, and the power failure and charging contents are displayed on the monitor according to the operator's request.
・ When a power system / equipment accident is detected, determine the power equipment that has failed due to the accident, and display the details of the power outage on the monitor as requested by the operator.

-Based on the status change of CB, relay, etc., it detects power system accidents, identifies accident facilities, etc., notifies the operator of the contents, and displays the accident contents on the monitor according to the operator's request.

-The single system is determined based on the equipment configuration of the generator, reference bus, and other equipment according to the connection status of the power system, and displayed on the monitor according to the operator's request.

-Always monitor whether the voltage value deviates from the upper and lower limit values of the voltage monitoring width set around the voltage reference value, and notify the operator of this content when it deviates / returns.
・ Display the voltage monitoring result on the monitor according to the operator's request.

・ The voltage flicker value is constantly monitored to see if the voltage flicker operation reference value, which is the operation reference of the power system, is the limit value, and whether or not the frequency flicker value is more than “4 times the operation reference value has been exceeded in one hour” or more. If this happens, notify the operator of this content.
-Also, the voltage flicker monitoring result is displayed on the monitor at the request of the operator.

・ Continuously monitor whether the active power exceeds the “operation target value” of the transmission / transformation equipment in the power system in charge of the command, and notify the operator of this content if it exceeds.
・ Also, the operation target value excess monitoring result is displayed on the monitor according to the operator's request.

・ Continuously monitor whether the active power deviates from the “equipment allowable value” of the transmission and substation equipment. If it exceeds, notify the operator of this content.
-Also, the overload monitoring result is displayed on the monitor according to the operator's request.

-Always monitor whether the current value information exceeds the "monitoring value" set by the system, and if it exceeds, notify the operator of this content.
・ Also, the result of overcurrent monitoring is displayed on the monitor at the request of the operator.

-Always monitor whether the apparent power obtained from the active power and reactive power information exceeds the "MVA operation target value" of the equipment in the command power system, and notify the operator if it exceeds.
In addition, the MVA monitoring result is displayed on the monitor according to the operator's request.

Monitor the operation status of the OLR (first stage operation, second stage operation, etc.).
When any operation from the first to third stages of the OLR is detected, the operator is immediately notified.
In addition, after the notification, the operation status of the OLR is displayed on the monitor in response to a request from the operator.

・ If an underground line facility abnormality or an abnormality in the power line fault location distance is detected, an abnormality message for the facility is created and transmitted to the branch power station and the maintenance department.
・ When a zero-phase voltage, zero-phase current, failure duration, or substation equipment abnormality is detected, it is transmitted to the branch power station or maintenance department using SV / TM information as abnormality information of the equipment concerned.

When a PC operation is detected, the operator is notified and the contents of the detected PC operation are displayed on the monitor in response to the operator's request. Also, the PC operation message information is edited and transmitted to the related places.

-Collect the usage / lock status regarding UFR equipment, thermal power system separation relay equipment, and system stabilization equipment information from the control center and power substation, and display them on the monitor along with the connecting buses as required by the operator.

-Detect open-phase power transmission based on relay information collected from control stations and substations.
When the phase loss power transmission is detected, the operator is notified and the detected abnormality content is displayed on the monitor in response to the operator's request.

・ Collect VQC device operation patterns, operation modes and device status information from control stations and substations. These states are displayed on the monitor in response to the operator's request.

・ Display the input capacity and remaining input capacity of the phase adjusting equipment on the monitor according to the operator's request.

-Monitor the instantaneous voltage drop of the power system that occurs over a very wide area from the point of the accident due to lightning, etc., and notify the operator if an instantaneous voltage drop is detected.

・ When an accident occurs or at the request of an operator, search for power outages related to power system changes, local distribution, and special heights, calculate the number of power outages, and display / output to the monitor and LBP.

-Monitor areas where power outages or instantaneous voltage drops occur and super critical customers (for customers with extra high voltage and customers designated as super critical under high voltage), and according to the operator's request, These states are displayed on the monitor.

・ When the power supply to the supply line of the special high-demand customer within the power supply command range of the branch office is stopped due to the operation of the power system facilities due to factors other than the accident, the stop time / contents of the special high-demand customer, etc. Edit and display on the monitor according to the operator's request.

-Edit the work equipment setting status set from the online single-line diagram and partial system diagram screen, and display it on the monitor according to the operator's request.

・ Displays the status of distant equipment belonging to each equipment on the monitor according to the operator's request.

・ When an abnormal drop in gas conduit pressure occurs due to the LNG facility's carburetor being shut down, etc., the branch / feeding station is the gas conduit pressure, the ORV operating status, the main gas shutoff valve status, and the thermal power generator transmitted from the LNG base Receives information such as output suppression and blocking instructions, and notifies the operator. In addition, the LNG equipment state is displayed on the monitor in response to the operator's request.

-Two transmission positions of current transmission position / new transmission position can be defined in the database, and the status of the transmission position currently in operation is displayed on the monitor according to the operator's request.
・ Also, in the current transmission position / new transmission position, the transmission position currently in operation can be switched by the operator.

-For monitoring value setting data management, monitor values are input to the above functions and used for system monitoring.

-The jumper release / connection display can be arbitrarily changed by the operator at the location of the jumper symbol on the system diagram. Also, the open / closed state of the offline device can be arbitrarily changed.

・ On-line monitoring of the dam water level, river flow, and pre-input water system capacity and constraints that are collected online is displayed on the water system map. When an abnormality is detected, the operator is notified and displayed on the monitor in response to the operator's request.
・ Using the dam reservoir water level and power plant output collected online, calculate the dam reservoir water volume and power plant water consumption at regular intervals and display them on the monitor.

・ Extract the target for calculating the equivalent water level from the dam reservoir water level collected online, calculate the equivalent water level at a fixed period, and display the result on the monitor.
-According to the operator's request, the amount of power that can be generated and the pumping time are calculated using the dam reservoir water level at the time of request and the power plant output or the value set by the operator, and the results are displayed on the monitor.

・ Water system records will be stored for a certain period and displayed and output in a prescribed format based on the operator's request.

System operation;
・ Using the subject of the shutdown decided in the shutdown planning work, use the fixed algorithm of the computer (server) or monitor the operation command procedure table and equipment individual operation procedure table for performing the shutdown work, system change, etc. Create and modify using the conversation method from the screen.
The created operation command procedure table, device individual operation procedure table, and initial system on the day of operation are displayed on the monitor, and simulation execution can be performed for each operation command procedure step and device individual operation procedure step for that operation command procedure. (Exercise function).
The created procedure is approved by selecting approval.

The method of creating the above operation command procedure is as follows:
1. Manual method Select and input equipment / equipment and operation terms using a single line diagram currently displayed on the monitor, and create them for each operation command procedure.
2. File method Creates a copy of the registered operation command procedure.
3. Daily method Creates a copy of the approved operation command procedure.
4). Logical method Based on the stop subject data, an operation command procedure is automatically created by a certain algorithm.

The method for creating the above individual device operation procedure is as follows. Pre-registration method A method that registers individual device operation procedures for specially operated facilities / devices in advance and calls the corresponding device individual operation procedure from a file for automatic creation.
2. Logic creation method Based on operation command procedure (equipment, purpose command term) and device deployment contents, device deployment information is rearranged according to a certain algorithm to create device individual operation procedure, and 43 device operation procedures and confirmation procedure are added and created method.
The device individual operation procedure creation method is the above method, and it is developed in a correct procedure for all facilities including a special facility form.

• Press the “system operation operation” button to enter the system operation operation mode, and create an operation command procedure / apparatus individual procedure. Procedures can be arbitrarily executed step by step, and procedures can be arbitrarily added until the system operation mode is canceled. A series of operation histories from when the “system operation operation” button is pressed to when the system operation operation mode is released are handled as one subject.

-Depending on the created operation subject, create / modify the operation command procedure table / device individual operation procedure table using a certain algorithm of the computer or using the conversation method from the monitor screen.
・ Exercise function can be executed for the created procedure.
・ Also, the created procedure is approved by selecting approval.

-Regarding the scheduled stop operation and system change operation that have already been approved, the power station operation command procedure and the individual device operation procedure are transmitted in advance to distribution control / maintenance, and the system control receives the procedure reception result “good or bad”.

・ Associating the procedure that has been completed in advance with the command console to acquire the control right of the operation target electric station. Direct operations are performed in accordance with individual procedures by executing operations in one or a plurality of procedures. Normal operation is possible for all facilities. Here, it is possible to monitor and control the facilities of the substation from a plurality of power stations. However, from the viewpoint of operational safety, in order to avoid simultaneous control of the same substation, the grid monitoring and control subsystem 11 includes a city center power station, other local power stations (store power stations, backbone system power stations), and control stations. Control right and control exclusion.

・ Execute the command in the order of the created procedure. Procedures can be arbitrarily added / executed until the grid operation mode ends.

・ Associating approved procedures with the command console to acquire the control right for the operation target electric station. Perform one or more procedures.

• Press the “Direct Selection Operation” button to enter the direct selection mode. Select the device on the system diagram displayed on the monitor, and obtain control rights. Operate by selecting an operation term from the menu.

・ Adjust the voltage by the above operation.

Record;
・ Always have three years of the previous year, current year and next year, and automatically create a new next year calendar and automatically update the previous year and current year calendars when the year changes.
-From the calendar screen, representative days and holidays can be changed from the calendar screen at the request of the operator.

・ Display information indicating the status of devices such as circuit breakers, disconnectors and protective relays, and measurement information such as active power, reactive power, current and voltage of power equipment on the power flow diagram when the time specified by the operator arrives Edit and output automatically.
・ Also, the same information at the same time is saved in a predetermined file for a certain period, and edited and output on the power flow diagram according to the operator's request.

・ Outputs attribute information on power substations, extra high customers, and power facilities according to operator requirements. The various information and operation information can be corrected by data maintenance and setting processing from the monitor screen.

・ Data is saved whenever the supply line of extra high customers is stopped and restored.
Store outage data for two months.
・ Output the input data for each branch, branch office and PPS height.

・ Displays information collected and stored as equipment operation records, total demand information, and weather information in a graph.

・ We save weather information every 5 minutes, and edit and output to a predetermined format according to the operator's request. Various information related to weather information can be corrected by setting processing from the monitor screen.

-Saves the detection time, gas base name, equipment name, equipment name, and direction when the status of the gas base vaporizer, gas conduit shut-off valve, pressure reducing valve changes, and displays the monitor screen and LBP if necessary. Perform the printing process.
・ Alarm / emergency response / security device operation status change records are saved, and monitor screen display and LBP printing are performed as necessary.
-Save the LNG gas conduit pressure every 5 minutes, and edit and output to a predetermined format according to the operator's request.

・ Numerical data (750 days worth), state change record data (100,000 cases) and extra high customer stop record data (8000 cases) are automatically registered in the database by the day shift DB server once a day.

Transfer the approved procedure table (1000 cases) and the operated procedure table (15000 cases) to the day shift DB server and register them in the database.
・ For tidal current charts, save four representative points every day for 400 days.

-By specifying the target computer, system diagnosis results and various log files are combined and transferred to the day shift DB server disk in a compressed format.

-Specify the corresponding server and set the time and information type to transfer data that meets the conditions to the disk of the day shift DB server.

-Save the 1-minute value of the TM data in the power station for the previous day to the PC for inputting the stop subject every day. The number of days to be stored is 400 days. As for the minute data on the day, a CSV file from 0:00 to the point in time of the day is created and saved in the stop subject PC at the request of the operator.

・ Effective power of the power generation calculation target equipment collected online, secondary power stations set offline, and power generation correction values set by the operator in advance, and power generation by system at 1-minute intervals Is calculated and transmitted to the central power station system.

・ Processing is performed based on the active power values collected from predetermined measurement points, and area demand is calculated. In addition, the company demand is calculated by subtracting the PPS customer demand received from the central power station from the area demand.
・ Each power station transmits the area current demand calculated by the power station and our current demand information to the related power station every minute. In addition, all store area demand and all store company demand are received from the central power station every minute and stored at a cycle of 5 minutes.
Each value obtained by each process is stored in a predetermined file for a certain period, edited in a predetermined format in accordance with an operator's request, and output to the designated device.

・ Calculate interchange power at the time of linking with other companies and record it on the monitor. The total for 6 hours and the total for the day are calculated from the values obtained at the same time.
・ Records will be saved for two days before the day.

・ Calculate and store one-hour values of other companies' power transmission / reception results from the measurement information of power transmission / reception power of other power stations (Kimitsu Joint Thermal Power, Nippon Steel).

・ Create a power supply overview, and save the power supply overview for the previous day at 24:00 and the power supply overview data for that day at the same time. Automatic transmission to the intra after manual or simultaneous save processing.

・ Data is saved whenever the supply line of extra high customers is stopped and restored.
Store outage data for two months. Input data is output to the screen for each branch, branch office, and PPS special height.

System failure;
・ When operation of a protection relay or all-stop UVR is detected, use the power outage equipment group information and the operation information of the protection relay and switch to correctly determine the accident equipment even when a complicated system fault occurs, and to the operator Notice.
・ Accidents that have occurred are stored for each subject, and the pre-accident system and post-accident system of the subject are stored.
・ Accident subjects are created correctly for each case, and unnecessary subjects are not created.

・ Perform power failure recovery by system operation.

・ Accident No. whose accident title is edited A serious accident bulletin is automatically created for each unit, forms are printed in a prescribed format, and sent to the system and PC at the same time. It is possible to correct / input and reprint on the command board including the automatically created content, and the input content can be converted to CSV and output externally. In addition, the system will automatically send a serious accident bulletin automatically created by the system control system to the relevant locations.

・ When an accident occurs, maintenance information (operation relay, accident equipment name, power failure location, zero-phase voltage / current, reclosing / retransmission result, etc.) is converted into a substation system, PC ground, distribution automation system, monitoring and control device 10 ( To the distribution monitoring control subsystem 12).
・ Also transmit power outage accident information (accident equipment name, power outage location name, recovery status, etc.) to the intra. In addition, information is automatically registered in the general information of the power failure information providing system.

・ Displays the power outage status of the equipment registered as a monitoring target from the current grid status, and transmits it to the central and main grid power station systems. The cut-off transmission line aggregation information includes load power transmission list information for managing a charge / power failure state and target facility list information for managing information on a power failure location information monitoring target facility.
-Load power transmission list information is transmitted to the central power station / main-system power station system at regular intervals every predetermined time (10 minutes).

Outage plan;
-When performing scheduled work stop operation and operation stop operation, enter necessary items in the stop work plan table and create a stop subject. Also, when performing system change operation, input necessary items in the system change subject and create it.
・ The determined suspension subject will be communicated to the relevant offices in response to a request from the operator.

Training;
・ Training will be divided into “trainers” who will prepare for training, setting the environment and instructions for training, and “trainers” who will actually perform training.
-One trainer table and multiple trainer tables can be used for one exercise.
・ One training subject is composed of subject management data, initial system data, and accident data, and OLR data, generator / distribution bank capacity data, and equipment abnormality message data are common data that can be used for all training subjects.

-Collect system online setting data, operation calculation data, training case data, and equipment DB from the menu of the PC for day shifter terminals, and save it in the DAT in a format that can be acquired by the training center system.

Data maintenance;
・ Enables data entry, rationality check, data test, and operation switching for all data changes in the computer system caused by expansion, abolition, or change of power system facilities.

・ After data maintenance of various data, "internal test" that is closed in the system, and conducted while sending and receiving simulated information such as monitoring control information and operation information between each system such as the destination system / device that performs data linkage “External test” can be executed.

System planning;
-By inputting necessary items such as expected total demand and past date and time (s), create a tidal current diagram with the total specified demand based on the actual data. The created expected flow chart can be printed and output to a file (flow chart, load data).

-The scheduled stop work plan table data and the system change plan table data created by the work stop adjustment system (LJ1) are read from the stop subject PC. The read data is edited so that it can be operated by the monitoring control device 10 (system monitoring control subsystem 11), and transmitted to the monitoring control device 10 (system monitoring control subsystem 11).
-The sent subject can be used as the subject of scheduled stop operation and system change operation.

System monitoring;
• Monitor the communication path between the main mode system console and other devices using the Hello Call telegram protocol. When a LAN abnormality is detected, it is determined whether an abnormality has occurred in the own apparatus or an abnormality has occurred in the counterpart apparatus.
-If an abnormality is detected in the duplicated LAN, the communication process is continued by avoiding the communication path that has become abnormal and switching to a normal communication path.
-The configuration control information managed in each device is equivalent by putting the configuration control information such as the LAN status, operation mode, DB version, etc. of all devices on the Hello Call message.

-Monitors the status of various hardware such as computers, LANs, peripheral devices, etc. that make up the monitoring and control device 10 (system monitoring control subsystem 11), and responds according to the degree of failure (major failure / light failure) when an abnormality occurs Perform mode transition.
・ Performs mode transition and backup operation according to the request from the operator, and enables monitor display and print output of the system operation status.
-Also, monitoring / switching of communication routes with external systems, switching of peripheral devices / fault monitoring, etc. are performed.

Trouble response / information communication;
-When power system abnormality occurs, if system operation is necessary, the system operation function is used according to the situation.

-Mode transition is automatically performed according to the degree of failure (major failure / light failure) occurring in the system. In addition, the operator can perform server mode transition, start / end of backup operation, and the like from the monitor.
-When an abnormality occurs in a duplicated LAN, the LAN is automatically switched so that communication processing is continued according to the location where the abnormality has occurred.
If a problem occurs in the information (SV, TM, command information) transmitted and received between the control station and the substation, the trace data is displayed and confirmed. Further, the trace information analyzed from the PC for day shifter terminal can be confirmed.

-If the transmitted device information, relay information, etc. are abnormal, lock the device / relay information from the system diagram.
・ Notify the operator when missing measurement information occurs. When the measurement information used for calculating the total demand is missing, a mark (for example, “*”) is added to the fixed position of the current total demand value in the total demand record and displayed. When information is missing, the total demand is calculated using offline values set by the operator.

Other duties;
-Select the current system, future system (possible to input changes such as equipment expansion), system conditions (current system, 10 system conditions entered in advance) and supply and demand conditions (current supply and demand, 10 entered in advance) The voltage is calculated by the NTR method by setting the supply and demand conditions.

-Select the current system, future system (possible to input changes such as equipment expansion), system conditions (current system, 10 system conditions entered in advance) and supply and demand conditions (current supply and demand, 10 entered in advance) The power flow is calculated by the FDC method by setting the supply and demand conditions.

-Select the current system, future system (possible to input changes such as equipment expansion), system conditions (current system, 10 system conditions entered in advance) and supply and demand conditions (current supply and demand, 10 entered in advance) Short circuit calculation is performed by the FSC method by setting the supply and demand conditions.

-Select the current system, future system (possible to input changes such as equipment expansion), system conditions (current system, 10 system conditions entered in advance) and supply and demand conditions (current supply and demand, 10 entered in advance) By setting the supply and demand conditions), the optimum system configuration is calculated by the FDC method, and the results of the maximum 10 cases from the one with the smallest transmission loss are displayed.

・ Calculate the optimal NL tap and LS LS operation pattern to compensate for charging current due to the ground capacitance of the cable system corresponding to various system configurations by system operation, and calculate the top three with the highest compensation rate Display as a result.
・ Calculation mode to determine the optimum operation pattern by combining both NLs of the two thermal power plants as a parameter, and fixing the NL of one of the two thermal power plants and the optimal operation pattern using the other thermal power NL as a parameter The required calculation mode can be executed.

  A specific example of the system function of the power distribution monitoring control subsystem 12 is shown below.

Monitoring;
・ Displays the status of CB, LS, etc. collected from the substation and the connection status of the grid.
・ Displays continuous failure, grounding, and door status during work at each substation.
-Describe the field work status such as track work tags, test tags, ground tags, and power line edge cutting work.
・ The status is reflected in real time.
・ Highlight display for each voltage class can be switched.
-Display on the console screen, large display (general supervisory board) (3 screen configuration).

・ Displays various devices for each substation, relay ON / OFF status, work, testing, operation prohibition, charging / power failure status, TM status, and grid connection.
・ Displays the status of each substation TC, such as the control right for each substation TC, whether or not there is a TC abnormality, whether or not there is an abnormality in the transport unit, whether or not there is a function lock, and whether or not to contact before operation.
・ Displays the distribution line current based on the data received from the relay device.
• State changes are reflected in real time.
-Use the skeleton for individual operations, status setting, procedure manual creation, device specification display, monitoring, etc.
・ Substation skeleton can be displayed simultaneously on DSP1, 3 on 2 screens and 4 screens at maximum.

・ Displays various devices for each substation via relay devices such as substations that do not support two layers, relay ON / OFF status, operation, operation prohibition, charging / power failure status, TM status, and grid connection.
-Display the status of each substation TC, such as the presence or absence of TC abnormality for each substation TC and the presence or absence of function lock.
• State changes are reflected in real time.
-Use the skeleton to set status, create procedure manuals, display device specifications, monitor, and request operations.
-A substation skeleton with a maximum of 2 screens can be displayed on DSP1.

・ Displays various devices for each distribution tower, relay ON / OFF status, work, testing, operation prohibition, charging / power failure status, TM status, and grid connection.
-Switchable display of two types of skeletons: the state via the relay device and the state via the distribution tower TCP / IP line.
• State changes are reflected in real time.
-Use the skeleton for individual operations, status setting, procedure manual creation, device specification display, monitoring, etc.
-A substation skeleton with a maximum of 2 screens can be displayed on DSP1.

・ Automatic switch for each 6kV distribution line, ON / OFF state of manual switch, various TM states of the switch, operation of track / switch, operation prohibition, charging power failure, accident power failure, construction power failure status, system connection The distribution line section number is displayed.
• State changes are reflected in real time.
-The display is displayed by two types of methods based on the switch, the arrangement of the tracks, two types of display methods, and the type of switch (automatic switch only, automatic manual switch both display).
-Use the skeleton for individual operations, status setting, procedure manual creation, device specification display, monitoring, etc.
・ Display symbols for both fictitious and underground switches.
・ Up to 2 screens of distribution line skeleton can be displayed on DSP3.

・ Automatic switch for each 6kV distribution line, ON / OFF state of manual switch, various TM states of switch, operation of track / switch, prohibition of operation, charging power failure, accident power failure, construction power failure, etc., system connection Is displayed.
・ The status is reflected in real time.
-The display is displayed on the common topographic map with various symbols such as 6kV various devices, utility poles, overhead wires, underground cables. Symbols and symbol names are divided into layers and can be displayed or hidden.
-Various highlighting, seamless display, and position change are possible.
-Use the skeleton for individual operation, status setting, procedure manual creation, device specification display, etc.

・ Intermediate substation (with 22kV voltage class) 22kV bus and distribution line part PTCB, W, grounding and other substation parts state, 22kV distribution line relay state, 22kV customer equipment state, 22kV line selection type transformer The device status, TM status, charging / discharging status, and system connection of the power receiving part are displayed.
・ Displays device specifications, status, and TM records.
-In the system diagram, the symbols and sections are colored from the respective information from the WAN 20 and the communication line.
・ The status is reflected in real time.
-Use the skeleton for individual operation, status setting, monitoring, etc.

・ Displays the equipment status of 22kV line selection type transformer, various TM status, working, testing, charging / discharging status, system connection, etc.
・ The status is reflected in real time.
-Use the connection diagram for individual operations, status setting, monitoring, etc.

・ Displays various lists such as substations, banks, distribution lines, distribution line switches, accident power outages, accident distribution lines, and switched distribution lines.
・ The status is reflected in real time.
・ Use various lists for monitoring.

・ Display and output records of transmission / distribution system status change, operation, accident detection, outage plan information, procedure information, intersystem reception information such as messages, connection status changes with various devices, etc.
・ Sort by mode (online, simulation), control mode (system control, power distribution control, maintenance), record type, and equipment type.
・ Automatic and manual printing is possible. You can print by specifying the period.
-Used for various types of monitoring and control.

-Outputs and manages alarms and voices in the event of a status change, accident, system abnormality, or operation.

・ Can print various screens.
・ Reverse printing of the skeleton display color is possible.

・ Initial management, first-come-first-served management, packet assembly, information transmission / reception for direct transmission / reception of information to / from TC, data between systems, and each system via DX-GW Implement order management, connection status management, and security management.

・ Initial management, packet assembly, information order management, connection status management, and security management for transmission / reception of monitoring control data for substations, distribution towers, and 6kV distribution line equipment using repeater lines carry out.

・ Manages the status of substation TCs, devices, relays, and TMs.
-Notifies the status to various functions such as alarms, message panel output, flicker management, record management, accident detection function, substation operation function, distribution line status update function, etc. accompanying various status changes.

-Update the power outage of the bus and distribution lines from the equipment status of the substation.

・ Use 6kV sensor built-in distribution line equipment Optical line and send / receive various data such as monitoring control, recording, waveform, etc. to / from the sensor built-in distribution line equipment.
・ Automatically sends a periodic transmission request to the distribution line equipment with a built-in sensor.

・ Transmission / reception of monitoring control data to / from distribution tower equipment using a distribution tower TCP / IP line.

・ Transmission / reception of SV / TM information of 22kV substation equipment, 22kV customer equipment information, and SV / TM information data from hydraulic TC using 22kVIP manager line (TCP / IP).

・ Use 22kV line selection type transformer line and send / receive SV / TM information and control information of 22kV line selection type transformer.
・ Automatically make a periodic transmission request to the 22kV line selection type transformer.

・ Manage various states of 6kV distribution line switches.
-Notifies various functions such as alarms, output to message panel, flicker management, record management, accident detection function, substation operation function, etc. accompanying various state changes.
・ Create status from changes in status of substations and distribution towers.

-Manage various states of TC, each device, relay, TM of distribution tower equipment.
-Notifies the status to various functions such as alarms, message panel output, flicker management, record management, accident detection function, substation operation function, distribution line status update function, etc. accompanying various status changes.

-Manage various states of 22kV substation equipment, 22kV customer equipment, 22kV line selection type transformer equipment.
-Notifies various functions such as alarms, output to message panel, flicker management, record management, accident detection function, substation operation function, etc. accompanying various state changes.

・ Updating the power outage, status, etc. of the system due to various status changes of the 6 kV distribution line.

-Renew system charging / discharging, status, etc. due to various changes in distribution tower status.

・ Updating the power supply, power outage, etc. of the system with various state changes of 22kV substation equipment, 22k customer equipment, and 22kV line selection type transformer equipment

-In the test system, connect to the substation TC via the WAN 20 etc., and manage monitoring, control, status management, and status update separately from the online system.

control;
・ Each console can be operated with substation, 6kV distribution line equipment, 22kV substation, customer, individual operation of line selection type transformer equipment, collective monitoring (multiple simultaneous monitoring control), scheduled operation procedure operation, status setting Carry out checks, operation content audio requests, and execution requests.
-Output the result for the response accompanying execution.
-Manage state transitions associated with various operations.
・ Each console can be set to enable / disable distribution lines.

・ In response to operation requests from each console, accident function, calendar function, exclusive management of the entire system, substation direct control function, 6kV switch monitoring control function status management.
-Implement parallel processing management of execution.
・ Implement requests for substation direct control function, 6kV switch monitoring and control function, 22kV equipment monitoring and control function, and CPU reclosing function.
-Carry out traffic control for each function for requests and responses and information with the console.
・ Return the result to the operation management of each console.

-Perform various checks on monitoring and control operations, status settings, and status requests for substation TCs and devices, create corresponding formats, and make requests to the communication line facing function.
・ Respond to the response, manage the presence / absence of abnormality, refractory behavior, etc., and return the result to the execution management function.

-Implement in-system reclosing management at TCs that do not have individual reclosing relays for distribution lines at substations.
-Manage the status related to reclosing for each substation according to the status of the collective reclosing relay and CPU reclosing relay.
-Depending on the state, when the substation CB is tripped, a CB closing reclosing operation request is automatically executed to the execution management function.

-For the substation, execute the control right acquisition location request, SV request, TM request, request during work, request during test, SOE request, and substation detail STS request.
-Displays the result on the screen in response to the request response.

・ Automatically request output of records depending on the specified date and time, and automatically request switching operation of substation equipment on weekdays / holidays.
-Depending on the specified date and time, the sensor built-in switch is requested to acquire setpoint / set value information, 1-day data, 1-month data, and 1-year data.

・ Performs various checks on monitoring control operations and status settings for 6kV distribution line equipment, and makes a request to the relay device line facing function or the relay device simulation function.
・ Respond to the response, manage the presence / absence of abnormality, refractory behavior, etc., and return the result to the execution management function.
・ For 6kV dedicated line switches (measures for incapability of receiving), supervise and control for substations where dedicated line master stations are installed.

-Implement and manage distribution line current requests and SV requests for relay devices.

・ Receiving acquisition requests for records, waveforms, operation history, and setting values stored internally by the sensor built-in distribution line device, execute and manage the request to the sensor built-in distribution line device optical communication opposing function.
・ Execution and management of settling / setting value remote setting for distribution line equipment with a built-in sensor.

・ Simulation of a relay device when supervising and controlling 6kV sensor built-in distribution line equipment through an optical line, arranging for batch monitoring separation request and batch input separation request, and optical line format, and distribution with built-in sensor Make a request to the optocommunication counter function of the electric wire device.
・ Respond to the response, manage the presence / absence of abnormality, refractory behavior, etc., and return the result to the switch monitoring and control function.
・ Up to the designated controller, request and manage the APL system that uses an optical line and then performs supervisory control by distribution line conveyance.

・ Check the status of 22kV substation equipment, 22kV customer equipment, and 22kV line selection type transformer equipment, and change the status.
・ Perform various checks on the monitoring and control of 22kV line selection type transformer equipment and make a request to the 22kV line selection type transformer facing function.
・ Respond to the response, manage the presence / absence of abnormality, refractory behavior, etc., and return the result to the execution management function.

・ Perform various checks on monitoring control operations and status settings for distribution tower equipment, and make requests to distribution tower facing functions.
-Manage the presence / absence and refractory behavior of responses.

Managing the login mode (“control mode”, “maintenance mode”, “system monitoring control subsystem 11 backup mode”) to the system operator console.
・ Depending on the login mode, substation equipment can be operated and whether there are alarms or not.

-As a backup for the system monitoring control subsystem 11, a power reception standby system for each substation is registered in advance.
・ Create and execute the procedure for the registered standby system configuration.

・ Register stop switches for each block (area).

・ Create plans and procedures for implementing planned power outages.

・ Perform operation management and response management of switches registered in the procedure manual in parallel for each substation.
・ After completion, automatically request current.

・ Calculate from substation bank tap value, distribution line SVR tap value, line impedance, voltage. Keep the appropriate voltage.

Scheduled operation work;
-Register the operation subject based on the substation stop / switch plan information entered by the operator.
-Manage the procedure creation status for the operation subject.
・ Register the subject of own power distribution control / system control / other power distribution control and manage them in chronological order.
-Complete and register the subject of the distribution control for which the operation has been completed and the subject of other distribution control.
-Cancel and register the subject of power distribution control that has been canceled and the subject of other power distribution controls.
-The system control subject whose operation date has passed is automatically deleted.

・ Expand the operation procedure up to the scheduled date and time (the subject of own power distribution control / subject of grid control / subject of other power distribution control / maintenance subject) to the planned grid in chronological order.
・ If there is an inconsistency in the operation procedure or maintenance contents, an error notification will be sent.

・ Automatically create substation operation / confirmation procedure / pre-operation status data based on substation stop / switch plan information on the planned system.
・ If switching of distribution lines is necessary due to the creation of substation operation procedures, distribution line switching procedures are also created automatically.

・ Create / delete / modify procedures / confirmation procedures for substation equipment on the planned system based on operator instructions.
-Expand / display the created / deleted / modified procedures on the planned system.
・ At the end of manual creation of the procedure, automatically creates the state data before device operation.

・ Extract the operation procedure (the subject of own power distribution control / subject of system control / subject of other power distribution control) in chronological order.
・ Request the procedure expansion to the substation simulation execution deployment function.
・ Procedure evaluation (good / bad) is set based on the result of procedure development.
-Simulated execution is automatically started at the set time for all procedures scheduled for execution on the day.

-The substation equipment procedure requested by the substation simulation execution management function is executed on the simulation system.
-Update the display of the simulated system status during procedure development as needed.
-Check the simulated system for abnormalities such as inconsistencies, power outages, bank overloads, etc., and evaluate the procedure.

・ Perform pre-operation check and operation check (excessive cross current, power failure, etc.).
・ Automatically obtain control rights for the target substation.
・ Substation equipment operation procedures are executed based on the operator's execution instructions.
・ Procedure history (not executed / normal end / abnormal end) is managed.

-When an operation request to another power distribution control is accompanied, the prior transmission information and the operation request information are requested to the other power distribution control.
• Manage procedure history based on operation results received from other power distribution controls.

-Receive prior transmission information and operation request information received from other power distribution controls.
・ When pre-communication information is received, registration, procedure creation, and schedule registration of other power distribution control subjects are automatically executed based on the transmission content.
-When the operation request information is received, the procedure of the subject of other distribution control is executed based on the operator's instruction, and the operation result is transmitted to the other distribution control.

・ Register the provisional name based on the distribution line stop / switch plan information entered by the operator.
-Manage the procedure creation status for the provisional subject name.
・ Provisionally register a temporary subject with good procedure evaluation as the subject of own power distribution control.
・ Manages the subject of own power distribution control, subject of grid control, subject of other power distribution controls in chronological order.
・ Register the subject of power distribution control for which operation has been completed.
-Cancel and register the subject of power distribution control that was canceled.

-Automatically create distribution line operation / confirmation procedures based on distribution line stop / switch plan information on the planned system.
-The scheduled operation subject and the distribution line device operation / confirmation procedure are automatically created based on the switching procedure creation request information linked from the distribution system information linkage system.

-Create / delete / modify the operation / confirmation procedure for distribution line equipment based on the operator's instructions on the planned system.
-Expand / display the created / deleted / modified procedures on the planned system.
・ At the end of manual creation of the procedure, automatically creates the state data before device operation.

・ Extract the operation procedure (the subject of own power distribution control / subject of system control / subject of other power distribution control) in chronological order.
-Request the procedure deployment to the distribution equipment simulation execution deployment function.
・ Procedure evaluation (good / bad) is set based on the result of procedure development.
-Simulated execution is automatically started at the set time for all procedures scheduled for execution on the day.

-The distribution device procedure requested by the distribution device simulation execution management function is executed on the simulation system.
-Update the display of the simulated system status during procedure development as needed.
-Check the simulated system for abnormalities such as inconsistencies, power outages, distribution line overloads, etc., and evaluate the procedure.

・ Perform operation checks (distribution line overload, power outage, etc.).
-Based on the operator's execution instructions, execute the distribution line device procedure operations.
・ Procedure history (not executed / normal end / abnormal end) is managed.

-Use the planned system creation function / distributed equipment procedure automatic creation function in response to a request for switching the construction subject linked from the distribution system information linkage system to determine whether the distribution line can be switched on the scheduled construction date.

Work at the time of the accident;
・ Accident detection is performed based on the accident judgment conditions held by the system, based on information on status changes such as operation relays and trip CB of distribution substations.
-Based on the status change information related to the detected accident, determine the staged accident situation of the detected accident.
・ Print the determined accident situation on the message panel.
・ Accurately detect accidents and perform staged processing even when accidents occur simultaneously or continuously at multiple facilities.

・ Accident detection is performed based on the accident judgment conditions stored in the system, based on status change information (via relay devices) such as operation relays and trip CBs of distribution substations.
-Based on the status change information related to the detected accident, determine the staged accident situation of the detected accident.
・ Print the determined accident situation on the message panel.
・ Accurately detect accidents and perform staged processing even when accidents occur simultaneously or continuously at multiple facilities.

・ Manage the distribution substation accident cases detected ・ Understand the range of power outages due to the accident ・ Acquire the pre-accident current used when creating the recovery procedure ・ About the accident subject that received the accident section value of the distribution line The switches that are supposed to be locked are automatically monitored to determine the accident section values.
・ For accident titles for which accident section values have been determined, a request for preparation of restoration procedures for healthy power outages is implemented.
-Execute the created recovery procedure automatically or under the instructions of the operator.
-Check the matters necessary for accident management, such as whether or not monitoring is performed at the time of accident and whether there is a sound power outage section at the end of management.

・ For accident titles with confirmed accident points (distribution lines: re-transmission failure accidents, re-transmission success accidents, high-order accidents: collective Y-lock accidents, accidents where substation automatic switching devices operate, etc.) The procedure for restoring the healthy power outage range by switching the distribution line is automatically created.
-In consideration of solar power generation, etc., it is also possible to specify the current value of the distribution line used for calculation when creating the restoration procedure.
・ Automatically create a procedure for restoring a power failure within the range of a power failure due to an accident by switching distribution lines.

・ Accident detection is performed based on the accident judgment conditions stored in the system, based on the status change information such as the operation relay and trip CB of the intermediate substation.
-Based on the status change information related to the detected accident, determine the staged accident situation of the detected accident.
・ Print the determined accident situation on the message panel.
・ Accident detection and staged processing will be implemented even when accidents occur simultaneously or continuously at multiple facilities.

・ Manage the recovery status of detected cases of intermediate substation accidents.

-For power distribution lines that have failed due to an accident, the charge / power failure status of the distribution line sections is sent to the power failure information provision system at regular intervals and at the timing of accident determination until the accident title management is completed.

・ To prevent personal injury, when the distribution line CB trips the accident more than the specified number of times within the specified time, the reclosing relay of the distribution line is automatically locked.

・ Accident detection, display, and alarm for information from 22k VIP Manager.

・ Detects and displays an accident for the information from the 22kV line selective transformer slave station and sounds an alarm.

・ Accident detection and display for information from distribution towers via trunk lines and alarms.

System setting;
・ Substation voltage monitoring, heavy overload monitoring, bank switching destination, operation order, operation takeover form creation, substation equipment activation time, automatic connection status confirmation with distribution automation system, simultaneous operation exclusion items, etc. Set up and manage.

-Monitor and manage heavy overloads of distribution equipment, various settings when creating procedures, distribution line skeleton display method, street map display method, adjacent substation settings, etc.

・ Set and manage the default address of the sensor built-in automatic switch.
・ Set and manage the network address of the automatic switch with built-in sensor.
・ Set and manage individual items of automatic switch with built-in sensor.
・ Set and manage the installation location of the optical central unit.

・ Set and manage IPP power and display switching on the 22 kV system diagram.

・ Sets and manages the automatic simulation execution of the scheduled operation procedure, the execution start time, and the effective time of the simulation execution result.
Set and manage the outage plan from the system monitoring control subsystem 11, whether or not the procedure manual is automatically deleted, and the number of days after the end of the deletion.

• Set and manage audio and alarm output for each external audio alarm device.

Set and manage users and passwords for each login mode (control, maintenance, backup of system monitoring control subsystem 11).

-Set and manage the confirmation method when checking for the one-person operation support function.

・ Set and manage the paper size and orientation when printing the procedure table, batch monitoring results, load record, and accident judgment conditions.
・ Settings and management of message panel automatic printing presence / absence, duplex printing setting, power outage customer list automatic output setting, recording statistics duplex printing.

・ Set and manage the presence or absence of automatic recovery in the event of a substation accident.
・ Set and manage the presence or absence of automatic recovery in the event of a distribution line accident.

・ Set and manage the use / lock of power outage information provision system for each substation, bank and distribution line.

・ Set and manage the load current in consideration of sunlight etc. for each distribution line section.
・ Used during automatic and manual recovery operations in the event of an accident.

Data maintenance;
・ Maintenance of the equipment name, feeder presence, address, etc. of the substation skeleton displayed based on the substation position via the relay device.

・ Sets and manages the substation's TC address and method, on-line system, and test system connection using WAN 20 and communication lines.
-For SV / TM positions for each TC, set and manage the position number, name, method, bit inversion presence / absence, presence / absence of alarm, and presence / absence of printing.
・ Set and manage positions managed by the substation automatic operation device.
・ Set and manage positions for simultaneous operation.
・ Set and manage fault meter positions.
・ Set and manage voltage regulator position combinations.
・ Set and manage automatic change special processing data.
・ Set and manage the positions to be switched between weekdays and holidays.
・ Set and manage accident judgment condition positions for distribution substations.
-Set and manage accident judgment condition positions for intermediate substations.
・ Read and output positions in CSV file.

・ Set, manage, and register the maintenance subject.
・ Maintenance of equipment symbol placement, TM symbol placement, position link, line connection, etc. of substation skeleton displayed based on substation position.
・ Maintenance of the substation overview and schematic connection diagrams will be performed.

・ Maintenance to display on the general monitoring panel such as the connection status of power transmission lines between substations, receiving circuit breakers, power line breakers, etc.

・ Maintenance of the list display chart for each substation, SV type, and TM type for each arbitrary substation.

・ Set, manage, and register the maintenance subject.
・ Maintenance of distribution line equipment arrangement, track connection, specification input, etc. on the common topographic map.
-Linking construction design drawings from the distribution information management system to automatically generate distribution line maintenance subjects.
・ Automatically generate distribution line skeleton from street map data.
・ Automatically generates distribution line maintenance subject based on equipment update information (electric pole position information, information on the completion of newly installed / removed / changed equipment) and contract load update information linked from the distribution information management system. The equipment specification information is automatically registered without generating a subject.
・ Automatically generate distribution line maintenance subject for inconsistent equipment generated by equipment consistency check implemented in the distribution information management system.
-Perform maintenance from the control support PC.

・ Easy to change distribution line switch specifications, energy registration, etc.
・ Register the pole-top transformer tap value for each section and utility pole.

・ Maintain the topographic maps in the system by reading the shared topographic map data. (Use shared topographic map information linked from the new sales process system)

・ Maintenance of distribution line block area, sign code and sign name.

-Expand the maintenance subject in time series and create a maintenance schedule.

-Comprehensive check for consistency of maintenance content.

-Instead of the distribution line load model that is automatically generated from the recorded statistics, manually set and maintain the load model due to solar linkage, etc. when changing the system or registering a new distribution line.

・ Maintenance of TC data of distribution tower and connection status.

・ Set up and maintain the equipment layout and specifications of the distribution tower skeleton.

-Maintain 22 substation skeletons of substation equipment acquired via IP manager.
・ Maintain the 22kV system diagram.
・ Perform data maintenance on positions of substation equipment, track relays, and customer equipment acquired via IP manager.

・ Maintain the address and connection of the master station for 22kV line selection type transformer.
・ Maintenance of 22kV line selection type transformer slave station address, connection / non-connection, transformer type, slave station type, customer name, transformer capacity, etc.
・ Maintenance of measurement value setting.
・ Maintain the connection diagram.

Set and manage the address of the system monitoring control subsystem 11 and the presence / absence of online / test system connection.

Set and manage the address of the distribution monitoring control subsystem 12 and the presence / absence of online / test connection.

Set and manage the address of the integrated NW equipment management subsystem 13 and the presence / absence of online / test connection.

-Set and manage the DX-GW address and presence / absence of connection.

・ Sets and manages the addresses of underground terminals, IP managers, substation systems, and distribution automation systems, and whether or not they are connected.

・ Maintenance of substation system name, SA / UA address, security phone, public telephone number, old network, and new network.

・ Maintenance of distribution automation system name, store code, and SA / UA address.

・ Maintain the relay device name, line number, and presence / absence of line connection.

Training;
-In the console, perform various settings to simulate the substation TC, such as response settings for substation equipment, scenario settings, accident scenario settings, status change settings, and fixed period settings in the simulation mode.
・ Simulate individual operations, normal operations, and accident operations for substation equipment.

-Perform various settings to simulate power distribution equipment such as scenario settings for power distribution equipment and automatic scenario creation in the simulation mode in the console.
・ Simulate individual operations, normal operations, and accident operations for power distribution equipment.

・ Simulate individual operation, normal operation, and accident operation for distribution towers.

・ Create response format for simulation of distribution line switch.

・ Simulate the transmission facing part for the relay device.

・ Automatically create accident scenarios based on system configuration and equipment status.

-Bank current and distribution line current in the simulation can be set arbitrarily (maximum past value, etc.).

It operates on a server or base other than the server of the monitoring control device 10. However, you may operate | move with the server of the monitoring control apparatus 10. FIG.
・ Simulate the substation TC, and implement response setting, scenario setting, automatic accident scenario creation, status change setting, fixed period setting, presence / absence of TC connection, and address management.
-Connect to the supervisory control device 10 and use it for training and competitions.
-Data maintenance in the external simulator is performed by acquiring equipment data from the monitoring control device 10 (power distribution monitoring control subsystem 12).

It operates on a server different from the server of the monitoring control device 10. However, you may operate | move with the server of the monitoring control apparatus 10. FIG.
・ Transmit / receive information that simulates a relay device.
・ Transmit / receive information that simulates a distribution tower.
-Implement various response settings for the switch and send a response with the settings when receiving information.
・ Set the scenario and send information according to the scenario.
・ Automatically create accident scenarios by entering simple information.
・ Send the settings and response to simulate operational contact information.
・ Sets and responds to various information on sensor-equipped devices.
-Connect to the supervisory control device 10 and use it for training and competitions.
-Data maintenance in the external simulator is performed by acquiring equipment data from the monitoring control device 10 (power distribution monitoring control subsystem 12).

・ Set various information simulating 22k VIP Manager and execute transmission.

-Simulate a 22kV line selection type transformer, set various information, and send a response with the setting contents when receiving information.

Cooperation with other systems;
・ Transfer information to and from the substation system during the work of equipment in the position managed within the system (the state of the position not transmitted from the local TC), the substation batch work, and the CPU reclosing relay status Reflect on the system.
-Send / receive information to / from the distribution automation system during the work of equipment in the positions managed within the system (positions not sent from the local TC), batch work of substations, and CPU reclosing relay status And reflect on the system.
The CPU reclosing relay state of the position managed in the system (the state of the position not transmitted from the local TC) is transmitted / received to / from each subsystem and reflected on the system.

-Send / receive cooperation information such as advance transmission of procedure manuals and operation requests between the subsystems 11, 12, and 13.
-Sends and receives stop plan information and device individual operation procedure information to and from the system monitoring control subsystem 11.
-Sends and receives stop plan information and device individual operation procedure information to and from the integrated NW facility management subsystem 13.

-Transmit message information of underground line facility abnormality information of 22 kV or less to the underground terminal through the DX-GW.
-Send message information of accident information of 22kV or less to the distribution automation system through DX-GW.
• Receive and display message information.

-The information which updates the distribution system information of the monitoring control apparatus 10 (distribution monitoring control subsystem 12) and the following information used at the time of a distribution line accident are linked, and the linked information is used by each function.
・ Design document information (construction design drawings)
・ Equipment update information (information on the location of utility poles, information on the completion of newly installed / removed / changed facilities)
-Contract load-Tree cutting information, defective equipment information-Shared topographic map information (used when updating topographic maps)
・ Lightning information

・ The following information is linked to the construction subject. The linked information is used in the scheduled operation work function and the control support function. Refer to each function for the function summary.
-Switchability examination request Based on the scheduled construction date to be linked and the distribution line stop range associated with the construction, the monitoring controller 10 (distribution monitoring control subsystem 12) judges whether or not the distribution line can be switched.
-Switching procedure creation request After the construction date is determined, the scheduled control subject / distribution line switching procedure is created by the monitoring control device 10 (distribution monitoring control subsystem 12) based on the linked construction subject information.

-Link the following construction subject information to the distribution information management system.
-Reply to switchability review request Link the distribution line switchability determination result performed by the monitoring control device 10 (distribution monitoring control subsystem 12).
-Scheduled operation subject information Link related information (related distribution line name, operation results, etc.) of the scheduled operation subject.
-Substation scheduled operation subject Link the scheduled operation subject information associated with the substation stop created independently by the monitoring and control device 10 (distribution monitoring control subsystem 12).

・ Link the updated accident investigation map to the distribution information management system.

Link the updated distribution system information (facility data, system diagram data, system load data, etc.) to the distribution information management system.

・ Thunder information is acquired every 3 minutes from the weather information system, plotted on a common topographic map, and displayed.

Control support;
・ Displays various information on distribution substations.
・ Displays various distribution line information.
・ Display a list of distribution lines outside the original bank.
A display similar to that of the monitoring control device 10 (distribution monitoring control subsystem 12) is performed on the control support PC.

・ Displays a list of scheduled subject names and contents during normal times.
・ Display the subject list and contents on the day of normal times.
A display similar to that of the monitoring control device 10 (distribution monitoring control subsystem 12) is performed on the control support PC.

-Display the record statistics and graphs for each distribution substation bank.
・ Display record statistics and graphs for each distribution line.
A display similar to that of the monitoring control device 10 (distribution monitoring control subsystem 12) is performed on the control support PC.

・ Displays various information related to distribution line accidents.
・ Displays various information related to power supply accidents.
・ Displays various information related to the 22 kV accident.
・ Displays various information related to open phase accidents.
・ Display a list of distribution substations during an accidental power outage.
・ Display a list of distribution lines during an accidental power outage.
A display similar to that of the monitoring control device 10 (distribution monitoring control subsystem 12) is performed on the control support PC.

・ Displays various records such as state changes, operation records, linkage information transmission / reception records, accident records, etc.
A display similar to that of the monitoring control device 10 (distribution monitoring control subsystem 12) is performed on the control support PC.

・ Acquire each current value individually or in batches with CSV.
・ Acquire a list of switch addresses in CSV.
・ Acquire a list of IP addresses of switches with built-in sensors using CSV.
・ Get information on the message panel in CSV format.
・ Acquire a list of scheduled subjects in CSV format.

・ Displays the H / W status.

・ Display the corresponding distribution line from the address.

-Display and obtain records of transmission / reception information with the relay device.

-Display the construction subject information linked from the distribution system information linkage system.

・ Accident investigation map is automatically generated from the maintenance contents of distribution lines.

・ Maintain accident investigation map manually.

・ Display and output the accident investigation map.
・ Manage field operation information (entrance / exit methods, etc.).
・ Display and output tree logging information and defective facility information linked from the new sales process system to the location of the accident investigation map.
-Generate a tap area map on the accident investigation map based on the tap value information managed by the pole tap management function.
・ Display and output lightning information linked from the new sales process system to the location of the accident investigation map.

・ Procedure No. in the scheduled operation procedure and prepare materials for local operators.

-Manage the taps on the pole transformer for each switch section of the distribution line, and colorize the sections for each tap.

・ Displays a list of various information acquired from the controller.

・ Acquire 1-minute average data of the dual controller selected from the controller list on the individual measurement screen or the skeleton screen at the specified period and specified cycle, and totalize and save it.

・ Acquire 1-minute average value data of the selected dual controller, and count and save the phase difference when the switch state is off.

・ Automatically obtain 1-minute average value data for dual controllers and monitor the status of measured values.

・ Automatically obtain 1-minute average value data of the dual controller and monitor the current direction.

-Manually obtain and display the average value data held for 10 minutes for 1 month (40 days) held by the controller.

-Manually acquire and display the average value data held by the controller for one month (40 days) for 30 minutes.

・ Manually acquire and display the year data held by the controller.

• List the controller's unbalance index.

-Obtain or display the daily measurement (average value per minute) held by the IT multi-circuit manually or automatically.

Create one-month data (10 minutes), one-month data (30 minutes), and one-year data based on the acquired daily measurement data (average value for one minute) of the IT multi-circuit.

・ Manually obtains and saves the set value set for the selected controller and displays it on the screen.

・ Get and set the set value for the selected controller or all the controllers registered in the system.

・ Get and set the set value for the selected controller.

・ Obtain a settling value periodically for the dual controller and save the data.

-Manually acquire and display the accident detection log [V0, ground fault, short circuit, 1, 2-wire disconnection, 3-wire disconnection] (up to 4 each) held by the controller.
・ The contents of up to 14 controllers can be displayed at the same time (up to 10 items can be saved in the system).

・ Manually obtain and display instantaneous low pressure drop logs (up to 5 records each) held by the controller ・ Display the contents of up to 5 slave stations simultaneously (store up to 10 records in the system)

-Manually acquire V / I waveforms (one each) stored in the selected controller (acquired waveform data is saved in CSV format)

-Manually obtain Vo / Io waveforms (one each) stored in the selected controller (acquired waveform data is saved in CSV format)

・ Manually obtain V0 accident waveform data (up to 4) stored in the selected controller (acquired waveform data is saved in CSV format)

・ Manually acquire the short-circuit accident waveform data (up to 4) stored in the selected controller (the acquired waveform data is stored in CSV format)

・ When V0, ground fault, or short circuit accident occurs, acquire the accident waveform data from the controller.

・ Manage the acquired waveform data.

・ Receives a status change (V0, ground fault, short circuit, abnormality detection, breaker off, etc.) that is called (transmitted) from the controller, and displays the contents on the screen.

• Display the distribution line skeleton (outline / detail) using the equipment data received from the distribution system.

・ When the V0 call from the controller is received and the accident section is confirmed, the distribution line skeleton is displayed.

-Determine the current direction of the controller based on the switch on / off status and loop configuration in the switch status file.

・ If the accident section cannot be determined when the V0 accident occurs, the operator can compare the V0 / I0 waveforms from the controller so that the operator can judge the accident section (compare waveforms of up to three controllers at a time) Can do it)

・ Displays 1 month data, 1 year data, and short-circuit waveform in graph format.

・ Displays the content of communication with the controller and the result (normal / abnormal).

・ Save various information in CSV format

・ Set the operation of distribution system analysis application.

・ Acquire and display the operation history of the controller.

-Record the operation history changed in the system, display it on screen, and save it in CSV format.

-Make your own settings for the linked controller from the skeleton screen.

・ Acquire waveform data and log data from the controller via the local data collection tool and save them.

Edit the information acquired from SC-D (conveyance) via the management system application and update the set value state table.

-Check the display of the substation.

・ Check the display of distribution lines.

・ Register and change the controller.

-Controls the controller and sends / receives information to / from the external setting device (HT / PC).

・ Automatically create and output various forms for taking over with the trainee.

Record statistics;
・ Aggregate, store, and manage various substation records for scheduled operations.

・ Collect, store, and manage various records of distribution lines for scheduled operations.

・ Automatically generate a record model for seasonal load estimation from distribution line records for scheduled operations.

System monitoring;
-Manage the start and stop of each application when the system starts and stops.
・ Manage the normality / abnormality of each application.
-Check the status of the server Regularly, and in the event of an abnormality, inform the operator and manage the status.
-Manage the start and stop status of each server.
-Manage the communication status for each connected LAN.
・ Manage the master slave.

-In order to carry out system inspections and hardware failure countermeasures, in order to hand over to hardware maintenance manufacturers, settings are made so that applications are not activated, and administrator passwords are automatically changed to inspection passwords.
-When the inspection is completed, the settings for starting the application and the administrator password are automatically changed.

-Notify the application management location (head office) server of application and facility data abnormalities.

-System monitoring control subsystem 11, power distribution monitoring control subsystem 12, integrated NW equipment management subsystem 13, DX-GW, TC, underground terminal, substation system, power distribution system, IP manager connection status, initial status Management display.

・ Manage and display the line status with each distribution tower.

-Manage the line status with the relay device.

-Manage the line connection status with the sensor built-in switch.

• Manage 22kV line selection type line status.

system management;
・ Equivalent processing of 1-system and 2-system databases can be separated, and database files can be added, deleted, and changed for each system without stopping the entire system.

・ Install new applications while managing them from the kernel settings in the server, including directory configuration and middleware settings.

-The control station operator can replace the application by himself / herself according to the system operating status regarding the function improvement contents.

・ Operator PC application can be installed. The support PC is a terminal that performs recording, information display, maintenance, and the like on the recording processing system NW side.

-The operator manually backs up the equipment data from the application to the tape device.

  A specific example of the system function of the integrated NW facility management subsystem 13 is shown below.

Equipment monitoring;
-Status monitoring Based on SV / TM information, the status of substation equipment is monitored.
-Substation status monitoring Monitors the status of substation equipment based on SV / TM information at the time of status change.
-Heavy overload monitoring Based on the heavy overload monitoring setting value of the setting value change job, the received periodic periodic TM information is analyzed and heavy overload monitoring is performed.
・ Voltage monitoring Based on the voltage monitoring setting value for the setting value change job, the received periodic period TM information is analyzed and voltage abnormality is monitored.
-A-system error recovery monitoring Based on the A-system error status of the SV during status change, A-system error recovery occurrence / recovery is monitored.
-TC system monitoring The occurrence / recovery is monitored based on the substation status in the SV / TM information.
-SV status mismatch When the SV / TM information does not match the system, SV status mismatch processing is performed.

Operation procedure table creation;
Stop Schedule List Lists the stop plan information received from the monitoring control device 10 (system monitoring control subsystem 11, power distribution monitoring control subsystem 12). Further, it is possible to change the content of the scheduled stop subject and add a subject to the scheduled stop subject unique to the integrated NW facility management subsystem 13.
-Work subject list Lists the work subjects created from the scheduled subject. It is also possible to change or delete the contents of the work subject.
Device-specific procedure list A list of device-specific procedure contents received from the monitoring control device 10 (system monitoring control subsystem 11, power distribution monitoring control subsystem 12) is displayed. In addition, it is possible to add a local operation procedure to the device individual operation procedure.

Create, edit, and print a charging unit confirmation diagram that displays device status and charging status using skeleton screen data. However, the storage function of the charging unit confirmation diagram is not provided. There are two types of charging unit check diagrams in the charging unit check diagram.
1) Displaying the pre-operation status of the individual device operation procedure.
2) Equipment that can freely set the device status.

On the device individual operation procedure screen, the device individual operation procedure information received from the system monitoring control subsystem 11 and the power distribution monitoring control subsystem 12 is registered and managed as a device individual operation procedure. The individual operation procedure can be added or corrected by the integrated NW facility management subsystem 13.

Accident / failure handling operations;
• If a state change due to an accident or failure is detected, edit the state change alarm sound, flicker, status inversion, and automatic state change message.

Record work;
a. Recording unit The recording unit is as follows.
(A) Daily report record (record showing daily measurement status)
(I) Extract and record the largest of the measured or calculated values every hour.
(Ii) If the maximum value is the same value and occurs more than once in a day, use the first value that was generated 3.5-10.
(Iii) In bank-related maximum value processing, if there are one or more stopped banks at a certain time, not only the bank but also other healthy banks in the same hierarchy exclude the data at that time, The maximum value is calculated from the data.
(IV) However, if the bank rating is “0” due to the data maintenance setting, the normal maximum value processing is performed except for the bank.
(V) Of measurement data at a certain time, if the measurement abnormality occurs, the time data is excluded from the maximum value processing.
(Vi) If abnormal measurement continues throughout the day, “abnormal” is printed.
(Vii) When one bank is stopped all day (1 to 24), the maximum value processing of all banks is impossible. When a plurality of banks are alternately stopped at every hour, the maximum value processing of all banks is impossible from the viewpoint of the maximum value processing. In this case, the maximum apparent power and the maximum power are printed as “stop”, and the related time, voltage, and current data fields are blank. The same processing is performed for the bank when the rated value is “0”.
(Viii) If “abnormal” and “stop” overlap, “abnormal” is assumed.
(IX) The maximum value of secondary current and apparent power of the transformation is determined by absolute values. However, if the value is negative, the display is signed.
(B) Substation operation monthly report record (hereinafter referred to as monthly report) The maximum value of the current month is extracted from the results of processing the maximum value of the daily report showing the measurement status in units of months, and the date, current, voltage, etc. at that time Add the related items.
The total apparent power of all banks (maximum monthly) is the maximum value of the total apparent power of all banks at every hour.
The maximum value of the “current maximum secondary current” and “current maximum apparent power” is determined as an absolute value. However, if the value is negative, the display is signed.

-Collect and save the measured values of all substations every hour on the hour, every day at 24:00, and every minute.
a. The editing timing includes automatic editing performed every hour, every day at 24:00, every minute, and editing when requested.
b. The storage period varies depending on the editing timing.
(A) In the case of automatic editing, it is 7 days or 2 months including the latest editing, and the oldest record is deleted.
(B) In the case of edit on demand, no saving is performed.
c. There are the following three editing periods.
(A) Edit contents from automatic editing to automatic editing.
(B) Edit contents from automatic editing to on-demand editing.
(C) Edit the contents at the time of request.
d. The editing condition shall specify the editing period, substation batch or multiple substations.
e. When working, edit with the value of previous value hold.
f. Report format The report format is fixed by the system.

・ The operation takeover record shows the substation's "heavy overload status", "equipment abnormal status", "working test setting status", "grounding attachment / detachment status", and "system status" from the previous automatic editing to the current editing time. Edit the status difference and ongoing anomalies. The name on the screen is “equipment operation”.

Request function;
・ SV on demand
Request SV information in TC units.
・ TM on demand
Request TM information in TC units.

-SV work setting status Requests the SV work setting status for each substation and TC.
-TM work setting status Request TM work setting status for each substation and TC.

-Setting status during SV test Requests the setting status during SV testing for each substation and TC.
・ Setting state during TM test Requests the setting state during TM test for substation units and TC units.

-Request a control right acquisition location for each substation.

Setting value change function;
・ Transmission (transmission substation) sets transmission lines and transformers, and distribution (distribution substation) sets heavy load / overload / occurrence / recovery time of transformers, and whether the equipment is locked or not. .

・ Transmission (substation for power transmission) is the main bus monitoring width / time / voltage value, and distribution is the transformer monitoring width / heavy load voltage / voltage value / light load current / voltage value / reference value The setting rate (90-2, 3) and the alarm lock presence / absence of the equipment are set. Set the number of sampling occurrences / returns in the system batch.

Work at the time of the accident;
・ Set the status of the non-distance device on the skeleton screen.

・ Set the non-distant grounding status on the skeleton screen.

-On the skeleton screen, set the working / testing status to TC units / equipment units.

Subject management;
・ When the stop schedule is confirmed, the work subject is automatically created from the information of the stop schedule.
a. Work subject creation timing The work subject automatic creation process occurs at the following times.
1) Timing when a new stop schedule is created and registered in the integrated NW facility management subsystem 13.
2) The timing when the stop schedule is changed and registered, and the plan No status becomes “initial transmission (confirmed)”, “retransmission (confirmed)”, and “maintenance creation”.
b. Scheduled stop for the creation of the work subject The work subject is created from the scheduled stop, but the scheduled stop must meet the following conditions to create it.
1) a. The scheduled stoppage registered in the section.
2) The operation classification of the plan No. scheduled to be stopped is “scheduled work”.

-The scheduled stop subject is a subject created from the stop plan information received from the monitoring control device 10 (system monitoring control subsystem 11, distribution monitoring control subsystem 12), and subject created in the integrated NW equipment management subsystem 13. There is. The titles created by the integrated NW equipment management subsystem 13 are divided into two types: “Kashiwa type” and “No stop”. In the case of “types” that involve substation equipment shutdown such as CVCF shutdown work, subject management on the scheduled shutdown screen and work subject screen is possible. On the other hand, in the case of “no outage” that does not involve the suspension of substation facilities, such as weeding a substation, subject management is possible only on the work subject screen. On the work subject screen, the daily work created by the integrated NW facility management subsystem 13 is managed based on the scheduled stop subject. The work subject can be freely modified and deleted.

  The PC data maintenance tool (hereinafter referred to as “PC data”) is a notebook PC that provides a data editing (subject / change data creation) function using PC data data (kda). The subject can be registered from a notebook PC (PC device). A two-layer common DB to be mounted on the integrated NW facility management subsystem 13 is provided. It is possible to connect to a PC device and network, and subject registration to a two-tier common DB.

Basic data of the integrated NW equipment management subsystem 13 and standard TCPIF can be created from the two-tier common DB. At the time of data expansion, each expansion result is automatically output to a printer.

The basic data of standard TCIF created by data expansion is tested by standard TCIF. In order to pass the basic data to the standard TCIF, the basic data of the standard TCIF is output to a portable medium that can be used by both the standard TCIF and the integrated NW facility management subsystem 13.

Configuration control;
-Each apparatus which comprises the integrated NW equipment management subsystem 13 is made into a single structure, and each apparatus does not have dependency among each apparatus, but operates independently.

・ Each device constituting the system should be loosely coupled so that even if a device fails, the function of the failed device is stopped, but other functions can be operated.

  Abnormalities that can be detected by the integrated NW facility management subsystem 13 include hardware abnormalities, software abnormalities, middleware abnormalities, external contact input abnormalities, and the like.

-Display the operation status of each device constituting the integrated NW facility management subsystem 13 on the "operation screen". It also displays the hardware and software failure status.

-Edit the status of equipment to be monitored, equipment status change, substation equipment status setting, or TC status change. Edit set value changes and alarm lock settings.

・ Edit information on scheduled stoppage and individual procedures.
• Edit the alarm lock settings.

-Edit the transmission / reception error information with other systems.

Edit the system abnormality information of the integrated NW facility management subsystem 13.

・ Messages to be edited can be cleared by function type. Only new messages are displayed after clearing. By releasing WAIT, the displayable message including the message before clearing is displayed again.

IP business;
・ A signal transmitted in a non-IP system is converted to IP and a transmission route is switched.
a. Slave station TC transmission line configuration (4W2R type)
The transmission circuit is duplexed for both the uplink and downlink, and the uplink is received by line switching in the IP unit, and the downlink is hybrid-branched and switched by the line switching apparatus on the slave station TC side.
b. Slave station TC transmission line configuration (4W1R type)
Since the transmission line has a single route configuration for both the upstream and downstream lines, it is directly connected to the serial transmission unit of the IP device.

-Connect to LAN-IF with a 2-port LAN connection.

-Connect to the IP-IF device via a 2-port LAN connection.

Information is transmitted / received from the IP device to the host LAN using IP multicast communication or unicast communication according to the type of information.
a. Information is transmitted and received from the IP device to the TC-LAN using IP multicast communication or unicast communication.
b. Multicast address assignment is basically performed on different addresses on the transmission side and the reception side of the IP device.
c. The transmission method for each information is as follows.
Display / Measurement Uplink = Multicast Downlink = Multicast / Unicast Control Uplink = Multicast Downlink = Unicast SOE Uplink = Multicast Downlink = Unicast Time synchronization Uplink = Unicast Downlink = Unicast d. Transmission for upper NW Information is transmitted from the regular system to the upper NW. At this time, the destination IP address is a multicast address, and the source IP address is the IP address of its own unit board. Information is collected in units of IP devices, and transmission from one IP to only one destination is performed. (Destinations are not individually set in the slave station TC, IP-IF device unit, and word unit)
e. Reception from the host NW The information transmitted from the host system is received by the regular system of the IP device. At this time, the destination IP address is a virtual IP address, and the source IP address is the IP address of the own unit port.

-The same data is transmitted to each of the independent upper NWs of n lines, and the receiving side receives only one information by first-come-first-served / last-arrival discard.

-For information that requires transmission guarantee, guarantee transmission by the retransmission procedure.
a. For information that requires transmission guarantee, the transmission is guaranteed by the retransmission procedure.
b. The transmission guarantee can be changed for each data type. (Information for notification of status change (for example, display status change) is guaranteed to be transmitted, and information for transmitting the same item at a fixed period (for example, fixed period measurement information) is not guaranteed to be transmitted.)
c. The retransmission procedure is performed by transmitting information with a serial number on the transmission side at regular intervals and requesting retransmission when the reception side detects a missing serial number.

The slave station TC information and IP-IF device information perform transmission / reception management of uplink / downlink data according to the route state.

-Edit the slave station TC detection error information received by the SV position or flag information from the slave station TC and the CDT line status detected by the IP device into the error presence / absence information of the station TC and distribute it to the host device .
a. Error presence / absence information request / error presence / absence information Error information (control line disconnection, control traffic jam, etc.) detected by the slave station received from the SV position or flag information from the slave station TC and the CDT line status (display line disconnection) detected by the IP device , Display traffic congestion) is edited into the error presence / absence information of the slave station TC and distributed to the upper maintenance system. When receiving an error presence / absence information request from the host maintenance system, the IP device distributes and returns the error presence / absence information of the slave station.
b. Selection control / selection control return The selection control received from the host system is transmitted to the slave station TC. The selection completion position received by clicking again from the slave station TC is monitored, edited to the selective return information of the slave station TC, and distributed and returned to the host device.
c. Upstream SV data

・ Detects the status change of the accident section information word received from the slave station TC by CDT, and distributes it to the upper system when the status change occurs.

・ Data management of operation mode transition and information transmission of IP device is performed.
a. The operation mode is normal / standby / test / stop.
b. The operation mode is identified by the DR classification and the data type.

-Monitors the failure of the local device and other connected devices, and notifies the host device of transmission as error information at the occurrence / recovery status change detection timing.
a. It monitors the failure of its own device and other connected devices, and notifies the host system of transmission as error information at the occurrence / recovery status detection timing.
b. Error information is stored in the device and notified when error information is requested from the host system.
c. If information loss occurs due to an unexpected multiple state change, it must have a data supplement function to match the latest information.

-Transmission data to be transmitted / received (HDLC packet data, CDT transmission data, LAN packet data) can be displayed at the transmission / reception timing.

The current state of display information of the slave station TC and the IP-IF device can be displayed in units of transmission words between the IP device and the slave station TC and the IP-IF device.

a. Selection control for the slave station TC and the IP-IF device can be performed.
b. During selection control by the maintenance tool, selection control from the host device is not accepted, and the operation is a two-behavior method.

System common function;
-Provide an operation mode for each functional unit installed in the system, and perform management and control according to the state of the equipment.

・ Allows continuous monitoring of the status of substations, making it easy to understand the local conditions at the time of an accident, etc., and facilitating support for creating procedure tables and data creation associated with power system / equipment changes Prepare an HMI.

・ The following functions can be operated. System monitoring, substation status monitoring (skeleton, message, mode setting, crisis status setting, function, alarm flicker stop), setting, request, recording, procedure, dem, external output, alarm lock, Printer setting, substation setting, testing, operation

-Edit and save the message information necessary to understand the state of the equipment, and display the message. The underground line equipment abnormality is transmitted to the underground terminal.

-Save various record information, message information, trace information, screen hard copy information, etc. to the connected PC.

・ Password management is used for external output.

-The recorded information file has the original file in the determined storage directory, and the file specified from the external output screen is acquired. The file format to be output to the external medium is a CSV format or a binary format.

-The message information file has the original file in the determined storage directory, and the file specified from the external output screen is acquired. The file format to be output to the external medium is the CSV format. If the message information file is poorly acquired, an announcement is made with a dialog message.

-The system abnormality information has the original file in the determined storage directory, and obtains the file specified from the external output screen. The file format to be output to the external medium is the CSV format.
・ If the system error information file is poorly acquired, a dialog message will be announced.

-Screen hard copy information is saved as a jpeg image in a predetermined saving directory. Acquires the file specified from the external output screen and outputs it to the external medium.
If the screen hard copy information file is poorly acquired, a dialog message will be announced.

-As for the screen hard copy information, a terminal screen instructed from the external output screen is created as a Jpeg file and stored in a predetermined storage directory.
If the JPEG file of screen hard copy information is poorly created, an announcement is made with a dialog message.

-Connect to the test system of the supervisory control system and confirm the SV / TM data of newly created data. Switching between the operation system and test system is performed individually for each monitoring operation terminal.

・ In the maintenance system, switching the monitoring operation terminal to the test system enables operation of various test systems. A monitoring operation terminal having two monitors can switch test systems individually (even with only one of the monitors). If it is possible to switch the number of all monitoring operation terminals to the test system, all monitoring operation terminals can be used as the operation system.

-In the maintenance system, the test system function continues processing even when there is no monitoring operation terminal switched to the test system.

-Maintain independence of functional data between the operational system and the test system. For example, the outage plan information received in the active system and the outage plan information received in the test system are different information, and the state check is not performed even if the plan number is the same.

-Connect directly to the control line and send / receive information to / from other systems directly connected to the control line.

  As described above, in the present embodiment, the monitoring control device 10 that monitors and controls the plurality of substation devices 63, 64, 73, and 74 provided in the substations 60 and 70, and the plurality of substation devices 63, Relay devices 31, 41, 61, 71, 62, and 72 that relay information transmitted and received between the monitoring control device 10 and the relay devices 31, 41, 61, 71, and 62. , 72 mutually convert information that does not conform to the international standard communication protocol and information that conforms to the international standard communication protocol between the plurality of substation devices 63 and 73 and the monitoring and control apparatus 10. The first relay unit 31, 41, 61, 71 that relays, and the second relay unit 31 that relays information that conforms to the international standard communication protocol between the plurality of substation devices 64, 74 and the monitoring control device 10. , 41, 6 It has, and 72. According to such a configuration, it is possible to operate a facility that conforms to the international standard (substation equipment 63, 73) and a facility that does not conform to the international standard (substation equipment 64, 74). . Therefore, it is possible to provide extensibility that can flexibly and quickly respond to changes in the system configuration, and to ensure interoperability and compatibility with other applications. Moreover, the monitoring and control apparatus 10 communicates by the communication system based on the same international standard, without distinguishing the equipment based on the international standard in the facilities of the substations 60 and 70 and the equipment not based on the international standard. Can do. Therefore, it is not necessary for the monitoring control apparatus 10 to recognize the transmission format for each communication protocol, the transmission procedure, etc., monitoring control is simplified, and system development costs can be suppressed.

  In the present embodiment, the second relay units 31, 41, 62, 72 collect information from the plurality of substation devices 64, 74, transmit the information to the monitoring control device 10, and receive information from the monitoring control device 10. Are configured to include gateways 62 and 72 (see FIG. 3). According to such a configuration, since the gateways 62 and 72 (that is, the FGW) are directly connected to the monitoring control device 10 (that is, the FEPs 15a and 15b), the existing system configuration (GWs 31 and 41 and TCs 61 and 71) is changed. A system configuration (FGW 62, 72) compliant with international standards can be added without change.

  In the present embodiment, the second relay units 31, 41, 62, 72 transmit information from the monitoring control device 10 and transmit information from the plurality of substation equipment 64, 74 side to the monitoring control device 10. First gateways 31 and 41, and information from the first gateways 31 and 41 are transmitted to the plurality of substation devices 64 and 74, and information from the plurality of substation devices 64 and 74 is collected to obtain the first gateway 31. , 41, and the first gateways 31, 41 also serve as information relays in the first relay unit (see FIG. 4). According to such a configuration, the second gateways 62 and 72 (that is, the FGW) are connected to the monitoring control device 10 (that is, the FEPs 15a and 15b) via the nearby first gateways 31 and 41. Laying becomes easy, and the system configuration can be reliably realized.

Second Embodiment
In the first embodiment described above, the monitoring control device 10 is provided in the data centers 1A, 1B, and 1C. On the other hand, in 2nd Embodiment, the monitoring control apparatus is provided not only in data center 1A, 1B, 1C but in the control center.

  FIG. 17 is a system configuration diagram showing the configuration of the monitoring control system SYS-B according to the second embodiment of the present invention. In the supervisory control system SYS-B shown in FIG. 17, a GW 35 is provided at the control station 30 and a GW 45 is provided at the control station 40. The GWs 35 and 45 have the same configuration as the GWs 31 and 41 in the first embodiment. The GWs 35 and 45 incorporate monitoring control devices 36 and 46, respectively. The monitoring control devices 36 and 46 have the same configuration as the monitoring control device 10 in the first embodiment. That is, the monitoring control devices 36 and 46 include a system monitoring control subsystem, a power distribution monitoring control subsystem, and an integrated NW facility management subsystem. In FIG. 17, the same components as those shown in FIG. In FIG. 17, the GW 51 of the control center 50, the power distribution facility 80, the operation service bus 110, the system operation service bus 111, and the external system 100 are omitted.

  The monitoring control devices 36 and 46 receive information passing through the GWs 35 and 45, that is, information exchanged between the monitoring control device 10 and the facilities (61 to 64 and 71 to 74) of the substations 60 and 70. Stored in a database (not shown). Thereby, when an abnormality such as a failure occurs in the monitoring control device 10, the operator of the control station 30, 40 uses the monitoring control device 36, 46 under the control of the control station 30, 40. Operation can be continued. In the second embodiment, the functions of the monitoring control devices 36 and 46 are provided in the terminals of the GWs 35 and 45 provided in the control stations 30 and 40. However, the functions are provided in the control stations 30 and 40. The supervisory control device may have a GW function.

<Third Embodiment>
In the third embodiment, a monitoring control system having a configuration different from the monitoring control systems SYS-A and SYS-B described in the first and second embodiments is shown.

  15 and 19 are system configuration diagrams showing the configuration of the monitoring control system according to the third embodiment of the present invention. The monitoring and control system according to the third embodiment includes a power generation and distribution facility 501, a substation / distribution automation device 502, a field device 503, a metering subnet 504, and other control centers 505. These devices are connected to a utility communication network 500 (MPLS / IP) which is a communication network compliant with international standards. The utility communication network 500 corresponds to the WAN shown in FIGS.

  The power generation and distribution facility 501 corresponds to the substation equipment 63 and 73 under the control of the TCs 61 and 71 in FIGS. The substation / distribution automation apparatus 502 also corresponds to the substation equipment 63 and 73 under the control of the TCs 61 and 71 in FIGS. The field device 503 corresponds to the substation equipment 64 and 74 under the FGWs 62 and 72 in FIGS. The metering subnet 504 is a part that transmits information related to the amount of power in each consumer. Each consumer is provided with a communication meter (smart meter (registered trademark)) in a watt-hour meter that measures electric power digitally. The metering subnet 504 transmits information regarding the amount of power from the watt hour meter to the AMI NMS 554 via the utility communication network 500. The other control center 505 is a control center such as a consumer or another electric power company.

  In addition, the monitoring control system includes a control center operation 541. The control center operation 541 includes an ICCP gateway 521, a SCADA gateway 522, an IEC 61850 gateway 523, a SCADA 542, a DER optimization 543, an energy management system (EMS) 544, and a DMS / OMS 545. The ICCP gateway 521, SCADA gateway 522, IEC 61850 gateway 523, SCADA 542, energy management system (EMS) 544, and DMS / OMS 545 are connected to the real-time real-time service bus bus 550, and these devices communicate information via the real-time service bus 550. Send and receive.

  The ICCP gateway 521 is connected to the utility communication network 500 via a communication line of a communication protocol of IEC 60870-6-TASE-2. The SCADA gateway 522 is connected to the utility communication network 500 via a communication line of a communication protocol of DNP3 / IEC60870-5-104 / OPC. The IEC 61850 gateway 524 is connected to the utility communication network 500 through a communication line of an IEC 61850 communication protocol. The ICCP gateway 521, the SCADA gateway 522, and the IEC 61850 gateway 523 correspond to the GWs 31 and 41 in FIGS. The SCADA 542 corresponds to the SCADA function of the system monitoring control subsystem 11 and the power distribution monitoring control subsystem 12 of the monitoring controller 10 in FIGS. The real-time service bus 550 corresponds to the real-time service bus 14 in FIGS. Note that FIG. 18 does not show a configuration corresponding to the FEPs 15a and 15b.

  The DER optimization 543 (DER: Distributed Energy Resource) is a part that optimizes the power supply and demand of the distributed energy resource. The EMS 544 corresponds to the EMS function that the system monitoring control subsystem 11 has. The DMS / OMS 545 corresponds to a DMS function and an OMS function (OMS: Outage Management System) that the power distribution monitoring control subsystem 12 has. The DER optimization 543, the EMS 544, and the DMS / OMS 545 are connected to the operation service bus 600 and the system operation service bus 610. The operation service bus 600 corresponds to the operation service bus 110 in FIG. 1, and the system operation service bus 610 corresponds to the system operation service bus 111 in FIG.

  In addition, the monitoring control system includes a network facility management 551. The network facility management 551 corresponds to the integrated NW facility management subsystem 13 in FIGS. However, the network facility management 551 shown in FIG. 18 is arranged as a device different from the monitoring control device 10. The network facility management 551 includes a 61850 SCL gateway 525, an SNMP gateway 526, a dedicated gateway 527, a CNMS 552, a device / configuration management 552, and an AMI NMS 554. The 61850 SCL gateway 525, the SNMP gateway 526, and the dedicated gateway 527 are connected to the utility communication network 500. The CNMS 552 and the device / configuration management 553 are connected to the 61850 SCL gateway 525, the SNMP gateway 526, and the dedicated gateway 527.

  The CNMS 552 is a network management system that manages a network. The device / configuration management 553 corresponds to the configuration / setting management function of the integrated NW facility management subsystem 13. The AMI NMS 554 (AMI: Advanced Metering Infrastructure, NMS: Network Management System) is connected to the utility communication network 500 and the system operation service bus 610 and receives information on the amount of power from the metering subnet 504 in the utility communication network. The information regarding the received electric energy is transmitted to the AMI 581 through the system operation service bus 610.

  The utility communication network 500, the operation service bus 600, and the system operation service bus 610 are connected via a device dedicated gateway 524. For example, information on devices such as sensors under the field device 503 can be stored directly in the data warehouse 567 via the device dedicated gateway 524 without going through the control center operation 541 and the network facility management 551.

  The utility communication network 500, the operation service bus 600 and the system operation service bus 610 are connected via a video gateway 528. Image information of a monitoring camera (for example, a monitoring camera under the control of the field device 503) provided in the substation can be stored in the data warehouse 567 via the video gateway 528 or monitored by a predetermined terminal. . The utility communication network 500, the operation service bus 600, and the system operation service bus 610 are connected via an FTP gateway 529. The substation is provided with a setting device capable of writing setting information (for example, a device for performing setting such as operation at an amperage), and the setting information for the setting device is FTP gateway 529 (FTP; file transfer protocol). Can be transmitted from the predetermined terminal to the setting device.

  The supervisory control system includes engineering and planning 561. Engineering and planning 561 corresponds to the tool 104 of the external system 100 in FIG. The engineering and planning 561 includes network planning 562, visualization 563 (visualization), performance analysis 564, performance data 565, protection and failure investigation 566, and data warehouse 567.

  The monitoring control system has reference information 571. The reference information 571 corresponds to a database provided in the monitoring control apparatus 10 in FIGS. The reference information 571 stores information such as a power supply network, topology, impedance, rating, and CIM model.

  The monitoring control system includes an AMI 581, an OMS 582, and a market operation 583 connected to the system operation service bus 610. The AMI 581 collects information related to the amount of electric power sent from the monitoring control device of the data center in the metering subnet main, and manages the collected information.

  The real-time service bus 550 and the enterprise service bus 601 are connected via an inter-application linkage 701 for linking messages between applications. The system operation service bus 610 and the enterprise service bus 601 are connected via an inter-application linkage 702 for linking messages between applications. The inter-application cooperation 701 and 702 is configured by middleware, for example. The inter-application cooperation 701 and 702 correspond to the inter-application cooperation 101 and 102 in FIG. A human resource management 602, asset management 603, geographic information system 604, customer information system 611, customer portal 612, and automatic voice response 613 are connected to the enterprise service bus 601. The human resource management 602, asset management 603, geographic information system 604, customer information system 611, customer portal 612, and automatic voice response 613 correspond to the tool 104 of the external system 100 in FIG.

  As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. Various modifications or improvements can be added to the above embodiment without departing from the spirit of the present invention. In addition, one or more of the requirements described in the above embodiments may be omitted. Such modifications, improvements, and omitted forms are also included in the technical scope of the present invention. In addition, the above-described embodiments can be applied in appropriate combination.

  For example, the data center is not limited to three locations, and may be one location or two locations or four or more locations (for example, 10 locations). Also in this case, a monitoring control device is provided in each data center, and a predetermined function is assigned to these monitoring control devices. Further, the monitoring control device 10 may be provided in a power supply station or the like instead of the data center.

  In the system configuration shown in FIG. 1 and the like, the GWs 31 and 41 are arranged in the control stations 30 and 40. However, the present invention is not limited to such a configuration, and may be installed at an optimal installation location (control station, substation, etc.) in consideration of the GW installation schedule, cost, disaster countermeasures, and the like.

  Also, the information format configuration shown in FIG. 9 and the transmission procedure shown in FIG. 10 are examples, and other format configurations and transmission procedures may be used. In addition, in FIG. 1 and the like, a configuration in which only one GW is provided in the control station is illustrated, but a configuration in which a plurality of GWs are provided in the control station may be used.

SYS-A, SYS-B Monitoring and Control System 10 Monitoring and Control Device 11 System Monitoring and Control Subsystem 12 Power Distribution Monitoring and Control Subsystem 13 Integrated NW Facility Management Subsystem 15a, 15b FEP
20 WAN
30, 40 Control station 31, 41 GW (relay device, first relay unit, second relay unit, first gateway)
61, 71 TC (relay device, first relay unit)
62,72 FGW (relay device, second relay unit, second gateway)
63,64 Substation equipment 73,74 Substation equipment

Claims (6)

A monitoring control system including a monitoring control device for monitoring and controlling an electric power system,
The monitoring and control device includes:
A creation unit for creating a procedure table for instructing an operation including a scheduled stop of the facility in the power system and a change of the power system;
And a control unit that executes the operation based on the procedure table created by the creation unit. A database for storing the operation procedure of the equipment and the subject in association with each other;
The monitoring control system according to claim 1, wherein the creation unit creates the procedure table based on an operation procedure corresponding to a subject of an operation target stored in the database.   The monitoring control device monitors the charge / power failure state of the facility in the power system, and manages first information for managing the charge / power failure state of the facility to be monitored and information on the facility to be monitored in the power failure state The monitoring control system according to claim 1, further comprising: an information transmission unit configured to transmit the second information to the terminal of the power supply station.   The monitoring control system according to any one of claims 1 to 3, wherein the control unit executes control of the equipment on condition that the control right for the equipment in the power system is acquired.   5. The monitoring control apparatus according to claim 1, further comprising an accident information transmission unit that creates information related to an accident including a power outage in the power system and transmits the information related to the generated accident to related locations including a power supply station. The monitoring control system according to claim 1.   The supervisory control system according to any one of claims 1 to 5, wherein the supervisory control device includes a power failure information posting unit that creates power failure information in the power system and posts the created power failure information on the Web. .

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