JP2011120352A - Apparatus and method for simulating power system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce an amount of correction from a predetermined default state when the initial open/closed states of an electrical switch, a switch, a relay, or the like comprising a power system are set before a monitor and control system is tested using a power system simulator. <P>SOLUTION: Before the connecting state of the power system is set, power system setting rules that define the open/closed state patterns of electric switches used in the power system are generated. The most suitable rule is selected from among them to set the connecting state and this setting can be thereafter corrected. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a power system simulator capable of verifying the operation of a monitoring control system that monitors and controls devices such as switches, switches, and relays constituting the power system from a distance before connecting to the actual power system. And the electric power system simulation method.

  The conventional power system simulation device refers to the device information of each device, sets the open / close state of each device so that the connection form of the power system matches the operation mode, and uses the open / close state of each device as a condition The tidal current calculation is executed to calculate the amount of electricity in the power system (see, for example, Patent Document 1).

JP-A-11-262175 (page 5-6, FIG. 1, FIG. 3, FIG. 4)

  In the conventional power system simulation device, when the connection state of the power system is set, the open / close state of each device is set to a standard connection state. The setting state is limited to the standard connection state, the default state is an arbitrary connection state, for example, all open state, all closed state, transmission line 1 is connected to the Oto bus line, and transmission line 2 is connected to the bus line, In order to operate in an arbitrary connection state, there is a problem that the state correction after the default state setting increases.

  The present invention has been made to solve the above-described problems. When arbitrarily setting the connection state of the equipment of the power system, a setting rule that is close to the open / close state to be set is selected. The purpose is to set the initial state of device connection and reduce state correction after setting the default state.

In the power system simulation apparatus according to the present invention, a device that constitutes a power system such as a switch, a switch, and a relay, a facility database that defines a relationship between facilities such as a transmission line and a transformer, and stores device information; A plurality of power system setting rules that define the open / closed state of the device, and the initial state of the device is set based on the selected setting rule.

  Since the present invention sets the open / close state of the devices constituting the power system based on the selected power system setting rule, the default state close to the open / close state to be set can be set, and the open / close state to be set Therefore, it is possible to reduce the state correction after setting the default state so that the initial state to be set can be easily set.

It is a block diagram of the electric power system simulation apparatus which shows Embodiment 1 and 2 of this invention. It is a figure showing the position data of the apparatus of the electric power system which simulates Embodiment 1 and 2 of this invention. It is a connection diagram of the electric power system which simulates Embodiments 1 and 2 of the present invention. It is a figure of the equipment database which relates the apparatus and equipment of the electric power system which simulates Embodiment 1 and 2 of this invention. It is a figure showing the electric power system setting rule (1) which shows Embodiment 1 and 2 of this invention. It is a figure showing the electric power system setting rule (2) which shows Embodiment 1 and 2 of this invention. It is a figure showing the electric power system setting rule (3) which shows Embodiment 1 and 2 of this invention. It is a figure showing the electric power system setting rule (4) which shows Embodiment 2 of this invention. It is a figure explaining description of the electric power system setting rule which shows Embodiment 1 and 2 of this invention. It is the flowchart 1 showing the default state setting method which shows Embodiment 1 of this invention. 2 is a flowchart 2 showing a default state setting method according to the first embodiment of the present invention. It is a figure showing the opening-and-closing state installation value when the rule number which shows Embodiment 1 of this invention is 001. It is a figure showing the opening-and-closing state setting value when the rule number which shows Embodiment 1 of this invention is 002. It is a figure showing the opening-and-closing state setting value when the rule number which shows Embodiment 1 of this invention is 003. It is a figure showing the opening-and-closing state setting value when the rule number which shows Embodiment 1 of this invention is 004. It is a figure showing the opening-and-closing state setting value when the rule number which shows Embodiment 1 of this invention is 005. It is a figure showing the opening-and-closing state setting value when the rule number which shows Embodiment 1 of this invention is 006. It is a figure showing the opening-and-closing state setting value when the rule number which shows Embodiment 1 of this invention is 007. It is a figure showing the opening-and-closing state setting value when the rule number which shows Embodiment 1 of this invention is 008. It is the flowchart 3 showing the default state setting method which shows Embodiment 2 of this invention. It is the flowchart 4 showing the default state setting method which shows Embodiment 2 of this invention.

Embodiment 1 FIG.
FIG. 1 is a block diagram of a power system simulation apparatus showing Embodiments 1 and 2 of the present invention. 1 shows a power system simulation device for operation verification of a monitoring control system that monitors and controls devices such as switches, switches, and relays constituting a power system from a distance. The power system is configured by connecting each device to facilities such as a power transmission line and a transformer.
In FIG. 1, 11 is a power system simulator for monitoring and control system operation verification, 12 is an open / close state setting unit for setting the open / close state of devices in the power system, and 13 is an actual communication device that indicates the open / close state of devices, control signals, and the like. Position data associated with the storage position, ie, address, of the data to be allocated in the signal to be communicated, 14 is an open / close state memory for holding the current open / close state of the device, 15 is a default state setting unit for setting the default state of the device, Reference numeral 16 denotes a power system setting rule that defines an open / close state pattern of equipment used in the power system, 17 denotes an equipment database that stores information indicating a connection relationship between each equipment constituting the power system and equipment, and 18 denotes an open / close state memory. 14 is an open / closed state transmitter for reading out the open / closed state of the device from 14 and transmitting it to the monitoring control system, 19 is a power system simulation It is the subject of the monitoring and control system to be tested using a location 11.
Reference numeral 20 denotes a display unit for displaying the open / close state set by the open / close state setting unit, and 21 denotes an operation unit for changing the open / close state of each device.
The open / close state scheduled to be transmitted from the open / close state setting unit 12 to the monitoring control system is displayed on the display unit 20. When changing a part, the device to be changed is selected by the operation unit 21 to set the open / close state, and the contents of the open / close state memory 14 are rewritten. When the change is completed, the open / close state transmission unit 18 that has read the changed open / close state from the open / close state memory 14 transmits the open / close state of each device after the change to the monitoring control system 19.

FIG. 2 is a diagram showing the position data of the electric power system apparatus that simulates the first and second embodiments of the present invention. In the diagram of the position of the equipment in the electric power system, the storage position or address of data to be assigned to each equipment is defined in the signals communicated between the supervisory control system and the equipment control devices such as switches, switches, and relays. Yes. The address is composed of a word and a bit. According to each address, the name of the corresponding device, the name of the open / closed state for data 0 and 1, the device serial number indicating which device is associated with the facility database, and the data regarding the device type are configured. Yes.
The device type includes LS (Line Switch) indicating a disconnect switch, ES (Earthing Switch) indicating a ground switch, and CB (Circuit Breaker) indicating a circuit breaker.

FIG. 3 is a connection diagram of a simulated power system showing Embodiments 1 and 2 of the present invention. It represents a part of the power system, and the sub-bus's double bus, the Kobus and the Otobus, via a switch, the double-transmission lines, Transmission Line 1 and Transmission Line 2, and The transformer connection No. 1 line and the transformer connection No. 2 line, which are connection lines to the double transformer, are connected via the respective devices.
Among the devices, LS indicating a disconnect switch and ES indicating a ground switch are indicated by “□” or “■”, and CB indicating a circuit breaker is indicated by “◯” or “●”. “□” and “◯” indicate an open (cut) state, and “■” and “●” indicate a closed (on) state.

FIG. 4 is a diagram of a facility database associating the power system facilities to be simulated and the respective devices according to the first and second embodiments of the present invention. The equipment belonging to the position data in FIG. 2 and the equipment number belonging to the equipment are defined by the equipment serial number as well as the assigned electrical station serial number and connection bus machine number of each equipment. Here, the facilities are a transmission line and a transformer.
The connected bus number is set to “1” if there is a bus connected to the device, and “2” if the bus is a former bus. When connected to both parties A and B, the connected bus number is “None”.
The affiliated equipment number is set to “1” if the transmission line or the line connected to the transformer is No. 1 when there is equipment connected to the equipment, and “2” if the No. 2 line.

5 to 7 are diagrams representing power system setting rules showing Embodiments 1 and 2 of the present invention. The rule selected by the rule number has one or more rule serial numbers. The applicable target is specified for the connected bus machine number, device type, belonging equipment, and belonging equipment machine number, and the open / close state of the corresponding equipment is specified. Is done.
FIG. 9 is a diagram for explaining the description of the power system setting rules showing the first and second embodiments of the present invention. A method of defining the rules of FIGS. 5 to 8 will be described.

FIG. 10 is a flowchart 1 showing a default state setting method according to the first embodiment of the present invention.
FIG. 11 is a flowchart 2 showing a default state setting method according to the first embodiment of the present invention. Flowchart 2 described in FIG. 11 is subroutine 1 called in flowchart 1 of FIG. The device information is sequentially read from FIG. 3 describing the position data of each device, and the open / close state for each device is determined in accordance with the equipment database and the specified rule.

Hereinafter, the operation of the power system simulator will be described according to the steps of the flowchart of FIG.
The flowchart shown in FIG. 10 shows a program executed when simulating the initial state of the power system. The program started in step 101 proceeds to step 102.
In step 102, 013 is set in the rule setting register Nr to apply the rule 013 in order to determine the initial state of each device. As shown in FIG. 7, rule 013 is a rule for setting all disconnectors (LS) and switches (CB) to a closed (on) state and setting all ground switches (ES) to an open (off) state. It is.
Next, at step 103, subroutine 1 shown as flowchart 2 in FIG. 11 is called. According to this subroutine 1, the rule specified by the rule setting register Nr is applied to the device specified in FIG. 2 representing the position data, and the open / close state of each device is determined. In step 103, rule 013 is designated and executed. As a result, the open / close state memory 14 is set so that the disconnect switch (LS) and the switch (CB) are closed (on) and the ground switch (ES) is open (cut).
Next, in step 104, the rule number instructed from the operation unit 21 is set in the rule setting register Nr.
Thereafter, in step 105, the subroutine 1 shown as the flowchart 2 in FIG. 11 is called, and the rule designated by the rule setting register Nr is selected from the rules 001 to 008 and 011 to 014 shown in FIGS. Applied. If there is a condition that matches the data of the devices sequentially read in the rule, the open / close state of the corresponding device is determined by the rule, and an initial value of the open / close state of each device is set in the open / close state memory 14.
Thereafter, in step 109, the flowchart of FIG. 10 ends, the initial states of all the devices are determined and installed in the open / close state memory 14.

After the process of the flowchart of FIG. 10 is completed, the operation unit 21 sets the open / close state of the device in order to obtain the desired initial open / close state while confirming the initial state setting value of each device on the display unit 20. The initial state can be set in the open / close state memory 14. After that, the initial state of each device is simulated and transmitted from the open / close state transmission unit 18 to the control monitoring system 19.

Next, the flowchart 2 shown in FIG. 11 will be described. Flowchart 2 is subroutine 1 called in the flowchart of FIG.
The called subroutine 1 starts from step 110, and in step 111, the value of the rule setting register Nr is read. The rule specified by the setting value is applied in the following steps.
In step 112, it is determined whether or not reading of the last row of devices defined in the previous position data 13 has been completed. If reading of the last line has been completed, the process proceeds to step 118 to execute RTS (return subroutine). The subroutine 1 is terminated and returned so that the next process can be started after returning to the original flow from which the subroutine 1 was called.
If the last data of the previous position data has not been read in step 112, the process proceeds to step 113.
In step 113, the open / close state setting unit 12 newly reads one line of the position data shown in FIG. 2, and prepares for setting of the initial state of the device described therein.
In step 114, “device serial number” is read for the device in the row read from the position data shown in FIG. Further, the facility database 17 is accessed via the default state setting unit 15 and the “device type”, “affiliated facility”, and “affiliated facility machine number” of the corresponding device in the facility database shown in FIG. . Similarly, the power system setting rule 16 is accessed through the default state setting unit 15 to read the selected rule.
Thereafter, in step 115, it is determined whether or not there is a corresponding line in the selected rule. If there is no corresponding line, that is, if the rule is not applied, the process skips step 117 and loops. Return to 112.
If there is a corresponding row, the process proceeds to step 117 to apply the specified rule, and the open / close state of the device is stored in the open / close state memory 14. Thereafter, the process loops and returns to step 112.

As an example, assume that rule 003 is selected. The contents of the rule 003 are described in FIG. When the first line of the position data in FIG. 2 is read in step 113, “device serial number” is “20000” and “device type” is “CB”, that is, a circuit breaker. Read the line with equipment serial number “20000” from the equipment database diagram of FIG. Make sure that there is.
When rule 003 is applied to these pieces of information, the circuit breaker R00 whose “device serial number” is “20000” does not correspond to any row, and the circuit breaker (CB) is closed (rule 013). (Entered) state remains stored in the open / closed state memory, loops as it is, and proceeds to step 112.

Further, as an example, when the fifth line of the position data in FIG. 2 is read, “device serial number” is “20101” and “device type” is “LS”, that is, a disconnector. The row with the device serial number “20101” is read from the facility database diagram of FIG. 4, “connected bus machine number” is “1”, “affiliated equipment” is “transmission line”, and “affiliated equipment machine number” is “1”. Make sure that
When rule 003 is applied to these pieces of information, rule serial number 3001 is applicable, and it can be confirmed that the open / close state for initial setting of disconnector R11 is “1”, which is a closed (on) state. In step 117, the closed (entered) state is stored in the address of the device in the open / close state memory, and the process loops to step 112.

As described above, the open / close state is set based on the specified power system setting rule for all the positions of the position data in FIG. 2 and stored in the open / close state memory 14.
In this way, when the default state setting unit 15 selects a rule number from the preset power system setting rules 16, it is possible to set the open / close state according to the rule for all switches in the position data. .

As apparent from the above, according to the first embodiment, the switching state of the switch is set based on the rule with reference to the contents of the specified power system setting rule, so a relatively small number. By negotiating these rules, the open / close states of a large number of devices can be determined. Moreover, when changing the switching state of the switch simulated by the power system simulation device over the entire power system, it is only necessary to change the rule number, and the initial state of the switch of the monitoring control system can be set easily and in a short time. There is an effect that can be.
By using this method, the time required for the initial setting of the power system simulation method for monitoring control system operation verification can be shortened, and verification efficiency can be improved.

  In addition, since the equipment database has the affiliated electrical station sequence numbers, the switching status of the switch is not changed over the entire power system, but only the designated electrical station can be changed based on another rule number. Play.

  Further, even when the scale of the power system becomes large during the operation verification and a new device is added to the position data 13, the open / close state may be set based on a predetermined rule for the added device. Therefore, there is no need to reset the initial state of the switch from scratch, and the effect of shortening the initial setting time can be achieved.

Here, FIG. 3 shows an example in which a combination of transmission line 1 and transmission line 2, transformer connection 1 line and transformer connection 2 line, and a combination of a bus line and a maiden line is shown.
The following rules are shown in FIGS.
Rule 001 shows a rule for connecting the first bus to the No. 1 line and connecting the second bus to the No. 2 line.
Rule 002 shows a rule for connecting the Otobus line to the No. 1 line and connecting the Kobus line to the No. 2 line.
Rule 003: Rules for connecting line 1 on the transmission line and the bus line, connecting line 2 on the transmission line and the Otome line, connecting line A and the line 2 on the transformer side, and connecting the line 2 on the transformer side and the line 1 on the transformer side Show.
Rule 004: Rules for connecting line 1 on the transmission line and the Oto bus line, connecting line 2 on the transmission line side and the bus line, connecting the bus line and line 1 on the transformer side, and connecting the line Oto bus line and line 2 on the transformer side Show.
Rule 005 shows a rule that separates the A / B bus and connects the transmission line side and the transformer side only to the A / B bus line.
Rule 006 shows a rule that separates the maiden bus line and connects the power transmission line side and the transformer side only to the maiden line.
Rule 007 shows a rule for separating the Ko-Oto bus line, connecting the transmission line side No. 1 and No. 2 line to the Ko Bus line, and connecting the transformer-side No. 1 line and No. 2 line to the Oto bus line.
Rule 008 shows a rule that separates the Ko-Oto bus line, connects the transmission line side No. 1 and No. 2 line to the Oto bus line, and connects the transformer-side No. 1 line and No. 2 line to the Ko bus line.
Rule 011 shows a rule for closing (entering) all devices.
Rule 012 shows a rule for setting all devices to the open (off) state.
Rule 013 shows a rule that closes (turns on) all disconnectors (LS) and circuit breakers (CB) and opens (cuts) all ground switches (ES).
Rule 014 shows a rule that opens (disconnects) all disconnectors (LS) and circuit breakers (CB), and closes (enters) all ground switches (ES).

In the flowchart 1 of FIG. 10, when the rule numbers 001 to 008 shown in FIGS. 5 and 6 are designated and executed, the open / closed state set as the initial state of each device is shown in FIGS. Shown in the “Open / close state” column.
In the “applied rule sequence number” column of FIGS. 12 to 19, a rule sequence number that is the basis for setting each device when the rule number is designated by the operation unit 21 is described. Since the open / close state is set in advance by the rule number 013 for the device whose open / close state is not determined by the rule of the rule number designated by the operation unit 21, the applicable rule serial number by the rule number 013 is described.
When the rule numbers 011 to 014 are designated, the open / close state of each device has the contents shown in the remarks column of FIG.

As described above, the connection diagram of the power system shown in FIG. 3 stipulates a case where two systems on the transmission line side, two systems on the transformer side, and two bus systems connected by these devices are combined. These can also be applied to a case where three or more systems are combined or a part of one system is combined, and rules can be formulated even in such a case.

In the above, the position data consisting of the address assigned to each equipment, the equipment serial number, etc., and the equipment database shown in FIG. 4 for associating the power system equipment with each equipment are set separately. Two elements may be combined and represented by a single data or database.

As shown in the rules 001 to 004, the power system setting rule can be defined for a case where two systems on the power transmission line side, two systems on the transformer side, and two bus systems connected by these devices are combined. As a result, it is possible to change the combination of “1st and 2nd” connections that are often used for actual power system connections.
Therefore, the simulation for the operation verification of the supervisory control system can be quickly performed in a state close to the actual use state and by easily changing the combination. As a result, higher reliability can be realized, and verification efficiency can be improved.

Like rules 005 and 006, a power system setting rule can be defined for a case where two systems on the power transmission line side or two systems on the transformer side are connected to only one system of the bus and combined. Thereby, not only can the verification when only one system of the buses is used be performed, but also the verification can be easily performed by changing the combination. As a result, higher reliability can be realized, and verification efficiency can be improved.

In the flowchart of FIG. 10, a rule 13 is first executed to set all disconnectors (LS) and circuit breakers (CB) in a closed (on) state and all ground switches (ES) in an open (off) state. Later, other rules are applied.

In this way, it is possible to designate all the open / closed states for all the devices without leaving any device with an undefined open / closed state. In addition, it is not necessary to distinguish between a device that has not specified an open / close state and a specified device, and the open / close state of all devices can be set without omission by simple processing.

According to the first embodiment, the setting of the opening / closing state of the device is corrected by the operation unit 21 in order to set the desired initial opening / closing state while confirming the initial state setting value of each device on the display unit 20. Any initial state setting can be set in the open / close state memory 14.
Therefore, you can select the rule that is closest to the open / closed state of the device you want to set, specify the rule, set the initial state, and then change the initial state of the required part. Can be set easily and quickly.
For this reason, the time required for the initial setting is shortened, and the verification efficiency can be improved.

As described above, the power system simulation method for setting the initial state of a device based on the selected power system setting rule using a plurality of power system setting rules that define the open / close state of the device in relation to the equipment is as follows. Since the initial state to be set can be selected from a plurality of rules, the initial state can be easily set in a short time.
By using this method, the time required for the initial setting of the power system simulation method for monitoring control system operation verification can be shortened, and verification efficiency can be improved.

Embodiment 2. FIG.
FIG. 20 is a flowchart 3 showing a default state setting method according to the second embodiment of the present invention.
FIG. 21 is a flowchart 4 showing a default state setting method according to the second embodiment of the present invention. The flowchart 4 described in FIG. 21 is a subroutine 2 called in the flowchart 3 of FIG. The device information is sequentially read from FIG. 3 describing the position data of each device, and the open / close state for each device is determined in accordance with the equipment database and the specified rule.

The operation of the power system simulator will be described according to the steps of the flowchart 3 in FIG.
The flowchart 3 shown in FIG. 20 shows a program executed when simulating the initial state of the power system. The program started in step 201 proceeds to step 202.
In step 202, all the open / close state setting flags for each device set in the open / close state memory 14 are cleared, and the open / close state is not set for all devices.
Next, in step 204, the rule number instructed from the operation unit 21 is set in the rule setting register Nr.
Thereafter, in step 205, the subroutine 2 shown as the flowchart 4 in FIG. 21 is called, and the rule specified by the rule setting register Nr is selected from the rules 001 to 008 and 011 to 014 shown in FIGS. Applied. If there is a condition that matches the data of the device sequentially read in the rule, the open / close state of the corresponding device is determined by the rule, the initial value of the open / close state of each device is set in the open / close state memory 14, and the device The open / closed state setting flag is set.
In step 206, 099 is set in the rule setting register Nr in order to apply the rule 099 in order to determine the initial state of each device for which the open / close state is not set. As shown in FIG. 8, Rule 099 opens the disconnect switch (LS) and the circuit breaker (CB) in which the switching state is not set, and opens the ground switch (ES) in which the switching state is not set. It is a rule set to the (cut) state.
Next, at step 207, subroutine 2 shown as flowchart 4 in FIG. According to this subroutine 2, the rules specified in the rule setting register Nr are applied to the devices specified in the position data of FIG. 2, and the open / close state of each device is determined. In step 207, rule 099 is designated and executed.
FIG. 8 is a diagram showing a power system setting rule (4) showing the second embodiment of the present invention.
In FIG. 8, all disconnectors (LS) and circuit breakers (CB) are closed (entered) only for devices that have not been set to open / close according to the rule applied before that, and all ground switches ( The rule 099 is set to open (cut) ES).
As a result of the execution of rule 099 in step 207, the disconnecting switch (LS) whose switch state is not set and the switch (CB) are closed (turned on), and the ground switch (ES) whose switch state is not set is opened. The open / close state memory 14 is set so as to be in the (OFF) state.
Thereafter, in step 209, the flowchart of FIG. 20 ends, the initial states of all the devices are determined and set in the open / close state memory 14.

After the processing of the flowchart of FIG. 20 is completed, the operation unit 21 sets the open / close state of the device in order to set the desired initial open / close state while confirming the initial state setting value of each device on the display unit 20. The initial state can be set in the open / close state memory 14. After that, the initial state of each device is simulated and transmitted from the open / close state transmission unit 18 to the control monitoring system 19.

Next, the flowchart 4 shown in FIG. 21 will be described. Flowchart 4 is subroutine 2 called in the flowchart of FIG.
This called subroutine 2 is started from step 210, but from step 111 to step 118, except for step 221 and step 222, is the same as subroutine 1 in FIG.
In step 221, the open / close state setting flag set for each device is read into the open / close state memory 14 to check whether the open / close state has already been set for the device to be checked. When the open / close state setting flag is 0, since the open / close state is not set, the process proceeds to the next step 114. When the open / close state setting flag is 1, since the open / close state has been set, the reference to the power system rule relating to the device is skipped, and the process loops to step 112.
Steps 114 to 117 are the same as those in the flowchart 2 of FIG.
After the confirmed open / close state of the device is stored in the open / close state memory in step 117, the open / close state setting flag is set in step 222, and then the process loops to step 112.
As a result, the open / closed state is set only for devices for which the open / closed state is not set.
1 to 9 can be applied to the second embodiment as they are.
When the rules 001 to 008 are specified and executed, the open / closed state set as the initial state of each device is the same as that of the first embodiment + FIG. 12 to FIG. 19, but the application of FIG. In the rule serial number column, “99901” is substituted for “13001” and “99902” is substituted for “13002”.

In the power system book apparatus according to the second embodiment, all disconnectors (LS) and circuit breakers (CB) are closed (on) and open / close states are designated only for devices that are not designated as open / close states. The rule 099 for opening (turning off) the ground switch (ES) is applied to devices that are not connected.
In this way, since the open / close state is determined once for all the devices and stored in the open / close state memory, the execution time of the process is completed in the shortest time. Therefore, the execution time can be shortened and the load on the computer can be reduced.

DESCRIPTION OF SYMBOLS 11 Electric power system simulation apparatus 12 Opening and closing state setting part 13 Position data 14 Opening and closing state memory 15 Default state setting part 16 Power system setting rule 17 Equipment database 18 Opening and closing state transmission part 19 Monitoring control system 20 Display part 21 Operation part

Claims (7)

  A facility database that defines a relationship between a device that configures a power system and a facility to which the device is connected; and a plurality of power system setting rules that define an open / closed state of the device in relation to the facility, the selected A power system simulation device that sets an initial state of the device based on a power system setting rule.   2. The power system simulation according to claim 1, wherein the power system setting rule is defined for a case where two systems on the transmission line side, two systems on the transformer side, and two bus systems connected to each other through a device are combined. apparatus.   The power system simulation device according to claim 1, wherein the power system setting rule is defined for a case where two systems on the transmission line side or two systems on the transformer side are connected to only one system of the bus and combined.   The initial state of the device is set based on a selected power system setting rule after tentatively determining that the disconnect switch and the circuit breaker are closed and the ground switch is opened for all devices. The power system simulation device according to any one of claims 3 to 4.   5. The operation unit according to claim 1, further comprising an operation unit configured to change an open / close state of the device after setting an initial state of the device based on the selected power system setting rule. Power system simulator.   6. The device according to claim 1, wherein the switch and the circuit breaker are closed and the grounding switch is opened for a device whose switching state cannot be determined by the selected power system setting rule. The electric power system simulation apparatus described in 1.   Selected using a facility database that prescribes the relationship between equipment constituting the power system and equipment to which the equipment is connected, and a plurality of power system setting rules that prescribe the open / closed state of the equipment in relation to the equipment A power system simulation method for setting an initial state of the device based on the power system setting rule.

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