JP2024049538A - Simulation device, simulation method, simulation program, and power system - Google Patents

Abstract

[Problem] When a power system regime is changed, a regime change is evaluated. [Solution] One aspect of the present disclosure is a simulation device including an acquisition unit that acquires power system information related to facilities included in the power system and market entrants, a variable change unit that receives variable information indicating variables related to the power system regime, and a simulation unit that calculates the impact on market entrants when variables related to the power system regime change based on the power system information acquired by the acquisition unit and the variable information received by the variable change unit. [Selected Figure] Figure 4

Description

The present invention relates to a simulation device, a simulation method, a simulation program, and a power system.

Conventionally, a technology for predicting information such as electricity prices in an electricity system is known. For example, an optimization support system described in Patent Document 1 includes an electricity meter, a power consumption optimization system, an electricity price forecasting system, an electricity supply and demand balance grasping system, an electricity supply and demand balance adjustment system, and a wheeling report system, and performs simulations of electricity prices and supports electricity trading between electricity suppliers and consumers. A market management system described in Patent Document 2 includes a wholesale electricity trading market database, an operation standard database, a supply and demand planning section, and a supply and demand planning database, and formulates a balance of interests between multiple related players. An electricity trading system described in Patent Document 3 creates strategies for electricity consumers and suppliers in the wholesale electricity trading market by predicting market prices based on data such as electricity demand data, generated electricity data, power generation cost data, consumer strategy parameters, and supplier strategy parameters. An electricity trading determination method described in Patent Document 4 includes consumer data and business data, predicts electricity demand, and creates an electricity consumer portfolio that maximizes profits according to the risk tolerated by the electric utility.

JP 2001-216384 A JP 2019-139527 A JP 2007-200053 A JP 2005-176495 A

The technologies described in Patent Documents 1 to 4 above predict the market price of electricity or electricity demand, and take into account the advantages or disadvantages for power generation companies or consumers. However, the technologies described in Patent Documents 1 to 4 do not take into account the impact on the entire power system, including power generation companies, retail electricity companies, consumers, and electricity transmission and distribution companies, when the power system system is changed. Therefore, the technologies described in Patent Documents 1 to 4 cannot evaluate the change in the power system system by taking into account the impact on the entire power system when the power system system is changed.

Furthermore, the Feed-in Tariff Scheme for Renewable Energy (FIT Scheme) was established in 2012 with the aim of accelerating the spread of renewable energy. This has led to the construction of residential solar power generation panels and solar power plants, and the decentralization of power generation facilities is progressing. However, the technology described in Patent Documents 1 to 4 has the problem that it does not take into account decentralized power generation facilities. Therefore, the technology described in Patent Documents 1 to 4 cannot evaluate system changes to the power system by taking into account distributed power sources.

This disclosure has been made in light of these circumstances, and aims to provide a simulation device, a simulation method, a simulation program, and an electric power system that can evaluate system changes when considering system changes to an electric power system.

The present disclosure has been made to solve the above-mentioned problems, and one aspect of the present disclosure is a simulation device including an acquisition unit that acquires power system information related to facilities and market entrants included in a power system, a variable change unit that receives variable information indicating variables related to the power system system, and a simulation unit that calculates the impact on the market entrants when variables related to the power system system change based on the power system information acquired by the acquisition unit and the variable information received by the variable change unit.

Another aspect of the present disclosure is a simulation method including the steps of acquiring power system information regarding facilities and market entrants included in a power system, accepting variable information indicating variables related to the power system regime, and calculating, based on the power system information and the variable information, the impact on the market entrants when a variable related to the power system regime changes.

Another aspect of the present disclosure is a simulation program that causes a computer to execute the steps of acquiring power system information regarding facilities and market entrants included in a power system, accepting variable information indicating variables related to the power system regime, and calculating, based on the power system information and the variable information, the impact on the market entrants when a variable related to the power system regime changes.

Another aspect of the present disclosure is an electric power system including consumer equipment, power generation equipment, renewable energy power generation equipment, retailer equipment, power transmission and distribution equipment, and an electric power supply and demand adjustment system that presents demand plan information and power generation plan information to a cross-regional organization, the electric power system including an acquisition unit that acquires electric power system information related to the equipment and market entrants included in the electric power system, a variable change unit that receives variable information indicating variables related to the system of the electric power system, and a simulation unit that calculates the impact on the market entrants when variables related to the system of the electric power system change based on the electric power system information acquired by the acquisition unit and the variable information received by the variable change unit.

According to one aspect of the present invention, when the power system system is changed, it is possible to evaluate the change in the system.

1 is a block diagram showing an example of a power system according to an embodiment. FIG. 2 is a diagram illustrating an example of components in a power system according to an embodiment. 2 is a block diagram showing an example of the relationship between the various units included in the power system according to the embodiment. FIG. 1 is a block diagram showing an example of a simulation device according to an embodiment; FIG. 2 is a block diagram showing an example of a specific configuration of the simulation device 1. 4 is a block diagram showing an example of the functions of a motion prediction unit according to the embodiment; FIG. FIG. 4 is a sequence diagram showing an example of a processing procedure of the power system according to the embodiment. 11A to 11C are diagrams illustrating an example of the total wheeling charges, the total power generation charges, and the variable costs of the power transmission and distribution facilities when variables in the power system are changed in the embodiment.

The simulation device, simulation method, simulation program, and power system to which the present invention is applied are described below with reference to the drawings.

(Power system configuration)
FIG. 1 is a block diagram showing an example of a power system according to an embodiment. The power system includes, for example, a simulation device 1, a power generation system 100, a power transmission and distribution system 200, a retail system 300, a consumer system 400, a power storage system 500, and a power market system 600. The simulation device 1, the power generation system 100, the power transmission and distribution system 200, the retail system 300, the consumer system 400, the power storage system 500, and the power market system 600 each have a communication interface such as a network interface card (NIC) or a wireless communication module for connecting to a network NW such as the Internet. The network NW may include, for example, a general-purpose network such as the Internet, and a private network such as local 5G or Wifi (registered trademark).

2 is a diagram showing an example of components in a power system according to an embodiment. Note that multiple consumer facilities 410 included in the consumer system 400 are shown distributed in various parts in FIG. 2, and the power generation/retail supply and demand adjustment system 610 in the power market system 600 is shown as a part of the retail system 300. Components of the power generation system 100 include, for example, a renewable energy power generation facility 110 and a power generation supply and demand adjustment system 112. The power generation system 100 may include power generation facilities such as distributed power sources other than the renewable energy power generation facility 110 and devices for managing the power generation facilities. The renewable energy power generation facility 110 includes power source resources that generate power using renewable energy, such as wind power generation facilities, solar power generation facilities, small hydroelectric power generation facilities, biomass power generation facilities, geothermal power generation facilities, heat pump facilities, storage battery facilities, and electric vehicles. The power generation supply and demand adjustment system 112 outputs commands to the renewable energy power generation facility 110 to adjust the balance between the demand for generated power and the supply of generated power in the power generation system 100.

The components of the power transmission and distribution system 200 include, for example, a power transmission and distribution facility 210 constructed by a power transmission and distribution business operator, a wheeling system 220, a customer facility 410, a smart meter system 420, and a meter information management system 430. The power transmission and distribution facility 210 receives power generated by a power generation business operator in the power generation system 100 and supplies the power to the customer facility. The customer facility 410 includes, for example, electrical equipment at the customer that uses the supplied power, and a smart meter installed for each customer.

The wheeling system 220 executes processes to support wheeling operations. The wheeling system 220 may execute processes to support wheeling operations based on package software. The wheeling system 220 arbitrates fees related to electricity wheeling using the power transmission and distribution equipment 210. The wheeling system 220 publishes wheeling information and accepts wheeling applications in accordance with a business protocol. The wheeling system 220 improves processing accuracy and reduces the labor required for the settlement of adjustment power trading.

The smart meter system 420 may include a database for managing information on a large number of smart meters, and a monitoring device for monitoring the status of each smart meter. The smart meter system 420 performs meter data management to realize collection and management of metering data, meter reading, distribution network operation, and demand control functions using smart meters. The smart meter system 420 manages and controls smart meters compatible with various communication methods. The smart meter system 420 realizes wireless multi-hop communication of smart meters. The smart meter system 420 may include a terminal for performing joint meter reading with gas or water, etc., and an intelligent terminal for remote monitoring and control of various sensors.

The meter information management system 430 manages information on various meters, such as smart meters, included in the customer equipment 410. The meter information management system 430 manages information on various meters included in the customer equipment 410 and provides the meter information to the smart meter system 420.

The components of the retail system 300 include multiple retail electricity supplier facilities 310 corresponding to multiple retail businesses, consumer facilities 410, and a power generation/retail supply and demand adjustment system 610. Each retail business supplies electricity to consumer facilities 410 using the electricity transmission and distribution system 200 constructed by the electric power company, and pays a facility usage fee for the transmission line (= wheeling fee) to the electricity transmission and distribution business. Each retail electricity supplier facility 310 collects electricity fees from consumers, and executes processes for the retail electricity supplier to pay the fees for procuring electricity to the power generation business. The retail electricity supplier facility 310 may execute processes for paying the fees based on package software.

The components of the power storage system 500 include a power storage facility 510 and a distributed power source operation system 520. The distributed power source operation system 520 monitors, controls, and controls supply and demand of power resources including the power storage facility 510 included in the power storage system 500. The distributed power source operation system 520 may control, monitor, and manage power resources based on commands from a higher level, such as the retail supply and receipt adjustment system 610 or the wheeling system 220. The distributed power source operation system 520 receives demand response commands based on requests from the outside and transmits power generation results and reception results. The distributed power source operation system 520 can bundle and control the input and output of power to and from the distributed power source, and supply the bundled power. The distributed power source operation system 520 can manage information on various distributed power sources and supply information on the distributed power sources to the simulation device 1. The distributed power source may include a renewable energy power generation facility.

Components of the electricity market system 600 include, for example, an electricity trading system 640. The electricity trading system 640 acquires power generation amount information obtained from the power generation system 100 and retail power amount information obtained from the retail electricity business facility 310, and acquires the demand amount from the power generation/retail supply and demand adjustment system 610. 640 performs electricity trading processing by referring to the power generation amount information, retail power amount information, and demand amount.

FIG. 3 is a block diagram showing an example of the relationship between the various units included in the power system according to the embodiment.
The power generation system 100 is supplied with fuel from the fuel market, and the power generation system 100 acquires fuel price information. Contract information indicating a contract between the wheeling system 220 and the power generation system 100 and the electric power retailer facility 310 is supplied to the wheeling system 220. The smart meter system 420 transmits power generation demand information and power generation performance information to the wheeling system 220. The wheeling system 220 transmits wheeling fee information indicating a wheeling fee to the power generation system 100 and the electric power retailer facility 310 based on the contract. In addition, when the wheeling system 220 is unable to achieve the same amount of planned and actual power supply at the same time, resulting in an excess or shortage of power supply, the wheeling system 220 supplies information indicating an in-balance charge to be paid as compensation for adjustment to the power generation system 100 and the electric power retailer facility 310. The wheeling system 220 accepts applications for wheeling contracts from the power generation system 100 and the electric power retailer facility 310. The wheeling system 220 requests the power generation system 100 or the electric power retailer facility 310 to pay a wheeling charge as a usage fee for the power transmission and distribution facility 210 when the power transmission and distribution facility 210 is used to supply electric power from the power generation system 100 or the electric power retailer facility 310 to the consumer facility 410. The wheeling system 220

The smart meter system 420 provides actual power generation information and actual demand information to the power generation/retail supply and demand adjustment system 610. The weather information providing server device 620, managed by a weather information provider, provides weather information to the power generation/retail supply and demand adjustment system 610. The weather information may be information indicating the weather for the area in which the power generation amount and power consumption amount are predicted in the power generation system 100, the retail electricity business equipment 310, and the consumer equipment 410. The information disclosure server device 630 provides public information to the power generation/retail supply and demand adjustment system 610.

The power generation/retail supply and demand adjustment system 610 receives power generation demand information and actual power generation information from the smart meter system 420. The power generation/retail supply and demand adjustment system 610 receives weather information from the weather information providing server device 620. The power generation/retail supply and demand adjustment system 610 performs weather forecasts based on the weather information. The power generation/retail supply and demand adjustment system 610 receives public information from the information disclosure server device 630. The power generation/retail supply and demand adjustment system 610 calculates power generation plans and demand plans based on the weather forecast results, and the power generation actual information and demand actual information received from the smart meter system 420.

The power generation/retail supply and demand adjustment system 610 transmits information including a demand plan and a power generation plan to the power supply control system 122. The power supply control system 122 supplies commands based on the power generation plan to the power generation system 100. The power supply control system 122 supplies commands based on the demand plan to the resource control system 120. The resource control system 120 supplies commands based on the demand plan to the power generation system 100, the consumer equipment 410, and the power storage system 500.

The power generation/retail supply and demand adjustment system 610 provides the power trading system 640 with market trading information for conducting market trading of electricity according to the calculated power generation plan and demand plan. The power generation system 100 supplies the power trading system 640 with market trading information indicating the amount of generated power. The retail electricity supplier facility 310 supplies the power trading system 640 with market trading information indicating the amount of retailed power. The power trading system 640 performs trading with, for example, the JEPX (Japan Electric Power Exchange) system based on the market trading information supplied from each of the power generation/retail supply and demand adjustment system 610, the power generation system 100, and the retail electricity supplier facility 310, and accumulates trading-related data.

The distributed power supply operation system 520 transmits control commands to the renewable energy power generation facility 110 and receives fuel information from the renewable energy power generation facility 110. The distributed power supply operation system 520 then calculates the power generation performance of the renewable energy power generation facility 110 from the fuel information. The distributed power supply operation system 520 outputs demand performance information indicating the demand performance of the renewable energy power generation facility 110 based on the power generation performance to the power generation/retail supply and demand adjustment system 610.

FIG. 4 is a block diagram showing an example of the functional configuration of a simulation device in an embodiment. The simulation device 1 includes, for example, an acquisition unit 10, a variable change unit 20, a simulation unit 30, and a display data creation unit 40. The acquisition unit 10, the variable change unit 20, the simulation unit 30, and the display data creation unit 40 are realized by, for example, a processor such as a CPU (Central Processing Unit) executing a simulation program stored in a program memory. In the embodiment, the acquisition unit 10, the variable change unit 20, the simulation unit 30, and the display data creation unit 40 are described as being integrated into the simulation device 1, but this is not limited thereto, and the acquisition unit 10, the variable change unit 20, the simulation unit 30, and the display data creation unit 40 may be distributed and arranged in the power system.

The acquisition unit 10 acquires power system information related to the facilities and market participants included in the power system. The facilities included in the power system are, for example, a power generation system 100, a power transmission and distribution system 200, a retail system 300, a consumer system 400, and a power storage system 500. The variable change unit 20 accepts variable information indicating variables related to the power system system. The simulation unit 30 predicts changes in components when variables related to the power system system change based on the power system information acquired by the acquisition unit 10 and the variable information accepted by the variable change unit 20, and calculates the impact of the change in variables on power trading among consumers, power generation companies, and retail companies based on the predicted changes.

Figure 5 is a block diagram showing an example of a specific configuration of the simulation device 1. The power system includes a plurality of software processing units 700, the simulation device 1, and an evaluator terminal device 800. Each software processing unit 700 includes a functional unit realized by software installed in each of the meter information management system 430, the smart meter system 420, the consignment system 220, the power generation/retail supply and demand adjustment system 610, and the resource control system 120 shown in Figure 4. The software processing unit 700 includes, for example, a system processing unit 710 customized by each of the meter information management system 430, the smart meter system 420, the consignment system 220, the power generation/retail supply and demand adjustment system 610, and the resource control system 120, an information extraction unit 720, an information provision unit 730, and a communication control unit 740. The system processing unit 710 performs processing to realize the functions of each of the meter information management system 430, the smart meter system 420, the consignment system 220, the power generation/retail supply and demand adjustment system 610, and the resource control system 120 described above.

The information extraction unit 720, the information provision unit 730, and the communication control unit 740 are functional units provided for performing a simulation by the simulation device 1. The information extraction unit 720 extracts information for performing a simulation by the simulation device 1 from the information processed by the system processing unit 710. The information provision unit 730 performs processing for providing the information for performing the simulation to the simulation device 1. The information provision unit 730 performs processing such as converting the information extracted by the information extraction unit 720 into a format that can be processed by the simulation device 1. The communication control unit 740 transmits information for performing a simulation to the simulation device 1 at a preset timing or in accordance with a request from the simulation device 1.

Information for performing a simulation by the simulation device 1 includes, for example, system parameter information, operation information, and fee information. The system parameter information is a parameter related to a system for determining various fees. For example, the system parameter information in the wheeling system 220 is information for determining wheeling fees such as labor costs, repair costs, depreciation costs, fixed property tax, power source development promotion tax, compensation contribution, decommissioning facilitation contribution, and other parameters in the power transmission and distribution equipment 210, and information indicating a calculation method of the wheeling fee using these. The operation information is, for example, information indicating the electricity usage [kWh] handled by the power transmission and distribution system 200. The fee information is information indicating the wheeling fee. The system parameter information may include a calculation method of the operation information. The operation information is, for example, information indicating the calculation process of labor costs, repair costs, and depreciation costs in the power transmission and distribution equipment 210, and the fee information is the wheeling fee calculated based on the calculation process of labor costs, repair costs, and depreciation costs in the power transmission and distribution equipment 210.

The evaluator terminal device 800 is an information processing device such as a personal computer operated by an evaluator who evaluates the system change of the power system. The evaluator terminal device 800 includes, for example, a communication unit 810, a variable adjustment unit 820, and a user interface (UI) unit 830. The variable adjustment unit 820 and the user interface unit 830 are functional units that are realized, for example, by installing package software for evaluating the system change. The variable adjustment unit 820 adjusts the system parameters based on the operation accepted by the user interface unit 830, and generates information specifying the system parameters. The communication unit 810 transmits the information specifying the system parameters generated by the variable adjustment unit 820 to the simulation device 1. The user interface unit 830 displays the simulation results using display data for the simulation results based on the information specifying the system parameters. In this way, the evaluator terminal device 800 allows the evaluator to recognize the operation of the power system and the charges when the system parameters are changed.

The simulation device 1 includes, for example, a communication unit 50, a communication control unit 52, a data management unit 54, a data storage unit 56, and a simulation processing unit 58. The communication unit 50 includes a NIC, etc. The communication unit 50 communicates with a plurality of software processing units 700. The communication control unit 52 controls the communication of the communication unit 50. For example, when the timing arrives to acquire information for performing a simulation, the communication control unit 52 requests information for performing a simulation from one or more software processing units 700. As a result, the communication unit 50 and the communication control unit 52 correspond to the acquisition unit 10.

The data management unit 54 stores information for performing a simulation acquired by the communication unit 50 in the data accumulation unit 56. The data accumulation unit 56 includes, for example, various storage devices, and accumulates information for performing a simulation acquired from a plurality of software processing units 700. The data accumulation unit 56, for example, stores system parameter information, operation information, and fee information in association with each other for each software processing unit 700. Note that fee information need not be included in information about software processing units 700 that are not related to fees.

The simulation processing unit 58 includes, for example, a variable changing unit 60, an operation prediction unit 62, a fee calculation unit 64, and a display data creation unit 66. The simulation processing unit 58 is a specific example that realizes the variable changing unit 20, the simulation unit 30, and the display data creation unit 40 described above.

The variable change unit 60 changes variables related to the power system regime based on information received from the evaluator terminal device 800. The variables related to the power system regime are not particularly limited as long as they cause changes to the equipment included in the power system or to market entrants. The variables related to the power system regime are, for example, variables that affect the prices in the electricity market. The variables related to the power system regime are, for example, variables that affect the operating volume of the equipment included in the power system. The impact on market entrants is, for example, a change in the prices borne by the market entrants.

Market participants may include consumers, power generation businesses, and retail businesses. The acquisition unit 10 acquires, as power system information, information on components of a power system including consumer facilities, power generation business facilities, renewable energy power generation facilities, retail business facilities, transmission and distribution facilities, and a power supply and demand adjustment system that presents demand plan information and power generation plan information to the cross-regional organization. The simulation unit 30 may predict changes in the components when variables related to the power system system change, and calculate the impact of the changes in the variables on power transactions among consumers, power generation businesses, and retail businesses based on the predicted changes. The change in the components when variables related to the power system system change is, for example, a change in the operating status of facilities included in the power system.

The operation prediction unit 62 predicts the operation of the system processing unit 710 when a variable related to the power system's system is changed. The fee calculation unit 64 calculates the fee when a variable related to the power system's system is changed based on the operation predicted by the operation prediction unit 62. The display data creation unit 66 creates display data for displaying information including the fee calculated by the fee calculation unit 64. The display data created by the display data creation unit 66 is transmitted to the evaluator terminal device 800.

For example, the variable change unit 60 accepts that a certain variable in the power system has changed from a first value to a second value. The operation prediction unit 62 predicts a change from the operating state when the first value is set to the operating state when the second value is set, when the equipment included in the power system is operated according to the second value. The fee calculation unit 64 compares a combination of fees borne by multiple market participants when the equipment is operating in the operating state when the first value is set with a combination of fees borne by multiple market participants when the equipment is operating in the operating state when the second value is set. This allows the simulation processing unit 58 to calculate the change in fees for each market participant.

The simulation unit 30 may predict, as a change in the equipment included in the power system, a change in the operating state of the equipment included in the power system or a change in the variable cost of the equipment included in the power system in response to a change in a variable related to the power system's system. In this way, the simulation device 1 can predict, for example, a change in the operating state of the equipment when the operation method of the equipment is changed.

Specifically, the evaluator terminal device 800 adjusts the scale of the expansion of the power transmission and distribution equipment 210 and the fee burden ratio for the equipment expansion of the power transmission and distribution equipment 210 as variables. The variable change unit 60 changes the scale of the expansion of the power transmission and distribution equipment 210 and the fee burden ratio for the equipment expansion of the power transmission and distribution equipment 210, and requests a prediction from the operation prediction unit 62. When the operation prediction unit 62 changes the scale of the expansion of the power transmission and distribution equipment 210 and the fee burden ratio for the equipment expansion of the power transmission and distribution equipment 210, for example, it predicts fluctuations in labor costs, repair costs, and depreciation costs in the power transmission and distribution equipment 210 as operation information. The fee burden ratio is, for example, the ratio of the costs required for the expansion of the power transmission and distribution equipment 210 between the costs borne by the installer of the power transmission and distribution equipment 210 and the costs borne by the power transmission and distribution business operator. The fee calculation unit 64 calculates the wheeling fee using the predicted labor costs, repair costs, and depreciation costs for the power transmission and distribution equipment 210.

Figure 6 is a block diagram showing an example of the functions of the motion prediction unit in the embodiment. A model construction unit 62B and a learning data storage unit 62C are connected to the motion prediction unit 62. The motion prediction unit 62 performs calculations according to a prediction model 62A. The prediction model 62A receives variable information supplied from the variable change unit 60 as input, and outputs motion information and confidence of the system processing unit 710 as prediction results. The prediction model 62A is a machine learning model, for example, a convolutional neural network (CNN).

The model construction unit 62B constructs a prediction model 62A. The model construction unit 62B acquires system parameter information, operation information, and fee information as learning data. During learning, the model construction unit 62B inputs system parameter information, operation information, and fee information to the prediction model 62A. The model construction unit 62B receives information acquired from multiple software processing units 700 as input and outputs the prediction results of the multiple software processing units 700, but is not limited to this. The model construction unit 62B may receive information acquired from multiple software processing units 700 as input and output the prediction result of one software processing unit 700, or may receive information acquired from one software processing unit 700 as input and output the prediction result of one software processing unit 700.

When system parameter information, operation information, and fee information are input during learning, the prediction model 62A outputs an estimation result including operation information and confidence. The model construction unit 62B recursively updates the processing parameters of the prediction model 62A so that the operation information output from the prediction model 62A matches the operation information as learning data. The processing parameters are, for example, at least one of the number of layers, the number of nodes in each layer, the node connection method between each layer, the activation function, the error function, and the gradient descent algorithm, the pooling area, the kernel, the weighting coefficient, and the weighting matrix in the convolutional neural network. As a result, the model construction unit 62B performs, for example, deep learning to obtain the processing parameters. Deep learning is machine learning using a multi-layer structure, particularly a neural network with three or more layers. Note that the model construction unit 62B does not need to be included in the operation prediction unit 62, and it is sufficient if the prediction model 62A can be introduced into the operation prediction unit 62 during initial setup or maintenance of the simulation device 1. During estimation, prediction model 62A inputs precision parameter information and outputs estimation results indicating operation information and confidence level.

Figure 7 is a sequence diagram showing an example of the processing procedure of the power system in the embodiment. When system parameter information, operation information, and fee information are transmitted from multiple package software processing units 700, the simulation device 1 updates the database stored in the data accumulation unit 56 and trains the prediction model 62A based on the information stored in the updated database. When the simulation device 1 receives variable information due to the adjustment of variables by the evaluator terminal device 800, it predicts the operation of the software processing unit 700 using the changed variables and calculates the fee when the software processing unit 700 operates with the predicted operation. The simulation device 1 creates display data including the calculated fee and provides the display data to the evaluator terminal device 800 that transmitted the variable information. In this way, the evaluator terminal device 800 can display the fee when the software processing unit 700 operates when the variables are adjusted.

Figure 8 is a diagram showing an example of the total wheeling charge, the total power generation side charge, and the variable cost of the power transmission and distribution equipment when the variables in the power system are changed in the embodiment. For example, the evaluator terminal device 800 adjusts the system parameter information indicating the reinforcement of the power transmission and distribution equipment 210. At this time, the operation prediction unit 62 predicts the operation of the power transmission and distribution power when the power transmission and distribution equipment 210 is reinforced, and the fee calculation unit 64 calculates the variable cost of the power transmission and distribution equipment 210 according to the predicted operation. In addition, the fee calculation unit 64 calculates the total amount of the power generation side charge and the total amount of the wheeling charge based on the variable cost of the power transmission and distribution equipment 210. When the power transmission and distribution equipment 210 is changed within the range of the change range of the reinforcement by the variable change unit 60, the operation prediction unit 62 predicts the fluctuation range of the power transmission and distribution power relative to the change range, and the fee calculation unit 64 can calculate the positive and negative impacts of the total wheeling charge, the total amount of the power generation side charge, and the variable cost of the power transmission and distribution equipment 210 relative to the fluctuation range of the power transmission and distribution. The display data creation unit 40 can create data that displays the total wheeling charge, which has the largest fluctuation range, at the top among the total wheeling charge, the total charge on the power generation side, and the variable cost of the power transmission and distribution facility 210. In this way, the simulation device 1 can allow a person considering a system change to recognize the fees that will be most affected by the system change in the power system.

The variable information may be information indicating the ratio in the electricity trading among the consumer, the power generation company, and the retailer. The ratio in the electricity trading among the consumer, the power generation company, and the retailer is, for example, the sharing ratio of the fee for using the electricity system. In this case, the variable change unit 60 receives information indicating that the ratio in the electricity trading has been changed as the variable information from the evaluator terminal device 800. The operation prediction unit 62 predicts the change in the operation of each system processing unit 710 when the change in the ratio in the electricity trading is applied. The fee calculation unit 64 calculates the change in the fee for the electricity trading among the consumer, the power generation company, and the retailer, which is determined by the operation of each system processing unit 710. In this way, the simulation device 1 can calculate the impact on the system design when the ratio borne by market participants in the electricity trading changes.

The variable information may be information indicating the ratio of fixed charges to variable charges in the power system. The variable change unit 60 receives information indicating that the ratio of fixed charges to variable charges has been changed as variable information from the evaluator terminal device 800. The operation prediction unit 62 predicts changes in the operation of each system processing unit 710 when a change in the ratio of fixed charges to variable charges is applied. The fee calculation unit 64 calculates changes in fees related to power trading at consumers, power generation companies, and retail companies relative to the ratio of fixed charges to variable charges. This allows the simulation device 1 to calculate the impact on the system design when the ratio of fixed charges to variable charges in power trading is changed.

The variable information may be information about the environment of the area to which the power system system is applied. The variable change unit 60 receives information indicating that the information about the environment has changed as variable information from the evaluator terminal device 800. The operation prediction unit 62 predicts changes in the operation of each system processing unit 710 when a change in the area's environment is applied. The operation prediction unit 62 predicts changes in the operation of the system processing unit 710 when, for example, a new distributed power source is connected to the power transmission and distribution facility 210. The fee calculation unit 64 calculates changes in fees related to electricity transactions at consumers, power generation companies, and retail companies in response to changes in the operation of the system processing unit 710. The environment of the area to which the power system system is applied may be, for example, the climate of the area where the simulation device 1 is used, the season in which the impact on the system design is to be simulated, the time of day, etc.

The simulation processing unit 58 may calculate the range of positive and negative fluctuations of the impact on electricity trading among consumers, power generation companies, and retailers when a variable related to the electricity system regime is changed. The simulation unit 30 may determine the risk of a change to the electricity system regime based on the range of fluctuations. For example, the simulation unit 30 may determine that the risk of the regime change is higher the greater the range of fluctuation of the impact on electricity trading due to a change in a variable related to the regime change. Furthermore, the display data creation unit 40 may create data that prioritizes and displays the impacts with the largest range of fluctuations among the impacts calculated by the simulation unit 30.

As described above, the simulation device 1 of the embodiment includes an acquisition unit 10 that acquires power system information related to the facilities and market entrants included in the power system, a variable change unit 20 that receives variable information indicating variables related to the power system regime, and a simulation unit 30 that calculates the impact on market entrants when variables related to the power system regime change based on the power system information acquired by the acquisition unit 10 and the variable information received by the variable change unit 20. According to the simulation device 1 of the embodiment, it is possible to evaluate the regime change when the power system regime is changed.

According to the embodiment of the simulation device 1, power system information on the equipment and market entrants included in the power system including the renewable energy power generation equipment 110 is acquired, a change in the renewable energy power generation equipment 110 when a variable related to the power system system changes is predicted, and based on the predicted change, the impact of the change in the variable on power trading among consumers, power generation companies, and retailers can be calculated. As a result, according to the simulation device 1, the impact of the change in the power system system on distributed power generation equipment such as solar power generation equipment can be calculated, and the change in the power system system can be evaluated taking into account the renewable energy power generation equipment 110. Similarly, according to the embodiment of the simulation device 1, power system information on the equipment and market entrants included in the power system including the power transmission and distribution equipment 210 that performs wheeling can be acquired, a change in the wheeling of the power transmission and distribution equipment 210 when a variable related to the power system system changes is predicted, and based on the predicted change, the impact of the change in the variable on power trading among consumers, power generation companies, and retailers can be calculated. As a result, according to the simulation device 1, the impact of the change in the power system system on the wheeling of the power transmission and distribution equipment 210 can be calculated, and the change in the power system system can be evaluated taking into account the wheeling of the power transmission and distribution equipment 210. Similarly, according to the embodiment of the simulation device 1, it is possible to obtain power system information on the facilities and market participants included in the power system including the smart meter system 420, predict changes in the smart meter system 420 when variables related to the power system system change, and calculate the impact of the change in the variables on power trading among consumers, power generation companies, and retailers based on the predicted changes. As a result, according to the simulation device 1, it is possible to calculate the impact of a change in the power system system on the smart meter system 420 and evaluate the change in the power system system taking the smart meter system 420 into consideration.

According to the embodiment of the simulation device 1, by introducing package software, for example, into the power system, it is possible to realize functions such as a meter information management system 430, a smart meter system 420, a wheeling system 220, a weather information providing server device 620, and a resource control system 120. The simulation device 1 collects information about the power system by the package software communicating with the simulation device 1. The simulation device 1 can simulate how the collected information about the power system changes when it acquires information indicating a change in the power system system.

The simulation device 1 may collect information from software installed in other facilities in the power system, in addition to the meter information management system 430, the smart meter system 420, the wheeling system 220, the power generation/retail supply and demand adjustment system 610, and the resource control system 120, which are realized by package software. The simulation device 1 collects information on power trading in the power trading system 640, for example, by package software installed in the power trading system 640. The simulation device 1 accumulates changes in information on power trading for variables related to the power system system. When a new variable related to the power system system is set, the simulation device 1 can simulate changes in information on power trading for the new variable. The simulation device 1 collects information on the supply and demand balance status grasped in the cross-regional organization system, for example, by package software installed in the cross-regional organization system. The simulation device 1 accumulates information on the supply and demand balance status for variables related to the power system system. When a new variable related to the power system system is set, the simulation device 1 can simulate changes in information on the supply and demand balance status for the new variable.

Furthermore, the simulation device 1 may install software in each of the consumer equipment 410, the power generation equipment in the power generation system 100, and the retailer equipment 310, and collect information on the behavior of the consumer equipment 410, the power generation equipment in the power generation system 100, and the retailer equipment 310. The simulation device 1 accumulates changes in information on the behavior of each of the consumer equipment 410, the power generation equipment in the power generation system 100, and the retailer equipment 310 with respect to variables related to the power system system. When a new variable related to the power system system is set, the simulation device 1 can simulate changes in information on the behavior of each of the power generation equipment in the power generation system 100 and the retailer equipment 310 with respect to the new variable.

As described above, the simulation device 1 can accumulate information about market participants (players) related to the power system, and can simulate the behavior of market participants related to the power system when variables related to future power distribution trends are introduced into the power system. As a result, the simulation device 1 can evaluate the power system system across the entire power system at the power system system review stage. Furthermore, the simulation device 1 can simulate the impact on each market participant related to the power system when the power system system is changed.

The simulation device 1 can support thorough consideration when changing the power system system by simulating the new power system system and using the simulation results. For example, when a new system is started without sufficient consideration of the power system system, the simulation device 1 can prevent chaos in the power system and the power market due to mismatches in the supply and demand balance, rising electricity prices, unfair competition, and the like. Furthermore, by supporting the system design of the power system, the simulation device 1 can prevent changes to the power system system or specifications as much as possible and reduce the system development costs for the new power system system. As a result, the simulation device 1 can provide the simulation results to general electricity transmission and distribution companies and the like who purchase the power system.

Note that although each embodiment and each modified example have been described, these are merely examples and are not intended to be limiting. For example, any of the embodiments or modified examples, or a part of each embodiment or a part of each modified example, may be combined with one or more other embodiments or one or more other modified examples to realize one aspect of the present invention.

1...simulation device, 10...acquisition unit, 20...variable change unit, 30...simulation unit, 40...display data creation unit, 100...power generation system, 120...resource control system, 200...power transmission and distribution system, 220...transportation system, 300...retail system, 400...consumer system, 420...smart meter system, 430...meter information management system, 500...energy storage system, 600...electricity market system, 610...power generation/retail supply and demand adjustment system, 620...weather information provision server device, 630...information disclosure server device

Claims (11)

an acquisition unit for acquiring power system information relating to facilities and market participants included in the power system;
A variable change unit that receives variable information indicating a variable related to a system of the power system;
a simulation unit that calculates an impact on the market entrant when a variable related to the power system is changed, based on the power system information acquired by the acquisition unit and the variable information accepted by the variable change unit; and
A simulation device comprising: The market participants include consumers, power generators, and retailers;
the acquisition unit acquires, as the power system information, information on components of a power system including consumer equipment, power generation company equipment, renewable energy power generation equipment, retailer equipment, power transmission and distribution equipment, and a power supply and demand adjustment system that presents demand plan information and power generation plan information to a cross-regional organization;
2. The simulation device according to claim 1, wherein the simulation unit predicts changes in the components when a variable related to a system of the power system changes, and calculates an impact of the change in the variable on power trading among the consumers, the power generation company, and the retailer based on the predicted change. The variable information is information indicating a ratio in an electricity transaction between a consumer, a power generation company, and a retail company,
the variable change unit receives, as the variable information, information indicating that a ratio in the electricity trading has been changed;
The simulation unit calculates a change in a price for the electricity trading among the consumer, the power generation company, and the retail company with respect to the ratio in the electricity trading.
The simulation device according to claim 1 or 2. the variable information is information indicating a ratio between a fixed charge and a variable charge in the electricity system,
the variable change unit receives, as the variable information, information indicating that a ratio between the fixed fee and the variable fee has been changed;
The simulation unit calculates a change in a fee for electricity trading among consumers, power generation companies, and retail companies in response to a ratio between the fixed fee and the variable fee.
The simulation device according to claim 1 or 2. The simulation device according to claim 1 or 2, wherein the simulation unit predicts, as a change in the equipment included in the power system, a change in the operating state of the equipment included in the power system or a change in the variable cost of the equipment included in the power system in response to a change in a variable related to the power system's system. The variable information is information regarding an environment of a region to which the power system is applied,
the variable change unit receives, as the variable information, information indicating that information regarding the environment has changed;
The simulation unit calculates changes in fees related to electricity transactions among consumers, power generation companies, and retail companies in response to changes in the environment.
The simulation device according to claim 1 or 2. The simulation device according to claim 1 or 2, wherein the simulation unit calculates the range of positive and negative fluctuations of the impact on electricity trading among consumers, power generation companies, and retailers when a variable related to the power system system is changed, and determines the risk of the change in the power system system based on the range of fluctuations. The simulation device according to claim 7, which creates data that prioritizes and displays influences that have a large fluctuation range among the influences calculated by the simulation unit. obtaining power system information regarding equipment and market participants included in the power system;
receiving variable information indicating a variable related to a system of the power system;
A step of calculating an impact on the market participant when a variable related to the power system system changes based on the power system information and the variable information;
A simulation method comprising: On the computer,
obtaining power system information regarding equipment and market participants included in the power system;
receiving variable information indicating a variable related to a system of the power system;
A step of calculating an impact on the market participant when a variable related to the power system system changes based on the power system information and the variable information;
A simulation program that executes the above. An electric power system including a consumer facility, a power generation facility, a renewable energy power generation facility, a retailer facility, an electric power transmission and distribution facility, and an electric power supply and demand adjustment system that presents demand plan information and power generation plan information to a cross-regional organization,
an acquisition unit that acquires power system information related to facilities and market participants included in the power system;
A variable change unit that receives variable information indicating a variable related to a system of the power system;
a simulation unit that calculates an impact on the market entrant when a variable related to the power system is changed, based on the power system information acquired by the acquisition unit and the variable information accepted by the variable change unit; and
A power system comprising:

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