JP6845091B2 - Electric power retail business evaluation device and electric power retail business evaluation method - Google Patents

Description

An embodiment of the present invention relates to an electric power retail business evaluation device and an electric power retail business evaluation method.

An electric power retailer operates an electric power retail business that procures electric power and supplies it to consumers. Conventionally, technologies for supporting such electric power retailers have been known.

For example, a technique for comparing a plurality of consumers from the viewpoint of profitability is disclosed based on information such as contract charges and electric power demands for electric power consumers.

Japanese Unexamined Patent Publication No. 2007-048050 JP-A-2007-272825

However, in the prior art, the evaluation of profitability is calculated based on the information about the consumer, and it is difficult to predict the influence on profitability due to the difference in the power supply source. For this reason, it has been required to evaluate the profitability of the electric power retail business with higher accuracy.

The electric power retail business evaluation device of the embodiment includes a storage unit, a reception unit, and an output unit. The storage unit includes the amount of electricity demanded by each consumer to whom the electricity retailer sells electricity, the purchase price of electricity by each power source from which electricity is purchased, and the amount of electricity that can be supplied by each power source. Remember. The reception unit accepts the input of the combination of the consumer and the power supply. The output unit determines the power purchased from the power sources included in the combination based on the combination, the amount of power demanded by each consumer, the purchase price of power for each power source, and the amount of power that can be supplied for each power source. Outputs the electric power retail business evaluation index that evaluates the profitability of the electric power retail business when it is sold to the consumers included in the combination. The storage unit also stores information about the power supply by the distributed generation installed in the consumer or power source. The reception unit accepts input of a combination of a consumer, a power source, and a distributed power source. The output unit outputs the amount of fluctuation in profit due to the installation of the distributed power source and the capacity of the distributed power source in which the profit increases, based on the combination and the information about the power supply by the distributed power source.

FIG. 1 is a diagram showing an example of a hardware configuration of the electric power retail business evaluation device according to the first embodiment. FIG. 2 is a block diagram showing an example of the functional configuration of the electric power retail business evaluation device according to the first embodiment. FIG. 3 is a diagram showing an example of the table configuration of the power area database according to the first embodiment. FIG. 4 is a diagram illustrating an outline of the power area and the interconnection line according to the first embodiment. FIG. 5 is a diagram showing an example of the table configuration of the interconnection line database according to the first embodiment. FIG. 6 is a diagram showing an example of the table configuration of the interconnection line utilization plan database according to the first embodiment. FIG. 7 is a diagram showing an example of the table configuration of the selling price database according to the first embodiment. FIG. 8 is a diagram showing an example of the table configuration of the demand assumption database according to the first embodiment. FIG. 9 is a diagram showing an example of the table configuration of the purchase price database according to the first embodiment. FIG. 10 is a diagram showing an example of a table configuration of the power supply amount database according to the first embodiment. FIG. 11 is a diagram showing an example of the table configuration of the consignment database according to the first embodiment. FIG. 12 is a diagram showing an example of the table configuration of the assumed spot price database according to the first embodiment. FIG. 13 is a diagram showing an example of the menu screen according to the first embodiment. FIG. 14 is a diagram showing an example of a setting screen for setting the power supply to be simulated according to the first embodiment. FIG. 15 is a diagram showing an example of a setting screen for setting a customer to be simulated according to the first embodiment. FIG. 16 is a graph showing an example of a supply and demand plan for each simulation case according to the first embodiment. FIG. 17 is an example of a graph comparing the profitability of each simulation case according to the first embodiment. FIG. 18A is a flowchart showing an example of the flow of the simulation case generation process according to the first embodiment. FIG. 18B is a flowchart showing an example of the flow of the simulation process of the profitability evaluation according to the first embodiment. FIG. 19 is a diagram showing an example of the distributed power source according to the second embodiment. FIG. 20 is a block diagram showing an example of the functional configuration of the electric power retail business evaluation device according to the second embodiment. FIG. 21 is a diagram showing an example of the table configuration of the PV attribute database according to the second embodiment. FIG. 22 is a diagram showing an example of the table configuration of the PV assumed output ratio database according to the second embodiment. FIG. 23 is a diagram showing an example of the table configuration of the storage battery attribute database according to the second embodiment. FIG. 24 is a diagram showing an example of a setting screen for setting a combination of the power source to be simulated and the distributed power source according to the second embodiment. FIG. 25 is a diagram showing an example of a setting screen for setting a combination of the customer to be simulated and the distributed power source according to the second embodiment. FIG. 26 is a diagram showing an example of a setting screen for setting a pattern of the combination of distributed power sources according to the second embodiment. FIG. 27 is a diagram showing an example of a setting screen for setting the rated capacity of the distributed power source according to the second embodiment. FIG. 28 is an example of a table showing the incremental profits assumed for each combination pattern of the distributed power sources according to the second embodiment. FIG. 29 is an example of a graph showing the payback period according to the second embodiment. FIG. 30 is an example of a table showing the payback period according to the second embodiment. FIG. 31 is another example of a graph showing the payback period according to the second embodiment. FIG. 32 is another example of a table showing the incremental profits assumed for each combination pattern of the distributed power sources according to the second embodiment. FIG. 33 is a flowchart showing an example of the flow of the simulation case generation process according to the second embodiment. FIG. 34 is a flowchart showing an example of the flow of the simulation process of the profitability evaluation according to the second embodiment. FIG. 35 is a diagram showing an example of the overall configuration of the electric power retail business evaluation device system in the modified example.

(Embodiment 1)
FIG. 1 is a diagram showing an example of the hardware configuration of the electric power retail business evaluation device 1 according to the present embodiment. As shown in FIG. 1, the electric power retail business evaluation device 1 includes a CPU (Central Processing Unit) 101, a memory 102, an HDD (Hard Disk Drive) 103, a display device 104, an input device 105, and a communication interface ( It includes an I / F) 106 and a bus 107.

The CPU 101 is a control device that controls the entire electric power retail business evaluation device 1. For example, the CPU 101 realizes various configurations by executing a program or the like stored in the memory 102.

The memory 102 is a memory for storing readable data, for example, a ROM. Further, the electric power retail business evaluation device 1 may adopt a configuration further including a memory such as a writable RAM.

HDD 103 is an external storage device (auxiliary storage device). The electric power retail business evaluation device 1 may adopt a configuration including a storage medium such as a flash memory instead of the HDD 103.

The display device 104 is a display or the like including a liquid crystal panel or the like.

The input device 105 is, for example, a keyboard, a mouse, a touch panel, or the like, and is a device that accepts user operations.

The communication interface 106 is an interface for the electric power retail business evaluation device 1 to transmit and receive via a network or the like.

The bus 107 is a data transmission line inside the electric power retail business evaluation device 1.

The configuration of the electric power retail business evaluation device 1 shown in FIG. 1 is an example, and may be any one having a general computer function. Further, the electric power retail business evaluation device 1 may be connected to a printer or the like (not shown).

FIG. 2 is a block diagram showing an example of the functional configuration of the electric power retail business evaluation device 1 according to the present embodiment. As shown in FIG. 2, the electric power retail business evaluation device 1 of the present embodiment includes a reception unit 111, a case generation unit 112, a calculation unit 113, an output unit 114, and a storage unit 115.

In the present embodiment, the electric power retailer or a person who performs processing related to the evaluation of profitability in response to a request from the electric power retailer is referred to as a user. The user of the present embodiment selects a consumer to whom the electric power retailer sells electric power. In addition, the user selects a power source for supplying electric power to the consumer. Then, the electric power retail business evaluation device 1 accepts the input of the combination of the consumer and the power source selected by the user. Then, the electric power retail business evaluation device 1 evaluates the profitability of the combination that receives the input. Hereinafter, the configuration required for evaluating profitability in the electric power retail business evaluation device 1 will be described.

The storage unit 115 is composed of, for example, an HDD 103. The storage unit 115 includes a power area database (DB) 121, an interconnection line database (DB) 122, an interconnection line utilization plan database (DB) 123, a selling price database (DB) 130, and a demand estimation database (DB). ) 131, the purchase price database (DB) 140, the power supply amount database (DB) 141, the consignment database (DB) 150, and the assumed spot price database (DB) 151 are stored.

The power area database 121, the interconnection line database 122, and the interconnection line utilization plan database 123 store information about the power area or the interconnection line.

Specifically, the electric power area database 121 is a database in which information about an electric power area in which an electric power retailer using the electric power retail business evaluation device 1 purchases and sells electric power is registered. The electric power area is the area under the jurisdiction of the electric power company that supplies electric power. The power area is an example of an area in this embodiment.

FIG. 3 is a diagram showing an example of the table configuration of the power area database 121 according to the present embodiment. As shown in FIG. 3, for example, the power area database 121 in the present embodiment stores an area name that identifies a power area. Further, the power area database 121 may store a number (No.) for identifying the power area, a code, and the like.

FIG. 4 is a diagram illustrating an outline of a power area and an interconnection line according to the present embodiment. As shown in FIG. 4, the electric power area according to the present embodiment is nine areas from the Hokkaido area a1 to the Kyushu area a9. The power area shown in FIG. 4 is an example, and the division of the power area is not limited to this.

Further, as shown in FIG. 4, the power areas are connected by interconnection lines l (L) 1 to l10. An interconnection line is a line for transmitting electric power between different electric power areas. When the interconnection lines l1 to l10 are not distinguished, they are simply referred to as interconnection lines l.

For example, an electric power retailer using the electric power retail business evaluation device 1 may purchase and supply electric power across a plurality of electric power areas. Further, the amount of electric power flowing into a certain electric power area from another electric power area through the interconnection line is also referred to as a tidal current of the interconnection line.

The interconnection line database 122 is a database that stores information about the interconnection line l. FIG. 5 is a diagram showing an example of the table configuration of the interconnection line database 122 according to the present embodiment. As shown in FIG. 5, in the interconnection line database 122, the item "connection line name" in which the name of the interconnection line l is registered and the item "connection area 1" indicating the power area to which the interconnection line l is connected And "connection area 2". Further, the interconnection line database 122 may store a number (No.) for identifying the interconnection line l, a code, and the like.

For example, as shown in FIGS. 4 and 5, the interconnection line l1 connects the Hokkaido area and the Tohoku area. Further, the interconnection line l2 connects between the Tohoku area and the Tokyo area, and the interconnection line l3 connects between the Tokyo area and the Chubu area. Similarly, the other interconnection lines l4 to l10 also connect different areas.

An upper limit is set in advance for the amount of electric power that can be used by each electric power retailer among the amount of electric power that can be supplied from one electric power area to the other electric power area per hour unit for each interconnection line l. In the present embodiment, data indicating the amount of electric power that can be supplied from one electric power area to the other electric power area per time unit for each interconnection line l and that can be used by the electric power retailer is used for the interconnection line. It is called usage plan data.

The interconnection line utilization plan database 123 is a database for storing the interconnection line utilization plan data. FIG. 6 is a diagram showing an example of the table configuration of the interconnection line utilization plan database 123 according to the present embodiment. As shown in FIG. 6, the interconnection line utilization plan database 123 is used by the electric power retailer among the date, the time, and the amount of electric power that can be supplied from one electric power area to the other electric power area by each interconnection line. Save the possible amount of power in association with it. Since the interconnection line utilization plan database 123 stores future plans, the dates and times set in the items “date” and “time” shown in FIG. 6 are future dates and times. Further, the date and time is an evaluation target period for evaluating the profitability of the electric power retail business of the simulation executed by the calculation unit 113 described later. The evaluation period will be described later.

In the example shown in FIG. 6, the interconnection line utilization plan database 123 is the electric power available to the electric power retailer every 30 minutes on the interconnection line l3 (“Tokyo-Chubu”) connecting the Tokyo area and the Chubu area. Save the amount. For example, it can be supplied from the Tokyo area to the Chubu area by the interconnection line l3 (“Tokyo-Chubu”) for 30 minutes between the time “0:00” and “0:30” on the date “2016/4/1”. Of the amount of electric power, the amount of electric power that can be used by the electric power retailer is 1000 kwh.

Further, as shown in FIG. 4, in Japan, AC power having a frequency of 50 Hz is used in eastern Japan, and AC power having a frequency of 60 Hz is used in western Japan. The electric power areas included in eastern Japan are Hokkaido area a1, Tohoku area a2, and Tokyo area a3. The electric power areas included in western Japan are the central area a4, the Hokuriku area a5, the Kansai area a6, the China area a7, the Shikoku area a8, and the Kyushu area a9.

Since the frequency is converted when power is transmitted between the Tokyo area and the Chubu area, the interconnection line l3 that connects the Tokyo area and the Chubu area has a different amount of power that can be transmitted per hour. Less than the interconnection line l of. Therefore, although the interconnection line l3 is particularly illustrated in FIG. 6, the interconnection line utilization plan database 123 stores the interconnection line utilization plan data not only for the interconnection line l3 but also for other interconnection lines l. Is also good.

Further, the selling price database 130 and the demand estimation database 131 store information about the consumer.

A consumer is a sales destination to which an electric power retailer sells electric power. The consumer in this embodiment is, for example, a factory or a company. In addition, the consumer may include a general household with an individual contract.

Specifically, the selling price database 130 is a database that stores information on the selling price of electric power for each consumer. FIG. 7 is a diagram showing an example of the table configuration of the selling price database 130 according to the present embodiment. As shown in FIG. 7, the selling price database 130 contains data set in the items "customer name", "electric power area", "contracted electric power", "basic charge", and "metered charge". Save in association with each other. Further, the selling price database 130 may store a number (No.) identifying each customer, a code, and the like.

The consumer name is a name that identifies the consumer. The electric power area is the electric power area where the consumer is located. The contracted electric power is the amount of electric power per month contracted with the electric power supplied by the electric power retailer to the consumer. If the contracted power changes on a monthly basis, the selling price database 130 may store the contracted power on a monthly basis.

Further, the basic charge and the metered charge registered in the selling price database 130 are charges paid by the consumer to the electric power retailer. The basic charge is a charge determined according to the monthly contracted electric energy. The pay-as-you-go rate is the unit price per kWh of the rate added according to the amount of electricity purchased by the consumer from the electricity retailer. The pay-as-you-go rate may further vary depending on conditions such as the time of day. In this case, the selling price database 130 may adopt a configuration further including an item in which conditions such as a time zone are registered. The basic charge and the metered charge registered in the selling price database 130 can also be referred to as the selling price of electric power.

Further, the demand estimation database 131 is a database that stores the estimated power demand amount for each consumer for each electric charge area. FIG. 8 is a diagram showing an example of the table configuration of the demand assumption database 131 according to the present embodiment. As shown in FIG. 8, the demand estimation database 131 stores the date, the time, and the estimated power demand amount for each consumer in association with each other.

For example, during the 30 minutes between the time "0:00" and "0:30" on the date "2016/4/1", the power demand amount of "Hokkaido area consumer 1" is 100 kwh. On the other hand, during the 30 minutes between the time "0:00" and "0:30" of "April 1, 2016", the amount of electricity demand of "Tohoku area consumer 1" is 200 kwh.

Since the demand estimation database 131 stores the estimated future power demand, the dates and times set in the items “date” and “time” shown in FIG. 8 are future dates and times. Further, the date and time is an evaluation target period for evaluating the profitability of the electric power retail business of the simulation executed by the calculation unit 113 described later. The evaluation period will be described later.

The demand estimation database 131 stores the electric power demand amount assumed for each consumer, and each consumer is associated with each electric power area where the selling price database 130 is located by the selling price database 130 shown in FIG. 7. Therefore, it can be said that the storage unit 115 stores the power demand amount for each consumer for each power area.

Further, the purchase price database 140 and the power supply amount database 141 store information on the power supply.

The power source is the place of purchase for the electric power retailer to purchase the electric power. The power source in this embodiment is, for example, an electric power company such as Tokyo Electric Power Company or a power generation company. Alternatively, the power source may be a unit of a power plant owned by the power generation company.

Specifically, the purchase price database 140 is a database that stores the purchase price of electric power for each power source. FIG. 9 is a diagram showing an example of the table configuration of the purchase price database 140 according to the present embodiment. As shown in FIG. 9, the purchase price database 140 associates the data set in the items "power supply name", "power area", "type", "basic charge", and "metered charge". And save.

The power supply name is a name that identifies the power supply. The electric power area is an electric power area where the power source is located. The type indicates the type of the power supply form of each power source. For example, the type "constant backup" refers to a form in which an electric power retailer continuously purchases electric power (wholesale supply) from an electric power company when supplying (retailing) electric power to a consumer. Generally, when the power source is an electric power company, the type is "always backup". Further, the type "fixed" indicates that the power supply amount of the power source is fixed for each hour. For example, in general, a power generation company of new electric power generates electricity according to a fixed power generation schedule, so that the amount of electric power supplied is fixed every hour. Therefore, when the power source is a power generation company of new electric power, the type of electric power supply form is "fixed".

Further, the basic charge and the metered charge registered in the purchase price database 140 are charges paid by the electric power retailer to the power source. The basic charge is a charge determined according to the monthly contracted electric energy. The pay-as-you-go rate is a unit price per kWh of a rate added according to the amount of electric power purchased from the power source by the electric power retailer. The pay-as-you-go rate may be a different amount depending on conditions such as the time of day. In this case, the purchase price database 140 may adopt a configuration that further includes an item in which conditions such as a time zone are registered. The basic charge and the metered charge registered in the purchase price database 140 are examples of the purchase price of electric power in the present embodiment.

Further, the power supply amount database 141 is a database that stores the power supply amount that can be supplied for each power source. FIG. 10 is a diagram showing an example of a table configuration of the power supply amount database 141 according to the present embodiment. As shown in FIG. 10, the power supply database 141 stores the date, the time, and the power that can be supplied for each power source in association with each other. The dates and times set in the items "date" and "time" shown in FIG. 10 are future dates and times. Further, the date and time is an evaluation target period for evaluating the profitability of the electric power retail business of the simulation executed by the calculation unit 113 described later. The evaluation period will be described later.

For example, the amount of electric power that can be supplied by the power source "Hokkaido area power source 1" is 100 kwh during the 30 minutes between the time "0:00" and "0:30" on the date "2016/4/1".

Further, the consignment database 150 is a database that stores the loss rate for each power area related to the supply of electric power and the consignment charge.

Consignment means that a power transmission and distribution business operator that owns a power transmission and distribution network carries electric power from a power source to a consumer. The electricity retailer pays the transmission and distribution company a consignment fee because it uses the power grid to supply the electricity purchased from the power source to the consumers. The amount of the transportation fee varies depending on the power area. In addition, the loss rate when power is consigned also differs from power area to power area.

FIG. 11 is a diagram showing an example of the table configuration of the consignment database 150 according to the present embodiment. As shown in FIG. 11, the consignment database 150 stores the data set in the items “electric power area”, “loss rate”, “basic charge”, and “metered charge” in association with each other.

For example, when power is consigned within the Hokkaido area, the loss rate is "3.00%". In this case, 3.00% of the electric power transmitted from the power source is lost without reaching the consumer. For this reason, the electric power retailer purchases from the power source by adding the electric power for the loss in advance to the amount of electric power to be sold to the consumer.

The basic charge and the metered charge registered in the consignment database 150 are charges paid by the electric power retailer to the power transmission and distribution business operator. The basic charge is a charge determined according to the monthly contracted electric energy. The pay-as-you-go rate is the unit price per kWh of the rate added according to the amount of electric power requested by the electric power retailer to be consigned. The basic charge and the metered charge registered in the consignment database 150 are examples of the consignment charge in the present embodiment.

Further, as shown in FIG. 4, the electric power retailer sells the electric power purchased from the electric power market M to the consumers located in each electric power area, or sells the electric power purchased from the electric power source in the electric power market M. ..

The electric power market M is specifically a market for trading electric power such as the Japan Electric Power Exchange (JEPX). In the present embodiment, the case where the electric power market M is a one-day-ahead market (electric power spot market) in which electricity is traded on the next day will be described, but other electric power markets may be used. The price of electric power for each preset time zone in the electric power market M is called a spot price. Further, in the present embodiment, the spot price is different for each electric power area. In the electric power market M of the present embodiment, it is assumed that transactions are carried out in units of 30 minutes per frame.

The assumed spot price database 151 is a database for storing the estimated spot price amount. The spot price stored in the assumed spot price database 151 may be, for example, a spot price on the same date and time one year ago. In addition, the spot price may fluctuate due to factors such as the weather and fuel price. Therefore, the spot price stored in the assumed spot price database 151 may be calculated in advance based on various factors.

FIG. 12 is a diagram showing an example of the table configuration of the assumed spot price database 151 according to the present embodiment. As shown in FIG. 12, the estimated spot price database 151 stores the date, the time, and the estimated spot price for each power area in association with each other. Since the assumed spot price is the price per 1 kWh, the unit is ¥ / kWh. The dates and times set in the items "date" and "time" shown in FIG. 12 are future dates and times. Further, the date and time is an evaluation target period for evaluating the profitability of the electric power retail business of the simulation executed by the calculation unit 113 described later. The evaluation period will be described later.

For example, the estimated spot price in the Hokkaido area is "8.66 \ / kWh" for 30 minutes between the time "0:00" and "0:30" on the date "2016/4/1".

The assumed spot price of the present embodiment is the same for the price of purchasing electric power from the electric power market M and the price of selling electric power to the electric power market M, but is not limited thereto. For example, the purchase price from the electricity market M and the selling price may be different amounts. In this case, the assumed spot price database 151 may be configured to hold the purchase price and the selling price in separate items. Alternatively, the storage unit 115 may store the purchase price and the selling price in different databases. Further, the assumed spot price may be the same price regardless of the power area.

The above-mentioned power area database 121, interconnection line database 122, interconnection line utilization plan database 123, selling price database 130, demand estimation database 131, purchase price database 140, power supply amount database 141, consignment database 150, assumed spot. The data and values stored in the price database 151 are examples and are not limited thereto.

Returning to FIG. 2, the output unit 114 outputs a menu screen showing options for the processing to be executed to the display device 104. FIG. 13 is a diagram showing an example of a menu screen according to the present embodiment. For example, the display device 104 displays options such as "data input", "simulation case setting", "simulation execution", and "end" so as to be selectable. When the user selects one of these options and clicks the execution button 900 with the mouse, the reception unit 111 described later accepts the user's operation. The screen configuration shown in FIG. 13 is an example and is not limited to this.

For example, when the reception unit 111 accepts the selection of the option "data input" on the menu screen shown in FIG. 13 from the user, the output unit 114 may, for example, store the input destination database and the data file or the like. You may also display a screen for entering the path. Alternatively, the output unit 114 may display a screen for accepting manual input of data. The input destination database is, for example, a power area database (DB) 121, an interconnection line database (DB) 122, an interconnection line utilization plan database (DB) 123, a selling price database (DB) 130, and a demand estimation database (DB). ) 131, purchase price database (DB) 140, power supply amount database (DB) 141, consignment database (DB) 150, or assumed spot price database (DB) 151. Then, when registering information in these databases, "data entry" is selected.

Further, when the reception unit 111 receives the selection of the option "simulation case setting" from the user, the output unit 114 further displays, for example, the setting screen of the simulation case. The simulation case setting screen will be described later in the description of the function of the case generation unit 112. The “simulation case setting” of the present embodiment is the setting of necessary conditions for the evaluation simulation of profitability. For example, the consumer to whom the electric power retailer supplies electric power and the electric power retail business concerned. Set the combination of power sources for which the person purchases electricity.

Further, the output unit 114 outputs the power supply / demand plan calculated by the calculation unit 113 described later and the power retail business evaluation index for evaluating the profitability of the power retail business for each simulation case to the display device 104. For example, the output unit 114 outputs to the display device 104 a supply and demand plan generated by the calculation unit 113, which will be described later, a graph showing the profitability of the electric power retail business, and the like. Details of the electricity supply and demand plan and the electricity retail business evaluation index will be described later.

Returning to FIG. 2, the reception unit 111 accepts the user's operation. For example, suppose that the option "data entry" on the menu screen shown in FIG. 13 is selected. In this case, the output unit 114 further displays a screen for inputting the input destination database and the path of the storage location of the data file or the like. The reception unit 111 reads a data file or the like according to the input path and registers it in the input destination database stored in the storage unit 115. Further, the method of inputting data into the database stored in the storage unit 115 is not limited to this.

Further, it is assumed that the option "simulation case setting" on the menu screen shown in FIG. 13 is selected by the user. In this case, the output unit 114 further displays a setting screen for setting the power supply and the consumer to be simulated. The reception unit 111 receives the combination of the consumer and the power supply input (set) by the user and sends it to the case generation unit 112.

Further, it is assumed that the option "simulation execution" on the menu screen shown in FIG. 13 is selected by the user. In this case, the reception unit 111 notifies the calculation unit 113, which will be described later, that the simulation execution operation has been accepted.

Further, it is assumed that the option "end" shown in FIG. 13 is selected by the user. In this case, the reception unit 111 notifies the output unit 114 to close the menu screen.

Returning to FIG. 2, the case generation unit 112 generates a simulation case used in the simulation of the profit evaluation of the electric power retail business. Specifically, the case generation unit 112 acquires the combination of the consumer and the power supply set by the user via the reception unit 111.

FIG. 14 is a diagram showing an example of a setting screen for setting a power supply to be simulated according to the present embodiment. Further, FIG. 15 is a diagram showing an example of a setting screen for setting a customer to be simulated according to the present embodiment.

As shown in FIG. 14, the setting screen (hereinafter referred to as the power supply setting screen) for setting the power source for which the simulation target, in other words, the power purchase target in the present embodiment is set, has a display field of "power supply No.". , Includes "power supply name". In addition, the power setting screen includes "reference" and "addition / deletion" as input fields. In the display columns "power supply No." and "power supply name", the data of "No." and "power supply name" of the purchase price database 140 shown in FIG. 9 is displayed by the output unit 114.

Further, as shown in FIG. 15, the setting screen (hereinafter referred to as the customer setting screen) for setting the simulation target in the present embodiment, in other words, the consumer to be the power supply target, is displayed as a "demand". Includes "house No." and "customer name". In addition, the consumer setting screen includes "standard" and "addition / deletion" as input fields. In the display columns "customer No." and "customer name", the data of "No." and "customer name" of the selling price database 130 shown in FIG. 7 is displayed by the output unit 114.

The input field "reference" shown in FIGS. 14 and 15 is a field in which the power source or the consumer, which is the reference of the simulation case, is set by the user. In the examples of FIGS. 14 and 15, the combination of the consumer and the power source in which the circle is entered in the input field "criteria" is a criterion for comparing with the profitability of other combinations when simulating the profitability. It shall be determined as. The combination is referred to as a simulation case reference.

Then, an input field "addition / deletion" is provided as an item for adjusting the combination of the power supply and the consumer set as the reference of the simulation case. The input field "addition / deletion" shown in FIGS. 14 and 15 is a field for accepting the setting of addition or deletion of the power supply or the consumer for the combination of the power supply or the consumer which is the reference of the simulation case. In the examples of FIGS. 14 and 15, when the reception unit 111 accepts the setting of "+" in the input field "addition / deletion" of any power supply or consumer, the power supply or consumer with "+" set. However, a case is generated that is added to the criteria of the simulation case. Further, when the reception unit 111 accepts the setting of the input field "addition / deletion" of any power supply or customer, the power supply or customer for which "-" is set is deleted with respect to the reference of the simulation case. Case is generated.

The case generation unit 112 generates a simulation case from the combination of the consumer and the power supply received by the reception unit 111. In the examples shown in FIGS. 14 and 15, there are eight types of simulation cases in which the combination of the power supply and the consumer is different, including the criteria of the simulation case (2 to the cube (presence or absence of Tohoku area power supply 3 and presence or absence of Tokyo area power supply 4). , And the combination of the presence or absence of the Tokyo area consumer 2)) is generated.

In the present embodiment, the power supply setting screen and the consumer setting screen have been described as separate screens, but these may be displayed on the same screen. The configuration of the setting screen shown in FIGS. 14 and 15 is an example, and the display field and the input field are not limited to these as long as the screen allows the user to set a simulation case for the combination of the power supply and the consumer. Absent.

Returning to FIG. 2, the calculation unit 113 executes a simulation based on the generated simulation case, and calculates an electric power retail business evaluation index for evaluating the profitability of the electric power retail business. Specifically, the calculation unit 113 is an optimization model (optimization problem) for minimizing the power purchase cost of the power retail business when the reception unit 111 notifies that the user has performed the simulation execution operation. Is used to execute the simulation in the set simulation case. The electric power purchase cost of the electric power retail business is an example of the electric power purchase cost in the present embodiment.

The calculation unit 113 uses the following equations (1) and equations (2-1) to (2-4) in the simulation. Equation (1) is an objective function indicating the amount of electricity purchase cost in the electricity retail business. Further, the equations (2-1) to (2-4) described later are equations showing the constraint conditions of the equation (1). Equations (2-1) to (2-4) are restrictions that the electric power retailer complies with when operating the electric power retail business, such as the balance between supply and demand.

The calculation unit 113 solves an optimization problem (linear programming problem) that minimizes the objective function of the equation (1) under the constraint conditions shown in the equations (2-1) to (2-4). For example, the calculation unit 113 may use a method such as a unit method or an interior point method.

“T” in the formula (1) is a time unit in which the evaluation target period for evaluating the profitability of the electric power retail business is divided every 30 minutes. Further, "g" in the formula (1) is a power source included in each of the above-mentioned simulation cases. Further, “a” in the formula (1) is a power area in which the power source or the consumer included in each of the above simulation cases is located.

_{Further, c g} (g, t), c _Jb (a, t), and c _Js (a, t) of the formula (1) are calculated from the data stored in each database stored in the storage unit 115. It is a parameter input to the equation (1) by 113.

The parameter c _g (g, t) is a metered rate of the power purchase price from the power source g at time t. Specifically, the calculation unit 113 inputs the commodity charge per 1kWh obtained from the purchase price database 140 shown in FIG. 9 _c g (g, t).

The parameters c _Jb (a, t) are assumed spot prices (purchase prices) of the power area a at time t. Further, the assumed spot price (selling price) of the electric power area a at the time t is input to the parameter c _{Js (a, t).} Specifically, the calculation unit 113 inputs the assumed spot price per 1 kWh acquired from the assumed spot price database 151 shown in FIG. 12 into c _Jb (a, t) and c _Js (a, t).

The variable P _g (g, t) is the amount of power purchased from the power source g at time t. The variables P _Jb (a, t) are the amount of electric power purchased from the electric power market M in the electric power area a at time t. The variable P _Js (a, t) is the amount of electric power sold to the electric power market M in the electric power area a at time t. The unit of the values of P _g (g, t), P _Jb (a, t), and P _Js (a, t) is kWh.

The first term of the formula (1) indicates the sum of the power purchase amount from the power source during the evaluation target period. The second term of the equation (1) indicates the amount obtained by subtracting the amount of electricity sold to the electricity market M in the evaluation period from the purchase amount of electricity from the electricity market M in the evaluation period. In other words, the second term of the equation (1) indicates the amount of money that the electricity retail business pays to the electricity market M during the evaluation period. The sum of the first and second terms of the formula (1) is the amount corresponding to the metered charge of the electricity purchase cost in the evaluation target period. Of the electricity purchase cost, the portion corresponding to the basic charge is constant because the demand does not change and does not affect the calculation result, so it is not included in the objective function here. A configuration may be adopted in which the basic charge for the electricity purchase cost is included in the optimization model.

The evaluation target period is the period for which the profitability of the electric power retail business is evaluated by this simulation. The evaluation target period in the present embodiment is a period in which assumed data regarding the power supply, the consumer, the interconnection line, the spot price, etc. registered in the storage unit 115 is registered. Specifically, the evaluation target period includes the interconnection line utilization plan database 123 shown in FIG. 6, the demand estimation database 131 shown in FIG. 8, the power supply amount database 141 shown in FIG. 10, and the estimated spot price database 151 shown in FIG. It is the date and time registered in the items "date" and "time" of. For example, in the present embodiment, when each of the above-mentioned databases holds data of a future date for one year, the evaluation target period is a period for one year in the future.

Further, an input field capable of further limiting the evaluation target period from the date and time registered in each database may be further provided in the power supply setting screen and the consumer setting screen described above.

Under the constraint conditions shown in the following equations (2-1) to (2-4), the values of these variables when the value of the equation (1) is the minimum are output as the solution of the optimization problem. .. In other words, the calculation unit 113 determines the electric energy purchased for each power source that minimizes the value of the equation (1), the electric energy purchased for each hour from the electricity market M, and the electric energy market M for each simulation case. Calculate the amount of electricity sold for each time to.

The “d” in the formula (2-1) indicates a consumer. The consumer entered in the equation (2-1) is the consumer included in each of the above simulation cases.

_{G a} of formula (2-1) represents the power set of the power area a. Further, L _a represents a set of tie-line connecting the power area a. _{D a} of the formula (2-1) represents a set of consumers in the power area a.

P _d (d, t) and η _a are parameters that accept input of values.

In the parameter P _d (d, t), the calculation unit 113 inputs the demand power amount of the consumer d at the time t acquired from the demand assumption database 131 shown in FIG. The unit of the value of P _d (d, t) is kWh.

In the parameter η _a , the loss rate in the power area a acquired from the consignment database 150 shown in FIG. 11 is input by the calculation unit 113.

The variable P _flow (l, t) is the amount of power (tide) that flows in or out from another power area using the interconnection line l at time t. The unit of the value of P _flow (l, t) is kWh. In addition to the variables included in the equation (1), the values of the variables P _flow (l, t) are also output by the calculation unit 113 as the solution of the optimization problem. Further, the variable P _flow (l, t) takes a value of + (plus) when it flows in from another power area and a value of-(minus) when it flows out.

Equation (2-1) is an equation showing a constraint condition that the supply and demand balance for each power area matches.

The left side of the equation (2-1) indicates the amount of electric power supplied to the electric power area a. Specifically, the left side of the equation (2-1) shows the amount of power supplied from the power source g in the power area a at time t, the amount of power flowing in or out between the other power areas, and the power. The value obtained by adding the amount of electricity purchased from the market M and subtracting the amount of electricity sold to the electricity market M is shown.

The right side of the equation (2-1) indicates the amount of power demand in the power area a. Specifically, the right side of the equation (2-1) shows a value obtained by adding the amount of power lost during power transmission in the power area a to the amount of power demanded by the consumer d in the power area a at time t.

When the values on the left side and the right side of the equation (2-1) are equal, the supply and demand balance for each power area matches.

Equation (2-2) is an equation showing the constraint condition of the upper limit of the power supply for each power source and each time.

_{P gmax} (g) of the formula (2-2) is a parameter that accepts the input of a value. In the parameter P _gmax (g), the value of the amount of power that can be supplied by the power source g, which is acquired from the power supply amount database 141 shown in FIG. 10, is input by the calculation unit 113. When the type of power supply g is "always backup", the upper limit constraint of the power supply is P _g (g, t) ≤ P _gmax (g). When the type of power supply g is “fixed”, the upper limit constraint of the supplied power is P _g (g, t) = P _gmax (g).

As shown in the formula (2-2), the amount of power purchased from the power source g at time t must be less than or equal to the amount of power that can be supplied by the power source g.

Equation (2-3) is an equation showing the constraint condition of the amount of power supplied for each power area of the power source whose type is "always backed up". BU _a indicates a set of power sources located in the power area a and whose type is "always backed up".

As shown in the formula (2-3), in the power area a, the amount of power purchased from the power source g at time t must be equal to or less than the amount of power demanded by the consumer d at time t.

Equation (2-4) is an equation showing the constraint condition of the upper limit of the tidal current of the interconnection line for each interconnection line and for each time.

P _flowmax (l) is a parameter for inputting an upper limit value of the tidal current of the interconnection line l (the amount of power flowing in or out of the interconnection line l to and from another power area). In the parameter P _flowmax (l), the amount of electric power available to the electric power retailer for each interconnection line l acquired from the interconnection line utilization planning database 123 shown in FIG. 6 is input by the calculation unit 113. Further, when electric power flows out to another electric power area through the interconnection line l, P _flow (l, t) takes a negative value, so -P _flowmax (l) is the tidal current. It becomes the lower limit value.

As shown in the formula (2-4), the amount of electric power flowing in or out from the interconnection line l at time t to and from other electric power areas can be used by the electric power retailer for each interconnection line l. Must be less than or equal to the amount of power.

The calculation unit 113 uses the above equations (1) and (2-1) to (2-4) to minimize the value of the objective function equation (1) for each simulation case, P _g (g). , T), P _Jb (a, t), P _Js (a, t), P _flow (l, t) are calculated. In other words, the calculation unit 113 determines the amount of electricity purchased for each power source that minimizes the electricity purchase cost during the evaluation period, the amount of electricity purchased for each time from the electricity market M, and the electricity market for each simulation case. The amount of electric energy sold to M for each time and the amount of electric energy (transmission amount) for each interconnection line flowing in or out of the other electric power areas are calculated.

For example, in each simulation case, the value of each variable is calculated multiple times until the value of the variable that minimizes the value of the equation (1), which is the objective function, is specified. The value of the variable that minimizes the cost is calculated as the solution.

The calculation unit 113 stores the calculation result for each simulation case in the storage unit 115 in association with the simulation case.

Further, the calculation unit 113 includes the calculated electric energy purchased for each power source at each time, the electric energy purchased from the electricity market M for each hour, the electric energy sold to the electricity market M for each hour, and other electric energy areas. From the electric energy (transmission amount) for each interconnection line that flows in and out between and the electric energy demand of the consumer d at the time t input in the _{parameter P d (d, t), in the evaluation target period.} Generate an electricity supply and demand plan.

FIG. 16 is a graph showing an example of a supply and demand plan for each simulation case according to the present embodiment. In the graph shown in FIG. 16, in one simulation case, the amount of power supplied to the consumer, the amount of power purchased from the power source, and the amount of power sold and sold between the power market M are shown for each power area. It is displayed.

The supply and demand plan shown in FIG. 16 is a one-day supply and demand plan during the evaluation target period. The horizontal axis of FIG. 16 indicates the time in 30-minute increments. The value "48" on the horizontal axis corresponds to 24 hours. The vertical axis represents the amount of electricity sold to consumers or the electricity market M, and the lower half indicates the amount of electricity purchased from the power source or the electricity market M, with the center as the boundary. In other words, the upper half of the vertical axis shows the demand for electricity, and the lower half of the vertical axis shows the supply of electricity.

Further, the supply and demand plan shown in FIG. 16 shows a supply and demand plan for a power area having a frequency of 50 Hz in a simulation case in which a customer and a power source located in a power area having a frequency of 50 Hz and a power area having a frequency of 60 Hz are selected. It is a thing. In addition to consumers and power sources located in the Tokyo area, Tohoku area, and Hokkaido area, which are power areas with a frequency of 50 Hz, interconnection lines supplied through interconnection lines from power sources located in power areas with a frequency of 60 Hz. The tide is shown. Further, as shown in FIG. 16, the amount of electric power to be bought and sold with the electric power market M is also included in the supply and demand plan.

As shown in FIG. 16, in the supply and demand plan, the amount of electricity demand and supply at each time coincides. According to the above equation (2-1), the amount of electricity purchased for each power source that satisfies the constraint that the supply and demand balance is matched, the amount of electricity purchased for each hour from the electricity market M, and the electricity market. This is because the amount of electricity sold to M for each time is calculated by the calculation unit 113.

Further, in the supply and demand plan shown in FIG. 16, the amount of electric power transmitted between different electric power areas is the amount of electric power that can be supplied from one electric power area to the other electric power area by each interconnection line by the electric power retailer. It will be less than the available power amount. According to the above equation (2-4), the calculation unit 113 determines the amount of purchased power for each interconnection line and for each time, and for each power source that satisfies the constraint condition of the upper limit of the tidal current of the interconnection line. This is because it has been calculated.

The calculation unit 113 performs simulations using the above equations (1) and (2-1) to (2-4) to satisfy the constraint conditions for each simulation case and then in the evaluation target period. It is possible to calculate a supply and demand plan that minimizes the cost of purchasing electricity.

The calculation unit 113 can calculate not only the power area shown in FIG. 16 but also the supply and demand plan for other power areas according to the simulation case.

Further, the display format of the supply and demand plan shown in FIG. 16 is an example, and is not limited to this. For example, the calculation unit 113 may generate a table, a list of numerical values, or the like instead of a graph. The calculation unit 113 stores the generated graph or the like in the storage unit 115 in association with the simulation case. Alternatively, the calculation unit 113 may generate a graph or the like when the reception unit 111 receives an operation from the user. The graph or the like generated by the calculation unit 113 is output to the display device 104 by the output unit 114 described above. Further, the output unit 114 may output a graph or the like to a printer or the like (not shown).

Then, the calculation unit 113 executes the following equations (3-1) to (3-3) for each simulation case, and calculates sales, profits, and expenses in the electric power retail business during the evaluation target period.

Equation (3-1) is an equation for calculating the profit of the electric power retail business during the evaluation target period. P is profit, S is sales (income), and E is expense (expenditure, cost).

Further, the formula (3-2) is a formula for calculating the sales in the evaluation target period.

SR is the sales that an electric power retailer obtains by selling electric power to consumers. Specifically, the calculation unit 113 is based on the basic charge and the metered charge registered in the selling price database 130 shown in FIG. 7 and the estimated power demand stored in the demand estimation database 131 shown in FIG. Then, the total value of the sales amount for each customer included in the simulation case is calculated. The calculation unit 113 inputs the total value of the calculated sales amounts into the SR.

SM is the sales obtained by an electric power retailer by selling electric power to the electric power market M. Specifically, the calculation unit 113 includes the assumed spot price stored in the assumed spot price database 151 shown in FIG. 12 and _{the value of PJs} (a, t) calculated by the equation (1) (time t). The total amount of sales to the electricity market M is calculated based on the amount of electricity sold to the electricity market M in the electricity area a). The calculation unit 113 inputs the calculated sales value to the SM.

Further, the formula (3-3) is a formula for calculating the cost in the evaluation target period.

EP is the cost (purchase amount, purchase amount) paid by an electric power retailer by purchasing electric power from a power source. Specifically, the calculation unit 113 includes the basic charge and the metered charge registered in the purchase price database 140 shown in FIG. 9 and _{the value of P g} (g, t) calculated by the formula (1) (at time t). The total value of the purchase price to be paid to each power source included in the simulation case is calculated based on the amount of power purchased from the power source g). The calculation unit 113 inputs the total value of the calculated power supply purchase amount into the EP.

EC is a consignment fee paid by a power retailer to a power transmission and distribution company in order to use the power grid. Specifically, the calculation unit 113 is based on the basic charge and the metered charge registered in the consignment database 150 shown in FIG. 11 and the estimated power demand stored in the demand estimation database 131 shown in FIG. , Calculate the transportation fee. The calculation unit 113 inputs the calculated transportation fee to the EC.

EM is a cost (purchase amount, purchase amount) paid by an electric power retailer by purchasing electric power from the electric power market M. Specifically, the calculation unit 113 includes the estimated spot price stored in the assumed spot price database 151 shown in FIG. 12 and _{the value of P Jb} (a, t) calculated by the equation (1) (time t). The total amount of purchases from the electricity market M is calculated based on the amount of electricity purchased from the electricity market M in the electricity area a). The calculation unit 113 inputs the total value of the calculated power supply purchase amount into the EM.

The above-mentioned method for calculating sales, profits, and expenses is an example, and the calculation unit 113 may further consider income, expenses, and the like other than those described above.

Then, the calculation unit 113 calculates the profit margin for each simulation case based on the calculated sales and the profit. The rate of return is the ratio of profit to sales.

The profit and the profit margin are examples of the electric power retail business evaluation index for evaluating the profitability of the electric power retail business in this embodiment. The electric power retail business evaluation index is not limited to this, and may be sales, expenses, or the like.

The calculation unit 113 stores the calculated profit margin for each simulation case in the storage unit 115 in association with the simulation case. Further, the calculation unit 113 generates a graph displaying the profit and the rate of return for each simulation case.

FIG. 17 is an example of a graph comparing the profitability of each simulation case according to the present embodiment. In the graph shown in FIG. 17, the horizontal axis represents profit and the vertical axis represents profit margin. In addition, the graph shown in FIG. 17 shows the difference between the profit and the profit margin with respect to the standard (the profit of the combination of the consumer and the power source in which the circle is entered in the "standard" and the profit margin) as the starting point. Points C1 to C7 indicating each simulation case (for example, point C1 is the profit and profit margin when the Tohoku area power supply 3 is added to the combination of the customer and the power supply in which the circle is entered in the "reference". The other points C2 to C7 also have the profit and the profit margin according to the combination of the consumer and the power source shown in the simulation case).

For example, in the simulation case indicated by point C1, both the profit and the rate of return are higher than the standard profit and rate of return of the simulation case. Further, in the simulation case indicated by point C7, both the profit and the rate of return are lower than the standard profit and the rate of return of the simulation case. The calculation unit 113 selects a more profitable combination of power sources and consumers for the electric power retailer by comparing the profit and the rate of return for each simulation case as shown in FIG. Can help.

In the prior art, changes in profitability due to differences in consumers were calculated. On the other hand, the electric power retail business evaluation device 1 of the present embodiment calculates the profit, the profit margin, and the like due to the difference in the power source, so that the profitability evaluation can be performed with higher accuracy. The electric power retail business evaluation device 1 of the present embodiment considers the upper limit of the transmission amount for each interconnection line as a constraint condition when electric power is transmitted between different electric power areas. Therefore, even when an electric power retailer conducts an electric power retail business including consumers or power sources located in a plurality of electric power areas, highly accurate profitability evaluation can be performed.

Further, since the electric power retail business evaluation device 1 of the present embodiment calculates the cost including the transportation fee (EC) in the calculation of the cost of the formula (3-3), the profitability evaluation based only on the electric power purchase cost. Compared with, more accurate profitability evaluation can be performed.

Further, the display format for comparing profitability for each simulation case shown in FIG. 17 is an example, and is not limited to this. For example, the calculation unit 113 may generate a table, a list of numerical values, or the like instead of a graph. The calculation unit 113 stores the generated graph or the like in the storage unit 115 in association with the simulation case. Alternatively, the calculation unit 113 may generate a graph or the like when the reception unit 111 receives an operation from the user. The graph or the like generated by the calculation unit 113 is output to the display device 104 by the output unit 114 described above. Further, the output unit 114 may output a graph or the like to a printer or the like (not shown).

Next, the flow of the generation processing of the simulation case of the present embodiment configured as described above will be described.

FIG. 18A is a flowchart showing an example of the flow of the simulation case generation process according to the present embodiment. The processing of this flowchart is started, for example, when the option "simulation case setting" of the menu screen shown in FIG. 13 is selected by the user and the setting screen shown in FIGS. 14 and 15 is displayed by the output unit 114.

First, the reception unit 111 receives inputs of a combination of a consumer to which the electric power retailer supplies electric power and a power source to which the electric power retailer purchases electric power (S1). The reception unit 111 sends the combination of the received consumer and the power supply to the case generation unit 112.

The case generation unit 112 generates a simulation case used in the simulation of the profit evaluation of the electric power retail business from the combination of the input consumer and the power source. Further, the case generation unit 112 stores the generated simulation case in the storage unit 115 (S2).

Next, the flow of the simulation process of the profitability evaluation of the present embodiment will be described. FIG. 18B is a flowchart showing an example of the flow of the simulation process of the profitability evaluation according to the present embodiment. The processing of this flowchart starts, for example, when the option "simulation execution" on the menu screen shown in FIG. 13 is selected by the user.

The calculation unit 113 selects the first simulation case from the plurality of simulation cases stored in the storage unit 115 (S11).

_{Then, the calculation unit 113 uses the parameters P gmax} (g), P _flowmax (l), and P _d (d) of the equations (1) and (2-1) to (2-4) based on the selected simulation case. , T), η _a, c _g (g, t), c _Jb (a, t), c _Js (a, t) are set to the values acquired from each database of the storage unit 115 (S12).

Next, the calculation unit 113 satisfies the constraint conditions of the equations (2-1) to (2-4), and then the variable P in which the value (electric power purchase cost) of the equation (1) which is the objective function is minimized. _{The values of g} (g, t), P _Jb (a, t), P _Js (a, t), and P _flow (l, t) are calculated (S13).

Further, the calculation unit 113 includes the calculated values of the variables P _g (g, t), P _Jb (a, t), P _Js (a, t), and P _flow (l, t), and the parameter P _d (d). , T), the supply and demand plan for each simulation case shown in FIG. 16 is generated based on the power demand of the consumer d at the time t (S14).

Next, the calculation unit 113 executes equations (3-1) to (3-3) for each simulation case, and calculates sales, profits, and costs in the electric power retail business during the evaluation target period (S15). ).

The calculation unit 113 includes the calculated values of the variables P _g (g, t), P _Jb (a, t), P _Js (a, t), and P _flow (l, t), and the data or graph of the supply and demand plan. , Sales, profits, and expenses are stored in the storage unit 115 in association with the simulation case (S16).

Here, the calculation unit 113 determines whether or not the simulation process has been completed for all the simulation cases (S17).

When the simulation process is not completed for all the simulation cases (S17 “No”), the calculation unit 113 selects the next simulation case (S18).

For all simulation cases, the calculation unit 113 repeats the processes of S12 to S18 until the simulation process is completed.

When the simulation process is completed for all the simulation cases (S17 “Yes”), the calculation unit 113 calculates the profit margin based on the sales and the profit of each simulation case (S19). Further, the calculation unit 113 generates a graph comparing the profitability of each simulation case as shown in FIG. 17 based on the profit and the rate of return. Further, the calculation unit 113 stores the calculated profit margin and the generated graph in the storage unit 115 in association with the simulation case.

The output unit 114 outputs the simulation result calculated by the calculation unit 113 to the display device 104 (S20). For example, the output unit 114 outputs a graph comparing the profit and the rate of return for each simulation case to the display device 104. Further, the output unit 114 may further output a graph showing a supply and demand plan for each simulation case.

In FIGS. 18A and 18B, the setting of the simulation case and the execution of the simulation process are started as separate processes, but the procedure of the process is not limited to this. For example, the setting of the simulation case and the execution of the simulation process may be continuously performed as a series of processes.

Further, in FIG. 18B, the calculation unit 113 performs the processing of calculating the profit margin of each simulation case (S19) after the loop processing (S12 to S18) for each simulation case is completed. The calculation of the rate may also be performed within the loop processing.

As described above, the storage unit 115 of the electric power retail business evaluation device 1 of the present embodiment stores the demand estimation database 131, the purchase price database 140, and the power supply amount database 141. Further, the reception unit 111 receives an input of a combination of the consumer and the power supply. Then, the output unit 114 transfers the electric power purchased from the power source included in the combination to the customer included in the combination based on the combination of the consumer and the power source and the data of the database stored in the storage unit 115. The profit and profit margin in the case of sale are output as an electric power retail business evaluation index for evaluating the profitability of the electric power retail business. Therefore, according to the electric power retail business evaluation device 1 of the present embodiment, it is possible to evaluate the profitability of the electric power retail business with higher accuracy.

Further, the storage unit 115 of the electric power retail business evaluation device 1 of the present embodiment stores the electric power area where the consumer is located in the selling price database 130, and stores the electric power area where the power source is located in the purchase price database 140. , The amount of electric power demanded for each consumer, the purchase price of the electric power for each power source, and the amount of electric power that can be supplied for each power source are stored for each region. Further, the storage unit 115 stores the interconnection line usage plan data and the consignment charge for each power area related to the power supply. Therefore, according to the electric power retail business evaluation device 1 of the present embodiment, it is possible to perform highly accurate profitability evaluation even for an electric power retail business including consumers or power sources located in a plurality of electric power areas.

Further, the output unit 114 of the electric power retail business evaluation device 1 of the present embodiment has the smallest value of the electric power purchase cost among the electric power purchase costs calculated a plurality of times by changing the amount of electric power purchased from the power source included in the combination. In this case, the purchased power amount for each power source and the power transmission amount for each interconnection line are output. However, it is not limited to the output when the power purchase cost is minimized, and the amount of power purchased for each power source when the value of the power purchase cost is smaller and the amount of power transmitted for each interconnection line are output. Is also good.

The output unit 114 of the electric power retail business evaluation device 1 of the present embodiment includes the electric power demand for each consumer stored for each electric power area, the purchase price of the electric power for each power source, and the electric energy that can be supplied for each power source. , Of the power purchase costs calculated multiple times by changing the amount of power purchased from the power sources included in the combination based on the interconnection line usage plan data, for each power source when the value of the power purchase cost is smaller Outputs the amount of purchased power and the amount of power transmitted for each interconnection line. Therefore, according to the electric power retail business evaluation device 1 of the present embodiment, it is possible to output a supply and demand plan in which the electric power purchase cost becomes smaller.

Further, the storage unit 115 of the electric power retail business evaluation device 1 of the present embodiment further stores the assumed spot price for each time in the electric power market M, and the output unit 114 is included in the combination of the consumer and the power source. When the electric power purchased from the power source or the electric power market M is sold to the consumers or the electric power market M included in the combination, the profit and the profit margin are output as the electric power retail business evaluation index. Therefore, according to the electric power retail business evaluation device 1 of the present embodiment, it is possible to evaluate the profit and the profit margin including the electric power sales transaction with the electric power market M, so that the profitability is more accurate. Can be evaluated.

In the present embodiment, the electric power retailer has described that the electric power is supplied from the electric power source to the consumer across a plurality of electric power areas, but the present invention is not limited to this. For example, the electric power retail business evaluation device 1 of the present embodiment can be applied to an electric power retailer that supplies electric power from a power source to a consumer in one electric power area.

(Embodiment 2)
In the electric power retail business evaluation device 1 of the above-described first embodiment, the profitability is evaluated on the premise that the electric power retailer sells the electric power purchased from the power source or the electric power market M to the consumer or the electric power market M. I was doing a simulation. The electric power retail business evaluation device 1 of the present embodiment further performs a simulation for evaluating the profitability when the electric power retailer installs the distributed power source in the customer or the power source.

FIG. 19 is a diagram showing an example of the distributed power source according to the second embodiment. The distributed power source in this embodiment is a PV (Photovoltaics, photovoltaic power generation device) or a storage battery. As shown in FIG. 19, the electric power retailer installs the PV 50 or the storage battery 51 in the consumer 4.

The electric power transmitted from the power source by the transmission line 41 shown in FIG. 19 is reduced to a predetermined voltage by the transformer 40 and then supplied to the consumer 4 through the distribution line 42. The PV 50 and the storage battery 51 are installed on the customer 4 side of the transformer 40. The electric power generated by the PV 50 and the electric power discharged from the storage battery 51 are supplied to the consumer 4 through the distribution line 42. Further, the storage battery 51 acquires at least one or more of the electric power transmitted from the power source by the transmission line 41 and the electric power generated by the PV 50 through the distribution line 42 and stores the electric power. The electric power transmitted from the power source includes the electric power purchased from the electric power market M.

In FIG. 19, both the PV 50 and the storage battery 51 are installed for the consumer 4, but only one of them may be installed.

Further, in FIG. 19, although the distributed power source is installed for the consumer 4, the storage battery 51 may be installed on the power source side. However, in this embodiment, it is not assumed that the PV50 is installed on the power supply side.

When the electric power retailer uses the transmission line 41 to supply electric power to the consumer 4, a consignment fee is incurred. On the other hand, when the electric power retailer uses the distribution line 42 to supply electric power to the consumer 4, no consignment fee is incurred. Therefore, by installing the distributed power source in the customer 4, the transportation fee paid by the electric power retailer is reduced. Further, by installing the storage battery 51 in the power source, the storage battery 51 is stored in a time zone when the power demand is low (or a time zone when the purchase price of the power is cheaper than other time zones), and the power demand is large. By using the stored electric power in the time zone, the purchase cost of the electric power is reduced.

By installing distributed power sources in this way, the profitability of the electricity retail business will change. Therefore, the electric power retail business evaluation device 1 of the present embodiment performs a simulation for evaluating the profitability of the electric power retail business when a distributed power source is installed as shown in FIG.

Further, the electric power retail business evaluation device 1 of the present embodiment can execute two types of profitability evaluation simulations. The first is a simulation to evaluate the profitability of the electricity retail business, including the incremental profit from the installation of distributed power sources. The second is the cost to recover the purchase price (initial investment, initial cost) of the distributed power source when the distributed power source is installed, in addition to the incremental profit from the installation of the distributed power source, and the initial investment. This is a simulation for evaluating the time required for collection. Hereinafter, the first simulation will be referred to as a first simulation, and the second simulation will be referred to as a second simulation.

Next, the configuration of the electric power retail business evaluation device 1 in the present embodiment will be described. The hardware configuration of the electric power retail business evaluation device 1 is the same as the hardware configuration of the first embodiment described with reference to FIG.

FIG. 20 is a block diagram showing an example of the functional configuration of the electric power retail business evaluation device 1 according to the present embodiment. As shown in FIG. 20, the electric power retail business evaluation device 1 of the present embodiment includes a reception unit 1111, a case generation unit 1112, a calculation unit 1113, an output unit 1114, and a storage unit 1115.

The storage unit 1115 is composed of, for example, the HDD 103. The storage unit 115 includes a power area database (DB) 121, an interconnection line database (DB) 122, an interconnection line utilization plan database (DB) 123, a selling price database (DB) 130, and a demand estimation database (DB). ) 131, purchase price database (DB) 140, power supply database (DB) 141, consignment database (DB) 150, assumed spot price database (DB) 151, PV attribute database (DB) 171 and The PV assumed output ratio database (DB) 172 and the storage battery attribute database (DB) 173 are stored.

Power area database 121, interconnection line database 122, interconnection line usage plan database 123, selling price database 130, demand estimation database 131, purchase price database 140, power supply amount database 141, consignment database 150 And the assumed spot price database 151 is the same as that of the first embodiment.

Further, the PV attribute database 171, the PV estimated output ratio database 172, and the storage battery attribute database 173 are examples of information on power supply by a distributed power source installed in a consumer or a power source in the present embodiment.

FIG. 21 is a diagram showing an example of the table configuration of the PV attribute database 171 according to the present embodiment. As shown in FIG. 21, the PV attribute database 171 has a PV No. , And the estimated price for each PV50 and the amortization period are stored in association with each other.

The item "PVNo." Is a number for identifying the PV50. The PV attribute database 171 is not limited to the number, and may store a code or the like that can identify the PV50.

The item "estimated price" is an item in which the estimated purchase price per 1 kW of the rated capacity of the PV50 is registered. The assumed price is an example of the initial cost of the distributed power source in this embodiment.

The item "depreciation period" is an item in which the accounting depreciation period of PV50 is registered. The depreciation period may be, for example, the statutory useful life specified in the depreciation of fixed assets.

FIG. 22 is a diagram showing an example of the table configuration of the PV assumed output ratio database 172 according to the present embodiment. As shown in FIG. 22, the PV estimated output ratio database 172 stores the date, the time, and the PV estimated output ratio for each power area in association with each other.

The PV estimated output ratio is the ratio of the amount of power generation that the PV50 is expected to generate to the rated capacity of the PV50. The unit of the PV assumed output ratio is kWh / kWh.

The rated capacity of the PV50 is the maximum amount of power that the PV50 can generate. The rated capacity of the PV50 is set by the user at the time of executing the simulation described later. Alternatively, the rated capacity of the PV50 is calculated by the calculation unit 1113, which will be described later. Details of the rated capacity will be described later.

The dates and times set in the items "date" and "time" shown in FIG. 22 are future dates and times. Further, the date and time is an evaluation target period for evaluating the profitability of the electric power retail business of the simulation executed by the calculation unit 1113 described later.

Further, the PV estimated output ratio differs depending on the power area in which the PV50 is installed. This is because the sunshine conditions and the like differ depending on the region. For example, the PV estimated output ratio of "Hokkaido area PV1" in 30 minutes between the time "4:30" and "5:00" on the date "2016/4/1" is "0.009kWh / kW". ..

The power area in which each PV50 is installed is input by the user from the setting screen described later.

The PV estimated output ratio data stored in the PV estimated output ratio database 172 may be, for example, the one obtained by changing the date of the PV output ratio data one year ago, or the one calculated in advance based on factors such as the weather. It may be.

FIG. 23 is a diagram showing an example of the table configuration of the storage battery attribute database 173 according to the present embodiment. As shown in FIG. 23, the storage battery attribute database 173 shows the storage battery No. , The charge rate for each storage battery 51, the discharge rate, the assumed price, and the amortization period are stored in association with each other.

The item "storage battery No." is a number for identifying the storage battery 51. The storage battery attribute database 173 is not limited to the number, and may store a code or the like that can identify the storage battery 51.

The item "charging rate" is an item in which the charging rate of the storage battery 51 is registered. The charging rate is the relative ratio of the charging current to the battery capacity. The larger the charging rate value of the storage battery 51, the faster the charging can be performed.

The item "discharge rate" is an item in which the discharge rate of the storage battery 51 is registered. The discharge rate is the relative ratio of the current at the time of discharge to the battery capacity.

The item "estimated price" is an item in which the estimated purchase price per 1 kW of the rated capacity of the storage battery 51 is registered. The assumed price is an example of the initial cost of the distributed power source in this embodiment.

The item "depreciation period" is an item in which the accounting depreciation period of the storage battery 51 is registered. The depreciation period may be, for example, the statutory useful life specified in the depreciation of fixed assets.

The data and values stored in the PV attribute database 171, the PV estimated output ratio database 172, and the storage battery attribute database 173 described above are examples, and are not limited thereto.

Returning to FIG. 20, the output unit 1114 of the present embodiment has the same functions as that of the first embodiment, and displays a setting screen for setting a combination of the customer to be simulated, the power supply, and the distributed power supply. Output to device 104. The details of the setting screen will be described later in the description of the case generation unit 1112.

Further, the output unit 1114 of the present embodiment outputs a selection screen as to whether to execute the above-mentioned first simulation or the second simulation to the display device 104. For example, a function capable of specifying either the first simulation or the second simulation may be added to the menu screen of the first embodiment shown in FIG.

Further, the output unit 1114 of the present embodiment has the fluctuation amount (incremental profit) of the profit due to the installation of the distributed power source in the evaluation target period calculated by the calculation unit 1113 described later, and the rated capacity of the distributed power source in which the profit increases. And the recovery period of the initial cost for installing the distributed power source.

Returning to FIG. 20, the reception unit 1111 of the present embodiment has the same functions as that of the first embodiment, and receives the input of the combination of the consumer, the power supply, and the distributed power supply. Specifically, the reception unit 1111 receives the input of the combination of the consumer, the power supply, and the distributed power supply input to the setting screen output to the display device 104 by the output unit 1114. Further, the reception unit 1111 receives the pattern of the combination of the distributed power sources input to the setting screen output to the display device 104 by the output unit 1114 and the rated capacity of the distributed power sources. The details of the setting screen will be described later in the description of the case generation unit 1112.

In addition, the reception unit 1111 accepts the user's selection as to whether to execute the above-mentioned first simulation or the second simulation.

The case generation unit 1112 of the present embodiment has the same functions as that of the first embodiment, and further includes a combination of a consumer, a power source, and a distributed power source received by the reception unit 1111 and a combination pattern of the distributed power source. Generate a simulation case from.

FIG. 24 is a diagram showing an example of a setting screen for setting a combination of the power source to be simulated and the distributed power source according to the present embodiment. The “power supply No.”, “power supply name”, “reference”, and “addition / deletion” shown in FIG. 24 are the same as those of the power supply setting screen of the first embodiment described with reference to FIG. The setting screen for setting the combination of the power source to be simulated and the distributed power source in the present embodiment (hereinafter referred to as the power supply and the distributed power source setting screen) is added to the input field of the power supply setting screen of the first embodiment. , Includes input field "distributed power supply".

The input field "distributed power supply" on the power supply and distributed power supply setting screen shown in FIG. 24 is an item that accepts the setting of the power supply for which the distributed power supply is installed. For example, if the user inputs a circle in the input field "distributed power supply" in any line of the power supply and distributed power supply setting screen, the distributed power supply is installed in the power supply corresponding to the line. Is accepted by the reception unit 1111 described later. In the example shown in FIG. 24, since no circle is input in any of the lines, it is shown that the distributed power source is not installed in the power source.

Further, FIG. 25 is a diagram showing an example of a setting screen for setting a combination of the customer to be simulated and the distributed power source according to the present embodiment. The “customer No.”, “customer name”, “standard”, and “addition / deletion” shown in FIG. 25 are the same as the customer setting screen of the first embodiment described with reference to FIG. The setting screen for setting the combination of the customer to be simulated and the distributed power source in the present embodiment (hereinafter referred to as the customer and the distributed power source setting screen) is an input field of the customer setting screen of the first embodiment. In addition, the input field "distributed power supply" is included.

The input field "distributed power source" of the setting screen of the consumer and the distributed power source shown in FIG. 25 is a field for accepting the setting of the customer who installs the distributed power source. For example, in the example shown in FIG. 25, a combination in which a distributed power source is installed in "Tokyo area consumer 2" is accepted by the reception unit 1111 described later.

Further, FIG. 26 is a diagram showing an example of a setting screen for setting a pattern of combinations of distributed power sources according to the present embodiment. As shown in FIG. 26, the setting screen for setting the pattern of the combination of the distributed power sources includes a display field "pattern", an input field "PV No.", and a "storage battery No.".

The display column "pattern" is a column in which the number of combinations of distributed power sources is displayed. The output unit 1114 may display a number according to the number of combinations entered by the user on the setting screen shown in FIG. 26. Alternatively, the number up to the upper limit of the number of patterns that can be set by the user in advance may be displayed in the display field "pattern" by the output unit 1114.

The input fields "PV No." and "storage battery No." are fields for accepting a combination of the PV 50 and the storage battery 51 to be introduced as a distributed power source. In the present embodiment, a pattern is set for each of the combinations. PVNo. Is a type of PV50 to be introduced as a distributed power source, and corresponds to "PVNo." In the PV attribute database 171 shown in FIG. Storage battery No. Is a type of storage battery 51 to be introduced as a distributed power source, and corresponds to "storage battery No." in the storage battery attribute database 173 shown in FIG. 23.

For example, “Pattern 1” shown in FIG. 26 refers to PVNo. The PV50 of "1" and the storage battery No. 2 shown in FIG. 23. The combination with the storage battery 51 of "1" is a pattern introduced as a distributed power source. Each pattern does not always have to include both the PV 50 and the storage battery 51, and the storage battery No. And PVNo. Only one of the above may be set.

In the power supply and distributed power supply setting screens shown in FIGS. 24 and 25, the power supply set on the consumer and distributed power supply setting screens, or the combination of distributed power sources with consumers, the type of distributed power source (PV50 or PV50 or The storage battery 51) has not been specified. Therefore, the combination of the types of distributed power sources to be combined with each power source or the consumer is set according to the pattern set on the setting screen shown in FIG. 26. In this embodiment, a simulation is performed for each of the patterns (combinations of distributed power sources) set in FIG. 26.

Further, FIG. 27 is a diagram showing an example of a setting screen for setting the rated capacity of the distributed power source according to the present embodiment. As shown in FIG. 27, the setting screen includes a display field "PV / storage battery No.", an input field "PV capacity", and a "storage battery capacity".

The display column "PV / storage battery No." is an item in which the PV attribute database 171 shown in FIGS. 21 and 23 and the "PV No." and "storage battery No." of the storage battery attribute database 173 are displayed by the output unit 1114, respectively. Is.

The input field "PV capacity" is the PV No. set in "PV / storage battery No.". It is a column which accepts the setting of the rated capacity of PV50 identified by. In addition, the input field "storage battery capacity" is the storage battery No. set in "PV / storage battery No.". This column accepts the setting of the rated capacity of the storage battery 51 identified by. By inputting the rated capacities of the PV 50 and the storage battery 51 on the setting screen, the user can freely set the rated capacities and obtain the result of a simulation for evaluating profitability.

In the present embodiment, the setting screens shown in FIGS. 24 to 27 have been described as individual screens, but these may be displayed on the same screen. Further, the configuration of the setting screen shown in FIGS. 24 to 27 is an example, and if the screen allows the user to set a simulation case for the combination of the power supply, the consumer, and the distributed power supply, the display field and the input field are set to these. It is not limited.

Returning to FIG. 20, the calculation unit 1113 of the present embodiment executes a simulation based on the generated simulation case, and calculates an electric power retail business evaluation index for evaluating the profitability of the electric power retail business. Specifically, the calculation unit 1113 is an optimization model (optimization problem) for minimizing the power purchase cost of the power retail business when the reception unit 1111 notifies that the user has performed the simulation execution operation. Execute a simulation using the objective function of. The electric power purchase cost of the electric power retail business is an example of the electric power purchase cost in the present embodiment.

Further, in the present embodiment, the calculation unit 1113 evaluates the profitability of the electric power retail business including the change in profitability when the distributed power source is installed in the power source or the consumer based on the generated simulation case. Calculate the electricity retail business evaluation index.

The calculation unit 1113 uses the following equations (4-1) or (4-2) and equations (5-1) to (5-17) in the simulation.

Specifically, the calculation unit 1113 minimizes the value of the objective function of the equation (4-1) or the equation (4-2) under the constraint conditions shown in the equations (5-1) to (5-17). Solve the optimization problem (linear programming problem) to be converted. For example, the calculation unit 1113 may use a method such as a unit method or an interior point method.

In the description of equations (4-1) and (4-2), the same variables and parameters as those of equations (1) and (2-1) to (2-4) of the first embodiment will be omitted. ..

_P PV of formula _{(4-1) (d, t)} , P rest (d, t), Q dchg (d, t), Q ddis (d, t) is a variable which is a solution of the optimization problem.

The variable P _PV (d, t) is the amount of power generation output of the PV 50 installed in the consumer d at time t.

The variable _Present (d, t) is the output suppression power of the PV50 installed in the consumer d at time t. The output suppression power is the power required to suppress the power output from the PV 50 from being transmitted to the transmission line 41 beyond the transformer 40 shown in FIG. The fact that the electric power output from the PV 50 exceeds the transformer 40 shown in FIG. 19 and is transmitted to the transmission line 41 is called "reverse power flow", and the electric power retailer is a distributed type so as not to generate a reverse power flow. The amount of power output must be controlled.

The variable Q _dchg (d, t) is the amount of charging power of the storage battery 51 installed in the customer d at time t.

The variable Q _ddis (d, t) is the amount of discharged power at time t of the storage battery 51 installed in the customer d.

_{P PV (d, t),} P rest (d, t), the unit of the value of _{Q dchg (d, t),} Q ddis (d, t) is a kWh.

Further, c _w (d) is a parameter in which the unit price per 1 kWh of the consignment charge of the consumer d is input by the calculation unit 1113. The calculation unit 1113 inputs the unit price per 1 kWh of the metered charge of the consignment charge acquired from the consignment database 150 shown in FIG. 11 into c _w (d).

_{W PV} (d), W _SBd (d), and W _SBg (g) of the equation (4-2) are variables that are solutions to the optimization problem.

The variable W _PV (d) is the rated capacity of the PV 50 installed in the customer d. Further, the variable W _SBd (d) is the rated capacity of the storage battery 51 installed in the customer d. The variable _WSB (g) is the rated capacity of the storage battery 51 installed in the power source g. In the second simulation using the equation (4-2), the rated capacity of the distributed power source is output as the solution of the optimization problem by the calculation unit 1113, so that the distribution set on the setting screen shown in FIG. 27 is used. The rated capacity of the type power supply is not used.

_{Further, C PV} , C _SB , T _PV , T _SB , and T in the equation (4-2) are parameters that accept the input of the value by the calculation unit 1113.

The parameter C _PV is an assumed price of the PV 50 registered in the PV attribute database 171 shown in FIG.

The parameter C _SB is an assumed price of the storage battery 51 registered in the storage battery attribute database 173 shown in FIG. 23.

The parameter T _PV is the amortization period of PV 50 registered in the PV attribute database 171 shown in FIG.

The parameter T _SB is the amortization period of the storage battery 51 registered in the storage battery attribute database 173 shown in FIG. 23.

Parameter T is an evaluation target period for evaluating the profitability of the electric power retail business. For example, the evaluation target period is input to the parameter T on a yearly basis.

Equations (4-1) and (4-2) are both objective functions that indicate the amount of electricity purchase costs in the electricity retail business. The calculation unit 1113 uses the equation (4-1) in the first simulation and the equation (4-2) in the second simulation.

Equation (4-1) is an equation showing the value of the electricity purchase cost of the electricity retail business including the amount of change in the payment amount of the transportation fee during the evaluation target period due to the installation of the distributed power source.

On the other hand, the formula (4-2) is, in addition to the formula (4-1), the power purchase cost of the power retail business including the investment recovery cost of the initial cost for installing the distributed power source during the evaluation target period. It is an expression showing a value.

First, the equation (4-1) will be described. The first and second terms of the formula (4-1) are the same as those of the formula (1) of the first embodiment. The third term of the formula (4-1) shows the amount of change in the payment amount of the transportation fee due to the installation of the distributed power source during the evaluation target period.

Next, the equation (4-2) will be described. The first and second terms of the formula (4-2) are the same as those of the formula (1) of the first embodiment. The fifth term of the equation (4-2) is the same as the third term of the equation (4-1).

The third term of the formula (4-2) indicates the total value of the investment recovery cost in the evaluation target period of the storage battery 51 installed in each power source. The return on investment cost is the amount required per year to recover the investment cost (initial investment of the distributed power source) during the amortization period of the distributed power source. The fourth item of the formula (4-2) is the investment recovery cost in the evaluation target period of the PV50 installed in each customer and the investment recovery cost in the evaluation target period of the storage battery 51 installed in each customer. Shows the total value of.

Next, equations (5-1) to (5-17) will be described.

Hereinafter, the variables and parameters included in the equations (5-1) to (5-17) will be described. The same variables and parameters as those of the formula (1) and the formulas (2-1) to (2-4), the formula (4-1), and the formula (4-2) of the first embodiment will not be described.

S _d (d, t), Q _gchg (g, t), Q _gdis (g, t), and S _g (g, t) are variables that solve the optimization problem.

The variable S _d (d, t) is the remaining charge of the storage battery 51 installed in the customer d at time t. The variable Q _gchg (g, t) is the amount of charging power at time t of the storage battery 51 installed in the power source g. The variable Q _gdis (g, t) is the amount of discharged power at time t of the storage battery 51 installed in the power source g. The variable S _g (g, t) is the remaining amount of electricity stored in the storage battery 51 installed in the power source g at time t.

Further, P _cont (d), η _chg , η _dis , R _chg , R _dis , and η _PV (t) are parameters that accept input of values by the calculation unit 1113.

The parameter P _cont (d) is the contracted electric energy of the consumer d. Calculator 1113 inputs the contracted power amount of the customer d obtained from the selling price database 130 shown in FIG. 7 to the parameter _{P cont} (d).

The parameter η _chg is the charge loss rate of the storage battery 51. The parameter η _dis is the discharge loss rate of the storage battery 51. The values of the charge loss rate and the discharge loss rate of the storage battery 51 may be determined by constants, or may be further registered in the storage battery attribute database 173 shown in FIG. 23.

Further, the parameter R _chg is a charging rate for each storage battery 51. Further, the parameter R _dis is a discharge rate for each storage battery 51.

The parameter η _PV (t) is the power generation output ratio to the rated capacity at time t for each PV50. The calculation unit 1113 inputs the power generation output ratio acquired from the PV estimated output ratio database 172 shown in FIG. 22 into the parameter η _PV (t).

Further, as described above, when the calculation unit 1113 executes the second simulation by the equation (4-2), W _PV (d), W _SBd (d), and W _SBg (g) are variables. .. On the other hand, when the calculation unit 1113 executes the first simulation process according to the equation (4-1), the values of W _PV (d), W _SBd (d), and W _SBg (g) are input by the calculation unit 1113. Is a parameter that accepts. In this case, the value of the rated capacity of the PV 50 set on the setting screen shown in FIG. 27 is input to _{the W PV (d) by the calculation unit 1113.} Further, in W _SBd (d) and W _SBg (g), the value of the rated capacity of the storage battery 51 set on the setting screen shown in FIG. 27 is input by the calculation unit 1113.

Equation (5-1) is an equation showing a constraint condition that the supply and demand balance for each power area matches. Further, the equation (5-2) is an equation showing a constraint condition that reverse power flow is not generated for each customer and each time. Equation (5-3) is an equation showing a constraint condition for limiting the contracted electric energy for each consumer and each time.

Further, the formula (5-5) is a formula showing the constraint condition of the capacity of the storage battery 51 installed on the power supply side for each storage battery 51 and for each time. Equation (5-6) is an equation showing the constraint conditions according to the energy conservation law of the storage battery 51 installed on the power supply side for each storage battery 51 and for each time. Equation (5-7) is an equation showing the constraint condition of the discharge power amount of the storage battery 51 installed on the power supply side for each storage battery 51 and for each time. Equation (5-8) is an equation showing the constraint condition of the charge power amount of the storage battery 51 installed on the power supply side for each storage battery 51 and for each time.

Further, the equation (5-9) is an equation showing the constraint condition that the forward flow of the storage battery 51 is not possible for each storage battery 51 and for each time. The restriction that forward flow is not possible means that the value obtained by subtracting the amount of electric power to be discharged from the amount of electric power to be charged per time unit of the storage battery 51 exceeds the amount of electric power generated per time unit of the power source in which the storage battery 51 is installed. It is a constraint that it should not be done.

Equation (5-12) is an equation showing the constraint condition of the capacity of the PV50 installed on the consumer side for each PV50 and for each time. Further, the equation (5-13) is an equation showing the constraint condition of the suppressed power amount of the PV50 installed on the consumer side for each PV50 and for each time.

Further, the formula (5-14) is a formula showing the constraint condition of the capacity of the storage battery 51 installed on the consumer side for each storage battery 51 and for each time. Further, the equation (5-15) is an equation showing the constraint conditions according to the energy conservation law of the storage battery 51 installed on the consumer side for each storage battery 51 and for each time. Equation (5-16) is an equation showing the constraint condition of the discharge power amount of the storage battery 51 installed on the consumer side for each storage battery 51 and for each time. Equation (5-17) is an equation showing the constraint condition of the amount of charging power of the storage battery 51 installed on the consumer side.

Further, the formula (5-4), the formula (5-10), and the formula (5-11) are the formulas (2-2), (2-3), and (2-4) of the embodiments, respectively. ), So the description will be omitted.

The calculation unit 1113 minimizes the value of the objective function of the equation (4-1) or the equation (4-2) under the constraint conditions shown in the above equations (5-1) to (5-17). To calculate the value of the variable. Further, the calculation unit 1113 stores the calculation result for each simulation case in the storage unit 115 in association with the simulation case.

Further, the calculation unit 1113 uses the calculated variables P _g (g, t), P _Jb (a, t), P _Js (a, t), P _flow (l, t), P _PV (d, t), and the like. _{P rest (d, t),} Q dchg (d, t), Q ddis (d, t), S d (d, t), Q gchg (g, t), Q gdis (g, t), S g The values of (g, t), W _PV (d), W _SBd (d), and W _SBg (g), the amount of power demanded by the consumer d at the time t input to the _{parameter P d (d, t), and} Generate a power supply and demand plan for each simulation case during the evaluation period. In addition to the supply and demand plan of the first embodiment, the calculation unit 1113 of the present embodiment includes the amount of power generated by the PV50 at each time, the output suppression power, the amount of power charged and discharged by the storage battery 51, and the like.

Then, the calculation unit 1113 calculates the sales, the profit, and the cost in the electric power retail business in the evaluation target period for each simulation case by the formulas (3-1) to (3-3) described in the first embodiment.

Further, as described above, the calculation unit 1113 of the present embodiment calculates the incremental profit for each simulation case due to the installation of the distributed power source by the above formula (4-1) or formula (4-2). To do. For the incremental profit, the case where the optimization problem is solved under the condition that the distributed power supply is not installed after using the equation (4-1) or the equation (4-2) as the objective function for solving the optimization problem. , The difference between the value of the objective function and the case where the optimization problem is solved under the condition that the distributed power supply is installed. For example, in the case of the first simulation, by installing a distributed power source, the payment amount of the transportation fee is reduced and an incremental profit is generated. Further, in the case of the second simulation, since the investment cost of the distributed power source (initial investment of the distributed power source) is included in advance as the power purchase cost, the incremental profit is the amount excluding the investment cost of the distributed power source. ..

FIG. 28 is an example of a table showing the incremental profits assumed for each combination pattern of the distributed power sources according to the present embodiment when the first simulation process is executed by the above equation (4-1). As shown in FIG. 28, the calculation unit 1113 has the incremental profit assumed for each combination pattern of the PV 50 and the storage battery 51 set on the setting screen shown in FIG. 26, and the PV 50 or the PV 50 corresponding to the increase amount of the incremental profit. A table showing the rated capacity of the storage battery 51 is generated. For example, in the pattern “1” in FIG. 26, “PV No.” is “1” and “storage battery No.” is “1”. Therefore, in the table, the estimated price "250,000 / kW" when "PV No." is "1" and the estimated price "200,000 / kW" when "storage battery No." is "1". In the case of "kWh" (Fig. 23), the incremental profit (3 million yen / year), the rated capacity of PV50 (150kW), the rated capacity of the storage battery 51 (10kWh), and the investment amount (PV250,000 yen / kWh x). 150 kW + storage battery 200,000 yen / kWh x 10 kWh = 39.5 million yen) is displayed. Other columns of the table shown in FIG. 28 are also not described as they are assigned according to the pattern.

Since the example shown in FIG. 28 shows the incremental profit when the distributed power source is installed in one consumer, the calculation unit 1113 generates the table for each consumer. Further, when a distributed power source is installed as a power source, the calculation unit 1113 generates a table displaying the incremental profit displaying only the storage battery 51 and the rated capacity.

Further, the calculation unit 1113 of the present embodiment calculates the investment payback period of the distributed power source in the evaluation target period for each simulation case when the first simulation process is executed by the above equation (4-1). .. Specifically, in the calculation unit 1113, the cumulative amount of the incremental profit becomes the same as the amount of the investment cost based on the investment cost of the distributed power source calculated by the formula (4-1) and the calculated incremental profit. Calculate the number of years.

In the present embodiment, in addition to the profit and the rate of return, the incremental profit from the installation of the decentralized power source and the investment payback period of the decentralized power source are used as an electric power retail business evaluation index for evaluating the profitability of the electric power retail business. To do.

For example, the calculation unit 1113 may generate a graph showing the payback period. FIG. 29 shows the case of pattern “1” in FIG. 26 as an example of a graph showing the payback period according to the present embodiment. As shown in FIG. 29, the initial investment amount (investment recovery cost) when a distributed power source having a rated capacity of PV150 kW and a storage battery of 10 kWh is installed in a customer is 39.5 million yen as shown in FIG. 28. In the simulation case, the calculation unit 1113 calculates that the incremental profit is 3 million yen per year. In this case, as shown in FIG. 29, the payback period is 13.2 years.

Further, the calculation unit 1113 may generate a table for comparing the payback period for each pattern of the combination of the PV 50 and the storage battery 51. FIG. 30 is an example of a table showing the payback period for the present embodiment. As shown in FIG. 30, the calculation unit 1113 generates a table displaying the number of years of the calculated return on investment for each combination pattern of the PV 50 and the storage battery 51 set on the setting screen shown in FIG. 26.

Further, FIG. 31 is another example of a graph showing the payback period according to the present embodiment. The “PV unit price” on the horizontal axis shown in FIG. 31 is an assumed price for each PV50 registered in the PV attribute database 171 shown in FIG. The "storage battery unit price" on the axis in the depth direction shown in FIG. 31 is an assumed price for each storage battery 51 registered in the storage battery attribute database 173 shown in FIG. 23. The “investment payback period” on the vertical axis shown in FIG. 31 is the number of years of the investment payback period calculated by the calculation unit 1113.

Further, FIG. 32 is another example of a table showing the incremental profits assumed for each combination pattern of the distributed power sources according to the present embodiment. Specifically, FIG. 32 shows the incremental profit expected for each combination pattern of the distributed power sources according to the present embodiment when the second simulation process is executed by the above equation (4-2). .. As shown in FIG. 32, the calculation unit 1113 sets the total value of the incremental profits in the evaluation target period calculated for each combination pattern of the PV 50 and the storage battery 51 set on the setting screen shown in FIG. 26, and the incremental profits. Generate a table showing the capacity of the PV 50 or battery 51 corresponding to the increased amount. For example, in the pattern “1” in FIG. 32, “PV No.” is “1” and “storage battery No.” is “1”. Therefore, in the table, the estimated price "250,000 / kW" when "PV No." is "1" and the estimated price "200,000 / kW" when "storage battery No." is "1". The incremental profit (0 yen) in the case of "kWh" (FIG. 23), the optimum capacity of the PV50 (0kW), and the optimum capacity of the storage battery 51 (0kWh) are displayed. The other columns of the table shown in FIG. 32 are also not described as they are assigned according to the pattern.

In the above formula (4-2), the investment cost of the distributed power source is included in advance as the power purchase cost. Therefore, in FIG. 32, the amount of incremental profit excluding the initial investment amount is displayed.

Since the example shown in FIG. 32 shows the incremental profit when the distributed power source is installed in one consumer, the calculation unit 1113 generates the table for each consumer. Further, when a distributed power source is installed as a power source, the calculation unit 1113 generates a table displaying the incremental profit displaying only the storage battery 51 and the rated capacity.

Further, the calculation unit 1113 may generate a graph comparing the profitability of each simulation case based on the profit and the rate of return, as in the first embodiment.

The calculation unit 1113 stores the generated graphs or tables shown in FIGS. 28 to 32 in the storage unit 1115 in association with the simulation case. Alternatively, the calculation unit 1113 may generate a graph or the like when the reception unit 1111 receives an operation from the user. The graph or the like generated by the calculation unit 1113 is output to the display device 104 by the output unit 1114 described above. Further, the output unit 1114 may output a graph or the like to a printer or the like (not shown).

The display formats of the graphs and tables shown in FIGS. 28 to 32 are examples, and the display format is not limited thereto.

Next, the flow of the generation processing of the simulation case of the present embodiment configured as described above will be described.

FIG. 33 is a flowchart showing an example of the flow of the simulation case generation process according to the present embodiment. The processing of this flowchart starts, for example, when the option "simulation case setting" of the menu screen shown in FIG. 13 is selected by the user and the setting screen shown in FIGS. 24 to 27 is displayed by the output unit 1114.

First, the reception unit 1111 receives an input of a combination of a consumer, a power source, and a distributed power source (S21). Further, in this case, the reception unit 1111 receives the pattern of the combination of the distributed power sources and the rated capacity of the distributed power sources. The reception unit 1111 sends the combination of the received consumer and the power supply, the pattern of the combination of the distributed power supply, and the rated capacity of the distributed power supply to the case generation unit 1112.

The case generation unit 1112 generates a simulation case used in the simulation of the profit evaluation of the electric power retail business from the input combination of the consumer, the power source, and the distributed power source, and the pattern of the combination of the distributed power source. Further, the case generation unit 1112 stores the generated simulation case in the storage unit 1115 (S22).

Next, the flow of the simulation process of the profitability evaluation of the present embodiment will be described. FIG. 34 is a flowchart showing an example of the flow of the simulation process of the profitability evaluation according to the present embodiment. The processing of this flowchart starts, for example, when the option "simulation execution" on the menu screen shown in FIG. 13 is selected by the user. Further, FIG. 34 shows a flow when the calculation unit 1113 executes the first simulation based on the equation (4-1).

The calculation unit 1113 selects the first simulation case from the plurality of simulation cases stored in the storage unit 1115 (S31).

_{Then, the calculation unit 1113 uses the parameters P gmax} (g), P _flowmax (l), and P _{d of} the equations (4-1) and the equations (5-1) to (5-17) based on the selected simulation case. _{(d, t), P cont} (d), η a, η chg, η dis, R chg, R dis, η PV (t), c g (g, t), c Jb (a, t), c _The values acquired from each database of the storage unit 1115 are set in Js (a, t) and c _{w (d).} Further, the calculation unit 1113 sets the value of the rated capacity of the PV 50 or the storage battery 51 set on the setting screen shown in FIG. 27 in _{the W PV} (d), W _SBd (d), and W _{SBg (g) (S32).} ).

Next, in the process of setting the parameters of S33, the calculation unit 1113 satisfies the constraint conditions of the equations (5-1) to (5-17), and then the value of the equation (4-1) which is the objective function. Variables that minimize (power purchase cost) P _g (g, t), P _Jb (a, t), P _Js (a, t), P _flow (l, t), P _PV (d, t), _{P rest (d, t),} Q dchg (d, t), Q ddis (d, t), S d (d, t), Q gchg (g, t), Q gdis (g, t), S g The values of (g, t) and are calculated (S33). Further, the calculation unit 1113 calculates the value of the formula (4-1) when the distributed power source is not installed, and calculates the difference from the value of the formula (4-1) for each simulation case to increase the increment. Calculate profit.

Further, the calculation unit 1113 supplies and supplies for each simulation case based on the value of each variable calculated in the process of S33 and the electric energy demand of the consumer d at the time t input to the _{parameter P d (d, t).} Generate a plan (S34).

Next, the calculation unit 1113 executes the formulas (3-1) to (3-3) described in the first embodiment for each simulation case, and the sales, profits, and costs in the electric power retail business during the evaluation target period. And are calculated (S35).

The calculation unit 1113 stores the calculated values of the variables, the data or graph of the supply / demand plan, the sales, the profit, and the cost in the storage unit 1115 in association with the simulation case (S36). Further, as shown in FIG. 28, the calculation unit 1113 generates a table or a graph showing the incremental profit due to the installation of the distributed power source, and stores it in the storage unit 1115 in association with the simulation case.

Here, the calculation unit 1113 determines whether or not the simulation process has been completed for all the simulation cases (S37).

When the simulation process is not completed for all the simulation cases (S37 “No”), the calculation unit 1113 selects the next simulation case (S38).

For all simulation cases, the calculation unit 1113 repeats the processes of S32 to S38 until the simulation process is completed.

When the simulation process is completed for all the simulation cases (S37 “Yes”), the calculation unit 1113 calculates the profit margin based on the sales and the profit of each simulation case (S39). Further, the calculation unit 1113 may generate a graph comparing the profitability of each simulation case based on the profit and the rate of return, as in the first embodiment.

Further, the calculation unit 1113 calculates the number of years in which the cumulative amount of the incremental profit becomes the same as the initial investment amount based on the initial investment amount of the distributed power source and the incremental profit per year. The investment payback period (recovery period of the initial cost) is calculated (S40). In addition, the calculation unit 1113 generates a graph or table showing the payback period, as shown in FIGS. 29 to 31. Further, the calculation unit 1113 stores the calculated rate of return, the return on investment, and the generated graph or table in the storage unit 1115 in association with the simulation case.

The output unit 1114 outputs the simulation result calculated by the calculation unit 1113 to the display device 104 (S41). For example, the output unit 1114 provides a graph comparing the profit and the rate of return for each simulation case, a table or graph showing the incremental profit due to the installation of the distributed power source, and a graph or table showing the payback period of the distributed power source. Output. Further, the output unit 1114 may further output a graph showing a supply and demand plan for each simulation case.

In FIGS. 33 and 34, the setting of the simulation case and the execution of the simulation process are started as separate processes, but the procedure of the process is not limited to this. For example, the setting of the simulation case and the execution of the simulation process may be continuously performed as a series of processes.

Further, in FIG. 34, the calculation unit 1113 performs the process of calculating the profit margin of each simulation case (S39) and the initial investment of the distributed power source after the loop processing (S32 to S38) for each simulation case is completed. Although the process of calculating the payback period (S40) is performed, the calculation of the rate of return may also be performed within the loop process.

Also, if the calculation unit 1113 performs the second simulation, _W PV _(d) in the equation (4-2), W SBd (d ), since _{W SBg} (g) is not a parameter, S32 parameter In the process of setting the above, the calculation unit 1113 does not set a value for these. For other parameters, the calculation unit 1113 sets the values acquired from each database of the storage unit 1115 as in the first simulation.

Further, in the processing of S33, the calculation unit 1113 calculates the values of W _PV (d), W _SBd (d), and W _SBg (g) in addition to the values of the variables similar to those in the first simulation. Further, the calculation unit 1113 calculates the investment recovery cost of the initial investment of the distributed power source according to the third and fourth terms of the equation (4-2).

Further, when the calculation unit 1113 executes the second simulation, the incremental profit excluding the investment cost of the distributed power source is calculated on the premise that the initial investment of the distributed power source is recovered in the amortization period. The calculation of the payback period for distributed power sources is not performed. Alternatively, the calculation unit 1113 may calculate the investment payback period of the distributed power source in the second simulation by the same processing as in the first simulation.

For the processes other than the above-mentioned S32, S33, and S40, the calculation unit 1113 performs the same process in the second simulation as in the first simulation.

As described above, the storage unit 1115 of the electric power retail business evaluation device 1 of the present embodiment stores the PV attribute database 171, the PV estimated output ratio database 172, and the storage battery attribute database 173. Further, the reception unit 1111 receives an input of a combination of a consumer, a power source, and a distributed power source. Then, the output unit 1114 increases the amount of fluctuation in profit due to the installation of the distributed power supply and the profit based on the combination of the consumer, the power supply, and the distributed power supply and the data of the database stored in the storage unit 1115. Outputs the capacity of the distributed power source. Therefore, according to the electric power retail business evaluation device 1 of the present embodiment, it is possible to perform more accurate profitability evaluation of the electric power retail business when the distributed power source is installed in the customer or the power source.

Further, the storage unit 1115 of the electric power retail business evaluation device 1 of the present embodiment further stores the initial cost (estimated price) of the distributed power source in the PV attribute database 171 and the storage battery attribute database 173. Further, the output unit 1114 further adds the initial cost of the distributed power source, the combination of the consumer, the power source, and the distributed power source, the PV attribute database 171 and the PV estimated output ratio database 172, and the storage battery attribute database 173. Based on the stored data, the recovery period of the initial cost of the distributed power source is output. Therefore, according to the electric power retail business evaluation device 1 of the present embodiment, it is possible to evaluate the profitability of the electric power retail business including the initial cost required for installing the distributed power source.

The distributed power source in this embodiment is a PV50 or a storage battery 51. The PV 50 and the storage battery 51 are often used in a distributed power source. Therefore, according to the electric power retail business evaluation device 1 of the present embodiment, the electric power retail business can be evaluated when the PV50 or the storage battery 51, which is a general distributed power source, is installed, so that many electric power retailers can evaluate the electric power retail business. It can correspond to the business type.

(Modification example)
The function of the electric power retail business evaluation device 1 described in the above-described first embodiment may be realized by cloud computing, a server device installed in a data center, or the like. FIG. 35 is a diagram showing an example of the overall configuration of the electric power retail business evaluation device system S in this modified example.

As shown in FIG. 35, the electric power retail business evaluation device system S in this modification includes the information processing device 1001 and the server device 10 installed in the data center 80. The information processing device 1001 and the server device 10 installed in the data center 80 are connected to each other via a network 90. The network 90 is a network such as the Internet.

In this modification, the electric power retailer or the person (user) who performs the processing related to the evaluation of profitability in response to the request from the electric power retailer uses the information processing device 1001 to combine the power source and the consumer. Input and execute operations such as execution of profitability evaluation simulation. In addition, a business operator or the like that provides a simulation service for evaluation of the electric power retail business manages the server device 10 installed in the data center 80 or the like and provides the service to the user.

The hardware configuration of the information processing device 1001 and the server device 10 of this modification is the same as the hardware configuration of the electric power retail business evaluation device 1 of the first embodiment described with reference to FIG. Alternatively, the server device 10 may be a virtual machine based on cloud computing technology.

As shown in FIG. 35, the information processing device 1001 includes a reception unit 2111, a communication unit 116, and an output unit 2114.

The reception unit 2111 has the same function as the reception unit 111 of the first embodiment described with reference to FIG. Further, the output unit 2114 has the same function as the output unit 114 of the first embodiment.

The communication unit 116 transmits / receives information to / from the server device 10. For example, the communication unit 116 sets the combination of the consumer to which the electric power retailer received by the reception unit 2111 to supply electric power and the power source to be purchased by the electric power retailer to the server device 10. Send to. Further, the communication unit 116 receives from the server device 10 an electric power supply / demand plan calculated by the server device 10, an electric power retail business evaluation index for evaluating the profitability of the electric power retail business for each simulation case, and the like.

Further, as shown in FIG. 35, the server device 10 includes a communication unit 117, a case generation unit 2112, a calculation unit 2113, and a storage unit 2115.

The case generation unit 2112 and the calculation unit 2113 have the same functions as the case generation unit 112 and the calculation unit 113 of the first embodiment described with reference to FIG. Further, the storage unit 2115 stores a database or the like similar to the storage unit 115 of the first embodiment described with reference to FIG.

The communication unit 117 transmits / receives information to / from the information processing device 1001. For example, the communication unit 117 receives the combination of the consumer to which the electric power retailer supplies the electric power and the power source to be purchased by the electric power retailer, which is transmitted from the information processing device 1001. To do. Further, the communication unit 117 transmits the power supply / demand plan calculated by the calculation unit 2113, the power retail business evaluation index for evaluating the profitability of the power retail business for each simulation case, and the like to the information processing device 1001.

The information processing device 1001 and the server device 10 execute a simulation case generation process and a profitability evaluation simulation process in the same manner as in FIGS. 18A and 18B.

According to the electric power retail business evaluation device system S of this modification, the evaluation of the electric power retail business is simulated even if the user does not have the electric power retail business evaluation device 1 for simulating the evaluation of the electric power retail business. be able to. Further, since a plurality of information processing devices 1001 can be connected to one server device 10, more users can simulate the evaluation of the electric power retail business.

The profitability evaluation program of the electric power retail business executed by the electric power retail business evaluation device 1 of each of the above-described embodiments is a CD-ROM, a flexible disk (FD), or a CD- in an installable or executable format file. It is provided by being recorded on a computer-readable recording medium such as R or DVD (Digital Versaille Disk).

Further, the profitability evaluation program of the electric power retail business executed by the electric power retail business evaluation device 1 of each of the above-described embodiments is provided by storing it on a computer connected to a network such as the Internet and downloading it via the network. It may be configured to do so. Further, the profitability evaluation program of the electric power retail business executed by the electric power retail business evaluation device 1 of each of the above-described embodiments may be provided or distributed via a network such as the Internet. Further, the profitability evaluation program of the electric power retail business executed by the electric power retail business evaluation device 1 of each of the above-described embodiments may be configured to be provided by incorporating it into a ROM or the like in advance.

The profitability evaluation program of the electric power retail business executed by the electric power retail business evaluation device 1 of each of the above-described embodiments has a modular configuration including each of the above-mentioned parts (reception unit, case generation unit, calculation unit, output unit). As the actual hardware, when the CPU (processor) reads the program from the storage medium and executes it, each of the above parts is loaded on the main storage device, and the reception part, the case generation part, the calculation part, and the output part are the main parts. It is designed to be generated on the storage device.

The profitability evaluation program of the electric power retail business executed by the information processing device 1001 and the server device 10 of the above-described modification is a CD-ROM, a flexible disk (FD), or a CD in an installable or executable format file. -R, DVD (Digital Versaille Disk) or the like, which is recorded on a computer-readable recording medium and provided.

Further, the profitability evaluation program of the electric power retail business executed by the information processing device 1001 and the server device 10 of the above-described modification is stored on a computer connected to a network such as the Internet and downloaded via the network. It may be configured to provide. Further, the profitability evaluation program of the electric power retail business executed by the information processing device 1001 and the server device 10 of the above-described modification may be provided or distributed via a network such as the Internet. Further, the profitability evaluation program of the electric power retail business executed by the information processing device 1001 and the server device 10 of the above-described modification may be configured to be provided by incorporating it in a ROM or the like in advance.

The profitability evaluation program of the electric power retail business executed by the information processing device 1001 and the server device 10 of the above-described modification includes the above-mentioned parts (communication unit (information processing unit), reception unit, output unit, communication unit (server device). ), Case generation unit, calculation unit), and as actual hardware, the CPU (processor) reads the program from the storage medium and executes it, so that each part is loaded on the main memory. The communication unit (information processing device), the reception unit, the output unit, the communication unit (server device), the case generation unit, and the calculation unit are generated on the main memory.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

1 Electric power retail business evaluation device 10 Server device 40 Transformer 41 Transmission line 42 Distribution line 50 PV
51 Storage battery 111,1111 Reception unit 112,1112 Case generation unit 113,1113 Calculation unit 114,1114 Output unit 115,1115 Storage unit 121 Power area database 122 Interconnection line database 123 Interconnection line utilization plan database 130 Selling price database 131 Demand Assumed database 140 Purchase price database 141 Power supply database 150 Consignment database 151 Assumed spot price database 171 PV attribute database 172 PV estimated output ratio database 173 Storage battery attribute database l, l1 to l10 Interconnection line M power market

Claims (7)

The amount of electric power demanded by each consumer to whom the electric power retailer sells electric power, the purchase price of the electric power for each electric power source from which the electric power is purchased, and the amount of electric power that can be supplied for each electric power source. A storage unit to memorize and
A reception unit that accepts input of a combination of the consumer and the power supply,
Purchased from the power sources included in the combination based on the combination, the amount of power demanded by the consumer, the purchase price of the power for each power source, and the amount of power that can be supplied for each power source. An output unit that outputs an electric power retail business evaluation index that evaluates the profitability of the electric power retail business when the electric power is sold to the consumer included in the combination.
Equipped with a,
The storage unit further stores information about power supply by the customer or a distributed power source installed in the power source.
The reception unit receives inputs of a combination of the consumer, the power source, and the distributed power source.
Based on the combination and the information about the power supply by the distributed power source, the output unit determines the amount of fluctuation in the profit due to the installation of the distributed power source and the capacity of the distributed power source in which the profit increases. Output,
Electric power retail business evaluation device. The storage unit stores the amount of power demand for each consumer, the purchase price of the power for each power source, and the amount of power that can be supplied for each power source for each region, and further connects different regions. Interconnection line utilization plan data that is data on the amount of electric power that can be supplied from one area to the other area by the electric power retailer per time unit for each of a plurality of interconnection lines. And the transportation fee for each region related to the supply of electric power are memorized.
The output unit includes the combination, the amount of power demand for each customer stored for each area, the purchase price of the power for each power source, the amount of power that can be supplied for each power source, and the series. The electric power retail business evaluation index is output based on the grid usage plan data and the transportation charge for each region.
The electric power retail business evaluation device according to claim 1. The output unit includes the combination, the electric power demand for each customer stored for each region, the purchase price of the electric power for each power source, the electric energy that can be supplied for each power source, and the ream. The above-mentioned case where the value of the purchase cost becomes smaller among the purchase costs of electric power calculated a plurality of times by changing the amount of electric power purchased from the power source included in the combination based on the system line utilization plan data. Outputs the purchased power amount for each power source and the power transmission amount for each interconnection line.
The electric power retail business evaluation device according to claim 2. The storage unit further stores the estimated power purchase price and the estimated power sale price for each time in the electricity market.
The output unit is from the power source or the electricity market included in the combination based on the combination, information about the consumer and the power source, and the estimated power purchase price and the estimated selling price. Outputs the electric power retail business evaluation index for evaluating the profitability of the electric power retail business when the purchased electric power is sold to the consumer or the electric power market included in the combination.
The electric power retail business evaluation device according to any one of claims 1 to 3. The storage unit further stores the initial cost of the distributed generation.
The output unit further outputs the recovery period of the initial cost based on the initial cost, the combination, and information about the power supply by the distributed power source.
The electric power retail business evaluation device according to any one of claims 1 to 4. The distributed power source is a photovoltaic power generation device or a storage battery.
The electric power retail business evaluation device according to any one of claims 1 to 5. It is an electric power retail business evaluation method executed by the electric power retail business evaluation device.
The electric power retail business evaluation device includes the amount of electric power demanded by each consumer to whom the electric power retailer sells electric power, the purchase price of the electric power for each power source from which the electric power is purchased, and each electric power source. Equipped with a storage unit that stores the amount of power that can be supplied
A reception step that accepts input of a combination of the consumer and the power supply, and
Purchased from the power sources included in the combination based on the combination, the amount of power demanded by the consumer, the purchase price of the power for each power source, and the amount of power that can be supplied for each power source. An output step that outputs an electric power retail business evaluation index that evaluates the profitability of the electric power retail business when the electric power is sold to the consumer included in the combination, and an output step.
Only including,
The storage unit further stores information about power supply by the customer or a distributed power source installed in the power source.
In the reception step, the input of the combination of the consumer, the power supply, and the distributed power supply is received.
In the output step, based on the combination and the information about the power supply by the distributed power source, the fluctuation amount of the profit due to the installation of the distributed power source and the capacity of the distributed power source in which the profit increases are determined. Output,
Electricity retail business evaluation method.

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