JP2017163746A - Power supply system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply system capable of reducing a sense of unfairness in transacting electric power between an undertaker and a plurality of users with a simple configuration.SOLUTION: The power supply system includes: a plurality of power supply units (a power storage device 115 and a photovoltaic power generation part 114) which a housing block T comprised of a plurality of dwelling houses H has; a power selling meter 117 for detecting each of electric power sold from the plurality of power supply units to an undertaker (an intermediate trader) other than the housing block T; and a power purchasing meter 111 for detecting each of electric power which a plurality of dwelling houses H purchase from the intermediate trader.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a technology of a power supply system that supplies power to a plurality of consumers.

  Conventionally, the technology of a power supply system that supplies power to a plurality of consumers is known. For example, as described in Patent Document 1.

  In the technique described in Patent Literature 1, each of a plurality of houses (customers) is provided with a storage battery, and the power of the storage battery charged in a time zone (such as midnight) where the electricity rate is low can be used in the house. In addition, power is accommodated from a house with a sufficient amount of storage battery charge to a house where power is insufficient. When accommodating electric power, the daily electric power consumption of each house is predicted, and the electric power interchange is determined based on the electric power usage and the charged amount of the storage battery. The control device accommodates electric power according to the determined accommodation amount.

  Here, assuming the future full-scale liberalization of electric power in the future, the exchange of electric power between a plurality of houses as described in Patent Document 1 is performed by an operator (intermediary trader) such as a retail electric company. Is assumed to be undertaken. That is, a mode of power purchase and purchase is assumed in which a business operator purchases power from a plurality of houses and distributes the power to a plurality of houses as appropriate.

JP 2010-220428 A

  However, in the technique described in Patent Document 1, it is necessary to determine the power usage amount by, for example, predicting the power usage amount in order to buy and sell power fairly between the business operator and the plurality of consumers. However, there is room for improvement in that the configuration is complicated, for example, a device for accommodating power according to the amount of accommodation is required.

  The present invention has been made in view of the situation as described above, and the problem to be solved is a simple configuration, and an unfair feeling when buying and selling power between an operator and a plurality of consumers. It is to provide a power supply system that can be reduced.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

  That is, the power supply system detects a plurality of power supply devices included in a consumer aggregate composed of a plurality of consumers, and power sold from the plurality of power supply apparatuses to a different business operator from the consumer aggregate. And a first power purchase detection unit that detects power purchased by the plurality of consumers from the business operator.

In addition, the power supply system includes a second power sale detection unit that detects power sold to the power company from the business operator, a second power purchase detection unit that detects power that the business company purchases from the power company, You may comprise.
With such a configuration, it is possible to detect the electric power traded between the business operator and the electric power company with a simple configuration.

In the power supply system, surplus power excluding power purchased from the operator by the plurality of consumers from the power sold to the operator from the plurality of power supply devices is sold to the power company. It may be done.
With such a configuration, the business operator can obtain a profit by selling power to an electric power company.

Further, in the power supply system, when only the power sold from the plurality of power supply devices to the business operator is insufficient in power to be sold from the business operator to the plurality of consumers, the business operator is from the power company. You may purchase electric power.
With such a configuration, it is possible to supply power appropriately in response to requests from a plurality of consumers.

In addition, the power supply device includes a power storage device capable of charging and discharging electric power, the operator purchases electric power from the electric power company at night, and the plurality of consumers include the electric power company from the electric power company at night. You may purchase the purchased electric power and charge the said electrical storage apparatus with the said electric power.
With such a configuration, it is possible to use power purchased from an electric power company at night.

In the power supply system, the price of power sold from the business to the power company may be set higher than the price of power sold from the plurality of power supply devices to the business.
With such a configuration, a business operator can obtain a profit by selling power purchased from a plurality of power supply apparatuses to an electric power company.

In the power supply system, the price of power sold from the business operator to the power company may be set higher than the price of power purchased by the business operator from the power company.
With such a configuration, the business operator can easily obtain profits.

The plurality of consumers may have at least one power supply device.
With such a configuration, unfairness among a plurality of consumers each having a power supply device can be reduced.

Further, the power supply device may include a power generation device capable of generating power using natural energy.
With such a configuration, it is possible to use electric power generated using natural energy (renewable energy).

The power generation device may include a solar power generation device that generates power by receiving sunlight, and a total installed capacity of the solar power generation devices included in the plurality of power supply devices may be 10 kW or more.
With such a configuration, the purchase period (procurement period) based on the fixed price purchase system can be set to 20 years in the contract relating to the power trading between the electric power company and the business operator.

  With a simple configuration, it is possible to reduce unfairness when buying and selling power between a business operator and a plurality of consumers.

(A) The schematic diagram which showed the aspect of the general electric power trading. (B) The schematic diagram which showed the aspect of the power trading using the electric power supply system which concerns on this embodiment. The block diagram which showed the structure of the electric power supply system. (A) The schematic diagram which showed the mode of the buying and selling of the electric power in the 1st case. (B) The schematic diagram which showed the mode of the buying and selling of the electric power in the 2nd case. (C) The schematic diagram which showed the mode of the buying and selling of the electric power in the 3rd case. The block diagram which showed the supply aspect of the electric power in a 1st case. The block diagram which showed the supply aspect of the electric power in a 2nd case. The block diagram which showed the supply aspect of the electric power in the 3rd case.

  First, an outline of an aspect of power trading using a power supply system 100 described later will be described with reference to FIG.

  The power supply system 100 according to the present embodiment is for realizing the buying and selling of power assuming the future full-scale liberalization of power retailing. For comparison, FIG. 1 shows two modes of power trading. Specifically, FIG. 1 (a) shows a general power trading mode, and FIG. 1 (b) shows a power trading mode using the power supply system 100 assumed after the full liberalization of retailing power. Are shown respectively.

  As shown in FIG. 1A, generally, a consumer such as a general household (hereinafter referred to as “customer”) has a contract regarding power trading with an electric power company (power generation company). Each customer can purchase (purchase) power appropriately from the power company. Each customer can sell (sell) the surplus (surplus power) of the power generated by the solar power generation apparatus he owns to the power company.

  Here, in the fixed-price purchase system, the purchase price (procurement price) and purchase period of the power sold from the customer to the power company (in accordance with the installed capacity (installed amount) of the solar power generation device) Procurement period) is set. For example, when the installed capacity is less than 10 kW, a predetermined price is set as the purchase price and 10 years is set as the purchase period. That is, the customer can sell the electric power to the electric power company for a fixed price for 10 years.

  On the other hand, when the installation capacity is 10 kW or more, a predetermined price is set as the purchase price and 20 years is set as the purchase period. That is, the customer can sell the electric power to the electric power company at a fixed purchase price for 20 years.

  Considering the current situation in which the purchase price is decreasing year by year, it is considered that customers can obtain more profits if they can sell power at a fixed purchase price for a longer period of time. However, it is said that the installation capacity of the solar power generation apparatus possessed by a general consumer (general household or the like) is about 4 to 5 kW (less than 10 kW) at most. Accordingly, in the power trading mode of FIG. 1A, normally, the purchase period is set to 10 years instead of 20 years.

  As shown in FIG. 1B, in the mode of power trading using the power supply system 100 according to the present embodiment, the customer indirectly powers through a business operator (intermediary company) such as a retail electricity business operator. Trade power with the company. Specifically, the intermediate contractor has a contract for power trading with an electric power company. In addition, the customer has a contract with the intermediate contractor regarding power sales. The intermediary trades power appropriately with the power company. In addition, the intermediary trades power appropriately with each customer.

  In such an aspect of power trading, if the intermediate contractor is regarded as one demand point (one consumer), the installed capacity of the solar power generation apparatus of the one consumer is the installation capacity of the solar power generation apparatus possessed by each customer. It can be regarded as a total value. Therefore, even if the installed capacity of the solar power generation apparatus possessed by each customer is less than 10 kW, by setting the total value to 10 kW or more, the intermediate contractor can conclude a contract with the electric power company in the purchase period of 20 years. . In this way, the intermediate trader can collectively buy and sell power with the power company on behalf of each customer, so that the power purchase period can be 20 years.

  Below, the structure of the electric power supply system 100 for implement | achieving the aspect of the electric power trading shown in FIG.1 (b) is demonstrated using FIG.

  The electric power supply system 100 distributes electric power among electric power companies, intermediaries, and a plurality of customers as appropriate. In addition, in this embodiment, the detached house (house H) of a general household is assumed as a customer. In the present embodiment, it is assumed that the power supply system 100 is applied to a residential block T (a collection of houses H) including a plurality of houses H. The power supply system 100 mainly includes a power distribution board 101, a sub-power purchase meter 111, a power distribution board 112, a general circuit 113, a solar power generation unit 114, a power storage device 115, a power conditioner 116, a sub-power sale meter 117, and the like. It has.

  The lead-in distribution board 101 distributes electric power as appropriate. The service distribution board 101 mainly includes a parent electricity meter 102 and a parent electricity meter 103.

  In addition, in the following description, the positional relationship of each part is demonstrated on the basis of the distribution line L in the service distribution board 101. FIG. One end of the distribution line L is connected to the system power source S of the power company. In FIG. 2, the distribution line L is indicated by a line extending linearly from the system power supply S side to the right side of the drawing. In the following description, for the sake of convenience, in the direction in which the distribution line L extends (left and right direction in the drawing), the left side (side closer to the system power supply S) is referred to as the upstream side, and the right side is referred to as the downstream side.

  The parent power purchase meter 102 detects the amount of electric power purchased by an intermediate contractor from an electric power company. The power purchase meter 102 is provided in the middle of the distribution line L (near the upstream end). The parent power meter 102 detects the amount of power supplied from the system power source S to the incoming distribution board 101. The amount of power detected by the parent power purchase meter 102 is regarded as the amount of power purchased by the intermediate contractor from the power company.

  The parent power meter 103 detects the amount of power sold by an intermediate contractor to an electric power company. The parent power meter 103 is provided in the middle of the distribution line L (upstream of the parent power meter 102). The parent power meter 103 detects the amount of power supplied from the service distribution board 101 to the system power source S. The amount of power detected by the parent power meter 103 is regarded as the amount of power sold by the intermediate contractor to the power company.

  The sub-power meter 111, the distribution board 112, the general circuit 113, the solar power generation unit 114, the power storage device 115, the power conditioner 116, and the sub-power meter 117 include a plurality (N in this embodiment) of houses H. (Housing H1, Housing H2,... Housing HN) are provided so as to correspond to each. Therefore, in the following, only the sub-electricity meter 111 etc. provided corresponding to one house H (house H1) will be described in detail, and the sub-electricity meter 111 etc. provided corresponding to the other house H, Only differences from those provided in the house H1 will be briefly described.

  The sub-electricity purchase meter 111 detects the amount of electric power that the house H1 purchases from an intermediate contractor. The sub-electricity meter 111 is disposed in the middle of the distribution line connecting the interconnection point P1 provided at the downstream end of the distribution line L and the house H1. The sub-electricity meter 111 detects the amount of power supplied from the service distribution board 101 to the house H1. The amount of power detected by the sub-electricity purchase meter 111 is regarded as the amount of power purchased by the house H1 from an intermediate contractor.

  The distribution board 112 distributes the electric power supplied to the house H1 as appropriate. Distribution board 112 is provided in house H1. The distribution board 112 is connected to the sub power purchase meter 111.

  The general circuit 113 is provided in the house H1 and supplies power to an appropriate electrical product or the like (power load). The general circuit 113 is connected to the distribution board 112 and receives the power distributed by the distribution board 112.

  The solar power generation unit 114 is a device (solar power generation device) that generates power using sunlight. The solar power generation unit 114 is installed in a sunny place such as on the roof of the house H1.

  The power storage device 115 is a device that can charge and discharge electric power. The power storage device 115 includes a storage battery made of a lithium ion battery, a nickel hydride battery, or the like that can charge and discharge power, a charger that rectifies supplied AC power and charges the storage battery. The power storage device 115 is provided in the house H1.

  The power conditioner 116 is a hybrid power conditioner connected to the solar power generation unit 114 and the power storage device 115. The power conditioner 116 includes a conversion device that appropriately converts DC power and AC power, a control unit that controls the conversion device, and the like. The power conditioner 116 is provided in the house H1. The power conditioner 116 is connected to the distribution board 112 of the first house 11. In FIG. 2, a part of the distribution line that connects the power conditioner 116 and the distribution board 112 is omitted. Further, the power conditioner 116 is connected to the interconnection point P2 disposed in the middle of the distribution line L.

  The power conditioner 116 can supply (charge) the electric power supplied from the distribution board 112 (electric power from the system power supply S) to the power storage device 115. The power conditioner 116 charges the power storage device 115 with power from the system power source S at night (a time zone when the power rate is relatively low).

  Further, the power conditioner 116 can sell (power sale) the electric power generated by the solar power generation unit 114 and the electric power discharged from the power storage device 115 via a sub power meter 117 described later. The power conditioner 116 discharges the power storage device 115 when a certain amount of electric power is stored in the power storage device 115 during the day.

  The sub power meter 117 detects the amount of power that the house H1 sells to an intermediate contractor. The sub power meter 117 is disposed between the power conditioner 116 and the interconnection point P2. The sub power meter 117 detects the amount of power supplied from the power conditioner 116 to the incoming distribution board 101. The amount of power detected by the sub power meter 117 is regarded as the amount of power sold by the house H1 to an intermediate contractor.

  Similarly to the housing H1, the sub-electricity meter 111, the distribution board 112, the general circuit 113, the solar power generation unit 114, the power storage device 115, and the power for the housing H other than the housing H1 (the housing H2,. A conditioner 116 and a sub power meter 117 are provided.

  The sub power purchase meters 111 of the houses H other than the house H1 are respectively arranged in the middle of the distribution lines connecting the interconnection points P1 of the distribution lines L and the houses H. The power conditioner 116 (child power meter 117) of the house H (the house H2,..., The house HN) other than the house H1 is sequentially arranged in the middle part of the distribution line L (upstream side from the connection point P2). Are connected to the connection point P3,.

  In the present embodiment, it is assumed that the installation capacity of each solar power generation unit 114 is set so that the total installation capacity of the solar power generation units 114 provided in each house H is 10 kW or more.

  In addition, control of operation | movement of each part of the electric power supply system 100 comprised as mentioned above is suitably performed by the control apparatus which is not shown in figure. That is, a program related to the operation of the power supply system 100 is stored in the control device in advance. The said control apparatus controls operation | movement of each part according to the said program. For example, the control device can control charging / discharging of the power storage device 115, distribution of power, accommodation, and the like by controlling the operation of each power conditioner 116. Any one of the power conditioners 116 can also function as the control device.

  Hereinafter, a state in which electric power is bought and sold between an electric power company, an intermediate contractor, and a customer (house H) using the electric power supply system 100 configured as described above will be described.

  First, as a premise, using FIG. 1 (b), the contents of a contract relating to the power trading that the power company and the middle trader, and the middle trader and the customer are respectively connected to will be described.

  Intermediaries have selected hourly lamps as a price plan when purchasing power from an electric power company. The electric light according to time zone is a rate plan in which the price (charge) of nighttime electricity is low and the price of electricity in the daytime is high. As an example, in this embodiment, the price of nighttime power is 13.45 yen / kWh, and the price of daytime power is 24.16 yen / kWh (24.16 yen or more per kWh).

  As the price (purchase price) and purchase period when the intermediate company sells the power to the power company, a purchase price based on the fixed price purchase system is set. Specifically, since the total installed capacity of the photovoltaic power generation units 114 provided in the plurality of houses H is 10 kW or more, 20 years is set as the purchase period. As an example, in the present embodiment, the purchase price is 27 yen / kWh. In this way, the price (purchase price) (27 yen / kWh) when the middle contractor sells power to the power company is the price (13.45 yen / kWh) when the middle trader purchases power from the power company. Or 24.16 yen / kWh).

  The customer has selected a metered lamp as a rate plan for purchasing power from an intermediary. The metered lamp is a rate plan in which the price of electricity is determined according to the amount of electricity used in a month, regardless of the time of day. As an example, in this embodiment, the price of the power is assumed to be 20 yen / kWh. Thus, the price (20 yen / kWh) when a customer purchases electric power from an intermediate company is higher than the price (24.16 yen ~ / kWh) when an intermediate company purchases electric power from an electric power company in the daytime. The price is lower and higher than the price (13.45 yen / kWh) when an intermediate contractor purchases power from an electric power company at night.

  The customer has a contract with an intermediate contractor to sell all the electric power generated by the solar power generation unit 114 and the electric power stored in the power storage device 115 to the intermediate contractor. The price (purchase price) when a customer sells electric power to an intermediary is determined by an agreement between the customer and the intermediary. As an example, in this embodiment, the purchase price is assumed to be 21 yen / kWh. In this way, the price (purchase price) (21 yen / kWh) when a customer sells power to an intermediate company (21 yen / kWh) is the price (purchase price) (27 yen) when an intermediate company sells power to an electric power company. / KWh).

  Next, with reference to FIG. 3 to FIG. 6, a specific state of buying and selling power according to the time zone will be described. In FIG. 3, only one customer among a plurality of customers is illustrated for simplification.

  3 (a) and 4 show the power when there is power generation in the solar power generation unit 114 and / or discharge from the power storage device 115 (hereinafter referred to as "first case") in the daytime time zone. It shows the state of buying and selling.

  In this case, the electric power generated in the solar power generation unit 114 and the electric power discharged from the power storage device 115 are all supplied to the incoming distribution board 101 via the sub power meter 117. That is, the entire amount of the electric power is once sold at 21 yen / kWh from each house H (customer) to an intermediate contractor.

  In addition, the electric power purchased by the intermediate contractor from each house H is supplied to each house H through the sub-electricity meter 111 in response to a request from the general circuit 113 of each house H. That is, the electric power is sold at 20 yen / kWh from the middleman to each house H.

  Further, when there is surplus power (surplus power) that is not sold from the intermediate contractor to each house H, the power is supplied to the system power source S via the parent power meter 103. That is, the electric power (surplus electric power) is sold from an intermediate contractor to an electric power company at 27 yen / kWh.

  In this way, in the first case, the intermediate contractor sells all the electric power once purchased from each house H to each house H as necessary. In addition, when surplus power is generated, an intermediate contractor can obtain a profit by selling the surplus power to an electric power company.

  In the first case, if only the power purchased from each house H is insufficient for selling to each house H, the middleman purchases power from the power company to make up for the shortage. In this case, the intermediate contractor purchases electric power from the electric power company for 24.16 yen / kWh.

  FIG. 3B and FIG. 5 show power trading when there is no power generation in the solar power generation unit 114 and no discharge from the power storage device 115 (hereinafter referred to as “second case”) during the daytime. The state of is shown. In addition, as a case where there is no power generation in the solar power generation unit 114 in the daytime, for example, a rainy day or a cloudy day when the amount of solar radiation is small is assumed. Further, as a case where there is no discharge from the power storage device 115, a case where the power that can be discharged is not stored in the power storage device 115 is assumed.

  In this case, since the middle contractor cannot purchase the power from the solar power generation unit 114 and the power storage device 115, the power demand from each house H cannot be met as it is. Therefore, the intermediate contractor supplies the electric power supplied from the system power supply S to each house H via the sub power purchase meter 111 in response to a request from the general circuit 113 of each house H. That is, the intermediate trader purchases electric power from an electric power company at 24.16 yen / kWh and sells the electric power to each house H at 20 yen / kWh. In each house H, electric power purchased from an intermediate contractor can be used as appropriate.

  Thus, in the second case, the intermediate contractor supplies (sells) the power purchased from the power company to each house H as necessary. As a result, the intermediate contractor can appropriately supply power to each house H even when the power from the solar power generation unit 114 and the power storage device 115 cannot be purchased. Moreover, since the customer (each house H) can purchase the electric power from the middle contractor at a lower price than purchasing the electric power directly from the electric power company, the electric charge can be saved.

  FIG. 3C and FIG. 6 show a state of buying and selling power in the night time zone (hereinafter referred to as “third case”).

  In this case, the intermediate contractor supplies the power supplied from the system power source S to each house H via the sub-electricity meter 111. That is, the intermediate trader purchases electric power from an electric power company for 13.45 yen / kWh and sells the electric power to each house H at 20 yen / kWh. The power storage device 115 of each house H charges the power supplied to the house H. Moreover, in each house H, the electric power purchased from the middle contractor can be used suitably.

  In this way, in the third case, the middleman purchases relatively inexpensive nighttime power from the power company and supplies (sells) it to each house H. The power storage device 115 of each house H charges the power. The electric power stored in the power storage device 115 is discharged in the daytime, and the entire amount is purchased by an intermediate contractor (see the first case described above (FIG. 4 and the like)).

As described above, the power supply system 100 according to the present embodiment is
A plurality of power supply devices (power storage device 115 and solar power generation unit 114) possessed by a residential block T (customer aggregate) composed of a plurality of houses H (customers);
A sub-electricity meter 117 (first electric power sale detection unit) for detecting electric power sold from the plurality of power supply devices to an operator (intermediate contractor) different from the residential block T;
A sub-electricity purchase meter 111 (first electric power purchase detection unit) that detects electric power purchased by the plurality of houses H from the intermediate company,
It comprises.
By comprising in this way, an unfair feeling at the time of buying and selling electric power between an intermediate agent and the some house H can be reduced with a simple structure. That is, it is possible to detect the power sold from a plurality of power supply devices to the middle contractor and the power purchased by the plurality of houses H from the middle contractor without using a complicated configuration (device, control method, etc.). Although the power to be bought and sold with the middle contractor differs for each power supply device and for each house H, since the power to be bought and sold can be detected for each power supply device and each house H, unfairness can be eliminated. it can. In addition, the power supply system 100 can be easily applied to the existing residential block T simply by providing the sub-power sales meter 117 and the sub-power purchase meter 111.
Moreover, once the power from each power supply device is purchased by an intermediary and sold to a plurality of houses H as necessary, the power of the power supply devices (the power storage device 115 and the photovoltaic power generation unit 114) is wasted. Or the occurrence of a situation where power is insufficient in the house H can be suppressed, and efficient accommodation of power can be performed as the entire residential block T.

In addition, the power supply system 100
A parent power meter 103 (second power sale detector) for detecting the power sold to the power company from the intermediate company;
A parent power purchase meter 102 (second power purchase detection unit) for detecting the power purchased by the intermediate company from the power company;
It comprises.
By comprising in this way, the electric power traded between an intermediate trader and an electric power company is detectable with a simple structure. Moreover, since the electric power traded between an electric power company, an intermediate trader, and the some house H can be detected, the business based on the electric power buying and selling can be performed.

Of the electric power sold from the plurality of power supply devices to the intermediate contractor, surplus power excluding the electric power purchased by the plural houses H from the intermediate contractor is sold to the electric power company. (See FIG. 3A and FIG. 4).
By comprising in this way, the intermediate trader can obtain the profit by selling electric power to an electric power company. In addition, power can be preferentially supplied to the plurality of houses H, and only surplus power can be sold to the power company.

In addition, when the power sold from the plurality of power supply devices to the intermediate contractor is insufficient for the sales from the intermediate contractor to the plurality of houses H, the intermediate contractor purchases power from the power company. It is.
By comprising in this way, electric power can be appropriately supplied according to the request | requirement from the some house H. FIG.

In addition, the power supply device
Including a power storage device 115 capable of charging and discharging electric power,
The intermediary is
Purchase power from the power company at night,
Multiple houses H
The intermediate company purchases power purchased from the power company at night and charges the power storage device 115 with the power (see FIGS. 3C and 6).
By comprising in this way, the electric power purchased from the electric power company at night can be utilized. In particular, when an intermediate contractor has signed a contract with an electric power company using hourly lamps (a charge plan with a low price for nighttime electricity), it is possible to purchase and use inexpensive electric power.

Further, the price (27 yen / kWh) of electric power sold from the intermediate company to the electric power company is set higher than the price (21 yen / kWh) of electric power sold from the plurality of power supply devices to the intermediate company. It is what is done.
By configuring in this way, an intermediate contractor can obtain a profit by selling power purchased from a plurality of power supply apparatuses to an electric power company.

In addition, the price (27 yen / kWh) of electric power sold from the intermediate company to the electric power company is the price (24.16 yen / kWh, or 13.45) of electric power purchased by the intermediate company from the electric power company. Yen / kWh).
By comprising in this way, an intermediate contractor can make a profit easy.

The plurality of consumers are
It has at least one power supply device.
By configuring in this way, it is possible to reduce unfairness among a plurality of consumers each having a power supply device.

In addition, the power supply device
It includes a power generation device (solar power generation unit 114) that can generate power using natural energy.
By comprising in this way, the electric power generated using natural energy (renewable energy) can be used. Further, by buying and selling the electric power, a plurality of houses H and middlemen can efficiently obtain profits.

In addition, the power generator
Including a solar power generation unit 114 (solar power generation device) that generates power by receiving sunlight,
The total installed capacity of the photovoltaic power generation units 114 included in the plurality of power supply devices is 10 kW or more.
By configuring in this way, the purchase period (procurement period) based on the fixed price purchase system can be set to 20 years in the contract relating to the power purchase and sale between the electric power company and the middleman. As a result, electric power can be sold to a power company for a longer period at a fixed price, and as a result, profits can be obtained efficiently.

House H is an embodiment of a consumer.
Moreover, the residential block T is one embodiment of a consumer aggregate.
Moreover, the solar power generation unit 114 is an embodiment of a power supply device, a power generation device, and a solar power generation device.
The power storage device 115 is an embodiment of a power supply device.
Moreover, the sub power sales meter 117 is one embodiment of the first power sales detection unit.
The sub-electricity purchase meter 111 is an embodiment of the first electric power purchase detection unit.
In addition, the parent power meter 103 is an embodiment of the second power sale detector.
The parent power purchase meter 102 is an embodiment of the second power purchase detection unit.

  Although one embodiment has been described above, the present invention is not limited to the above-described configuration, and various modifications can be made within the scope of the invention described in the claims.

  For example, in the above embodiment, the intermediate contractor purchases the entire amount of power from the house H (power from the solar power generation unit 114 and the power storage device 115). However, for example, only a predetermined amount is purchased and the remaining power is purchased. Can be configured to be used in each house H (for example, supplied to the general circuit 113 or stored in the power storage device 115 in case of emergency).

  Moreover, in the said embodiment, it was set as the structure by which the electrical storage apparatus 115 and the solar power generation part 114 were provided in each house H, For example, the electrical storage apparatus 115 and solar power generation only in some houses H among the some houses H. The structure in which the part 114 is provided may be sufficient. Moreover, the structure which provides the shared electrical storage apparatus 115 and the solar power generation part 114 in the residential block T may be sufficient.

  Moreover, the specific value of the price of electric power illustrated in the above embodiment is an example. For example, the price of the electric power traded between an intermediate trader and a customer can be arbitrarily set by the intermediate trader in consideration of profitability and the like.

  Moreover, in the said embodiment, although the detached house (house H) of a general household was illustrated as a consumer, it can apply also to other various consumers (for example, each household of an apartment house, etc.). . Moreover, it is also possible to set another middle trader as a consumer who buys and sells electric power with the middle trader (concludes a contract related to power trade with another middle trader).

DESCRIPTION OF SYMBOLS 100 Electric power supply system 102 Parent electricity purchase meter 103 Parent electricity sale meter 111 Child electricity purchase meter 114 Solar power generation part 115 Power storage device 117 Child electricity sale meter

Claims (10)

A plurality of power supply devices possessed by a consumer aggregate comprising a plurality of consumers;
A first power sale detection unit that detects each of the electric power sold from the plurality of power supply devices to an operator different from the consumer aggregate;
A first electric power purchase detection unit for detecting electric power purchased by the plurality of consumers from the operator;
A power supply system comprising: A second power sale detection unit for detecting power sold to the power company from the operator;
A second power purchase detection unit for detecting power purchased by the operator from the power company;
Comprising
The power supply system according to claim 1. Of the power sold from the plurality of power supply devices to the business operator, surplus power excluding the power purchased by the plurality of consumers from the business operator is sold to the power company.
The power supply system according to claim 2. If the power sold from the plurality of power supply devices to the business operator alone is insufficient to sell power from the business operator to the plurality of consumers, the business operator purchases power from the power company.
The power supply system according to claim 2 or claim 3. The power supply device
Including a power storage device capable of charging and discharging electric power,
The operator is
Purchase power from the power company at night,
The plurality of consumers are:
Purchasing power purchased from the power company by the operator at night and charging the power storage device with the power,
The power supply system according to any one of claims 2 to 4. The price of power sold to the power company from the company is set higher than the price of power sold to the company from the plurality of power supply devices.
The power supply system according to any one of claims 2 to 5. The price of power sold from the operator to the power company is set higher than the price of power purchased by the company from the power company.
The power supply system according to any one of claims 2 to 6. The plurality of consumers are:
Having at least one power supply unit,
The power supply system according to any one of claims 1 to 7. The power supply device
Including power generation equipment that can generate electricity using natural energy,
The power supply system according to any one of claims 1 to 8. The power generator is
Including solar power generators that generate sunlight and generate electricity,
The total installed capacity of the solar power generation devices included in the plurality of power supply devices is 10 kW or more.
The power supply system according to claim 9.

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