JP6675717B2 - Power trading history generation system - Google Patents

Description

  The present invention relates to a power transaction history system, and more particularly, to a technology that guarantees traceability of generated power using blockchain technology.

  In recent years, “blockchain technology (distributed ledger technology)” that guarantees the authenticity of transaction information using a hash function and a public key cryptosystem is being used in various fields. As an example, in cryptocurrency transactions, cryptocurrency transaction information (hereinafter, referred to as “transaction”) is broadcast to all terminals that use cryptocurrencies. The transmitted transaction is verified for its authenticity by a terminal called a miner (miner), and when it is approved, it is put into a block and recorded in a ledger called a block chain. In cryptocurrency transactions, transactions are prevented from being tampered with by allowing miners to perform a calculation process called mining and then adding blocks to the blockchain.

  Patent Literature 1 discloses a technique for increasing the degree of guarantee of authenticity of transaction information using such a block chain. Patent Document 2 proposes a technology that uses an electronic signature technology to realize a mechanism for proving that the power is green power.

JP 2017-207860 A JP 2011-175556 A

  By the way, in recent years, there is a growing need among companies and local governments to actively use renewable energy power (hereinafter referred to as “renewable power”). In the background, it can be assumed that the report to the CDP (Carbon Disclosure Project), which discloses the company's efforts to address climate change, is directly linked to the evaluation of shareholders including institutional investors. . Here, “traceability (specification of power source)” is required for the requirement for using renewable energy, but such a technology has not yet existed. That is, once the generated power enters the power network (power transmission network), it is assimilated with other power, so that it is no longer possible to specify the power source.

  Therefore, an object of the present invention is to provide a technique capable of securing traceability of renewable power.

According to the present invention, it includes a supplier terminal connected to a power generator and managed by a supplier, a consumer terminal managed by a consumer who wants to use the power generated by the power generator, and a transaction history generation terminal. , A power trading history generation system,
The supplier terminal notifies the transaction history generation terminal of a supply amount to be transmitted to a predetermined power network among power generated by the power generation device,
The transaction history generation terminal issues a transaction currency corresponding to the notified supply amount and sends it to a supplier wallet of the supplier,
The consumer terminal notifies the transaction history generation terminal of a demand amount received from the supplier via the predetermined power network,
The transaction history generation terminal generates a transaction of the transaction currency corresponding to the demand amount and notifies the transaction to the supplier terminal,
The supplier terminal sends a predetermined amount of the transaction currency from the supplier wallet to the demand-side power receiver wallet based on the transaction.
An electric power trading history generation system is obtained.

  According to the present invention, it is possible to provide a renewable power P2P transaction platform with traceability, and to prevent tampering of the history by further utilizing blockchain technology.

It is an image figure showing power selling processing of electric power by a power generator. It is an image figure showing the state where a plurality of generators and a plurality of consumers exchange electric power via an electric power network. It is a conceptual diagram showing the situation of a one-to-one power transaction between a supplier and a consumer and the movement of a token. It is a figure showing a terminal which constitutes a power transaction history generation system by an embodiment of the invention. FIG. 5 is a diagram illustrating a functional block diagram of a supplier terminal illustrated in FIG. 4. FIG. 5 is a diagram illustrating a functional block diagram of a transaction history generation terminal in FIG. 4. FIG. 5 is a diagram showing a functional block diagram of the consumer terminal of FIG. 4. FIG. 5 is a functional block diagram relating to wallet management of the transaction history generation terminal in FIG. 4. FIG. 5 is a diagram showing a functional block diagram relating to wallet management of the supplier terminal of FIG. 4. FIG. 5 is a functional block diagram illustrating wallet management of the consumer terminal of FIG. 4. It is a figure showing the flow of processing of the electric power transaction history generation system by an embodiment of the invention. It is an image figure showing the flow of electric power when the amount of demand exceeds the amount of power generation. It is an image figure showing the flow of electric power when the amount of power generation exceeds the amount of demand.

The contents of the embodiment of the present invention will be listed and described. A power transaction history generation system (hereinafter, simply referred to as “system”) according to an embodiment of the present invention has the following configuration.
[Item 1]
Power transaction history generation including a supplier terminal connected to the power generation device and managed by a supplier, a customer terminal managed by a customer who wants to use the power generated by the power generation device, and a transaction history generation terminal The system
The supplier terminal notifies the transaction history generation terminal of a supply amount to be transmitted to a predetermined power network among power generated by the power generation device,
The transaction history generation terminal issues a transaction currency corresponding to the notified supply amount and sends it to a supplier wallet of the supplier,
The consumer terminal notifies the transaction history generation terminal of a demand amount received from the supplier via the predetermined power network,
The transaction history generation terminal generates a transaction of the transaction currency corresponding to the demand amount and notifies the transaction to the supplier terminal,
The supplier terminal sends a predetermined amount of the transaction currency from the supplier wallet to the consumer wallet of the consumer based on the transaction.
Power trading history generation system.
[Item 2]
The power transaction history generation system according to item 1, wherein
The transmitted power amount and the received power amount are related to the amount of power transmitted and received within a predetermined unit time in the future,
Power trading history generation system.
[Item 3]
A power transaction history generation system according to item 1 or item 2,
The transaction history generation terminal accepts requests for the demand amount from a plurality of customer terminals, and generates the transaction corresponding to the request with the supply amount as an upper limit, respectively.
Power trading history generation system.
[Item 4]
The power transaction history generation system according to any one of item 1 to item 3,
The supplier terminal performs disposal processing of the transaction currency sent to the consumer wallet after consuming power corresponding to the demand amount,
Power trading history generation system.
[Item 5]
The power transaction history generation system according to any one of item 1 to item 3,
The transaction currency is a token generated using distributed ledger technology,
Power trading history generation system.

<Details of Embodiment>
Hereinafter, a system according to an embodiment of the present invention will be described with reference to the drawings.

<Overview>
2. Description of the Related Art In recent years, renewable energy power typified by photovoltaic power generation has been utilized by a self-consumption method and a full power selling method. FIG. 1A is an image diagram illustrating the self-consumption method. According to such a method, the generated power can be sold to a power company as surplus power when the power is left unused for home consumption. Here, when the power selling process is performed, the supplier is subjected to a predetermined payment process (including a process of offsetting with the electricity bill). On the other hand, FIG. 2B is an image diagram showing a full-amount power selling system. In such a system, large-scale power generation is often performed using a vast idle land or the like in order to sell all generated power.

  In recent years, electricity trade has been liberalized. For example, as shown in FIG. 2, it is theoretically possible to sell power generated by a plurality of suppliers 1 to a plurality of consumers 2 via a power transmission network 30. Is now possible. However, as described above, it is difficult at present to trace the power generated by each supplier once it has entered the power transmission network.

  The present invention thus realizes traceable power trading between a plurality of suppliers and a plurality of consumers. Specifically, as shown in FIG. 3, the power generated by the supplier 1 (for example, 100 kWh) is transmitted to the power transmission network 30 via a power pole or the like. When the consumer 2 uses 100 kWh of electric power in the same time zone, “electric power including the electric power generated by the supplier 1” is actually supplied from the power transmission network.

  On the other hand, on the blockchain network, a token corresponding to transmission power (power to be traded: 100 kWh) is transmitted from the wallet 100 of the supplier 1 to the wallet 200 of the consumer 2. At this time, if the tokens are traded after grasping the “in” and “out” of the power in a certain time zone (for example, the power generation amount and the demand amount in every 30 minutes), the power transaction is simulated. Can be traced.

  Further, the consumer 2 can make the act of purchasing the token have the same meaning as purchasing power from the supplier 1.

<System terminal configuration>
As shown in FIG. 4, the system according to the embodiment of the present invention includes a supplier terminal of a supplier 1 that generates power and wants to sell surplus power and a consumer terminal 2 that wants to purchase generated power. It has at least a consumer terminal and a transaction history generation terminal (terminal of a management company) that manages transactions by issuing the above-described token.

  As shown in FIG. 5, the supplier terminal includes a power generation monitoring unit, a power control unit, a surplus power management unit, and a communication unit. The power generation amount monitoring unit acquires information on the power generated from the power generation device (SQ1). The power generation device according to the present embodiment may employ, for example, a solar power generation device. In the self-consumption method described above, the power generation device supplies power to power consumption devices in the home (SQ2). Note that, for example, in the case of the full power selling method, there is no power consuming device. The power control unit obtains information on the amount of power generation from the power generation amount monitoring unit (SQ3), and separates the generated power from the power used by the power consuming device and the surplus power. The surplus power management unit receives the information on the surplus power amount from the power control unit (SQ4), manages the information on the surplus power, transmits the information to the communication unit (SQ5), and transmits the information to the transaction history generation terminal (SQ5). SQ6). The power control unit controls the power generation device based on the breakdown of the power used in the home and the surplus power to supply power to the power consuming device (SQ2) and transmits the surplus power to the power transmission network (SQ8). ).

  As shown in FIG. 6, the transaction history generation terminal includes a communication unit, a conversion unit, a Token management unit, and a Token issuing unit. The communication unit acquires information on the amount of power generation from the above-mentioned supplier terminal (SQ9). The conversion unit receives information on the amount of power generation from the communication unit (SQ10), and calculates the number of tokens from the amount of power generation based on a predetermined rate. In the present embodiment, it is assumed that 100 kWh = 100 tokens to simplify the description. The conversion rate may be a fixed rate or a variable rate. Upon acquiring the converted information (SQ11), the token management unit manages and stores the number of tokens to be issued, together with information such as issued token information and to whom and how many. The number of tokens to be issued is transmitted to the token issuing unit (SQ12), and the issued token and destination information are sent to the communication unit (SQ13). The communication unit sends the issued Token to the supplier wallet associated with the supplier (SQ14).

  As shown in FIG. 7, the consumer terminal includes a power demand receiving unit and a communication unit. The power demand receiving unit uses, for example, a device such as a smart meter, which has a function of measuring and recording the amount of electricity used every 30 minutes and a communication function, thereby making it possible to reduce the power consumption of the entire consumer's home. Obtain demand data (SQ15). The data is sent to the power demand receiving unit (SQ16). Calculate (predict) power demand. The calculated power demand is transmitted to the communication unit (SQ17), and further transmitted to the transaction history generation terminal (SQ18). The power consuming device of the consumer is supplied with power from the power transmission network (SQ19).

  Next, the wallet management configuration of the transaction generation terminal will be described with reference to FIG. As illustrated, the transaction history generation terminal includes a communication unit and a transaction generation unit. The communication unit obtains information about the demand amount from the consumer terminal (SQ20). The transaction generation unit calculates the number of tokens that the consumer should receive from the supplier based on the predetermined rate for the demand amount. The conversion rate may be a fixed rate, a fluctuating rate, or a rate condition different from the rate used for the above-described calculation of the supplier. The information of Token is transmitted to the communication unit (SQ22) and transmitted to the supplier terminal (SQ23).

  The wallet management configuration of the supplier terminal will be described with reference to FIG. As shown in the figure, the supplier terminal includes a communication unit, a wallet management unit, and a transaction execution unit. The communication unit receives the transaction information from the transaction history generation terminal (SQ24). The received transaction information is transmitted to the wallet management unit that manages the wallet of the supplier (SQ25), and the transaction is executed based on the transaction information (SQ26). The supplier's Token is sent to the consumer's wallet based on the executed transaction (SQ27 and SQ28).

  The wallet management configuration of the consumer terminal will be described with reference to FIG. As illustrated, the consumer terminal includes a communication unit, a wallet management unit, and a power consumption monitoring unit. The communication unit receives Token regarding the execution of the transaction by the supplier (SQ29). The wallet management unit manages the number of tokens received (SQ30). The token that has been received has, so to speak, properties such as the right to use the electricity generated by the supplier. Accordingly, upon receiving the information about Token (SQ31), the power consumption monitoring unit acquires the power demand data of the entire home and checks whether the received amount of electricity corresponding to Token has been used up.

  FIG. 11 is a diagram summarizing the above flow into a processing flow. First, the supplier terminal notifies the power generation amount to the transaction history generation terminal (SQ601). Token corresponding to the power generation amount is sent from the wallet of the transaction history generation terminal to the wallet of the supplier (SQ603). On the other hand, the consumer terminal notifies the transaction history generation terminal of the demand amount (SQ605). The transaction history generation terminal generates a transaction for sending Token corresponding to the demand from the supplier to the consumer (SQ607). The generated transaction information is transmitted from the transaction history generation terminal to the supplier terminal as a transaction instruction (SQ609). In response to the transaction, the necessary token is sent from the wallet of the supplier terminal to the wallet of the consumer terminal (SQ611).

  In the above-described embodiment, the amount of power generation and the amount of demand match. The following description is for the case where they do not match. As shown in FIG. 12, for example, when the supplier 1 generates 100 kWh of power, 100 Tokens are sent to the consumer 2. The consumer can use 100 kWh of power by trading (purchasing) 100 tokens. However, since the demand of the customer 2 is 120 kWh, it is not enough to consider only the power generation of the supplier (100 kWh). Thus, when the demand amount exceeds the power generation amount, the shortage of the demand amount may be received from the power transmission network 30 as usual.

  On the other hand, when the amount of power generation exceeds the amount of demand, as shown in FIG. 13, the power may be supplied to another customer 2a. It may be returned to the network (power sale).

  The embodiment described above is merely an example for facilitating the understanding of the present invention, and is not intended to limit and interpret the present invention. The present invention can be changed and improved without departing from the spirit thereof, and it goes without saying that the present invention includes equivalents thereof.

DESCRIPTION OF SYMBOLS 1 Supplier 2 Consumer 3 Power generator 30 Transmission network 100 Supplier wallet 200 Consumer wallet

Claims (4)

A power transaction history generation system between a plurality of power generators and a plurality of consumers,
A supply terminal of the supplier connected to the power generating device manages, the consumer terminal that the consumer wishing to utilize the power generated by the power generation device manages, seen including a transaction history generation terminal,
For each of the power generation devices, the supplier terminal notifies the transaction history generation terminal of a supply amount to be transmitted within a predetermined unit time to a predetermined power network among power generated by the power generation device,
The transaction history generation terminal issues a transaction currency corresponding to the notified supply amount and sends it to a supplier wallet of the supplier,
For each of the consumers, the customer terminal notifies the transaction history generation terminal of a demand amount that the customer receives within the unit time via the predetermined power network,
The transaction history generation terminal, as well as accept requests for a plurality of consumers from said terminal demand, the supply amount to a maximum of transactions respectively generate the transaction currency corresponding to the demand from a plurality of the power generation device And notify the supplier terminal,
Wherein each of the supply terminal s can send the transaction currency of a predetermined amount from the supplier wallet on the basis of the transaction, the consumer wallet of the corresponding consumer,
Power trading history generation system. The power transaction history generation system according to claim 1,
The transmitted power amount and the received power amount is related amount of power transmission and power reception in the future of the unit time,
Power trading history generation system. The power transaction history generation system according to claim 1 or 2 ,
The supplier terminal performs disposal processing of the transaction currency sent to the consumer wallet after consuming power corresponding to the demand amount,
Power trading history generation system. The power transaction history generation system according to any one of claims 1 to 3, wherein
The transaction currency is a token generated using distributed ledger technology,
Power trading history generation system.