JP7225823B2 - Electric power transaction management method, program, and electric power transaction management system - Google Patents

Description

The present invention provides an electric power transaction management method, a program, and an electric power transaction management suitable for providing consumers with an environmental value certificate certifying that they have made a transaction with a power generation business that generates power using renewable energy. Regarding the device.

Demand for so-called CO2 _- free power, which supplies power without burning natural energy or fossil fuels such as petroleum and coal, is increasing worldwide these days.
These alternatives to thermal power generation using conventional fossil fuels also have value in terms of reducing _CO2 emissions, so they are called the "environmental value (or environmental added value)" of electricity. .
In order to reduce carbon dioxide emissions, government agencies and local governments are working to separate this environmental value from electricity trading, and to enable trading and buying and selling of environmental value between power generators and consumers. system is in operation.

In Japan, the following systems are known for the certification of environmental value.
(1) Green Power Certificates are adopted by the Green Energy Certification Center of the Institute of Energy Economics, Japan, a third-party organization, to formulate certification standards and certify facilities. Also known as method. Many organizations are registered as certificate issuers, and some of them are registered as new electric power companies. It is a mechanism in which the amount equivalent to the purchased certificate is indirectly regarded as having used green power.
(2) J-credits are operated by the Ministry of Economy, Trade and Industry, the Ministry of the Environment, and the Ministry of Agriculture, Forestry and Fisheries, and are used not only for clean energy created with renewable energy sources, but also for energy that could be reduced through new energy-saving equipment, forests, etc. Credits are issued for broader eco-actions, such as the amount of carbon dioxide absorbed through management and afforestation. The credits can be sold, like Green Power Certificates, to companies that need to meet their obligations to reduce their carbon footprint. The J-credit system was created by integrating and succeeding the existing domestic credit system and the offset credit system (J-VER system).
(3) A non-fossil certificate is a certificate obtained by separating the non-fossil value of electricity generated by a non-fossil power source. Non-fossil power sources include renewable energy and nuclear power. For non-fossil certificates, since the purchase period under the FIT system will end in November 2019, new business needs related to FIT power sources are increasing.

By the way, as an example of proof of the above-mentioned environmental value, a technique for issuing value information is disclosed in Patent Document 1.
In Patent Document 1, with the aim of providing a system using value information that also functions as a virtual currency, the server computer of the value information exchange is equipped with cryptographic means. Encrypted value information (virtual currency) is issued with the purchased power supply guarantee information as the backing of the value. When a company wants to use virtual currency for value information issued by an exchange as a currency for commercial transactions, a technology is disclosed in which a client computer accesses a server computer of the exchange via communication means in order to purchase the value information. It is

Japanese Patent Application Laid-Open No. 2016-031630

However, in any of the above systems (1) to (3), a third party intervenes between the power producer and the consumer. In addition, each system has the following problems.
(1) Green Power Certificates and J-credits are for non-FIT power sources, and the trading volume is small. In addition, there is a problem that it is difficult for the consumer to understand under what means and under what circumstances the certificate was obtained.
(2) Non-fossil certificates have the problem that the type of power generation cannot be specified. In addition, this system is for retail electric power companies, and consumers do not trade directly.
Further, in Patent Document 1, a third party intervenes, such as an exchange that issues value information that also functions as a virtual currency.
Therefore, it is strongly desired to clearly prove that the transaction has been made with a power generation company that generates power by means of power generation using renewable energy for the environmental value that reaches the consumer.
One embodiment of the present invention has been made in view of the above, and its purpose is to clarify that the certificate of environmental value delivered to the customer has been traded with a power generation business that generates power by means of power generation using renewable energy. to testify.

In order to solve the above problems, the invention according to claim 1 is a transaction that stores and manages a power generation business account owned by a power generation business operator and a consumer account owned by a consumer in a distributed ledger on a database. Using a system in which a management server and a certificate issuing server are connected to each other via a network, the power generation company that generates power by means of power generation using renewable energy sells power to the consumer. an electric power transaction management method for providing a terminal of the consumer with an environmental value certificate proving that the consumer is using the power generation means, wherein the transaction management server comprises the power generation business operator a granting step of granting an amount of environmental value tokens corresponding to the reverse flow power amount data to the power generation business account based on the reverse flow power amount data received from the power generation business power meter of the power generation business operator; and a transfer step of transferring the environmental value token from the power generation company account on the database to the consumer account when a transaction is established between the certificate issuing server and the consumer. and issuing the environmental value certificate based on the environmental value token transferred from the power generation business account to the consumer account when an application instruction for the environmental value certificate is received from the consumer 's terminal . , and an issuing step of transmitting the environmental value certificate to the terminal of the consumer .

According to the present invention, it is possible to clearly prove, in the environmental value certificate delivered to the consumer, that the transaction has been made with a power generation company that generates power using renewable energy.

1 is a block diagram showing a schematic configuration of a transaction management system according to a first embodiment of the invention; FIG. It is a block diagram showing a schematic structure of a transaction management server used in the transaction management system according to the first embodiment of the present invention. 1 is a functional block diagram showing schematic functions of a transaction management system according to a first embodiment of the present invention; FIG. It is a diagram showing a block chain in a distributed ledger managed by the transaction management system according to the first embodiment of the present invention. FIG. 4 is a sequence diagram showing the flow of transactions using the transaction management system according to the first embodiment of the present invention; FIG. 11 is a sequence diagram showing the flow of transactions using the transaction management server according to the second embodiment of the present invention;

BEST MODE FOR CARRYING OUT THE INVENTION The present invention will now be described in detail with reference to embodiments shown in the drawings.
The present invention has the following configuration in order to clearly prove that the certificate of environmental value delivered to the consumer has made a transaction with a power generator that generates power using renewable energy.
That is, the power transaction management method of the present invention uses a distributed ledger blockchain network that manages accounts for power generation companies and accounts for consumers, so that power generation companies that generate power by means of power generation using renewable energy , an electric power transaction management method that, when electric power is sold to a consumer, provides the consumer with an environmental value certificate proving that the consumer is using the means of power generation, wherein the reverse power flow of the power generation company A granting step of granting an amount of environmental value tokens equivalent to the reverse flow power data to the power generation business account based on the power data, and when a transaction is established between the power generation business and the consumer, In the transfer step of transferring the environmental value token from the power generation business account to the consumer account, and when receiving a request for issuing an environmental value certificate from the consumer, the environmental value token transferred to the consumer account is transferred to the environmental value token. and an issuing step of issuing a value certificate.
By providing the above configuration, it is possible to clearly prove that the customer has made a transaction with a power generation company that generates power using renewable energy in the environmental value certificate delivered to the consumer.
The features of the invention described above will be explained in detail with reference to the following drawings. However, unless there is a specific description, the components, types, combinations, shapes, relative arrangements, and the like described in this embodiment are merely illustrative examples and not intended to limit the scope of the present invention. .
The features of the present invention described above will be described in detail below with reference to the drawings.

<First Embodiment>
Next, embodiments of the present invention will be described with reference to the drawings.
<Transaction management system>
FIG. 1 is a block diagram showing a schematic configuration of a transaction management system according to the first embodiment of the invention.
The transaction management system 1 includes a distributed ledger block chain network 2, a transaction management server 10, a power generator personal computer 12, a power generator power meter 14, and a consumer personal computer 18, which are connected to each other via a network N1.
The distributed ledger blockchain network 2 has a parent account 36 owned by the platform provider, a power generator account 38 owned by the power generator H, and a consumer account 40 owned by the consumer J as accounts that are addresses on the wallet. are stored, and are handed over to environmental value tokens at the time of transaction.

The deposit/withdrawal server 4 receives the consumer's account 40 and the amount X yen from the consumer's personal computer 18 . The deposit/withdrawal server 4 deposits an amount of X yen to the customer's account 40 received from the customer's personal computer 18, and stores the amount of X yen corresponding to the customer's account 40 on the database DB30. The deposit/withdrawal server 4 accepts a contract in accordance with the contract acceptance instruction received from the transaction management server 10 .
The deposit/withdrawal server 4 withdraws X yen from the customer J's account and deposits X yen into the power generator H's account. At this time, the deposit/withdrawal server 4 collects, for example, a fixed amount of 105 yen per order from the customer J's account and the power generator H's account as a commission.
The deposit/withdrawal server 4 acquires a power generation company account by referring to the conversion table using the power generation company ID received from the power generation company personal computer 12 as a key. The deposit/withdrawal server 4 withdraws the amount of X yen to the bank account number of the power generation business operator H, and subtracts the amount of X yen from the deposit amount corresponding to the power generation business account on the database DB30. The deposit/withdrawal server 4 transmits an e-mail including a message to the effect that the payment has been processed to the personal computer 12 of the power generation company.

The certificate issuing server 8 accepts the consumer account 40 and the environmental value certificate application instruction received from the consumer personal computer 18 . The certificate issuing server 8 generates an environmental value certificate including the contents of the latest environmental value token for the customer's account 40 in response to the environmental value certificate application instruction, and transmits the environmental value certificate to the customer's personal computer.
The certificate issuing server 8 generates an environmental value certificate by referring to the environmental value token given from the power generation company account 38 to the consumer account 40 . The certificate issuing server 8 refers to the conversion table using, for example, the input side (In) power generation company account 38 and the output side (Out) consumer account 40 described in block # 005 to be described later as keys. Convert to power generation business name and consumer name, and generate an environmental value certificate representing that consumer J with a certain consumer name purchased a certain token value from power generation business H with a certain power generation business name do.

The transaction management server 10 manages a power generation business account and a consumer account, and when a power generation business that generates power using renewable energy power generation means sells power to consumers, the transaction management server 10 The consumer is provided with an environmental value certificate that proves that the house is using the power generation means.
Note that the distributed ledger blockchain network 2 may be configured as a private distributed ledger by providing it in the content of a local network operated by an electric power company.
The power generation company personal computer 12 is a personal computer that the power generation company H can operate.
The power generator H's power meter 14 is a meter for measuring the power generated by the power generator H using, for example, a solar panel and supplied to the distribution line 16 by reverse power flow.
The consumer personal computer 18 is a personal computer that can be operated by the consumer J. FIG.

<Transaction management server>
FIG. 2 is a block diagram showing a schematic configuration of a transaction management server used in the transaction management system according to the first embodiment of the invention.
The transaction management server 10 includes an operation section 22 , a communication section 24 , a display control section 26 , a display section 28 , a database DB 30 and a main control section 32 .
The operation unit 22 includes a keyboard, a mouse, and the like.
The communication unit 24 communicates data with the power generator personal computer 12 via the network N1 and communicates data with the consumer personal computer 18 via the network N1.

The display control unit 26 draws an image input from the main control unit 32 on the VRAM and causes the display unit 28 to display the image.
The display unit 28 displays images drawn on the VRAM by the display control unit 26 .
The database DB30 stores a parent account 36 owned by the platform provider, a power generator account 38 owned by the power generator H, and a consumer account 40 owned by the consumer J.

The main control unit 32 internally includes a CPU (central processing unit) 32a, a ROM (read only memory) 32b, and a RAM (random access memory) 32c. The CPU 32a reads the operating system OS from the ROM 32b, expands it on the RAM 32c, starts the OS, reads programs (processing modules) from the ROM 32b, and executes various processes under the control of the OS.
Note that the deposit/withdrawal server 4 and the certificate issuing server 8 provided in the transaction management system 1 have the same configuration as the transaction management server 10, so the description thereof will be omitted.

<Functional block diagram>
FIG. 3 is a functional block diagram showing schematic functions of the transaction management system according to the first embodiment of the present invention.
<Flow of Environmental Value Token>
The flow of environmental value tokens in the distributed ledger shown in FIG. 3 will be described.
The distributed ledger blockchain network 2 has a parent account 36 owned by the platform provider, a power generator account 38 owned by the power generator H, and a consumer account 40 owned by the consumer J as accounts that are addresses on the wallet. are stored, and are handed over to environmental value tokens at the time of transaction.
(1) In the provision step S2, in the distributed ledger blockchain network 2, based on the reverse flow power amount data D received by the parent account 36 from the power generator power meter 14, the amount corresponding to the reverse flow power amount data D environmental value token 37 is given to the power generation company account 38 .

(2) In the transfer step S4, when a transaction is established between the power generation business operator H and the consumer J regarding the amount of electric power required by the consumer J, the power generation business operator account 38 is transferred to the consumer account 40. to the environment value token 39 .
(3) In the returning step S6, when the parent account 36 issues the environmental value certificate in response to a request from the consumer J, the environmental value token of the amount corresponding to the required electric energy is transferred from the consumer account 40 to the parent account. Return to 36.

The configuration and operation of each processing unit shown in FIG. 3 will be described.
In each server provided in the system shown in FIG. has a return part 2a.
Power generation means using renewable energy using the distributed ledger blockchain network 2 that manages the power generation business account 38 and the consumer account 40 according to the power transaction management method controlled by the main control unit 32 When a power generation company H sells electric power to a consumer J, it provides the consumer J with an environmental value certificate proving that the consumer J is using the means of power generation.
Based on the reverse flow power amount data of the power generation company H, the granting unit 10a grants an amount of environmental value tokens corresponding to the reverse power flow power amount data to the power generation company account 38 (S18).
The transfer unit 10b transfers the environmental value token from the power generation business operator account 38 to the consumer account 40 when a transaction is established between the power generation business operator H and the consumer J (S38).
The issuing unit 8c issues an environmental value certificate based on the environmental value token transferred to the customer account 40 when receiving the environmental value certificate issuance request from the consumer J (S54).

Specifically, the issuing unit 8c issues an environmental value certificate using the power generation company name, consumer name, transaction price, and usage date and time range included in the environmental value token transferred to the consumer account 40. FIG.
When receiving an environmental value certificate issuance request from consumer J, the determination unit 8d adds It is determined whether or not there is a usage date and time range that has been used. At this time, the determination unit 8d determines the date and time of issuance of the environmental value certificate, which is the history information acquired from the storage unit 8e, separately from the power generation business name, consumer name, transaction price, and usage date and time range at the time of previous issuance. It is determined whether or not there is an additional usage date and time range.
If there is an additional use date and time range as a result of the judgment by the judgment unit 8d, the issuing unit 8c provides the power generation business name, the consumer name, the transaction price, And issue an environmental value certificate using the date and time range of use.
The storage unit 8e stores the date and time of issuance of the environmental value certificate as history information.
The issuing unit 8c does not issue a new environmental value certificate if the result of determination by the determination unit 8d is that there is no additional usage date and time range.

When the issuing unit 8c issues the environmental value certificate, the return unit 2a subtracts the transaction value token corresponding to the commission from the customer account 40, thereby returning the transaction value environment value token to the parent account. .

<Structure of Environmental Value Token>
FIG. 4 is a diagram showing a blockchain in a distributed ledger managed by the transaction management system according to the first embodiment of the invention.
A blockchain is established by connecting sequentially generated transaction information in block units.
In other words, in blockchain technology, data (a collection of data) whose content is to be guaranteed, such as transaction records and contracts, is handled in units of blocks. A block chain is a chain of these blocks connected in a predetermined way. A hash function is used to generate a block chain, and the hash function is a function for obtaining a fixed-length hash value for arbitrary data of arbitrary length.
Hash functions have the characteristic of being one-way, and it is easy to obtain a hash value from arbitrary data, but conversely, it is said that it is practically impossible to restore the original data from a hash value. be.

Each block shown in FIG. 4 has a block number, a header describing a transaction, a prehash describing the hash value of the previous block, In representing the input side, and an output side. , and a transaction describing an Out representing a value and a Value representing a value. Note that the hash value is also called a transaction ID in blockchain technology.
Note that the value can be changed in units of 0.01 since the minimum unit of the electric power meter is the second decimal place.

In order to connect a new block to the blockchain, the hash value of the previous block in the chain and the transaction data of the new block to be connected are combined into data called a Merkle root, called a nonce value. A nonce value is obtained such that the upper several bits (eg 10 bits) are 0 when a hash value (eg SHA-256 hash) is calculated for data in which numeric values (eg 32-bit fixed-length numeric values) are connected.
In order to connect a new block to the blockchain, the hash value of the previous block in the chain and the transaction data of the new block to be connected are combined into data called a Merkle root, called a nonce value. A nonce value is obtained such that the upper several bits (eg 10 bits) are 0 when a hash value (eg SHA-256 hash) is calculated for data in which numeric values (eg 32-bit fixed-length numeric values) are connected.

In such a blockchain, each block has the hash value of the previous block, so it is possible to confirm the validity of all blocks by tracing them in order from the tip (the oldest starting point). I can.
If you try to tamper with a block in the middle, it is necessary to recalculate the Nonce values of all blocks after that block. .
These features ensure the reliability of blockchain.

(1) Block #002 (Block #002) shown in FIG. 4 is an environmental value token given from the parent account 38 to the power generation company account 38 in the above-described giving step. Block #002 contains a block number, a header describing the transaction, a prehash describing the hash value of the previous block (Prev Hash), the input side (In) as the parent account 38, and the output side (Out). ) is described as a power generation business operator, and a transaction (Tr#002-01) in which, for example, one token is described as a value.

(2) Block #005 (Block #005) shown in FIG. 4 is an environmental value token that is given from the power generation company account 38 to the consumer account 40 by the transfer step described above. Block #005 includes a block number, a header describing the transaction, a prehash describing the hash value of the previous block (Prev Hash), an input side (In) for the power generation business account 38, and an output A transaction (Tr#005-01) in which the side (Out) is the consumer account 40 and the value is one token, for example, is described.
(3) Block #010 (Block #010) shown in FIG. 4 is an environment value token given from the customer account 40 to the parent account 38 in the above-described giving step. Block # 010 includes a block number, a header describing the transaction, a prehash describing the hash value of the previous block (Prev Hash), the input side (In) for the customer account 40, and the output side ( Out) is the parent account 38, and a transaction (Tr#010-01) describing, for example, 1 token as a value is described.

By recording the input side, output side, value, etc. on the distributed ledger, one of the advantages of the distributed ledger is excellent traceability. By ensuring the transparency of the transaction, the consumer J can make it clear that he/she is certainly purchasing the environmental value from the power generator H, which has a high environmental value.
As a result, the environmental value delivered to the consumer J can clearly indicate with which power generator H the transaction has been made.

<Sequence diagram>
FIG. 5 is a sequence diagram showing the flow of transactions using the transaction management system according to the first embodiment of the present invention. Note that each unit shown in FIG. 5 may be implemented as smart contract processing.
In step S10, the consumer personal computer 18 designates the consumer account 40, which is an account opened on the platform of the transaction management server 10 managed by the electric power company, and deposits the Japanese yen (JPY) amount X yen. do.
In step S<b>12 , the deposit/withdrawal server 4 of the transaction management server 10 receives the customer account 40 and the amount X yen from the customer personal computer 18 .
In step S14, the deposit/withdrawal server 4 deposits an amount of X yen into the customer's account 40 received from the customer's personal computer 18, and stores the amount of X yen corresponding to the customer's account 40 on the database DB30.

<Grant processing>
In step S16, the power generator power meter 14 measures the power supplied from the power generator H to the distribution line 16 by reverse power flow, and adds the meter ID of the power meter to the power value KWA to obtain actual power generation data. , to the transaction management server 10 .
In step S<b>18 , the transaction management server 10 of the transaction management server 10 receives the power value KWA and the meter ID of the power meter from the power generator power meter 14 . Furthermore, the transaction management server 10 calculates the value of the environmental value token according to the received power value KWA using the hash value of the previous block, and obtains the power generation company account according to the received meter ID. , to grant environmental value tokens.
In step S20, the distributed ledger blockchain network 2 records the value of the environmental value token in the distributed ledger on the database DB30 in association with the account for the power generation company.

<Movement processing>
In step S22, the distributed ledger blockchain network 2 transfers the value of the environmental value token from the parent account to the power generation company account.
In step S24, the power generation company personal computer 12 transmits to the transaction management server 10 sales order data including the time zone of the electricity that can be sold, the power value KWA, and the power generation company ID unique to the power generation company H.
<Buy order>
In step S26, the transaction management server 10 of the transaction management server 10 accepts the sell order data received from the power generator personal computer 12 and stores it in the work area of the RAM 32c and the database DB30.
On the other hand, in step S28, the consumer's personal computer 18 transmits to the transaction management server 10 the purchase order data including the time zone for the power that can be purchased, the power value KWA, and the consumer ID unique to the consumer J. FIG.
At this time, the transaction management server 10 passes the transaction ID (hash value) to the consumer's personal computer 18 .
In step S30, the transaction management server 10 of the transaction management server 10 accepts the purchase order data received from the customer's personal computer 18 and stores it in the work area of the RAM 32c and the database DB30.

<Contract processing>
In step S32, the transaction management server 10 compares the sell order data of the power generation company H with the buy order data of the customer J as contract processing, and concludes when the buy order data of the customer J is satisfied.
The transaction management server 10 makes a contract by the Itayose method or Zaraba method as the contract processing.
In the Itayose method, trading is established at a price that satisfies the following three conditions.
(Condition 1) All market sell orders and buy orders are executed.
(Condition 2) All buy orders higher than the execution price and sell orders lower than the execution price are executed.
(Condition 3) At the execution price, both sell orders and buy orders are executed.
In the Zaraba method, a trade is executed when the price of an already placed sell order (or buy order) matches the price of a newly placed buy order (or sell order).
The transaction management server 10 stores, in the work area of the RAM 32 c and the database DB 30 , the result of the execution or non-execution of the contract by the Itayose method or Zaraba method.

In step S34, the transaction management server 10 determines whether or not a contract is established as a result of the contract processing in step S32. If the contract has not been concluded, the process proceeds to step S36 to cancel the corresponding order.
On the other hand, if the contract is concluded, the transaction management server 10 proceeds to step S38, generates a token transfer instruction to transfer the environmental value token, and outputs it to the distributed ledger blockchain network 2. At the same time, the transaction management server 10 generates a contract acceptance instruction and outputs it to the deposit/withdrawal server 4 .

In step S40, the distributed ledger blockchain network 2 records in the distributed ledger on the database DB30 a token transfer instruction to transfer the environmental value token from the power generator account to the consumer account 40.
In step S42, in the distributed ledger blockchain network 2, as shown in the movement step S4 described above, a transaction is established between the power generator H and the consumer J regarding the required amount of electric power required by the consumer J. If so, the environment value token is transferred from the power generation company account 38 to the consumer account 40 .
Here, in the distributed ledger blockchain network 2, the environment value token moves from the power generation company account 38 to the consumer account 40 as shown in Block #005 in FIG. Block #005 includes a block number, a header describing the transaction, a prehash describing the hash value of the previous block (Prev Hash), an input side (In) for the power generation business account 38, and an output A transaction (Tr#005-01) in which the side (Out) is the consumer account 40 and the value is one token, for example, is described.

On the other hand, in step S<b>44 , the deposit/withdrawal server 4 accepts a contract in accordance with the contract acceptance instruction received from the transaction management server 10 .
In step S46, the deposit/withdrawal server 4 withdraws X yen from the customer J's account and deposits X yen into the power generator H's account. At this time, the deposit/withdrawal server 4 collects a fixed amount of 105 yen per order from the customer J's account and the power generator H's account as a commission. Instead of collecting a fixed amount, a commission of, for example, 3% of the transaction amount X yen may be collected from each account. The processing result in step S46 is stored in the database DB30.

<Application for Environmental Value Certificate>
In step S50, the consumer personal computer 18 accesses the home page by designating the web address (URL) of the transaction management server 10, and clicks on the "Environmental value certificate application" tab located on the home page. An input area for entering 40 is displayed. When the consumer account 40 specific to the consumer J is entered in this input area and the “Send” button is clicked, the consumer account 40 and the application instruction for the environmental value certificate are sent to the transaction management server 10 .
In step S52, the certificate issuing server 8 of the transaction management server 10 accepts the consumer's account 40 and the environmental value certificate application instruction received from the consumer's personal computer 18. FIG.

In step S54, the certificate issuing server 8 generates an environmental value certificate including the contents of the latest environmental value token for the customer's account 40 in response to the environmental value certificate application instruction, and transmits the environmental value certificate to the customer's personal computer.
Here, the certificate issuing server 8 refers to block #005 (Block #005) shown in FIG. to generate environmental value certificates. The certificate issuing server 8 uses the input side (In) power generation business account 38 and the output side (Out) consumer account 40 described in block #005 as keys, and refers to the conversion table to determine the respective power generation business operators. name and consumer name, and generates an environmental value certificate representing that a certain token value has been purchased by a consumer J with a certain consumer name from a power generator H with a certain power generator name.
In step S56, the consumer's personal computer 18 may display the environmental value certificate received from the certificate issuing server 8 on the monitor, print it on the printer, or store it in the hard disk.

On the other hand, in step S58, the distributed ledger blockchain network 2 receives the fact that the certificate issuing server 8 has generated the environmental value certificate and records it in the distributed ledger. That is, the distributed ledger blockchain network 2 records, in the distributed ledger on the database DB30, a token transfer instruction to transfer the environmental value token from the consumer account 40 to the parent account.
In step S60, the distributed ledger blockchain network 2 moves the environment value token from the consumer account 40 to the parent account 38 as shown in Block #010 in FIG. Block # 010 includes a block number, a header describing the transaction, a prehash describing the hash value of the previous block (Prev Hash), the input side (In) for the customer account 40, and the output side ( Out) is the parent account 38, and a transaction (Tr#010-01) describing, for example, 1 token as a value is described.

<Withdrawal application>
In step S70, the power generation company personal computer 12 sends payment application data including a power generation company ID specific to the power generation company H, a withdrawal amount of X yen, and a bank account number of the withdrawal destination to the transaction management server 10. Send.
In step S<b>72 , the deposit/withdrawal server 4 of the transaction management server 10 receives the withdrawal application data from the personal computer 12 of the power generation company.
In step S74, the deposit/withdrawal server 4 uses the power generation company ID received from the power generation company personal computer 12 as a key and refers to the conversion table to acquire the power generation company account. The deposit/withdrawal server 4 withdraws the amount of X yen to the bank account number of the power generation business operator H, and subtracts the amount of X yen from the deposit amount corresponding to the power generation business account on the database DB30. The deposit/withdrawal server 4 transmits an e-mail including a message to the effect that the payment has been processed to the personal computer 12 of the power generation company.
In step S76, after confirming the e-mail received from the transaction management server 10, the power generator personal computer 12 accesses the bank account of the power generator H and displays the amount deposited in the bank account.

According to the first embodiment, it is possible to clearly prove that the transaction has been made with a power generator that generates power using renewable energy in the environmental value certificate delivered to the consumer.
In addition, by issuing an environmental value certificate using the power generation company name, consumer name, transaction value, and usage date and time range included in the environmental value token, renewable energy was used for the environmental value certificate delivered to the consumer. It is possible to clearly prove that the transaction was made with a power generation company that generates power by means of power generation.
In addition, the parent account can obtain from the consumer account a transaction value equivalent to the fee for issuing the environmental value certificate.

<Second embodiment>
<Sequence diagram>
FIG. 6 is a sequence diagram showing the flow of transactions using the transaction management server according to the second embodiment of the present invention.
The transaction management server 10 according to the second embodiment of the present invention is applied to the technical items shown in FIGS. 1 to 5 described in the first embodiment. Also, in the present embodiment, the sequence diagram shown in FIG. 6 shows the processing after steps S10 to S42 shown in FIG. 5 have been executed.

<Application for Environmental Value Certificate>
In step S100, the consumer personal computer 18 accesses the home page by designating the web address (URL) of the transaction management server 10, and clicks on the "Environmental Value Certificate Application" tab located on the home page. An input area for entering 40 is displayed. When the consumer account 40 specific to the consumer J is entered in this input area and the “Send” button is clicked, the consumer account 40 and the application instruction for the environmental value certificate are sent to the transaction management server 10 .
In step S 102 , the certificate issuing server 8 of the transaction management server 10 accepts the consumer account 40 and the environmental value certificate application instruction received from the consumer personal computer 18 .

In step S104, the certificate issuing server 8 outputs a confirmation instruction including the consumer account 40 received from the consumer personal computer 18 to the distributed ledger blockchain network 2, thereby confirming the content added to the consumer account 40. do.
In step S<b>106 , the distributed ledger blockchain network 2 confirms the additional content to the consumer account 40 included in the confirmation instruction, and outputs the confirmation result to the certificate issuing server 8 .
At step S108, the certificate issuing server 8 determines whether or not there has been an addition since the previous issue. Here, when receiving a request for issuance of an environmental value certificate from consumer J, the determination unit 8d, apart from the power generation business name, consumer name, transaction price, and usage date and time range at the time of the previous issuance, It is determined whether or not there is an additional use date and time range. At this time, the judging unit 8d judges whether or not there is an additionally used range of dates and times of use in the date and time of issuance of the environmental value certificate, which is the history information acquired from the storage unit 8e.
The certificate issuing server 8 proceeds to step S110 if there has been an addition since the previous issuance, and on the other hand, if there has been no addition since the previous issuance, instructs the customer's personal computer 18 to cancel the application instruction for the environmental value certificate. Send.
In step S112, the issuing unit 8c of the consumer personal computer 18 does not issue a new environmental value certificate if the determining unit 8d determines that there is no additional usage date and time range. That is, the application instruction for the environmental value certificate issued by the consumer's personal computer 18 in step S100 is cancelled.

In step S110, the certificate issuing server 8 generates an environmental value certificate including the contents of the latest environmental value token for the consumer account 40 in response to the environmental value certificate application instruction, and transmits the environmental value certificate to the consumer personal computer.
Here, the certificate issuing server 8 refers to block #005 (Block #005) shown in FIG. to generate environmental value certificates. The certificate issuing server 8 uses the input side (In) power generation business account 38 and the output side (Out) consumer account 40 described in block #005 as keys, and refers to the conversion table to determine the respective power generation business operators. name and consumer name, and generates an environmental value certificate representing that a certain token value has been purchased by a consumer J with a certain consumer name from a power generator H with a certain power generator name.
In step S114, the consumer's personal computer 18 may display the environmental value certificate received from the certificate issuing server 8 on the monitor, print it on the printer, or store it in the hard disk.

According to the second embodiment, if there is an additional usage date and time range, the power generation business name, consumer name, transaction price, and usage date and time range in the additionally used usage date and time range are used. environmental value certificate can be issued.
In addition, by storing the date and time of issuance of the environmental value certificate as history information, it is possible to determine whether or not there is a range of dates and times of use that has been additionally used.
Furthermore, if there is no additional usage date and time range, by not issuing a new environmental value certificate, it is possible to avoid duplicate environmental value certificates to be issued.

<Summary of Actions and Effects of Mode Examples of the Present Embodiment>
<First aspect>
The power transaction management method of this embodiment uses the distributed ledger block chain network 2 that manages the power generation business account 38 and the consumer account 40, and the power generation business that generates power using renewable energy. An electric power transaction management method for providing, when H sells electric power to consumer J, to consumer J an environmental value certificate proving that consumer J is using a means of power generation, wherein: a granting step (S18) of granting an amount of environmental value tokens corresponding to the reverse flow power amount data to the power generation business operator account 38 based on the reverse power flow power amount data of the business operator H; A transfer step (S38) of transferring the environmental value token from the power generation business account 38 to the consumer account 40 when the transaction is established with J, and receiving a request for issuing an environmental value certificate from the consumer J. and an issuance step (S54) of issuing an environmental value certificate based on the environmental value token transferred to the customer account 40 in the case where the environmental value token is transferred.
According to this aspect, it is possible to clearly prove that the transaction has been made with a power generator that generates power using renewable energy in the environmental value certificate delivered to the consumer.

<Second aspect>
The issuing step (S54) of this aspect is to issue an environmental value certificate using the power generation business name, consumer name, transaction value, and usage date and time range included in the environmental value token transferred to the consumer account 40. characterized by
According to this aspect, by issuing an environmental value certificate using the power generation business name, the consumer name, the transaction value, and the usage date and time range included in the environmental value token, the environmental value certificate delivered to the consumer can be reproduced. It is possible to clearly prove that the transaction was made with a power generation company that generates power using energy-based power generation means.

<Third aspect>
In the electric power transaction management method of this aspect, when a request for issuance of an environmental value certificate is received from a consumer J, the power generation business name, the consumer name, the transaction value, and the usage date and time range at the time of the previous issuance are Separately, there is provided a judgment step (S108) for judging whether or not there is an additionally used usage date and time range. If there is a date and time range, the environmental value certificate is issued using the additionally used power generation business name, consumer name, transaction price, and usage date and time range.
According to this aspect, if there is an additional usage date and time range, the environment A certificate of value can be issued.

<Fourth Aspect>
The electric power transaction management method of this aspect is characterized by comprising a storage step (S58) of storing the date and time of issuance of the environmental value certificate as history information.
According to this aspect, by storing the date and time of issuance of the environmental value certificate as history information, it is possible to determine whether or not there is a range of dates and times of use that has been additionally used.

<Fifth aspect>
The issuance step of this aspect is characterized by not issuing a new environmental value certificate if, as a result of the judgment in the judgment step (S108), there is no additional usage date and time range.
According to this aspect, by not issuing a new environmental value certificate when there is no additional usage date and time range, it is possible to avoid duplicate environmental value certificates to be issued.

<Sixth Aspect>
In the electric power transaction management method of this aspect, when the environmental value certificate is issued in the issuing step (S54), the token of the transaction value corresponding to the fee is subtracted from the consumer account 40, thereby transferring the transaction value to the parent account. is provided with a return step (S60) for returning the environmental value token of .
According to this aspect, the parent account can obtain from the consumer account the transaction value equivalent to the fee for issuing the environmental value certificate.

<Seventh Aspect>
The program of this aspect is characterized by causing a processor to execute each step described in any one of the first to sixth aspects.
According to this aspect, each step can be executed by a processor.

<Eighth aspect>
The power transaction management system 1 of this embodiment uses a distributed ledger block chain network 2 that manages a power generation business account 38 and a consumer account 40 to generate power by means of power generation using renewable energy. A power transaction management server 10 that provides a consumer J with an environmental value certificate proving that the consumer J uses a power generation means when a person H sells power to the consumer J. ,
A granting unit 10a that grants an amount of environmental value tokens corresponding to the reverse flow power amount data of the power generation company H to the power generation company account 38 based on the reverse power flow power amount data, the power generation company H and the consumer J. When the transfer unit 10b transfers the environmental value token from the power generator account 38 to the consumer account 40 when a transaction is established between and an issuing unit 8c for issuing an environmental value certificate based on the environmental value token transferred to the customer account 40.
Since the operation and effect of the eighth aspect are the same as those of the first aspect, the explanation thereof will be omitted.

1... Transaction management system, 2... Distributed ledger blockchain network, 2a... Return unit, 4... Deposit/withdrawal server, 8... Certificate issuing server, 8c... Issuing unit, 8d... Judging unit, 8e... Storage unit, 10... Transaction Management server 10a Granting unit 10b Moving unit 12 Power generation company personal computer 14 Power generation company power meter 16 Distribution line 18 Consumer personal computer 22 Operation unit 24 Communication unit 26 Display control unit 28 Display unit 30 Database DB 32 Main control unit 32a CPU 32b ROM 32c RAM 36 Parent account 37 Environmental value token 38 Parent account 38 ...account for power generation business, 39...environmental value token, 40...account for consumer

Claims (8)

A transaction management server that stores and manages a power generation company account owned by a power generation company and a consumer account owned by a consumer in a distributed ledger on a database , and a certificate issuing server are connected to each other via a network. When the power generator that generates electricity by a power generation means using renewable energy using a system that uses renewable energy sells power to the consumer, the consumer uses the power generation means An electric power transaction management method for providing the terminal of the consumer with an environmental value certificate proving the
The transaction management server
a granting step of granting an amount of environmental value tokens corresponding to the reverse flow power amount data to the power generation company account based on the reverse flow power amount data received from the power generation company power meter of the power generation company;
a transfer step of transferring the environment value token from the power generation business account on the database to the consumer account when a transaction is established between the power generation business operator and the consumer ;
The certificate issuing server
issuing the environmental value certificate based on the environmental value token transferred from the power generation business account to the consumer account when an instruction to apply for the environmental value certificate is received from the consumer 's terminal ; and an issuance step of transmitting the environmental value certificate to the terminal of the consumer . The issuing step is characterized in that the environmental value certificate is issued using the power generation business name, consumer name, transaction price, and usage date and time range included in the environmental value token transferred to the consumer account. The electric power transaction management method according to claim 1. The certificate issuing server
When an application instruction for the environmental value certificate is received from the consumer 's terminal , it is used in addition to the power generation business name, consumer name, transaction price, and usage date and time range at the time of the previous issuance. comprising a judgment step for judging whether or not there is a usage date and time range,
In the issuing step, if the additionally used usage date and time range exists as a result of the determination by the determination step, the name of the power generation company, the name of the consumer, and the transaction 3. The electricity transaction management method according to claim 2, wherein said environmental value certificate is issued using a value and a range of dates and times of use. The certificate issuing server
4. The electric power transaction management method according to claim 3, further comprising a storage step of storing the date and time of issuance of said environmental value certificate as history information. 4. The power supply according to claim 3, wherein said issuing step does not issue a new environmental value certificate if the result of determination by said determining step is that there is no additional usage date and time range. Transaction management method. When the environmental value certificate is issued in the issuing step, the transaction value is transferred to the parent account on the database by subtracting the environmental value token of the transaction value corresponding to the commission from the consumer account on the database. 4. The electric power transaction management method according to any one of claims 1 to 3, further comprising a return step of returning the environmental value token of . A program that causes a processor to execute each step of the power transaction management method according to any one of claims 1 to 6. A transaction management server that stores and manages a power generation company account owned by a power generation company and a consumer account owned by a consumer in a distributed ledger on a database , and a certificate issuing server are connected to each other via a network. When the power generation business that generates power by a power generation means using renewable energy using a system that uses renewable energy sells power to the customer, the customer uses the power generation means An electric power transaction management system that provides an environmental value certificate proving to the terminal of the consumer,
The transaction management server
granting means for granting an amount of environmental value tokens corresponding to the reverse flow power amount data to the power generation company account, based on the reverse power flow power amount data received from the power generation company power meter of the power generation company;
a transfer means for transferring the environmental value token to the consumer account on the database when a transaction is established between the power generation business operator and the consumer ;
The certificate issuing server
issuing the environmental value certificate based on the environmental value token transferred from the power generation business account to the consumer account when an instruction to apply for the environmental value certificate is received from the consumer 's terminal ; and issuing means for transmitting the environmental value certificate to the terminal of the consumer .

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