KR20200094441A - Method and apparatus for trading power - Google Patents

Abstract

Provided are a power trading system for efficiently trading power based on a blockchain, and a method thereof. A power trading device operating as a node of a blockchain network generates power profile information when receiving power amount information, and stores the power profile information in a distributed ledger when validation is performed on the information through the blockchain network. The power trading device determines whether a first participant has excess energy or lacks power based on the power profile information stored in the distributed ledger, and identifies a second participant who lacks power based on the power profile information of other participants stored in the distributed ledger when the first participant has excess energy, or identifies a second participant who has excess energy based on the power profile information of other participants stored in the distributed ledger when the first participants lacks power so that the first participant and the second participant can trade power each other.

Description

Method and apparatus for trading power

The present invention relates to power trading, and more particularly, to a power trading system and method.

Recently, as small-scale photovoltaic power generation facilities (new and renewable power generation facilities) targeting small buildings and homes are spreading, prosumers that generate profits by selling the remaining power produced by users themselves are receiving great attention. In particular, energy prosumers are rapidly being activated in the United States, Australia and Germany, where the share of renewable energy is high. In general, prosumer means a consumer participating in production.

In Korea, a prosumer market will be opened that can trade even a small amount of power generation. When such an energy prosumer market is opened, prosumers can profit by selling the generated power to not only corporations and KEPCO, but also to general consumers.

Existing electricity trading technologies are not suitable for the market where prosumers trade electricity. In other words, the existing power trading technology has a fixed participant role, there are not many numbers, and there is no change in a short time, but in the market where prosumers trade power, there is no distinction between seller and consumer, and anyone can participate in the market. It should be able to reflect the phosphorus market environment.

In addition, since information on insufficient power of each prosumer is not shared, matching between prosumer and consumer is difficult, so the participation rate of prosumer power transaction is low.

In addition, when a prosumer trades power, the amount of power traded is small, but the frequency of transactions is high.

Therefore, there is a problem in that it takes a lot of money to collect information between prosumers by applying a centralized operation technology so that transactions can be made.

As a related prior document, there is a "power transaction method and apparatus" disclosed in Korean Patent Publication No. 10-2016-0115071.

The problem to be solved by the present invention is to provide a system and method for efficiently performing power transactions based on a blockchain.

A method according to an embodiment of the present invention, as a method for performing power transaction, when a power trading device operating as a node of a blockchain network receives power amount information, generates power profile information, and generates a data block including the power profile information. Requesting validation by transmitting to the blockchain network; Storing the power profile information in a distributed ledger by the power trading device after validation is performed through the blockchain network; Determining, by the power trading device, whether a surplus energy is generated or a power supply is insufficient due to power profile information stored in the distributed ledger; When the surplus energy of the first participant is generated, the power trading device identifies a second participant who is in a power supply shortage state based on power profile information of other participants stored in the distributed ledger, or the power supply shortage of the first participant If a condition occurs, identifying a second participant that generated surplus energy based on power profile information of other participants stored in the distributed ledger, and the power trading device concludes a power transaction between the first participant and the second participant It includes the steps.

The step of signing the power transaction may include determining whether the first participant's transaction profile information stored in the distributed ledger matches the second transaction profile information, and when the match is made, signing the power transaction. have.

The transaction profile information may include information related to conditions for power transaction, and the power profile information may include the amount of power produced and the amount of power consumed.

The method further includes, after the step of signing the power transaction, the power transaction device generating transaction processing request information according to the power transaction and transmitting it to a token management server operating as a node of the blockchain network. The transaction processing request information may include identification information for the first and second participants, the amount of power that has been entered into the transaction, and the transaction amount.

The method comprises: the token management server receiving the transaction processing request information; If the token management server is a seller whose surplus energy is held by the first participant, transferring the energy tokens granted to the electronic wallet of the second participant to the electronic wallet of the first participant; And when the token management server is a purchaser in which the first participant is in a shortage of power supply, transferring the energy token granted to the electronic wallet of the first participant to the electronic wallet of the second participant. have.

An apparatus according to another embodiment of the present invention, a power transaction device for performing a power transaction, a communication unit configured to transmit a data block to a blockchain network, and receive authentication information and power amount information for the data block; A memory that stores a distributed ledger of the blockchain network; And when receiving the power amount information through the communication unit, generates power profile information including the generated power amount and the consumed power amount, and sends a data block including the same to the blockchain network through the communication unit to request validation. After validation through the blockchain network is achieved, the power profile information is stored in the distributed ledger of the memory, and surplus energy is generated or power supply is insufficient due to the power profile information stored in the distributed ledger of the memory. It includes a processor configured to determine whether.

When the surplus energy of the first participant is generated, the processor further identifies the second participant in a power supply shortage state based on the power profile information of other participants stored in the distributed ledger of the memory, or the power of the first participant When a supply shortage occurs, the second participant that generated surplus energy is identified based on the power profile information of other participants stored in the distributed ledger of the memory, and configured to conclude a power transaction between the first participant and the second participant Can be.

Specifically, the processor may be configured to determine whether the first participant's transaction profile information stored in the distributed ledger of the memory matches the second transaction profile information, and to conclude the power transaction when they match.

The processor is further configured to generate transaction processing request information according to the power transaction and deliver it to the token management server operating as a node of the blockchain network through the communication unit, and the transaction processing request information is the first participant And it may include identification information for the second participant, the amount of power entered into the transaction, and the transaction amount.

The distributed ledger of the memory may include first blockchain data including data blocks including the power profile information and second blockchain data including data blocks including transaction profile information including power transaction conditions. have.

The transaction profile information may include a smart contract code, and the processor may be configured to perform a power transaction between the first participant and the second participant according to the smart contract code.

The processor, when the number of authentication successes among the authentication information for the corresponding data block received from the blockchain network through the communication unit according to the validation request is greater than a preset value, validates through the blockchain network It can be configured to judge that this has been done.

The power transaction device may acquire the power amount information in connection with the power measurement device by measuring the power amount of the power generation facility of the participant.

According to an embodiment of the present invention, information including the amount of power produced and the amount of power consumed in the power generation facilities of each participant is stored and shared in a distributed ledger, and based on this, surplus energy retention and shortage of power supply are easily confirmed, Power transactions can be made between participants. In addition, since information is stored in a distributed ledger based on mutual verification between participants, a fair market economy may be possible through transactions between participants without a centralized operation device.

In addition, a power contract is automatically concluded through a smart contract, so that surplus energy can be supplied to a household where power supply is insufficient.

1 is a diagram illustrating a network environment of a power transaction system according to an embodiment of the present invention.
2 is a conceptual diagram showing the flow of power transaction according to an embodiment of the present invention.
3 is a structural diagram of a power trading device according to an embodiment of the present invention.
4 is a flowchart of a power transaction method according to an embodiment of the present invention.
5 is a flowchart of an operation of a power transaction device according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains may easily practice. However, the present invention can be implemented in many different forms and is not limited to the embodiments described herein. In addition, in order to clearly describe the present invention in the drawings, parts irrelevant to the description are omitted, and like reference numerals are assigned to similar parts throughout the specification.

Throughout the specification, when a part “includes” a certain component, it means that the component may further include other components, not to exclude other components, unless otherwise specified.

In the present specification, expressions expressed in singular may be interpreted as singular or plural unless explicit expressions such as “one” or “single” are used.

Further, terms including ordinal numbers such as first and second used in the embodiment of the present invention may be used to describe elements, but the elements should not be limited by terms. The terms are only used to distinguish one component from other components. For example, the first component may be referred to as a second component without departing from the scope of the present invention, and similarly, the second component may be referred to as a first component.

In addition, terms such as “…unit”, “…group”, “…module” described in the specification mean a unit that processes at least one function or operation, which may be implemented by hardware or software or a combination of hardware and software. Can.

Hereinafter, a power trading system and a method according to an embodiment of the present invention will be described with reference to the drawings.

1 is a diagram illustrating a network environment of a power transaction system according to an embodiment of the present invention.

As shown in FIG. 1, the power transaction system 100 according to an embodiment of the present invention includes a plurality of power transaction devices 10 and a token management server 20 connected through a blockchain network 200. , And a power management server 30.

The blockchain network 200 represents a P2P structure network composed of a plurality of nodes operating according to the blockchain algorithm. Nodes represent the entities that make up the blockchain network and maintain and manage the blockchain data based on the blockchain algorithm. The node may be implemented as a computing device, but may also be implemented as a virtual machine.

The power trading device 10 is a computing device that performs power trading in conjunction with the blockchain network 200. The power trading device 10 works with the blockchain network 200 based on the power amount information measured by the power measuring device 40 of users who want to trade power to store the power amount information in a distributed ledger, and based on this Conduct a transaction. The power measuring device 40 is a device that measures the amount of power produced and consumed in a power generation facility (for example, a power generation facility installed in a building or a home), and may be, for example, a smart meter. Including such a smart meter and power trading device 10, it may also be referred to as a smart meter and controller (SMC).

Users who want to trade power include a prosumer. Prosumers represent consumers and producers who consume electricity (or energy) and also participate in electricity production. Power trading may mean trading power generated or generated by distributed power facilities using solar, solar, wind, fuel cell, hydrogen energy, waste energy, and geothermal methods. Prosumers can generate electricity using distributed power equipment. A user who wants to do a power transaction may include a consumer consuming electricity without generating electricity. In an embodiment of the present invention, a user (prosumer, consumer) who wishes to conduct power transaction using the power transaction device 10 is referred to as a'participant' for convenience of explanation. The power trading device 10 may be a power trading device of these participants.

The token management server 20 is a computing device that works with the blockchain network 200 to perform issuance and management of energy tokens and transaction payment for energy tokens. The token management server 20 may be a server owned by an existing bank or a financial company, or may be a server constructed separately.

The power management server 30 is a computing device that performs electricity production and demand management. The power management server 30 may be a server possessed by an existing Korea Electric Power Corporation, or may be a server constructed separately.

The computing device may be a laptop, a desktop, a laptop, etc., but is not limited thereto, and may include all types of devices equipped with a processor and communication means.

Meanwhile, the node of the blockchain network 200 verifies the validity of the corresponding transaction in response to a request for processing the generated transaction, records the verified transaction in a new block, and propagates it on the blockchain network 200. Here, the transaction may include processing various types of information generated on the blockchain network 200. Each node maintains the same blockchain data. The blockchain network 200 may be implemented as a permission-based blockchain network. That is, the blockchain network 200 may be a limited network where only participants (eg, users, nodes) whose permission has been verified can participate, and in this case, participation of unspecified nodes and transaction requests of unauthorized users may be limited. .

The power transaction device 10, the token management server 20, and the power management server 30 according to an embodiment of the present invention may be implemented as nodes of the blockchain network 200, respectively. The node of the blockchain network 200 may be a physical server device, or a logical node operating on a physical server device provided by service providers, or may be operated through a network. For example, the power trading device 10 may be a logical node operating on a physical server device.

The power transaction device 10, the token management server 20, and the power management server 30 may operate as a consensus entity that verifies the validity of the transaction request made on the blockchain network 200, respectively, and the blockchain network It includes a blockchain database that is a distributed ledger that stores all or part of the blocks that are distributed and agreed upon. That is, it stores data blocks of other nodes propagated through the blockchain network.

The power transaction device 10 generates power profile information based on the amount of power measured by the power measurement device 40, and also generates transaction profile information for signing a transaction and stores it in a distributed ledger. The power trading device 10 performs power trading between the prosumer and the consumer based on the power profile information and the transaction profile information stored in the distributed ledger.

On the other hand, the token management server 20 issues energy tokens to participants and manages them through accounts for each participant. In addition, the token management server 20 performs payment according to the power transaction between the prosumer and the consumer. For example, an energy token corresponding to the amount of power traded can be transferred from a consumer's account to a prosumer's account.

2 is a conceptual diagram showing the flow of a blockchain-based power transaction according to an embodiment of the present invention.

2, the power transaction device 10, the token management server 20 and the power management server 30 are configured to interwork with the blockchain network 200, that is, the blockchain network 200 Each is implemented to operate as a single node. The power trading device 10 is a plurality.

The power trading device 10 generates power profile information including power generation and power consumption based on the amount of power measured by the power measurement device 40 that works in conjunction with the power generation facilities of each home, and stores it in the distributed ledger. Write. Accordingly, power profile information is stored for each participant in the distributed ledger, and power profile information is shared between power transaction devices interworking with the blockchain network 200.

In addition, the power trading device 10 records transaction profile information in a distributed ledger. The transaction profile information includes conditions for power trading, and based on this, power trading can be performed between participants. The transaction profile information may be different for each participant, or may include transaction conditions commonly applied for each participant. In the following embodiments, it will be described as an example that different transaction profile information is generated and stored for each participant, but the present invention is not limited thereto. Transaction profile information is stored in the distributed ledger for each participant, and sharing of transaction profile information is performed between power trading devices interworking with the blockchain network 200. Here, the participants may be distinguished based on identification information of a corresponding power measuring device, or may be distinguished based on identification information provided for each participant.

The power trading device 10 may determine whether there is surplus energy based on the power profile information described in the distributed ledger, and in this case, may identify a participant who lacks power supply. In addition, the power transaction device 10 may determine whether or not the power supply is insufficient, and in this case, the participant who has excess energy.

The power trading device 10, if it is confirmed that there is surplus energy based on the power profile information, or when it is determined that the power supply is insufficient, the power trading device 10 is provided with a participant who has insufficient power to purchase surplus energy or a participant who can provide surplus energy. Perform power transactions. In this case, the power trading device 10 may check whether the transaction profile information is matched and, if matched, perform power trading between the participants.

When a transaction is concluded between a participant with excess energy and a participant with insufficient power supply, the power transaction device 10 requests the transaction settlement processing for the token management server 20. The token management server 20 transfers the energy token of the account of the surplus energy holding participant to the account of the power shortage participant according to the transaction payment processing request.

According to this power transaction, surplus energy can be supplied to consumers who lack electricity.

3 is a structural diagram of a power trading device according to an embodiment of the present invention.

3, the power trading device 10 includes a communication unit 11, an interface 12, a processor 13, a memory 14. In the embodiment of the present invention, only the above-described components are shown for convenience of explanation, but other components necessary for power transactions may be additionally included.

The communication unit 11 provides blocks generated by the power trading device 10 to other nodes through the blockchain network 200. The communication unit 11 receives blocks or information from other nodes connected through a blockchain network, and also receives authentication information for blocks provided to other nodes. In addition, the communication unit 11 receives the power amount information measured for the power generation equipment from the power measurement device 40. Above this, the communication unit 11 may be implemented to include a first communication module communicating with the blockchain network 200 and a second communication module communicating with the power measurement device 40. The power amount information includes the amount of power produced and the amount of power consumed.

The interface 12 receives transaction condition information transmitted from a participant who wants to perform a power transaction or a terminal (not shown) of the participant.

The transaction condition information is information related to conditions for power transaction. The conditions for the power transaction include, for example, condition information set to sell surplus energy generated when surplus energy is generated, condition information set to purchase insufficient power when a power shortage supply condition occurs, or When the consumption pattern based on the power consumption amount corresponds to, for example, 90% to 100% of the power production amount, condition information set to purchase 20% of the power consumption amount may be included. Alternatively, when the residual power amount is, for example, 50% or more of the output amount and the consumption pattern based on the power consumption amount is less than 80% of the power output amount, the condition information set to sell 20% of the power output amount is displayed. It can contain. Conditions for such power trading may be set differently for each participant, or may be equally applied to all participants according to rules operating in the power trading market. In addition, the interface 12 may provide a result of a transaction conclusion to a participant or a participant's terminal.

Such transaction condition information may be received from other nodes on the blockchain network 200 through the communication unit 11 or may be received through a wired or wireless network. Here, it will be described as an example that the participant who wants to trade power is provided through the interface 12, but the present invention is not limited thereto.

The processor 13 generates power profile information based on the amount of power received through the communication unit 11, and also generates transaction profile information based on conditions for power transmission received through the interface 12, and power profile Create a data block containing information and/or transaction profile information.

The power profile information includes production power, power consumption, and residual power, and may further include identification information. Here, the identification information may be identification information of the power measurement device, or may be identification information of a participant, but is not limited thereto. Based on the power profile information, it is possible to know whether the current power supply state is insufficient or insufficient, that is, a power shortage state or a surplus energy generation state.

The transaction profile information includes conditions for power transaction, and may further include identification information. Here, the identification information may be identification information of the power measurement device, or may be identification information of a participant, but is not limited thereto.

The processor 13 generates a data block including power profile information, and also generates a data block including transaction profile information. Here, it has been exemplified that data blocks each including power profile information and transaction profile information are individually generated, but the present invention is not limited thereto. Here, the form of the data block or the type of information included is not limited to any one form. In addition, since the processor 13 can also perform various methods for generating a data block, the embodiment of the present invention is not limited to any one method. The data block including the power profile information is called "power data block" for convenience of description, and the data block including the transaction profile information is called "transaction data block" for convenience of description.

The transaction profile information may include a code for a smart contract in which the contract is executed when the conditions are met, that is, a smart contract code. The smart contract code is a code to execute the transaction when an event occurs. When the transaction profile information is stored and executed in the data block, the address of the contract account, which is a kind of contract account for the smart contract, may be generated and stored in the data block. You can access the smart contract through this address. When a data block having such a smart contract code is described in the distributed ledger, all nodes on the blockchain network 200 can execute the corresponding smart contract. When one node changes the contents of the smart contract (which can be changed after distributed agreement through the blockchain network), the other node accesses the smart contract of the corresponding address to get the changed contents.

In addition, when the data block is received from other nodes connected through the blockchain network through the communication unit 11, the processor 13 receives authentication information according to whether the verification code included in the corresponding data block matches the verification code generated directly. Can be generated and propagated to other nodes on the blockchain network through the communication unit 11.

In addition, when the processor 13 receives authentication information that matches from nodes having a set value (eg, a majority of all nodes) or more connected through a blockchain network through the communication unit 11, the corresponding data block is memory ( 14).

As such, by allowing data blocks to be stored in a distributed ledger based on mutual verification between participants, a fair market economy may be possible through transactions between participants without a centralized operation device.

The memory 14 stores and manages data blocks that are distributed ledgers. The memory 14 may function as a blockchain database that stores all or part of the blocks, which are distributed and agreed through the entire blockchain network. That is, it stores data blocks of other nodes propagated through the blockchain network. The data block may have a data structure of a linked list having a connection relationship with the previous data block according to the order of occurrence, and the internal structure may have a hierarchical structure in a tree form. The power transaction data block may be composed of a header and a body, and the header includes a hash value of the previous block header, a nonce, a timestamp, etc., and the body includes power profile information or transaction profile information. .

When a change occurs in the power profile information or transaction profile information, a new data block for the changed content can be generated and linked to an existing data block. These data blocks are called blockchain data. The memory 14 includes first blockchain data 141 including power data blocks and second blockchain data 142 including transaction data blocks.

Meanwhile, the processor 13 determines whether surplus energy is generated based on a block of power data stored in the memory 14, checks a participant that has insufficient power supply when surplus energy is generated, and performs a power transaction. Or, if there is a shortage of power supply, check the participants who have surplus energy and conduct a power transaction.

Specifically, through matching the transaction profile information of the transaction data block of the participants, matching participants are searched for and the power transaction is concluded. When the power transaction is concluded, the processor 13 generates transaction processing request information according to the transaction conclusion, and signs it with a private key to propagate through the blockchain network. That is, the processor 13 generates a data block including transaction processing request information and propagates it on the blockchain network through the communication unit 11. The transaction processing request information includes identification information about participants who have entered into a power transaction (or the address of the participants' electronic wallet), and the amount of power that has been entered into the transaction, and includes the transaction amount. Transaction processing request information may be added to a transaction data block or included in a new data block to be propagated. Meanwhile, information according to the power transaction conclusion may be provided to the participants through the interface 12.

In addition, the power transaction device 10 includes an electronic wallet 15. The electronic wallet 15 may store and manage energy tokens issued and provided by the token management server 20 according to an embodiment of the present invention, and may be provided with separate identification information (eg, an address). The energy token of the electronic wallet can be deposited or withdrawn using the public key and the corresponding secret key. The energy token can be provided from the token issuing server 20 based on the amount of power produced by the power generation facility. For example, a predetermined energy token may be issued based on the amount of power generated by the power generation equipment of the participant. Alternatively, the participant may acquire the energy token through a method of purchasing the energy token through the token issuing server 20. The energy token can be used not only for power transactions, but also as a means for payment of electricity rates, payment of payments at electric vehicle charging stations, and can also be refunded in cash. The electronic wallet 15 holding such an energy token is installed by linking the identity verification process in the step of installing an account through a financial institution, and a virtual account may be built and operated in the electronic wallet 15 at the same time as installation. .

In response to the transaction processing request propagated to the blockchain network by the power transaction device 10, the token management server 20 and the power management server 30 constituting the blockchain network perform processing according to the power transaction conclusion.

The token management server 20 issues and manages energy tokens for power transactions. The token management server 20 may share power profile information and transaction profile information through the blockchain network 200. The token management server 20 may also be configured to include a communication unit, a processor, a memory, and/or an interface.

The token management server 20 issues an energy token according to an energy token charging request transmitted from the power trading device 10 or an energy token charging request input through the interface, and stores the energy token in the electronic wallet of the power trading device 10 or (For example, by issuing and charging an energy token based on the original currency of the account), an energy token can be issued according to the amount of power generated by the participant and stored in the electronic wallet of the power trading device 10 of the corresponding participant.

In addition, the token management server 20 is based on the identification information, the amount of power entered into the transaction, the amount of the transaction, the transaction amount included in the transaction transaction included in the transaction processing request transmitted from the power transaction device 10, the transaction amount The corresponding energy token is transferred from the electronic wallet of the participant with surplus energy to the electronic wallet of the participant with insufficient power supply. Here, the transfer processing includes a process of subtracting the value of the energy token of the participant's electronic wallet that has surplus energy by the amount to be transferred, and increasing the value of the energy token of the participant's electronic wallet that is under power supply by the amount that is transferred. .

The power management server 30 performs power management including supplying surplus energy to a participant with insufficient power according to the power transaction.

Next, a power transaction method according to an embodiment of the present invention will be described.

4 is a flowchart of a power transaction method according to an embodiment of the present invention.

As shown in the attached Figure 4, the power transaction device 10 is based on the amount of power provided from the power measurement device 40 for measuring the amount of power generated and consumed in the power generation equipment (S100), power profile information Create and create a block containing it to propagate to the blockchain network 200 (S110, S120). Validation of a block including power profile information is performed by distributed agreement through the blockchain network 200, and the verification result is transmitted to the power transaction device 10 (S130, S140). At the time of such validation, a plurality of different power transaction devices, token management server 20, power management server 30, and the like can participate as an agreement subject to perform verification.

The power trading device 10 stores a data block including power profile information in a distributed ledger (S150). Here, it is assumed that the transaction profile information is also generated and recorded in the distributed ledger, and the steps of the following steps will be described. The power profile information and transaction profile information may be stored and managed in a distributed ledger after a distributed agreement through the blockchain network 200, thereby sharing power profile information and transaction profile information for each participant.

The power trading device 10 determines whether the corresponding participant is insufficient in power supply or whether excess energy is generated based on the power profile information stored in the distributed ledger (S160). Here, the corresponding participant is a participant who has a power measuring device 40 that provides power information to the power trading device 10, and for convenience of description, is referred to as a first participant.

When it is determined that surplus energy has been generated based on the power profile information of the first participant, the power trading device 10 identifies a participant whose power supply is insufficient based on the power profile information of other participants stored in the distributed ledger. Alternatively, when it is determined that a power supply shortage occurs based on the power profile information of the first participant, the power transaction device 10 identifies a participant who has surplus energy based on the power profile information of other participants stored in the distributed ledger. Participants with insufficient power supply identified as above or participants with excess energy are referred to as second participants (S170).

The power trading device 10 then performs power trading between the first participant and the second participant (S180). To this end, the power transaction device 10 may determine whether to match through comparison of the transaction profile information of the first participant and the transaction profile information of the second participant, and, if matched, may determine to perform power transaction. At this time, the power trading device 10 generates and delivers a query inquiring of a transaction conclusion to the matching second participant's power trading device, and a response including permission for the query is received from the second participant's power trading device. In some cases, the first participant and the second participant may finally conclude a power transaction.

When it is determined to perform the power transaction, the power transaction device 10 generates transaction processing request information and transmits it to the token management server 20 (S190, S200). The token management server 20 performs energy token transfer processing between the first and second participants according to the transaction processing request (S210). If the first participant has surplus energy, the second participant's energy token is paid to the first participant, and if the first participant is in short supply, the first participant's energy token is paid to the second participant.

As described above, information including the amount of power produced by each participant's power generation facility and the amount of power consumed is stored and shared in a distributed ledger, and based on this, surplus energy retention and shortage of power supply are easily confirmed to establish a smart contract. Through this, power transactions can be made between the participants.

5 is an operation flowchart of the power transaction device 10 according to an embodiment of the present invention.

5, the power trading device 10 receives the power amount information from the power measuring device 40 (S300), generates power profile information based on the received information, and generates a data block including the power profile information. Create, and transmit to the blockchain network 200 (S310). Each node of the blockchain network 200 verifies the validity of the data block, generates authentication information according to the verified validity, and transmits it to the power transaction device 10. In this case, each node may generate authentication information according to whether the verification code included in the received data block matches the verification code generated directly, and propagate it to other nodes on the blockchain network.

The power transaction device 10 receives authentication information according to validation (S320), and checks whether the number of authentication successes among the received authentication information is greater than a preset value (S330).

When the number of authentication successes among the received authentication information is greater than a preset value, the power transaction device 10 stores a data block including the power profile information in the first blockchain data 141 of the memory 14 . On the other hand, if the number of authentication successes among the received authentication information is smaller than a preset value, it is determined that it is not valid, and the corresponding data block may not be generated (S350). For example, the corresponding data block is not stored, and accordingly, the corresponding data block may be processed as not being generated.

Thereafter, the power transaction device 10 determines whether the corresponding participant, that is, the first participant's power supply is insufficient or surplus energy, based on the power profile information stored in the first blockchain data 141 of the memory 14 ( S360). When it is determined that surplus energy is generated based on the power profile information of the first participant, the power trading device 10 supplies power based on the power profile information of other participants stored in the first blockchain data 141 of the memory 14 Identify this lacking second participant. Alternatively, when it is determined that a power supply shortage occurs based on the power profile information of the first participant, the power transaction device 10 may display power profile information of other participants stored in the first blockchain data 141 of the memory 14. Based on this, identify the second participant who has surplus energy (S370).

Subsequently, the power transaction device 10 determines whether or not a match is made by comparing the transaction profile information of the first participant and the transaction profile information of the second participant stored in the second blockchain data 142 of the memory 14, and matching If possible, it is determined to perform the power transaction (S380).

Thereafter, the power transaction device 10 requests transaction processing including identification information (or e-wallet addresses of the seller and the buyer), the amount of power entered into the transaction, and the transaction amount for the first and second participants that have entered into the power transaction. It generates information and transmits it to the token management server 20 to request another payment processing to conclude a transaction (S390).

On the other hand, in the above-described embodiment, the power trading device 10 performed power trading based on the power profile information and the transaction profile information stored in the distributed ledger, but unlike this, the token management server 20 is stored in the distributed ledger. Power trading may be performed based on power profile information and transaction profile information. That is, when the power trading device 10 of each participant generates power profile information and transaction profile information and stores them in a blockchain-based distributed ledger, the token management server 20 is based on the power profile information of the participants stored in the distributed ledger. It is possible to identify a participant with surplus energy and a participant with insufficient power supply, and conduct a power transaction between a participant with surplus energy and a participant with insufficient power. In this case, the token management server 20 finally determines the conclusion of the transaction through matching of the transaction profile information of the participant with the surplus energy stored in the distributed ledger and the participant with insufficient power supply, and the participant with insufficient power supply with which the transaction is concluded. Energy tokens are paid to participants who have surplus energy. Those skilled in the art can implement the token management server 20 through the embodiment described above to perform the power transaction, the detailed description is omitted here.

The embodiment of the present invention is not implemented only through the apparatus and/or method described above, and is implemented through a program for realizing a function corresponding to the configuration of the embodiment of the present invention, a recording medium in which the program is recorded, and the like. Alternatively, such an implementation can be easily implemented by those skilled in the art to which the present invention pertains from the description of the above-described embodiments.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited to this, and various modifications and improvements of those skilled in the art using the basic concept of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Claims (14)

As a way to conduct power trading,
A power transaction device operating as a node of the blockchain network, generating power profile information when receiving the power amount information, and requesting validation by transmitting a data block including the data to the blockchain network;
Storing the power profile information in a distributed ledger by the power trading device after validation is performed through the blockchain network;
Determining, by the power trading device, whether a surplus energy is generated or a power supply is insufficient due to power profile information stored in the distributed ledger;
When the surplus energy of the first participant is generated, the power trading device identifies a second participant who is in a power supply shortage state based on power profile information of other participants stored in the distributed ledger, or the power supply shortage of the first participant Identifying a second participant generating surplus energy based on power profile information of other participants stored in the distributed ledger when a condition occurs; and
The power trading device signing a power transaction between the first participant and the second participant
Power trading method comprising a. According to claim 1,
Signing the power transaction is
And determining whether the first participant's transaction profile information stored in the distributed ledger matches the second transaction profile information, and when the match is made, signing the power transaction. According to claim 2,
The transaction profile information includes information related to conditions for power trading, and the power profile information includes the amount of power produced and the amount of power consumed. According to claim 1,
After the step of signing the power transaction,
Generating, by the power trading device, transaction processing request information according to the power transaction and delivering it to a token management server operating as a node of the blockchain network.
Further comprising,
The transaction processing request information includes identification information for the first participant and the second participant, the amount of power entered into the transaction, and the transaction amount. According to claim 4,
The token management server receiving the transaction processing request information;
If the token management server is a seller whose surplus energy is held by the first participant, transferring the energy tokens granted to the electronic wallet of the second participant to the electronic wallet of the first participant; And
When the token management server is a purchaser in which the first participant is in a shortage of power supply, transferring the energy token granted to the first participant's electronic wallet to the second participant's electronic wallet;
Power trading method further comprising. According to claim 1,
The verification of the validity through the blockchain network indicates that the number of authentication successes among authentication information for the corresponding data block received from the blockchain network according to the validation request is greater than a preset value. . A power trading device that performs power trading,
A communication unit configured to transmit a data block to a blockchain network and receive authentication information and power amount information for the data block;
A memory that stores a distributed ledger of the blockchain network; And
When the power amount information is received through the communication unit, power profile information including the generated power amount and the consumed power amount is generated, and a data block including the same is transmitted to the blockchain network through the communication unit to request validation, and the After validation through the blockchain network is achieved, the power profile information is stored in the distributed ledger of the memory, and surplus energy is generated or the power supply is insufficient due to the power profile information stored in the distributed ledger of the memory. Processor configured to determine
Power trading device comprising a. The method of claim 7,
The processor additionally,
When the surplus energy of the first participant is generated, the second participant in the power supply shortage state is identified based on the power profile information of other participants stored in the distributed ledger of the memory, or when the power supply shortage state of the first participant occurs , It is configured to identify a second participant that generated surplus energy based on power profile information of other participants stored in the distributed ledger of the memory, and to conclude a power transaction between the first participant and the second participant. The method of claim 8,
Specifically, the processor,
And configured to determine whether the first participant's transaction profile information stored in the distributed ledger of the memory matches the second transaction profile information, and to conclude the power transaction when matched. The method of claim 8,
The processor additionally,
It is configured to generate transaction processing request information according to the power transaction and deliver it to the token management server operating as a node of the blockchain network through the communication unit, and the transaction processing request information is transmitted to the first and second participants. Power transaction device, including identification information, the amount of power entered into the transaction, and the transaction amount. The method of claim 8,
The distributed ledger of the memory includes first blockchain data including data blocks including the power profile information and second blockchain data including data blocks including transaction profile information including power transaction conditions, Power trading device. The method of claim 11,
The transaction profile information includes a smart contract code,
And the processor is configured to perform power trading between the first participant and the second participant according to the smart contract code. The method of claim 7,
The processor,
When the number of authentication successes among the authentication information for the corresponding data block received from the blockchain network through the communication unit is greater than a preset value according to the validation request, it is determined that validation is performed through the blockchain network A power trading device, configured to. The method of claim 7,
The power trading device measures the amount of power for a power generation facility of a participant and acquires the amount of power information in connection with the power measuring device.

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