KR20240018929A - System for managing transaction information of carbon credits based in blockchain - Google Patents

Abstract

The present invention relates to a blockchain-based carbon emissions trading information management system, which includes a user request receiver that receives user requests for inquiry or input of carbon emissions trading information from a client node corresponding to the user, and identification of network participating members. A plurality of these authenticated and authorized participating nodes are connected to each other to form a single blockchain, and the transaction is performed based on the results of user authentication for the request received from the client node and verification of the transaction according to the request. A blockchain network that generates a block of transactions, a data security unit that generates an encryption key based on a preset encryption key service when the transaction block is created to encrypt or decrypt the data of the transaction block, and the plurality of participating nodes. A storage unit that adds and updates the encrypted transaction block data while the encrypted data of the carbon emissions trading ledger in which the transaction details of each company are recorded are pre-stored, and stores the generated encryption key by matching it. The blockchain network includes a distributed ledger in which the encrypted data stored in the storage unit is divided corresponding to the number of the plurality of participating nodes, and the distributed ledger is stored in each participating node, and the creation and type of the transaction block is determined. It is characterized by updating the current status information of the carbon emission trading ledger, which changes accordingly, to the distributed ledger in real time.
Accordingly, by individually encrypting each company's carbon emissions trading data and storing the data record and the decryption key to decrypt it on the blockchain, there is an effect of maximizing the security of the data subject to management.

Description

Blockchain-based carbon emissions trading information management system {SYSTEM FOR MANAGING TRANSACTION INFORMATION OF CARBON CREDITS BASED IN BLOCKCHAIN}

The present invention is a blockchain technology that can integrate and safely manage information on carbon emissions transactions occurring in most companies using a blockchain network as interest in carbon neutral policies increases worldwide and the carbon emissions market expands. It is about a carbon emissions trading information management system.

Recently, as communication technology and mobile terminal technology have developed rapidly, various types of data storage systems that store data in cloud servers have been developed and used. The use of data stored in the cloud storage of a cloud server is increasing recently because cloud service users can not only download data anytime and anywhere, but also store large amounts of data without concerns about storage capacity.

However, the cloud data storage system is not only exposed to many users, but also has the inherent problem that when an external attack or hacking occurs, all data stored in the cloud storage is exposed at once.

Meanwhile, a blockchain network distributes and stores data by directly verifying and agreeing on data by users participating in the network, allowing users to transact directly without a central management agency. Blockchain not only ensures the reliability of data because it is difficult to forge or falsify transactions, but also ensures transparency and integrity of data because all users have the same blockchain ledger and anyone can view it.

These blockchain networks are divided into public blockchain networks and private blockchain networks. In a public blockchain network, all data is public and anyone can participate in the network to become a node that can verify data and create blocks. Currently, Bitcoin and Ethereum are public blockchain networks.

Meanwhile, private blockchain networks were developed for enterprises and are also called private blockchains, closed blockchains, permissioned blockchains, enterprise blockchains, or enterprise blockchains. Transaction details and actions other than those of authorized participants are not permitted. It is not shared and cannot be tracked. Additionally, in order to participate in a private blockchain network, only participants authorized by one entity can participate and create blocks, and a representative example of a private blockchain is Hyperledger Fabric. Hyperledger Fabric allows only authorized participants to participate in the blockchain network, and it is possible to form an organization within the network and share different ledgers as logical bundles (Channel).

As described above, conventional cloud services have a very high risk of exposing data stored in cloud storage when the cloud server is attacked. Therefore, the present invention seeks to propose a method to safely manage data stored in cloud storage using a blockchain network.

KR 10-0967229 B1 KR 10-2188504 B1

The purpose of the present invention is to solve the above problems, and due to the global carbon neutral trend and the expansion of the carbon emissions market, information on carbon emissions trading occurring in most companies can be managed safely and integrated using a blockchain network. The purpose is to provide a blockchain-based carbon emissions trading information management system.

A blockchain-based carbon emission trading information management system according to one aspect of the present invention to achieve the above purpose is a user request that receives a user request for inquiry or input of carbon emission trading information from a client node corresponding to the user. A receiving unit and a plurality of participating nodes whose identities are authenticated and authorized for participating network members are connected to each other to form a single blockchain, and perform user authentication for requests received from the client nodes and verification of transactions according to the requests. A blockchain network that generates a transaction block that blocks the transaction based on the execution result, and when the transaction block is created, generates an encryption key based on a preset encryption key service to encrypt or decrypt the data of the transaction block. A data security unit and a carbon emission trading ledger in which transaction details for each company corresponding to each of the plurality of participating nodes are recorded, and the encrypted transaction block data is added and updated while the encrypted data is pre-stored, and the generated encryption is performed. It includes a storage unit that stores the key by matching it, and the blockchain network stores a distributed ledger in which the encrypted data stored in the storage unit is divided corresponding to the number of the plurality of participating nodes in each participating node, The current status information of the carbon emissions trading ledger, which changes depending on whether or not the transaction block is created and the type, is updated in real time in the distributed ledger.

Preferably, the blockchain network hosts a guarantee node that generates a request transaction according to the received user request and returns the execution result to the client node, and at least one distributed ledger, and each of the distributed ledgers A plurality of peer nodes hosting a chaincode defining an execution function for a transaction that accesses the ledger and applies a state change to the distributed ledger, and according to a preset consensus algorithm based on the request transaction and the results of executing it. It is characterized in that it includes an orderer node that distributes the ordered and blocked transaction blocks to the plurality of peer nodes so that the distributed ledger is updated by the transaction blocks.

Preferably, the data security unit includes an encryption key generation unit that generates an encryption key based on the encryption key service when generating a first transaction block according to a user's transaction input request, and an encryption key generation unit that generates an encryption key based on the encryption key service according to the creation of the first transaction block. An encryption unit that encrypts the first transaction block data using the generated encryption key, and an encryption unit that matches the encryption data stored in the storage unit at the current time when generating the second transaction block according to the user's transaction inquiry request. It is characterized by including a decryption unit that decrypts using a key.

Preferably, the user request receiving unit includes a router unit providing an API path that allows a client application running on the client node to access the blockchain network, and when receiving a user's transaction input request from the client node. , Characterized by comprising a data stream unit that receives new transaction information corresponding to the transaction input request and converts it into a packet form to generate a data stream.

Preferably, when a request from the client node is received, user authentication is performed to confirm the identity of the client node based on the result of checking the validity of a certificate issued through a certification authority with respect to the unique ID information of the client node. When registration of the client node is permitted by mutual agreement between the user authentication unit that performs the user authentication and the plurality of participating nodes constituting the blockchain network after the user authentication is completed, the client node is registered in the blockchain network. It is characterized by further including a node register to be added as a member.

According to the present invention, there is an effect of maximizing the security of data subject to management by individually encrypting carbon emissions trading data for each company and storing the data record and the decryption key to decrypt it in the blockchain. .

In addition, according to the present invention, transaction information is processed and encrypted based on blockchain technology and stored in the blockchain, making hacking virtually impossible, and even if an error occurs in the system, transaction information combined and registered in the blockchain is safe. Because it is distributed and stored, it has the effect of preventing data loss in advance.

In addition, according to the present invention, using private blockchain technology, only companies that are parties to a transaction are granted permission to participate in the blockchain network, and stakeholders related to the transaction amount are given limited authority to access and view the network. By granting a system, it is possible to build a system at a lower cost than in the case of a general public blockchain, and the reliability and transparency of data can be strengthened.

Figure 1 is a diagram schematically showing a blockchain-based carbon emissions trading information management system according to an embodiment of the present invention.
Figure 2 is a block diagram showing a configuration related to the operation of adding a transaction block to the blockchain according to a transaction input request from a client node in the transaction information management system of Figure 1;
Figure 3 is a block diagram showing the configuration related to the operation of providing transaction history information on the blockchain based on the transaction block according to the transaction inquiry request from the client node in the transaction information management system of Figure 1;
Figure 4 is a diagram showing an example of the transaction information management system of Figure 1 implemented through a Hyperledger Fabric-based architecture.

Specific details, including the problem to be solved by the present invention, the means for solving the problem, and the effect of the invention, are included in the examples and drawings described below. The advantages and features of the present invention and how to achieve them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. Like reference numerals refer to like elements throughout the specification.

Figure 1 is a diagram schematically showing a blockchain-based carbon emissions trading information management system according to an embodiment of the present invention, and Figure 2 shows a transaction block according to a transaction input request from a client node in the transaction information management system of Figure 1. It is a block diagram showing the components that perform the operation of adding to the blockchain, and FIG. 3 shows the operation of providing transaction history information on the blockchain based on the transaction block according to the transaction inquiry request from the client node in the transaction information management system of FIG. 1. It is a block diagram showing the configurations that perform, and FIG. 4 is a diagram showing an example of the transaction information management system of FIG. 1 implemented through a Hyperledger Fabric-based architecture.

Hereinafter, a blockchain-based carbon emissions trading information management system according to an embodiment of the present invention will be described with reference to the above-described drawings.

First, referring to FIG. 1, the blockchain-based carbon emissions trading information management system according to an embodiment of the present invention largely includes a user request reception unit 100, a blockchain network 200, a data security unit 400, and a storage unit. It is configured to include (500), a user authentication unit (600), a transaction history provision unit (700), and a node registration unit (800).

The user request receiving unit 100 receives a user request for inquiry or input of carbon emission trading information from the client node 10 corresponding to the user.

The client node 10 is a type of terminal device capable of executing an application that enables communication connection to the transaction information management system according to the present invention, and as shown in FIG. 1, it includes a corporate terminal 11 used for corporate financial transactions and It may include a user terminal 12 carried by an individual user.

Specifically, the client node 10 corresponds to a corporate terminal 11 that participates in a carbon emissions trading transaction, and includes a first client node that requests input of transaction information according to the transaction, and a donation collection fee for the carbon emissions trading transaction. It may include a second client node that corresponds to the user terminal 12 participating in and requests an inquiry about transaction history information based on a specific point in time.

For example, the second client node corresponds to the terminal 12 of a user who purchased an NFT-based PFP (Profile Picture) issued to raise carbon credit-related costs, and the first client node It may correspond to the terminal (11) of a company that participated in a transaction to resell carbon credits purchased to companies.

At this time, a client application capable of communicating with the carbon emission trading information management system 30 according to the present invention may be pre-installed on the client node 10.

In this case, when a user executes a client application and inputs a specific user request related to transaction information, the application generates a transaction proposal corresponding to the input request and transmits it to the user request receiver 100. You can.

Accordingly, the user request receiver 100 receives a transaction proposal corresponding to the user request, and the received transaction proposal is delivered to the guarantee node 210 of the blockchain network 200. You can.

Meanwhile, the user request receiving unit 100 includes a router unit 120 that provides an API path that allows a client application running on the client node 10 to access the blockchain network 200, and a router unit 120 that provides an API path that allows the client application running on the client node 10 to access the blockchain network 200. When receiving a transaction input request, it may include a data stream unit 140 that receives new transaction information corresponding to the transaction input request and converts it into a packet form to generate a data stream.

Here, the router unit 120 and the data stream unit 140 are configured as an API gateway and Kinesis Data Streams, respectively, when implemented with a Hyperledger Fabric-based architecture as shown in FIG. 4. It may be a correspondence.

The blockchain network 200 forms a single blockchain by connecting a plurality of participating nodes 20, in which the identities of network participating members are authenticated and authorized, to each other.

Here, the blockchain formed by the blockchain network 200 is a private blockchain with the characteristics that only authorized organizations or individuals can participate in the network and only participants authorized by an entity with block approval authority can create blocks. (Private Blockchain).

The blockchain network 200 receives the encrypted data of the carbon emissions trading ledger (L _T ) from the storage unit 500 and divides it into distributed ledgers (L _D ) corresponding to the number of participating nodes (20). Distributed storage at participating nodes (20).

The blockchain network 200 performs user authentication for the request received from the client node 10 and verification of the transaction according to the request, and generates a transaction block in which the transaction is blocked based on the execution result.

In this regard, the blockchain network 200 may include an endorsement node 210, a peer node 220, and an orderer node 230, as shown in FIGS. 2 and 3.

The assurance node 210 receives a transaction proposal corresponding to the user request from the user request receiver 100, generates a request transaction (Tx) accordingly, and returns the execution result to the client node 10. .

Peer node 220 hosts at least one distributed ledger (L _D ), and has an execution function for a transaction that accesses each distributed ledger (L _D ) and applies state changes to that distributed ledger (L _D ). Hosts the defined chaincode (CC).

Here, the number of peer nodes 220 may be equal to the number of participating nodes 20, and the chain code includes a function for executing a write operation to additionally input new transaction information and a read function for querying existing transaction information. One of the functions that executes the action may be written in a code language.

The orderer node 230 generates a transaction block (BT) that blocks the transaction based on the result of executing the request transaction (Tx) generated by the guarantee node 210.

When a plurality of request transactions (Tx) are executed by the guarantee node 210 for a predetermined period of time, the orderer node 230 orders the executed request transactions (Tx) according to a preset consensus algorithm and blocks them into transaction blocks. (BT) can be created.

The orderer node 230 may distribute the transaction block (BT) to a plurality of peer nodes 220 so that the distributed ledger (L _D ) is updated by the transaction block (BT).

In this case, the peer node 220 receives from the storage unit 500 the current state information of the carbon emissions trading ledger (L _T ), which changes depending on the creation and type of a transaction block (BT), and stores the corresponding distributed ledger ( L _D ) may be updated in real time.

The data security unit 400 secures transaction information according to user requests using encryption/decryption technology.

When a transaction block (BT) is created by the orderer node 230, the data security unit 400 can encrypt or decrypt the data of the transaction block (BT) by generating an encryption key based on a preset encryption key service. there is.

In this regard, the data security unit 400 may include an encryption key generation unit 420, an encryption unit 440, and a decryption unit 460.

The encryption key generator 420 generates an encryption key based on the encryption key service (KMS; Key Management Service) when generating the first transaction block (BT1) according to the user's transaction input request.

Encryption Key Service (KMS) is a data key that can encrypt or decrypt data requiring security using a Customer Master Key (CMK) that is uniquely assigned to each customer and managed through a client application. By providing a function to generate a , the above-described data key may correspond to an encryption key generated by the encryption key generator 420 according to the present invention.

The encryption unit 440 encrypts the data of the first transaction block (BT1) using an encryption key generated upon creation of the first transaction block (BT1).

The decryption unit 460 decrypts the encrypted data (De) stored in the storage unit 500 at the current time when generating the second transaction block (BT2) according to the user's transaction inquiry request using the encryption key matched thereto.

Here, when the above-described encryption unit 440 and decryption unit 460 are implemented with a Hyperledger Fabric-based architecture as shown in FIG. 4, encryption or decryption is performed using a Lambda function based on the Python language. It may correspond to the code value in which the function for the algorithm was written.

The transaction history provider 800 provides transaction history information based on the data (Dd) decrypted by the decryption unit 460 to the client node 10 corresponding to the user request reflected in the creation of the second transaction block (BT2). do.

The storage unit 500 stores data (De) encrypted by the encryption unit 440 on the carbon emission trading ledger (L _T ) in which transaction details for each company corresponding to each of the plurality of participating nodes 20 are recorded. .

The storage unit 500 updates the previously stored encryption data (De) by adding transaction block data encrypted by the encryption unit 440, and matches the encryption key generated by the encryption key generation unit 420 to it. Save.

At this time, the transaction ledger (L _T ) records the world state, which is a ledger database that stores the ledger state (e.g., account balance state) at the current point in time, and all transactions that have become the current value are recorded as the world state. It may correspond to a combination of transaction logs that update .

The user authentication unit 600 serves to limit access rights to the blockchain network 200 so that only authorized participants are allowed access.

When a request from the client node 10 is received, the user authentication unit 600 checks the validity of the certificate issued through a certificate authority (CA) with respect to the unique ID information of the client node 10. Based on this, user authentication is performed to confirm the identity of the client node 10.

When user authentication by the user authentication unit 600 is completed, the node register 800 permits registration of the client node 10 by mutual agreement of a plurality of participating nodes 20 constituting the blockchain network 200. If so, the corresponding client node 10 is added as a member of the blockchain network 200.

Here, the above-described user authentication unit 600 and node registration unit 800 correspond to the configuration of a membership service provider (MSP) when implemented with a Hyperledger Fabric-based architecture as shown in FIG. 4. It may be.

Accordingly, according to the present invention described above, the security of the data subject to management can be maximized by individually encrypting the carbon emissions trading data for each company and storing the data record and the decryption key to decrypt it in the blockchain. You can.

In addition, according to the present invention, transaction information is processed and encrypted based on blockchain technology and stored in the blockchain, making hacking virtually impossible, and even if an error occurs in the system, the transaction information combined and registered in the blockchain is safe. Because it is distributed and stored, data loss can be prevented in advance.

In addition, according to the present invention, by using private blockchain technology, only companies that are parties to a transaction are granted permission to participate in the blockchain network, and stakeholders related to the transaction amount are given limited authority to access and inquire into the network. By granting a system, it is possible to build a system at a lower cost than in the case of a general public blockchain, and the reliability and transparency of data can be strengthened.

Above, the present invention has been described in detail through preferred embodiments, but the present invention is not limited thereto and may be implemented in various ways within the scope of the patent claims.

In particular, the foregoing has described the features and technical strengths of the present invention rather broadly to enable a better understanding of the claims of the invention to be described later. Therefore, the concept and specific embodiments of the present invention described above are intended to serve a similar purpose as the present invention. It should be recognized by those skilled in the art that it can be immediately used as a basis for the design or modification of other shapes for use.

In addition, the embodiment described above is only one embodiment according to the present invention, and can be implemented in various modified and changed forms by those skilled in the art within the scope of the technical idea of the present invention. You will understand. Accordingly, the disclosed embodiments should be considered from an explanatory rather than a limiting perspective, and various modifications and changes thereof are also included in the scope of the technical spirit of the present invention and are indicated in the claims of the present invention, and the scope equivalent thereto is thereto. All differences therein should be construed as being included in the present invention.

10: Client Node 20: Participating Node
30: Transaction information management system 100: User request receiving unit
120: router unit 140: data stream unit
200: Blockchain network 210: Endorsement node
220: Peer node 230: Orderer node
400: Data security unit 420: Encryption key generation unit
440: Encryption unit 460: Decryption unit
500: storage unit 600: user authentication unit
700: Transaction details provision unit 800: Node register

Claims (5)

a user request receiver that receives a user request for inquiry or input of carbon emissions trading information from a client node corresponding to the user;
A plurality of participating nodes in which the identity of network participating members is authenticated and authorized are connected to each other to form a single blockchain, and the result is user authentication for the request received from the client node and verification of the transaction according to the request. A blockchain network that generates a transaction block based on the transaction;
When the transaction block is created, a data security unit that generates an encryption key based on a preset encryption key service to encrypt or decrypt the data of the transaction block; and
With data encrypted in the carbon emissions trading ledger in which transaction details for each company corresponding to each of the plurality of participating nodes are recorded, the encrypted transaction block data is added and updated, and the generated encryption key is matched thereto. It includes a storage unit that stores the
The blockchain network is,
A distributed ledger in which the encrypted data stored in the storage unit is divided corresponding to the number of the plurality of participating nodes is distributed and stored in each participating node, and the carbon emission trading ledger that changes depending on whether or not the transaction block is created and the type of the transaction block is distributed. A blockchain-based carbon emissions trading information management system that updates current status information in real time to the distributed ledger. According to paragraph 1,
The blockchain network is,
an assurance node that generates a request transaction according to the received user request and returns the execution result to the client node;
A plurality of peer nodes hosting at least one distributed ledger, each of which hosts a chaincode defining an execution function for a transaction that accesses the distributed ledger and applies a state change to the distributed ledger; and
An orderer node that distributes transaction blocks ordered and block according to a preset consensus algorithm based on the request transaction and the result of executing it to the plurality of peer nodes so that the distributed ledger is updated by the transaction block. A blockchain-based carbon emissions trading information management system characterized by: According to paragraph 1,
The data security department,
an encryption key generator that generates an encryption key based on the encryption key service when generating a first transaction block according to a user's transaction input request;
an encryption unit that encrypts the first transaction block data using the encryption key generated upon creation of the first transaction block; and
Blockchain-based carbon, comprising a decryption unit that decrypts the encrypted data stored in the storage unit at the current time when generating a second transaction block according to the user's transaction inquiry request using an encryption key matched thereto. Emissions trading information management system. According to paragraph 1,
The user request receiver,
a router unit providing an API path that allows a client application running on the client node to access the blockchain network; and
When receiving a user's transaction input request from the client node, a data stream unit that receives new transaction information corresponding to the transaction input request and converts it into a packet form to generate a data stream; a block characterized in that it includes a. Chain-based carbon emissions trading information management system. According to paragraph 1,
When a request from the client node is received, user authentication is performed to confirm the identity of the client node based on the results of checking the validity of a certificate issued through a certification authority for the unique ID information of the client node. wealth; and
After the user authentication is completed, a node register that adds the client node as a member of the blockchain network when registration of the client node is permitted by mutual agreement of the plurality of participating nodes constituting the blockchain network; A blockchain-based carbon emissions trading information management system further comprising:

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