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KR-20260062738-A - Blockchain-based battery history management system and battery safety management system using it

KR20260062738AKR 20260062738 AKR20260062738 AKR 20260062738AKR-20260062738-A

Abstract

A blockchain-based battery history management system and a battery safety management system using the same are disclosed. The blockchain-based battery history management system comprises: an input communication module connected to an energy storage system via a wired or wireless method to receive information regarding the battery from the energy storage system; an output communication module that transmits the information regarding the battery transmitted to the input communication module to a blockchain network; a control module that controls the input communication module and the output communication module when there is a user request to transmit a request for certificate issuance or safety verification of the energy storage system to the blockchain network and processes to receive the certificate or safety verification result processed in the blockchain network; and a storage module that non-temporarily stores information regarding the battery, the certificate, and the safety verification result according to the control of the control module.

Inventors

  • 장병훈
  • 김기욱
  • 최백성

Assignees

  • 한국전력정보(주)

Dates

Publication Date
20260507
Application Date
20241029

Claims (7)

  1. In a blockchain-based battery history management system, An input communication module connected to an energy storage system via wired or wireless means to receive information regarding a battery from the energy storage system; An output communication module that transmits information regarding the battery transmitted to the above input communication module to a blockchain network; A control module that, upon a user's request, controls the input communication module and the output communication module to transmit a request for certificate issuance or safety verification of the energy storage system to a blockchain network, and processes to receive the certificate or safety verification result processed by the blockchain network; and A storage module that non-temporarily stores information regarding the battery, the certificate, and the safety verification results according to the control of the control module; comprising Blockchain-based battery history management system.
  2. In Article 1, The above control module is characterized by receiving information regarding the target battery of the received certificate issuance request from the battery management module of the energy storage system through the input communication module when it receives a user's request for certificate issuance. Blockchain-based battery history management system.
  3. In Article 1, The above control module is characterized by receiving information regarding the target battery of the received safety verification request from the battery management module of the energy storage system through the input communication module when it receives a user's safety verification request. Blockchain-based battery history management system.
  4. A participating node participating in a blockchain-based battery history management system comprising: an input communication module connected to an energy storage system via a wired or wireless method to receive information regarding a battery from the energy storage system; an output communication module that transmits the information regarding the battery transmitted to the input communication module to a blockchain network; a control module that, upon a user request, controls the input communication module and the output communication module to transmit a request for certificate issuance or safety verification of the energy storage system to the blockchain network and processes to receive the certificate or safety verification result processed by the blockchain network; and a storage module that non-temporarily stores the information regarding the battery, the certificate, and the safety verification result according to the control of the control module; A certificate issuance mining node participating in a certificate issuance processing system that processes the issuance of a certificate for the corresponding battery upon receiving a certificate issuance request from the above-mentioned battery history management system; A safety verification mining node participating in a safety verification processing system that processes safety verification for the battery upon receiving a safety verification request from the above-mentioned battery history management system; A light node storing partial records of transactions of the above-mentioned participating node, the above-mentioned certificate issuance mining node, and the above-mentioned security verification mining node; and A pool node that stores all records of transactions of the above-mentioned participating node, the above-mentioned certificate issuance mining node, and the above-mentioned security verification mining node; Battery safety management system utilizing a blockchain-based battery history management system.
  5. In Paragraph 4, The above-mentioned participating node participates in a blockchain network using a battery history management system attached to an energy storage device, and is characterized by being able to function as the above-mentioned light node and the above-mentioned full node. Battery safety management system utilizing a blockchain-based battery history management system.
  6. In Paragraph 4, The mining node for issuing the above certificate is Characterized by performing a certificate creation transaction using the battery information of the participating node in response to a certificate issuance request from the participating node, thereby creating a new block and connecting it to the existing blockchain. Battery safety management system utilizing a blockchain-based battery history management system.
  7. In Paragraph 4, The above-mentioned mining node for safety verification is, Characterized by performing a safety verification transaction using battery information by the participating node in response to a safety verification request from the aforementioned participating node, thereby creating a new block and connecting it to the existing blockchain. Battery safety management system utilizing a blockchain-based battery history management system.

Description

Blockchain-based battery history management system and battery safety management system using it Blockchain-based battery history management system and battery safety management system using it The present invention relates to a battery history management system and a battery safety management system using the same, and more specifically, to a blockchain-based battery history management system that stores and processes battery history in a distributed network and a battery safety management system using the same. Recently, blockchain technology is being utilized in various fields beyond cryptocurrencies. One such application is the battery traceability system. Blockchain-based battery traceability systems enable the transparent and secure management of the entire process, from battery manufacturing to disposal. When blockchain technology is applied to a battery history management system, data is not concentrated on a central server but can be distributed and stored on the computers of network participants. All transaction records are permanently stored on the blockchain and can be verified by anyone. Once recorded, data cannot be altered or deleted, making tampering impossible. Data is protected through encryption technology, ensuring safety from hacking. The blockchain technology applied to this battery history management system executes contracts by implementing the conditions of each stage—such as manufacturing, sale, use, and disposal—through automated code. Furthermore, it represents batteries as digital assets called tokens to prove ownership and facilitate transactions. External data (e.g., battery performance data, environmental data) can be connected to the blockchain to update information in real time. It is an algorithm that defines the process of network participants creating new blocks and reaching consensus. The advantage of a battery history management system is that it can enhance consumer trust by transparently tracking the entire history of a battery from manufacturing to disposal. Since data falsification is impossible, it ensures confidence in the battery's performance and safety. Through an automated system, management costs can be reduced and processing speeds improved. It offers the advantage of securely protecting data through encryption technology and being safe from hacking. Furthermore, there is a need for its development in that it can prevent illegal distribution by tracking the movement of batteries and enable a rapid response in the event of a recall. FIG. 1 is a block diagram exemplarily illustrating a blockchain-based battery history management system according to one embodiment of the present invention, FIG. 2 is a block diagram exemplarily illustrating a battery safety management system using a blockchain-based battery history management system according to another embodiment of the present invention, FIG. 3 is a block diagram exemplarily illustrating an example of the operation of the battery safety management system illustrated in FIG. 2, FIG. 4 is a block diagram exemplarily illustrating an example of the history management system illustrated in FIG. 1 interacting with a battery safety management system, FIG. 5 is a block diagram exemplarily illustrating a series of processes processed by the history management system illustrated in FIG. 4 in conjunction with a blockchain network, FIG. 6 is a block diagram exemplarily illustrating an example of the operation of the battery safety management system illustrated in FIG. 2, FIG. 7 is a flowchart illustrating, in an exemplary manner, the blockchain-based certificate issuance process illustrated in FIG. 6. FIG. 8 is a flowchart illustrating, in an exemplary manner, the blockchain-based security verification process illustrated in FIG. 6, and FIG. 9 is a flowchart illustrating the blockchain-based certificate verification process illustrated in FIG. 6. Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. The preferred embodiments of the present invention described below may be modified in various ways within the scope of the technical concept of the present invention, and it is obvious that the scope of the rights of the present invention extends to such modified embodiments. FIG. 1 is a block diagram illustrating an exemplary blockchain-based battery history management system according to an embodiment of the present invention. Referring to FIG. 1, the blockchain-based battery history management system (100) can communicate bidirectionally with an energy storage system (1000). The battery history management system (100) may be implemented by being attached to or embedded in the energy storage system (1000). Alternatively, the battery history management system (100) may be implemented by being included as a part component of the energy storage system (1000). In the case of Fig. 1, the battery history management system (100) is implemented separately from the battery man