Blockchain-based Distributed Contract Electricity Transfer

doi:10.3969/j.issn.1006-2475.2025.02.002

Abstract

Abstract: This paper introduces a distributed contract-based electricity transfer system leveraging blockchain technology to adapt to the diversity of the electricity market and the volatility in electricity demand. The necessary contracts for electricity transfer， namely， original contracts， electricity mutual assurance agreements， and transfer transaction contracts， are categorized into three distinct types. Specific protocols are designed for the generation of each type of contract. Verification of contract authenticity is performed using ordered multi-signature schemes， ensuring the validity of the contracts. Furthermore， broadcast encryption is employed to safeguard the privacy and accuracy of contract content. All contracts are stored on the blockchain， guaranteeing their immutability. The results of experiments demonstrate that this system significantly enhances the efficiency of contract generation and verification， facilitating swift and secure electricity transfers.

Key words: blockchain, sequential multi-signature, broadcast encryption, contractual electricity transfer, electricity demand

CLC Number:

TM73

ZHANG Zihao1, 3, YE Meng2, PAN Shixian1, MA Li2, BAO Tao1, YU Qi3. Blockchain-based Distributed Contract Electricity Transfer [J]. Computer and Modernization, 2025, 0(02): 13-18.

References

［1］ FANG R S， DAVID A K. Optimal dispatch under transmission contracts［J］. IEEE Transactions on Power Systems， 1999，14（2）:732-737.
［2］ HOGAN W W. Contract networks for electric power transmission［J］. Journal of Regulatory Economics， 1992，4（3）:211-242.
［3］陕西省发展和改革委员会关于印发《陕西电力市场合同电量转让交易实施细则（试行）》的通知［J］. 陕西省人民政府公报， 2021（16）:25-30.
［4］孙辉. 浅谈发电合同电量转让交易在广东电力市场中的作用［J］. 低碳世界， 2018（10）:108-110.
［5］ LUO X Y， XUE K P， XU J， et al. Blockchain based secure data aggregation and distributed power dispatching for microgrids［J］. IEEE Transactions on Smart Grid， 2021，12（6）:5268-5279.
［6］ QIN R Z， ZHAO L H， LI D， et al. Research on design and application of power dispatch based on blockchain［C］// 2021 the 3rd International Conference on Blockchain Technology. 2021:155-162.
［7］ HOGAN W W. Contract networks for electric power transmission: Technical reference［R］. Energy and Environmental Policy Center， 1990.
［8］陈江尧，穆海伦，裘雨音，等. 基于区块链和机器学习的分散式电力交易研究［J］. 制造业自动化， 2023，45（8）:136-140.
［9］李达，郭庆雷，冯景丽. 基于区块链的分布式电力交易隐私结算模型［J］. 电网技术， 2023，47（9）:3608-3619.
［10］陈宋宋，龚桃荣，田珂，等. 基于区块链的园区微网分布式电力交易实现机制综述［J］. 电力需求侧管理， 2023，25（4）:34-40.
［11］傅宏，杨剑蓝，李靖，等. 基于区块链的去中心化电力交易与访问控制系统［J］. 计算机应用与软件， 2023，40（2）:118-123.
［12］魏文淼，张洪铭，田学刚，等. 基于区块链的含安全约束分布式电力交易方法［J］. 武汉理工大学学报（信息与管理工程版）， 2022，44（5）:766-769.
［13］杨成，卢峰，韩少勤. 基于区块链的电力交易处理方法研究与应用［J］. 微型电脑应用， 2022，38（3）:180-181.
［14］施泉生，黄晓辉，胡伟，等. 基于区块链的改进智能合约电力交易模型［J］. 电力工程技术， 2022，41（1）:11-18.
［15］ WASEEM M， ADNAN KHAN M， GOUDARZI A， et al. Incorporation of blockchain technology for different smart grid applications: Architecture， prospects， and challenges［J］. Energies， 2023，16（2）. DOI: 10.3390/en16020820.
［16］ RICHTER B， MENGELKAMP E， WEINHARDT C. Maturity of blockchain technology in local electricity markets［C］// Proceedings of the 2018 15th International Conference on the European Energy Market （EEM）. IEEE， 2018. DOI: 10.1109/EEM.2018.8469955.
［17］ WANG N Y， ZHOU X， LU X， et al. When energy trading meets blockchain in electrical power system: The state of the art［J］. Applied Sciences， 2019，9（8）. DOI: 10.3390/app9081561.
［18］ MATAMOROS J， GREGORATTI D， DOHLER M. Microgrids energy trading in islanding mode［C］// Proceedings of 2012 IEEE the 3rd International Conference on Smart Grid Communications（SmartGridComm）. IEEE， 2012:49-54.
［19］ WANG Y， MAO S W， NELMS R M. On hierarchical power scheduling for the macrogrid and cooperative microgrids［J］. IEEE Transactions on Industrial Informatics， 2015，11（6）:1574–1584.
［20］ ZHU X Z， LEUNG K. An adaptive distributed power scheduling algorithm for renewable Microgrid cooperation［C］// Proceedings of the 2017 IEEE International Conference on Communications （ICC）. IEEE， 2017. DOI: 10.1109/ICC.2017.7996940.
［21］ ORSINI L， COLLINS B， WEBB M， et al. Exergy-Technical White Paper［EB/OL］. ［2024-02-21］. https://lo3energy.com/wp-content/uploads/2018/04/Exergy-BIZWhitepaper-v11.pdf.
［22］ MENGELKAMP E， GÄRTTNER J， ROCK K， et al. Designing microgrid energy markets: A case study: The Brooklyn Microgrid［J］. Applied energy， 2018，210:870-880.
［23］ Power Ledger. Power Ledger Whitepaper［EB/OL］. ［2024-02-20］. https://www.powerledger.io/company/power-ledger
-whitepaper.
［24］ NAKAMOTO S. Bitcoin: A Peer-to-peer Electronic Cash System［EB/OL］. ［2024-02-22］. http://bitcoin.org/bitcoin.pdf.
［25］刘丹，毕晓红. 多重数字签名及其应用场景［J］. 信息技术与信息化， 2022（8）:78-81.
［26］雷琼. 电子合同签署中有序多重数字签名的应用［J］. 计算机与现代化， 2016（2）:72-74.
［27］黄宗敏. Hyperledger Fabric中广播加密算法的设计与实现［D］. 北京：北京交通大学， 2023.
［28］徐朝东，王化群. 基于区块链的有序多重签名方案［J］. 南京邮电大学学报（自然科学版）， 2021，41（2）:85-94.