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首页 > 过刊浏览>2021年第44卷第8期 >156-164. DOI:10.11835/j.issn.1000-582X.2020.289
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基于区块链的电力营销数据存储机制
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TP309.2

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重庆市高校优秀成果转化资助项目(KJZH17116);重庆市创新创业示范团队培育计划(CSTC2017kjrc-cxcytd0063);重庆市技术创新与应用示范重大主题专项(CSTC2018JSZX-CYZTZX0185);重庆市基础科学与前沿技术研究项目(CSTC2017jcyjAX0270)。


Storage mechanism of electricity marketing data based on blockchain
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    摘要:

    随着电力的发展电力营销数据持续增长,传统的集中式数据存储模式已经不能满足电力业务数据存储的安全性和高效性需求。针对上述问题,提出了一种基于区块链的多级加密电力营销数据存储架构,该存储架构以区块链技术作为底层技术支撑,结合分布式存储提供稳定性高、安全可靠的电力数据存储方案。同时在区块链的基础上提出多级加密机制,该机制支持电力数据上链及电力数据传输等流程的逐级加密及验证,使得电力数据存储的安全性得到进一步的保证。通过创建分布式存储设施,对提出的存储机制与集中式存储机制进行对比实验,分析实验结果发现提出的存储机制在电力数据存储方面相比于传统的存储机制在系统延迟、响应时间和吞吐量上都更具有优势,表明了该存储机制合理可行,具有良好的应用前景。

    Abstract:

    With the development of electricity supply, electricity marketing data continue to grow. Traditional centralized data storage modes have been unable to meet the security and efficiency requirements of power business data storage. To address the issues, this paper proposes a multi-level encrypted electricity marketing data storage architecture based on blockchain. The storage architecture uses the blockchain as the underlying technical support and combines with distributed storage to provide highly stable, secure and reliable power data storage scheme. At the same time, a multi-level encryption mechanism is proposed on the basis of the blockchain. This mechanism supports step-by-step encryption and verification of power data on-chain and power data transmission processes, which further guarantees the security of power data storage. The proposed storage mechanism is compared with the centralized storage mechanism by creating a distributed storage facility. The experimental results show that the proposed storage mechanism has more advantages in terms of system latency, response time, and throughput than traditional storage mechanisms, indicating that the proposed storage mechanism is reasonable and feasible and has good application prospects.

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王凌宇,傅宏,杨云,刘俊.基于区块链的电力营销数据存储机制[J].重庆大学学报,2021,44(8):156-164.

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  • 收稿日期:2020-01-15
  • 在线发布日期: 2021-08-31
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