A Power Transfer Optimization Model of Receiving-End Power Systems Considering Line Joint Temperature Rise Constraints
Zhou Niancheng1, Lan Xueke1, Mo Fuxue1, Lei Chao2, Wang Qianggang1
1. State Key Laboratory of Power Transmission Equipment & System Security and New Technology Chongqing University Chongqing 400044 China; 2. State Grid Sichuan Electric Power Company Tianfu Power Supply Company Chengdu 610000 China
Abstract:To relieve the continuous heating problem of transmission line joint caused by abnormal temperature rise under heavy load and high temperature conditions, this paper proposes an power transfer optimization model of receiving-end power system considering line joint temperature rise constraints. Firstly, based on electro-thermal coupling theory, the equivalent thermal model of line joint temperature rise and its parameter estimation method are studied. And using power flow variation as the intermediate variable, the linearized equation of line joint temperature rise with load changes under a certain operation point is derived. Combining with the topology of 220kV/110kV receiving-end power system, the linear constraints of the line joint temperature rise with power flow transferring is constructed. And then a power transfer optimization model is proposed in the constraints of line joint temperature rise, electro-thermal flow security, active power balance and radial grid structure, for the objective function of minimum switching number. The model is a mixed integer linear programming problem, so CPLEX tools are used for solving. Finally, a practical 220kV/110kV receiving-end power system is used for simulating and verifying that the proposed model is effective.
周念成, 兰雪珂, 莫复雪, 雷超, 王强钢. 计及线路接头温升约束的受端电网转供优化模型[J]. 电工技术学报, 2021, 36(15): 3237-3249.
Zhou Niancheng, Lan Xueke, Mo Fuxue, Lei Chao, Wang Qianggang. A Power Transfer Optimization Model of Receiving-End Power Systems Considering Line Joint Temperature Rise Constraints. Transactions of China Electrotechnical Society, 2021, 36(15): 3237-3249.
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2021, Vol. 36 
