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OPTIMIZATION OF THERMOELECTRIC INTERACTION STRATEGRY OF COMMUNITY INTEGRATED ENERGY SYSTEM BASED ON BUILDING PHOTOVOLTAIC

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ã€Authorã€‘ Wei Changqi;Zhou Yuan;Jin Ying;Zhao Lei;Li Yuxin;Wang Jiangjiang;Hebei Key Laboratory of Low Carbon and High Efficiency Power Generation Technology, North China Electric Power University;Beijing Electronic Intelligent Energy Co., Ltd;

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ã€Abstractã€‘ To address the imbalance between the production and consumption of solar power in integrated communities, this article focuses on optimizing the on-site consumption of building-integrated photovoltaics(BIPV) and implementing low-carbon economic scheduling in community energy systems to facilitate energy sharing. The study employs the alternating direction multiplier method to develop a strategy for minimizing the total operating cost of community groups while also preserving the privacy of participating members.Additionally, the Shapley value method is utilized to allocate benefits based on the contribution of participating communities. Through mathematical analysis, this article examines the performance of the community integrated energy system under interactive operation and compares it with the independent operation approach. The calculations demonstrate that the interactive operation strategy offers a 3% to 5% increase in operating cost efficiency compared to independent operations. It also results in a carbon emission reduction efficiency improvement of 4% to 8% and a 4% to 25% increase in photovoltaic consumption. However, the interactive operation strategy has a negligible impact on the efficiency improvement in a single multi-power community combination.æ›´å¤š è¿˜åŽŸ