2025年6月9日 周一
Home > Archive>Volume 36, Issue 2, 2021 >89-97. DOI:10.19781/j.issn.1673-9140.2021.02.011
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Bidding strategy of the virtual power plant based on the consideration of carbon-electricity integration trading in auxiliary service market
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    Abstract:

    Distributed energy and controllable load can be aggregated in virtual power plants to participate in the electricity market, ancillary service market and carbon trading market. In this paper, an operation model including wind energy, micro gas turbine, photovoltaic, electric vehicle and battery energy storage system are constructed in virtual power plant. Through further analysis the carbon-electricity integrated market characteristics, a carbon-electricity integrated trading strategy model of the virtual power plant is constructed, and the objective function and operational constraints of each unit are listed. Simulation results show that the introduction of carbon trading mechanism can significantly reduce the bidding output level of high-carbon units, and then affect the energy output structure and bidding strategy in virtual power plants. The simulation results validate the effectiveness of bidding strategy for virtual power plants with integrated carbon-electricity transaction.

    Reference
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贾德香,柳占杰,高骞,吴洁.计及碳—电一体化交易的虚拟电厂竞价策略[J].电力科学与技术学报英文版,2021,36(2):89-97. Jia Dexiang, Liu Zhanjie, Gao Qian, Wu Jie. Bidding strategy of the virtual power plant based on the consideration of carbon-electricity integration trading in auxiliary service market[J]. Journal of Electric Power Science and Technology,2021,36(2):89-97.

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  • Online: May 08,2021
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