2025年4月8日 周二
首页 > 过刊浏览>2024年第39卷第5期 >192-202. DOI:10.19781/j.issn.1673-9140.2024.05.020
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基于碳排放生产优先级的综合能源虚拟电厂优化运行策略
作者:
作者单位:

(上海电机学院电气工程学院,上海 201306)

通讯作者:

王致杰(1964—),男,博士,教授,主要从事微电网智能控制和并网等方面的研究;E?mail:wzjsdstu@163.com

中图分类号:

TM73

基金项目:

上海市自然科学基金资助项目(15ZR1417300)


Optimal operation strategy of integrated energy virtual power plant based on production priority of carbon emission
Author:
Affiliation:

(College of Electrical Engineering, Shanghai Dianji University, Shanghai 201306, China)

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    摘要:

    随着综合能源交易市场的不断发展,碳排放难以控制的问题愈发凸显。为最大程度降低综合能源交易市场的碳排放,先构建了电—热—冷—气综合能源虚拟电厂的系统构型,为其建立需求转换模型和碳排放生产优先度指标;再搭建基于碳排放生产优先级的综合能源交易分配模型;然后,根据确定的各能源交易量,以综合能源供应商、共享储能运营商和用户这三方的效益最大化为目标,优化各能源定价及需求响应策略;最后,将优化的能源交易策略与3种能源交易策略进行对比,验证该策略的有效性。研究结果表明:该策略的碳排放量比策略2、3、4的分别降低了23.4%,30.1%和21.1%,其收益总体相较策略2、3、4的相差不大。该策略能较好地促使综合能源交易市场的低碳运行,同时也兼顾经济效益。

    Abstract:

    With the continuous development of the integrated energy trading market, the issue of uncontrollable carbon emissions has become increasingly prominent. To minimize carbon emissions in the integrated energy trading market, this paper first constructs a system configuration for an electricity-heat-cooling-gas integrated energy virtual power plant, and establishes a demand conversion model and a carbon emission production priority index for it. Next, a comprehensive energy trading allocation model based on carbon emission production priority is developed. Then, based on the determined energy trading volumes, the pricing and demand response strategies for various energies are optimized with the goal of maximizing the benefits of integrated energy suppliers, shared energy storage operators, and users. Finally, the optimized energy trading strategy is compared with three other energy trading strategies, verifying its effectiveness. The research results indicate that this strategy reduces carbon emissions by 23.4%, 30.1%, and 21.1% compared to the other three strategies, respectively. While the revenue is slightly lower than that of strategies 2 and 4, the difference is around 5%, and it is even higher compared to strategy 3. This strategy effectively promotes low-carbon operation in the integrated energy trading market while also balancing economic benefits.

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杨丰任,王 鸿,王致杰.基于碳排放生产优先级的综合能源虚拟电厂优化运行策略[J].电力科学与技术学报,2024,39(5):192-202.
YANG Fengren, WANG Hong, WANG Zhijie. Optimal operation strategy of integrated energy virtual power plant based on production priority of carbon emission[J]. Journal of Electric Power Science and Technology,2024,39(5):192-202.

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