计及多时间尺度碳排放因子的虚拟电厂-配电网协同调度

doi:10.11930/j.issn.1004-9649.202508039

摘要/Abstract

摘要：

随着双碳目标的推进，电力系统的低碳化运行成为研究热点，虚拟电厂与配电网的协同调度面临多时间尺度碳排放量化不足的挑战。为此，提出一种计及多时间尺度碳排放因子的虚拟电厂-配电网协同调度模型。首先，将新能源弃风弃光现象考虑到碳排放因子计算中，并通过多时间尺度修正机制提升碳排放因子的时空精度。其次，构建粗调-细调的多时间尺度协同调度框架：日前调度以经济性和安全性为目标，日内调度基于实时数据修正碳排放因子并优化运行策略。最后，采用目标级联分析法求解模型。算例分析表明，改进的碳排放因子能有效区分零碳时段的风光消纳差异，相比传统碳排放因子计算方法使配电网碳排放量减少4.7t，碳排放成本下降17.5%。多时间尺度协同机制显著提升了新能源消纳能力与经济性，为电力系统低碳调度提供了有力支持。

关键词: 多时间尺度碳排放因子, 虚拟电厂, 协同调度, 新能源消纳, 目标级联分析

Abstract:

With the advancement of dual-carbon goals, the low-carbon operation of power systems has become a research focus. However, the coordinated dispatch between virtual power plants (VPPs) and distribution networks (DNs) faces challenges due to insufficient multi-time scale carbon emission quantification. To address this issue, this paper proposes a coordinated dispatch model for VPPs and DNs that incorporates multi-time scale carbon emission factors. First, the phenomenon of renewable energy curtailment is integrated into the carbon emission factor calculation, and a multi-time scale correction mechanism is introduced to enhance the spatiotemporal accuracy of the carbon emission factors. Second, a coarse-fine tuning multi-time scale coordinated dispatch framework is established: the day-ahead scheduling prioritizes economic efficiency and security, while the intraday scheduling adjusts carbon emission factors and optimizes operational strategies based on real-time data. Finally, the model is solved using the analytical target cascading method. Case study shows that the improved carbon emission factor can effectively differentiate the accommodation differences of wind and solar power during zero-carbon periods. Compared with traditional carbon emission factor calculation methods, it reduces the DNs' carbon emissions by 4.7 tons and cuts carbon emission costs by 17.5%. The multi-time scale coordination mechanism significantly enhances the renewable energy accommodation capacity and economic efficiency, providing strong support for low-carbon dispatch of the power system.

Key words: multi-time scale carbon emission factors, virtual power plant, coordinated dispatch, renewable energy accommodation, analytical target cascading

王泽森, 王宣元, 孔帅皓, 孙舶皓, 季震, 孙巍. 计及多时间尺度碳排放因子的虚拟电厂-配电网协同调度[J]. 中国电力, 2026, 59(3): 14-26.

WANG Zesen, WANG Xuanyuan, KONG Shuaihao, SUN Bohao, JI Zhen, SUN Wei. Coordinated dispatch of virtual power plant and distribution network considering multi-time scale carbon emission factors[J]. Electric Power, 2026, 59(3): 14-26.

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链接本文: https://www.electricpower.com.cn/CN/10.11930/j.issn.1004-9649.202508039

https://www.electricpower.com.cn/CN/Y2026/V59/I3/14

图/表 13

图 1 多时间尺度协同调度机制

Fig.1 Multi-time scale coordinated scheduling mechanism

图 2 日前调度求解流程

Fig.2 Day-ahead scheduling solution process

图 3 日内调度求解流程

Fig.3 Intraday scheduling solution process

图 4 配电网拓扑

Fig.4 DN topology

表 1 分时电价

Table 1 Time-of-use electricity price

时段	电价/(元·(MW·h)^–1)
00:00—05:00，23:00—24:00	385
05:00—07:00，16:00—18:00，21:00—23:00	754
07:00—16:00，18:00—21:00	1 020

图 5 配电网碳排放因子

Fig.5 Carbon emission factors of DN

图 6 配电网碳排放因子变化

Fig.6 Variation of the carbon emission factor in DN

表 2 不同碳排放因子计算方法对比

Table 2 Comparison of the carbon emission factor calculation methodologies

碳排放因子计算方法	配电网碳排放量/t	配电网碳排放成本/元
传统碳排放因子	26.88	1 967.62
改进的碳排放因子	22.18	1 623.28

图 7 配电网调度结果

Fig.7 Dispatch results of DN

图 8 VPP1调度结果

Fig.8 Dispatch results of VPP1

表 3 系统调度成本对比

Table 3 Comparison of the power system dispatch costs

碳排放因子计算方法	碳排放量/t	碳排放成本/元	弃风/弃光成本/元	购电成本/元	机组发电成本/元	总成本/ 元
传统碳排放因子	49.2	3 600.7	1 201.4	7 913.3	5 963.7	18 679.1
改进的碳排放因子	39.9	2 921.1	0.0	8 137.7	5 879.1	16 937.9

图 9 日内碳排放因子修正情况

Fig.9 Intraday carbon emission factor correction

表 4 日内-日前系统调度成本对比

Table 4 Comparison of the day-ahead and intraday power dispatch costs

时间尺度	碳排放量/t	碳排放成本/元	弃风弃光成本/元	购电成本/元	机组发电成本/元	总成本/ 元
日前（传统碳排放因子）	49.2	3 600.7	1 201.4	7 913.3	5 963.7	18 679.1
日前（改进的碳排放因子）	39.9	2 921.1	0.0	8 137.7	5 879.1	16 937.9
日内（改进的碳排放因子）	41.2	3 018.4	315.2	8 054.6	5 912.4	17 300.6

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