Local Control Strategy for Optimal Power Flow in Low-Voltage Distribution Network Based on Robust Stochastic Optimization

doi:10.16183/j.cnki.jsjtu.2024.066

Abstract

Abstract:

With the promotion of the “dual carbon” goal and the construction of new power systems, the complexity and uncertainty of power systems have increased dramatically, which brings challenges of high proportion of distributed energy and asymmetric loads, such as voltage overstep and three-phase imbalance to distribution network. To cope with these problems, this paper proposes a local control strategy for optimal power flow (OPF) in low voltage distribution network based on robust stochastic optimization (RSO), which uses a 1-norm Wasserstein distance uncertainty set to describe the output uncertainty of distributed energy resource (DER), and builds a robust stochastic optimization model for three-phase four-wire low-voltage distribution network. This model aims to minimize control costs and network losses, while considering the expected adjustments under worst-case scenarios. Local control strategies for distributed energy are obtained without communication infrastructure by convolutional neural networks training. The simulation results verify the effectiveness and economy of the proposed control strategy.

Key words: optimal power flow (OPF), three-phase four-wire system, distributed energy resource (DER), robust stochastic optimization (RSO), Wasserstein distance

CLC Number:

TM732

WANG Rui, BAI Xiaoqing, HUANG Shengquan. Local Control Strategy for Optimal Power Flow in Low-Voltage Distribution Network Based on Robust Stochastic Optimization[J]. Journal of Shanghai Jiao Tong University, 2026, 60(2): 235-245.

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方案	电压最大值 (p. u.)	网络损耗/%	三相不平衡度/%	综合成本/ 美元
①	1.145	6.43	8.47	0
②	1.089	5.89	2.00	45 097
③	1.068	5.48	1.02	32 158

场景	屋顶光伏注入(p.u.)	电压幅值 (p.u.)	可控负荷变化情况
1	0	0.9930	增加
2	0	0.9940	增加
3	0	1.0000	不变
4	0	1.0240	不变
5	0	1.0460	减小
6	0	1.0480	减小
7	0.100	1.0020	增加
8	0.100	1.0312	不变
9	0.100	1.0409	不变
10	0.100	1.0511	减小
11	0.140	1.0618	减小
12	0.200	1.0132	增加
13	0.200	1.0391	不变
14	0.300	1.0300	增加
15	0.350	1.0350	增加
16	0.380	1.0390	增加
17	0.384	1.0390	增加
18	0.500	1.0460	增加
19	0.740	1.0540	增加
20	0.800	1.0470	增加