Distributed Optimization for VPP and Distribution Network Operation Considering Uncertainty and Green Certificate Market

doi:10.11930/j.issn.1004-9649.202409069

Abstract

Abstract:

In order to cope with the uncertainties brought by the growing scale of renewable energy, this paper proposed a distributed optimization for virtual power plant (VPP) considering uncertainties. On the VPP side, a scenario-based stochastic optimization model was used to depict the stochastic characteristics of photovoltaic and wind power output. On the distribution network side, considering the uncertainty of electricity prices when purchasing power from the grid, a two-stage robust optimization model and an opportunity model based on information gap decision theory were established to enhance the model's robustness against electricity price fluctuations or to capture potential benefits amidst volatile electricity prices. The problem was solved distributedly between the VPP and the distribution network through the alternating direction multiplier method algorithm to protect their privacy. The results show that the proposed model is more flexible than the robust model and can better balance the risks and benefits under uncertain conditions. The distributed algorithm has a good convergence performance and can better utilize computing resources compared to the centralized algorithm.

Key words: virtual power plant, distribution network, tradable green certificate market, uncertainty, distributed optimization

WANG Jinfeng, LI Jinpeng, XU Yinliang, LIU Haitao, HE Jinxiong, XU Jianyuan. Distributed Optimization for VPP and Distribution Network Operation Considering Uncertainty and Green Certificate Market[J]. Electric Power, 2025, 58(4): 21-30, 192.

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URL: https://www.electricpower.com.cn/EN/10.11930/j.issn.1004-9649.202409069

https://www.electricpower.com.cn/EN/Y2025/V58/I4/21

Figures/Tables 7

Fig.1 33-bus system topology used in the case study

Fig.2 Typical scenarios for the PV and WT power output in the VPP 1

Fig.3 Electricity prices obtained under different conservativeness level based on the IGDT model

Fig.4 Cost comparison of the RM model and OM model with different parameters

Fig.5 Operational strategy for VPP 2

Fig.6 Cost and carbon emission of VPP under different renewable energy output level

Fig.7 Convergence process of the distributed algorithm

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