Evaluation of Virtual Power Plant Flexibility Resources Based on External Characteristic Equivalence

doi:10.11930/j.issn.1004-9649.202310002

Abstract

Abstract:

In order to fully utilize the clean, flexible and economic characteristics of distributed energy(DE), it is needed to efficiently manage its comprehensive and flexible regulation characteristics. However, directly embedding the virtual power plant(VPP) model into the main grid scheduling is prone to the risk of privacy leakage and great computational burden of different energy entities. Therefore, it is necessary to aggregate the multi-category flexibility resources of VPP to calculate their equivalent external characteristics. To this end, this article proposes a VPP flexibility characterization method based on vertex search, which aggregates various flexibility within the VPP into the output power of the VPP nodes, whose mathematical essence is the projection of a high-dimensional flexibility space to a low-dimensional space. Then, by introducing the extrapolation-based vertex search method, we achieve the approximation of the projection by maximizing the Euclidean distance between hyperplanes. Finally, based on the flexibility equivalence method, we propose an evaluation method for VPP flexibility resources to explain the main grid operation cost and optimal solution changes before and after the VPP access from a geometric perspective. The case study shows that the proposed flexibility aggregation model can effectively reduce the operating cost of the main grids, and the proposed VPP value assessment method based on external characteristic equivalence can effectively evaluate the value generated by various types of flexible equipment under small changes of flexibility ranges.

Key words: distributed energy, virtual power plant, vertex search, flexibility value assessment

Rui ZHU, Yiding OU, Xiaotian LI, Xingyu LEI, Yuqing ZHOU, Poyang ZHANG, Rui OU. Evaluation of Virtual Power Plant Flexibility Resources Based on External Characteristic Equivalence[J]. Electric Power, 2024, 57(1): 30-39.

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URL: https://www.electricpower.com.cn/EN/10.11930/j.issn.1004-9649.202310002

https://www.electricpower.com.cn/EN/Y2024/V57/I1/30

Figures/Tables 14

Fig.1 Maximum and minimum point projection diagram

Fig.2 Hyperplane extrapolation process

Fig.3 Complete process of hyperplane extrapolation

Fig.4 Flow chart of the flexibility characterization method based on vertex search

Fig.5 Geometric diagram of optimal solution variation

Fig.6 Calculation diagram of optimal solution variation

Fig.7 VPP energy composition and flexibility resource utilization when supplying energy

Fig.8 VPP energy composition and flexibility resource utilization when consuming energy

Fig.9 Variation of flexibility with the number of devices

Fig.10 Variation of main grid operating costs with the number of devices

Fig.11 Variation of operating costs with the access location of high-energy equipment

Fig.12 Variation of operating costs with the access location of P2G equipment

Fig.13 Variation of operating costs with the access location of captive power plant equipment

Table 1 Comparison of the value assessment methods and optimization results

设备	本文方法	优化结果
自备电厂	1.984	2.031
P2G	1.185	1.187
工业高载能	1.000	1.000

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