A Parallel Decentralized Solution for Multi-Regional Unit Commitment with Convex AC Power Flow Constraints

2022 7th Asia Conference on Power and Electrical Engineering (ACPEE) Pub Date : 2022-04-01 DOI:10.1109/ACPEE53904.2022.9783909

Zitong Wang, Gengfeng Li, Yao Xiao, Shunyu Tang, Mengjie Teng

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Abstract

Scheduling a multi-regional unit commitment is an efficient way to operate the power system economically. The conventional unit commitment models, which adopts the DC power flow, fail to take the network loss and voltage drop constraints into account. This paper proposes a novel AC power flow model to fill this gap. The proposed model first achieves convexity by decomposing the nonlinear part of the network loss into the voltage amplitude part and the phase angle part, and then is formulated into two sets of linear inequalities. After that, this paper integrates it into a multi-regional unit commitment. Considering the independence and parallelism of operation between regions, the established unit commitment is solved via a parallel decentralized solution, where the simplicial decomposition method (SDM), the nonlinear block Gauss-Seidel (GS) method, and the augmented Lagrangian method (ALM) (abbreviated as SDM-GS-ALM) are integrated. Finally, the efficiency and applicability of the multi-regional unit commitment with convex AC power flow constraints are verified on IEEE Test Systems.

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具有凸型交流潮流约束的多区域机组承诺并联分散解

多区域机组负荷调度是实现电力系统经济运行的有效途径。传统的采用直流潮流的机组承诺模型没有考虑网损和压降约束。本文提出了一种新的交流潮流模型来填补这一空白。该模型首先通过将网络损耗的非线性部分分解为电压幅值部分和相角部分来实现凸性，然后将其表述为两组线性不等式。之后，本文将其整合为一个多区域的单位承诺。考虑到区域间操作的独立性和并行性，采用简化分解法(SDM)、非线性块高斯-塞德尔法(GS)和增广拉格朗日法(ALM)相结合的并行分散解求解已建立的单元承诺。最后，在IEEE测试系统上验证了带凸型交流潮流约束的多区域机组承诺的有效性和适用性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 7th Asia Conference on Power and Electrical Engineering (ACPEE)

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