含多微网的主动配电网双层分布式优化调度

doi:10.16182/j.issn1004731x.joss.21-0573

摘要/Abstract

摘要：

随着配网中可再生能源渗透比例的不断提高，传统集中式调度面临潮流计算压力大、可再生能源消纳困难等问题，难以保证系统的运行品质。提出一种含多微网的主动配网分布式双层优化调度方法。上层建立以区域配网网损最小为目标的优化模型，运用二阶锥松弛方法以及同步型ADMM(alternating direction method of multipliers)算法求解各微网联络线调度指令；下层考虑碳捕获(carbon capture and storage, CCS)、电转气(power-to-gas, P2G)等能源耦合设备与柔性负荷协调调度，建立以提高经济性、降低弃风弃光、保证环保性等为目标的下层优化模型。基于实时数据库建立仿真验证平台，以IEEE33节点系统为例，验证了所提方法的有效性。

关键词: 微电网群, 同步型ADMM, 二阶锥松弛, CCS, P2G

Abstract:

With continuous increase of the penetration proportion of renewable energy in the distribution network, the traditional centralized dispatching is facing problems such as high pressure of power flow calculation and difficulty in recycling renewable energy, which makes it difficult to guarantee the operation quality of the system. A distributed optimal two-layer scheduling method for active distribution networks with multiple micro-grids is proposed. The upper-level aims to minimize the loss of regional distribution network, the second-order conical relaxation method and synchronous ADMM (alternating direction method of multipliers) algorithm are used to solve the scheduling instructions of the micro-grid connection lines. At lower-level, the coordinated scheduling of energy coupling devices such as carbon capture and storage (CCS), power-to-gas (P2G) and flexible loads are considered, and the optimization model at lower-level is established to improve economy, reduce wind and light abandonment, and ensure environmental protection, etc. A simulation platform is established based on real-time databaseto verify the effectiveness of the proposed method by taking the IEEE33 node system as an example.

Key words: microgrid group, synchronous alternating direction method of multipliers (ADMM), second-order cone relaxation, carbon capture and storage (CCS), power-to-gas (P2G)

中图分类号:

TP319.9

林永君, 陈鑫, 杨凯, 周珊珊, 白青飞. 含多微网的主动配电网双层分布式优化调度[J]. 系统仿真学报, 2022, 34(11): 2323-2336.

Yongjun Lin, Xin Chen, Kai Yang, Shanshan Zhou, Qingfei Bai. Bilevel Distributed Optimal Dispatch of Active Distribution Network with Multi-microgrids[J]. Journal of System Simulation, 2022, 34(11): 2323-2336.

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设备	装机容量	设备功率/kW
风力	2 160 kW	—
光伏	1 500 kW	—
微燃机	600 kW	600
P2G机组	500 kW	500
电储能	750 kW·h	80
单台电动汽车	50 kW·h	20