A Two-Stage Approach for PV Inverter Engagement in Power Factor Correction and Voltage Regulation

IF 4.2 2区工程技术 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Transactions on Industry Applications Pub Date : 2025-01-13 DOI:10.1109/TIA.2025.3529827

Shiva Poudel;Tylor E. Slay;Monish Mukherjee;Alexander A. Anderson;Daniel Kopin;Cyril Brunner;Kevin P. Schneider;Peter Christensen

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Abstract

Rapid integration of distributed energy resources, such as solar photovoltaic (PV), can lead to overvoltage challenges in distribution feeders due to reverse power flow and low power factor at the substation interface. While existing literature extensively explores the utilization of smart inverter capabilities for reactive power flexibility using volt-var curve (VVC), obtaining time-varying operating points of such curves in real-time is challenging due to computational demands and communications requirements. Similarly, employing optimization-based approaches for reactive power control and active voltage regulation in large-scale distribution feeders is difficult due to the complexity of the problem and the challenges in effectively engaging customer-owned resources. This paper proposes a two-stage strategy to harness smart inverters for reactive power support. The first stage formulates short-term planning by optimally designing VVCs (sub-daily basis) for large-scale solar PVs based on projected system needs and communicating optimal curves to smart inverters in advance. Subsequently, the second stage employs a transactive-based method to involve customer-owned PVs for reactive power support, effectively enhancing overall system performance and addressing real-time demands. The efficacy of this approach will be demonstrated using real-world distribution circuits provided by Vermont Electric Power Company (VELCO) and Vermont Electric Cooperative (VEC).

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光伏逆变器功率因数校正和电压调节的两阶段方法

太阳能光伏（PV）等分布式能源的快速集成会导致配电馈线出现过电压问题，原因是变电站接口处存在反向功率流和低功率因数。虽然现有文献广泛探讨了如何利用智能逆变器的功能，通过伏-变曲线（VVC）实现无功功率灵活性，但由于计算需求和通信要求，实时获取此类曲线的时变工作点具有挑战性。同样，在大规模配电馈线中采用基于优化的方法进行无功功率控制和有功电压调节也很困难，因为问题十分复杂，而且在有效利用客户拥有的资源方面也存在挑战。本文提出了一种分两个阶段利用智能逆变器进行无功功率支持的策略。第一阶段根据预测的系统需求，为大规模太阳能光伏发电优化设计 VVC（分日），制定短期规划，并提前将优化曲线通知智能逆变器。随后，第二阶段采用基于事务处理的方法，让客户拥有的光伏发电设备参与无功功率支持，从而有效提高整体系统性能，满足实时需求。我们将利用佛蒙特电力公司（VELCO）和佛蒙特电力合作社（VEC）提供的实际配电线路来演示这种方法的功效。

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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来源期刊

IEEE Transactions on Industry Applications 工程技术-工程：电子与电气

CiteScore

9.90

自引率

9.10%

发文量

747

审稿时长

3.3 months

期刊介绍： The scope of the IEEE Transactions on Industry Applications includes all scope items of the IEEE Industry Applications Society, that is, the advancement of the theory and practice of electrical and electronic engineering in the development, design, manufacture, and application of electrical systems, apparatus, devices, and controls to the processes and equipment of industry and commerce; the promotion of safe, reliable, and economic installations; industry leadership in energy conservation and environmental, health, and safety issues; the creation of voluntary engineering standards and recommended practices; and the professional development of its membership.