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利用分布式光伏电源进行母线电压控制的协调式集中电压调节方案
Coordinated Centralized Voltage Regulation Scheme for Bus Voltage Control Using Distributed PV Sources
| 作者 | Atif Iqbal · Sheetal Deshmukh · Shirazul Islam · Mousa Marzband · Irfan Khan · Abdullah M.A.B. Al-Wahedi |
| 期刊 | IEEE Transactions on Industry Applications |
| 出版日期 | 2025年2月 |
| 技术分类 | 光伏发电技术 |
| 技术标签 | 储能系统 |
| 相关度评分 | ★★★★★ 5.0 / 5.0 |
| 关键词 | 电压偏差 光伏电源 集中式监督电压控制器 功率协调 实时数字模拟器 |
语言:
中文摘要
电力系统中的电压偏差问题,尤其是在重载和轻载条件下,已成为一个备受关注的重要问题。为解决这一问题,可利用光伏(PV)电源将电压偏差补偿至规定范围内。现有的控制方案,如P - Q - V下垂控制和网络激励自适应PQ法,存在不协调的问题,可能导致系统过载和压力过大。为满足这一需求,本文提出了一种集中式监控电压控制器(CSVC),以最小化各母线处的电压偏差。CSVC利用广域测量系统(WAMS)获取母线电压信息。基于所获取的电压偏差,CSVC为分布式光伏电源的各个本地控制器分配参考有功和无功功率信号。通过协调多个光伏电源的功率注入,所提出的CSVC确保有功和无功功率实现平衡且按比例分配,从而减轻光伏电源变流器的压力。本文的主要成果在于证明了所提出的CSVC能够在欠载和过载条件下将母线电压调节至所需范围内。所提出的CSVC分配的参考信号经过设计,使得每个光伏电源按其额定容量成比例地提供有功和无功功率,这有助于减少光伏电源变流器的过载情况。所提出的CSVC方案的有效性在实时数字仿真器(RTDS)平台上得到了成功验证,与使用一个和两个光伏电源相比,该方案通过协调三个光伏电源,可将母线电压维持在0.95 - 1.05标幺值的范围内。
English Abstract
Voltage deviation in power systems, particularly during overloading and light load conditions, has become a significant concern. To address this issue, Photovoltaic (PV) sources are used to compensate for voltage deviations within the specified range. Existing control schemes, such as P-Q-V droop and network agonist adaptive PQ method, are uncoordinated and can lead to overloading and stress on the system. To address this need, a centralized supervisory voltage controller (CSVC) is proposed in this paper to minimize voltage deviations at various buses. The CSVC uses a wide area measurement system (WAMS) to obtain information on bus voltage. Based on the available voltage deviations, the CSVC assigns reference active and reactive power signals to each local controller of the distributed PV source. By coordinating the power injection from multiple PV sources, the proposed CSVC ensures balanced and proportionate sharing of active and reactive power, thereby reducing stress on PV source converters. The main achievement of this paper is demonstrating that the proposed CSVC can regulate the voltage of the buses within the required limits during underload and overload conditions. The reference signals allocated by the proposed CSVC are designed so that each PV source supplies active and reactive power in proportion to its rated capacity. This helps reduce the overloading of PV source converters. The effectiveness of the proposed CSVC scheme is successfully validated on a real-time digital simulator (RTDS) platform, that maintains bus voltages within 0.95–1.05 pu, limit by coordinating three PV sources as compared to one and two PV source.
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SunView 深度解读
从阳光电源的业务视角来看,这项集中式协调电压控制技术(CSVC)与我们在分布式光伏并网和智能电网解决方案领域的战略布局高度契合。该技术通过广域测量系统(WAMS)实现多个光伏电源的协调控制,有效解决了传统P-Q-V下垂控制等非协调方案导致的系统应力不均问题,这对我们的光伏逆变器产品升级具有重要参考价值。
技术核心价值在于按容量比例分配有功和无功功率,避免单个逆变器过载。这与阳光电源当前推广的智能光伏系统理念不谋而合——不仅要求单机性能优越,更需要系统级的协同优化。该方案在实时数字仿真平台(RTDS)上验证了0.95-1.05标准电压范围的控制效果,技术成熟度已达到可工程化阶段,可直接应用于我们的1500V大型地面电站和工商业分布式项目。
从产品创新角度,该技术为阳光电源逆变器的电网支撑功能提供了新方向。我们可将CSVC算法集成到SG系列组串式逆变器和SG250HX集中式逆变器的控制系统中,配合现有的SVG产品线,形成"逆变器+储能+集中控制"的综合电压调节解决方案。特别是在高比例新能源接入的弱电网场景,这种协调控制能力将成为核心竞争力。
技术挑战主要在于通信延迟对控制精度的影响,以及WAMS系统的部署成本。但随着5G和边缘计算技术的成熟,这些问题正逐步得到解决。建议公司研发团队深入研究该算法的分布式实现方案,结合我们在iSolarCloud云平台的数据优势,开发具有自主知识产权的协调控制系统,抢占智能电网调控技术制高点。