Comparison of Local Volt/var Control Strategies for PV Hosting Capacity Enhancement of Low Voltage Feeders

IF 0.5 Q4 ENERGY & FUELS
D. Schultis
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引用次数: 12

Abstract

The PV hosting capacity of low voltage feeders is restricted by voltage and current limits, and in many cases, voltage limit violations are the limiting factor for photovoltaic integration. To control the voltage, local Volt/var control strategies absorb or inject reactive power, provoking an additional current. This study analyzes the hosting capacity increase potential and the associated additional grid losses of local cosφ(P)- and Q(U)-control of photovoltaic inverters, and of local L(U)-control of inductive devices and its combination with Q-Autarkic prosumers. Therefore, four theoretical and one real low voltage test-feeders with distinct structures are considered: long overhead line, short overhead line, long cable, short cable and branched cable. While the theoretical test-feeders host homogeneously distributed PV-plants, the real one hosts heterogeneously distributed PV-plants. Each test-feeder is used to conduct load flow simulations in the presence of no-control and the different control strategies separately, while gradually increasing the PV-penetration. The minimum PV-penetration that provokes voltage or current limit violations is compared for the different control strategies and test-feeders. Simulation results of the theoretical test-feeders show that the hosting capacity increase potential of all local Volt/var control strategies is higher for the overhead line feeders than for the cable ones. Local L(U)-control, especially its combination with Q-Autarkic prosumers, increases the hosting capacity of all low voltage test-feeders significantly. The PV-inverter-based local Volt/var control strategies, i.e., Q(U)- and cosφ(P)-control, enable lower hosting capacity increases; in particular, cosφ(P)-control causes high additional currents, allowing the feeder to host only a relatively small PV-module rating per prosumer. Q(U)- and cosφ(P)-control are not sufficient to increase the hosting capacity of the long cable feeder significantly; they provoke high additional grid losses for the overhead line test-feeders. Meanwhile, L(U)-control, especially its combination with Q-Autarkic prosumers, increases the hosting capacity of the long cable feeder significantly, causing high additional grid losses during peak production of PV-plants. Regarding the real test-feeder with heterogeneously distributed PV-plants, on the one hand, the same trend concerning the HC increase prevails for the real branched cable test-feeder as for the theoretical short cable one. On the other hand, higher losses occur for the branched feeder in the case of L(U)-control and its combination with Q-Autarkic prosumers, due to the lower voltage set-points that have to be used for the inductive devices. All in all, the use of local L(U)-control, whether combined with Q-Autarkic prosumers or not, enables the effective and complete utilization of the existing radial low voltage feeders.
提高低压馈线光伏承载能力的局部电压/无功控制策略比较
低压馈线的光伏承载能力受到电压和电流限制,在许多情况下,违反电压限制是光伏集成的限制因素。为了控制电压,本地电压/无功控制策略吸收或注入无功功率,引发额外电流。本研究分析了光伏逆变器的局部cosφ(P)-和Q(U)-控制,以及电感器件的局部L(U)控制及其与Q-Autarkic生产消费者的组合的托管容量增加潜力和相关的额外电网损耗。因此,考虑了四种结构不同的理论低压试验馈线和一种实际低压试验馈线:长架空线、短架空线、长电缆、短电缆和分支电缆。理论上的测试馈线托管均匀分布的光伏电站,而实际的测试馈线则托管非均匀分布的太阳能电站。每个测试馈线用于在没有控制和不同控制策略的情况下分别进行潮流模拟,同时逐渐增加PV渗透率。针对不同的控制策略和测试馈线,比较引发电压或电流限制违规的最小PV穿透。理论测试馈线的仿真结果表明,架空线路馈线的所有本地电压/无功控制策略的主机容量增加潜力都高于电缆馈线。本地L(U)-控制,尤其是其与Q-Autarkic生产用户的组合,显著提高了所有低压测试馈线的托管容量。基于光伏逆变器的局部电压/无功控制策略,即Q(U)-和cosφ(P)-控制,能够实现较低的托管容量增加;特别是,cosφ(P)-控制会导致高附加电流,使馈线只能为每个生产用户提供相对较小的光伏组件额定值。Q(U)-和cosφ(P)-控制不足以显著增加长电缆馈线的承载能力;它们会引起架空线路测试馈线的高附加电网损耗。同时,L(U)-控制,特别是其与Q-Autarkic生产消费者的组合,显著增加了长电缆馈线的承载能力,在光伏发电厂的高峰生产期间造成了高的额外电网损耗。关于具有非均匀分布光伏电站的真实测试馈线,一方面,真实分支电缆测试馈线与理论短电缆测试馈线的HC增加趋势相同。另一方面,在L(U)-控制及其与Q-Autarkic生产消费者的组合的情况下,由于必须用于电感器件的较低电压设定点,分支馈线会出现更高的损耗。总之,本地L(U)-控制的使用,无论是否与Q-Autarkic生产用户相结合,都能够有效和完整地利用现有的径向低压馈线。
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
Advances in Energy Research
Advances in Energy Research ENERGY & FUELS-
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