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光伏发电技术
★ 5.0
基于低电压穿越与反正切控制的VSC在多光伏阵列并网系统中的应用以提升电能质量
Low Voltage Ride-Through and Arctangent Based VSC Control for High Gain Multiple PV Arrays Coupled to the Grid With Improved Power Quality Platform
| 作者 | Pavan Prakash Gupta · Shailendra Kumar · Tanu Prasad · Ramesh Kumar Tripathi |
| 期刊 | IEEE Transactions on Industry Applications |
| 出版日期 | 2025年3月 |
| 技术分类 | 光伏发电技术 |
| 相关度评分 | ★★★★★ 5.0 / 5.0 |
| 关键词 | 并网光伏系统 功率流管理 AM - LMS算法 电能质量 低电压穿越 |
语言:
中文摘要
本文提出了一种并网太阳能光伏(PV)系统,该系统旨在在正常和不平衡电压骤降条件下管理有功和无功功率流动,同时满足非线性负载需求。在公共连接点(CPC)处于正常电压时,光伏系统通过满足有功和无功功率要求实现单位功率因数(UPF)运行,光伏阵列采用扰动观察(P&O)算法在最大功率点(MPP)运行。在不平衡和电压骤降期间,该系统采用一种基于反正切的新型改进最小均方(AM - LMS)算法来维持电网支撑并防止电压源变流器(VSC)过额定运行。这是通过使一个光伏阵列以非最大功率点运行来削减其有功功率,并按照IEEE - 1547 - 2018标准向电网输送无功功率来实现的。AM - LMS算法具有快速收敛、步长参数可调、计算负担小的特点,并且在正常和异常电网条件下都能实现稳健控制。该系统平衡动态和稳态性能的能力可将电网电流总谐波畸变率(THD)降至最低,并确保具备低电压穿越(LVRT)能力。所提出的解决方案在MATLAB/Simulink中进行了建模和分析,并使用OP4510硬件进行了实时验证。结果表明,该系统能有效利用已安装的光伏容量来支撑电网,提高电能质量,并确保电压源变流器可靠运行,使其成为现代并网光伏应用的可靠解决方案。这项工作的主要发现包括:在低电压穿越期间能很好地利用已安装的光伏功率来支撑电网;能对电压源变流器进行有效的快速收敛控制,减轻控制器负担,提高电能质量;在任何电网支撑功能下都能防止电压源变流器过额定运行。
English Abstract
This paper presents a grid-tied solar photovoltaic (PV) system designed to manage active and reactive power flow during normal and unbalanced voltage sag conditions while catering to non-linear load demands. Under normal voltage at the common point of connection (CPC), the PV system achieves unity power factor (UPF) operation by meeting active and reactive power requirements, with PV arrays operating at maximum power point (MPP) using the perturb and observe (P&O) algorithm. During unbalanced and voltage sags, the system employs a novel arctangent-based modified least mean square (AM-LMS) algorithm to maintain grid support and prevent overrating of the voltage source converter (VSC). This is achieved by curtailing the active power of one PV array through non-MPP operation and delivering reactive power to the grid in compliance with IEEE-1547-2018 standards. The AM-LMS algorithm provides fast convergence, adjustable step-size parameters, reduced computational burden, and robust control under normal and abnormal grid conditions. The system's ability to balance dynamics and steady-state performance minimizes grid current total harmonic distortion (THD) and ensures low-voltage ride-through (LVRT) capability. The proposed solution is modelled and analysed in MATLAB/Simulink and validated in real-time using OP4510 hardware. Results demonstrate effective utilization of installed PV capacity for grid support, enhanced power quality, and reliable VSC operation, making it a robust solution for modern grid-tied PV applications. The main findings of the work are good utilization of installed PV powers for the grid support during LVRT, effective fast convergence control of VSC with less burden on controller with power quality and prevent over rating operation of VSC during any grid support feature.
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SunView 深度解读
从阳光电源光伏逆变器及电网解决方案业务视角来看,该论文提出的低电压穿越(LVRT)技术与基于反正切函数的改进型LMS控制算法具有显著的工程应用价值。
**核心技术价值分析:**
论文针对电网不平衡及电压跌落工况,提出通过主动调节光伏阵列偏离最大功率点运行来释放无功容量的策略,这与阳光电源在大型地面电站及工商业并网系统中面临的电网支撑需求高度契合。该技术使单台逆变器在不增加硬件成本的前提下实现有功-无功协调控制,符合IEEE-1547-2018等国际标准要求,对提升产品在海外市场的竞争力具有战略意义。AM-LMS算法的快速收敛特性和低计算负荷特点,可有效降低DSP控制器成本,这对阳光电源逆变器产品的性价比优化具有直接推动作用。
**技术成熟度评估:**
论文已完成MATLAB仿真和OP4510硬件在环验证,技术就绪度约在TRL5-6级。但从工程化角度,仍需关注:(1)多台逆变器并联时的协调控制策略;(2)长时间非MPP运行对组件热应力的影响;(3)复杂电网拓扑下算法的鲁棒性验证。
**业务机遇与挑战:**
该技术可直接应用于阳光电源新一代组串式及集中式逆变器的控制算法升级,特别是在弱电网地区和高比例新能源接入场景下的电网适应性增强。建议结合公司现有的储能系统(如PowerTitan液冷储能产品),构建光储协同的电网支撑解决方案,形成差异化竞争优势。技术挑战主要在于算法参数的自适应整定和与各国电网规范的兼容性测试,需投入中试验证资源。