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光伏并网MMC-HVDC系统直流故障的协调式故障穿越策略
Coordinated fault ride-through strategy for DC faults of photovoltaic grid-connected MMC-HVDC systems
语言:
中文摘要
摘要 为了减少化石燃料的使用,采用直流架空线路的大规模光伏(PV)并网模块化多电平换流器-高压直流(MMC-HVDC)系统是未来的发展趋势。然而,直流架空线路发生短路故障的可能性较高,可能对设备造成损害。首先,本文建立了系统及光伏电站的模型;其次,针对大容量光伏双极性MMC-HVDC系统,分析了直流架空线路的单极短路接地故障;最后,提出了一种综合考虑直流断路器(DCCB)、换流站控制和光伏功率输出的协调式直流故障穿越控制策略。故障发生时,非故障极的换流站维持功率传输,计算系统的不平衡功率,并利用光伏阵列的功率输出能力优化直流线路电压,同时降低光伏功率输出。为应对瞬时性故障,提出了光伏电站的负荷削减措施以及换流站功率前馈增量控制方法,以维持系统的功率平衡和并网运行稳定性。PSCAD/EMTDC仿真结果表明,该方法能够有效维持光伏电站和MMC-HVDC系统的正常运行,实现故障穿越。
English Abstract
Abstract To cut fossil fuel use, using DC overhead line in large-scale photovoltaic (PV) grid-connected modular multilevel converter-high voltage direct current (MMC-HVDC) systems is a future trend. But DC overhead line short-circuit faults are likely and can damage devices. First, models for the system and PV station are set up in this paper. Second, for a large-capacity PV bipolar MMC-HVDC system, a unipolar short-circuit grounding fault of DC overhead line is analyzed. Finally, a coordinated DC fault ride-through control strategy considering direct current circuit breaker (DCCB), converter station control, and PV power output is proposed. When a fault occurs, the non-fault pole converter station keeps power transmission. The unbalanced power is calculated. By using PV array power output, the DC line voltage is optimized and PV power output reduced. To handle instantaneous failures, load reduction of PV station and converter station power feed-forward incremental control are proposed to maintain system power balance and grid connection stability. PSCAD/EMTDC simulation shows the method effectively maintains PV station and MMC-HVDC system operation and achieves fault ride-through.
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SunView 深度解读
该MMC-HVDC直流故障穿越技术对阳光电源大型光伏并网系统具有重要参考价值。文中提出的协调控制策略可应用于SG系列高压光伏逆变器与储能系统的联合调度:通过ST系列PCS快速功率响应平衡故障期间的功率波动,结合iSolarCloud平台实现光伏阵列出力优化与前馈增量控制。该方案对阳光电源开发具备故障穿越能力的1500V光伏系统、提升PowerTitan储能系统在直流侧故障场景下的电网支撑能力具有创新启发,可增强大规模新能源基地的并网稳定性与智能运维水平。