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一种考虑故障穿越能力及交流微网稳定支持的并网储能灵活双模式切换策略
A Flexible Dual-Mode Switching Strategy for Grid-Connected Energy Storage Considering Fault Ride Through Capability and Support for AC Microgrid Stability
| 作者 | Li Wang · Ningting Zhou · Yi Shu · Xiangjun Zeng · Bin Zhao · Jie Zhao |
| 期刊 | IEEE Transactions on Energy Conversion |
| 出版日期 | 2025年2月 |
| 技术分类 | 光伏发电技术 |
| 技术标签 | 微电网 |
| 相关度评分 | ★★★★★ 5.0 / 5.0 |
| 关键词 | 光伏储能系统 切换控制 微电网稳定性 故障穿越控制 控制策略验证 |
语言:
中文摘要
摘要:可再生能源,特别是光伏发电大规模接入电网,逐渐削弱了电网强度。针对这一挑战,本文提出了一种具有电网跟随(GFL)/电网形成(GFM)控制结构的光伏储能系统新型切换控制方法。利用积分器和状态跟随法,实现了这两种控制模式之间的平滑切换控制策略,确保了系统在不同电网强度下的稳定运行。通过采用库拉托莫模型和盆地稳定性方法,划定了GFM控制下微电网的参数稳定域,并基于短路比确定了切换边界。此外,考虑到电网故障时光伏储能系统稳定运行的要求,提出了一种具有负序电流抑制策略的故障穿越控制方法,该方法能有效抑制GFM控制下的负序电流。随后,基于仿真的验证证实了所提出控制策略的有效性。该策略确保了光伏储能系统在对称和不对称故障以及孤岛等各种工况下的平稳运行。所提出的控制策略保证了故障期间直流母线的稳定,且电流畸变率不超过5%。
English Abstract
The substantial integration of renewable energy sources, specifically photovoltaic (PV) power into the power grid, has gradually weakened its strength. A novel switching control for a PV storage system with a GFL/GFM control structure was proposed in response to this challenge. By leveraging integrators and the state follower method, a smooth switching control strategy between these two control modes was facilitated, ensuring stable operation across varying grid strengths. Through employing the Kuramoto model and basin stability method, the parameter stability domain of the microgrid under GFM control was delineated, and the switching boundary was established based on the short-circuit ratio. Additionally, recognizing the requirements of stable operation for PV storage systems under grid faults, a fault ride through control method with a negative sequence current suppression strategy was proposed. This method effectively suppressed negative sequence current under GFM control. Subsequently, simulation-based validation confirmed the effectiveness of the proposed control strategies. It ensured the smooth operation of the PV storage system under a gamut of conditions, including symmetric and asymmetric faults, as well as islanding scenarios. The proposed control strategies ensure that the DC bus remains stable and that the current distortion rate does not exceed 5% during faults.
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SunView 深度解读
从阳光电源的业务视角来看,这项双模式切换控制技术对我们的光储一体化系统具有重要战略价值。该技术通过GFL(跟网型)/GFM(构网型)的灵活切换,直接解决了当前高比例新能源接入导致电网强度减弱的核心痛点,这与我们在全球市场推广的1+X模块化逆变器和液冷储能系统的应用场景高度契合。
技术层面上,该方案的三个创新点值得关注:首先,基于积分器和状态跟随器的平滑切换策略可显著提升我们储能变流器在弱电网环境下的适应性,这对拓展中亚、非洲等电网薄弱地区市场具有实际意义;其次,采用Kuramoto模型和盆稳定性方法建立的参数稳定域,为我们的控制算法优化提供了理论依据,可融入现有PowerTitan等储能系统的控制架构;第三,负序电流抑制的故障穿越能力使系统在不对称故障下仍能保持直流母线稳定且电流畸变率低于5%,这直接提升了产品的电能质量指标和并网可靠性。
从应用成熟度评估,该技术已完成仿真验证并涵盖对称/不对称故障及孤岛等复杂工况,具备工程化条件。建议我们在PowerStack储能系统的下一代控制平台中进行实验验证,特别是在澳洲、欧洲等要求严格故障穿越能力的市场。潜在挑战在于GFL/GFM切换判据(短路比阈值)需结合实际电网参数进行本地化调试,以及构网模式下的多机并联稳定性需进一步测试。这项技术若成功产业化,将强化我们在"新能源+储能"微电网解决方案中的技术领先地位,特别是在矿山、海岛等离网/弱网场景的竞争优势。