具备故障电流限制能力的多端口直流断路器

doi:10.19595/j.cnki.1000-6753.tces.220381

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摘要混合式直流断路器是实现柔性直流电网故障电流快速阻断的重要装备。然而,目前每条直流线路两端均需配备一台价格昂贵的二端口混合式直流断路器,这严重限制了其在未来新型电力系统中的规模化应用。该文提出一种具备故障电流限制能力的多端口直流断路器,在实现故障双向阻断的基础上,与常规方案相比故障电流峰值下降了38.0 %、避雷器能量耗散应力下降了61.21 %。更为重要的是,所提断路器完成直流母线故障隔离后,与故障母线相连的健全直流线路仍可以进行正常功率传输,最大程度地保障了柔性直流电网的健全和持续可靠运行。首先,分析了直流断路器在故障工况下的故障电流阻断原理,并对各个动作过程进行了理论推导;然后,揭示了电容和电感参数对断路器限流性能的影响机理,确定了限流单元的元件选型方法;最后,基于PSCAD/EMTDC对所提具备故障电流限制能力的多端口直流断路器进行了仿真分析,结果表明,所提多端口直流断路器具有较强的有效性和适应性。

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关键词 ：柔性直流电网, 多端口混合式直流断路器, 限流单元, 预充电

Abstract：The hybrid DC circuit breaker (DCCB) is the critical equipment to realize the fast interruption of fault currents for VSC-based DC grids. However, with the continuous expansion of VSC-based DC grids, based on the local protection strategy, each DC line must be equipped with an expensive two-port hybrid DCCB at both ends. It causes enormous project investment costs and seriously restricts the large-scale application of hybrid DCCB in future complex DC grid projects. Therefore, this paper proposes a multi-port DCCB with fault current limiting capability (FCL-MHDCB) to improve the fault current limiting effect by optimizing the overall operation sequence. At the same time, after the DC bus fault isolation is completed, based on the proposed FCL-MHDCB scheme, the healthy DC lines connected to the fault bus can still carry out normal power transmission, which greatly improves the power supply reliability of the system.
Firstly, the FCL-MHDCB topology is proposed, which consists of the main branch, transfer branch, energy dissipation branch, current limiting unit, and auxiliary unit. Secondly, the fault current blocking principle of the proposed FCL-MHDCB under DC line fault conditions is analyzed. The working process can be divided into three stages: the steady-state operation stage, the fault current limiting stage, and the fault current interruption stage. Thirdly, taking the n-terminal VSC-based DC grids as an example, the action process of the proposed FCL-MHDCB is theoretically deduced. The proposed scheme is verified by the derived formula. Finally, considering the thyristor withstand voltage, fault current peak, full input time of current limiting inductor, and current limiting effect, the value range of pre-charged capacitor C and current limiting inductor L_FCL in the current limiting unit is designed. Considering comprehensively, the range of capacitor C can be determined to be 10~15 μF, and the range of inductor L_FCL can be determined to be 0.1~0.15 H.
In general, to highlight the advantages of the proposed FCL-MHDCB, a metal grounding fault occurs at the bus of the positive outlet of the converter station at t =3 s. The simulation results of the port current show that the proposed FCL-MHDCB can still maintain the power transmission of the sound line after DC bus fault isolation, which ensures the continuous and reliable operation of VSC-based DC grids to the greatest extent. In addition, the simulation results of each branch current of the proposed FCL-MHDCB show that it can effectively complete the fault current suppression and fast blocking. At about 3.011 s, the fault current drops to 0 under the transient breaking voltage of metal oxide varistors, and FCL-MHDCB completes the fault current interruption. Compared with the multi-port DCCB without the current limiting unit, the peak fault current is as high as 9.09 kA at 3.006 s, while the peak fault current of the proposed FCL-MHDCB is only 5.64 kA, reducing by 38.0 %. Moreover, the energy dissipation stress of the arrester is reduced by 61.21 % compared with the conventional scheme.
The following conclusions can be drawn from the simulation analysis: (1) Compared with the existing technical scheme, the proposed FCL-MHDCB can still transmit power between healthy lines after completing the DC bus fault isolation, ensuring the continuous and reliable operation of VSC-based DC grids to the greatest extent. (2) When the circuit breaker recloses in the permanent fault, the permanent fault isolation can be quickly realized only by coordinating the thyristors in the ordered conduction current limiting unit with the pre-charged capacitors. Immediately charging the capacitors of the current limiting unit is not needed. (3) The whole action sequence of DCCB is optimized, and the limiting effect of fault current is improved. The peak value of fault current decreases by 38.0 %, and the energy dissipation stress of the arrester decreases by 61.21 %.

Key words： VSC-based DC grid multi-port hybrid DC circuit breaker current limiting unit pre-charge

收稿日期: 2022-03-16

PACS:

TM561

基金资助:湖南省自然科学基金项目（2021JJ40594）和研究生实践创新项目（SJCX202159）资助

通讯作者: 裴翔羽男,1986年生,博士,硕士生导师,研究方向为柔性直流电网控制与保护技术。E-mail: 646888200@qq.com

作者简介: 李浩男,1998年生,硕士研究生,研究方向为柔性直流输电控制与保护技术。E-mail: 244294282@qq.com

引用本文:

李浩, 裴翔羽, 李泽文, 周万迪, 李弸智. 具备故障电流限制能力的多端口直流断路器[J]. 电工技术学报, 2023, 38(10): 2818-2831. Li Hao, Pei Xiangyu, Li Zewen, Zhou Wandi, Li Pengzhi. A Multi-Port DC Circuit Breaker with Fault-Current Limiting Capability. Transactions of China Electrotechnical Society, 2023, 38(10): 2818-2831.

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