全控电流源换流器稳态功率特性分析与主参数设计

doi:10.19595/j.cnki.1000-6753.tces.250979

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摘要全控电流源换流器（CCSC）的稳态功率特性分析与主参数设计是实现有功和无功解耦控制的关键,其解耦范围与运行边界能够通过稳态运行区间（SSOR）表征。现有研究约束条件覆盖不全,导致SSOR存在偏差,且主参数设计并未结合SSOR要求。该文在系统分析CCSC稳态功率特性的基础上,提出考虑SSOR要求的主参数优化设计方法。首先,建立标幺化稳态数学模型,通过等电气量轨迹特性分析和电气量稳态运行限制梳理,实现对SSOR精确刻画。其次,解析稳态运行点与谐波特性的耦合关系,得到综合SSOR与谐波电流限制的主参数通用设计要求。然后,针对采用改进相控调制的CCSC-HVDC,以最大电容电压和滤波器单位功率储能峰值最小为目标优化主参数设计,并分析单位功率因数运行区间要求对设计结果的影响。最后,通过PSCAD仿真验证SSOR分析的准确性和主参数设计的有效性。

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	宋兆祺
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	张闻闻

关键词 ：全控电流源换流器, 稳态功率特性, 稳态运行区间, 主参数设计

Abstract：The steady-state power characteristic analysis and main parameter design for controlled current source converter (CCSC) are essential for achieving decoupled active and reactive power control. However, existing studies often overlook certain constraints, leading to inaccurate SSOR estimation and parameter designs that fail to incorporate SSOR requirements. Based on a systematic analysis of CCSC steady-state power characteristics, this paper proposes an optimized design method for CCSC main parameters by integrating SSOR requirements with harmonic current limits.
First, a per-unit steady-state model is established. Then the SSOR is derived by mapping one-dimensional operational limits—including DC voltage (U_d), DC current (I_d), modulation index (M), and capacitor voltage (U_v)—to a two-dimensional feasible region on the P-Q plane through intersection operations of these constraints. The SSOR boundaries are shaped by combinations of these constraints: the U_d-M joint constraint, the I_d-M joint constraint, the P constraint and U_v constraint. The influence of parameters such as grid voltage (U), transformer ratio (K), susceptance (B_v), and resonant frequency (ω_r) on the reactive power boundaries is systematically analyzed, revealing monotonic trends and critical transition points.
Second, a universal design framework is proposed by combining SSOR requirements with harmonic limits. For a specified SSOR Ω_d, the expressions for ranges of M and maximum capacitor voltage U_vH is derived. Then the nth harmonic current distortion in percent of normal demand load current at the point of common coupling is defined as k_n. The relationship among k_n, main parameters and operating points (P, Q) is established, ensuring k_n remains below the permissible limit k_n_H across Ω_d, in compliance with IEEE 519.
Third, the method is applied to the improved phase control (IPC) based CCSC for HVDC systems. The IPC modulation enables decoupled power control at a low switching frequency (150 Hz) with 0.8<M<1.1. For SSOR requirement, unity power factor (UPF) operation is adopted to prevent wide-range variation of harmonics. Harmonic limits are set to k_5H=20% and k_11H=0.7%. main parameters (K, B_v, and ω_r)—are optimized with dual objectives: minimizing the maximum capacitor voltage and the L-C filter's peak energy storage per unit power. Parametric sweeping within feasible ranges are performed under SSOR and harmonic constraints. Results indicated that the lower UPF boundary (P_uLd) expands the operating range but increases capacitor voltage and filter size. A practical trade-off is identified when P_uLd lies between 0.80(pu)~1.00(pu). For P_uLd =0.80(pu), optimal parameters are K = 1.40, B_v = 0.19(pu) and ω_r = 3.80(pu).
Finally, PSCAD simulations validate the SSOR boundaries and parameter design. Electrical variables in simulations match theoretical predictions with errors below 0.5%. Harmonic distortions k₅ and k₁₁ align with expectations, and the grid currents' total demand distortion remains below 1.12%, meeting IEEE 519. Compared to existing designs, the proposed method yields a lower maximum capacitor voltage (183.77 kV vs. 201.39 kV) and comparable filter energy storage (1.80 kJ/(MV·A) vs. 1.79 kJ/(MV·A)), improving cost-effectiveness and harmonic performance across the UPF range.
In conclusion, the integrated SSOR analysis and multi-objective optimization approach enables CCSCs to achieve reliable power decoupling and harmonic compliance in HVDC systems. The methodology is adaptable to other modulation strategies and voltage levels, offering a systematic design framework for high-performance CCSCs.

Key words： Controlled current source converter (CCSC) steady-state power characteristics steady-state operating region (SSOR) main parameter design

收稿日期: 2025-06-06

PACS:

TM721.1

基金资助:国家自然科学基金面上项目资助（52077174）

通讯作者: 魏晓光男,1976年生,博士,教授级高级工程师,研究方向为直流输电技术与直流电网设备。E-mail：weixiaoguang@neps.hrl.ac.cn

作者简介: 宋兆祺男,1998年生,博士研究生,研究方向为基于全控电流源换流器的高压直流输电系统。E-mail：zq_song@foxmail.com

引用本文:

宋兆祺, 魏晓光, 刘进军, 安荣汇, 陈龙龙, 单云海, 张闻闻. 全控电流源换流器稳态功率特性分析与主参数设计[J]. 电工技术学报, 2026, 41(11): 3799-3816. Song Zhaoqi, Wei Xiaoguang, Liu Jinjun, An Ronghui, Chen Longlong, Shan Yunhai, Zhang Wenwen. Analysis of Steady-State Power Characteristics and Design of Main Parameters for Controlled Current Source Converters. Transactions of China Electrotechnical Society, 2026, 41(11): 3799-3816.

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