一种碳化硅与硅器件混合型三电平有源中点钳位零电压转换软开关变流器

doi:10.19595/j.cnki.1000-6753.tces.230172

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摘要该文提出一种碳化硅与硅（SiC&Si）器件混合型三电平有源中点钳位零电压转换（3L-ANPC ZVT）变流器拓扑。该拓扑中每相主电路采用两个SiC MOSFET器件工作在高频,其余主电路开关为Si器件工作在低频,通过辅助电路使得SiC器件工作在ZVT软开关条件下,进一步降低SiC MOSFET高频开关损耗和开关应力。拓扑中辅助电路开关采用Si器件且仅在主器件换相过程工作,具有额定电流小且无开关损耗的特点。该文首先介绍该软开关变流器的电路拓扑结构和工作原理,并给出辅助电路参数的优化设计过程。然后基于双脉冲测试数据对变流器进行损耗建模,分析对比不同开关频率下硬开关和软开关有源中点钳位三电平变流器的损耗分布和效率变化,揭示所提出的软开关变流器拓扑在高开关频率下可以有效改善变流器的效率。最后通过搭建的单相变流器实验平台验证上述分析结论的正确性。

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关键词 ：损耗建模, 逆变器, 软开关, 零电压转换, 多电平变流器

Abstract：Improving power density and efficiency is a current development trend in the new energy generation system. This objective can be achieved by reducing system switching losses and increasing switching frequency. Compared with silicon (Si) devices, silicon carbide (SiC) wide bandgap semiconductor devices have the advantages of low losses and high junction temperature, which can effectively improve the efficiency and switching frequency of converters and have emerged as a prominent topic in recent academic research. However, the cost of SiC devices is still several times higher than that of Si devices. As a result, realizing an all-SiC converter in the three-level active-neutral-point-clamped (3L-ANPC) topology for cost reasons is challenging. Consequently, the industry has proposed a hybrid configuration incorporating SiC and Si devices to enhance converter efficiency and power density and control costs. In addition, the use of SiC-wide bandgap semiconductor devices can lead to severe switching overvoltage and electromagnetic interference issues. Furthermore, at higher switching frequencies, such as 100 kHz, the hard-switching losses with SiC devices can be significant, hindering further improvements in converter efficiency and power density. As a solution to these challenges, researchers have proposed the use of soft-switching technology. A hybrid 3L-ANPC zero-voltage transition (ZVT) soft-switching converter based on SiC and Si devices was proposed. Based on the two SiC MOSFET devices' hybrid 3L-ANPC converter topology, the main circuit SiC devices and the auxiliary circuit Si devices can achieve soft-switching in the full power range with an auxiliary circuit, thus improving converter efficiency while considering its economy.
Firstly, the circuit topology and working mechanism of the proposed 3L-ANPC ZVT soft-switching converter were illustrated. The main circuit's modulation strategy is designed to operate the outer switches and clamping switches in the line frequency. The inner switches operate at high frequency to leverage the benefits of the high-speed switching of SiC MOSFETs and concentrate the switching losses on the inner switches. The auxiliary circuit only works during the switch transition process to assist the inner switches in achieving ZVT and reducing switching losses. Secondly, an optimized design process was formulated for the auxiliary switching timing and auxiliary circuit parameters to facilitate the successful implementation of soft-switching in practical applications. Thirdly, the switching and commutation characteristics of the devices were obtained under hard-switching and soft-switching conditions by double-pulse test. Based on the experimental results. A loss model for the converter was built, and a comparison was conducted between the distribution of losses and the efficiency changes of the soft-switching converter and a traditional hard-switching converter. Finally, an experimental platform of 10 kW/100 kHz was established to verify the proposed 3L-ANPC ZVT soft-switching converter.
The theoretical analysis and experimental results show that the proposed 3L-ANPC ZVT soft-switching converter can improve the efficiency of the converter at a switching frequency above 20 kHz, increasing the efficiency from 96.63% of the hard-switching to 97.42% at the switching frequency of 100 kHz.

Key words： Losses modeling inverter soft-switching zero-voltage transition multilevel converter

收稿日期: 2023-02-16

PACS:

TM46

通讯作者: 李锦男,1982年生,高级工程师,硕士生导师,研究方向为大功率并网变流器拓扑、控制及其应用。E-mail: 12781881@qq.com

作者简介: 党恩帅男,1998年生,硕士研究生,研究方向为高频软开关变流器拓扑。E-mail: des1149@163.com

引用本文:

李锦, 党恩帅, 范雨顺, 董航飞, 刘进军. 一种碳化硅与硅器件混合型三电平有源中点钳位零电压转换软开关变流器[J]. 电工技术学报, 2024, 39(8): 2496-2510. Li Jin, Dang Enshuai, Fan Yushun, Dong Hangfei, Liu Jinjun. A Hybrid Three-Level Active-Neutral-Point-Clamped Zero-Voltage Transition Soft-Switching Converter with Silicon Carbide and Silicon Devices. Transactions of China Electrotechnical Society, 2024, 39(8): 2496-2510.

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[1] Barater D, Concari C, Buticchi G, et al.Performance evaluation of a three-level ANPC photovoltaic grid- connected inverter with 650V SiC devices and optimized PWM[J]. IEEE Transactions on Industry Applications, 2016, 52(3): 2475-2485.
[2] 万文超, 段善旭, 余天宝, 等. 有源中点钳位逆变器的损耗均衡和效率优化策略[J]. 电工技术学报, 2022, 37(19): 4872-4882.
Wan Wenchao, Duan Shanxu, Yu Tianbao, et al.Loss equalization and efficiency optimization strategy of active neutral point clamped inverter[J]. Transactions of China Electrotechnical Society, 2022, 37(19): 4872-4882.
[3] 卫炜, 高瞻, 赵牧天, 等. 基于切换调制波的三电平有源中点钳位逆变器优化容错技术研究[J]. 电工技术学报, 2022, 37(15): 3818-3833.
Wei Wei, Gao Zhan, Zhao Mutian, et al.Research on optimal fault-tolerant technique for three-level active- neutral-point-clamped inverter based on switching modulation wave[J]. Transactions of China Electro- technical Society, 2022, 37(15): 3818-3833.
[4] 李科峰, 肖飞, 刘计龙, 等. 多电平有源中点钳位逆变器串联IGBT均压方法[J]. 电力系统自动化, 2022, 46(2): 163-170.
Li Kefeng, Xiao Fei, Liu Jilong, et al.Voltage balancing method of series-connected IGBTs for multi-level active neutral point clamped inverter[J]. Automation of Electric Power Systems, 2022, 46(2): 163-170.
[5] Morya A K, Gardner M C, Anvari B, et al.Wide bandgap devices in AC electric drives: opportunities and challenges[J]. IEEE Transactions on Trans- portation Electrification, 2019, 5(1): 3-20.
[6] Yin Shan, Tseng K J, Simanjorang R, et al.A 50-kW high-frequency and high-efficiency SiC voltage source inverter for more electric aircraft[J]. IEEE Transactions on Industrial Electronics, 2017, 64(11): 9124-9134.
[7] Novák M, Novák J, Sivkov O.An SiC inverter for high speed permanent magnet synchronous machines[C]// IECON 2015-41st Annual Conference of the IEEE Industrial Electronics Society, Yokohama, Japan, 2015: 002397-002402.
[8] Fu Yu, Takemoto M, Ogasawra S, et al.Investigation of efficiency enhancement of an ultra-high-speed bearingless motor at 100,000 r/min by high switching frequency using SiC-MOSFET[C]//2018 IEEE Energy Conversion Congress and Exposition (ECCE), Port- land, OR, USA, 2018: 2306-2313.
[9] 盛况, 任娜, 徐弘毅. 碳化硅功率器件技术综述与展望[J]. 中国电机工程学报, 2020, 40(6): 1741-1753.
Sheng Kuang, Ren Na, Xu Hongyi.A recent review on silicon carbide power devices technologies[J]. Proceedings of the CSEE, 2020, 40(6): 1741-1753.
[10] 朱小全, 刘康, 叶开文, 等. 基于SiC器件的隔离双向混合型LLC谐振变换器[J].电工技术学报, 2022, 37(16): 4143-4154.
Zhu Xiaoquan, Liu Kang, Ye Kaiwen, et al.Isolated bidirectional hybrid LLC converter based on SiC MOSFET[J]. Transactions of China Electrotechnical Society, 2022, 37(16): 4143-4154.
[11] Liu Yong, See K Y, Yin Shan, et al.LCL filter design of a 50-kW 60-kHz SiC inverter with size and thermal considerations for aerospace applications[J]. IEEE Transactions on Industrial Electronics, 2017, 64(10): 8321-8333.
[12] He Ning, Chen Min, Wu Junxiong, et al.20-kW zero- voltage-switching SiC-MOSFET grid inverter with 300kHz switching frequency[J]. IEEE Transactions on Power Electronics, 2019, 34(6): 5175-5190.
[13] Guan Xinqing, Li Chushan, Zhang Yu, et al.An extremely high efficient three-level active neutral- point-clamped converter comprising SiC and Si hybrid power stages[J]. IEEE Transactions on Power Electronics, 2018, 33(10): 8341-8352.
[14] Zhang Li, Lou Xiutao, Li Chushan, et al.Evaluation of different Si/SiC hybrid three-level active NPC inverters for high power density[J]. IEEE Transa- ctions on Power Electronics, 2020, 35(8): 8224-8236.
[15] Feng Zhijian, Zhang Xing, Yu Shaolin, et al.Com- parative study of 2SiC&4Si hybrid configuration schemes in ANPC inverter[J]. IEEE Access, 2020, 8:33934-33943.
[16] Chen Mengxing, Pan Donghua, Wang Huai, et al.Investigation of switching oscillations for silicon carbide MOSFETs in three-level active neutral- point-clamped inverters[J]. IEEE Transactions on Power Electronics, 2021, 9(4): 4839-4853.
[17] 刘妍, 杨晓峰, 闫成章, 等. 考虑寄生电感的谐振开关电容变换器电压尖峰抑制[J]. 电工技术学报, 2021, 36(12): 2627-2639.
Liu Yan, Yang Xiaofeng, Yan Chengzhang, et al.Suppression of voltage spike in resonant switched capacitor converter considering parasitic indu- ctance[J]. Transactions of China Electrotechnical Society, 2021, 36(12): 2627-2639.
[18] 黄勇胜, 张建忠, 王宁. 一种SiC MOSFET串扰抑制的谐振辅助驱动电路[J]. 电工技术学报, 2022, 37(12): 3004-3015.
Huang Yongsheng, Zhang Jianzong, Wang Ning.A resonant auxiliary drive circuit for SiC MOSFET to suppress crosstalk[J]. Transactions of China Electro- technical Society, 2022, 37(12): 3004-3015.
[19] Zhao Xingchen, Hu Jiewen, Ravi L, et al.Planar common-mode EMI filter design and optimization for high-altitude 100-kW SiC inverter/rectifier system[J]. IEEE Journal of Emerging and Selected Topics in Power Electronics, 2022, 10(5): 5290-5303.
[20] Safari S, Castellazzi A, Wheeler P.Experimental and analytical performance evaluation of SiC power devices in the matrix converter[J]. IEEE Transactions on Power Electronics, 2014, 29(5): 2584-2596.
[21] Chen Yenan, Xu Dehong.Review of soft-switching topologies for single-phase photovoltaic inverters[J]. IEEE Transactions on Power Electronics, 2022, 37(2): 1926-1944.
[22] He Ning, Zhu Yingfeng, Zhao An, et al.Zero- voltage-switching sinusoidal pulsewidth modulation method for three-phase four-wire inverter[J]. IEEE Transactions on Power Electronics, 2019, 34(8): 7192-7205.
[23] Xia Yinglai, Ayyanar R.Naturally adaptive, low-loss zero-voltage-transition circuit for high-frequency full-bridge inverters with hybrid PWM[J]. IEEE Transactions on Power Electronics, 2018, 33(6): 4916-4933.
[24] 寇宝泉, 张海林, 张赫, 等. 改进型零电压转换PWM软开关功率变换器的实现机理分析[J]. 电工技术学报, 2017, 32(14): 116-126.
Kou Baoquan, Zhang Hailin, Zhang He, et al.The analysis of a novel zero-voltage-transition PWM soft-switching power converter[J]. Transactions of China Electrotechnical Society, 2017, 32(14): 116-126.
[25] 姚修远, 吴学智, 杜宇鹏, 等. T型中点钳位三电平逆变器的零电流转换软开关技术[J]. 电工技术学报, 2016, 31(23): 179-188.
Yao Xiuyuan, Wu Xuezhi, Du Yupeng, et al.The zero-current-transition soft-switching technique for T-type neutral-point-clamped inverter[J]. Transa- ctions of China Electrotechnical Society, 2016, 31(23): 179-188.
[26] 何宁, 李雅文, 杜成瑞, 等. 高功率密度碳化硅MOSFET软开关三相逆变器损耗分析[J]. 电源学报, 2017, 15(6): 1-9.
He Ning, Li Yawen, Du Chengrui, et al.Loss analysis of high power density SiC-MOSFET zero-voltage- switching three-phase inverter[J]. Journal of Power Supply, 2017, 15(6): 1-9.
[27] Li Jin, Liu Jinjun, Boroyevich D, et al.Three-level active neutral-point-clamped zero-current-transition converter for sustainable energy systems[J]. IEEE Transactions on Power Electronics, 2011, 26(12): 3680-3693.
[28] Jiang Yunlei, Shen Yanfeng, Shillaber L, et al.Hybrid-mode adaptive zero-voltage switching for single-phase DC-AC conversion with paralleled SiC MOSFETs[J]. IEEE Transactions on Power Elec- tronics, 2022, 37(12): 14067-14081.
[29] Wang Jianing, Xun Yuanwu, Liu Xiaohui, et al.Soft switching circuit of high-frequency active neutral point clamped inverter based on SiC/Si hybrid device[J]. Journal of Power Electronics, 2021, 21: 71-84.
[30] Yuan Xiaoming, Barbi I.Analysis, designing, and
experimentation of a transformer-assisted PWM zero- voltage switching pole inverter[J]. IEEE Transactions on Power Electronics, 2000, 15(1): 72-82.