[1]陈燕平,蒋云富,忻兰苑.风电变流器功率组件技术及发展趋势[J].控制与信息技术(原大功率变流技术),2017,(06):1-9.[doi:10.13889/j.issn.2095-3631.2017.06.001]
 CHEN Yanping,JIANG Yunfu,XIN Lanyuan.Development of Power Assembly Technology for Wind Power Converters[J].High Power Converter Technology,2017,(06):1-9.[doi:10.13889/j.issn.2095-3631.2017.06.001]
点击复制

风电变流器功率组件技术及发展趋势()
分享到:

《控制与信息技术》(原《大功率变流技术》)[ISSN:2095-3631/CN:43-1486/U]

卷:
期数:
2017年06期
页码:
1-9
栏目:
综述·评论
出版日期:
2017-12-05

文章信息/Info

Title:
Development of Power Assembly Technology for Wind Power Converters
文章编号:
2095-3631(2017)06-0001-09
作者:
陈燕平蒋云富忻兰苑
(1. 新型功率半导体器件国家重点实验室,湖南株洲 412001;2. 株洲中车时代电气股份有限公司,湖南株洲 412001)
Author(s):
CHEN YanpingJIANG Yunfu XIN Lanyuan
(1.State Κey Laboratory of Advanced Power Semiconductor Devices, Zhuzhou, Hunan 412001, China; 2.Zhuzhou CRRC Times Electric Co., Ltd., Zhuzhou, Hunan 412001, China)
关键词:
风电变流器功率组件IGBT驱计技术散热技术自诊断
Keywords:
wind power converter power assembly IGBT driven technology heatdissipation technology self-diagnose
分类号:
TM614;TN6
DOI:
10.13889/j.issn.2095-3631.2017.06.001
文献标志码:
A
摘要:
功率组件是风电变流器的核心构成部件,其性能及可靠性直接影响变流器的整体性能及可靠性。文章对风电变流器中IGBT 功率组件的电路拓扑结构、关键器件选型、驱动技术、散热技术等关键技术及其未来的发展趋势进行研究与阐述,为风电变流器中功率组件的设计、选型与技术研究提供参考依据。
Abstract:
Power assembly is the key component of wind power converter, whose performance and reliability affect the performance and reliability of converter. For IGBT power assembly in wind power converter, it introduced its key technoligies such as circuit topology & composition structure, key device selection, gate-driver technology, heat dissipation technology and its development trend, which could provide references for the design, selection and technical research of power assembly in wind power converter.

参考文献/References:

[1]肖宏伟. 2016 年电力形势分析与2017 年展望[J]. 中国物价, 2017(1):31-34.
[2]魏宇晨. 浅析《巴黎协议》对中国新能源发展的推动[J]. 科技经济导刊, 2016(35):79-80.
[3]冯江华. 风电变流器的技术现状与发展[J]. 大功率变流技术, 2013 (3) :5-11.
FENG J H. Technology Status and Development of Wind Power Converters[J]. High Power Converter Technology, 2013(3): 5-11.
[4]RATHORE A K, HOLTZ J, BOLLER T. Synchronous Optimal Pulsewidth Modulation for Low-Switching-Frequency-Control of Medium-voltage Multilevel Inverters[J]. IEEE Transactions on Industrial Electronics, 2010, 57(7):2378-2381.
[5]任康乐 . 中压三电平全功率风电变流器[D]. 安徽:合肥工业大学, 2016.
[6]CHUANGPISHIT S,TABESH A,MORADI-SHARBABK Z, et al.Topology Design for Collector Systems of Offshore Wind Farms With Pure DC Power Systems[J]. IEEE Transactions on Industrial Electronics,2014,61( 1 ):320-328.
[7]黄晟,王辉,廖武,等. 基于VSC-HVDC 串并联拓扑结构风电场协调控制策略研究[J]. 电工技术学报,2015(12):155-162.
HUANG S, WANG H, LIAO W, et al. The Coordinated Control Strategy Based on VSC-HVDC Series-parallel Topology in Wind Farm[J].Transactions of China Electrotechnical Society, 2015 (12):155-162.
[8]高宁,王勇,蔡旭. 三电平中压风电变流器的研究[J]. 电力电子技术,2011,45(11):39-46. GAO N, WANG Y, CAI X. Research on Three-level Medium Voltage Wind Power Converter[J]. Power Electronics, 2011, 45(11):39-46.
[9]ABU-RUB H, HOLTZ J, RODRIGUEZ J, et al. Medium- Voltage Multilevel Converters—State of the Art, Challenges, andRequirements in Industrial Applications[J]. IEEE Transactions on Industrial Electronics, 2010, 57 (8):2581-2596.
[10]ZHAO K,LI G Y,WANG B Z,et al.Grid-connected topology of PMSG wind power system based on VSC-HVDC[C] //International Conference on Electric Utility Deregulation and Restructuring and Power Technologies. Weihai:IEEE, 2011:297- 302.
[11]POLLER T, BASLER T, HERNES M, et al. Mechanical analysis of press-pack IGBTs[J]. Microelectronics Reliability, 2012,52 (9-10):2397-2402.
[12]王兆安,张明勋. 电力电子设备设计和应用手册[M]. 北京:机械工业出版社,2009.
[13]陈燕平,忻力,李中浩. 牵引变流器中支撑电容器研究[J]. 铁道机车车辆,2011(2):76-81.
CHEN Y P, XIN L, LI Z H. Study of the DC-Link Capacitor for Traction Converter[J]. Railway Locomotive & Car, 2011(2): 76-81.
[14]唐海燕,唐洲. 功率变换器中直流支撑电容器的选择和应用[J]. 大功率变流技术,2011(6):27-30.
TANG H Y, TANG Z. Selection and Application of DC Support Capacitor in Power Converter[J]. High Power Converter Technology, 2011(6):27-30.
[15]GRBOVIC P J. An IGBT Gate Driver for Feed-Forward Control of Turn-on Losses and Reverse Recovery Current[J]. IEEE Transactions on Power Electronics, 2008, 23(2):643-652.
[16]唐开毅,尹新,沈征,等. IGBT 驱动设计原理及技术比较[J]. 电源技术,2016(3):693-696.
 TANG K Y, YIN X, SHEN Z, et al. Design Principles and Technical Comparisons of IGBT Gate Driver[J]. Chinese Journal of Power Technology, 2016(3):693-696.
[17]忻兰苑,孙康康,龚喆,等. 功率组件IGBT 并联均流设计[J]. 大功率变流技术,2017(1):18-23.
 XIN L Y, SUN K K, GONG Z, et al. Current Balancing Design of Paralleled-IGBT in Power Assembly[J]. High Power Converter Technology, 2017(1):18-23.
[18]FINK K, DUSTERT C, VOLKE A. An Approach to Balancing the Switching Behavior of Paralleled IGBT-Modules using a Differential-Mode Choke in a Gate-Control Loop[C]//PCIM Asia 2015,International Exhibition and Conference for Power Electronics, Intelligent Motion, Renewable Energy and Energy Management. Shanghai:Proceedings of VDE, 2015.
[19]陈建业,吴文伟. 大功率变流器冷却技术及其进展[J]. 大功率变流技术,2010(1):15-30.
CHEN J Y, WU W W. Cooling Technology for High Power Converter and Its Development[J]. High Power Converter Technology, 2010(1):15-30.
[20]孙微,刘钧,马翀慧,等. IGBT 功率模块新型直接冷却技术研究[J] . 电气传动,2014(1):82-84.
SUN W, LIU J, MA C H, et al. New Direct Cooling Technology Research of IGBT Power Module[J]. Electric Drive, 2014(1): 82-84.
[21]PLUSCHKE N. 基于SKiiP 技术的双馈异步发电机与同步发电机的比较[J] . 电力电子,2007(3):36-37.
[22]陈明翊,马伯乐,陈玉其,等. 低感母排技术在IGBT 变流器中的应用[J]. 大功率变流器技术,2012(6):14-17.
CHEN M Y, MA B L, CHEN Y Q, et al. Application of Low Stray Inductance Bus-bar Technology in IGBT Converter[J]. High Power Converter Technology, 2012(6):14-17.
[23]CAPONET M C,PROFUMO F,DE DONCKER R W,et al. Low stray inductance bus bar design and construction for good EMC performance in power electronic circuits[J]. IEEE Transactions on Power Electronics,2002,17(2):225-231.
[24]蒋云富,黄南,袁勇,等. 集成式IGBT 功率组件的现状及发展趋势[J]. 大功率变流技术,2015(3):1-5.
JIANG Y F,HUANG N,YUAN Y, et al. Status and Development Trends of Integrated IGBT Power Assembly[J]. High Power Converter Technology, 2015(3):1-5.
[25]厥春兰,傅晓锦,杨恩星,等. 基于智能PEBB 的风电变流器模组设计[J]. 太阳能学报, 2016(3):617-621.
QUE C L,FU X J,YANG E X, et al. The Design of Wind Power Converter Based on Intelligent PEBB[J]. Acta Energiae Soloaris Sinica, 2016(3):617-621.
[26]MACKEN K J P, MACNAIR D, NGUYEN M N, et al. IGBT PEBB technology for future high energy physics machine operation applications[C]//Applied Power Electronics Conference and Exposition. USA:IEEE, 2012:1319-1337.
[27]李诚瞻,常桂钦,彭勇殿,等. 一种低感封装的1 200 V 混合碳化硅功率模块[J]. 大功率变流技术,2016(5):71-74.
LI C Z, CHANG G Q, PENG Y D, et al. 1 200 V Hybrid SiC Power Module with Low Stray Inductance[J]. High Power Converter Technology, 2016(5):71-74.

相似文献/References:

[1]蒋云富,黄 南,袁 勇,等.集成式IGBT 功率组件的现状及发展趋势[J].控制与信息技术(原大功率变流技术),2015,(03):1.[doi:10.13889/j.issn.2095-3631.2015.03.001]
 JIANG Yunfu,HUANG Nan,YUAN Yong,et al.Status and Development Trends of Integrated IGBT Power Assembly[J].High Power Converter Technology,2015,(06):1.[doi:10.13889/j.issn.2095-3631.2015.03.001]
[2]黄 南,王世平,宋自珍.兆瓦级功率组件IGBT 失效研究[J].控制与信息技术(原大功率变流技术),2015,(03):35.[doi:10.13889/j.issn.2095-3631.2015.03.008]
 HUANG Nan,WANG Shiping,SONG Zizhen.Study of the IGBT Failure in Megawatt Power Assembly[J].High Power Converter Technology,2015,(06):35.[doi:10.13889/j.issn.2095-3631.2015.03.008]
[3]余 军,马雅青,赵振龙,等.电动汽车用水冷散热器的设计及仿真[J].控制与信息技术(原大功率变流技术),2015,(03):51.[doi:10.13889/j.issn.2095-3631.2015.03.012]
 YU Jun,MA Yaqing,ZHAO Zhenlong,et al.Design and Simulation of Water-cooled Radiator Used in Electric Vehicle[J].High Power Converter Technology,2015,(06):51.[doi:10.13889/j.issn.2095-3631.2015.03.012]
[4]张宇,谭娟,徐立恩.双馈风电变流器半实物仿真平台的开发[J].控制与信息技术(原大功率变流技术),2014,(06):14.[doi:10.13889/j.issn.2095-3631.2014.06.004]
 ZHANG Yu,TAN Juan,XU Lien.Development of Semi-physical Simulation Platform for Doubly-fed Wind Power Converter[J].High Power Converter Technology,2014,(06):14.[doi:10.13889/j.issn.2095-3631.2014.06.004]
[5]熊 辉,袁 勇,黄 南,等. 风电功率组件电热特性分析[J].控制与信息技术(原大功率变流技术),2016,(02):47.[doi:10.13889/j.issn.2095-3631.2016.02.010]
 XIONG Hui,YUAN Yong,HUANG Nan,et al. Analysis of Electrical & Thermal Performances for Power Assembly of Wind Power[J].High Power Converter Technology,2016,(06):47.[doi:10.13889/j.issn.2095-3631.2016.02.010]
[6]冯江华.风电变流器的技术现状与发展[J].控制与信息技术(原大功率变流技术),2013,(03):5.[doi:10.13889/j.issn.2095-3631.2013.03.005]
 FENG Jiang-hua.Technology Status and Development of Wind Power Converters[J].High Power Converter Technology,2013,(06):5.[doi:10.13889/j.issn.2095-3631.2013.03.005]
[7]李保国,陈燕平,蒋云富,等.全功率风电变流器并联运行关键技术研究[J].控制与信息技术(原大功率变流技术),2016,(04):38.[doi:10.13889/j.issn.2095-3631.2016.04.008]
 LI Baoguo,CHEN Yanping,JIANG Yunfu,et al.Research on the Key Technologies of Parallel Operation for Full Power Wind Power Converter[J].High Power Converter Technology,2016,(06):38.[doi:10.13889/j.issn.2095-3631.2016.04.008]
[8]翟 龙,陈燕平,蒋云富,等.兆瓦级风电功率组件的IGBT 吸收电路设计[J].控制与信息技术(原大功率变流技术),2016,(04):42.[doi:10.13889/j.issn.2095-3631.2016.04.009]
 ZHAI Long,CHEN Yanping,et al.Design of the IGBT Snubber Circuit for Megawatt Level Wind Power Module[J].High Power Converter Technology,2016,(06):42.[doi:10.13889/j.issn.2095-3631.2016.04.009]
[9]陈 俊,万超群,陈 彦,等.大功率压接式IGBT及其在脉冲强磁场发生器中的应用[J].控制与信息技术(原大功率变流技术),2017,(03):59.[doi:10.13889/j.issn.2095-3631.2017.03.011]
 CHEN Jun,WAN Chaoqun,CHEN Yan,et al.High Power Press-pack IGBT and Its Application in Pulsed Magnetic-field Generator[J].High Power Converter Technology,2017,(06):59.[doi:10.13889/j.issn.2095-3631.2017.03.011]
[10]李 炘,方 杰,宁旭斌,等.风电变流器用1 700 V/2 400 A IGBT 模块的开发与测试[J].控制与信息技术(原大功率变流技术),2017,(05):74.[doi:10.13889/j.issn.2095-3631.2017.05.013]
 LI Xin,FANG Jie,NING Xubin,et al.Development and Test of the 1 700 V/2 400 A IGBT Module for Wind Power Converter[J].High Power Converter Technology,2017,(06):74.[doi:10.13889/j.issn.2095-3631.2017.05.013]

备注/Memo

备注/Memo:
收稿日期:2017-09-20
作者简介:陈燕平(1975-),女,教授级高级工程师,主要从事变流技术研究。
更新日期/Last Update: 2017-12-18