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杜文娟

日期:2019年09月18日     本文发布:www.3499.com

 


 

杜文娟  特聘研究员/硕士生导师

专业:  电力系统及其自动化

方向:  新能源电力系统和交直流电网混成电力系统稳定性分析与控制、人工智能

Email: ddwenjuan@qq.com

地址:  成都市一环路南一段24号www.3499.com基教A215

邮编:  610065

迄今(2019年9月)已出版英文专著 2 部,中文专著3部;申请美国发明专利 1 项,授权或申请中国专利9项;已发表 SCI期刊论文66篇(其中IEEE汇刊论文35篇)。

完成的科研项目包括:英国国家重大研究项目子课题3项和基金会研究课题4项(主研,参与项目研究经费总计1209万英镑);973项目子课题和重大研发计划项目子课题项目各1项(均为子课题本单位项目负责人,负责研究经费总计270万元),青年基金项目1项(负责);企业横向课题5项(负责),横向课题研究经费总计345万元。

自2014年起,担任本领域权威期刊IET Renewable Power Generation的Associate Editor。曾担任第2届国际可持续电力供电会议(SUPERGEN)组织委员会主席(2010年),第一届中英电力系统博士研究生论坛主席(2010年)。


学习简历

1998年9月至2002年7月  河海大学 获工学学士学位

2003年9月至2006年4月  河海大学 获工学硕士学位

2006年10月至2009年11月 University of Bath, U.K Electronic & Electrical Engineering 获工学博士学位 (导师: DR. ROD DUNN)

 

工作经历

2002年至2003年 贵阳电力设计院                       实习工程师

2003年至2006年 河海大学                           讲师

2006年至2009年 University of Bath, Bath, U.K             Research Officer

2009年至2012年 The Queen's University of Belfast, Belfast, U.K. Research Fellow

2012年至2013年 Brunel University                     Research Fellow

2013年至2018年 华北电力大学                         副教授、教授

2019年至今    www.3499.com                           特聘研究员


专著

1.H F Wang , W Du, Analysis and damping control of power system low-frequency oscillations,Springer US, 2016, ISBN 978-1-4899-7696-3

2.W Du, H F Wang and S Q Bu, Small-signal stability analysis of power system integrated with variable speed wind generators,Springer US, 2018, ISBN 978-3-319-94168-4

3.杜文娟,王海风,电力系统低频振荡阻尼转矩分析理论与方法,科学出版社, 2015.3,ISBN9787030437464

4.杜文娟,王海风,电力系统低频振荡模式分析理论与方法,科学出版社,2017.1,ISBN9787030506092

5.杜文娟,王海风,电力系统宽频振荡开环模式谐振原理与分析方法,科学出版社,2018.10,ISBN 978-7-03-058112-9

   

近3年代表性论文

【1】W Du, Qiang Fu and H F Wang,Power System Small-signal Angular Stability Affected by Virtual Synchronous Generators IEEE Transaction on Power Systems, early excess, 2019

【2】W Du, Bixing Ren, H F Wang and Yang Wang, Comparison of Methods to Examine Sub-synchronous Oscillations Caused by Grid-connected Wind Turbine Generators IEEE Transaction on Power Systems, early excess, 2019

【3】W Du, Guoyun Su, H F Wang and Yining Ji, Dynamic Instability of a Power System Caused by Aggregation of Induction Motor Loads IEEE Transaction on Power Systems, early excess, 2019

【4】W Du, Wenkai Dong and H F Wang, A Method of Reduced-order Modal Computation for Planning Grid Connection of a Large-scale Wind Farm IEEE Transaction on Sustainable Energy, early excess, 2019

【5】W Du, Qiang Fu and H F Wang, Damping Torque Analysis of DC Voltage Stability of a MTDC Network for the Wind Power DeliveryIEEE Transaction on Power Delivery, early excess, 2019

【6】Wenjuan Du, Zijing Zhen and Haifeng Wang, The Subsynchronous Oscillations Caused by an LCC HVDC Line in a Power System under the Condition of Near Strong Modal Resonance, IEEE Transactions on Power Delivery, 2019.2, 34(1):231-240

【7】J Cao, W Du and H F Wang, Optimal sizing and control strategies for hybrid storage system as limited by grid frequency deviations, IEEE Transaction on Power Systems, 2018.9, 33(5): 5486 - 5495

【8】W Du, Jingtian Bi and H F Wang, Damping degradation of power system low-frequency electromechanical oscillations caused by open-loop modal resonance, IEEE Transaction on Power Systems, 2018.9, 33(5):5072 – 5081

【9】W Du, Qiang Fu and H F Wang, Open-loop modal coupling analysis for a multi-input multi-output interconnected MTDC/AC power system, IEEE Transaction on Power Systems, 2019.1, 34(1):246-256

【10】W Du, Qiang Fu and H F Wang, Concept of Modal Repulsion for Examining the Subsynchronous    Oscillations Caused by Wind Farms in Power Systems, IEEE Transaction on Power Systems, 2019.1, 34(1):518 – 526

【11】W Du, Yang Wang and H F Wang, Concept of modal repulsion in examining the sub-synchronous oscillations in power system, IEEE Transaction on Power Systems, 2018.7, 33(4):4614-4624

【12】W DuJ BiJ Cao and H F Wang, A Method to Examine the Impact of Grid Connection of the DFIGs on Power System Electromechanical Oscillation Modes, IEEE Transactions on Power Systems, 2016.9, 31(5):3775-3785    

【13】W Du, H F Wang, J Cao and L Y Xiao, Application of the phase compensation method for the design a DC/AC converter based stabilizer to damp inter-area oscillations, IEEE Transactions on Power Systems, 2012.8, 27(3):1302-1310

【14】W Du, Xiao Chen and H F Wang, A method of open-loop modal analysis to examine the SSOs in a multi-machine power system with multiple variable speed wind generators, IEEE Transaction on Power Systems, 2018.7, 33(4):4614-4624, 4297-4307

【15】W Du, Chen Chen and H F Wang, Subsynchronous interactions induced by the DFIGs in power systems without series compensated lines, IEEE Transaction on Sustainable Energy, 2018.7, 9(3): 1275-1284

【16】W Du, Qiang Fu and H F WangSub-synchronous oscillations caused by open-loop modal coupling between VSC-based HVDC line and power system, IEEE Transaction on Power Systems, 2018.7, 33(4):3664-3677

【17】W Du, Qiang Fu and H F WangSmall-signal stability of an AC/MTDC power system as affected by open-loop modal coupling between the VSCs, IEEE Transaction on Power Systems, 2018.5,33(3):3143-3152  

【18】W Du, Qiang Fu and H F Wang,Comparing AC dynamic transients propagated through VSC HVDC connection with master-slave control versus DC voltage droop control, IEEE Transaction on Sustainable Energy, 2018.7, 9(3):1949-3029

【19】W Du, Qiang Fu and H F Wang, Method of open-loop modal analysis for examining the subsynchronous interactions introduced by VSC control in an MTDC/AC power system, IEEE Transaction on Power Delivery, 2018.4, 33(2):840-850

【20】W Du, X Chen and H F Wang, Power system electromechanical oscillation modes as affected by dynamic interactions from grid-connected PMSGs for wind power generation, IEEE Transaction on Sustainable Energy, 2017.6, 8(3):1301–1312  

【21】W Du, X Chen and H F Wang, Strong dynamic interactions of grid-connected DFIGs with power systems caused by modal coupling, IEEE Transaction on Power Systems, 2017.11, 32(6):4386-4397

【22】W Du, Xiao Chen and H F Wang, Impact of dynamic interactions introduced by DFIGs on power system electromechanical oscillation modes, IEEE Transaction on Power Systems, 2017.11, 32(6):4954-4967

【23】W Du, X Chen and H F Wang, PLL-Induced Modal Resonance of Grid-Connected PMSGs With the Power System Electromechanical Oscillation ModesIEEE Transactions on Sustainable Energy,2017.10, 8(4):1581 – 1591

【24】S Q Bu W Du H F Wang Y Liu and X Liu, Investigation on Economic and Reliable Operation of Meshed MTDC/AC Grid as Impacted by Offshore Wind Farms, IEEE Transactions on Power Systems, 2017.9, 32(5):3901-3911    

【25】Y Liu, W Du, L Xiao, H F Wang, S Q Bu and J Cao, Sizing a Hybrid Energy Storage System for Maintaining Power Balance of an Isolated System With High Penetration of Wind Generation, IEEE Transactions on Power Systems, 2016.7, 31(4):3267-3275 

【26】J Cao, W Du and H F Wang, Weather-Based Optimal Power Flow With Wind Farms Integration, IEEE Transactions on Power Systems, 2016.7, 31(4):3073-3081        

【27】J Cao, W Du and H F Wang, An Improved Corrective Security Constrained OPF for Meshed AC/DC GridsWith Multi-Terminal VSC-HVDC, IEEE Transactions on Power Systems, 2016.1, 33(1):485 - 495

【28】J Cao, W Du, and H F Wang, An Improved Corrective Security Constrained OPF With Distributed Energy Storage, IEEE Transactions on Power Systems, 2016.3, 31(4):1537-1545

【29】Y Liu, W Du,L Xiao and H F Wang,A Method for Sizing Energy Storage System to Increase Wind Penetration as Limited by Grid Frequency Deviations, IEEE Transactions on Power Systems, 2016.1, 31(1):729-737

  

近期中文论文

 

[1]杨斌,杜文娟,王海风.数据驱动下的虚拟同步发电机等效建模[J/OL].电网技术:1-9[2019-09-18].

 

[2]苏国贇,杜文娟,王海风.感应电动机群负荷引起的电力系统机电功率振荡研究[J/OL].中国电机工程学报:1-11[2019-09-18]

 

[3]甄自竞,杜文娟,王海风.强模式耦合现象中复转矩系数法和开环模式判稳方法的等价性证明[J].中国电机工程学报,2019,39(08):2272-2279+10.

 

[4]黄睿,杜文娟,王海风.计及湍流强度的风电功率短期预测[J].电网技术,2019,43(06):1907-1914.

 

[5]付强,杜文娟,王海风.小增益闭环系统稳定性分析方法及其在含并网VSC电力系统中的应用[J].中国电机工程学报,2019,39(06):1551-1559+1852.

 

[6] 付强,杜文娟,王海风.多端柔性直流输电系统中电流型潮流控制器引发的模式谐振现象及其对稳定性的影响[J/OL].中国电机工程学报:1-9[2019-09-18].

 

[7]王洋,杜文娟,王海风.多风电场-多机电力系统次同步振荡稳定性分析[J/OL].中国电机工程学报:1-11[2019-09-18].

 

[8]苏田宇,杜文娟,王海风.直驱风电场场网/场内振荡现象及抑制方法[J].电网技术,2019,43(02):417-428.

 

[9]陈晨,杜文娟,王灵安,王海风.双馈风电场内部多模式谐振引发电力系统次同步振荡的机理研究[J].中国电机工程学报,2019,39(03):642-651+944.

 

[10]苏田宇,杜文娟,王海风.并网双馈风电场次/超同步混合振荡现象及阻尼控制方案[J].中国电机工程学报,2018,38(20):5919-5928.

 

[11]付强,杜文娟,王海风.多虚拟同步发电机接入对电力系统机电振荡模式的影响[J].中国电机工程学报,2018,38(19):5615-5624+5919.

 

[12]陈晨,杜文娟,王海风.近似强开环模式谐振条件下风电场接入引发电力系统次同步振荡分析方法[J].电网技术,2018,42(09):2778-2788.

 

[13]王旭斌,杜文娟,王海风.一种直驱风电场中换流器控制系统间动态交互引起系统的失稳机理分析[J].电网技术,2018,42(08):2423-2432.

 

[14]付强,杜文娟,王海风.交直流混联电力系统小干扰稳定性分析综述[J].中国电机工程学报,2018,38(10):2829-2840+3134.

 

[15]王旭斌,杜文娟,王海风.考虑锁相环动态的直驱风电机组虚拟惯性控制对电力系统小干扰稳定性影响[J].中国电机工程学报,2018,38(08):2239-2252+2534.

 

[16]付强,杜文娟,王海风.柔性直流输电控制与交流系统次同步交互机理研究[J].中国电机工程学报,2018,38(13):3717-3726+4013.

 

[17]王旭斌,杜文娟,王海风.直驱风电并网系统中锁相环引起次同步振荡的开环模式谐振机理分析[J].中国电机工程学报,2018,38(07):1935-1950+2209.

 

[18]陈晨,杜文娟,王海风.DFIG风电场并网引发多机电力系统次同步振荡开环模式分析方法[J].中国电机工程学报,2018,38(14):4064-4073+4312.

 

[19]付强,杜文娟,王海风,郑凯元.多端柔性直流输电中换流站的同步切换控制策略[J].电网技术,2018,42(04):1241-1251.

 

[20]王旭斌,杜文娟,王海风.弱连接条件下并网VSC系统稳定性分析研究综述[J].中国电机工程学报,2018,38(06):1593-1604+1895.

 

[21]付强,杜文娟,王海风.多端柔性直流接入对交流系统功角稳定性的影响[J].电网技术,2018,42(01):34-40.

 


 

 

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