电网暂态故障下风电机组动态载荷分析
|
摘要
随着风电规模化开发利用,电网暂态故障引起的风电机组疲劳损伤问题也越来越突出。针对风电机组机械和电气部分仿真模型简化的问题,基于联合仿真思想,建立了5 MW风电机组FAST与MATLAB/Simulink的联合仿真模型。研究分析了对称和不对称电压暂态跌落工况对风电机组机械动态载荷的影响机理和特性。仿真结果表明,电网电压暂态故障对风电机组叶尖摆振和塔架及主轴受力带来较大影响,增大了叶片、塔架和主轴等部件的机械疲劳载荷,尤其是在不对称跌落时更为显著,而叶尖挥舞及塔架振动加速度所受影响较小。研究结果也为后续进一步动态载荷抑制提供了理论基础。
With the large-scale development and utilization of wind power,power grid transient fault for the wind turbine fatigue damage problem is more and more prominent. For the problem of simulation model simplification of mechanical and electrical part of wind turbine,a co-simulation model for FAST and Matlab/Simulink of 5 MW wind turbine was established based on the idea of co-simulation. The impact mechanism and characteristics of mechanical dynamic load of wind turbine were researched and analyzed under symmetrical and asymmetrical voltage transient dip. The simulation results show that it is great impact on the blade tip flapwise acceleration and the force of the tower and the shaft of the wind turbine because of voltage transient dip. Mechanical fatigue load of blades,tower and shaft of wind turbine is increased,especially under asymmetrical voltage transient dip it is more pronounced,while blade tip edgewise acceleration and tower vibration acceleration are less affected.The results also provide a theoretical basis for further dynamic load suppression.
With the large-scale development and utilization of wind power,power grid transient fault for the wind turbine fatigue damage problem is more and more prominent. For the problem of simulation model simplification of mechanical and electrical part of wind turbine,a co-simulation model for FAST and Matlab/Simulink of 5 MW wind turbine was established based on the idea of co-simulation. The impact mechanism and characteristics of mechanical dynamic load of wind turbine were researched and analyzed under symmetrical and asymmetrical voltage transient dip. The simulation results show that it is great impact on the blade tip flapwise acceleration and the force of the tower and the shaft of the wind turbine because of voltage transient dip. Mechanical fatigue load of blades,tower and shaft of wind turbine is increased,especially under asymmetrical voltage transient dip it is more pronounced,while blade tip edgewise acceleration and tower vibration acceleration are less affected.The results also provide a theoretical basis for further dynamic load suppression.
引文
[1]TSILI M,PAPATHANASSIOU S.A review of grid code technical requirements for wind farms[J].IET Renewable Power Generation,2009,3(3):308-332.
[2]刘皓明,唐俏俏,苏媛媛,等.大型风电机组主动减振电气控制方法综述[J].电力科学与技术学报,2016,31(3):182-194.
[3]郑小霞,叶聪杰,符杨.海上风电场运行维护的研究与发展[J].电网与清洁能源,2012,28(11):90-94.
[4]HANSEN A D,MICHALKE G.Fault ride-through capability of DFIG wind turbines[J].Renewable Energy,2007,32(9):1594-1610.
[5]骆皓,林明耀,曹阳,等.基于定子电流正弦化的双馈风电系统低电压穿越强励控制[J].电力系统自动化,2014,38(18):20-26.
[6]AGA J M,JADHAV H T.Improving fault ride-through capability of DFIG connected wind turbine system:A review[C]∥Proceedings of the 2013 International Conference on Power,Energy and Control,February 6-8,2013,Dindigul,India:613-618.
[7]孙云鹏,谢冬梅.双馈风力发电机低电压穿越技术综述[J].中国设备工程,2017(8):151-153.
[8]张永斌,舒成杰,吴永德.双馈风力发电机组低电压穿越试验与分析[J].电器与能效管理技术,2014(17):49-54.
[9]HANSEN A D,CUTULULIS N A,MARKOU H,et al.Grid fault and design-basis for wind turbines-Final report[M].Danmarks Tekniske Universitet,RisNationallaboratoriet for Bredygtig Energi,2010.
[10]JONKMAN J M,BUHL M L.FAST user’s guide[M].Golden,CO:National Renewable Energy Laboratory,NREL/EL-500-38230,2005.
[11]许寅,陈颖,陈来军,等.基于平均化理论的PWM变流器电磁暂态快速仿真方法[J].电力系统自动化,2013,37(11):58-64.
[12]孟岩峰,胡书举,王玲玲,等.电网故障条件下双馈机组运行特性分析及其协调控制[J].电力系统保护与控制,2013,41(8):106-113.
[13]张志,王清灵,朱一凡.变速恒频双馈风力发电系统最大风能捕获控制[J].电机与控制应用,2010,37(3):18-21.
[2]刘皓明,唐俏俏,苏媛媛,等.大型风电机组主动减振电气控制方法综述[J].电力科学与技术学报,2016,31(3):182-194.
[3]郑小霞,叶聪杰,符杨.海上风电场运行维护的研究与发展[J].电网与清洁能源,2012,28(11):90-94.
[4]HANSEN A D,MICHALKE G.Fault ride-through capability of DFIG wind turbines[J].Renewable Energy,2007,32(9):1594-1610.
[5]骆皓,林明耀,曹阳,等.基于定子电流正弦化的双馈风电系统低电压穿越强励控制[J].电力系统自动化,2014,38(18):20-26.
[6]AGA J M,JADHAV H T.Improving fault ride-through capability of DFIG connected wind turbine system:A review[C]∥Proceedings of the 2013 International Conference on Power,Energy and Control,February 6-8,2013,Dindigul,India:613-618.
[7]孙云鹏,谢冬梅.双馈风力发电机低电压穿越技术综述[J].中国设备工程,2017(8):151-153.
[8]张永斌,舒成杰,吴永德.双馈风力发电机组低电压穿越试验与分析[J].电器与能效管理技术,2014(17):49-54.
[9]HANSEN A D,CUTULULIS N A,MARKOU H,et al.Grid fault and design-basis for wind turbines-Final report[M].Danmarks Tekniske Universitet,RisNationallaboratoriet for Bredygtig Energi,2010.
[10]JONKMAN J M,BUHL M L.FAST user’s guide[M].Golden,CO:National Renewable Energy Laboratory,NREL/EL-500-38230,2005.
[11]许寅,陈颖,陈来军,等.基于平均化理论的PWM变流器电磁暂态快速仿真方法[J].电力系统自动化,2013,37(11):58-64.
[12]孟岩峰,胡书举,王玲玲,等.电网故障条件下双馈机组运行特性分析及其协调控制[J].电力系统保护与控制,2013,41(8):106-113.
[13]张志,王清灵,朱一凡.变速恒频双馈风力发电系统最大风能捕获控制[J].电机与控制应用,2010,37(3):18-21.
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |