国防科技大学学报

引用本文:	周鹏展,肖加余,曾竟成,等.基于ANSYS的大型复合材料风力机叶片结构分析.[J].国防科技大学学报,2010,32(2):46-50.[点击复制]
	ZHOU Pengzhan,XIAO Jiayu,ZENG Jingcheng,et al.Structural Analysis of Large-scale Composite Wind Turbine Blade Based on ANSYS[J].Journal of National University of Defense Technology,2010,32(2):46-50[点击复制]

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基于ANSYS的大型复合材料风力机叶片结构分析

周鹏展^1,2,3, 肖加余¹, 曾竟成¹, 王进², 杨军²

(1.国防科技大学航天与材料工程学院，湖南长沙 410073;2.株洲时代新材料科技股份有限公司，湖南株洲 412007;3.长沙理工大学能源与动力工程学院，湖南长沙 410076)

摘要:

基于ANSYS软件，对某款应用于GL3A风场的1500kW大型复合材料风力机叶片进行了结构分析。分析结果表明：该叶片的振型以一阶挥舞和一阶摆振为主，其频率分别为0.86Hz和1.59Hz；在极限挥舞载荷作用下，该叶片有限元模型计算得到的叶尖挠度为8.445m，而该叶片全尺寸静力试验得到的极限挥舞载荷作用下的叶尖挠度为8.12m，计算值与试验值的误差只有3.8%；另外，该叶片的最大计算拉应力和压应力分别为228MPa和201MPa，而该叶片玻纤/环氧复合材料实测拉伸强度和实测压缩失稳强度分别为720MPa和380MPa，其计算最大应力只有对应实测极限强度的31.7%和52.9%。

关键词: 复合材料风力机叶片结构分析极限挥舞载荷

DOI：

投稿日期：2009-09-22

基金项目:国家863计划资助项目(2007AA03Z563)；中国博士后科学基金资助项目(20070420832)；湖南省科技资助项目(2008RS4033)

Structural Analysis of Large-scale Composite Wind Turbine Blade Based on ANSYS

ZHOU Pengzhan^1,2,3, XIAO Jiayu¹, ZENG Jingcheng¹, WANG Jin², YANG Jun²

(1.College of Aerospace and Materials Engineering, National Univ. of Defense Technology, Changsha 410073, China;2.Zhuzhou Times New Material Technology Co. Ltd., Zhuzhou 412007, China;3. 3.College of Energy and Power Engineering，Changsha Univ. of Science & Technology, Changsha 410076, China)

Abstract:

Based on the ANSYS software, the structural analysis of a kind of 1500kW large-scale composite wind turbine blade which applied in GL3A wind farm was carried out. The analysis results show that the vibration modes of this blade are mainly presented as first flapwise mode and first edgewise mode, the frequencies of the vibration are respectively 0.86Hz and 1.59Hz. At the action of ultimate flapwise loads, the FEM analysis results show that the blade tip deformation is 8.445m, while the blade tip deformation of the full scale blade under static test is 8.12m, so the deviation between the calculated and tested value of the blade tip deformation is only 3.8%. Moreover, the calculated maximum tensile stress and the compressive stress are 228MPa and 201MPa, while the tested tensile strength and compressive buckling strength of the glass-fiber/epoxy composite are 720MPa and 380MPa, respectively. Consequently, the percentages of the calculated maximum stress and the tested ultimate strength are respectively 31.7% and 52.9%.

Keywords: composite wind turbine blade structural analysis ultimate flapwise load