Fatigue Life Prediction for Flange Connecting Bolts of Wind Turbine Tower 被引量：8

导出

摘要 Flange joint part is the weak link of wind turbine tower.In view of the special structure,complex stress and easy failure of the connecting bolt of the wind turbine tower flange,the relationship between the external load of the tower section and the internal stress of the bolt is established by the finite element method,and the time series internal stress of the bolt is calculated by the Schmidt-Neuper algorithm.The S-N curve which is suitable for the connecting bolt material of the tower flange is selected by the GL2010 specification.On the basis of Miner’s fatigue cumulative damage theory and rain flow counting method,the fatigue strength of the whole ring bolt is roughly calculated,and the most dangerous part is determined.The axial symmetry model of screw connection is used for accurately calculating the fatigue cumulative damage of the bolt at the dangerous part.The results show that the fatigue life of the bolts in the most dangerous position can meet the requirements,the engineering algorithm has advantages in determining the dangerous part of the whole ring bolt,and the finite element method has high accuracy in predicting the fatigue life of the bolts in the dangerous part.The proposed method is feasible and effective in predicting the fatigue life of the flange joint bolts of the tower.

作者 YU Zelin SUN Pengwen WANG Dong 于泽林;孙鹏文;王栋(School of Mechanical Engineering,Inner Mongolia University of Technology,Hohhot 010051,China;Research Institute,Beiqi Foton Motor Co.,Ltd.,Beijing 102206,China)

机构地区 School of Mechanical Engineering Research Institute

出处《Journal of Shanghai Jiaotong university(Science)》 EI 2020年第4期526-530,共5页 上海交通大学学报（英文版）

基金 the Special Research Fund for the Natural Science Foundation of Inner Mongolia Autonomous Region(No.2019MS05070)。

关键词 fatigue cumulative damage internal stress of bolt engineering algorithm flange connecting bolt wind turbine tower

分类号 TH12 [机械工程—机械设计及理论]

引文网络
相关文献

参考文献4

1赵少汴.常用累积损伤理论疲劳寿命估算精度的试验研究[J].机械强度,2000,22(3):206-209. 被引量：43
2陈严,田鹏,刘雄,叶枝全.水平轴风力机轮毂强度分析方法研究[J].太阳能学报,2010,31(7):912-916. 被引量：14
3LIAO Ridong,SUN Yujuan,ZHANG Weizheng.Nonlinear Analysis of Axial-load and Stress Distribution for Threaded Connection[J].Chinese Journal of Mechanical Engineering,2009,22(6):869-875.
4龙凯,贾娇,肖介平.基于Schmidt-Neuper算法塔筒螺栓疲劳强度研究[J].太阳能学报,2014,35(10):1904-1910. 被引量：17

二级参考文献27

1陈严,王楠.水平轴风力机极限载荷预测方法的研究[J].汕头大学学报（自然科学版）,2005,20(1):43-47. 被引量：9
2刘雄,陈严,叶枝全.水平轴风力机气动性能计算模型[J].太阳能学报,2005,26(6):792-800. 被引量：105
3疲劳累积损伤规律研究课题组.疲劳累积损伤规律研究课题技术资料[M].郑州:郑州机械研究所,1991..
4SOPWITH D G. The distribution of load in screw threads[J]. Inst. Mech. Engrs. Appl. Mech. Proc., 1948, 159:373- 383.
5YAMAMOTO A. The theory and computation of thread connection[M]. Tokyo: Youkendo, 1980: 39-54. (in Japanese).
6MARUYAMA K. Stress analysis of a nut-bolt joint by the finite element method and the copper-electroplating method (1 st Report) [J]. Bulletin of JSME, 1973, 16 (94): 671-678.
7MARUYAMA K. Stress analysis of a nut-bolt joint by the finite element method and the copper-electroplating method (2nd Report) [J]. Bulletin of JSME, 1974, 17 (106): 442-450.
8GREWAL A S, SABBAGHIAN M. Load distribution between threads in threaded connections[J]. Journal of Pressure Vessel Technology, 1997, 119 (1): 91-95.
9FUKUOKA T, YAMASAKI N, KITAGAWA H, et al. Ratio of flank loads of screw threads in hollow-bolt[J]. Bulletin of JSME, 1986, 29 (247): 265- 272.
10FUKUOKA T. Evaluation of the method for lowering stress concentration at the thread root of bolted joints with modifications of nut shape[J]. Journal of Pressure Vessel Technology, 1997, 119 (1): 1-9.

共引文献91

1朱永梅,王明强,刘艳梨.曲轴轴系的结构强度分析与疲劳寿命估算[J].机械强度,2010,32(6):1018-1021. 被引量：8
2毕继红,陈花丽,任洪鹏.基于简化载荷谱法与雨流计数法的接触网疲劳寿命对比分析[J].铁道标准设计,2012,32(4):116-119. 被引量：8
3YANG Guoqing,HONG Jun,ZHU Linbo,LI Baotong,XIONG Meihua,WANG Fei.Three-dimensional Finite Element Analysis of the Mechanical Properties of Helical Thread Connection[J].Chinese Journal of Mechanical Engineering,2013,26(3):564-572. 被引量：21
4王永廉.一种估算谱载疲劳裂纹起始寿命的方法[J].力学与实践,2004,26(5):43-46. 被引量：1
5王永廉.估算变幅疲劳寿命的等效折算法[J].应用力学学报,2005,22(1):90-94. 被引量：10
6李荣,邱洪兴,淳庆.疲劳累积损伤规律研究综述[J].金陵科技学院学报,2005,21(3):17-21. 被引量：15
7冯秀峰,宋玉普,朱美春.随机变幅疲劳荷载下预应力混凝土梁疲劳寿命的试验研究[J].土木工程学报,2006,39(9):32-38. 被引量：37
8王永廉.估算谱载下疲劳裂纹起始寿命的工程实用方法[J].机械强度,2007,29(1):86-91.
9金祥曙,周晓军.汽车驱动桥半轴室内试验强化系数模型研究[J].汽车工程,2007,29(2):146-148. 被引量：6
10金祥曙,周晓军.基于随机载荷谱的汽车驱动桥疲劳性能强化试验研究[J].机械设计,2007,24(12):49-52. 被引量：10

同被引文献67

1史卜涛,刘莉媛,管家伟,李红有.带栓钉基础环式风机基础受力有限元法分析[J].建筑结构,2022,52(S01):2378-2381. 被引量：8
2徐祉康,易伟同,祝磊.风力发电机组钢塔筒M64螺栓连接法兰受拉承载性能试验研究[J].建筑结构,2021,51(S01):1522-1527. 被引量：4
3施敏捷,王建梅,侯定邦,宁可.风电法兰摩擦因数预测与表面工艺优化[J].中国表面工程,2021,34(6):197-204. 被引量：6
4陈鑫,李爱群,王泳,张志强.高耸钢烟囱环形TLD减振试验与数值模拟[J].建筑结构学报,2015,36(1):37-43. 被引量：10
5刘锡良,周颖.风荷载的几种模拟方法[J].工业建筑,2005,35(5):81-84. 被引量：133
6杨树森,张光明,刘煜.拉铆钉及其在铁道车辆中的应用[J].铁道车辆,2006,44(12):11-13. 被引量：21
7瞿伟廉,秦文科,郭佳凡.高耸塔架结构节点联结螺栓松动等效模型研究[J].武汉理工大学学报,2007,29(1):139-141. 被引量：9
8柳国环,李宏男,国巍.TLD-结构体系转化为TMD-结构体系的减振计算方法[J].工程力学,2011,28(5):31-34. 被引量：11
9何平,刘光复,谷叶水,周丹,黄海鸿,王雁.基于三维精确建模法的螺栓有限元分析[J].中国机械工程,2012,23(16):1991-1996. 被引量：39
10张晋华,刘永前,田德,顾波,汪宁渤.以风电机组叶片延寿为目标的风电场优化调度[J].太阳能学报,2013,34(11):1978-1985. 被引量：10

引证文献8

1陶涛,龙凯,刘永前,乔延辉.计及限功率工况的风电塔筒螺栓疲劳寿命预测方法[J].太阳能学报,2021,42(11):359-366. 被引量：12
2李九一,周丰峻,张鏖,孙云厚,雷志刚,朱精忠.螺纹结构精确有限元建模及有效性分析[J].工程科学与技术,2022,54(3):220-229. 被引量：9
3赵艳,杨哲,王新武,李晓露,陈枫.过渡循环对风力机疲劳评估的影响及修正[J].振动与冲击,2024,43(3):241-246. 被引量：3
4宁可,王奇,陈纪光,王建梅,宁文钢.倾覆力耦合的大兆瓦风机主轴-齿轮箱法兰结构疲劳寿命研究[J].机械设计,2024,41(7):121-127. 被引量：2
5田晶,高崇,关焦月,付鹏哲,刘仕运,姚玉东.收口自锁螺母高保真建模方法及松动特性研究[J].机械工程学报,2024,60(21):132-143. 被引量：1
6樊轲,戴靠山,衡俊霖,王睿,廖光明.风电塔筒环法兰连接结构型高强铆钉的疲劳特性[J].土木与环境工程学报(中英文),2025,47(2):151-161. 被引量：3
7曹宝雅,杨冰沂,李爱群,邓扬,丁幼亮.自立式钢烟囱法兰螺栓连接节点风致疲劳研究[J].工业建筑,2025,55(1):75-85. 被引量：1
8Yongchao Liu,Shuqing Dong,Qingfeng Wang,Wenhe Cai,Ruizhuo Song,Qinglai Wei.Fault Diagnosis for Wind Turbine Flange Bolts Based on One-Dimensional Depthwise Separable Convolutions[J].The International Journal of Intelligent Control and Systems,2024,29(1):42-47.

二级引证文献31

1刘飞鹏,李红星,梁刚,郭宏超,张思嘉.拼腔钢-混凝土组合结构双盖板穿芯螺栓节点疲劳性能研究[J].建筑结构,2023,53(S01):1834-1841.
2梁原,王有良,魏泰,刘俭辉.风力发电机塔筒法兰高强度螺栓疲劳强度分析[J].兰州理工大学学报,2023,49(2):65-69. 被引量：9
3王珏,杜学波.螺栓紧固件参数化有限元建模平台及有限元分析[J].现代制造技术与装备,2023,59(4):101-106.
4彭超峰,王红亮,张先兆.风能发电机组叶片连接高强度螺栓断裂失效分析[J].金属材料与冶金工程,2023,51(3):33-36. 被引量：4
5张鸿泰,杨书仪,何先龙,李志鹏.陆上风力发电机塔架振动监测研究进展[J].电子测量技术,2023,46(7):172-179. 被引量：7
6宋永巍,李博,李显伟,朱丽,欧阳剑蒙.直升机桨叶安装螺栓强度与疲劳寿命计算分析[J].装备环境工程,2023,20(11):63-71. 被引量：1
7孙宇航.球磨机筒体中空轴处连接螺栓疲劳寿命预测[J].金属功能材料,2023,30(6):151-156. 被引量：1
8苑光明,王全彪,景国玺,王尚忠,王功成,曾小春,张丽强.基于子模型的主轴承螺纹疲劳强度分析方法[J].内燃机工程,2024,45(1):37-46. 被引量：4
9李佳泽,朱晓磊,陆晓峰.横向振动载荷下有无螺纹配合间隙对连接松脱性能的影响[J].化工机械,2024,51(2):242-251. 被引量：2
10宁文钢,王奇,姜宏伟,王岳峰,宁可.大兆瓦风机主轴法兰螺栓疲劳寿命评估方法研究[J].机床与液压,2024,52(14):78-82. 被引量：2

1Abeer E. Dief,Elena V. Sivukhina,Gustav F. Jirikowski.Oxytocin and Stress Response[J].Open Journal of Endocrine and Metabolic Diseases,2018,8(3):93-104.
2Minhai Huang.Interfacial Crack Problem of a Class of Spliced Materials[J].Journal of Applied Mathematics and Physics,2019,7(11):2811-2817.
3李亚重,杨有龙,仇海全.一种基于嵌入式的弱标记分类算法[J].南京大学学报（自然科学版）,2020,56(4):549-560. 被引量：2
4Yinling Zhang,Aihan Feng,Shoujiang Qu,Jun Shen,Daolun Chen.Microstructure and low cycle fatigue of a Ti2AlNb-based lightweight alloy[J].Journal of Materials Science & Technology,2020,44(9):140-147. 被引量：9
5王立安,赵建昌,杨华中.饱和多孔地基与矩形板动力相互作用的非轴对称混合边值问题[J].力学学报,2020,52(4):1189-1198. 被引量：2
6Zhen-Xia Niu,Yong-Hang Tai,Jun-Sheng Shi,Wei Zhang.Bose-Einstein condensates in an eightfold symmetric optical lattice[J].Chinese Physics B,2020,29(5):400-405.

Journal of Shanghai Jiaotong university(Science)

2020年第4期

浏览历史

内容加载中请稍等...