高速列车车轴载荷谱及压装部位的损伤研究
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摘要
车轴是保障动车组行车安全的关键部件。随着时速达到380公里的CRH380AL系列动车组的研制成功,高速运行下车轴承受的交变载荷得到加剧。同时,由于轮轴压装部位存在微动损伤,在随机载荷的长期作用下逐渐积累,到达一定程度引起疲劳断裂,严重危及行车安全。
本文以CRH380AL动车车轴为研究对像,采用线路动应力实测和有限元方法研究车轴载荷谱及压装部位的损伤,主要内容如下:
1、提出车轴动应力实验布片方案及组桥方式。采用准静态法对车轴进行载荷识别,利用有限元前处理软件Hypermesh及有限元分析软件Ansys计算分析动车轮对有限元模,得到测点的载荷应力传递系数。
2、在京沪线分区段进行动应力线路实测并对数据进行处理。通过载荷识别将动应力时间历程转换成载荷时间历程,编制不同速度级下的载荷谱。
3、从车轴受载角度出发,简化分析载荷对轮轴压装部位损伤的影响。
4、基于标准计算得到车轴压装部位的名义应力谱,按照等损伤原则获得安全运行1200万公里的等效应力幅,标准对轮轴压装部位疲劳极限的规定,通过等效应力幅与疲劳极限的对比结果,对轮轴压装部位的损伤进行分析。
5、从车轴的尺寸角度出发,探讨了如何减小轮轴压装部位微动损伤的措施和方法。
The train axle is the key component of the Electric Motor Unit (EMU). With the successful development of the CRH380AL in China, the alternating load on bearings becomes more and more serious by the speed of 380km/h. At the same time, due to accumulated fretting damage on the axle press-fit parts, fatigue fracture may happen during the operation of the EMU, leading to severe accidents and economic loss.
This paper researches on the load spectrum of the axles and damage on the axle press-fit parts, using the dynamic strain measurement and Finite Element Method (FEM).The approaches of the paper are stated as follows:
1. The approaches to fixing up the strain gauges and arranging the bridge are proposed in this paper. Hypermesh and Ansys are used to analyze the model of wheel set. Then the load-strain transfer coefficient can be obtained by the load of the measuring points.
2. We process the dynamic stress data derived from the intervals on the Beijing-Shanghai Highspeed Railway.The time history of the dynamic strain is transformed into the time history of the load by load identification. According to the previous research, load spectrums at the different speeds are shown in the paper.
3. We analyze the relation between the load and the damage on the axle press-fit parts according to the load on the axles.
4. With the principle of equivalent damage,we obtain the equivalent stress amplitude of 12 million km by stress spectrum with the different methods.According to the manufacturer's standards and regulations for fatigue limit of axle press-fit parts, we compare equivalent stress amplitude with fatigue limit to analyze the damage on the axle press-fit parts.
5. From the perspective of axle size,we discuss measures and methods that how to reduce the fretting damage of axle press-fit parts measures and methods.
本文以CRH380AL动车车轴为研究对像,采用线路动应力实测和有限元方法研究车轴载荷谱及压装部位的损伤,主要内容如下:
1、提出车轴动应力实验布片方案及组桥方式。采用准静态法对车轴进行载荷识别,利用有限元前处理软件Hypermesh及有限元分析软件Ansys计算分析动车轮对有限元模,得到测点的载荷应力传递系数。
2、在京沪线分区段进行动应力线路实测并对数据进行处理。通过载荷识别将动应力时间历程转换成载荷时间历程,编制不同速度级下的载荷谱。
3、从车轴受载角度出发,简化分析载荷对轮轴压装部位损伤的影响。
4、基于标准计算得到车轴压装部位的名义应力谱,按照等损伤原则获得安全运行1200万公里的等效应力幅,标准对轮轴压装部位疲劳极限的规定,通过等效应力幅与疲劳极限的对比结果,对轮轴压装部位的损伤进行分析。
5、从车轴的尺寸角度出发,探讨了如何减小轮轴压装部位微动损伤的措施和方法。
The train axle is the key component of the Electric Motor Unit (EMU). With the successful development of the CRH380AL in China, the alternating load on bearings becomes more and more serious by the speed of 380km/h. At the same time, due to accumulated fretting damage on the axle press-fit parts, fatigue fracture may happen during the operation of the EMU, leading to severe accidents and economic loss.
This paper researches on the load spectrum of the axles and damage on the axle press-fit parts, using the dynamic strain measurement and Finite Element Method (FEM).The approaches of the paper are stated as follows:
1. The approaches to fixing up the strain gauges and arranging the bridge are proposed in this paper. Hypermesh and Ansys are used to analyze the model of wheel set. Then the load-strain transfer coefficient can be obtained by the load of the measuring points.
2. We process the dynamic stress data derived from the intervals on the Beijing-Shanghai Highspeed Railway.The time history of the dynamic strain is transformed into the time history of the load by load identification. According to the previous research, load spectrums at the different speeds are shown in the paper.
3. We analyze the relation between the load and the damage on the axle press-fit parts according to the load on the axles.
4. With the principle of equivalent damage,we obtain the equivalent stress amplitude of 12 million km by stress spectrum with the different methods.According to the manufacturer's standards and regulations for fatigue limit of axle press-fit parts, we compare equivalent stress amplitude with fatigue limit to analyze the damage on the axle press-fit parts.
5. From the perspective of axle size,we discuss measures and methods that how to reduce the fretting damage of axle press-fit parts measures and methods.
引文
[1]张大鹏,陈光雄,田合强.车轴轮座微动损伤对车轴疲劳寿命的影响[J].2009.1(1).113-115
[2]高镇同.疲劳应用统计学[M].北京.国防工业出版社.1986
[3]平安,王德俊,徐教.疲劳载荷谱编制方法的统一[J].机械工程学报.1996.7
[4]徐颧.疲劳强度[M].北京.高等教育出版社.1988
[5]阎楚良,高镇同.飞机高置信度中值随机疲劳载荷谱的编制原理[J].航空学报2000.
[6]毛贺.高速列车载荷谱编制方法的研究[工学硕士论文].北京交通大学.2009.5.
[7]C.B.魏尔辛斯基等著.车辆强度计算[M].成建民,李祥会译,北京,人民铁道出版社,1963
[8]本松启美,手家和彦,前桥荣一.新干线电动车用车轴疲劳试验结果,国外高速列车译文集,1997
[9]日本铁道技术协会,铁道车辆用车轴的实体疲劳强度研究,国外高速列车译文集,1997
[10]侯卫星,王至尧.关于客货车轴载荷谱的研究[R].铁道部四方车辆研究所,青岛,1989
[11]王至尧.双客车轴动载荷分布与疲劳寿命估算[R],铁道部四方车辆研究所,青岛,1992
[12]张瑞亭,崔洪举.提速客车车轴疲劳载荷谱的试验研究[J],铁道车辆科(6),4-7,2006
[13]Hiromichi I改善新干线车辆车轴常规检测[J].国外铁道车辆,2001,38:42-45.
[14]李述松,唐东平,徐建生,宋春如.对DF4、8型机车车轴不良状态的研究[J].内燃机车,2003,8:32-34.
[15]李炳华,杜欣.高速机车车辆车轴的疲劳设计[J].内燃机车,2000,1:14-20.
[16]黄志辉.我国首台高速动力车空心车轴结构设计及工艺[J].机械设计,1998,25-27.
[17]徐文正.CRH2动车组转向架焊接构架结构强度研究[工学硕士论文].北京交通大学.2008.5.
[18]李晏良.符合中国铁路线况的转向架动态载荷系数研究[工学硕士论文].北京交通大学.2008.5.
[19]程育仁等.疲劳强度[M].北京.中国铁道出版社.1992
[20]EN_13104:铁路应用--轮对及转向架-动力车轴-设计方法.2001
[21]江克斌等编著.结构分析有限元原理及ANSYS实现[M].北京.国防工业出版社.2005
[22]徐有成.直升机疲劳载荷谱编制与结构定寿.北京航空航天大学硕士研究生学位论文.2002
[23]文祥荣.车体转向架时域动载荷识别方法研究.北京交通大学:博士论文.2000
[24]Ory H, Glaser H, Holzdeppe D. The reconstruction of forcingfunction based on aeroelasticity and structural dynamics[M]. Aschen, FRG, USA:1985:164-168.
[25]唐秀近.动态力识别的时域方法[J].大连工学院学报,1987,26(4):21-27.
[26]Ory H. Glaser H. Holzdeppe D. Quality of modal analysis andreconstruction of forcing Inunction based on measured output data[C]. In:Proceedings of4th IMAC, USA:1986: 350-357.
[27]石长伟.SW-220型转向架构架主要吊支座的载荷识别[工学硕士论文].北京交通大学.2008.5.
[28]冯玉珍,范存新,张毅.动载荷识别的研究进展 商丘师范学院院报:2008,24(9);57-61
[29]中华人民共和国铁道部.TB/T2705—1996车辆车轴设计与强度计算方法[s].北京:中国铁道出版社,1996
[30]动车组转向架.铁道部运输局,北京交通大学机电学院.2007
[31]UIC510-5标准.整体车轮技术检验.2001
[32]郭杏林.结构随机载荷识别的理论和实验研究.大连理工大学:博士论文.2003
[33]黄梦妮.RD_2型车轴过盈配合损伤分析研究.西南交通大学:硕士论文.2007
[34]张曙光.CRH2型动车组[M].北京.中国铁道出版社.2008.
[35]韦成龙,赵邦华.车轴压装应力的有限元计算与三维光弹性分析[J].铁道车辆.1990.1(5).42-48
[36]杨广雪.高速列车车轴钢旋转弯曲微动疲劳损伤机理及寿命预测研究.北京交通大学:博士论文.2010
[37]赵少汴,王忠保.疲劳设计.北京:机械工业出版社.1995
[38]J.T.巴恩比.曾春华译.疲劳.北京:科学出版社.1984
[39]姚金山.车辆强度和动力性能测试技术[M].北京.中国铁道出版社.1993.
[40]魏延刚,宋亚昕,李键,董思敬.过盈配合接触边缘效应与应力集中[J].大连铁道学院学报Vol.24, No.3,2003
[41]宋勇,艾宴清,梁波.精通ANSYS7.0有限元分析[M].北京:清华大学出版社,2004
[42]曹志礼,王勤忠.高速客车空心车轴的研究[J].铁道车辆,1995,1:5-10.
[43]周素霞.高速列车空心车轴损伤容限理论与方法研究.北京交通大学:博士论文.2009
[44]丁锋,何正嘉,陈雪峰.考虑损伤程度的设备运行可靠性研究.西安交通大学学报Vol. 44No.01,2010.1.
[45]许小强,赵洪伦.过盈配合应力的接触非线性有限元分析.机械设计与研究.No.01,2000.
[46]魏延刚.轴毂过盈联接的应力分析和接触边缘效应.机械设计Vol.21No.01,2004.1.
[47]罗纹.轮轴压装部位周围车轴动应力的研究.铁道车辆.Vol.10,1991.
[48]赵锁宗,王大智.车辆的微动腐蚀与对策[J].铁道车辆,1995,33(7):10-13
[49]Lee S K,Nakazawa K, MSumita. Effects of contact load and contact curvature radius of cylinder pad on fretting fatigue in high strength steel[C]//The 2nd International Symposium on Fretting Fatigue:Current Technology and Practices, Salt Lake City, UT, USA,2000.
[50]张进德,曹志礼.RDZ型实物车轴疲劳实验报告[J].铁道车辆,1987,5:40-5
[51]陈晗.轮对加工、组装质量对预防车轴早期疲劳裂纹的探索.试验检测,2003,5:75-7
[2]高镇同.疲劳应用统计学[M].北京.国防工业出版社.1986
[3]平安,王德俊,徐教.疲劳载荷谱编制方法的统一[J].机械工程学报.1996.7
[4]徐颧.疲劳强度[M].北京.高等教育出版社.1988
[5]阎楚良,高镇同.飞机高置信度中值随机疲劳载荷谱的编制原理[J].航空学报2000.
[6]毛贺.高速列车载荷谱编制方法的研究[工学硕士论文].北京交通大学.2009.5.
[7]C.B.魏尔辛斯基等著.车辆强度计算[M].成建民,李祥会译,北京,人民铁道出版社,1963
[8]本松启美,手家和彦,前桥荣一.新干线电动车用车轴疲劳试验结果,国外高速列车译文集,1997
[9]日本铁道技术协会,铁道车辆用车轴的实体疲劳强度研究,国外高速列车译文集,1997
[10]侯卫星,王至尧.关于客货车轴载荷谱的研究[R].铁道部四方车辆研究所,青岛,1989
[11]王至尧.双客车轴动载荷分布与疲劳寿命估算[R],铁道部四方车辆研究所,青岛,1992
[12]张瑞亭,崔洪举.提速客车车轴疲劳载荷谱的试验研究[J],铁道车辆科(6),4-7,2006
[13]Hiromichi I改善新干线车辆车轴常规检测[J].国外铁道车辆,2001,38:42-45.
[14]李述松,唐东平,徐建生,宋春如.对DF4、8型机车车轴不良状态的研究[J].内燃机车,2003,8:32-34.
[15]李炳华,杜欣.高速机车车辆车轴的疲劳设计[J].内燃机车,2000,1:14-20.
[16]黄志辉.我国首台高速动力车空心车轴结构设计及工艺[J].机械设计,1998,25-27.
[17]徐文正.CRH2动车组转向架焊接构架结构强度研究[工学硕士论文].北京交通大学.2008.5.
[18]李晏良.符合中国铁路线况的转向架动态载荷系数研究[工学硕士论文].北京交通大学.2008.5.
[19]程育仁等.疲劳强度[M].北京.中国铁道出版社.1992
[20]EN_13104:铁路应用--轮对及转向架-动力车轴-设计方法.2001
[21]江克斌等编著.结构分析有限元原理及ANSYS实现[M].北京.国防工业出版社.2005
[22]徐有成.直升机疲劳载荷谱编制与结构定寿.北京航空航天大学硕士研究生学位论文.2002
[23]文祥荣.车体转向架时域动载荷识别方法研究.北京交通大学:博士论文.2000
[24]Ory H, Glaser H, Holzdeppe D. The reconstruction of forcingfunction based on aeroelasticity and structural dynamics[M]. Aschen, FRG, USA:1985:164-168.
[25]唐秀近.动态力识别的时域方法[J].大连工学院学报,1987,26(4):21-27.
[26]Ory H. Glaser H. Holzdeppe D. Quality of modal analysis andreconstruction of forcing Inunction based on measured output data[C]. In:Proceedings of4th IMAC, USA:1986: 350-357.
[27]石长伟.SW-220型转向架构架主要吊支座的载荷识别[工学硕士论文].北京交通大学.2008.5.
[28]冯玉珍,范存新,张毅.动载荷识别的研究进展 商丘师范学院院报:2008,24(9);57-61
[29]中华人民共和国铁道部.TB/T2705—1996车辆车轴设计与强度计算方法[s].北京:中国铁道出版社,1996
[30]动车组转向架.铁道部运输局,北京交通大学机电学院.2007
[31]UIC510-5标准.整体车轮技术检验.2001
[32]郭杏林.结构随机载荷识别的理论和实验研究.大连理工大学:博士论文.2003
[33]黄梦妮.RD_2型车轴过盈配合损伤分析研究.西南交通大学:硕士论文.2007
[34]张曙光.CRH2型动车组[M].北京.中国铁道出版社.2008.
[35]韦成龙,赵邦华.车轴压装应力的有限元计算与三维光弹性分析[J].铁道车辆.1990.1(5).42-48
[36]杨广雪.高速列车车轴钢旋转弯曲微动疲劳损伤机理及寿命预测研究.北京交通大学:博士论文.2010
[37]赵少汴,王忠保.疲劳设计.北京:机械工业出版社.1995
[38]J.T.巴恩比.曾春华译.疲劳.北京:科学出版社.1984
[39]姚金山.车辆强度和动力性能测试技术[M].北京.中国铁道出版社.1993.
[40]魏延刚,宋亚昕,李键,董思敬.过盈配合接触边缘效应与应力集中[J].大连铁道学院学报Vol.24, No.3,2003
[41]宋勇,艾宴清,梁波.精通ANSYS7.0有限元分析[M].北京:清华大学出版社,2004
[42]曹志礼,王勤忠.高速客车空心车轴的研究[J].铁道车辆,1995,1:5-10.
[43]周素霞.高速列车空心车轴损伤容限理论与方法研究.北京交通大学:博士论文.2009
[44]丁锋,何正嘉,陈雪峰.考虑损伤程度的设备运行可靠性研究.西安交通大学学报Vol. 44No.01,2010.1.
[45]许小强,赵洪伦.过盈配合应力的接触非线性有限元分析.机械设计与研究.No.01,2000.
[46]魏延刚.轴毂过盈联接的应力分析和接触边缘效应.机械设计Vol.21No.01,2004.1.
[47]罗纹.轮轴压装部位周围车轴动应力的研究.铁道车辆.Vol.10,1991.
[48]赵锁宗,王大智.车辆的微动腐蚀与对策[J].铁道车辆,1995,33(7):10-13
[49]Lee S K,Nakazawa K, MSumita. Effects of contact load and contact curvature radius of cylinder pad on fretting fatigue in high strength steel[C]//The 2nd International Symposium on Fretting Fatigue:Current Technology and Practices, Salt Lake City, UT, USA,2000.
[50]张进德,曹志礼.RDZ型实物车轴疲劳实验报告[J].铁道车辆,1987,5:40-5
[51]陈晗.轮对加工、组装质量对预防车轴早期疲劳裂纹的探索.试验检测,2003,5:75-7