Fatigue features study on the crankshaft material of 42CrMo steel using acoustic emission 被引量：4

Fatigue features study on the crankshaft material of 42CrMo steel using acoustic emission

导出

摘要 Crankshaft is regarded as an important component of engines, and it is an important application of remanufacturing because of its high added value. However, the fatigue failure research of remanufactured crankshaft is still in its primary stage. Thus, monitoring and investigating the fatigue failure of the remanufacturing crankshaft is crucial. In this paper, acoustic emission （AE） technology and machine vision are used to monitor the four-point bending fatigue of 42CrMo, which is the material of crankshaft. The specimens are divided into two categories, namely, pre-existing crack and non-pre- existing crack, which simulate the crankshaft and crank- shaft blank, respectively. The analysis methods of para- meter-based AE techniques, wavelet transform （WT） and SEM analysis are combined to identify the stage of fatigue failure. The stage of fatigue failure is the basis of using AE technology in the field of remanufacturing crankshafts. The experiment results show that the fatigue crack propagation style is a transgranular fracture and the fracture is a brittle fracture. The difference mainly depends on the form of crack initiation. Various AE signals are detected by parameter analysis method. Wavelet threshold denoising and WT are combined to extract the spectral features of AE signals at different fatigue failure stages. Crankshaft is regarded as an important component of engines, and it is an important application of remanufacturing because of its high added value. However, the fatigue failure research of remanufactured crankshaft is still in its primary stage. Thus, monitoring and investigating the fatigue failure of the remanufacturing crankshaft is crucial. In this paper, acoustic emission （AE） technology and machine vision are used to monitor the four-point bending fatigue of 42CrMo, which is the material of crankshaft. The specimens are divided into two categories, namely, pre-existing crack and non-pre- existing crack, which simulate the crankshaft and crank- shaft blank, respectively. The analysis methods of para- meter-based AE techniques, wavelet transform （WT） and SEM analysis are combined to identify the stage of fatigue failure. The stage of fatigue failure is the basis of using AE technology in the field of remanufacturing crankshafts. The experiment results show that the fatigue crack propagation style is a transgranular fracture and the fracture is a brittle fracture. The difference mainly depends on the form of crack initiation. Various AE signals are detected by parameter analysis method. Wavelet threshold denoising and WT are combined to extract the spectral features of AE signals at different fatigue failure stages.

作者 Yue SHI Lihong DONG Haidou WANG Guolu LI Shenshui LIU

机构地区 School of Materials Science and Engineering National Key Laboratory for Remanufacturing

出处《Frontiers of Mechanical Engineering》 SCIE CSCD 2016年第3期233-241,共9页 机械工程前沿（英文版）

基金 This research was supported by the National Natural Science Foundation of China （Grant Nos. 51535011 and 51275151）.

关键词 acoustic emission fatigue failure remanufac- turing crankshaft wavelet analysis acoustic emission, fatigue failure, remanufac- turing crankshaft, wavelet analysis

分类号 TH [机械工程]

引文网络
相关文献

参考文献3

1郝如江,卢文秀,褚福磊.声发射检测技术用于滚动轴承故障诊断的研究综述[J].振动与冲击,2008,27(3):75-79. 被引量：76
2张志强,李国禄,王海斗,徐滨士,朴钟宇.基于声发射原理监测涂层疲劳磨损的研究[J].摩擦学学报,2012,32(1):89-95. 被引量：10
3周迅,俞小莉.曲轴疲劳裂纹扩展规律测试及形成机理分析[J].机械工程学报,2008,44(1):238-242. 被引量：16

二级参考文献54

1李凤英,沈玉娣,熊军.滚动轴承故障的声发射检测技术[J].无损检测,2005,27(11):583-586. 被引量：14
2赵晓琴,周惠娣,陈建敏.等离子喷涂纳米和常规喂料WC-Co涂层在干摩擦和水环境中的摩擦磨损性能研究[J].摩擦学学报,2006,26(3):208-213. 被引量：12
3Zhu S,Xu B S,Yao J K.High quality ceramic coatings sprayed by high efficiency hypersonic plasma spraying gun[J].Material Science Forum 2005; 475-479:3 981-3 984.
4Tan C K,Mba D.Identification of the acoustic emission source during a comparative study on diagnosis of a spur gearbox[J].Tribology International,2005,38(5):469-80.
5Yu J,Ziehl P,Zarate B,et al.Prediction of fatigue crack growth in steel bridge components using acoustic emission[J].Journal of Constructional Steel Research,2011,67:1 254-1 260.
6Mba D.Development of acoustic emission technology for condition monitoring and diagnosis of rotating machines; bearings,pumps,gearboxes,engines and rotating structures[J].Shock and Vibration Digest,2006,38(1):3-16.
7Meriaux J,Boinet M.Identification of fretting fatigue crack propagation mechanisms using acoustic emission[J].Tribology International,2010,43:2 166-2 174.
8Piao Z Y,Xu B S,Wang H D,et al.Influence of undercoating on rolling contact fatigue performance of Fe-based coating[J].Tribology International,2010.43:252-258.
9Piao Z Y,Xu B S,Wang H D,et al.Investigation of fatigue prediction of Fe-Cr alloy coatings under rolling contact based on acoustic emission technique[J].Applied Surface Science,2011,257(7):2 581-2 586.
10Khamis R,Balushi Al,Addali A.Energy Index technique for detection of acoustic emissions associated with incipient bearing failures [J].Applied Acoustics,2010,71:812-821.

共引文献96

1尹玉玺,周常飞,史春祥,徐卫鹏,慕杰,许志鹏.采煤机摇臂齿轮箱故障诊断研究现状及展望[J].煤炭工程,2022,54(11):107-112. 被引量：8
2姚晓山,张永祥,明廷涛.基于经验模态分解的齿轮裂纹声发射检测[J].无损检测,2009,31(6):464-467. 被引量：1
3卢大平,祁文军,程伟.ANSYS在连杆疲劳寿命分析中的应用[J].汽车零部件,2009(4):57-59. 被引量：3
4李成,铁瑛,郑艳萍.复合型裂纹系统能量变化的仿真分析及同Ⅰ型裂纹系统能量的比较[J].机械工程学报,2010,46(10):54-58. 被引量：2
5赵元喜,胥永刚,高立新,崔玲丽.基于谐波小波包和BP神经网络的滚动轴承声发射故障模式识别技术[J].振动与冲击,2010,29(10):162-165. 被引量：62
6张子庆,倪计民,石秀勇.路面激励对车用发动机动平衡特性的影响[J].机械工程学报,2011,47(8):134-140. 被引量：5
7吴占稳,沈功田,袁俊,王勇.声发射技术在大型观览车主轴检测中的应用[J].无损检测,2011,33(5):39-42. 被引量：3
8吴占稳,沈功田,袁俊.大型观览车主轴系统的声发射信号特征[J].无损检测,2011,33(9):29-32. 被引量：1
9韩衍昭,刘爱敏.内燃机柴滤架振动特性分析[J].矿山机械,2011,39(11):92-95. 被引量：1
10刘浩,鲁五一.铁路货车轴承在线故障诊断智能系统研究[J].微计算机信息,2011,27(11):32-33. 被引量：2

同被引文献26

1赵长财,张涛,袁荣娟,于寅辰.液压机立柱导套接触应力研究[J].重型机械,1995(4):14-16. 被引量：6
2吴生富,金淼,聂绍珉,宋清玉.大型锻造液压机全预紧组合机架的整体性及影响因素分析[J].塑性工程学报,2006,13(2):110-113. 被引量：33
3边勇俊,张娜,盛静波,劳金越,陈洁.42CrMo连铸辊裂纹原因分析[J].金属热处理,2010,35(1):125-127. 被引量：10
4李雅倩,王斌修.精冲工艺与模具设计[J].制造技术与机床,2010(4):21-23. 被引量：2
5王荣.高强度螺栓表面开裂原因分析[J].物理测试,2010,28(4):37-41. 被引量：10
6余兆新,蒋佩华,姚志江,徐云峰.42CrMo钢螺栓断裂分析[J].金属热处理,2012,37(4):128-130. 被引量：13
7孙伟,熊邦书,黄建萍,莫燕.小波包降噪与LMD相结合的滚动轴承故障诊断方法[J].振动与冲击,2012,31(18):153-156. 被引量：92
8陈希原.42CrMo钢汽车前轴淬火开裂原因分析[J].金属热处理,2013,38(1):131-134. 被引量：19
9祁学军,杨冬梅,晏高华.42CrMo轴件断裂原因分析[J].理化检验（物理分册）,2013,49(1):55-58. 被引量：10
10隋文涛,张丹.基于峭度的阈值降噪方法及在振动信号分析中应用[J].振动与冲击,2013,32(7):155-158. 被引量：15

引证文献4

1马骏,吴开志,李新民,俞子荣.时空域相关自适应小波包声发射信号降噪方法[J].南昌航空大学学报（自然科学版）,2018,32(1):90-96. 被引量：2
2李霞,朱施利,金满洁.42CrMo高强螺栓热处理开裂原因分析[J].物理测试,2019,37(6):51-54. 被引量：6
3刘德政,李炎,罗静,秦志洪.液压式精冲压力机抗偏载曲线的绘制与研究[J].锻压技术,2020,45(11):143-149.
4冷建成,王玉洁,钱万东,刘晔.服役构件疲劳损伤的声发射信号特征提取[J].化工机械,2021,48(2):186-192.

二级引证文献8

1吴跃.引风机转子芯轴断裂原因分析[J].上海金属,2020,42(5):89-93. 被引量：2
2海超,郭晓静.连铸机连杆断裂原因分析[J].物理测试,2020,38(5):23-26.
3董凤奎,刘年富,廖卓文,胡昭锋,丘先堂,何永杰.热处理工艺对GCr15轴承钢淬火裂纹的影响[J].金属材料与冶金工程,2020,48(6):46-50. 被引量：7
4魏娜莎,闫献国,谷丰收,陈峙.基于声发射的活塞环-缸套摩擦润滑特征研究[J].机械工程学报,2021,57(8):107-114. 被引量：2
5袁希金,许用会.42CrMo传动半轴断裂失效分析[J].山西冶金,2022,45(7):53-55. 被引量：1
6赵敬,刘德政,杨高元,黄洛川.42CrMo传动轴花键轴套断裂失效分析[J].热加工工艺,2023,52(21):145-147.
7葛海彬,刘巍,赵洪光,朱昱瑛,董占坤,许颜贺.基于PVMD-AE-SVM的分步式水轮机空化状态诊断方法[J].失效分析与预防,2024,19(2):73-79.
8王海金.工程机械高强度螺栓的疲劳断裂分析[J].失效分析与预防,2024,19(4):284-289.

1于庆波,杨和礼.塔式起重机常见事故分析与预防[J].建筑机械,2003,23(2):53-54. 被引量：11
2First ship crankshaft processed by home-made machine tool off production line[J].国际船艇,2008(3):9-9.
3Yu Yangui,Zhang Wenbin,(Wenzhou University).CALCULATIONS TO ITS FATIGUE DAMAGE FRACTURE AND TOTAL LIFE UNDER MANY－STAGE LOADING FOR A CRANK SHAFT[J].Chinese Journal of Mechanical Engineering,1994,7(4):281-288. 被引量：2
4刘庆华.在线分析仪表在工程应用中存在的问题及解决方案[J].石油化工自动化,2009,45(6):63-65. 被引量：19
5孟丹,杨金堂,黄新豪,谈大伟.变截面吊车梁静动态特性的有限元分析[J].机械设计与制造,2014(4):44-46. 被引量：6
6吴江锋.机械加工制造工艺研究与探析[J].中国新技术新产品,2011(6):158-158. 被引量：10
7陈翠梅,霍臻.压力容器声发射信号参数分析方法的探讨[J].工业安全与防尘,1999,25(5):4-6. 被引量：1
8唐钟麟,冯志华,黄晓蔚.电磁轴承柔性转子系统分析方法[J].机械工程学报,1999,35(2):97-100. 被引量：9
9刘岩,高国安,于华.并行工程下面向制造的设计[J].机械科学与技术,1999,18(3):504-505. 被引量：4
10邓小林,刘夫云,韦衡冰.产品尺寸参数分析方法及其应用研究[J].制造业自动化,2009,31(7):118-120. 被引量：4

Frontiers of Mechanical Engineering

2016年第3期

浏览历史

内容加载中请稍等...