Fatigue Crack Growth and Nondestructive Quantitative Characterization in Centrifugal Wheels

doi:10.3969/j.issn.1004-132X.2021.06.004

Abstract

Abstract: In order to study the internal fatigue crack growth and the nondestructive quantitative characterization of the centrifugal wheels, the high-speed and low cycle rotating fatigue tests were carried out, and a variety of nondestructive quantitative characterization, fracture analysis and fatigue crack growth simulation were compared. The results show that after the fatigue cracks reach to the surfaces, the fatigue cracks are in the unstable growth stage. During 20 000~21 700 cycles, the simulation values of the interval fatigue crack growth rate are close to the non-destructive characterization values. During 21 700~21 789 cycles, the non-destructive characterization values of the interval fatigue crack growth rate are about 2.5 times larger than that of the simulation values. When the fatigue cracks propagate inside the centrifugal wheel and outside the inclusion areas, the fatigue cracks are in a stable growth stage. Total focusing method(TFM) ultrasonic testing and time of flight diffraction(TOFD) ultrasonic testing may identify the inclusion / fatigue crack internal growth of the centrifugal wheels. At 0 and 6000 cycles, the fatigue cracks are in the inclusion area, the nondestructive characterization values remain unchanged. After 9000 cycles, the TFM ultrasonic nondestructive characterization values of cracks height H and radial length LR increase significantly, the change is similar to the fracture values, but the increased amplitude is smaller.

Key words: nondestructive testing, titanium alloy wheel, fatigue crack growth, inclusion

摘要： 为研究某离心轮内部疲劳裂纹扩展及其无损定量表征，开展了高速低循环旋转疲劳试验以及多种无损检测定量表征、断口分析、疲劳裂纹扩展仿真对比研究。研究结果表明：疲劳裂纹到达表面后，疲劳裂纹处于非稳定扩展阶段；20 000~21 700循环间，区间疲劳裂纹扩展速率仿真值与无损表征值接近；21 700~21 789循环间，区间疲劳裂纹扩展速率无损表征值比仿真值大2.5倍左右。疲劳裂纹在离心轮内部、夹杂缺陷区外扩展时，疲劳裂纹处于稳定扩展阶段；全聚焦法(TFM)超声检测和衍射时差(TOFD)超声检测能识别离心轮夹杂缺陷/疲劳裂纹内部扩展；0循环和6000循环时疲劳裂纹在夹杂缺陷区内，无损检测表征值均未发生变化；9000循环及之后，裂纹高度H和径向长度LR的TFM超声无损表征值出现明显的增大，变化与断口值相似但增幅偏小。

关键词: 无损检测, 钛合金盘, 疲劳裂纹扩展, 夹杂缺陷

CLC Number:

V231.95

WU Yinglong, XUAN Haijun, SHAN Xiaoming, FU Rulong. Fatigue Crack Growth and Nondestructive Quantitative Characterization in Centrifugal Wheels[J]. China Mechanical Engineering, 2021, 32(06): 658-665.

吴英龙, 宣海军, 单晓明, 付汝龙. 离心轮内部疲劳裂纹扩展及其无损定量表征[J]. 中国机械工程, 2021, 32(06): 658-665.

References

［1］中国民用航空局.航空发动机适航规定：CCAR-33R2［S］.北京：中国民用航空局，2011：34-35.

Civil Aviation Administration of China. Chinese Civil Aviation Regulations: CCAR-33R2［S］. Beijing: Civil Aviation Administration of China,2011：34-35.

［2］SERRANO-MUNOZ I, BUFFIERE J Y, VERDU C, et al. Influence of Surface and Internal Casting Defects on the Fatigue Behavior of A357-T6 Cast Aluminium Alloy［J］. International Journal of Fatigue, 2016,82:361-370.

［3］SANDAIJI Y, TAMURA E, TSUCHIDA T. Influence of Inclusion Type on Internal Fatigue Fracture under Cyclic Shear Stress［J］. Procedia Materials Science, 2014, 3:894-899.

［4］DWIVEDI S K, VISHWAKARMA M, SONI P A. Advances and Researches on Nondestructive Testing: a Review［J］. Materials Today Proceedings, 2018,5(2):3690-3698.

［5］KAMSU-FOGUEM B. Knowledge-based Support in Nondestructive Testing for Health Monitoring of Aircraft Structures［J］. Advanced Engineering Informatics,2012,26(4):859-869.

［6］叶伟龙. 基于AATT法相控阵超声检测裂纹高度定量误差研究［D］. 大连：大连理工大学，2015.

YE Weilong. The Study of Crack Height Error by Phased Array Ultrasonic Testing Based on AATT Method［D］. Dalian:Dalian University of Technology,2015.

［7］池强强. 超声相控阵检测的数值模拟及全聚焦成像研究［D］.上海：华东理工大学，2019.

CHI Qiangqiang. Research on Ultrasonic Phased Array detection and TFM imaging based on Finite Element Method［D］.Shanghai:East China University of Science and Technology,2019.

［8］樊萍，刘新宝. 超声检测中金属裂纹多特征提取研究［J］.西北大学学报(自然科学版)，2018,48(4)：521-526.

FAN Ping, LIU Xinbao. A Study of Multi-feature Extraction for Metal Crack Using Ultrasonic Testing［J］. Journal of Northwest University ( Natural Science Edition), 2018,48(4)：521-526.

［9］刘斌，刚铁，万楚豪，等. 金属杆内疲劳裂纹与振动/超声相互作用及其定量表征［J］.声学学报，2016,41(4)：507-514.

LIU Bin, GANG Tie, WAN Chuhao, et al. Interaction of Fatigue Crack with Vibration and Ultrasound in Metallic Rod and Its Use for Quantitative Characterization［J］. Acta Acustica,2016,41(4)：507-514.

［10］方漂漂,郑慧峰,喻桑桑,等. 基于振动声调制的金属微裂纹检测方法［J］. 中国机械工程, 2016, 27(11):1497-1501.

FANG Piaopiao, ZHENG Huifeng, YU Sansan, et al. Metal Micro Crack Detection Based on Vibro-acoustic Modulation Method［J］. China Mechanical Engineering, 2016, 27(11):1497-1501.

［11］陶春虎，习年生，张卫方，等. 断口反推疲劳应力的新进展［J］.航空材料学报，2000,30(3)：158-163.

TAO Chunhu, XI Niansheng, ZHANG Weifang, et al. Resent Development of Fractographic Restrostimationon Determining Fatigue Stress［J］. Journal of Aeronautical Materials, 2000, 3(3):158-163.

［12］赵光菊，钟蜀晖，邓建华.TA6V钛合金疲劳断口形貌及断口分析［J］.贵州工业大学学报(自然科学版)，2007,36(6)：25-28.

ZHAO Guangju, ZHONG Shuhui, DENG Jianhua. Study on the Fatigue Fracture in TA6V Titanium Alloy［J］. Journal of Guizhou University of Technology(Natural Science Edition)，2007,36(6)：25-28.

［13］YOSHITAKA W, MASANORI K, SHINJI Y, et al. Fatigue Growth of Internal Flaw:Simulation of Subsurface Crack Penetration to the Surface of the Structure［J］. Engineering Fracture Mechanics, 2014,7:100-115.

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Fatigue Crack Growth and Nondestructive Quantitative Characterization in Centrifugal Wheels

离心轮内部疲劳裂纹扩展及其无损定量表征

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