The Review of Research on Fatigue Crack Propagation in Metallic Materials

Yunbo Zhang; Yunrong Luo; Xin Wu; Yanbing Guan

doi:10.62051//ijmsts.v1n1.05

Authors

Yunbo Zhang
Yunrong Luo
Xin Wu
Yanbing Guan

DOI:

https://doi.org/10.62051//ijmsts.v1n1.05

Keywords:

Fatigue crack propagation, Fracture mechanics, Temperature, Stress ratio, Frequency

Abstract

In recent years, with the development of industry and scientific technology, the demand for materials has been increasing. Fatigue crack propagation is an important issue in the field of materials, and developing relevant theories and methods, understanding the mechanisms of fatigue cracks, and making scientific predictions on fatigue crack propagation are hot topics both domestically and internationally. Fracture mechanics, as a discipline studying the strength and propagation of cracks in materials, has developed a relatively complete theoretical system and engineering application methods over more than 100 years of continuous development. This article focuses on the effects of factors such as temperature, stress ratio, and load frequency on the fatigue crack propagation characteristics of metallic materials, and summarizes the common theories and methods of fatigue crack propagation.

References

Dan B M, Dupac M. Fatigue failure[J]. Machine Component Analysis with MATLAB. 2019: 69-101.

Chinese Mechanical Engineering Society of Materials, R.Z. Wang, P.Y. Wu. Fatigue failure analysis [M]. Fatigue Failure Analysis, 1987.

Yang LY, Wang QC, Wang YW, et al. Progress of fracture criterion research on linear elastic fracture mechanics of materials[J]. Science and Technology Herald. 2020, 38(2): 10.

Nilsson K F, Jaki N, Vokál V. An elasto-plastic fracture mechanics based model for assessment of hydride embrittlement in zircaloy cladding tubes[J]. . Journal of Nuclear Materials. 2010, 396(1): 71-85.

Fu Xiangjiong, Yin Zhiping, Xie Wei, et al. Fatigue life analyzing method based on Paris formula[P].

[6] Ni Xianggui, Li Xinliang, Wang Xiuxi. General modification and application of Paris formula for fatigue crack propagation law[J]. Pressure Vessel. 2006, 23(12): 9.

YANG Yanhui, BAI Yun, FAN Haidong, et al. Comparison of KIC test standards for metallic materials at home and abroad[J]. Physical testing. 2020(1): 4.

Jeglic F, Niessen P, Burns D J. Temperature dependence of fatigue crack propagation in an Al-2.6 Mg alloy[J]. Fatigue at Elevated Temperature, American Society for Testing and Minerals (ASTM) STP. 1973, 520: 139-148.

Teng Kui, Liang Zhiguo, Shi Songxin, et al. Effect of temperature to stress ratio on fatigue crack propagation behaviour of 6061 aluminium alloy[J]. China Metallurgy. 2021, 31(12): 102-106.

MA Lei, LI Changsheng, GUO Jierong. Atomic simulation of fatigue crack propagation mechanism in Ni_3Al at different temperatures[J]. Journal of Southwest Normal University (Natural Science Edition). 2020, 45(07): 55-61.

Zhang YW Wang ZQ. Progress in the application of molecular dynamics methods in studying the mechanical behaviour of materials[J]. Progress in Mechanics. 1996(01): 14-27.

Rackwitz J, Yu Q, Yang Y, et al. Effects of Cryogenic Temperature and Grain Size on Fatigue-Crack Propagation in the Medium-Entropy CrCoNi Alloy[J]. Acta Materialia. 2020, 200.

Li J, Cai J M, Duan R, et al. Fatigue Crack Growth Behavior of TA29 Titanium Alloy at Different Temperatures[J]. Materials Science Forum. 2020, 993: 259-266.

Yu Lanlan, Mao Xiaonan, Li Hui. Effect of Temperature on Fatigue Crack Expansion Behaviour of TC4-DT Damage Tolerant Titanium Alloy[J]. Rare Metals Express. 2007(12): 20-23.

ZHANG Guangping WANG Zhongguang ZHANG Bin. Effect of temperature and loading waveform on fatigue-creep crack propagation behaviour of Ni_3Al(B)[J]. Journal of Metals. 1999(06): 589-593.

XU Lianyong, ZHAO Lei, TANG Zhengqiu. Characterisation of creep-fatigue crack propagation behaviour of high temperature components[J]. Power Technology and Environmental Protection. 2021, 37(04): 1-11.

M. N B, G. S. Effect of temperature on the fatigue crack growth behaviour of SS316L(N)[J]. International Journal of Fatigue. 2020, 140.

SONG Chi-Guang, ZHAO Bin, GENG Xiao-Liang, et al. Influence of temperature and stress ratio on fatigue crack propagation pattern of aerospace aluminium alloy and its mechanism[J]. Journal of Materials Science and Engineering. 2015, 33(02): 157-162.

WEI Lianfeng, CUI Guangshun, BAO Chen, et al. Study on the effect of temperature and hydride on fatigue crack propagation behaviour of Zr-Sn-Nb alloy welds[J]. Atomic Energy Science and Technology. 2021, 055(003): 527-533.

WANG Ke, QIN Gang, CUI Pengfei, et al. Experimental study on fatigue crack propagation rate of titanium alloy at room temperature and low temperature[J]. Ship Science and Technology. 2020, 42(6): 5.

Rani B, Tanaka M, Yamasaki S, et al. Effects of Temperature and Stress Ratio on Stage II Fatigue Crack Propagation in Bimodal Ti6Al4V[J]. Materials Transactions. 2021.

T.L. Xu, R. Wang, Y.R. Feng, et al. Effect of Stress Ratio on Fatigue Crack Expansion Performance of K55 Casing Drilling Steel[J]. Materials Engineering. 2015, 043(006): 79-84.

Liu S-L. Influence of stress ratio on high and ultra-high circumferential fatigue behaviour of alloy materials[J]. 2015.

Wang Y, Fei Q, Zhao C, et al. Effect of Load on Fatigue Crack Growth of ADB610 Steel[J]. Development and Application of Materials. 2018.

Wei L, Wang Shiyue, Liu Guoshou, et al. Experimental Study on Fatigue Crack Expansion Rate of ADB610 Steel under Different Stress Ratios[J]. Mechanical Strength. 2016, 38(1): 5.

Zhong Z, Gu Y, Osada T, et al. Fatigue crack growth characteristics of a new Ni-Co-base superalloy TMW-4M3: effects of temperature and load ratio[J]. Journal of Materials Science. 2011, 46(23): 7573-7581.

Benachour M, Benachour N, Benguediab M. Effect of Single Overload Ratio and Stress Ratio on Fatigue Crack Growth[J]. 2013(12).

Liu H, Gong Y, Zhang C, et al. Effect of Stress Ratio on Fatigue Crack Expansion Rate of ST12 Mild Steel[J]. Mechanical Engineering Materials. 2020, 44(06): 25-27.

Wang J, Guo C, Huang K, et al. Study on fatigue crack growth rate of 15CrMo steel based on stress ratio and corrosion environment[C]. 2020.

Li Chunyan, Yu FY, Huang YW, et al. Effect of stress ratio on fatigue crack propagation behaviour of 6082T651 aluminium alloy[J]. Lab Sci. 2019, 22(01): 53-56.

YANG Wulin, YANG Xiaohua, LI Xiaoyan, et al. Fatigue life and fracture analysis of laser-welded joints of TC4 titanium alloy thin plate[J]. Journal of Welding. 2012, 33(03): 105-108.

Costa J D M, Ferreira J A M. Effect of stress ratio and specimen thickness on fatigue crack growth of CK45 steel[J]. Theoretical and Applied Fracture Mechanics. 1998, 30(1): 65-73.

WANG Heng, LIU Xiao, NI Guangxian. Experimental study on the effect of stress ratio on corrosion fatigue crack propagation of E690 high strength steel[J]. Thermal Processing Technology. 2019, 48(10): 79-82.

ZHANG Yubo, GUO Rongxin, XIA Haiting, et al. Analysis of fatigue crack propagation behaviour and influence mechanism of Cu/WCp composites under different stress ratios[J]. Materials Herald. 2016, 30(20): 129-133.

Malipatil S G, Majila A N, Fernando D C, et al. Correlating Stress Ratio Effects on the Fatigue Crack Growth Rate of a Nickel Base Superalloy IN718[J]. 2021.

Nakai Y, Kikuchi S, Asayama K, et al. Stress Ratio Effect on Fatigue Crack Initiation Mechanism of Magnesium Alloy AZ31[J]. Materials Science Forum. 2021, 1016: 1003-1008.

Lee C D. Effect of Stress Ratio on Fatigue Life of A356 Aluminium Casting Alloys[J]. Journal of Materials Engineering and Performance. 2022(31-2).

Wei S A, Jl A, Xl B, et al. Fatigue crack growth rates of 10CrNi3MoV steel welded joints considering the stress ratio[J]. 2021.

LI Yang, YANG Ying, WANG Zhou. Study on fatigue crack propagation behaviour under different stress ratios[J]. Science and Technology Wind. 2020(27): 2.

WANG Gang, GAO Chen, WANG Shuyan, et al. Effect of frequency and stress ratio on fatigue properties of 18CrNiMo7-6 alloy steel[J]. Thermal Processing Technology. 2022, 51(2): 5.

Albedah A, Bouiadjra B B, Mohammed S, et al. Fractographic analysis of the overload effect on fatigue crack growth in 2024-T3 and 7075-T6 Al alloys[J]. . International Journal of Minerals, Metallurgy, and Materials. 2020, 27.

Yasuji O, Hiroshi N, Kenji H. Loading Frequency Effect on Fatigue Crack Growth Rate in Low Pressure Hydrogen Gas in the Case of A6061-T6 Aluminium Alloy [J]. Journal of Solid Mechanics and Materials Engineering. 2011, 5(11).

LU Minxu, ZHENG Xiulin. Influence of stress ratio and frequency on CF crack propagation characteristics of GC-4 steel [J]. Chinese Journal of Corrosion and Protection. 1994, 14(2): 95-105.

Qian Z, Takezono S, Tao K. Effect of loading frequency on fatigue crack growth under high temperature[J]. International Journal of Solids & Structures. 1996, 33(24): 3601-3610.

Yu-Huai H E, Guo W B, Duo-Kui Y U, et al. Effect of Loading Frequency on Fatigue Crack Growth of Direct Aging GH4169 Superalloy[J]. Failure Analysis and Prevention. 2008.

Kim B J, Lim B S. Effect of loading frequency on fatigue crack growth behaviour and microstructural damage in P92 HAZ[C]. 2007.

Fu Z H, Chen F, Gou G, et al. Effect of load frequency on corrosion fatigue crack growth behaviour of alloy 690(TT)[J]. Journal of Materials Heat Treatment. 2016, 37(02): 36-41.

Sharma M, Arora P, Singh P K, et al. Effect of Loading Frequency on the Fatigue Crack Growth Rate of Type 304L(N) Material[J]. 2018.

Liu Z, Li Y Ch, Wang C G, Wang Y, Liu Chong Y. Effect of load frequency and heat treatment on the fatigue crack expansion rate of die-cast magnesium alloy AZ91HP[J]. Journal of Aerospace Materials. 2000(01): 7-11.

Prakash R, Jayaram V, Saxena A. Advances in Structural Integrity || Effect of Loading Frequency on the Fatigue Crack Growth Rate of Type 304L(N) Material[J]. 2018, 10.1007/978-981-10-7197-3(Chapter 51): 611-622.

Yasniy P, Rudawska A, Iasnii V, et al. Methodology and some results of study of frequency and waveform effect on the fatigue crack growth resistance of heat-resistant steel[J]. 2017.

Yu Y, Sun W, Tong D. Effect of loading frequency on corrosion fatigue crack growth rate of 7N01 aluminium alloy[J]. IOP Conference Series: Materials Science and Engineering. 2020, 768(2): 22060-22065.

Lee J H, Lee H Y, Hong S G, et al. Fatigue crack growth behaviour of Mod.9Cr-1Mo steel at elevated temperatures: effect of temperature, loading frequency and R ratio[J]. Journal of Mechanical Science & Technology. 2017, 31(8): 3665-3669.

Fu Z, Wu P, Zhang Y, et al. Effects of hydrogen and loading frequency on the fatigue crack propagation behaviour of selective laser melted Inconel 718 alloy [J]. 2022.

Yang Q, Ning CY. Effect of diffused hydrogen in Q235 steel on its mechanical properties [C]. 2014.

Elboujdaini M, Hay M G, Saxena A, et al. Review of the effect of hydrogen on mechanical properties of low strength steels in oil and gas applications[J]. . Strength Fracture and Complexity. 2018, 11(2-3): 169-184.

Li Jiangli. Effect of hydrogen on mechanical properties of seamless steel pipes for petrochemical applications[J]. 2020.

Dobrotvorskii A M, Archakov Y I. Theoretical examination of the effect of hydrogen on the mechanical properties of iron[J]. Soviet Materials Science. 1989, 25(3): 231-235.

Zhang Yi-Wei, Gu Chao-Hua, Li Yan-Hua, et al. Effect of hydrogen on mechanical properties of X80 steel spiral welded pipes in coal to natural gas[J]. Pressure Vessel. 2020, 37(3): 8.

Ziquan Liu, Liu Ziquan, Fang He, et al. Hydrogen-induced delayed fracture behaviour of high-strength steel and its influence mechanism[C]. 2017.

Linchang Xiong, Xiong Lincang, Qingjun Zhou, et al. Study on hydrogen delayed fracture properties of several martensitic ultra-high strength steels for automotive applications[C]. 2017.

Liu X, Zhao X, Hui W, et al. Study on the Hydrogen-induced Delayed Fracture Behaviour of Ni-bearing High Strength Bolt Steel[J]. Shanghai Metals. 2018.

Wang J, Huang K, Dou L. The Experimental Study on the Influence of Hydrogen Corrosion on the Crack Growth Rate of 45 Steel[J]. Journal of Physics: Conference Series. 2021, 1965(1): 12124-12127.

Al-Daham S N, Nassar A A. Fatigue Crack Growth Analysis Using Finite Elements Method[J]. 1998.

Wormsen A, Fjeldstad A, Hrkegrd G. A post-processor for fatigue crack growth analysis based on a finite element stress field - ScienceDirect[J]. Computer Methods in Applied Mechanics & Engineering. 2008, 197(6-8): 834-845.

Su Shaopu, Dong Dengke, Zhang Haiying. Research on fatigue crack propagation analysis based on Abaqus/Python[J]. Science Technology and Engineering. 2015, 35(27): 6.

Zhou H. Research on fatigue crack propagation simulation method [D]. Wuhan University of Technology, 2015.

Liu Yang, Wang Zhongzheng. Fatigue crack propagation and life calculation based on finite element analysis[J]. Metal Products. 2022, 48(1): 4.

Gori Y, Verma R P, Kumar A, et al. FEA based fatigue crack growth analysis[J]. Materials Today: proceedings. 2021(4).

Wilde H D, Hannink M, Blom F J. Fatigue Failure Predictions Based on FEA Fracture Mechanics Simulations[C]. 2020.