Analysis of quenching stresses in 35CrMo axle

Hai Gong , Yunxin Wu , Xiaolei Feng , Yihua Li

Journal of Wuhan University of Technology Materials Science Edition ›› 2016, Vol. 31 ›› Issue (3) : 630 -635.

PDF
Journal of Wuhan University of Technology Materials Science Edition ›› 2016, Vol. 31 ›› Issue (3) : 630 -635. DOI: 10.1007/s11595-016-1421-9
Metallic Materials

Analysis of quenching stresses in 35CrMo axle

Author information +
History +
PDF

Abstract

By using the finite element method (FEM), we comprehensively analyzed the fields of temperature, organization, and stress in 35CrMo train axles during the quenching process is conducted, and experimentally studied the formation and evolution of inner stresses in axles during the quenching process. The results show that in the quenching process, stresses on the axle surface change from tensile to compressive gradually, while stresses in the axle core change from compressive to tensile gradually. Heat stresses and the amount of martensitic transformation are all increased with the increase of cooling rate. As a result, the maximum instantaneous stresses in the axle are increased greatly when the cooling rate is increased with brine quenching. Large instantaneous tensile stress in the axle core with brine quenching is very likely to cause quench cracking and should be avoided.

Keywords

35CrMo axle / quenching / residual stress / FEM / X-ray diffraction

Cite this article

Download citation ▾
Hai Gong, Yunxin Wu, Xiaolei Feng, Yihua Li. Analysis of quenching stresses in 35CrMo axle. Journal of Wuhan University of Technology Materials Science Edition, 2016, 31(3): 630-635 DOI:10.1007/s11595-016-1421-9

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Arimoto K, Yamanaka S, Michiharu N, et al. Explanation of the Origin of Quench Distortion and Residual Stress in Specimens using Computer Simulation[J]. Microstructure and Materials Properties, 2009, 4(2): 168-186.

[2]

Lingamanaik S N, Chen B K. Microstructure and Thermo-mechanical Analysis of Quench Cracking during the Production of Bainiticmartensitic Railway Wheels[J]. Engineering Failure Analysis, 2014, 40: 25-32.

[3]

Liu G W. Forging and Heat Treatment Technology Study of EA4T Material[J]. Forging and Stamping Technology, 2010, 35(1): 162-164.
[4]

Schleinzer G, Fischer F D. Residual Stresses in New Rails[J]. Materials Science and Engineering, 2008, A288: 281.
[5]

Chen Z L, Lu D X, Cao M Y, et al. Study on Residual Stress and Crack Failure in Metal Heat Treatment[J]. Heat Treatment of Metal, 2007, 32: 40-44.
[6]

Makino T, Kato T, Hirakawa K. Review of the Fatigue Damage Tolerance of High-speed Railway Axles in Japan[J]. Engineering Fracture Mechanics, 2011, 78: 810-825.

[7]

Beretta S, Ghidini A, Lombardo F. Fracture Mechanics and Scale Effect in the Fatigue of Railway Axles[J]. Engineering Fracture Mechanics, 2005, 72: 195-208.

[8]

Kumar B R, Bhattacharya D K, Das S K, et al. Premature Fatigue of a Spring due to Quench Cracks[J]. Engineering Failure Analysis, 2000, 7(6): 377-384.

[9]

Mukhopadhyay N K, Das S K, Ravikumar B, et al. Premature Failure of a Leaf Spring due to Improper Materials Processing[J]. Engineering Failure Analysis, 1997, 4(3): 161-170.

[10]

Davide G. Finite Element Prediction of Crack Formation Induced by Quenching in a Forged Valve[J]. Engineering Failure Analysis, 2011, 18: 2250-2259.

[11]

Li H P, Zhao G Q, He L F. Finite Element Method Based Simulation of Stress-strain Field in the Quenching Process[J]. Materials Engineering A, 2008, 478(1-2): 276-290.

[12]

He L F, Li H P, Zhao G Q. FEM Simulation of Temperature, Phasetransformation and Stress/strain in Quenching Process[J]. Transactions of Materials and Heat Treatment, 2011, 32(1): 128-133.
[13]

Momeni A, Abbasi S M, Badri H. Hot Deformation Behavior and Constitutive Modeling of VCN200 Low Alloy Steel[J]. Applied Mathematical Modeling, 2012, 36: 5624-5632.

[14]

Wang G C, Pan Z F, Fei H J, et al. Numerical Simulation of Grind Hardening of 40Cr Steel for Two Passes Grinding[J]. Transactions of Materials and Heat Treatment, 2009, 30(3): 198-202.
[15]

Yuan S Y, Zhang L W, Zhang G L, et al. Numerical Simulation and Experimental Validation of Large Forging during Quenching Process[J]. Journal of Dalian University of Technology, 2005, 45(4): 547-551.
[16]

Wang M G, Zhang T J, Yang F Z, et al. Numerical Simulation Quenching Process of Cylindrical 20CrMnMo Steel Specimen[J]. Transactions of Materials and Heat Treatment, 2013, 34: 258-261.
[17]

Li Y H. Research on Axle Stress Evolution during Forging and Residual Stress during Heat Treating[D], 2013 Changsha: Central South University.
[18]

Sun J T. Axis Class Forging Heat Treatment Craft Simulation and Experimental Study[D], 2008 Qinhuangdao: Yanshan University.
[19]

Miya S. Production and Countermeasure of Residual Stress[M], 1983 Beijing: China Machine Press.
[20]

Yuan F R, Wu S L. Residual Stress Measurement and Calculation[M], 1987 Changsha: Hunan University Press.
AI Summary AI Mindmap
PDF

102

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/