Abstract
Laminated shafts are often used as alternatives to elemental metal shafts, which are prone to corrosion and wear. However, manufacturing laminated shafts is difficult. In this paper, a laminated shaft production method involving cross-wedge rolling was proposed. The cross-wedge rolling of 42CrMo/Q235 laminated shafts was numerically simulated using ANSYS/LS-DYNA software. The deformation characteristics and stress distribution laws of the 42CrMo/Q235 laminated shafts in the knifing zone and stretching zones were obtained. The formation mechanisms of the stress distributions were analyzed, and the theoretical significance of the interface bonding on the cross-wedge-rolled 42CrMo/Q235 laminated shafts was discussed. Furthermore, the feasibility of 42CrMo/Q235 laminated shaft production via cross-wedge rolling was validated. Theoretical foundations were also provided for use in future studies concerning the rolling lamination mechanisms of dissimilar-metal laminated shafts.
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References
Liu S, Yue ZW, Ma CH (2011) Fracture analysis on the input shaft of coal pulverize reducer of 350 MW supercritical unit. Phys Exam Test 29(5):36–39 (in Chinese)
Rojo I, Psarra A, Pachidis V, Pilidis P (2010) Evaluation of the energy dissipated as friction/heat between turbines following shaft failure. Proceedings of the ASME Turbo Expo (6): 1345–1352 (in Chinese)
Zhang XY, Fu CA, Huang QS (2009) Losing efficiency analysis and improved design of broken shaft of vibration reducer on a certain aircraft. Aircr Des 29(5):28–31 (in Chinese)
Cassada W, Liu J, Staley J (2002) Aluminum alloys for aircraft structures. Adv Mater Process 160(12):27–29
Jiang Y, Yin ZD, Zhu JC, Li MW (2004) Development of ultra-high strength maraging steel. Special Steel 25(2):1–5 (in Chinese)
Chen YX, Liang XB, Shuang JC, Xu BS (2013) Analysis of FEA of residual stress for thermal sprayed coating on shaft parts. Trans Chin Weld Institut 34(6):13–16
Yahiro A, Masui T, Yoshida T, Doi D (1991) Development of nonferrous clad plate and sheet by warm rolling with different temperature of materials. ISIJ Int 31(6):647–654
Seok LK, Hyun YD, Kyoung KH (2012) Effect of annealing on the interface microstructure and mechanical properties of a STS-Al-Mg 3-ply clad sheet. Mater Sci Eng A 556:319–330
Luo YB, Liu XH, Xie JX (2009) Lateral spreading deformation behavior in flat rolling of copper cladding aluminum composite rods. Chin J Nonferrous Metal 19(11):1976–1981
Li DJ, Wang HK, Yi Z (2004) Heating effect on bonding strength of Ti/Cu cladding bar by pass rolling. Met Form Technol 22(1):46–48 (in Chinese)
Zbigniew P, Andrzej G, Arkadiusz T (2011) Analysis of the cross-wedge rolling process of toothed shafts made from 2618 aluminium alloy. J Shanghai Jiaotong Univ 16(2):162–166
Bartnicki J, Pater Z (2005) Numerical simulation of three-rolls cross wedge rolling of hollowed shaft. J Mater Process Technol 164–165:1154–1159
Pater Z (2006) Finite element analysis of cross wedge rolling. J Mater Process Technol 173:201–208
Pater Z (2000) Theoretical and experiment analysis of cross wedge rolling process. Int J Mach Tools Manuf 40:49–60
Pater Z (1999) Numerical simulation of the cross wedge rolling process including upsetting. J Mater Process Technol 92–93:468–473
Peng WF, Zhang KS, Jia Z, Hu ZH (2010) Analysis on finite element model of cross wedge rolling asymmetric shaft-parts. J Plastic Eng 17(2):79–83 (in Chinese)
Matveev AV, Safonov AS, Medvedev VE (2002) Modern equipment and technology of billets cross-wedge rolling of machine-building components. Tyazheloe Mashinostroenie 5:12–15
Li Q, Lovell MR (2008) Cross wedge rolling failure mechanism and industrial application. Int J Adv Manuf Technol 37:265–278
Li Q, Lovell MR (2002) Predicting critical friction in a two-roll cross wedge rolling process. J Tribol 125:200–203
Li Q, Lovell MR (2004) The establishment of a failure criterion in cross wedge rolling. Int J Adv Manuf Technol 24:180–189
Li Q, Lovell MR (2005) On the critical interfacial friction of a two roll CWR process. J Mater Process Technol 160:245–256
Zhou J, Chuan X, Ying YY, Jia Z (2013) Influence of tool parameters on tool wear in two-roll cross-wedge roll. Int J Adv Manuf Technol 65:745–753
Zhang N, Wang BY, Hu ZH (2011) Thermomechanical coupled numerical simulation of GH4169 alloy for cross wedge rolling. J Univ Sci Technol Beijing 33(11):1396–1401
Ji HC, Liu JP, Wang BY, Zheng ZH, Huang JH, Hu ZH (2015) Cross-wedge rolling of a 4Cr9Si2 hollow valve: explorative experiment and finite element simulation. Int J Adv Manuf Technol 77:15–26
Wang MT, Li XT, Du FS (2005) A coupled thermal–mechanical and microstructural simulation of the cross wedge rolling process and experimental verification. Mater Sci Eng A 391:305–312
Silva MLN, Pires GH, Button ST (2011) Damage evolution during cross wedge rolling of steel DIN 38MnSiVS5. 11th Int Conf Mech Behav Mat 10:752–757
Shu Xuedao, Valery Ya.Shchukin, G.Kozhevnikova, Sun Baoshou, Peng Wenfei (2014) The theory and forming technology of cross wedge rolling. Publ House Science Beijing
Hu ZH, Zhang KS, Wang BY, Shu XD (2004) Formed technology and simulation of parts about the cross-wedge rolling. Publ House Metall Ind Beijing
Zhou JH, Guan KZ, Liu J, Liu WH (1991) An mathematical model of flow stress for hot strip mill. J Univ Sci Technol Beijing 13(1):20–25
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Peng, W.F., Zhang, J.H., Huang, G.X. et al. Stress distributions during the cross-wedge rolling of composite 42CrMo/Q235 laminated shafts. Int J Adv Manuf Technol 83, 145–155 (2016). https://doi.org/10.1007/s00170-015-7541-0
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DOI: https://doi.org/10.1007/s00170-015-7541-0