Effect of process parameters on product surface finish and thickness variation in hydro-mechanical deep drawing

Journal of Materials Processing Technology

Volumn 204, Issue 1-3, 2008, Pages 169-178

  Singh, Swadesh Kumar ^a   Ravi Kumar, D ^b  

^a GOKARAJU RANGARAJU INSTITUTE OF ENGINEERING AND TECHNOLOGY   (India)

^b INDIAN INSTITUTE OF TECHNOLOGY DELHI   (India)

Author keywords

Conventional deep drawing; Cutoff pressure; Hydro mechanical deep drawing; Pre bulging pressure; Surface finish; Thickness distribution

Indexed keywords

DEEP DRAWING; HYDROFORMYLATION; PARAMETER ESTIMATION; PROCESS CONTROL;

CONVENTIONAL DEEP DRAWING; CUTOFF PRESSURE; HYDRO-MECHANICAL DEEP DRAWING; PRE-BULGING PRESSURE; SURFACE FINISH; THICKNESS DISTRIBUTION;

SURFACE TREATMENT;

EID: 44649105982     PISSN: 09240136     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.jmatprotec.2007.11.060     Document Type: Article

References (16)

1. Amino H., Nakamura K., and Nakagawa T. Counter-pressure deep drawing and its application in the forming and automobile parts. J. Mater. Process. Technol. 23 (1990) 243-265
2. El-Sebaie M.G., and Mellor P.B. Pressure assisted deep drawing. Ann. CIRP 22 1 (1973) 71-72
3. Karpenko Yu.A., and Akai A. A numerical model of friction between rough surfaces. Tribol. Int. 34 (2001) 531-545
4. Kim J., Son B.M., Kang B.S., Hwang S.M., and Park H.J. Comparison stamping and hydro-mechanical forming process for an automobile fuel tank using finite element method". J. Mater. Process. Technol. 153/154 (2004) 550-557
5. Lee B.H., Keum Y.T., and Wagoner R.H. Modelling of the friction caused by lubrication and surface roughness in sheet metal forming. J. Mater. Process. Technol. 130/131 (2002) 60-63
6. Nakagawa T., Nakamura K., and Amino H. Various applications of hydraulic counter pressure deep drawing. J. Mater. Process. Technol. 71 (1997) 160-167
7. Palumbo G., Pinto S., and Tricarico L. Numerical/experimental analysis of the sheet hydro forming process using cylindrical, square and compound shaped cavities. J. Mater. Process. Technol. 155/156 (2004) 1435-1442
8. Plevy T.A.H. The role of friction in metal working with particular reference to energy saving in deep drawing. Wear 58 (1980) 359-380
9. Shima H., and Yang D.Y. A simple method to determine pressure curve for sheet hydro-forming and experimental verification. J. Mater. Process. Technol. 169 (2005) 134-142
10. Singh S.K., and Kumar D.R. A comparison of different neural network training algorithms for hydro-mechanical deep drawing. Int. J. Mater. Product Technol. 21 1/2 (2004)
11. Singh S.K., and Kumar D.R. Numerical prediction of the limiting draw ratio and thickness strains for EDD steel sheet in hydro-mechanical deep drawing. Int. J. Mater. Product Technol. 21 1/2 (2004)
12. Wilson W.R.D. Friction models for metal forming in the boundary lubricant regime. J. Eng. Mater. Technol. 113 (1991) 60-68
13. Yossifon S., and Tirosh J. Buckling prevention by lateral fluid pressure in deep drawing. Int. J. Mech. Sci. 27 3 (1985) 177-185
14. Yossifon S., and Tirosh J. Deep drawing with a fluid pressure assisted blank holder. Proc. Inst. Mech. Eng. 206 (1992) 247-252
15. Zhang S.H., and Danckert J. Development of hydro-mechanical deep drawing. J. Mater. Process. Technol. 83 (1998) 14-25
16. Zhang S.H., Jensen M.R., Nielsen K.B., Danckert J., Lang L.H., and Kang D.C. Effect of anisotropy and prebulging on hydromechanical deep drawing of mild steel cups. J. Mater. Process. Technol. 142 2 (2003) 544-550