Abstract
Multistage forming is usually adopted to form those parts which have steep angles or even vertical walls during incremental sheet forming (ISF) process. In order to study the multistage incremental forming further, based on a finite element method model which was experimentally verified, different forming strategies were adopted to form a frustum of cone with a wall angle of 30° to research the influence of the number of forming stages (n) and the incremental wall angle between the two adjacent stages (∆α) on the formability of ISF. The simulation results including the thickness distribution, the equivalent plastic strain, and the magnitude of springback were analyzed in detail. It was found that with the growth of n, the minimum thickness increases largely, and more uniform thickness distribution is achieved, but the quantity of springback becomes larger in contrast with a single-pass process because of the accumulation of springback during each forming stage. Furthermore, an expression to figure out the appropriate value of n was given. In addition, the maximum thickness reduction decreases initially and then increases as the value of ∆α grows. Meanwhile, it indicates that there is no relation between ∆α and the quantity of springback.
Similar content being viewed by others
References
Jeswiet J, Micari F, Hirt G, Bramley A, Duflou J, Allwood J (2005) Asymmetric single point incremental forming of sheet metal. CIRP Ann Manuf Technol 54(2):623–649
Malhotra R, Reddy NV, Cao J (2010) Automatic helical toolpath generation for single point incremental forming. J Manuf Sci E-T ASME 132(6):98–101
Jackson KR, Allwood JM, Landert M (2008) Incremental forming of sandwich panels. J Mater Process Technol 204(1–3):290–303
Micari F, Ambrogi G, Filice L (2007) Shape and dimensional accuracy in single point incremental forming: state of the art and future trends. J Mater Process Technol 191(1):390–395
Bambach M, Taleb Araghi B, Hirt G (2009) Strategies to improve the geometric accuracy in asymmetric single point incremental forming. Prod Eng Res Devel 3(2):145–156
Hagan E, Jeswiet J (2003) A review of conventional and modern single-point sheet metal forming methods. Proc I Mech E Part B J Eng Manuf 217(2):213–225
Kim Y, Park J (2002) Effect of process parameters on formability in incremental forming of sheet metal. J Mater Process Technol 130(20):42–46
Iseki H (2001) An approximate deformation, analysis and FEM analysis for the incremental bulging of sheet metal using a spherical roller. J Mater Process Technol 111(1–3):150–154
Malhotra R, Bhattacharya A, Kumar A, Reddy NV, Cao J (2011) A new methodology for multi-pass single point incremental forming with mixed toolpaths. CIRP Ann Manuf Technol 60(1):323–326
Ales P, Karl K (2012) Backward hole-flanging technology using an incremental approach. J Mech Eng 58(2):73–80
Verbert J, Belkassem B, Henrard C (2008) Multi-Step toolpath approach to overcome forming limitations in single point incremental forming. Int J Mater Form 1(1):1203–1206
Skjoedt M, Bay N, Endelt B, Ingarao G (2008) Multistage strategies for single point incremental forming of a cup. Int J Mater Form 1(s1):1199–1202
Kim TJ, Yang DY (2000) Improvement of formability for the incremental sheet metal forming process. Int J Mech Sci 42(7):1271–1286
Li J, Hu J, Pan J, Geng P (2012) Thickness distribution and design of a multi-stage process for sheet metal incremental forming. Int J Adv Manuf Technol 62:981–988
Ma LW, Mo JH (2008) Three-dimensional finite element method simulation of sheet metal single-point incremental forming and the deformation pattern analysis. Proc I Mech E Part B J Eng Manuf 222(3):373–380
Kitazawa K, Okaku H (1996) Possibility of CNC incremental stretch-expanding of sheet metal by single-tool-path process. Nippon Kikai Gakkai Ronbunshu 62(597):2012–2017
Young D, Jeswiet J (2004) Wall thickness variations in single-point incremental forming. Proc I Mech E Part B J Eng Manuf 218(11):1453–1459
Silva MB, Nielsen PS, Bay N, Martins PAF (2011) Failure mechanisms in single-point incremental forming of metals. Int J Adv Manuf Technol 56:893–903
Zhu H, Liu Z, Fu J (2011) Spiral tool-path generation with constant scallop height for sheet metal CNC incremental forming. Int J Adv Manuf Technol 54:911–919
Han F, Mo J (2008) Numerical simulation and experimental investigation of incremental sheet forming process. J Cent South Univ T 15(5):581–587
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Li, J., Geng, P. & Shen, J. Numerical simulation and experimental investigation of multistage incremental sheet forming. Int J Adv Manuf Technol 68, 2637–2644 (2013). https://doi.org/10.1007/s00170-013-4870-8
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00170-013-4870-8