Tube Expansion by Single Point Incremental Forming: An Experimental and Numerical Investigation

In this paper, we revisit the formability of tube expansion by single point incremental forming to account for the material strain hardening and the non-proportional loading paths that were not taken into consideration in a previously published analytical model of the process built upon a rigid perfectly plastic material. The objective is to provide a new insight on the reason why the critical strains at failure of tube expansion by single point incremental forming are far superior to those of conventional tube expansion by rigid tapered conical punches. For this purpose, we replaced the stress triaxiality ratio that is responsible for the accumulation of damage and cracking by tension in monotonic, proportional loading paths, by integral forms of the stress triaxiality ratio that are more adequate for the non-proportional paths resulting from the loading and unloading cycles of incremental tube expansion. Experimental and numerical simulation results plotted in the effective strain vs. stress triaxiality space confirm the validity of the new damage accumulation approach for handling the non-proportional loading paths that oscillate cyclically from shearing to biaxial stretching, as the single point hemispherical tool approaches, contacts and moves away from a specific location of the incrementally expanded tube surface.

[1]  A. H. Shabaik,et al.  A New Workability Criterion for Ductile Metals , 1986 .

[2]  Zhongqin Lin,et al.  A theoretical and experimental study on forming limit diagram for a seamed tube hydroforming , 2011 .

[3]  A. J. Martínez-Donaire,et al.  Analysis of the influence of stress triaxiality on formability of hole-flanging by single-stage SPIF , 2019, International Journal of Mechanical Sciences.

[4]  Stuart P. Keeler,et al.  Circular Grid System — A Valuable Aid for Evaluating Sheet Metal Formability , 1968 .

[5]  Gorton M. Goodwin,et al.  Application of Strain Analysis to Sheet Metal Forming Problems in the Press Shop , 1968 .

[6]  A. J. Martínez-Donaire,et al.  Stretch-flanging of AA2024-T3 sheet by single-stage SPIF , 2021 .

[7]  P. Martins,et al.  Towards the characterization of fracture in thin-walled tube forming , 2016 .

[8]  Chen Yang,et al.  Characterization of deformation behavior of thin-walled tubes during incremental forming: a study with selected examples , 2015 .

[9]  J. P. Magrinho,et al.  Theory of single point incremental forming of tubes , 2020 .

[10]  A. Atkins Fracture in forming , 1996 .

[11]  A. J. Martínez-Donaire,et al.  Novel experimental techniques for the determination of the forming limits at necking and fracture , 2015 .

[12]  P. Martins,et al.  Formability limits by fracture in sheet metal forming , 2014 .

[13]  F. A. McClintock,et al.  A Criterion for Ductile Fracture by the Growth of Holes , 1968 .

[14]  P. Martins,et al.  On the determination of forming limits in thin-walled tubes , 2019, International Journal of Mechanical Sciences.

[15]  M. Elyasi,et al.  An investigation on flaring process of thin-walled tubes using multistage single point incremental forming , 2018 .

[16]  Paulo A.F. Martins,et al.  Characterization of fracture loci in metal forming , 2014 .

[17]  Mohammad Javad Mirnia,et al.  Numerical prediction of failure in single point incremental forming using a phenomenological ductile fracture criterion , 2017 .

[18]  M. Brünig,et al.  Damage and failure at negative stress triaxialities: Experiments, modeling and numerical simulations , 2017 .

[19]  David J. Meuleman,et al.  Analytical and Experimental Examination of Tubular Hydroforming Limits , 1998 .

[20]  A. J. Martínez-Donaire,et al.  New approaches to detect the onset of localised necking in sheets under through-thickness strain gradients , 2014 .

[21]  J. P. Magrinho,et al.  A digital image correlation based methodology to characterize formability in tube forming , 2019, The Journal of Strain Analysis for Engineering Design.

[22]  C. Vallellano,et al.  On the formability limits of thin-walled tube inversion using different die fillet radii , 2019, Thin-Walled Structures.

[23]  G. Centeno,et al.  Revisiting Formability and Failure of AISI304 Sheets in SPIF: Experimental Approach and Numerical Validation , 2017 .

[24]  J. P. Magrinho,et al.  On the Characterization of Fracture Loci in Thin-Walled Tube Forming , 2021, Forming the Future.

[25]  M. L. Garcia-Romeu,et al.  Experimental and numerical analysis of innovative processes for producing a resorbable cheekbone prosthesis , 2021 .