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International Journal of Material Forming

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25-04-2016 | Original Research

Inverse identification of the Swift law parameters using the bulge test

Authors: L. C. Reis, P. A. Prates, M. C. Oliveira, A. D. Santos, J. V. Fernandes

Published in: International Journal of Material Forming | Issue 4/2017

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Abstract

An inverse methodology is proposed for determining the work hardening law of metal sheets, from the results of pressure vs. pole height, obtained from the bulge test. This involves the identification of the parameters of the Swift law. The influence of these parameters as well as the sheet anisotropy and the sheet thickness on the results of pressure with pole height is studied following a forward analysis, based on finite element simulation. This allows understanding that the overlapping of the pressure vs. pole height curves of different metal sheets is possible, provided that the hardening coefficient has the same value, whatever the values of the remaining parameters of the Swift law, the sheet anisotropy and the initial sheet thickness. The overlapping of the curves is performed by multiplying the values of the pressure and the pole height using appropriate factors, which depend on the ratios between the yield stresses and the thicknesses of the sheets, and also on their anisotropy. Afterwards, an inverse methodology is established, consisting of the search for the best coincidence between pressure vs. pole height of experimental and reference curves, the latter being obtained by numerical simulation assuming isotropic behaviour with various values of the Swift hardening coefficient in the range of the material under study. This methodology is compared with a classical strategy and proves to be an efficient alternative for determining the parameters of the Swift law. It aims to be simple from an experimental point of view and, for that purpose, only uses results of the load evolution during the test. The methodology is limited to materials with the hardening behaviour adequately described by the Swift law.

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DIN EN ISO 16808:2014–11 (E) (2014) Metallic materials - sheet and strip - Determination of biaxial stress–strain curve by means of bulge test with optical measuring systems. BSI

Mulder J, Vegter H, Aretz H, van den Boogaard AH (2013) Accurate evaluation method for the hydraulic bulge test. Key Eng Mater 554–557:33–40. doi:10.4028/www.scientific.net/KEM.554-557.33 CrossRef

Keller S, Hotz W, Friebe F (2009) Yield curve determination using bulge test combined with optical measurements. In: Levy BS, Matlock DK, Van Tyne CJ (eds) Int. Deep Draw. Res. Gr. Conf. IDDRG. IDDRG, Golden, Colorado, pp 319–330

Mulder J, Vegter H, Aretz H et al (2015) Accurate determination of flow curves using the bulge test with optical measuring systems. J Mater Process Technol 226:169–187. doi:10.1016/j.jmatprotec.2015.06.034 CrossRef

Liu K, Lang L, Cai G et al (2015) A novel approach to determine plastic hardening curves of AA7075 sheet utilizing hydraulic bulging test at elevated temperature. Int J Mech Sci 100:328–338. doi:10.1016/j.ijmecsci.2015.07.002 CrossRef

Atkinson M (1997) Accurate determination of biaxial stress—strain relationships from hydraulic bulging tests of sheet metals. Int J Mech Sci 39:761–769. doi:10.1016/S0020-7403(96)00093-8 CrossRef

Hill R (1950) C. A theory of the plastic bulging of a metal diaphragm by lateral pressure. London Edinburgh Dublin Philos Mag J Sci 41:1133–1142. doi:10.1080/14786445008561154 MathSciNetCrossRefMATH

Smith LM, Hadad Y, Thotakura R, et al. (2007) Flow stress curves using new volume measurement method for hydraulic bulge test. In: AIP Conf. Proc. AIP, Porto, Portugal, pp 637–642

Chakrabarty J, Alexander JM (1970) Hydrostatic bulging of circular diaphragms. J Strain Anal Eng Des 5:155–161. doi:10.1243/03093247V053155 CrossRef

10.

Slota J, Spišák E (2008) Determination of flow stress by the hydraulic bulge test. Metalurgija 47:13–17

11.

Panknin W (1970) The hydraulic bulge test and the determination of the flow stress curves. University of Stuttgart

12.

Chamekh A, BelHadjSalah H, Hambli R, Gahbiche A (2006) Inverse identification using the bulge test and artificial neural networks. J Mater Process Technol 177:307–310. doi:10.1016/j.jmatprotec.2006.03.214 CrossRef

13.

Ludwik P (1909) Elemente der Technologischen Mechanik. doi: 10.1007/978-3-662-40293-1

14.

Bambach M (2011) Comparison of the identifiability of flow curves from the hydraulic bulge test by membrane theory and inverse analysis. Key Eng Mater 473:360–367. doi:10.4028/www.scientific.net/KEM.473.360 CrossRef

15.

Voce E (1948) The relationship between stress and strain for homogeneous deformations. J Inst Met 74:537–562

16.

Swift HW (1952) Plastic instability under plane stress. J Mech Phys Solids 1:1–18. doi:10.1016/0022-5096(52)90002-1 CrossRef

17.

Santos AD, Teixeira P, Barata da Rocha A, et al (2010) On the determination of flow stress using bulge test and mechanical measurement. In: Barlat F, Moon YH, Lee MG (eds) 10th Int. Conf. NUMIFORM. American Institute of Physics, Pohang, Republic of Korea, pp 845–852

18.

Alves JL (2005) Drawbeads: to Be or Not to Be. In: AIP Conf. Proc. AIP, pp 655–660

19.

Alves JL (2003) Simulação numérica do processo de estampagem de chapas metálicas: Modelação mecânica e métodos numéricos. Universidade do Minho

20.

Menezes LF, Teodosiu C (2000) Three-dimensional numerical simulation of the deep-drawing process using solid finite elements. J Mater Process Technol 97:100–106. doi:10.1016/S0924-0136(99)00345-3 CrossRef

21.

Oliveira MC, Alves JL, Menezes LF (2008) Algorithms and strategies for treatment of large deformation frictional contact in the numerical simulation of deep drawing process. Arch Comput Methods Eng 15:113–162. doi:10.1007/s11831-008-9018-x MathSciNetCrossRefMATH

22.

Reis LC, Prates PA, Oliveira MC, et al. (2011) Caracterização do comportamento plástico de chapas metálicas com recurso ao ensaio de expansão biaxial simétrica. In: Tadeu A, Figueiredo IN, Menezes LF, et al. (eds) Congr. Métodos Numéricos em Eng. APMTAC, Coimbra, Portugal, p 54

23.

Reis LC, Rodrigues CA, Oliveira MC, et al (2012) Characterization of the plastic behaviour of sheet metal using the hydraulic bulge test. In: Andrade-Campos A, Lopes N, Valente RAF, Varum H (eds) First ECCOMAS Young Investig. Conf. Comput. Methods Appl. Sci. Aveiro, Portugal, p 67

24.

Rodrigues CA, Reis LC, Sakharova NA, et al (2012) On the characterization of the plastic behaviour of sheet metals with bulge tests: numerical simulation study. In: Eberhardsteiner J. et al. (ed) 6th Eur. Congr. Comput. Methods Appl. Sci. Eng. ECCOMAS. ECCOMAS 2012, Vienna, Austria, pp 4575–4589

25.

Hill R (1948) A theory of the yielding and plastic flow of anisotropic metals. Proc R Soc A Math Phys Eng Sci 193:281–297. doi:10.1098/rspa.1948.0045 MathSciNetCrossRefMATH

26.

Prates PA, Oliveira MC, Fernandes JV (2015) On the equivalence between sets of parameters of the yield criterion and the isotropic and kinematic hardening laws. Int J Mater Form 8:505–515. doi:10.1007/s12289-014-1173-z CrossRef

27.

Santos AD, Teixeira P, Barlat F (2011) Flow stress determination using hydraulic bulge test and a mechanical measurement system. In: Int. Deep Draw. Res. Gr. Conf. IDDRG. IDDRG, Bilbao, Spain, pp 91–100

28.

Chaparro BM (2006) Comportamento plástico de materiais metálicos: identificação e optimização de parâmetros. Universidade de Coimbra

29.

Cazacu O, Barlat F (2001) Generalization of Drucker’s yield criterion to orthotropy. Math Mech Solids 6:613–630. doi:10.1177/108128650100600603 CrossRefMATH

30.

Drucker DC (1949) Relation of experiments to mathematical theories of plasticity. J Appl Mech ASME 16:349–357MathSciNetMATH

31.

Barlat F, Aretz H, Yoon JW et al (2005) Linear transfomation-based anisotropic yield functions. Int J Plast 21:1009–1039. doi:10.1016/j.ijplas.2004.06.004 CrossRefMATH

Title: Inverse identification of the Swift law parameters using the bulge test
Authors: L. C. Reis
P. A. Prates
M. C. Oliveira
A. D. Santos
J. V. Fernandes
Publication date: 25-04-2016
Publisher: Springer Paris
Published in: International Journal of Material Forming / Issue 4/2017
Print ISSN: 1960-6206
Electronic ISSN: 1960-6214
DOI: https://doi.org/10.1007/s12289-016-1296-5

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