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Experimental Mechanics

Erschienen in:

27.04.2018

Identification of Heterogeneous Elastoplastic Behaviors Using the Constitutive Equation Gap Method

verfasst von: T. Madani, Y. Monerie, S. Pagano, C. Pelissou, B. Wattrisse

Erschienen in: Experimental Mechanics | Ausgabe 6/2018

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Abstract

Recent developments in imaging techniques now facilitate local field measurements (e.g. strain, temperature, etc.). In this study, we identify the spatial distribution of material properties and local stress fields using an inverse identification method based on the constitutive equation gap (CEG). The CEG concept is based both on minimization of a cost function equal to the sum of the potential and complementary energies, and on the deviation between the measured and computed strain fields. We propose a new approach for identifying heterogeneous property fields (mechanical parameters and stress) using a secant elastoplastic tensor and a measured strain field obtained by full-field measurement. The reliability of the method is checked using finite element simulation data as reference full-field measurements. The method is then applied on noisy displacement fields to assess its robustness. Finally, the developed inverse method is tested on real measured data.

Vorheriger Artikel Simulation of Pipe-Manufacturing Processes Using Sheet Bending-Flattening

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Wattrisse B, Chrysochoos A, Muracciole J-M, Nemoz-Gaillard M (2001) Analysis of strain localization during tensile tests by digital image correlation. Exp Mech 41:29–39CrossRefMATH

Grédiac M (2004) The use of full-field measurement methods in composite material characterization: interest and limitations. Composites Part A: Appl Sci Manufac 35:751–761CrossRef

Chalal H, Avril S, Pierron F, Meraghni F (2006) Experimental identification of a nonlinear model for composites using the grid technique coupled to the virtual fields method. Composites Part A: Appl Sci Manufac 37(2):315–325CrossRef

Avril S, Pierron F (2007) General framework for the identification of constitutive parameters from full-field measurements in linear elasticity. Int J Solids Struct 44(14–15):4978–5002CrossRefMATH

Rossi M, Pierron F (2012) On the use of simulated experiments in designing tests for material characterization from full-field measurements. Int J Solids Struct 49(3–4):420–435CrossRef

Avril S, Bonnet M, Bretelle A-S, Grédiac M, Hild F, Ienny P, Latourte F, Lemosse D, Pagano S, Pagnacco E, Pierron F (2008) Overview of identification methods of mechanical parameters based on full-field measurements. Experiment Mech 48(4):381–402CrossRef

Kavanagh KT, Clough RW (1971) Finite element applications in the characterization of elastic solids. Int J Solids Struct 7:11–23CrossRefMATH

Meuwissen MHH, Oomens CWJ, Baaijens FPT, Petterson R, Janssen JD (1998) Determination of the elasto-plastic properties of aluminum using a mixed numerical-experimental method. J Mater Process Technol 75(1-3):204211CrossRef

Cooreman S, Lecompte D, Sol H, Vantomme J, Debruyne D (2008) Identification of mechanical material behavior through inverse modeling and DIC. Exp Mech 48(4):421–433CrossRefMATH

10.

Passieux J-C, Bugarin F., David C., Périé J-N and Robert L., Multiscale displacement field measurementusing digital image correlation: application to the identification of elastic properties. Experiment Mech, volume: 55, Issue: 1, Pages: 121-137, 2015

11.

Mathieu F., Leclerc H., Hild F. and Roux S., Estimation of elastoplastic parameters via weighted FEMU and integrated-DIC. Experiment Mech, volume: 55, Issue: 1, Pages: 105-119, 2015

12.

Guery A, Hild F, Latourte F, Roux S (2016) Identification of crystal plasticity parameters using DIC measurements and weighted FEMU. Mech Mater 100:55–71CrossRef

13.

Siddiqui M, Khan SZ, Khan MA, ShahzadK M, Khan KA, Nisar S, Noman D (2017) A projected finite element update method for inverse identification of material constitutive parameters in transversely isotropic laminates. Experiment Mech 57(5):755–772CrossRef

14.

Bui HD, Constantinescu A, Maigre H (2004) Numerical identification of linear cracks in 2D elastodynamics using the instantaneous reciprocity gap. Inverse Problems 20:993–1001MathSciNetCrossRefMATH

15.

Sun Y, Guo Y, Ma F (2016) The reciprocity gap functional method for the inverse scattering problem for cavities. Appl Anal 95(6):1327–1346MathSciNetCrossRefMATH

16.

Feissel P, Allix O (2007) Modified constitutive relation error identification strategy for transient dynamics with corrupted data: the elastic case. Comput Eng Appl Mech Eng 196:1968–1983CrossRefMATH

17.

Florentin E, Lubineau G (2011) Using constitutive equation gap method for identification of elastic material parameters: technical insights and illustrations. Int J Interact Design Manufac (IJIDeM) 5(4):227–234CrossRef

18.

Merzouki T, Nouri H, Roger F (2014) Direct identification of nonlinear damage behavior of composite materials using the constitutive equation gap method. Int J Mech Sci 89:487–499CrossRef

19.

Grédiac M, Toussaint E, Pierron F (2002) Special virtual fields for the direct determination of material parameters with the virtual fields method.1 - Principle and definition. Int J Solids Struct 39:2691–2705CrossRefMATH

20.

Grédiac M, Pierron F (2006) Applying the virtual field method to the identification of elasto-plastic constitutive parameters. Int J Plast 22:602–627CrossRefMATH

21.

Kim J-H, Pierron F, Wisnom MR, Syed-Muhamad K (2007) Identification of the local stiffness reduction of a damaged composite plate using the virtual fields method. Composites Part A: Appl Sci Manufac 38(9):2065–2075CrossRef

22.

Avril S, Huntley JM, Pierron F, Steele DD (2008) 3D heterogeneous stiffness reconstruction using MRI and the virtual fields method. Exp Mech 48(4):479–494CrossRef

23.

Pierron F, Avril S, The TV (2010) Extension of the virtual fields method to elastoplastic material identification with cyclic loads and kinematic hardening. Int J Solids Struct 47(22–23):2993–3010CrossRefMATH

24.

Grama SN, Subramanian SJ, Pierron F (2015) On the identifiability of Anand visco-plastic model parameters using the virtual fields method. Acta Mater 86:118–136CrossRef

25.

Rossi M, Pierron F, Štamborská M (2016) Application of the virtual fields method to large strain anisotropic plasticity. Int J Solids Struct 97–98:322–335CrossRef

26.

Wang P, Pierron F, Rossi M, Lava P, Thomsen OT (2016) Optimised experimental characterisation of polymeric foam material using DIC and the virtual fields method. Strain 52(1):59–79CrossRef

27.

Marek A, Davis FM, Pierron F (2017) Sensitivity-based virtual fields for computational mechanics. Comput Mech 60(3):409–431MathSciNetCrossRefMATH

28.

Roux S, Hild F, Pagano S (2005) A stress scale in full-field identification procedures: a diffuse stress gauge. Eur J Mech - A/Solids 24:442451CrossRefMATH

29.

Ben AM, Périé J-N, Guimard J-M, Hild F, Roux S (2011) On the identification and validation of an anisotropic damage model using full-field measurements. Int J Damage Mech 20(8):1130–1150CrossRef

30.

Ladevèze P (1983) And and Leguillon D., Error estimate procedure in the finite element method and applications. SIAM. J Num Anal 20:485–509CrossRefMATH

31.

Constantinescu A (1995) On the identification of elastic modulus from displacement force boundary measurements. Inverse Problems Eng 1:293–315CrossRef

32.

Geymonat G, Pagano S (2003) Identification of mechanical properties by displacement field measurement: a variational approach. Meccanica 38:535–545MathSciNetCrossRefMATH

33.

Latourte F, Chrysochoos A, Pagano S, Wattrisse B (2008) Elastoplastic behavior identification for heterogeneous loadings and materials. Exp Mech 48:435–449CrossRef

34.

Simo J, Hughes T (1998) Computational inelasticity. Springer, VerlagMATH

35.

Bornert M, Brémand F, Doumalin P, Dupré M, Fazzini J-C, Grédiac M, Hild F, Mistou S, Molimard J, Orteu J-J, Robert L, Surrel Y, Vacher P, Wattrisse B (2008) Assessment of digital image correlation measurement errors: methodology and results. Exp Mech 49:353–370CrossRef

Titel: Identification of Heterogeneous Elastoplastic Behaviors Using the Constitutive Equation Gap Method
verfasst von: T. Madani
Y. Monerie
S. Pagano
C. Pelissou
B. Wattrisse
Publikationsdatum: 27.04.2018
Verlag: Springer US
Erschienen in: Experimental Mechanics / Ausgabe 6/2018
Print ISSN: 0014-4851
Elektronische ISSN: 1741-2765
DOI: https://doi.org/10.1007/s11340-018-0389-0

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