Bridging meso- and microscopic anisotropic unilateral damage formulations for microcracked solids

Qi-Zhi Zhu; Shuang-Shuang Yuan; Jian-fu Shao

doi:10.1016/j.crme.2017.02.003

Bridging meso- and microscopic anisotropic unilateral damage formulations for microcracked solids

Qi-Zhi Zhu ¹ ; Shuang-Shuang Yuan ¹ ; Jian-fu Shao ^1,²

¹ CKey Laboratory of Ministry of Education for Geomechanics and Embankment Engineering, Hohai University, Nanjing, China
² Laboratory of Mechanics of Lille, UMR8107 CNRS, University of Lille, Villeneuve-d'Ascq, France

Comptes Rendus. Mécanique, Volume 345 (2017) no. 4, pp. 281-292.

Résumé

A mathematically consistent and unified description of induced anisotropy and unilateral effects constitutes one of the central tasks in the continuum damage theories developed so far. This paper aims at bridging constitutive damage formulations on meso- and micro-scales with an emphasis on a complete mesoscopic determination of material effective properties for microcracked solids. The key is to introduce a new set of invariants in terms of strain tensor and fabric tensor by making use of the Walpole's tensorial base. This invariant set proves to be equivalent to the classical one, while the new one provides great conveniences to high-order orientation-dependent tensor manipulations. When limited to the case of parallel microcracks, potential relations between ten combination coefficients are established by applying continuity conditions. It is found that the dilute approximation with penny-shaped microcracks is a particular case of the present one. By originally introducing effective strain effect, interactions between microcracks are taken into account with comparison to the Mori–Tanaka method as well as the Ponte-Castaneda and Willis scheme. For completeness, discussions are also addressed on macroscopic formulations with high-order damage variables.

Reçu le : 2016-11-15
Accepté le : 2017-02-08
Publié le : 2017-03-09

DOI : 10.1016/j.crme.2017.02.003

Mots clés : Continuum Damage Mechanics, Thermodynamics, Induced anisotropy, Unilateral effects, Brittle materials, Interaction between microcracks

Affiliations des auteurs :

Qi-Zhi Zhu ¹ ; Shuang-Shuang Yuan ¹ ; Jian-fu Shao ^{1, 2}

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     title = {Bridging meso- and microscopic anisotropic unilateral damage formulations for microcracked solids},
     journal = {Comptes Rendus. M\'ecanique},
     pages = {281--292},
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     volume = {345},
     number = {4},
     year = {2017},
     doi = {10.1016/j.crme.2017.02.003},
     language = {en},
}

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Qi-Zhi Zhu; Shuang-Shuang Yuan; Jian-fu Shao. Bridging meso- and microscopic anisotropic unilateral damage formulations for microcracked solids. Comptes Rendus. Mécanique, Volume 345 (2017) no. 4, pp. 281-292. doi : 10.1016/j.crme.2017.02.003. https://comptes-rendus.academie-sciences.fr/mecanique/articles/10.1016/j.crme.2017.02.003/

Bibliographie
Cité par

[1] R.L. Kranz Microcracks in rocks: a review, Tectonophysics, Volume 100 (1983), pp. 44-80

[2] C.D. Martin; N.A. Chandler The progressive failure of Lac du Bonnet granite, Int. J. Rock Mech. Min. Sci., Volume 31 (1994) no. 4, pp. 643-659

[3] B. Haimson; C. Chang A new true triaxial cell for testing mechanical properties of rock and its use to determine rock strength and deformability of Westerly granite, Int. J. Rock Mech. Min. Sci., Volume 37 (2000), pp. 285-296

[4] J. Lemaitre A Course on Damage Mechanics, Springer, Berlin, 1992

[5] D. Krajcinovic Damage Mechanics, North-Holland, Amsterdam, 1996

[6] S. Murakami Continuum Damage Mechanics – A Continuum Mechanics Approach to the Analysis of Damage and Fracture, Springer, 2012

[7] J.L. Chaboche Damage induced anisotropy: on the difficulties associated with the active/passive unilateral condition, Int. J. Damage Mech., Volume 1 (1992), pp. 148-171

[8] D. Halm; A. Dragon A model of anisotropic damage by mesocrack growth: unilateral effect, Int. J. Damage Mech., Volume 5 (1996), pp. 384-402

[9] F. Cormery; H. Welemane A critical review of some damage models with unilateral effect, Mech. Res. Commun., Volume 29 (2002), pp. 391-395

[10] H. Welemane; F. Cormery An alternative 3D model for damage induced anisotropy and unilateral effect in microcracked materials, J. Phys., Volume 105 (2003), pp. 329-336

[11] A.J.M. Spencer Constitutive theory for strongly anisotropic solids (A.J.M. Spencer, ed.), Continuum Theory of the Mechanics of Fiber-Reinforced Composites, Springer Verlag–CISM, Vienna, 1984, pp. 1-32

[12] A. Curnier; Q.C. He; P. Zysset Conewise linear elastic materials, J. Elast., Volume 37 (1995), pp. 1-38

[13] M. Ortiz A constitutive theory for the inelastic behavior of concrete, Mech. Mater., Volume 4 (1985) no. 1, pp. 67-93

[14] J.C. Simo; J.W. Ju Strain- and stress-based continuum damage models—I. Formulation, Int. J. Solids Struct., Volume 23 (1987) no. 7, pp. 821-840

[15] V.A. Lubarda; D. Krajcinovic; S. Mastilovic Damage model for brittle elastic solids with unequal tensile and compressive strengths, Eng. Fract. Mech., Volume 49 (1994) no. 5, pp. 681-697

[16] G.Z. Voyiadjis; T.M. Abu-Lebdeh Plasticity model for concrete using the bounding surface concept, Int. J. Plast., Volume 10 (1994), pp. 1-21

[17] N.R. Hansen; H.L. Schreyer Damage deactivation, J. Appl. Mech., Volume 62 (1995), pp. 450-458

[18] R. Faria; J. Olivier; M. Cervera A strain-based plastic visco-damage model for massive concrete structures, Int. J. Solids Struct., Volume 35 (1997), pp. 1533-1558

[19] J.F. Shao; J.W. Rudnicki A microcrack-based continuous damage model for brittle geomaterials, Mech. Mater., Volume 32 (2000) no. 10, pp. 607-619

[20] G.Z. Voyiadjis; Z.N. Taqieddin; P.I. Kattan Anisotropic damage-plasticity model for concrete, Int. J. Plast., Volume 24 (2008), pp. 1946-1965

[21] S. Murakami; K. Kamiya Constitutive and damage evolution equations of elastic-brittle materials based on irreversible thermodynamics, Int. J. Mech. Sci., Volume 39 (1997), pp. 473-486

[22] N. Challamel; C. Lanos; C. Casandjian Strain-based anisotropic damage modelling and unilateral effects, Int. J. Mech. Sci., Volume 47 (2005), pp. 459-473

[23] P. Badel; V. Godard; J.B. Leblond Application of some anisotropic damage model to the prediction of the failure of some complex industrial concrete structure, Int. J. Solids Struct., Volume 44 (2007), pp. 5848-5874

[24] R. Desmorat; F. Gatuingt; F. Ragueneau Nonlocal anisotropic damage model and related computational aspects for quasi-brittle materials, Eng. Fract. Mech., Volume 74 (2007) no. 10, pp. 1539-1560

[25] T. Mori; K. Tanaka Averages stress in matrix and average elastic energy of materials with misfitting inclusions, Acta Metall., Volume 21 (1973), pp. 571-574

[26] M. Kachanov Effective elastic properties of cracked solids: critical review of some basic concepts, Appl. Mech. Rev., Volume 45 (1992), pp. 304-335

[27] V. Pensée; D. Kondo; L. Dormieux Micromechanical analysis of anisotropic damage in brittle materials, J. Eng. Mech., Volume 128 (2002), pp. 889-897

[28] Q.Z. Zhu; D. Kondo; J.F. Shao; V. Pensée Micromechanical modelling of anisotropic damage in brittle rocks and application, Int. J. Rock Mech. Min., Volume 45 (2008), pp. 467-477

[29] Q.Z. Zhu; D. Kondo; J.F. Shao Micromechanical analysis of coupling between anisotropic damage and friction in quasi brittle materials: role of the homogenization scheme, Int. J. Solids Struct., Volume 45 (2008), pp. 1385-1405

[30] L.J. Walpole Elastic behavior of composite materials: theoretical foundations, Adv. Appl. Mech., Volume 21 (1981), pp. 169-242 (Ed. C.S. Yih)

[31] L. Dormieux; D. Kondo; F.J. Ulm Microporomechanics, Chichester, England, 2006

[32] A. Zaoui Matériaux hétérogènes et composites, Cours de l'Ecole Polytechnique, 2000

[33] Q.Z. Zhu Applications des approches d'homogénéisation à la modélisation tridimensionnelle de l'endommagement des matériaux quasi fragile: formulations, validations et implémentations numériques, University of Lille-1, Lille, France, 2006 PhD thesis (in French)

[34] P. Ponte-Castaneda; J.R. Willis The effect of spatial distribution on the behavior of composite materials and cracked media, J. Mech. Phys. Solids, Volume 43 (1995), pp. 1919-1951

[35] R.J. Rodin; G.J. Weng On reflected interactions in elastic solids containing inhomogeneities, J. Mech. Phys. Solids, Volume 68 (2014), pp. 197-209

[36] Q.Z. Zhu; J.F. Shao; D. Kondo A micromechanics-based thermodynamic formulation of isotropic damage with unilateral and friction effects, Eur. J. Mech. A, Solids, Volume 30 (2011), pp. 316-325

[37] Q.Z. Zhu; L.Y. Zhao; J.F. Shao Analytical and numerical analysis of frictional damage in quasi brittle materials, J. Mech. Phys. Solids, Volume 92 (2016), pp. 137-163

[38] Q.Z. Zhu; J.F. Shao A refined micromechanical damage-friction model with strength prediction for rock-like materials under compression, Int. J. Solids Struct., Volume 60 (2015) no. 61, pp. 75-83

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