Applied Mathematics and Mechanics >
Interface models for thin interfacial layers
Received date: 2015-09-21
Revised date: 2015-11-24
Online published: 2016-06-01
Supported by
Project supported by the National Natural Science Foundation of China (No. 10632040)
There have already been several interface models for the analyses of thin interfacial layers in bonded materials. To distinguish their corresponding advantages or limitations, a comparative study is carried out, and a new constitutive-based interface model is proposed. Through numerical examinations, the limitations of typical models are clarified. It is found that the new interface model is an efficient and accurate model, by which both the traction and the displacement jumps across the modelled interface with the thickness of zero are allowed, and the stresses within the interfacial layer can also be analyzed.
Key words: interface model; interfacial layer; bonding
Xiaojing CAI, Jinquan XU . Interface models for thin interfacial layers[J]. Applied Mathematics and Mechanics, 2016 , 37(6) : 707 -724 . DOI: 10.1007/s10483-016-2084-6
[1] Rizzoni, R., Dumont, S., Lebon, F., and Sacco, E. Higher order model for soft and hard elastic interfaces. International Journal of Solids and Structures, 51, 4137-4148 (2014)
[2] Lebon, F. and Rizzoni, R. Asymptotic analysis of a thin interface: the case involving similar rigidity. International Journal of Engineering Science, 48, 473-486 (2010)
[3] Lebon, F., Khaoua, A. O., and Licht, C. Numerical study of soft adhesively bonded joints in finite elasticity. Computational Mechanics, 21, 134-140 (1998)
[4] Dundurs, J. Micromechanics and Inhomogeneity, Springer-Verlag, Berlin, 109-114 (1990)
[5] Xu, J. Q. The Mechanics of Interface (in Chinese), Science Publication, Beijing (2006)
[6] Benveniste, Y. A general interface model for a three-dimensional curved thin anisotropic interphase between two anisotropic media. Journal of the Mechanics and Physics of Solids, 54, 708-734 (2006)
[7] Corigliano, A. Formulation, identification and use of interface models in the numerical analysis of composite delamination. International Journal of Solids and Structures, 30, 2779-2811 (1993)
[8] Benveniste, Y. and Miloh, T. Imperfect soft and stiff interfaces in two-dimensional elasticity. Mechanics of Materials, 33, 309-323 (2001)
[9] Elices, M., Guinea, G. V., Gomez, J., and Planas, J. The cohesive zone model: advantages, limitations and challenges. Engineering Fracture Mechanics, 69, 137-163 (2002)
[10] Valoroso, N., Sessa, S., Lepore, M., and Cricri, G. Identification of mode-I cohesive parameters for bonded interfaces based on DCB test. Engineering Fracture Mechanics, 104, 56-79 (2013)
[11] Özdemir, I., Brekelmans, W. A. M., and Geers, M. G. D. A thermo-mechanical cohesive zone model. Computational Mechanics, 46, 735-745 (2010)
[12] Rabinovitch, O. An extended high-order cohesive interface approach to the debonding analysis of FRP strengthened beams. International Journal of Mechanical Sciences, 81, 1-16 (2014)
[13] Cai, X. J. and Xu, J. Q. Interfacial fracture criteria based on the nominal deformation energy of interface. Theoretical and Applied Fracture Mechanics, 75, 16-21 (2014)
[14] Yuuki, R. and Kisu, H. Elastic Analysis Based on Boundary Element Analysis, Baifukan, Tokyo (1987)
[15] Bogy, D. B. Edge-bonded dissimilar orthogonal elastic wedges under normal and shear loading. Journal of Applied Mechanics, 35, 460-466 (1968)
[16] Yuuki, R. and Xu, J. Q. Boundary element analysis of dissimilar materials and interface crack. Computational Mechanics, 14, 116-127 (1994)
[17] Xu, J. Q., Fu, L. D., and Mutoh, Y. A method for determining elastic-plastic stress singularity at the interface edge of bonded power law hardening materials. JSME International Journal Series A, 45, 177-183 (2002)
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