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Applied Mathematics and Mechanics >

2023 , Vol. 44 >Issue 4: 583 - 602

DOI: https://doi.org/10.1007/s10483-023-2977-6

Articles

Antiplane shear crack in a prestressed elastic medium based on the couple stress theory

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  • School of Civil Engineering, Central South University, Changsha 410075, China

Received date: 2022-09-05

  Revised date: 2023-01-02

  Online published: 2023-03-30

Supported by

the National Natural Science Foundation of China (Nos. 11672336 and 12072374)

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Abstract

A prestressed elastic medium containing a mode-III crack is studied by means of the couple stress theory (CST). Based on the CST under initial stresses, a governing differential equation along with a mixed boundary value problem is established. The singularities of the couple stress and force stress near the crack tips are analyzed through the asymptotic crack-tip fields resulting from the characteristic expansion method. To determine their intensity, a hypersingular integral equation is derived and numerically solved with the help of the Chebyshev polynomial. The obtained results show a strong size-dependence of the out-of-plane displacement on the crack and the couple stress intensity factor (CSIF) and the force stress intensity factor (FSIF) around the crack tips. The symmetric part of the shear stress has no singularity, and the skew-symmetric part related to the couple stress exhibits an r-3/2 singularity, in which r is the distance from the crack tip. The initial stresses also affect the crack tearing displacement and the CSIF and FSIF.

Key words: couple stress theory (CST); initial stress; antiplane shear crack; singularity; hypersingular integral equation

Cite this article

Jian CHEN, Yawei WANG, Xianfang LI . Antiplane shear crack in a prestressed elastic medium based on the couple stress theory[J]. Applied Mathematics and Mechanics, 2023 , 44(4) : 583 -602 . DOI: 10.1007/s10483-023-2977-6

References

[1] FLECK, N. A., MULLER, G. M., ASHBY, M. F., and HUTCHINSON, J. W. Strain gradient plasticity: theory and experiment. Acta Metallurgica et Materialia, 42, 475-487(1994)
[2] LUO, J., WANG, H., XI, C., ZHAI, H., and ZHANG, C. Indentation size effect-crack propagation model and finite element simulation verification for microhardness test of ceramic materials. Ceramics International, 47, 4914-4924(2021)
[3] MINDLIN, R. D. and TIERSTEN, H. F. Effects of couple-stresses in linear elasticity. Archive for Rational Mechanics and Analysis, 11, 415-448(1962)
[4] KOITER, W. T. Couple-stresses in the theory of elasticity, I and II. Proceedings of the Koninklijke Nederlandse Akademie van Wetenschappen, 67, 17-44(1964)
[5] MISHURIS, G., PICCOLROAZ, A., and RADI, E. Steady-state propagation of a mode III crack in couple stress elastic materials. International Journal of Engineering Science, 61, 112-128(2012)
[6] PICCOLROAZ, A., MISHURIS, G., and RADI, E. Mode III interfacial crack in the presence of couple-stress elastic materials. Engineering Fracture Mechanics, 80, 60-71(2012)
[7] SIGAEVA, T. and SCHIAVONE, P. Influence of boundary elasticity on a couple stress elastic solid with a mode-III crack. The Quarterly Journal of Mechanics and Applied Mathematics, 68, 195-202(2015)
[8] BAXEVANAKIS, K., GOURGIOTIS, P., and GEORGIADIS, H. Interaction of cracks with dislocations in couple-stress elasticity, part II: shear modes. International Journal of Solids and Structures, 118-119, 192-203(2017)
[9] GOURGIOTIS, P. A. Interaction of shear cracks in microstructured materials modeled by couples-tress elasticity. Journal of Mechanics of Materials and Structures, 13, 401-419(2018)
[10] NOBILI, A., RADI, E., and VELLENDER, A. Diffraction of antiplane shear waves and stress concentration in a cracked couple stress elastic material with micro inertia. Journal of the Mechanics and Physics of Solids, 124, 663-680(2019)
[11] GIANNAKOPOULOS, A. E. and ZISIS, T. Uniformly moving antiplane crack in flexoelectric materials. European Journal of Mechanics A/Solids, 85, 104136(2021)
[12] ZHANG, X., WU, Y., XIE, L., ZHANG, Y., and ZHANG, K. The effects of pre-cyclic stress on fracture properties and fatigue crack propagation life of 7N01 aluminum alloy. Engineering Fracture Mechanics, 191, 1-12(2018)
[13] WANG, L., DAI, L., BIAN, H., MA, Y., and ZHANG, J. Concrete cracking prediction under combined prestress and strand corrosion. Structure and Infrastructure Engineering, 15, 285-295(2019)
[14] JIANG, Z. C., TANG, G. J., and LI, X. F. Effect of initial T-stress on stress intensity factor for a crack in a thin pre-stressed layer. Engineering Fracture Mechanics, 150, 19-27(2015)
[15] ZHOU, S. X. and LI, X. F. Full incremental elastic field induced by a mode I crack in a prestressed orthotropic material. Engineering Fracture Mechanics, 235, 107070(2020)
[16] SUN, D. L., ZHANG, X. Y., and LI, X. F. Interaction of multiple parallel cracks in a pre-stressed orthotropic elastic plane. European Journal of Mechanics A/Solids, 96, 104704(2022)
[17] LAKES, S. Experimental microelasticity of two porous solids. International Journal of Solids and Structures, 22, 55-63(1986)
[18] BIGONI, D. and DRUGAN, W. J. Analytical derivation of Cosserat moduli via homogenization of heterogeneous elastic materials. Journal of Applied Mechanics-Transactions of the ASME, 74, 741-753(2006)
[19] ROSSIKHIN, Y. A. and SHITIKOVA, M. V. Transient wave velocities in pre-stressed thin-walled beams of open profile with cosserat-type micro-structure. Composites Part B: Engineering, 83, 323-332(2015)
[20] YANG, F., CHONG, A., LAM, D., and TONG, P. Couple stress based strain gradient theory for elasticity. International Journal of Solids and Structures, 39, 2731-2743(2002)
[21] HADJESFANDIARI, A. R. and DARGUSH, G. F. Couple stress theory for solids. International Journal of Solids and Structures, 48, 2496-2510(2011)
[22] KOLPAKOV, A. G. Stressed Composite Structures Homogenized Models for Thin-Walled Nonhomogeneous Structures with Initial Stresses, Springer Science, Berlin (2004)
[23] AKBAROV, S. D. Dynamics of Pre-strained Bi-material Elastic Systems: Linearized ThreeDimensional Approach, Springer, Berlin (2015)
[24] RADI, E. On the effects of characteristic lengths in bending and torsion on mode III crack in couple stress elasticity. International Journal of Solids and Structures, 45, 3033-3058(2008)
[25] GOURGIOTIS, P. and GEORGIADIS, H. An approach based on distributed dislocations and disclinations for crack problems in couple-stress elasticity. International Journal of Solids and Structures, 45, 5521-5539(2008)
[26] MORINI, L., PICCOLROAZ, A., MISHURIS, G., and RADI, E. On fracture criteria for dynamic crack propagation in elastic materials with couple stresses. International Journal of Engineering Science, 71, 45-61(2013)
[27] BAESU, E. and SOOS, E. Antiplane fracture in a prestressed and prepolarized piezoelectric crystal. IMA Journal of Applied Mathematics, 66, 499-508(2001)
[28] HU, Z. L., YANG, Y., and LI, X. F. Bending fracture of ultra-thin plates with surface elasticity containing a thickness-through crack. International Journal of Solids and Structures, 226-227, 111093(2021)
[29] HU, Z. L., YANG, Y., ZHANG, X. Y., and LI, X. F. Bending of a nanoplate with strain-dependent surface stress containing two collinear through cracks. Meccanica, 57, 1937-1954(2022)
[30] FANNJIANG, A. C., PAULINO, G. H., and CHAN, Y. S. Strain gradient elasticity for antiplane shear cracks: a hypersingular integrodifferential equation approach. SIAM Journal on Applied Mathematics, 62, 1066-1091(2001)
[31] LI, J. E. and WANG, B. L. Strain gradient fracture of a mode III crack in an elastic layer on a substrate. Journal of Mechanics of Materials and Structures, 13, 555-570(2018)
[32] PAULINO, G. H., FANNJIANG, A. C., and CHAN, Y. S. Gradient elasticity theory for mode III fracture in functionally graded materials-part I: crack perpendicular to the material gradation. Journal of Applied Mechanics, Transactions ASME, 70, 531-542(2003)
[33] ZHAO, B., LIU, T., PAN, J., PENG, X., and TANG, X. A stress analytical solution for mode III crack within modified gradient elasticity. Mechanics Research Communications, 84, 142-147(2017)
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