Research ArticleNo Access

A Perforated High-Order Element for Fracture Mechanics Problems Using the Hybrid Strain Method

Mohammadreza Ramezani

Department of Civil Engineering, School of Engineering, Ferdowsi University of Mashhad, Mashhad, Iran

E-mail Address: mohammadrezaramezani1994@gmail.com

Corresponding author.

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Mansour Ghalehnovi

Department of Civil Engineering, School of Engineering, Ferdowsi University of Mashhad, Mashhad, Iran

E-mail Address: ghalehnovi@um.ac.ir

Corresponding author.

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Mohammad Rezaiee-Pajand

Department of Civil Engineering, School of Engineering, Ferdowsi University of Mashhad, Mashhad, Iran

E-mail Address: rezaiee@um.ac.ir

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https://doi.org/10.1142/S1758825122500922Cited by:1 (Source: Crossref)

Abstract

In this paper, a novel hybrid approach with complex and conformal mapping functions is proposed for the first time. This strain-based approach is based on the special trial functions and the assumed natural strain (ANS) theory, which provides a unified framework for solving fracture problems. In the utilized method, the proposed super-element is divided into perforated and solid domains. For the perforated domain, Muskhelishvili–Kolosov potential function is employed to simulate the perforated discontinuity. For the solid domain, the higher-order strain field is assumed as the enriched interpolation functions. Moreover, the rigid body terms are imposed into the kinematic variables to enhance the convergence ability and the element performance. Numerical examples demonstrate that the proposed element (PHSM20) produces high precision results for both displacement and stresses.

Keywords:

References

Akbaş, Ş. D. [2016] “ Post-buckling analysis of edge cracked columns under axial compression loads,” International Journal of Applied Mechanics 8(8), 1650086. Link, Web of Science, Google Scholar
Aliha, M., Berto, F., Bahmani, A. and Gallo, P. [2017] “ Mixed mode I/II fracture investigation of Perspex based on the averaged strain energy density criterion,” Physical Mesomechanics 20(2), 149–156. Crossref, Web of Science, Google Scholar
Alimoradzadeh, M. and Akbaş, Ş. D. [2021] “ Superharmonic and subharmonic resonances of atomic force microscope subjected to crack failure mode based on the modified couple stress theory,” The European Physical Journal Plus 136(5), 1–20. Crossref, Web of Science, Google Scholar
Berto, F., Ayatollahi, M., Borsato, T. and Ferro, P. [2016] “ Local strain energy density to predict size-dependent brittle fracture of cracked specimens under mixed mode loading,” Theoretical and Applied Fracture Mechanics 86, 217–224. Crossref, Web of Science, Google Scholar
Cai, K., Cao, J., Shi, J. and Qin, Q. H. [2016] “ Layout optimization of ill-loaded multiphase bi-modulus materials,” International Journal of Applied Mechanics 8(3), 1650038. Link, Web of Science, Google Scholar
Carrera, E. and Zozulya, V. [2022] “ Carrera unified formulation (CUF) for the micropolar plates and shells. II. Complete linear expansion case,” Mechanics of Advanced Materials and Structures 29(6), 796–815. Crossref, Web of Science, Google Scholar
De Lorenzis, L. and Maurini, C. [2021] “ Nucleation under multi-axial loading in variational phase-field models of brittle fracture,” International Journal of Fracture 237, 61–81. Crossref, Web of Science, Google Scholar
Fu, Z. J., Qin, Q. H. and Chen, W. [2011] “ Hybrid-Trefftz finite element method for heat conduction in nonlinear functionally graded materials,” Engineering Computations 28(5), 578–599. Crossref, Web of Science, Google Scholar
Heydarpour, Y., Malekzadeh, P., Dimitri, R. and Tornabene, F. [2020] “ Thermoelastic analysis of rotating multilayer FG-GPLRC truncated conical shells based on a coupled TDQM-NURBS scheme,” Composite Structures 235, 111707. Crossref, Web of Science, Google Scholar
Hu, J., Zhou, Y., Liu, Z. and Ng, T. Y. [2017] “ Pattern switching in soft cellular structures and hydrogel-elastomer composite materials under compression,” Polymers 9(6), 229. Crossref, Web of Science, Google Scholar
Iqbal, M., Birk, C., Ooi, E., Pramod, A., Natarajan, S., Gravenkamp, H. and Song, C. [2022] “ Thermoelastic fracture analysis of functionally graded materials using the scaled boundary finite element method,” Engineering Fracture Mechanics 264, 108305. Crossref, Web of Science, Google Scholar
Irwin, G. R., Paris, P. C. and Tada, H. [2000] The Stress Analysis of Cracks Handbook (American Society of Mechanical Engineers. Three–Park Avenue, New York), 10016. Google Scholar
Jiang, Y., Dong, J., Nie, D. and Zhang, X. [2021] “ XFEM with partial Heaviside function enrichment for fracture analysis,” Engineering Fracture Mechanics 241, 107375. Crossref, Web of Science, Google Scholar
Lal, A. and Vaghela, M. [2020] “ Numerical investigation of an orthotropic plate with interactions of crack, inclusions and voids under uniaxial tensile loading by XFEM,” International Journal of Applied Mechanics 12(10), 2050113. Link, Web of Science, Google Scholar
Leconte, N., Langrand, B. and Markiewicz, E. [2010] “ On some features of a plate hybrid-Trefftz displacement element containing a hole,” Finite Elements in Analysis and Design 46(10), 819–828. Crossref, Web of Science, Google Scholar
Li, Z. and Liu, Z. [2020] “ The elongation-criterion for fracture toughness of hydrogels based on percolation model,” Journal of Applied Physics 127(21), 215101. Crossref, Web of Science, Google Scholar
Liu, Z., Toh, W. and Ng, T. Y. [2015] “ Advances in mechanics of soft materials: A review of large deformation behavior of hydrogels,” International Journal of Applied Mechanics 7(5), 1530001. Link, Web of Science, Google Scholar
Nguyen, D. T. D., Javidan, F., Attar, M., Natarajan, S., Yang, Z., Ooi, E. H., Song, C. and Ooi, E. T. [2022] “ Fracture analysis of cracked magneto-electro-elastic functionally graded materials using scaled boundary finite element method,” Theoretical and Applied Fracture Mechanics 118, 103228. Crossref, Web of Science, Google Scholar
Ooi, E. T., Rajendran, S. and Yeo, J. H. [2007] Extension of unsymmetric finite elements US-QUAD8 and US-HEXA20 for geometric nonlinear analyses,” Engineering Computations 24(4), 407–431. Crossref, Web of Science, Google Scholar
Piltner, R. [1992] “ A quadrilateral hybrid-Trefftz plate bending element for the inclusion of warping based on a three-dimensional plate formulation,” International Journal for Numerical Methods in Engineering 33(2), 387–408. Crossref, Web of Science, Google Scholar
Qin, Q. H. [2005] “ Formulation of hybrid Trefftz finite element method for elastoplasticity,” Applied Mathematical Modelling 29(3), 235–252. Crossref, Web of Science, Google Scholar
Qin, Q. H. [2021] “Introduction to fundamental solution based finite element methods,” Trefftz and Fundamental Solution-Based Finite Element Methods, Chapter 5, pp. 163–201. Google Scholar
Ramezani, M., Rezaiee-Pajand, M. and Tornabene, F. [2022a] “ Nonlinear dynamic analysis of FG/SMA/FG sandwich cylindrical shells using HSDT and semi ANS functions,” Thin-Walled Structures 171, 108702. Crossref, Web of Science, Google Scholar
Ramezani, M., Rezaiee-Pajand, M. and Tornabene, F. [2022b] “ Nonlinear thermomechanical analysis of CNTRC cylindrical shells using HSDT enriched by zig-zag and polyconvex strain cover functions,” Thin-Walled Structures 172, 108918. Crossref, Web of Science, Google Scholar
Ramezani, M., Rezaiee-Pajand, M. and Tornabene, F. [2022c] “ Linear and nonlinear mechanical responses of FG-GPLRC plates using a novel strain-based formulation of modified FSDT theory,” International Journal of Non-Linear Mechanics 140, 103923. Crossref, Web of Science, Google Scholar
Ramezani, M., Rezaiee-Pajand, M. and Tornabene, F. [2022d] “ Nonlinear thermomechanical analysis of GPLRC cylindrical shells using HSDT enriched by quasi-3D ANS cover functions,” Thin-Walled Structures 179, 109582. Crossref, Web of Science, Google Scholar
Rezaiee-Pajand, M. and Gharaei-Moghaddam, N. [2019] “ Vibration and static analysis of cracked and non-cracked non-prismatic frames by force formulation,” Engineering Structures 185, 106–121. Crossref, Web of Science, Google Scholar
Rezaiee-Pajand, M., Gharaei-Moghaddam, N. and Ramezani, M. [2019a] “ Two triangular membrane elements based on strain,” International Journal of Applied Mechanics 11, 1950010. Link, Web of Science, Google Scholar
Rezaiee-Pajand, M., Gharaei-Moghaddam, N. and Ramezani, M. [2019b] “ A new higher-order strain-based plane element,” Scientia Iranica 26, 2258–2275. Web of Science, Google Scholar
Rezaiee-Pajand, M., Gharaei-Moghaddam, N. and Ramezani, M. [2020a] “ Strain-based plane element for fracture mechanics’ problems,” Theoretical and Applied Fracture Mechanics 108, 102569. Crossref, Web of Science, Google Scholar
Rezaiee-Pajand, M., Ramezani, M. and Gharaei-Moghaddam, N. [2020b] “ Using higher-order strain interpolation function to improve the accuracy of structural responses,” International Journal of Applied Mechanics 12(3), 2050026. Link, Web of Science, Google Scholar
Rezaiee-Pajand, M., Gharaei-Moghaddam, N. and Ramezani, M. [2021a] “ A novel assumed-strain finite element for detecting the elastic behavior of wall-like structures,” Mechanics of Advanced Materials and Structures 1–21. Web of Science, Google Scholar
Rezaiee-Pajand, M., Gharaei-Moghaddam, N. and Ramezani, M. [2021b] “ Review of the strain-based formulation for analysis of plane structures Part I: Formulation of basics and the existing elements,” Iranian Journal of Numerical Analysis and Optimization 11, 437–483. Google Scholar
Rezaiee-Pajand, M., Gharaei-Moghaddam, N. and Ramezani, M. [2021c] “ Review of the strain-based formulation for analysis of plane structures Part II: Evaluation of the numerical performance,” Iranian Journal of Numerical Analysis and Optimization 11, 485–511. Google Scholar
Rezaiee-Pajand, M. and Ramezani, M. [2021a] “ An evaluation of MITC and ANS elements in the nonlinear analysis of shell structures,” Mechanics of Advanced Materials and Structures, 1–21. Web of Science, Google Scholar
Rezaiee-Pajand, M. and Ramezani, M. [2021b] “ Nonlinear deformation and numerical post-buckling analysis of plate structures using the assumed natural strain concept,” International Journal of Applied Mechanics 13, 2150110. Link, Web of Science, Google Scholar
Song, C., Ooi, E. T. and Natarajan, S. [2018] “ A review of the scaled boundary finite element method for two-dimensional linear elastic fracture mechanics,” Engineering Fracture Mechanics 187, 45–73. Crossref, Web of Science, Google Scholar
Surendran, M., Lee, C., Nguyen-Xuan, H., Liu, G. and Natarajan, S. [2021] “ Cell-based smoothed finite element method for modelling interfacial cracks with non-matching grids,” Engineering Fracture Mechanics 242, 107476. Crossref, Web of Science, Google Scholar
Tong, P., Pian, T. H. and Lasry, S. J. [1973] “ A hybrid-element approach to crack problems in plane elasticity,” International Journal for Numerical Methods in Engineering 7(3), 297–308. Crossref, Google Scholar
Wang, L., Feng, P., Wu, Y. and Liu, Z. [2019] “ A tensile-compressive asymmetry model for shape memory alloys with a redefined martensite internal variable,” Smart Materials and Structures 28(10), 105050. Crossref, Web of Science, Google Scholar
Wang, H. and Qin, Q. H. [2017] “ Voronoi polygonal hybrid finite elements with boundary integrals for plane isotropic elastic problems,” International Journal of Applied Mechanics 9(3), 1750031. Link, Web of Science, Google Scholar
Xu, J., Liu, J. and Rajendran, S. [2015] “ A hybrid ‘FE-Meshfree’QUAD4 element with nonlocal features,” Computational Mechanics 56(2), 317–329. Crossref, Web of Science, Google Scholar
Zhang, H., Wang, H. and Wang, J. [2007] “ Parametric variational principle based elastic–plastic analysis of materials with polygonal and Voronoi cell finite element methods,” Finite Elements in Analysis and Design 43(3), 206–217. Crossref, Web of Science, Google Scholar
Zhang, N., Zheng, S. and Liu, Z. [2017] “ Numerical simulation and experimental study of crack propagation of polydimethylsiloxane,” Procedia Engineering 214, 59–68. Crossref, Google Scholar