SGBEM–FEM coupling for analysis of cracks in 3D anisotropic media

Rungamornrat, Jaroon; Mear, Mark E.

doi:10.1002/nme.3055

Cited by 16 publications

(4 citation statements)

References 51 publications

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“…( 18), one obtains a relationship between the nodal force vector and the nodal displacement vector for the cracked superelement shown in Fig. 2, which can be written as e e e  F K U (19) where e K is the stiffness matrix of the cracked superelement, which can be expressed as…”

Section: Consider An Arbitrary Cracked Superelement Ementioning

confidence: 99%

“…However, for crack problems of complex structures with complex boundary conditions, it is not convenient to model the structures and apply the boundary conditions with BEM, and for multicrack problems, multi-domain coupling techniques are further required in BEM formulation when the single-crack Erdogan fundamental solutions are used. Therefore, in order to make full use of the unique advantage of BEM in dealing with the singular behaviour at crack tips and the superior flexibility of FEM in modelling complex structures and boundary conditions, several researchers proposed the BEM-FEM coupling methods to solve complex crack problems [15][16][17][18][19][20]. Actually, the BEM-FEM coupling techniques stem from the pioneering work of Zienkiewicz et al [21] and Brebbia and Georgiou [22], and now have appeared in the areas of flexoelectricity [23], vibroacoustic response [24], fluid-structure interaction [25] and soil-structure interaction [26], among others.…”

Section: Introductionmentioning

confidence: 99%

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A SFBEM–FEM coupling method for solving crack problems based on Erdogan fundamental solutions

Cai

Zong-ze

2022

J Eng Math

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The boundary element method (BEM) has proven to be an efficient approach for crack analysis in fracture mechanics, while its versatility in application to crack problems of complex structures with irregular boundaries deserves further attention. In this study, to improve the applicability to complex crack analysis, a cracked superelement is first established with BEM to model the near-crack region, and the crack problem is then solved within the frame of finite element method (FEM). The stiffness matrix of the cracked superelement is formulated using the spline fictitious boundary element method (SFBEM) based on the Erdogan fundamental solutions for an infinite plane with a single crack. The proposed superelement is further incorporated into a finite element mesh to simulate the behaviour of the crack zone, and the governing equation of the crack problem is finally established and solved using the typical procedure of FEM. After obtaining the nodal displacements of the superelement, the stress intensity factors (SIFs) of crack tips can be obtained by a backward analysis with SFBEM. The accuracy and efficiency of the proposed SFBEM-FEM coupling method are demonstrated by two numerical examples involving a rectangular plate with a central crack and a square plate with 100 horizontal cracks. The present approach is further applied to the analysis of the SIFs of multiple cracks exposed in a steel anchorage box for a hanger of a suspension bridge, which indicates the merging of the cracked superelements to the commercial FEM software is computationally efficient for the analysis of complex structures with multiple cracks.

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Section: Consider An Arbitrary Cracked Superelement Ementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A SFBEM–FEM coupling method for solving crack problems based on Erdogan fundamental solutions

Cai

Zong-ze

2022

J Eng Math

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“…The new methods to solve this problem also include boundary integral equation methods (BIEMs). In recent years, BIEMs have been proven to be computationally efficient and yield accurate results for the analysis of fracture problems in both 2D and 3D settings [10][11][12][13][14][15][16].…”

Section: Introductionmentioning

confidence: 99%

The Numerical Simulation Method of the Slot Crack Groups’ Effect Analysis for Solid Rocket Motor Grain

Xuan

et al. 2022

International Journal of Aerospace Engineering

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This study is aimed at the stability and effect of the crack groups in the solid rocket motor (SRM) grain when it was launched at normal temperature. Based on the nearly incompressible viscoelastic finite element method, several cracks were preset in a critical location along with the dangerous point of the back slot. The singular crack elements at the tips of crack groups were established to calculate the J -integral. With the position of the cracks, the J -integral of the various crack tips was, respectively, calculated to prejudge its stability and the group effect. Finally, the experimental measured critical J -integral J IC was compared with the numerical simulation result. The results showed that in the collinear crack groups, the enhancement effect of the main crack was caused by the nearest second crack, and the significant shielding effect of the main crack was occurred in the noncollinear crack groups. Moreover, the experimental result showed that the numerical method had high accuracy.

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“…In this work we treat stationary fractures. Fracture propagation has been modeled using level set methods [10,22], phase-field methods [33], or boundary element methods [41]. Incorporating some of these techniques into the Brinkman-Biot model is a topic of future research.…”

Section: Introductionmentioning

confidence: 99%

Dimensional model reduction for flow through fractures in poroelastic media

2016

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We study the interaction between a poroelastic medium and a fracture filled with fluid.The flow in the fracture is described by the Brinkman equations for an incompressible fluid and the poroelastic medium by the quasi-static Biot model. The two models are fully coupled via the kinematic and dynamic conditions. The Brinkman equations are then averaged over the cross-sections, giving rise to a reduced flow model on the fracture midline. We derive suitable interface and closure conditions between the Biot system and the dimensionally reduced Brinkman model that guarantee solvability of the resulting coupled problem. We design and analyze a numerical discretization scheme based on finite elements in space and the Backward Euler in time, and perform numerical experiments to compare the behavior of the reduced model to the full-dimensional formulation and study the response of the model with respect to its parameters.

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SGBEM–FEM coupling for analysis of cracks in 3D anisotropic media

Cited by 16 publications

References 51 publications

A SFBEM–FEM coupling method for solving crack problems based on Erdogan fundamental solutions

A SFBEM–FEM coupling method for solving crack problems based on Erdogan fundamental solutions

The Numerical Simulation Method of the Slot Crack Groups’ Effect Analysis for Solid Rocket Motor Grain

Dimensional model reduction for flow through fractures in poroelastic media

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