Enriched finite elements and level sets for damage tolerance assessment of complex structures

Bordas, Stéphane Pierre Alain; Moran, Brian

doi:10.1016/j.engfracmech.2006.01.006

Cited by 150 publications

(120 citation statements)

References 35 publications

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“…Figure 19 shows the strain εyy along line x = 0. We believe that using the enhanced strain and stress fields to compute the interaction integrals commonly used to obtain the stress intensity factors, the oscillations in the soobtained SIFs, reported in various papers [30,21,13,40,42] will be reduced. Not only is the enhanced strain field smoothed in the direction normal to the crack front, but also in the tangent direction, which should reduce the amount of oscillations in the SIFs.…”

Section: D Mode I Edge Crackmentioning

confidence: 99%

“…Typically, XFEM and related methods add, locally, special functions to the FE approximation, in order to better approximate particular features of a problem. For problems with discontinuities in the primal dependent variable (cracks [29,28,13], fluid-structure interaction [26]), discontinuous functions are added. To handle discontinuities in the dual unknown (multi-materials [41], solidification [16], biofilms [35], multi-phase flow [15], Stokes flow [47]), functions with discontinuous derivatives enhance the standard basis.…”

Section: Introductionmentioning

confidence: 99%

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Derivative recovery and a posteriori error estimate for extended finite elements

Bordas

Duflot

2007

Computer Methods in Applied Mechanics and Engineering

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102

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The goal of this work is to devise a simple and effective local a posteriori error estimate for partition of unity enriched finite element methods such as the extended finite element method (XFEM). In each element, the local estimator is the L2 norm of the difference between the raw XFEM strain field and an enhanced strain field computed by extended moving least squares (XMLS) derivative recovery obtained from the raw nodal XFEM displacements. The XMLS construction is taylored to the nature of the solution. The technique is applied to linear elastic fracture mechanics, in which near-tip asymptotic functions are added to the MLS basis. The XMLS shape functions are constructed from weight functions following the diffraction criterion to represent the discontinuity. The result is a very smooth enhanced strain solution including the singularity at the crack tip. Results are shown for two and three dimensional linear elastic fracture mechanics problems in mode I and mixed mode. The effectivity index of the estimator is always close to 1. and improves upon mesh refinement. It is also shown that for the linear elastic fracture mechanics problems treated, the proposed estimator outperforms one of the superconvergent patch recovery technique of Zienkiewicz and Zhu, which is only C0. Parametric studies of the general performance of the estimator are also carried out.

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Section: D Mode I Edge Crackmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Derivative recovery and a posteriori error estimate for extended finite elements

Bordas

Duflot

2007

Computer Methods in Applied Mechanics and Engineering

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130

102

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“…For case 2 the results of the present study for the crack path prediction is also compared qualitatively with the numerical results using enriched element free Galerkin method (EFGM) [9] and the extended finite element method results (X-FEM) [10] as shown in Fig. 9a and 9b respectively with a good agreement.…”

Section: Numerical Results and Validationmentioning

confidence: 69%

Development of Efficient Finite Element Software of Crack Propagation Simulation using Adaptive Mesh Strategy

Alshoaibi¹

2009

American Journal of Applied Sciences

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Abstract:The purpose of this study is on the determination of 2D crack paths and surfaces as well as on the evaluation of the stress intensity factors as a part of the damage tolerant assessment. Problem statement: The evaluation of SIFs and crack tip singular stresses for arbitrary fracture structure are a challenging problem, involving the calculation of the crack path and the crack propagation rates at each step especially under mixed mode loading. Approach: This study was provided a finite element code which produces results comparable to the current available commercial software. Throughout the simulation of crack propagation an automatic adaptive mesh was carried out in the vicinity of the crack front nodes and in the elements which represent the higher stresses distribution. The finite element mesh was generated using the advancing front method. The adaptive remising process carried out based on the posteriori stress error norm scheme to obtain an optimal mesh. The onset criterion of crack propagation was based on the stress intensity factors which provide as the most important parameter that must be accurately estimated. Facilitated by the singular elements, the displacement extrapolation technique is employed to calculate the stress intensity factor. Crack direction is predicted using the maximum circumferential stress theory. The fracture was modeled by the splitting node approach and the trajectory follows the successive linear extensions of each crack increment. The propagation process is driven by Linear Elastic Fracture Mechanics (LEFM) approach with minimum user interaction. Results: In evaluating the accuracy of the estimated stress intensity factors and the crack path predictions, the results were compared with sets of experimental data, benchmark analytical solutions as well as numerical results of other researchers. Conclusion/Recommendations: The assessment indicated that the program was highly reliable to evaluate the stress intensity factors and successfully predicts the cracks trajectories. Based on the results, it was recommended to add further development in the software to simulate crack propagation in elastoplastic materials.

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“…This is possible through enrichment of the standard polynomial finite element space with special functions: discontinuous, to account for the displacement jump, and crack-tip fields to reduce the mesh density required for accurate fracture parameter computations. The method is now becoming quite mature, and has already been applied to industrial fracture mechanics problems [5]. Some elements are split by the crack and others contain the crack tips.…”

Section: Crack Modeling With Partition Of Unity Enrichmentmentioning

confidence: 99%

Mechanical Failure in Microstructural Heterogeneous Materials

Bordas

Hoppe

Petrova

2007

Numerical Methods and Applications

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Enriched finite elements and level sets for damage tolerance assessment of complex structures

Cited by 150 publications

References 35 publications

Derivative recovery and a posteriori error estimate for extended finite elements

Derivative recovery and a posteriori error estimate for extended finite elements

Development of Efficient Finite Element Software of Crack Propagation Simulation using Adaptive Mesh Strategy

Mechanical Failure in Microstructural Heterogeneous Materials

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