Predicting Stress Intensity Factor for Aluminum 6062 T6 Material in L-Shaped Lower Control Arm (LCA) Design Using Extended Finite Element Analysis

El Fakkoussi, Said; Vlase, Sorin; Marin, Marin; Koubaiti, Ouadie; Elkhalfi, Ahmed; Moustabchir, Hassane

doi:10.3390/ma17010206

Cited by 2 publications

(1 citation statement)

References 23 publications

(44 reference statements)

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“…In surface-based cohesive behavior, the material along the crack is modeled using a set of traction–separation laws. This approach has been widely used in various engineering applications, including the analysis of cracked structures [ 29 , 30 ] and failure prediction of composite materials [ 31 ]. The failure mechanism includes two parameters: the damage initiation and damage evolution criteria.…”

Section: Theoretical Backgroundmentioning

confidence: 99%

Numerical Study of Crack Prediction and Growth in Automotive Wheel Rims

Montassir,

Moustabchir,

El Khalfi

et al. 2024

Materials

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Finite element analysis has become an essential tool for simulating and understanding crack growth. This technique holds significant importance in the field of mechanical engineering, where it finds wide application in the design and optimization of structural components and material properties. This work began with the identification of critical zones and estimated the number of load life repeats through fatigue analysis, specifically applied to automotive rims utilizing innovative finite element methods. To investigate crack behavior, we are used the Extended Finite Element Method (XFEM) with the volumetric approach to compute the Stress Intensity Factor (SIF). The results obtained by our study align closely with experimental tests in terms of detecting the critical zone where a crack can appear. Our findings contribute to the understanding of fatigue behavior in automotive rims, offering new insights into their structural integrity and performance under various load conditions.

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Section: Theoretical Backgroundmentioning

confidence: 99%

Numerical Study of Crack Prediction and Growth in Automotive Wheel Rims

Montassir,

Moustabchir,

El Khalfi

et al. 2024

Materials

Self Cite

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Numerical Analysis of the Cylindrical Shell Pipe with Preformed Holes Subjected to a Compressive Load Using Non-Uniform Rational B-Splines and T-Splines for an Isogeometric Analysis Approach

EL Fakkoussi,

Koubaiti,

Elkhalfi

et al. 2024

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In this paper, we implement the finite detail technique primarily based on T-Splines for approximating solutions to the linear elasticity equations in the connected and bounded Lipschitz domain. Both theoretical and numerical analyses of the Dirichlet and Neumann boundary problems are presented. The Reissner–Mindlin (RM) hypothesis is considered for the investigation of the mechanical performance of a 3D cylindrical shell pipe without and with preformed hole problems under concentrated and compression loading in the linear elastic behavior for trimmed and untrimmed surfaces in structural engineering problems. Bézier extraction from T-Splines is integrated for an isogeometric analysis (IGA) approach. The numerical results obtained, particularly for the displacement and von Mises stress, are compared with and validated against the literature results, particularly with those for Non-Uniform Rational B-Spline (NURBS) IGA and the finite element method (FEM) Abaqus methods. The obtained results show that the computation time of the IGA based on the T-Spline method is shorter than that of the IGA NURBS and FEM Abaqus/CAE (computer-aided engineering) methods. Furthermore, the highlighted results confirm that the IGA approach based on the T-Spline method shows more success than numerical reference methods. We observed that the NURBS IGA method is very limited for studying trimmed surfaces. The T-Spline method shows its power and capability in computing trimmed and untrimmed surfaces.

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Predicting Stress Intensity Factor for Aluminum 6062 T6 Material in L-Shaped Lower Control Arm (LCA) Design Using Extended Finite Element Analysis

Cited by 2 publications

References 23 publications

Numerical Study of Crack Prediction and Growth in Automotive Wheel Rims

Numerical Study of Crack Prediction and Growth in Automotive Wheel Rims

Numerical Analysis of the Cylindrical Shell Pipe with Preformed Holes Subjected to a Compressive Load Using Non-Uniform Rational B-Splines and T-Splines for an Isogeometric Analysis Approach

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