Modeling Fatigue Crack Growth in CFRP Adhesively Bonded Substrate Using XFEM

Al-Dakheel, Hussain; Temitope, Idris; Albinmousa, Jafar; Al-Athel, Khaled S.

doi:10.1115/imece2020-23537

Cited by 3 publications

(1 citation statement)

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“…A parametric analysis was also performed to get several mechanical responses. Al-Dakheel et al [43] model the fatigue crack propagation in CFRP composites using the XFEM technique on ANSYS software. The correction factor for the energy release rate was calculated using the CZM technique, and the number of cycles was calculated using Paris law.…”

Section: Xfemmentioning

confidence: 99%

Mode-I Interlaminar Fracture Modeling of DCB Composite Laminate using Finite Element Techniques

Sharma

Mali

Dixit

2023

Preprint

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The interlaminar fracture is the most common type of failure in polymeric textile composites because these composites are prone to delaminate under the influence of external loading. Depending on the type of deformation, the interlayer fracture can be Mode-I, Mode-II, Mode-III, and Mixed Mode-I/II type. In this research work, Mode-I interlaminar fracture modeling of carbon fiber reinforced polymer (CFRP) composite laminate is performed using a double cantilever beam (DCB) test specimen on ABAQUS software as a cost-effective numerical simulation approach. The finite element based fracture modeling techniques, virtual crack closure technique (VCCT), cohesive zone modeling (CZM), and extended finite element method (XFEM) were employed under the two-dimensional and three-dimensional interlayer crack propagation to evaluate the load-displacement responses. The interaction properties were applied between the top and bottom part of DCB specimen and the adhesive layer was modeled using the CZM approach. The numerically simulated responses were compared with the published experimental load-displacement responses and found to be in good agreement. All the fracture modeling approaches validate the experimental trend, however the three-dimensional XFEM technique was found to be the most suitable modeling approach for crack growth in adhesively bonded parts. The stress based criteria was used for crack initiation, whereas the energy based approach used for crack propagation in DCB laminate. The parametric study of various fracture parameters (cohesive strength, fracture energy, interfacial stiffness, laminate thickness, and pre-crack length) were also conducted to understand their effects on load-displacement responses of the Mode-I interlaminar fracture. The fracture modeling approaches were compared by considering the element type, shape, total elements, accuracy, run-time, increments, and convergence speed.

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Section: Xfemmentioning

confidence: 99%

Mode-I Interlaminar Fracture Modeling of DCB Composite Laminate using Finite Element Techniques

Sharma

Mali

Dixit

2023

Preprint

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Mode-I interlaminar fracture modeling of DCB composite laminate using finite element techniques

Sharma,

Mali,

Dixit

2023

J Braz. Soc. Mech. Sci. Eng.

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Characterizing Cohesive Zone Parameters to Model Crack Growth in Composite Materials

Al-Dakheel

Albinmousa

Temitope

2022

Day 2 Tue, February 22, 2022

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CFRP is gaining interest in several industries such as aerospace, sports, and oil field. When this material is assembled, the adhesive is considered a preference over screws and fasteners as screws holes can lead to matrix delamination. Prior applying an adhesive, surface pre-treatment is done to enhance bonding. Due to the complexity of the composite material namely in complex geometry, one can consider finite element analysis as an optimum method to model the material behavior. Failure of crack growth under cyclic loading is typically modeled using the CZM. However, finding the constitutive behavior parameters is considered challenging. In this work, the maximum stress, which is difficult to calculate experimentally, is estimated using the virtual closure technique (VCCT) as it is considered less complicated and costy than the conventional methods. The VCCT is a finite element method that is employed to simulate monotonic crack growth. From this model, the maximum stress is recorded and used as the maximum traction stress in the cohesive zone model (CZM) to simulate fatigue crack growth. The bilinear traction separation law was employed to simulate the cohesive process zone. To calibrate the model results, an experiment is conducted on two samples those were treated by two different methods. One sample has a sandblasting surface pre-treatment and the other is pre-treated by peelply. Each pre-treatment enhances different material toughness and hence validity of the results if supported. Both samples were tested under both static and cyclic loadings. The maximum energy release rate and the crack length were selected as comparison parameters between the models results and the experimental observations. Overall, it was noticed that the results are considered having reasonable fit.

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Modeling Fatigue Crack Growth in CFRP Adhesively Bonded Substrate Using XFEM

Cited by 3 publications

References 0 publications

Mode-I Interlaminar Fracture Modeling of DCB Composite Laminate using Finite Element Techniques

Mode-I Interlaminar Fracture Modeling of DCB Composite Laminate using Finite Element Techniques

Mode-I interlaminar fracture modeling of DCB composite laminate using finite element techniques

Characterizing Cohesive Zone Parameters to Model Crack Growth in Composite Materials

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