Modelling fracture and delamination in composite laminates: Energy release rate and interface stress

Curiel-Sosa, J.L.; Tafazzolimoghaddam, Behrooz; Zhang, Chao

doi:10.1016/j.compstruct.2018.02.006

Cited by 44 publications

(13 citation statements)

References 32 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Hence, a discrete segmentation of the piezoelectric layer may be required. Furthermore, considering the failure analysis, fracture and delamination in the piezoelectric composite laminates [59] may need to be addressed in the future, as well as the fracture during flight operation [60]. In addition, an evaluation on continuous gust or turbulence disturbance may also be considered for the future works.…”

Section: Resultsmentioning

confidence: 99%

An iterative finite element method for piezoelectric energy harvesting composite with implementation to lifting structures under Gust Load Conditions

Akbar

Curiel-Sosa

2019

Composite Structures

Self Cite

View full text Add to dashboard Cite

In this paper, a novel iterative finite element method (FEM) for energy harvesting purpose is presented. The new iterative FEM is implemented to solve the dynamic problems of piezoelectric-based energy harvester in the frequency and time domains. The validation against other methods from the literature shows the robustness and capabilities of the iterative FEM. Implementation to a transport aircraft wingbox with 14.5 m half span and an embedded piezoelectric layer is shown in some details. The energy harvesting potential of the wingbox due to the cruise and the 1-cosine gust loads is investigated. In addition, for the first time, stress and failure analyses of the structure with an active energy harvesting layer are performed. The results pointed out that the wingbox is still in a safe condition even when it is subjected to a 30 m/s gust amplitude while harvesting 51 kW power.

show abstract

Section: Resultsmentioning

confidence: 99%

An iterative finite element method for piezoelectric energy harvesting composite with implementation to lifting structures under Gust Load Conditions

Akbar

Curiel-Sosa

2019

Composite Structures

Self Cite

View full text Add to dashboard Cite

show abstract

“…Similarly, in pushout delamination as the tool reaches the bottom-most layers in the composite, the intact plies under the drill are easily delaminated and undergo bending with the decreasing thickness of the composite. Push out delamination due to combined mode I and mode II failure is represented in Figure 4(b) (Anand & Patra, 2017;Curiel-Sosa et al, 2018;Geier, Davim et al, 2019;Rahme et al, 2015). The stress-induced between the layers transcends to the bond strength between the layers.…”

Section: Types Of Delaminationmentioning

confidence: 99%

A review on strengthening, delamination formation and suppression techniques during drilling of CFRP composites

Rathod

Patel

et al. 2021

Cogent Engineering

View full text Add to dashboard Cite

Carbon fiber-reinforced composite laminates are progressively appealing for several applications in various manufacturing sectors such as aeronautical and automobile, because of their amazingly predominant mechanical properties. This has subsequently led to an increase in research of various machinability techniques emphasizing on both conventional and non-conventional methods. Typically, conventional drilling is one of the most significant machining processes for most kinds of fiber composite laminates. The most unsolicited damage termed as delamination during drilling has recently become one of the most influential research subjects as numerous engineers in manufacturing sector have been trying to prevent this problem over decades. This review paper briefly discusses about the incorporation of different types of fillers in carbon fiber-reinforced composites. The paper also summarizes the steady progress in drilling-induced delamination of carbon fiber laminates. It covers the delamination formation mechanism, delamination suppression strategies, and the optimization of various drilling parameters to reduce the delamination damage. The present article provides researchers an opportunity to deepen their knowledge on specific aspects by exploring different methods for reducing delamination in CFRP composites.

show abstract

“…However, for the first time, in this paper, XFEM is combined with the Rousselier model, thus enabling the crack to propagate while keeping the observation of the void volume fraction. Hence, the energy concentration exerted by the crack is released when the crack propagated (Curiel-Sosa et al, 2018;Tafazzolimoghaddam and Curiel-Sosa, 2015) and resulted in a much lower void volume fraction compared to the case without crack extension. Nevertheless, the results are still can be acceptable in a purpose to predict the void damage formation with crack development.…”

Section: Computational Tests Lorentz Notched Rod Specimenmentioning

confidence: 99%

An enhanced void-crack-based Rousselier damage model for ductile fracture with the XFEM

Ahmad

Curiel-Sosa

Arun

et al. 2018

International Journal of Damage Mechanics

View full text Add to dashboard Cite

This work presents a modelling strategy for ductile fracture materials by implementing the Rousselier damage model with the extended finite element method (XFEM). The implicit integration scheme and consistent tangent modulus (CTM) based on a radial return mapping algorithm for this constitutive model are developed by the user-defined material subroutine UMAT in ABAQUS/ Standard. To enhance the modelling of the crack development in the materials, the XFEM is used that allows modelling of arbitrary discontinuities, where the mesh does not have to be aligned with the boundaries of material interfaces. This modelling strategy, so-called Rousselier-UMAT-XFEM (RuX) model is proposed to connect both concepts, which gives an advantage in predicting the material behaviour of ductile material in terms of voids and crack relation. This is the first contribution where XFEM is used in ductile fracture analysis for micromechanical damage problems. The results indicate that the RuX model is a promising technique for predicting the void volume fraction damage and crack extension in ductile material, which shows a good agreement in terms of stress-strain and force-displacement relationships.

show abstract

Modelling fracture and delamination in composite laminates: Energy release rate and interface stress

Cited by 44 publications

References 32 publications

An iterative finite element method for piezoelectric energy harvesting composite with implementation to lifting structures under Gust Load Conditions

An iterative finite element method for piezoelectric energy harvesting composite with implementation to lifting structures under Gust Load Conditions

A review on strengthening, delamination formation and suppression techniques during drilling of CFRP composites

An enhanced void-crack-based Rousselier damage model for ductile fracture with the XFEM

Contact Info

Product

Resources

About