Analytical solution for first ply failure analysis of laminated plates using Reddy-Legendre higher-order theory

The existing finite element formulation generally leads to overestimation on the first ply failure (FPF) load. Reasons of this phenomenon have been less cleared in detail. Therefore, it requires to propose an analytical solution to provide an accurate prediction of the FPF with the high efficiency-c...

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Bibliographic Details
Published in:Mechanics of advanced materials and structures 2024-03, Vol.31 (5), p.1043-1058
Main Authors: Zhou, Jie, Wu, Zhen, Liu, Zhengliang, Xiaohui, Ren
Format: Article
Language:English
Subjects:
analytical solution
Composite laminate
Composite structures
Constitutive equations
Constitutive relationships
Exact solutions
Failure analysis
Failure modes
Finite element method
first ply failure
Laminar composites
Mathematical models
Plates (structural members)
Polynomials
Reddy-Legendre
Shear deformation
Shear stress
Stacking sequence (composite materials)
Stress distribution
Transverse loads
Transverse shear
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Summary:The existing finite element formulation generally leads to overestimation on the first ply failure (FPF) load. Reasons of this phenomenon have been less cleared in detail. Therefore, it requires to propose an analytical solution to provide an accurate prediction of the FPF with the high efficiency-cost ratio. To this end, the following work has been carried out: (1) Legendre polynomials as local terms are first introduced into Reddy-type higher-order theory, which provide a novel alternative form of global-local displacement field. (2) Compared with the classical first-order and higher-order shear deformation theories, the proposed model can predict transverse shear stresses directly by constitutive equations which is close to the results obtained by the three-dimensional finite element method (3D-FEM). Therefore, the accuracy and efficiency of the FPF analysis can be improved, attributing to the accurate prediction of the quasi-three-dimensional stress field. (3) The static response and the FPF of laminated composite plates are analyzed, which have been compared with the results of selected models in the published literature and 3D-FEM. Influences of different failure theories, transverse loads, stacking sequence on prediction of the FPF loads are also explored. (4) By visualizing full-field displacement, stress and damage variables rather than those obtained from key points, it is easier to find the failure tendency and the failure modes. As a result, it is necessary to propose an analytical solution for predicting the FPF of composite laminated plates, which can provide a reference for other investigators.
ISSN:1537-6494
1537-6532
DOI:10.1080/15376494.2022.2129529