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Prediction of Residual Stress in Carbon Fiber Reinforced LM- PAEK Composites

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Abstract:

Residual internal stresses arise during thermal processing of thermoplastic composites due to differential shrinkage of stacked orthotropic plies and can lead to defects such as shape distortion, microcracking or delamination. In the current study, a comprehensive thermomechanical model for predicting residual stresses and strains in semicrystalline thermoplastic composites is presented with specific application to unidirectional Carbon fiber reinforced LM-PAEK composite laminates. The model is based on an incremental Classical Laminate Theory (CLT) framework that incorporates temperature-dependent material properties and accounts for both thermal and crystallization-induced shrinkage effects. Material characterization is performed to measure key temperature-dependent properties: thermomechanical analysis (TMA) is used to measure the transverse thermal expansion coefficient (CTE) and crystallization shrinkage upon cooling from melt state, dynamic mechanical analysis (DMA) to obtain the transverse modulus. The stress-free temperature, the temperature at which residual stresses begin to develop, is identified through curvature evolution measurements of unsymmetric laminates using image analysis. The model validation is performed via curvature measurements of unsymmetric cross-ply laminates using laser scanning techniques, demonstrating good agreement between model predictions and experimental measurements.

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Periodical:

Materials Science Forum (Volume 1182)

Pages:

113-123

DOI:

https://doi.org/10.4028/p-H1MHkN

Citation:

Cite this paper

Online since:

April 2026

Authors:

Manoj R. Gongati*, Laurent Warnet, Francesco Rondina, Edwin T.J. Klompen, Remko Akkerman

Keywords:

Residual Stress, Thermoplastic Composites, Unsymmetric Laminates

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Creative Commons CC BY 4.0

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* - Corresponding Author

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