Effects of Ply Misalignment in Material Characterization of Composite Laminates

Effects of Ply Misalignment in Material Characterization of Composite Laminates

Carbon fiber reinforced plastic (CFRP) parts find a rising number of applications as structural components. Therefore, new manufacturing technologies are developed, enabling high volume production of such parts. With those higher volumes, variation management during product design becomes more criti...

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Bibliographic Details
Main Authors: Michael Franz, Racim Radjef, Boris Eisenbart, Sandro Wartzack
Format: Article
Language:English
Published: MDPI AG 2024-11-01
Series:Fibers
Subjects:
CFRP
material characterization
mechanical properties
variation analysis
ply angles
Online Access:https://www.mdpi.com/2079-6439/12/12/103
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Summary:Carbon fiber reinforced plastic (CFRP) parts find a rising number of applications as structural components. Therefore, new manufacturing technologies are developed, enabling high volume production of such parts. With those higher volumes, variation management during product design becomes more critical. While manufacturing variations in CFRP materials occur on different scales, detecting and considering those on the meso (ply) scale becomes more important. Thus, the question arises whether such variations can be detected with standardized testing methods. In this study, artificial fiber misalignment has been introduced into the outer plies of standardized tensile specimens to explore the influence of such variations on the mechanical properties. A simulation model was developed to identify these variations and the test results were used to calibrate and optimize the material parameters of the simulation model. The effects of the artificially induced variation were distinguishable in the test data as well as in the simulation models. Furthermore, the simulation models showed good agreement with the experimental data, which leads to the conclusion that the utilized measuring techniques are well suited to characterize the fiber misalignment. The developed simulation models can be used to investigate the effects of fiber misalignment within the product development process without the need for physical testing.
ISSN:2079-6439

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