Effect of reparation on the mechanical behavior of glass fibers/Elium acrylic laminate composites: Experimental and numerical approaches

Effect of reparation on the mechanical behavior of glass fibers/Elium acrylic laminate composites: Experimental and numerical approaches

Elium® Acrylic/Glass Fiber thermoplastic laminate composites are liable to develop irreversible local defects under quasi‐static loading. To reinforce the damaged material, repair is a cost‐effective mechanical alternative. The present study investigates the tensile behavior of an Elium® glass‐fiber...

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Bibliographic Details
Published in:Polymer composites Vol. 45; no. 7; pp. 6385 - 6403
Main Authors: Koumba, N., Boumbimba, R. Matadi, Bonfoh, N., Eba, F., Wary, M.
Format: Journal Article
Language:English
Published: Hoboken, USA John Wiley & Sons, Inc 10-05-2024
Blackwell Publishing Ltd
Subjects:
Acrylic resins
Bonding
Damage
Elium acrylic
Fiberglass
Finite element method
finite elements
Glass fiber reinforced plastics
Laminar composites
laminate composite
Laminates
Mechanical properties
repair
Tensile strength
tensile tests
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Summary:Elium® Acrylic/Glass Fiber thermoplastic laminate composites are liable to develop irreversible local defects under quasi‐static loading. To reinforce the damaged material, repair is a cost‐effective mechanical alternative. The present study investigates the tensile behavior of an Elium® glass‐fiber‐based acrylic laminate composite panel, repaired by vacuum bonding with Elium® repair resin and double overlap of external patches (DP). The results obtained for all repaired laminate composites E190/GF_D(10, 20, 30)R with diameters 10, 20, and 30 mm showed an improvement in the mechanical properties of the repaired panels, compared with the drilled and pristine samples. Average load recovery rates were significant for E190/GF_D10R (7.9%, 3.55%, 13%) E190/GF_D20R (23%, 18%, 3.32%), E190/GF_D30R (7.2%, 9.36%, 32.37%) at strain rates of 0.001, 0.01, and 0.05 s−1 respectively. Finite element (FE) models for the virgin, drilled, and repaired composite, performed by coupling the Hashin criteria with the cohesive zone model (CZM), provided a relevant prediction of intra‐ and interlaminar failures of these woven laminated composites. Highlights The effect of vacuum bonding repair with Elium E351 EOT resin was studied. Symmetrical repair of acrylic laminate drilled by fiberglass patches. Tensile strength of the repaired laminates was investigated. Intra‐ and interlaminar damage was predicted by finite elements modeling. Experimental and numerical tensile behavior of a glass fibers/Elium acrylic, after repaire
ISSN:0272-8397
1548-0569
DOI:10.1002/pc.28204