Modeling of water wicking along fiber/matrix interface voids in unidirectional carbon/vinyl ester composites
Modeling of water wicking along fiber/matrix interface voids in unidirectional carbon/vinyl ester composites
Void formation at the fiber/matrix (F/M) interface is known to be a primary structural defect in a composite material. It is a major factor that contributes to the water uptake in composite materials for underwater applications. We develop a mathematical model to describe the kinetics of water uptake in unidirectional fiber reinforced resin composites containing voids. By using a one-dimensional two-phase fluid flow model with parameters derived from Microcomputed X-ray tomography (µCT), we predict the water wicking process in carbon/vinylester (CF/VE) panels containing capillary voids at the F/M interphase. The capillary driven flow is impeded by viscous forces and the compressed air bubble, trapped between the two flow fronts. In particular, our calculation indicates that the effective contact angle at the F/M interface in CF/VE composite is 29.7 ± 0.1° for the equivalent capillary radius of 1.2 µm. The results are validated by comparing the simulated water absorption to the experimental data for CF/VE composite specimens of three different sizes immersed in sea water.
Dona, Kalpani N U Galpayage
6f38dda1-23f0-4e00-b2b9-772b0852de9f
Du, E
48a0ae64-261d-4d42-a7a2-2b59b54f7d88
Carlsson, Leif A
9611eaaa-f456-45b6-a4e9-2fd9a04a4f01
Fletcher, Daniel McKay
60e9adeb-182b-4dfd-846a-b684f8e2358e
Boardman, Richard P
5818d677-5732-4e8a-a342-7164dbb10df1
May 2020
Dona, Kalpani N U Galpayage
6f38dda1-23f0-4e00-b2b9-772b0852de9f
Du, E
48a0ae64-261d-4d42-a7a2-2b59b54f7d88
Carlsson, Leif A
9611eaaa-f456-45b6-a4e9-2fd9a04a4f01
Fletcher, Daniel McKay
60e9adeb-182b-4dfd-846a-b684f8e2358e
Boardman, Richard P
5818d677-5732-4e8a-a342-7164dbb10df1
Dona, Kalpani N U Galpayage, Du, E, Carlsson, Leif A, Fletcher, Daniel McKay and Boardman, Richard P
(2020)
Modeling of water wicking along fiber/matrix interface voids in unidirectional carbon/vinyl ester composites.
Microfluidics and Nanofluidics, 24 (31).
(doi:10.1007/s10404-020-02332-8).
Abstract
Void formation at the fiber/matrix (F/M) interface is known to be a primary structural defect in a composite material. It is a major factor that contributes to the water uptake in composite materials for underwater applications. We develop a mathematical model to describe the kinetics of water uptake in unidirectional fiber reinforced resin composites containing voids. By using a one-dimensional two-phase fluid flow model with parameters derived from Microcomputed X-ray tomography (µCT), we predict the water wicking process in carbon/vinylester (CF/VE) panels containing capillary voids at the F/M interphase. The capillary driven flow is impeded by viscous forces and the compressed air bubble, trapped between the two flow fronts. In particular, our calculation indicates that the effective contact angle at the F/M interface in CF/VE composite is 29.7 ± 0.1° for the equivalent capillary radius of 1.2 µm. The results are validated by comparing the simulated water absorption to the experimental data for CF/VE composite specimens of three different sizes immersed in sea water.
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Published date: May 2020
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Local EPrints ID: 453720
URI: http://eprints.soton.ac.uk/id/eprint/453720
ISSN: 1613-4982
PURE UUID: 56a442ba-037f-431d-8b59-5a188ff7e68c
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Date deposited: 21 Jan 2022 17:39
Last modified: 17 Mar 2024 02:58
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Author:
Kalpani N U Galpayage Dona
Author:
E Du
Author:
Leif A Carlsson
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