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A source‐sink model for water diffusion in an activated carbon fiber/phenolic composite
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Cris Arnold ,
Martin Swan,
Corinne Stone
Polymer Composites, Volume: 42, Issue: 7, Pages: 3550 - 3561
Swansea University Authors:
Sue Alston , Cris Arnold
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DOI (Published version): 10.1002/pc.26078
Abstract
The moisture absorption behavior of a composite comprising phenolic resin and activated carbon fibers was characterized. The resin starts with a water content from curing and the active fibers both adsorb water on their surface and absorb water in sub-surface pores, acting as a sink or source of wat...
| Published in: | Polymer Composites |
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| ISSN: | 0272-8397 1548-0569 |
| Published: |
Wiley
2021
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| Online Access: |
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| URI: | https://cronfa.swan.ac.uk/Record/cronfa56994 |
| Abstract: |
The moisture absorption behavior of a composite comprising phenolic resin and activated carbon fibers was characterized. The resin starts with a water content from curing and the active fibers both adsorb water on their surface and absorb water in sub-surface pores, acting as a sink or source of water. Measured data showed that the dependence of this water uptake on the surrounding relative humidity was highly nonlinear, and that the effective diffusion rate through the composite was very dependent on the starting and end conditions. A physically based model has been successfully developed to simulate this behavior. Diffusion was assumed to be Fickian and entirely through the resin, with a linear dependence of resin water content on external humidity. Water movement between resin and fibers was determined so as to maintain equilibrium, based on measured steady-state water uptake curves across a range of relative humidities. This meant that in mid-range humidities, most water movement was between fibers and resin rather than through the resin, giving low effective diffusion rates. This model and a simple Arrhenius expression for the diffusion coefficient through the resin enabled measured composite diffusion behavior to be accurately predicted over a range of temperatures and humidity changes. |
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| Keywords: |
adsorption; composites; computer modeling; diffusion |
| College: |
Faculty of Science and Engineering |
| Funders: |
This work was supported by the Defence Science and Technology Laboratory, UK. |
| Issue: |
7 |
| Start Page: |
3550 |
| End Page: |
3561 |