Processing maps based on polymerization modelling of thick methacrylic laminates

Control of the in-situ polymerization of thick methacrylic laminates is essential to minimize cavitation due to monomer boiling. To this end, a computationally efficient thermochemical model is developed to predict the temperature and degree of monomer conversion during polymerization of a methyl me...

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Bibliographic Details
Published in:Materials & design 2020-11, Vol.196, p.109170, Article 109170
Main Authors: Gayot, Sarah F., Bailly, Christian, Pardoen, Thomas, Gérard, Pierre, Van Loock, Frederik
Format: Article
Language:English
Subjects:
Methyl methacrylate
Polymer-matrix composite
Polymerization kinetics
Process monitoring
Thermochemical model
Thermoplastic resin
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Summary:Control of the in-situ polymerization of thick methacrylic laminates is essential to minimize cavitation due to monomer boiling. To this end, a computationally efficient thermochemical model is developed to predict the temperature and degree of monomer conversion during polymerization of a methyl methacrylate (MMA)-based resin in a fibrous preform. The model couples the self-accelerating exothermic free-radical bulk polymerization of MMA (gel effect) with the heat transfer within the preform and to the environment. The predicted temperature profiles are in excellent agreement with experimental data measured during a series of in-situ polymerization tests with different heating conditions and preform thicknesses. Processing diagrams are constructed to reveal the regimes of interest for the production of thick fiber-reinforced methacrylic composites without voids induced by monomer boiling. [Display omitted] •Thick composite laminates are produced via vacuum infusion and in-situ polymerization of a methyl methacrylate-based resin.•Monomer boiling due to the self-accelerating polymerization reaction can lead to macro-sized voids in the laminate.•A thermochemical model is developed to predict the maximum temperature within the laminate during in-situ polymerization.•The predicted temperature profiles are in excellent agreement with those measured for different processing conditions.•Processing maps reveal optimal heating conditions leading to short cycle times without thermally-induced cavitation.
ISSN:0264-1275
1873-4197
DOI:10.1016/j.matdes.2020.109170