Monitoring the continuous manufacture of a polymeric foam via a thermokinetic-informed acoustic technique

Polymer foams are difficult to characterise due to rapidly evolving physical features from liquid to porous solid. Swift changes in volume, porosity and moduli render many techniques challenging for the characterisation of the foam curing during a manufacturing process. A technique that employs the...

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Bibliographic Details
Published in:Proceedings of the Institution of Mechanical Engineers. Part E, Journal of process mechanical engineering Journal of process mechanical engineering, 2021-12, Vol.235 (6), p.1998-2007
Main Authors: Holt, Joseph A, Torres-Sanchez, Carmen, Conway, Paul P
Format: Article
Language:English
Subjects:
Cure monitoring
Curing
Electrical properties
Mechanical properties
Mechanical tests
Physical properties
Plastic foam
Poisson's ratio
Polymers
Polyurethane foam
Sound
Stiffness
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Summary:Polymer foams are difficult to characterise due to rapidly evolving physical features from liquid to porous solid. Swift changes in volume, porosity and moduli render many techniques challenging for the characterisation of the foam curing during a manufacturing process. A technique that employs the longitudinal speed of sound of an ultrasonic signal, informed by a thermokinetic model, is proposed as an in situ, in-line, non-destructive and continuous monitoring tool during the production of rigid polyurethane foams. This study demonstrates that speed of sound measurements are suitable for (a) continuous characterisation of different foaming stages in the polymer reaction and curing; (b) determining the degree of cure for the continuous monitoring of foams, and (c) predicting mechanical properties (i.e., stiffness and Poisson's ratio) of cured foam samples. The validity of this monitoring technique is confirmed by comparison with well-established methods that use physical characteristics (e.g., expansion rate, electrical properties), thermo-kinetic models and mechanical testing. This method positions itself as a monitoring tool and convenient method for determining material stiffness during production.
ISSN:0954-4089
2041-3009
DOI:10.1177/09544089211026549