Abstract
Producing precision parts requires good control of the production parameters. When casting thermoset polymers an understanding of the curing process, with its heat release and associated temperature changes, is important. This paper describes how the cure of a polymer of unknown detailed chemical composition in a large part can be predicted and how the necessary material properties required for the predictions can be obtained. The approach given is a relatively simple method that a part manufacturer can perform. It will not characterize chemical reactions in detail, but it gives sufficient accuracy to describe the process. The procedures will be explained for an example of casting a large block of a filled two-component thermoset polyurethane. The prediction of the degree of cure, the associated heat and temperature increase during the curing of a polymer was successfully done using a standard finite element program with the input parameters reaction energy, the Arrhenius pre-factor and the kinetic function, which describes the chemical reaction. The three parameters could be obtained with standard Differential Scanning Calorimetry (DSC) equipment. The data were analyzed with the model-free isoconversional method combined with the compensation effect. The same set of parameters allowed the prediction of experimental cure behavior over two orders of magnitude of time and at a curing temperature range from room temperature up to 420 K.
Highlights
Good control of the production parameters is required for producing precision parts
The data were analyzed with the model-free isoconversional method combined with the compensation effect
The results have shown that the kinetic triplet describing the curing of a polymer can be obtained by straightforward experimental Differential Scanning Calorimetry (DSC) measurements
Summary
Good control of the production parameters is required for producing precision parts. When casting thermoset polymers an important and fundamental aspect is the understanding of the curing process [1,2,3,4,5]. A complete cure is required to obtain good mechanical properties. Curing causes shrinkage that can influence the surface quality of the component. When the heat cannot be removed from the inside of the component, temperature increases substantially and the properties of the polymer may degrade, even leading to a fire in the worst case. The control of the heat development is especially important for big components having a large volume to surface ratio, since, due to the low heat conductivity of most polymers, the heat cannot be removed [13,14]
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