Composite materials used in the fabrication of industrial products/compo nents are under constant development. Applications vary widely from consumer products to high-performance aerospace components. The pultrusion process is one of the impor tant methods of production of composite materials. In order to develop a fundamental understanding of this process, a computational model employing the finite element method is developed which enables a prediction of the material temperature and degree-of-cure at any time during the process. The model is comprehensive; it can readily be employed to perform parametric studies of the process and to aid in the development of efficient design procedures for this type of material system. Comparisons are made between model predic tions and experimental results and good agreement is observed.
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