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A comprehensive chemical model for the preliminary steps of thermal stabilization process in carbon fibre manufacturing line

Abstract

Thermal stabilisation process of the carbon fibre production line, as an energy consuming oxidation reaction, is diffusion limited. Therefore the kinetic parameters, estimated from traditional methods, cannot be applied due to the significance of oxygen diffusivity. Moreover, this process involves a multiple chemical reaction system, which is interconnected and often too complex to explain via analytical frameworks. One common solution to comprehend such process and optimise its parameters is mathematical deterministic models. In the present study, a comprehensive deterministic model was developed to predict the kinetic parameters with a finite number of experiments by an optimisation algorithm. Then the model was used to study the progress of the process, particularly in the first steps of the process to explain the decrement of C=O bonds in oxidised fibre by adding a reduction step to stabilisation mechanism and considering the role of oxygen as a catalyst in cyclisation. The developed model is based on the structure of the PAN precursor, fibre tow and the governing differential equations for the underlying phenomena, including chemical kinetics and mass transfer, associated with empirical relations for oxygen diffusivity and physical properties in the isothermal condition. The results presented up to 95% improvement in outcomes of the model for a pilot carbon fibre production line.

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Publication details

The article was received on 09 Aug 2018, accepted on 11 Oct 2018 and first published on 12 Oct 2018


Article type: Paper
DOI: 10.1039/C8RE00164B
Citation: React. Chem. Eng., 2018, Accepted Manuscript
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    A comprehensive chemical model for the preliminary steps of thermal stabilization process in carbon fibre manufacturing line

    K. Badii, G. Golkarnarenji, A. S. Milani, M. Naebe and H. Khayyam, React. Chem. Eng., 2018, Accepted Manuscript , DOI: 10.1039/C8RE00164B

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