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Pyrolytic Kinetics of Polystyrene Particle in Nitrogen Atmosphere: Particle Size Effects and Application of Distributed Activation Energy Method

Lin Jiang, Xinrui Yang, Xu Gao, Qiang Xu, Oisik Das, Jinhua Sun, Manja Kitek Kuzman

2020Polymers33 citationsDOIOpen Access PDF

Abstract

This work was motivated by a study of particle size effects on pyrolysis kinetics and models of polystyrene particle. Micro-size polystyrene particles with four different diameters, 5, 10, 15, and 50 µm, were selected as experimental materials. Activation energies were obtained by isoconversional methods, and pyrolysis model of each particle size and heating rate was examined through different reaction models by the Coats–Redfern method. To identify the controlling model, the Avrami–Eroféev model was identified as the controlling pyrolysis model for polystyrene pyrolysis. Accommodation function effect was employed to modify the Avrami–Eroféev model. The model was then modified to f(α) = nα0.39n − 1.15(1 − α)[−ln(1 − α)]1 − 1/n, by which the polystyrene pyrolysis with different particle sizes can be well explained. It was found that the reaction model cannot be influenced by particle geometric dimension. The reaction rate can be changed because the specific surface area will decrease with particle diameter. To separate each step reaction and identify their distributions to kinetics, distributed activation energy method was introduced to calculate the weight factor and kinetic triplets. Results showed that particle size has big impacts on both first and second step reactions. Smaller size particle can accelerate the process of pyrolysis reaction. Finally, sensitivity analysis was brought to check the sensitivity and weight of each parameter in the model.

Topics & Concepts

PolystyreneActivation energyMaterials scienceParticle sizePyrolysisParticle (ecology)Pyrolytic carbonKineticsThermodynamicsChemical kineticsChemical engineeringOrder of reactionKinetic energyComposite materialPhysical chemistryReaction rate constantChemistryPolymerPhysicsOceanographyGeologyEngineeringQuantum mechanicsThermochemical Biomass Conversion ProcessesThermal and Kinetic AnalysisPolymer crystallization and properties