Pyrolysis of municipal solid waste: Kinetics and thermodynamic parameters via Coats-Redfern method

Applied Chemical Engineering Pub Date : 2024-03-14 DOI:10.59429/ace.v7i2.1872

A. Hassan, Muhammad Asif, Tariq Hussain, Rida Sajjad, Farzana Yasmin, Mayeen UddinKhandaker

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Abstract

Renewable and sustainable energy resources are the dire need of time for environmental sustainability and to minimize the effects of global warming and climate change. The objective of this study was to investigate the thermos-kinetic parameters of municipal solid waste through pyrolysis. The sample was collected and prepared according to the American standards for test materials. Thermogravimetric analysis showed the three distinct regions, while the maximum degradation occurs in the second region within the temperature range of 230–400 ℃. A model-fitting approach using the Coats Redfern model was applied in this region to perform thermo-kinetic analysis. Based on the kinetic analysis, the D3 diffusion model showed the highest regression coefficient with an activation energy of 16–18 kJ/mole among all three diffusion models. Thermodynamic analysis showed that the pyrolysis process is endothermic, the product has more energy and a well-ordered arrangement of molecules confirmed by the positive change in enthalpy values and negative entropy values. The results demonstrate the usefulness of municipal solid waste in the creation of productive methods for converting to energy.

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城市固体废物的热解：通过 Coats-Redfern 方法获得动力学和热力学参数

可再生和可持续能源资源是环境可持续发展的迫切需要，也是将全球变暖和气候变化的影响降至最低的需要。本研究的目的是通过热解研究城市固体废物的热动力参数。样品是根据美国测试材料标准收集和制备的。热重分析显示了三个不同的区域，而最大降解发生在 230-400 ℃ 温度范围内的第二个区域。在这一区域采用 Coats Redfern 模型拟合方法进行热动力学分析。根据动力学分析，在所有三种扩散模型中，D3 扩散模型的回归系数最高，活化能为 16-18 kJ/mole。热力学分析表明，热解过程是内热过程，产物具有更多的能量，分子排列有序，焓值的正向变化和熵值的负向变化证实了这一点。这些结果表明，城市固体废物在创造转化为能源的生产方法方面非常有用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Applied Chemical Engineering

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