生物质与塑料原料热解循环热力学分析

Sampad Kumar Das , Sadhan Kumar Ghosh
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引用次数: 3

摘要

本研究利用热解工艺研究了塑料和生物质废弃物转化过程的产率。为了研究热解过程及其产率,采用二次元模型,并从理论和实验工作中确定了模型系数。通过动力学模型对生物质和塑料的热解过程进行了分析。该模型预测了生物油、生物气和生物炭的产量。通过动力学模型分析,确定了热力学参数。由活化能和绝对反应温度计算了反应速率常数的阿伦尼乌斯系数。还计算了反应的焓、吉布斯自由能和熵。活化能在144.9 ~ 158.5 kJ/mol之间变化。反应速率常数的阿伦尼乌斯系数为0.000779 / min。焓和吉布斯自由能分别为154.35和103.65 kJ/mol。生物油的产率从总产率的60%到80%不等。对于生物炭的生产,生物炭的重量百分比已被发现为总产量的2%至3%。已发现沼气占总产量的10%-25%。因此,添加塑料进行热解可以在高热值、效率和能量输出方面对合成气和生物油的质量做出积极贡献。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Thermodynamic analysis of biomass and plastic feedstock circulation using pyrolysis technology

In this study, the yield of conversion process of plastic and biomass wastes has been investigated using the pyrolysis process. To study the pyrolysis process and its yield, a quadratic model has been adopted and the coefficients of the model have been identified from the theoretical and experimental work. The pyrolysis of biomass and plastics has been analyzed through the kinetic model. The model has predicted bio-oil, bio-gas, and bio-char yields. Through kinetic model analysis, thermodynamic parameters have been identified. The Arrhenius coefficient of reaction rate constant has been calculated from the activation energy and absolute reaction temperature. The enthalpy, Gibbs free energy, and entropy of reaction have also been calculated. The activation energy has been observed to vary from 144.9 to 158.5 kJ/mol. The Arrhenius coefficient of reaction rate constant has been identified as 0.000779 per minute. The enthalpy and Gibbs free energy have been observed to have values of 154.35 and 103.65 kJ/mol, respectively. The bio-oil yield has been observed to vary from 60% to 80% of the total yield. For bio-char production, the weight percentage of bio-char has been found as 2 to 3 percent of the total yield. Bio-gas has been found as 10%–25% of the total yield. Therefore, the addition of plastic for pyrolysis can make a positive contribution to the quality of syngas and bio-oil in terms of high heating value, efficiency, and energy output.

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