Kinetics and simulation of biodiesel production using a geopolymer heterogenous catalyst.

IF 1.9 4区环境科学与生态学 Q4 ENGINEERING, ENVIRONMENTAL Journal of Environmental Science and Health Part A-toxic\/hazardous Substances & Environmental Engineering Pub Date : 2024-11-26 DOI:10.1080/10934529.2024.2429953

Pascal Mwenge, Bulanga Djemima, Simphiwe Zwane, Salvation Muthubi, Hilary Rutto, Tumisang Seodigeng

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Abstract

This work aims to develop a comprehensive kinetic and simulation study of biodiesel production using waste cooking oil (WCO) catalyzed by blast furnace slag geopolymer (BFSG) as a heterogeneous catalyst. The kinetic investigation was established following the pseudo-first and second-order model using three reaction parameters, namely, the reaction temperature (40-60 °C), reaction time (4-8 h) and catalyst ratio (6-14 wt.%), while maintaining a constant methanol-to-oil composition of 40 wt.%. The geopolymer-catalyzed transesterification process was simulated using ChemCAD version 8.1.0, which incorporates the four major triglycerides (triolein, tripalmitin, tristearin and triolein) of WCO. The results of the transesterification reaction of WCO in a kinetic plug flow reactor (PFR) demonstrated a good fit of the data, with an R² above 0.96 in both cases. The pseudo-first-order (PFO) model revealed a more favorable reaction pathway, with an activation energy of 58.876 kJ.mol^-1, as opposed to the value of 131.369 kJ.mol^-1 obtained from the pseudo-second-order (PSO) analysis. The catalytic activity of BFSG yielded a maximum conversion of 99.18% at a 12 wt.% catalyst ratio. The study results demonstrated the effectiveness of the transesterification process catalyzed by BFSG as a promising low-cost technology for the biodiesel industry.

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使用土工聚合物异质催化剂生产生物柴油的动力学和模拟。

本研究旨在对高炉矿渣土工聚合物（BFSG）作为异相催化剂催化废弃食用油（WCO）生产生物柴油的过程进行全面的动力学和模拟研究。动力学研究采用伪一阶和二阶模型，使用三个反应参数，即反应温度（40-60 °C）、反应时间（4-8 h）和催化剂比例（6-14 wt.%），同时保持甲醇与油的比例为 40 wt.%。使用 ChemCAD 8.1.0 版模拟了土工聚合物催化的酯交换反应过程，其中包含了 WCO 的四种主要甘油三酯（三油酸甘油酯、三棕榈酸甘油酯、三硬脂酸甘油酯和三油酸甘油酯）。在动力学塞流反应器（PFR）中进行的 WCO 酯交换反应结果表明数据拟合良好，两种情况下的 R2 均高于 0.96。伪一阶（PFO）模型显示了更有利的反应途径，活化能为 58.876 kJ.mol-1 ，而伪二阶（PSO）分析得出的活化能为 131.369 kJ.mol-1 。在催化剂比例为 12 wt.% 时，BFSG 的催化活性产生了 99.18% 的最大转化率。研究结果表明，BFSG 催化的酯交换过程是一种很有效的生物柴油工业低成本技术。

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来源期刊

$Journal of Environmental Science and Health Part A-toxic\/hazardous Substances & Environmental Engineering$

Journal of Environmental Science and Health Part A-toxic\/hazardous Substances & Environmental Engineering 环境科学-工程：环境

CiteScore

4.10

自引率

4.80%

发文量

审稿时长

3.0 months

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