Biodiesel production from transesterification of Australian Brassica napus L. oil: optimisation and reaction kinetic model development

Biodiesel production from transesterification of Australian Brassica napus L. oil: optimisation and reaction kinetic model development

Edible oil-based feedstocks based biodiesel is still leading the industry around the world. Canola oil (Brassica napus L.) contributes significantly to that race. Process optimisation and the development of reaction kinetic models of edible oil feedstocks are still required since the knowledge of ki...

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Bibliographic Details
Main Authors: Hazrat M.A., Rasul M.G., Khan M.M.K., Ashwath N., Fattah I.M.R., Ong H.C., Mahlia T.M.I.
Other Authors: 55936470700
Format: Article
Published: Springer Science and Business Media B.V. 2024
Subjects:
Biodiesel
Homogeneous alkaline catalyst
Optimisation
Reaction kinetics
RSM
Transesterification
activation energy
biofuel
catalyst
chemical reaction
herb
industrial production
numerical model
optimization
reaction kinetics
response surface methodology
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Institution: Universiti Tenaga Nasional
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Summary:Edible oil-based feedstocks based biodiesel is still leading the industry around the world. Canola oil (Brassica napus L.) contributes significantly to that race. Process optimisation and the development of reaction kinetic models of edible oil feedstocks are still required since the knowledge of kinetics is needed for designing industrial facilities and evaluating the performance of catalysts during transesterification or other related processes in a biorefinery. This research focuses on the transesterification process for biodiesel production because of its higher output efficiency, reactivity with feedstock, techno-economic feasibility in terms of FFA content, and environmental sustainability. The response surface method with the Box�Behnken model was used to optimise the process. Multivariate analysis of variance (ANOVA) was also performed to investigate the effectiveness of the regression model. The optimal process conditions were found to be 5.89�M methanol, 0.5% (w/w) KOH, 60��C and 120�min. The predicted yield was 99.5% for a 95% confidence interval (99.1, 99.9). The experimental yield was 99.6% for these conditions. Two different kinetic models were also developed in this study. The activation energy was 16.9% higher for the pseudo-first-order irreversible reaction than for the pseudo-homogenous irreversible reaction. Such a comprehensive analysis will assist stakeholders in evaluating the technology for industrial development in biodiesel fuel commercialisation. � 2022, The Author(s).

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