Glycerol-Free Biodiesel via Catalytic Interesterification: A Pathway to a NetZero Biodiesel Industry

Omar Youssef, Esraa Khaled, Omar Aboelazayem () and Nessren Farrag ()
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Omar Youssef: Department of Chemical Engineering, The British University in Egypt, El Sherouk City 11837, Cairo, Egypt
Esraa Khaled: Department of Chemical Engineering, The British University in Egypt, El Sherouk City 11837, Cairo, Egypt
Omar Aboelazayem: School of Computing, Engineering and Digital Technologies, Teesside University, Middlesbrough TS1 3BX, UK
Nessren Farrag: Department of Chemical Engineering, The British University in Egypt, El Sherouk City 11837, Cairo, Egypt

Sustainability, 2024, vol. 16, issue 12, 1-16

Abstract: Conventional biodiesel manufacturing uses alcohol as an acyl acceptor, resulting in glycerol as a side product. The increased demand for biodiesel has led to the production of a substantial surplus of glycerol, exceeding the market need. Consequently, glycerol is now being regarded as a byproduct, and in some cases, even as waste. The present study aims to suggest an economically viable and ecologically friendly approach for maintaining the viability of the biodiesel sector. This involves generating an alternative byproduct of higher value, rather than glycerol. Triacetin is produced through the interesterification of triglycerides with methyl acetate, and is a beneficial ingredient to biodiesel, reducing the need for extensive product separation. The primary objective of this research is to improve the interesterification reaction by optimising process parameters to maximise biodiesel production while using sulphuric acid as an economically viable catalyst. The study utilised the Box–Behnken design (BBD) to investigate the influence of various process variables on biodiesel yield, such as reaction time, methyl acetate to oil molar ratio, and catalyst concentration. An optimisation study using Response Surface Methodology (RSM) focused on key process reaction parameters, including the methyl acetate to oil (MA:O) molar ratio, catalyst concentration, and residence time. The best conditions produced a biodiesel blend with a 142% yield at a 12:1 MA:O molar ratio, with 0.1 wt% of catalyst loading within 1.7 h. The established technique is deemed to be undeniably effective, resulting in an efficient biodiesel production process.

Keywords: biodiesel; glycerol-free; triacetin; process optimisation; Box–Behnken design; NetZero (search for similar items in EconPapers)
JEL-codes: O13 Q Q0 Q2 Q3 Q5 Q56 (search for similar items in EconPapers)
Date: 2024
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