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Glycerolysis of high free fatty acid oil by heterogeneous catalyst for biodiesel production

Asumin Selemani, Godlisten G. Kombe

2022Results in Engineering31 citationsDOIOpen Access PDF

Abstract

The most widely used commercial biodiesel production technique, alkali-catalysed transesterification, requires only moderate temperatures and pressures to achieve a more than 98% conversion yield. Unfortunately, oil feedstock's high free fatty acid (FFA) content limits the technology's usefulness. A heterogeneous base catalysed glycerolysis process was investigated in this study to lower the FFA and meet these requirements. The response surface methodology (RSM) based on I-optimal design was used to model and optimize a CaO catalysed glycerolysis reaction under the influence of five reaction variables: temperature (60–180 °C), residence time (30–120 min), FFA concentration (6–50%), catalyst amount (0.4–0.6 wt (g/g)), and Glycerol to Oil ratio (G/O) (1–1.5). The data were fitted in a quadratic model, and R2 of 0.986 was observed, signifying that the model well defined the experimental data. The model was validated by running four replicates of the experiment, and a residual standard error of 2.7% was obtained, indicating the model would accurately predict future observations. The 48.584% FFA in oil was reduced to 0.98% under optimal conditions of 170 °C, 39.9 min of residence time, 0.591 wt g catalyst concentration, and 1.026 g/g glycerol/oil (G/O) ratio. CaO catalysed glycerolysis has significantly reduced FFA to less than 3% in less than an hour in biodiesel feedstock for biodiesel production.

Topics & Concepts

BiodieselGlycerolBiodiesel productionResponse surface methodologyRaw materialChemistryCatalysisYield (engineering)TransesterificationOrganic chemistryChromatographyMaterials scienceMetallurgyBiodiesel Production and ApplicationsCatalysis and Hydrodesulfurization StudiesCatalysis for Biomass Conversion