Journal
CHEMICAL PAPERS
Volume 76, Issue 11, Pages 6915-6929Publisher
SPRINGER INT PUBL AG
DOI: 10.1007/s11696-022-02326-6
Keywords
Transesterification; Fractionation; Oleic acid; Linoleic acid; Palmitic acid; Gas chromatography; Cloud point; Pour point
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Funding
- Deanship of Scientific Research (DSR) at King Abdulaziz University, Jeddah, Saudi Arabia [KEP-1-155-42]
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This study investigated the effects of condensation polymerization, catalytic breakdown, kink production, and double bond induction on biodiesel production. The optimization of fatty acid carbon chain length was found to improve biodiesel yield and low-temperature flow properties. Gas chromatographic analysis of the fatty acids in Pongamia pinnata showed high percentages of oleic acid, linoleic acid, and palmitic acid.
Condensation polymerization, catalytic breakdown, kink production, and double bond induction in the feedstock have been tested first time for biodiesel production. Biodiesel as an alternative fuel has gained much importance in the past few decades. Still, higher densities and poor low-temperature flow properties have made its excessive usage quite questionable. Therefore, the present research work was designed to overcome the above-mentioned problems by taking a step towards sustainable development of renewable energy sources. The fatty oil of Pongamia pinnata was extracted, vacuum filtered, fractionated, and treated to optimize the carbon chain length of fatty acids (by condensation polymerization, catalytic breakdown, kink production, and double bond induction) prior to the base-catalyzed transesterification. The highest biodiesel yield (%) was obtained by removing excessive long-chain fatty acids that could cause the hindrance in transesterification reaction and reduce the quality of fuel. The gas chromatographic analysis of fatty acids of Pongamia pinatta showed the highest percentages of oleic acid (54.76 +/- 0.001%), linoleic acid (11.87 +/- 0.085%), and palmitic acid (10.03 +/- 0.014%). The results of the present study showed the best low-temperature flow properties of fraction-ethylene glycol-L-V [(cloud point (CP): 1.7 +/- 0.056 degrees C) and (pour point (PP): -5.2 +/- 0.098 degrees C)] and fraction-catalytic breakdown-L-II [(cloud point (CP): 1.5 +/- 0.054 degrees C) and (pour point (PP): -5.2 +/- 0.023 degrees C)].
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