Sunflower oil transesterification with methanol using immobilized lipase enzymes

The transesterification of sunflower oil with methanol, using immobilized lipase enzymes as catalysts, was studied. The process was carried out in a semi-continuous mode. Temperature (30–50 °C), methanol flow (0.024–0.04 ml/min), kind of enzyme (Lipozyme 62350, Lipozyme TL-IM, Novozym 435 and Pseudo...

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Veröffentlicht in:	Bioprocess and biosystems engineering 2019-01, Vol.42 (1), p.157-166
Hauptverfasser:	Encinar, José María, González, Juan Félix, Sánchez, Nuria, Nogales-Delgado, Sergio
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Sprache:	eng
Schlagworte:	Alcohols Biofuels Biotechnology Catalysis Catalysts Chemistry Chemistry and Materials Science Conversion Deactivation Diesel fuels Environmental Engineering/Biotechnology Enzymes Food Science Helianthus High flow Industrial and Production Engineering Industrial Chemistry/Chemical Engineering Lipase Methanol Parameters Pseudomonas Pseudomonas cepacia Research Paper Sol-gel processes Sunflower oil Transesterification Vegetable oils Weight
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description	The transesterification of sunflower oil with methanol, using immobilized lipase enzymes as catalysts, was studied. The process was carried out in a semi-continuous mode. Temperature (30–50 °C), methanol flow (0.024–0.04 ml/min), kind of enzyme (Lipozyme 62350, Lipozyme TL-IM, Novozym 435 and Pseudomonas cepacia Sol–Gel-AK) and enzyme concentrations (1.25–10% by weight) were the operating variables. The final product was characterized by the EN 14214 standard. All the parameters, except for cold filter plugging point, were similar to a diesel fuel. For low methanol flows, reaction rate was proportional to methanol concentration. High flows caused catalyst deactivation. Novozyme 435, Lipozyme TL-IM and Lipozyme 62350 showed similar maximum reaction rates, but Novozyme 435 was more resistant to deactivation. Pseudomonas cepacia hardly obtained 1% conversion. The catalyst concentration, up to 2.5%, had a positive effect on the reaction rate and conversion. The optimum temperature was 40 °C. The initial reaction rate was in line with the Arrhenius law, up to 50 °C. By differential and integral methods, the Michaelis–Menten, competitive inhibition and ping-pong bi–bi kinetic parameters were determined. The transesterification of sunflower oil in a semi-continuous regime of alcohol improved the results, compared to the discontinuous regime, and those were similar to the obtained ones in a discontinuous regime with step-by-step methanol addition. The lipase that showed the best yield and higher resistance to deactivation was Novozym 435. The kinetic models that forecast the deactivation of lipases by an inhibitor described the experimental behavior properly.
doi_str_mv	10.1007/s00449-018-2023-z
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By differential and integral methods, the Michaelis–Menten, competitive inhibition and ping-pong bi–bi kinetic parameters were determined. The transesterification of sunflower oil in a semi-continuous regime of alcohol improved the results, compared to the discontinuous regime, and those were similar to the obtained ones in a discontinuous regime with step-by-step methanol addition. The lipase that showed the best yield and higher resistance to deactivation was Novozym 435. 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The process was carried out in a semi-continuous mode. Temperature (30–50 °C), methanol flow (0.024–0.04 ml/min), kind of enzyme (Lipozyme 62350, Lipozyme TL-IM, Novozym 435 and Pseudomonas cepacia Sol–Gel-AK) and enzyme concentrations (1.25–10% by weight) were the operating variables. The final product was characterized by the EN 14214 standard. All the parameters, except for cold filter plugging point, were similar to a diesel fuel. For low methanol flows, reaction rate was proportional to methanol concentration. High flows caused catalyst deactivation. Novozyme 435, Lipozyme TL-IM and Lipozyme 62350 showed similar maximum reaction rates, but Novozyme 435 was more resistant to deactivation. Pseudomonas cepacia hardly obtained 1% conversion. The catalyst concentration, up to 2.5%, had a positive effect on the reaction rate and conversion. The optimum temperature was 40 °C. The initial reaction rate was in line with the Arrhenius law, up to 50 °C. By differential and integral methods, the Michaelis–Menten, competitive inhibition and ping-pong bi–bi kinetic parameters were determined. The transesterification of sunflower oil in a semi-continuous regime of alcohol improved the results, compared to the discontinuous regime, and those were similar to the obtained ones in a discontinuous regime with step-by-step methanol addition. The lipase that showed the best yield and higher resistance to deactivation was Novozym 435. The kinetic models that forecast the deactivation of lipases by an inhibitor described the experimental behavior properly.</abstract><cop>Berlin/Heidelberg</cop><pub>Springer Berlin Heidelberg</pub><pmid>30302549</pmid><doi>10.1007/s00449-018-2023-z</doi><tpages>10</tpages></addata></record>
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subjects	Alcohols Biofuels Biotechnology Catalysis Catalysts Chemistry Chemistry and Materials Science Conversion Deactivation Diesel fuels Environmental Engineering/Biotechnology Enzymes Food Science Helianthus High flow Industrial and Production Engineering Industrial Chemistry/Chemical Engineering Lipase Methanol Parameters Pseudomonas Pseudomonas cepacia Research Paper Sol-gel processes Sunflower oil Transesterification Vegetable oils Weight
title	Sunflower oil transesterification with methanol using immobilized lipase enzymes
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