Using ethanol for continuous biodiesel production with trace catalyst and CO2 co-solvent

The continuous biodiesel production process under sub- and supercritical conditions using a trace amount of potassium hydroxide (KOH) as a catalyst has been studied. CO2 was added as a co-solvent to reduce the reaction time and increase biodiesel yield. The proposed procedure enables simultaneous tr...

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Bibliographic Details
Published in:Fuel processing technology 2020-06, Vol.203, p.106377, Article 106377
Main Authors: Hassan, Aso A., Alhameedi, Hayder A., Smith, Joseph D.
Format: Article
Language:English
Subjects:
Biodiesel
Biodiesel fuels
Carbon dioxide
Catalysts
CO2 co-solvent
Energy consumption
Enthalpy
Esterification
Ethanol
Fatty acids
Gibbs free energy
Kinetic model
Potassium hydroxides
Process variables
Reaction time
Solvents
Supercritical ethanol
Transesterification
Triglycerides
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Summary:The continuous biodiesel production process under sub- and supercritical conditions using a trace amount of potassium hydroxide (KOH) as a catalyst has been studied. CO2 was added as a co-solvent to reduce the reaction time and increase biodiesel yield. The proposed procedure enables simultaneous transesterification and esterification of triglycerides and free fatty acid (FFA), respectively. The shorter reaction time and milder reaction conditions may reduce energy consumption due to the simplification of the separation and purification steps. The process variables, including reaction temperature, ethanol to oil molar ratio, catalyst amount, and process pressure, were systematically optimized. The highest biodiesel yield (98.12%) was obtained after a 25-min reaction time using only 0.11% wt. of KOH and a 20:1 ethanol to oil ratio. The process optimum temperature and pressure were 240 °C and 120 bar, respectively. The proposed kinetic model suggested a first-order reaction with an activation energy of 15.7 kJ·mol−1 and a reaction rate constant of 0.0398/min−1. The thermodynamic parameters such as Gibbs free energy, enthalpy, and entropy were calculated as 144.82 kJ·mol−1, 11.4 kJ·mol−1, −0.26 kJ·mol−1 and at 240 °C, respectively. •Application of supercritical technology in chemical energy materials production discussed•Method is a novel approach to study use of supercritical ethanol in biodiesel production•CO2 added as a co-solvent to reduce reaction time and increase biodiesel yield•Shorter reaction time/milder conditions reduce energy consumption and simplify separation step•Kinetic model for biodiesel production evaluated with calculated thermodynamic parameters
ISSN:0378-3820
1873-7188
DOI:10.1016/j.fuproc.2020.106377