Abstract:
Moringa oleifera produces oil which can be extracted and converted to biodiesel. However, the kinetics and thermodynamics of this viable fuel have been seldomly investigated. We examine the kinetics and thermodynamics of the oil extraction for biodiesel production. The biodiesel kinematic viscosity (3.75 ± 0.04 mm2 /s), cetane number (67.12), oxidative stability (15.2 ± 0.5), acid value (0.012 mg/KOH), pour point ( 9C) and carbon residue (0.020 6 .001) satisfy the American Society for testing and Materials (ASTM) limits. Fourier transform infrared spectroscopy distinguishes the biodiesel and the base oil at 1435.77 cm 1 (-CH3 stretch), 1195.74 cm 1 (O-CH3) and 1377.67 cm 1 (O-CH2) because -CH3 and O-CH3 stretches are absent in the oil whereas the biodiesel lacks O-CH2 stretch. he highly negative activation entropy ( 214.1160.16 J mol 1K 1) and greater activation enthalpy (30.39 60.05 kJ/mol) indicate a slower extraction rate due to the higher energy requirement and stiffer transition of the extraction, respectively. he slower extraction rate agrees with the lower mass transfer coefficients (0.0119–0.0210 min 1). The equilibrium constant (K) is positive whilst the Gibbs free energy (DG) is negative, indicating a forward and spontaneous process. This investigation of kinetics, thermodynamics and transesterification essentially provides in-depth knowledge on oil extraction and biodiesel production
