Idowu Abdulfatai Tijani scite author profile

Biodiesel production waste cooking oil is usually limited by its high free fatty acid and moisture content. The synergetic effect of both base and acid source from biomass was employed to proffer way out to this challenge. This study shows the coupled development of sulfonated carbonized corn cob (S-CCC) and calcined cow-bone (C-CB) catalysts for transesterification of waste cooking oil. The catalyst was prepared by physically mixing several mass percentages of S-CCC and C-CB (fluorapatite) in strategic proportions. The maximum biodiesel yield of 96.2 % was attained for catalyst mixture of 60 wt% and 40 wt%. The developed catalyst mixture was characterized by Fourier Transform Infrared Ray (FTIR), powder X-ray diffraction (XRD), Scanning Electron Microscopy (SEM), Energy Dispersive X-ray (EDX), Brunauer–Emmett-Teller (BET). The surface area (472.3 m2/g), pore size (2.4330 nm) and volume (0.1380 cc/g) were obtained for the catalyst. The XRD shows that the crystallized structure of the bifunctional catalyst was formed majorly between 2 theta 10 and 65.Also the SEM shows a well dispersive pattern of the particles of the catalyst. The developed catalyst was employed for biodiesel optimization studies by varying factors such as time, temperature, catalyst loading and methanol: oil using optimal design under the response surface methodology. Maximum yield of 98.98 % was attained at time 6 h, temperature 65 °C, catalyst loading 6 %wt/ wt of oil and methanol to oil ratio of 11.75:1. It was observed that time and temperature had notable effect on the biodiesel yield.

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Waste Cooking Oil Conversion to Biodiesel Using Solid Bifunctional Catalysts

Aderibigbe

Saka²,

Mustapha

et al. 2023

ChemBioEng Reviews

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The draining of fossil fuels and their toxic influence on the environment has prompted the need for alternative fuels known as biofuels. Of the various types of biofuel, biodiesel has attracted wide interest in the world today since it promotes carbon neutrality. The transesterification and interesterification process remains the most widely used process route for biodiesel production. In this review, the performance efficiency of solid base, solid acid, and bifunctional solid acid‐base catalysts for biodiesel production from waste cooking oil is considered. In particular, the benefit of exploring the biomass‐derived acid‐base heterogeneous bifunctional catalysts, current status, and future prospects for biodiesel production from waste cooking oil are elucidated.

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Idowu Abdulfatai Tijani

Kinetics modelling of acid hydrolysis of cassava (Manihot esculanta Cranz) peel and its hydrolysate chemical characterisation

Development of Bi-Functional Heterogeneous Catalyst for Transesterification of Waste Cooking Oil to Biodiesel: Optimization Studies

Waste Cooking Oil Conversion to Biodiesel Using Solid Bifunctional Catalysts

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