Thermal and catalytic micropyrolysis for conversion of cottonseed oil dregs to produce biokerosene

Thermal and catalytic micropyrolysis for conversion of cottonseed oil dregs to produce biokerosene

•Biokerosene produced from waste biodiesel industry.•Thermal conversion of cottonseed oil dregs in hydrocarbons.•Micropyrolysis system to predict the potential of biomass to produce biofuels.•Novel application to catalysts from petroleum industry.•WO3 and MoO3 as catalysts to pyrolysis of cottonseed...

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Bibliographic Details
Published in:Journal of analytical and applied pyrolysis Vol. 129; pp. 21 - 28
Main Authors: Souza, Tarciane Greyci dos Santos, Santos, Brenda Lohanny Passos, Santos, Ayrla Murielly Alves, Souza, Anne Michelle Garrido Pedrosa de, Correia de Melo, James, Wisniewski, Alberto
Format: Journal Article
Language:English
Published: Elsevier B.V 01-01-2018
Subjects:
Bio-oil
Biokerosene
Catalytic thermal conversion
Cottonseed oil dregs
Micropyrolysis
Catalytic thermal conversion
Micropyrolysis
Cottonseed oil dregs
Bio-oil
Biokerosene
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Summary:•Biokerosene produced from waste biodiesel industry.•Thermal conversion of cottonseed oil dregs in hydrocarbons.•Micropyrolysis system to predict the potential of biomass to produce biofuels.•Novel application to catalysts from petroleum industry.•WO3 and MoO3 as catalysts to pyrolysis of cottonseed oil dregs. A sample of cottonseed oil dregs was obtained by the alkali pretreatment of the oil to remove free fatty acids and other impurities before an industrial biodiesel production process. The alkali dregs was characterized and submitted to non-catalytic, catalytic, and reactive hydrogen atmosphere micropyrolysis experiments to assess the capacities for type SPK–HEFA biokerosene production. Non-catalytic and catalytic micropyrolyses were performed at 500 and 550 °C. In the catalytic experiments, catalysts based on Mo or W oxides supported on Zr or Ti oxides were tested for the first time for this purpose. The moisture content of the cottonseed oil dregs was 23.4% (wt%) and the other major components were triacylglycerols + free fatty acids (65.0%) and inorganic material (9.8%). The products of the micropyrolysis experiments were characterized by GC–MS and quantified by GC-FID. The presence of moisture in the initial feedstock provided better results in the thermal conversion to liquid biofuel (16%), compared to dry biomass (6%), considering the n-alkanes and n-alkenes produced in the range C9–C16. The mass conversion performed in the presence of catalysts at 550 °C resulted in an average yield of around 32%, compared to a value of 19% for a non-catalytic process under a nitrogen atmosphere, with the same values for the yields under a reactive hydrogen atmosphere. The reactive atmosphere and the catalysts did not have any substantial influence on the ratio between n-alkanes and n-alkenes.
ISSN:0165-2370
1873-250X
DOI:10.1016/j.jaap.2017.12.010