Abstract
1,2:3,5-Di-O-isopropylidene-α-D-xylofuranose (DX) is a major component of a new bio-crude: a viscous oil presenting petroleum-friendly properties produced by the ketalization of sugarcane bagasse. This article studies DX HDO (hydrodeoxygenation) over a Pd/HBEA catalyst in a batch reactor at 250°C. The effects of hydrogen pressure from 10 to 40 bar, catalyst/DX ratio from ½ to 2, and reaction time 0–24 h were investigated. A range of conditions for complete hydrodeoxygenated DX into alkanes with a Pd/HBEA catalyst was found. In these conditions, a low coke yield with water as the principal deoxygenated product was obtained. Further, higher amounts of alkanes containing seven or more carbons (A7+) were favored at 30 bar of hydrogen pressure, Cat/DX ratio = 2, and short reaction time. Products analysis that accompanied the above variations during reaction time led to general insights into reaction pathways. First, in the presence of DX, an effective n-hexane conversion was not observed on experiments of low catalyst/DX ratio (½) or in the initial period of high Cat/DX ratio, suggesting DX is much more successful than n-hexane to compete for active sites. Then, the formation of a pool of oxygenated compounds, such as furans, ketones, and carboxylic acids, along with lighter and heavier alkanes was observed. Hence, the aforementioned oxygenates may undergo reactions, such as aldol condensation with subsequent hydrodeoxygenation reaction, generating heavier alkanes.
Highlights
In the last decades, the increase of greenhouse gas (GHG) emissions has induced environmental awareness, which led to developing policies concerning the implementation of clean energy sources worldwide (French Government, 2015)
The results showed that A5− yield increased with an increase in reaction time
The results demonstrated that the Pd/HBEA catalyst was capable of enhancing DX conversion into hydrocarbons by, first, improving DX deoxygenating and, second, yielding more A7+ (CyAlk6+ and Alk7+) compounds compared with the Pd/HZSM-5 catalyst
Summary
The increase of greenhouse gas (GHG) emissions has induced environmental awareness, which led to developing policies concerning the implementation of clean energy sources worldwide (French Government, 2015). In this scenario, biomass could be considered the major feedstock capable of flattening the curve of GHG emissions in the short term due to its year-round availability and low cost (Saghaei et al, 2020). Pyrolysis gained importance over the last 2 decades It could be described as a simple thermochemical process under an inert or a low oxygen content atmosphere at temperatures around. Despite the simplicity of the pyrolysis process, several drawbacks should be overcome to achieve sequential bio-oil conversion in a typical oil refinery process
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