Conversion of carbonyl compounds in bio-oil during the acid/base-catalysed reactive distillation at high pressure

•Light and heavy carbonyl compounds would have different behaviour at high pressure.•Acid-catalysed reaction would not cause the significant consumption of carbonyls.•The base (e.g. NaOH) could remove carbonyl compounds more effectively than the acid.•Based-catalysed aldol condensation and neutralis...

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Bibliographic Details
Published in:Fuel (Guildford) 2021-11, Vol.304, p.121492, Article 121492
Main Authors: Wang, Hongqi, Liu, Yurong, Zhang, Lei, Gunawan, Richard, Wang, Zhitao, Li, Chun-Zhu
Format: Article
Language:English
Subjects:
Aldehydes
Aldol condensation
Bio-oil
Boiling points
Carbonyl compounds
Carbonyls
Carboxylic acids
Catalysed reactive distillation
Catalysts
Condensates
Conversion
Distillation
High pressure
Ketones
Molecular weight
Oil
Oxidation
Pressure
Sodium hydroxide
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Summary:•Light and heavy carbonyl compounds would have different behaviour at high pressure.•Acid-catalysed reaction would not cause the significant consumption of carbonyls.•The base (e.g. NaOH) could remove carbonyl compounds more effectively than the acid.•Based-catalysed aldol condensation and neutralisation can remove carbonyl compounds. The carbonyl compounds are mainly responsible for the instability and corrosiveness of a bio-oil. To upgrade or utilise a bio-oil, it is important to stabilise the carbonyl compounds. This study mainly investigates the conversion of carbonyl compounds in bio-oil via high-pressure reactive distillation in the presence of acid and base catalysts. It is found that high pressure could affect the distribution of carbonyl compounds in the bio-oil to accelerate the reaction of light carbonyl compounds and inhibit the reaction of heavy carbonyl compounds. The acid could not remove the carbonyl compounds significantly because it can not only catalyse the aldol condensation of carbonyl compounds but also help produce more carbonyl compounds by accelerating the hydrolysis of sugar compounds. The base (e.g. NaOH) could remove carbonyl compounds by acting as a catalyst to the aldol condensation reaction of aldehydes and ketones and neutralising the carboxylic acids during the high-pressure reactive distillation. Even though the based-catalysed aldol condensation could lead to the increase of the average molecular weight, the average boiling point of the distillation product is still in the acceptable range for fuels.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2021.121492