Biobased tar pitch produced from biomass pyrolysis oils

[Display omitted] •Distillate residues from biomass pyrolysis oils were synthesized into renewable pitch.•The biopitch properties closely align with those of coal tar pitch.•Diverse biomasses used allow greater flexibility for biorefineries. Petroleum-based carbon solid materials, such as petcoke an...

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Bibliographic Details
Published inFuel (Guildford) Vol. 318; p. 123300
Main Authors Elkasabi, Yaseen, Mullen, Charles A., Strahan, Gary D., Wyatt, Victor T.
Format Journal Article
LanguageEnglish
Published Kidlington Elsevier Ltd 15.06.2022
Elsevier BV
Subjects
Aluminum
Anodes
Biomass
Biorefineries
Carbon
Carbon dioxide
Coal tar
Coal tar pitch
Coking
Crude oil
Deoxygenation
Distillation
Environmental impact
Guayule
Heat treatment
Heat treatments
Hydrocarbon fuels
Oxygen content
Pitch (material)
Pyrolysis
Quinoline
Residues
Sustainability
Tar
Toluene
Pyrolysis
Coal tar pitch
Biomass
Anodes
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Summary:[Display omitted] •Distillate residues from biomass pyrolysis oils were synthesized into renewable pitch.•The biopitch properties closely align with those of coal tar pitch.•Diverse biomasses used allow greater flexibility for biorefineries. Petroleum-based carbon solid materials, such as petcoke and coal tar pitch, have decreased in quality and/or availability due to various factors, such as the declining elemental quality of crude oil and the push towards environmental sustainability. Coal tar pitch acts as a binder in smelting anodes for aluminum production, which contributes significantly to the fossil-based CO2 production globally. In an effort to reduce the carbon footprint of these processes, we synthesized a renewable biopitch based on biomass pyrolysis. In comparison to previous studies on biopitch, we utilized pyrolysis bio-oils with reduced oxygen content (<15%). Guayule and switchgrass biomasses served as the biomass of choice, and their bio-oils underwent continuous distillation. Solid residues underwent extraction to remove toluene insolubles (TI), and the remaining fraction underwent heat treatment to ∼ 380 °C. While both the residues and biopitches contained trace amounts of quinoline insolubles (QI), the pitch TI amounted to 32 – 54 wt%. Coking values exceeded 43 wt% for both pitches, making them feasible for anode utilization. The use of distilled partially deoxygenated oils enables greater flexibility for biorefineries to provide a marketable coproduct alongside hydrocarbon fuels.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2022.123300