2022
DOI: 10.1021/acs.energyfuels.2c01608
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Derivatizing of Fast Pyrolysis Bio-Oil and Coprocessing in Fixed Bed Hydrotreater

Abstract: In several countries forest-based biofuels are being developed and to some extent also deployed. Fast pyrolysis bio-oil produced from, for example, sawdust, has now been coprocessed in fluid catalytic cracking refinery units in a number of commercial trials. However, this application is limited to about 10% of the total feed, and coprocessing in conventional fixed bed hydrotreaters is necessary to reach the high potential with this feedstock. Feeding and upgrading of fast pyrolysis bio-oil in a fixed bed react… Show more

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Cited by 9 publications
(3 citation statements)
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“…The most abundant compound group present in FPBOs is hydroxyls, which include carboxylic acids (4–15 wt %), phenolics (17–35 wt %), sugars (20–35 wt %), and water (20–30 wt %). , GCxGC-MS analysis provided information regarding the monomeric fraction present in the FPBO, including volatile and semivolatile compounds. The average molecular weight of FPBO produced from sawdust 554 g mol –1 (an average reported on a FPBO sample of the same feedstock from the same producer by gel permeation chromatography using tetrahydrofuran (THF) as a mobile phase) indicates the presence of large compounds. Although extensive characterization of bio-oils and method development of GCxGC analysis have been reported for FPBOs in the literature, variations in the biomass feedstock, the pyrolysis process and GC analysis methods, and precision make comparing results challenging. Therefore, in this paper, some typical functional groups have been categorized by GCxGC analysis (marked 1–5 in Figure a), and a few of the most typical compounds were selected in these groups, namely, isopropanol, lactic acid (1), hydroxy acetone (2), furfural (3), guaiacol (4), and levoglucosan (5); their chemical structures and peaks are shown in Figure b.…”
Section: Resultsmentioning
confidence: 99%
“…The most abundant compound group present in FPBOs is hydroxyls, which include carboxylic acids (4–15 wt %), phenolics (17–35 wt %), sugars (20–35 wt %), and water (20–30 wt %). , GCxGC-MS analysis provided information regarding the monomeric fraction present in the FPBO, including volatile and semivolatile compounds. The average molecular weight of FPBO produced from sawdust 554 g mol –1 (an average reported on a FPBO sample of the same feedstock from the same producer by gel permeation chromatography using tetrahydrofuran (THF) as a mobile phase) indicates the presence of large compounds. Although extensive characterization of bio-oils and method development of GCxGC analysis have been reported for FPBOs in the literature, variations in the biomass feedstock, the pyrolysis process and GC analysis methods, and precision make comparing results challenging. Therefore, in this paper, some typical functional groups have been categorized by GCxGC analysis (marked 1–5 in Figure a), and a few of the most typical compounds were selected in these groups, namely, isopropanol, lactic acid (1), hydroxy acetone (2), furfural (3), guaiacol (4), and levoglucosan (5); their chemical structures and peaks are shown in Figure b.…”
Section: Resultsmentioning
confidence: 99%
“…Lutz et al 11 studied the effect of hydrotreatment on process performance and gasoline quality when wood-derived FPBOs are used as co-feed in an FCC pilot plant and concluded the potentiality of the co-FCC process as a possible near-future pathway to ensure high biofuel contents in commercially available fuels. Janosik et al 12 presented an approach that involves complete dewatering of FPBO, followed by esterification. The overall results are promising because simple unit operations can be used to produce derivatized FPBOs that do not need additional standalone hydrotreating units but can be co-processed in existing units.…”
Section: ■ Co-refining Of Bioliquids and Fossil Oils In Refinery Proc...mentioning
confidence: 99%
“…There are also research studies focused on enhancing accuracy and identifying sources of CO 2 contamination, , particularly pertaining to air CO 2 pollution caused by various pathways. In recent years, there has been a growing application of the 14 C method in determining the ratio of mixed utilization of biogenic and fossil fuel, including the determination of biomass-coal blending ratios, , the biogenic carbon content of biobased liquid blended fuel, , and the biogas-natural gas blending ratios …”
Section: Introductionmentioning
confidence: 99%