2014
DOI: 10.1021/ef500754d
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Fractionation of Bio-Oil

Abstract: The fuel properties of fast pyrolysis bio-oils differ significantly from those of fossil fuels. As transportation fuel, bio-oil is not suitable without upgrading because of its relatively low energy content, high water content, acidity, and poor storage stability. Upgrading of bio-oil has usually been done by treating the whole oil in a reactor. The problem with this treatment is that pyrolysis oil is a mixture of different compound groups, which all need different conditions and catalysts to react in a desira… Show more

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Cited by 77 publications
(65 citation statements)
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References 31 publications
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“…7 Effective bio-oil fractionation prior to upgrading may be a valuable approach of producing liquid fuels and chemicals versus upgrading whole bio-oil. 2,8 Iowa State University has developed a fractionating bio-oil recovery system that allows for collection of bio-oil as heavy-ends (stage fraction (SF) 1 and SF 2), intermediate fractions (SF 3 and SF 4), consisting of monomeric compounds, and light ends (SF 5) that contain the majority of acids and water ( Figure 1). 9,10 Complete details on the reactor and recovery system can be found in Pollard et al 9 and Rover et al 10 The mass distribution (wet basis) when using red oak feedstock is approximately 40− 45 wt % for SF 1 and SF 2 heavy ends, 10 wt % for SF 3 and SF 4 intermediates, and 45−50 wt % of SF 5 light ends.…”
Section: ■ Introductionmentioning
confidence: 99%
“…7 Effective bio-oil fractionation prior to upgrading may be a valuable approach of producing liquid fuels and chemicals versus upgrading whole bio-oil. 2,8 Iowa State University has developed a fractionating bio-oil recovery system that allows for collection of bio-oil as heavy-ends (stage fraction (SF) 1 and SF 2), intermediate fractions (SF 3 and SF 4), consisting of monomeric compounds, and light ends (SF 5) that contain the majority of acids and water ( Figure 1). 9,10 Complete details on the reactor and recovery system can be found in Pollard et al 9 and Rover et al 10 The mass distribution (wet basis) when using red oak feedstock is approximately 40− 45 wt % for SF 1 and SF 2 heavy ends, 10 wt % for SF 3 and SF 4 intermediates, and 45−50 wt % of SF 5 light ends.…”
Section: ■ Introductionmentioning
confidence: 99%
“…Because this feedstock was used in the steam reforming experiments without any additional water, the subsequent S/C ratio was calculated to be 3.84. Aqueous pyrolysis oil obtained via water-induced phase separation has been shown to contain sugar-type compounds and light organics in a ratio of 3:1 [24]. Compared to this, the aqueous fraction that has been characterized and used in this study contained a clearly lower amount of sugar-type compounds.…”
Section: Feedstock Characterizationmentioning
confidence: 88%
“…The feedstock for the pyrolysis experiment was forest thinnings, and the pyrolysis was carried out at a temperature of 480 C. Fractional condensation of the pyrolysis vapours was achieved by operating the scrubbers at 65 C. The aqueous fraction, which was utilized in this i n t e r n a t i o n a l j o u r n a l o f h y d r o g e n e n e r g y 4 0 ( 2 0 1 5 ) 3 1 4 9 e3 1 5 7 study, was collected after the scrubbers via a secondary condensation system. The fractionation procedure is described in more detail by Lindfors et al [24].…”
Section: Bio-oil Preparation and Characterizationmentioning
confidence: 99%
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“…(2014) used a sieve-plate column (scrubber) on the pyrolysis vapor to condense it in the first stage of liquid recovery. To condense the vapor generated by the reactor in the first stage, direct and indirect cooling were applied to the liquid from the hot vapor; inlet direct cooling was applied in the sieve-plate column, then the thermal degradation reaction of the collected pyrolysis liquids was reduced (Lindfors et al, 2014). A hydrocarbon liquid was used as the liquid cooler in the scrubber.…”
Section: Lcs With Spray Quench and Distillationcolumnmentioning
confidence: 99%