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570 to 660°F) and pressure 1,770 to 2,650 psi) to produce bio-crude. This can be separated by flashing or by extraction to a viscous oil that is suitable for co-combustion in coal power stations and low-density crude oil, which can be upgraded by hydrodeoxygenation (HDO) to biofuels.

      Bio-oil is a dark brown viscous liquid that bears some resemblance to fossil crude oil. However, bio-oil is a complex oxygenated compound comprised of water, water- soluble compounds, such as acid derivatives, ester derivative, and water-insoluble compounds, usually called pyrolytic lignin because it comes from the lignin fraction of the biomass. The elemental composition of bio-oil is similar to that of the parent biomass. Because of its high oxygen content, the heating value (Btu per gallon) of bio-oil is lower than fossil fuel, typically only approximately half the heating value of fossil crude such as high-boiling fuel oil. However, it contains less nitrogen and only traces of metals or sulfur.

Property
Water content, % w/w 15 – 35
pH 2.8 – 4.0
Density (kg/L) 1.1 - 1.25
Elemental analysis (moisture free)
Carbon, % w/w 55 – 64
Hydrogen, % w/w 5 – 8
Nitrogen, % w/w 0.05 – 1
Sulfur, % w/w 0 - 0.05
Oxygen, % w/w 100 - (C + H + N + S)
Ash, % w/w 0.03 - 0.3
Viscosity (42oC, 108oF, cP) 25-1000

      Although freshly made bio-oil can be pumped and transported through pipelines, its viscosity increases with time. Unprocessed bio-oil cannot be readily mixed with crude oil-derived fuels.

      Despite the above-mentioned shortcomings, bio-oil has great potential. It can be used as heating oil if proper furnaces can be designed to do so; nitrogen oxide emissions are low when combusted. Additionally, it can be potentially upgraded (or refined) to produce liquid transportation fuels and organic chemicals.

      Due to large amounts of oxygenated components present in bio-oil, the oil tends to be polar (like water) and, therefore, does not mix readily with hydrocarbon derivatives or with biodiesel. The degradation products from the biomass constituents include organic acids (like formic and acetic acid), giving the oil its low pH, typically between 2 and 4. Water is also an integral part of the single-phase chemical solution (water-soluble fraction).

      The water content of bio-oil is typically 15 to 35% v/v, and the oil has the tendency to phase-separate when the water content reaches the 30 to 45% v/v range. The heating value (i.e., the higher heating value, HHV) is below 11,175 Btu/lb compared to 18,052-18,911 Btu/lb for conventional fuel oils. The high heating values of bio-oil (dry-ash free) of switchgrass (cave-in-rock), corn cob, corn stover (no cobs) and alfalfa stems at early bud are 10,164, 11,249, 10,448, and 14,249 Btu/lb, respectively.

      See also: Biomass, Bio-oil Upgrading, Fischer-Tropsch Process, Hydrothermal Upgrading Process.

      Bio-oil produced by the pyrolysis of lignocellulosic materials is among the most complex and inexpensive raw oils that can be derived from biomass and required upgrading prior to use. Typically, bio-oil consists of five major fractions: (i) water, 15 to 30% w/w, (ii) low-boiling oxygenated compounds, 8 to 26% w/w, (iii) phenols derivatives, 2 to -7% w/w, (iv) water-insoluble oligomers derived from lignin, 15 to 25% w/w, and (v) water- soluble products, 10 to 30% w/w.

Feedstock Process (primary) Product Process (secondary) Products
Biomass Bio-oil
Hydrocracking
(plus hydrotreating) Methane
Naphtha (gasoline)
Kerosene (diesel)

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