Pyrolysis oil

This article is about synthetic liquid fuel extracted by pyrolysis from biomass. For other uses, see Pyrolysis oil (disambiguation).

Pyrolysis oil, sometimes also known as biocrude or biooil, is a synthetic fuel under investigation as substitute for petroleum. It is extracted by biomass to liquid technology of destructive distillation from dried biomass in a reactor at temperature of about 500 °C with subsequent cooling. Pyrolytic oil (or bio-oil) is a kind of tar and normally contains too high levels of oxygen to be a hydrocarbon. Which results in non-volatility, corrosiveness, being immiscible with fossil fuels, thermal instability and a tendency to polymerize with exposure to air.[1] As such it is distinctly different from similar petroleum products. The process of oxygen removal is also referred to as upgrading, which also applies to the removal of nitrogen from algal bio-oil.[2]

Standards

There have been few standards efforts so far for pyrolysis oil; one of the few is from ASTM.[3]

Feedstock decomposition

Pyrolysis is a well established technique for decomposition of organic material at elevated temperatures in the absence of oxygen into oil and other constituents. In second-generation biofuel applications—forest and agricultural residues, wood waste and energy crops can be used as feedstock.

Wood Pyrolysis

Derivation of a wood-tar creosote from resinous woods

When wood is heated above 270 °C it begins a process of decomposition called carbonization. If air is absent the final product, since there is no oxygen present to react with the wood, is charcoal. If air, which contains oxygen, is present, the wood will catch fire and burn when it reaches a temperature of about 400-500 °C and the fuel product is wood ash. If wood is heated away from air, first the moisture is driven off and until this is complete, the wood temperature remains at about 100-110 °C. When the wood is dry its temperature rises and at about 270 °C it begins to spontaneously decompose and, at the same time, heat is evolved. This is the well known exothermic reaction which takes place in charcoal burning. At this stage evolution of the by-products of wood carbonization starts. These substances are given off gradually as the temperature rises and at about 450 °C the evolution is complete.

The solid residue, charcoal, is mainly carbon (about 70%) and then of tarry substances which can be driven off or decomposed completely only by raising the temperature to above about 600 °C to produce Biochar, a high-carbon, fine-grained residue that today is produced through modern pyrolysis processes, which is the direct thermal decomposition of biomass in the absence of oxygen, which prevents combustion, to obtain an array of solid (biochar), liquid—Pyrolysis oil (bio-oil/pyrolysis-oil), and gas (syngas) products. The specific yield from the pyrolysis is dependent on process conditions. such as temperature, and can be optimized to produce either energy or biochar.[4] Temperatures of 400–500 °C (752–932 °F) produce more char, while temperatures above 700 °C (1,292 °F) favor the yield of liquid and gas fuel components.[5] Pyrolysis occurs more quickly at the higher temperatures, typically requiring seconds instead of hours. High temperature pyrolysis is also known as gasification, and produces primarily syngas.[5] Typical yields are 60% bio-oil, 20% biochar, and 20% syngas. By comparison, slow pyrolysis can produce substantially more char (~50%). Once initialized, both processes produce net energy. For typical inputs, the energy required to run a “fast” pyrolyzer is approximately 15% of the energy that it outputs.[6] Modern pyrolysis plants can use the syngas created by the pyrolysis process and output 3–9 times the amount of energy required to run.

Algal Pyrolysis

Algae may be subjected to high temperatures (~500 °C) and normal atmospheric pressures. The resultant products include oil and nutrients such as nitrogen, phosphorus, and potassium.

There are numerous papers on the pyrolysis of lignocellulosic biomass. However, very few reports are available for algal bio-oil production via pyrolysis. Miao et al. (2004b) performed fast pyrolysis of Chllorella protothecoides and Microcystis areuginosa at 500 °C, and bio-oil yields of 18% and 24% were obtained, respectively. The bio-oil exhibited a higher carbon and nitrogen content, lower oxygen content than wood bio-oil. When Chllorella protothecoides was cultivated heterotrophically, bio-oil yield increased to 57.9% with a heating value of 41 MJ/kg (Miao et al., 2004a). Recently when microalgae become a hot research topic as the third generation of biofuel, pyrolysis has drawn more attention as a potential conversion method for algal biofuel production. Pan et al. (2010) investigated slow pyrolysis of Nannochloropsis sp. residue with and without the presence of HZSM-5 catalyst and obtained bio-oil rich in aromatic hydrocarbons from catalytic pyrolysis. Algal pyrolytic liquids separate into two phases with the top phase called bio-oil (Campanella et al., 2012; Jena et al., 2011a). The higher heating values (HHV) of algal bio-oil are in the range of 31−36 MJ/kg, generally higher than those of lignocellulosic feedstocks. Pyrolytic bio-oil consists of compounds with lower mean molecular weights and contains more low boiling compounds than bio-oil produced by hydrothermal liquefaction. These properties are similar to those of Illinois shale oil (Jena et al., 2011a; Vardon et al., 2012), which may indicate that pyrolytic bio-oil is suited for petroleum fuel replacement. In addition, the high protein content in microalgae led to a high N content in the bio-oil, resulting in undesirable NOx emissions during combustion and deactivation of acidic catalysts when co-processed in existing 10 crude oil refineries. Algal bio-oil had better qualities in many aspects than those produced from lignocellulosic biomass. For example, algal bio-oil has a higher heating value, a lower oxygen content and a greater than 7 pH value. However, upgrading towards the removal of nitrogen and oxygen in the bio-oil is still necessary before it can be used as drop-in fuels.[7]

Algal Hydrothermal Liquefaction

Hydrothermal liquefaction (HTL) is a thermal depolymerization process used to convert wet biomass into an oil—sometimes referred to as bio-oil or biocrude—under a moderate temperature and high pressure[8] of 350 °C (662 °F) and 3,000 pounds per square inch (21,000 kPa). The crude-like oil (or bio-oil) has high energy density with a lower heating value of 33.8-36.9 MJ/kg and 5-20 wt% oxygen and renewable chemicals.[9][10]

The HTL process differs from pyrolysis as it can process wet biomass and produce a bio-oil that contains approximately twice the energy density of pyrolysis oil. Pyrolysis is a related process to HTL, but biomass must be processed and dried in order to increase the yield.[11] The presence of water in pyrolysis drastically increases the heat of vaporization of the organic material, increasing the energy required to decompose the biomass. Typical pyrolysis processes require a water content of less than 40% to suitably convert the biomass to bio-oil. This requires considerable pretreatment of wet biomass such as tropical grasses, which contain a water content as high as 80-85%, and even further treatment for aquatic species, which can contain higher than 90% water content. Per Algal HTL, the properties of the resulting bio-oil are affected by temperature, reaction time, algae species, algae concentration, reaction atmosphere, and catalysts, in subcritical water reaction conditions.

Bio crude oil

Bio-oil typically requires significant additional treatment to render it suitable as a refinery feedstock to replace crude oil derived from petroleum, coal-oil, or coal-tar.

Tar is a black mixture of hydrocarbons and free carbon[12] obtained from a wide variety of organic materials through destructive distillation.[13][14][15] Tar can be produced from coal, wood, petroleum, or peat.[15]

Wood-tar creosote is a colourless to yellowish greasy liquid with a smoky odor, produces a sooty flame when burned, and has a burned taste. It is non-buoyant in water, with a specific gravity of 1.037 to 1.087, retains fluidity at a very low temperature, and boils at 205-225 °C. When transparent, it is in its purest form. Dissolution in water requires up to 200 times the amount of water as the base creosote. The creosote is a combination of natural phenols: primarily guaiacol and creosol (4-methylguaiacol), which will typically constitute 50% of the oil; second in prevalence, cresol and xylenol; the rest being a combination of monophenols and polyphenols.

Pitch is a name for any of a number of viscoelastic polymers. Pitch can be natural or manufactured, derived from petroleum, coal tar[16] or plants.

Black liquor and Tall oil is a viscous liquid by-product wood pulp manufacturing.

Rubber oil is the product of the pyrolysis method for recycling used tires.

Biofuel

Biofuels are synthesized from intermediary products such as syngas using methods that are identical in processes involving conventional feedstocks, first generation and second generation biofuels. The distinguishing feature is the technology involved in producing the intermediary product, rather than the ultimate off-take.

A Biorefinery is a facility that integrates biomass conversion processes and equipment to produce fuels, power, heat, and value-added chemicals from biomass. The biorefinery concept is analogous to today's petroleum refinery, which produce multiple fuels and products from petroleum.[17]

See also

References

  1. Crocker, Mark (2010). Thermochemical Conversion of Biomass to Liquid Fuels and Chemicals. Royal Society of Chemistry. p. 289. ISBN 978-1-84973-035-8.
  2. Lee, James W. (30 August 2012). Advanced Biofuels and Bioproducts. Springer Science & Business Media. p. 175. ISBN 978-1-4614-3348-4.
  3. Standard Specification for Pyrolysis Liquid Biofuel http://www.astm.org/Standards/D7544.htm
  4. Gaunt & Lehmann 2008, pp. 4152, 4155 ("Assuming that the energy in syngas is converted to electricity with an efficiency of 35%, the recovery in the life cycle energy balance ranges from 92 to 274 kg (203 to 604 lb) CO2 MW-1 of electricity generated where the pyrolysis process is optimized for energy and 120 to 360 kilograms (790 lb) CO2MW-1 where biochar is applied to land. This compares to emissions of 600–900 kilograms (1,300–2,000 lb) CO
    2    MW-1 for fossil-fuel-based technologies.)
  5. 1 2 Winsley, Peter (2007). "Biochar and bioenergy production for climate change mitigation". New Zealand Science Review. 64. (See Table 1 for differences in output for Fast, Intermediate, Slow, and Gasification).
  6. Laird 2008, pp. 100, 178–181 "The energy required to operate a fast pyrolyzer is ∼15% of the total energy that can be derived from the dry biomass. Modern systems are designed to use the syngas generated by the pyrolyzer to provide all the energy needs of the pyrolyzer."
  7. ZHENYI DU (January 2013). "THERMOCHEMICAL CONVERSION OF MICROALGAE FOR BIOFUEL PRODUCTION" (PDF). p. 8. Retrieved 15 October 2016.
  8. Akhtar, Javaid; Amin, Nor Aishah Saidina (2011-04-01). "A review on process conditions for optimum bio-oil yield in hydrothermal liquefaction of biomass". Renewable and Sustainable Energy Reviews. 15 (3): 1615–1624. doi:10.1016/j.rser.2010.11.054.
  9. Elliott, Douglas C. (2007-05-01). "Historical Developments in Hydroprocessing Bio-oils". Energy & Fuels. 21 (3): 1792–1815. doi:10.1021/ef070044u. ISSN 0887-0624.
  10. Goudriaan, F.; Peferoen, D.G.R. (1990-01-01). "Liquid fuels from biomass via a hydrothermal process". Chemical Engineering Science. 45 (8). doi:10.1016/0009-2509(90)80164-a.
  11. Bridgwater, A.V; Peacocke, G.V.C (March 2000). "Fast pyrolysis processes for biomass". Renewable and Sustainable Energy Reviews. 4: 1–73. doi:10.1016/s1364-0321(99)00007-6.
  12. Daintith, John. "tar". Oxford University Press (6th ed.). A dictionary of chemistry. Retrieved 14 March 2013.
  13. "Tar: Definition". Miriam Webster. Retrieved 14 March 2013.
  14. "Tar: Definition". Collins Dictionary. Retrieved 14 March 2013.
  15. 1 2 "tar and pitch" (6th ed.). The Columbia Electronic Encyclopedia. Retrieved 14 March 2013.
  16. COAL-TAR PITCH, HIGH TEMPERATURE
  17. Dr W J Smith, Tamutech Consultancy. Mapping the Development of UK Biorefinery Complexes, NNFCC, 2007-06-20. Retrieved on 2011-02-16.
  18. "New Biofuel From Trees Developed". www.sciencedaily.com. May 20, 2007. Retrieved 17 October 2016.
  19. Ojus, Doshi (May 2007). "New Method Developed to Extract Biofuel from Wood | JYI – The Undergraduate Research Journal". www.jyi.org. Retrieved 17 October 2016. According to the researchers, the process is very easy to carry out. Wood chips—Adams and his colleagues used pine,are subjected to pyrolysis, or heating in the absence of oxygen to cause decomposition, which generates a wood-charcoal and gas. The gas is rapidly condensed to yield a liquid categorized as bio-oil. "You cannot use bio-oil as crude fuel because it has too much oxygen and water,it's soluble in water. That's why it has not been used in engines," Adams said. In order to be used in diesel engines, the bio-oil must dissolve in bio-diesel, an alternative diesel fuel that is produced from animal fats or vegetable oils. High water and oxygen content, however, prevents this from happening. After Adams's team conducted chemical treatments, most of the water was removed, and the bio-oil was blended with bio-diesel and tested in conventional diesel engines.
  20. "Renewable Fuels from Algae Boosted by NREL Refinery Process - News Releases | NREL". www.nrel.gov. Retrieved 16 October 2016.
  21. Dong, Tao; Knoshaug, Eric P.; Davis, Ryan; Laurens, Lieve M. L.; Van Wychen, Stefanie; Pienkos, Philip T.; Nagle, Nick. "Combined algal processing: A novel integrated biorefinery process to produce algal biofuels and bioproducts". Algal Research. doi:10.1016/j.algal.2015.12.021. Retrieved 16 October 2016.
  22. Errol Kiong (May 12, 2006). "NZ firm makes bio-diesel from sewage in world first". The New Zealand Herald. Retrieved 2007-01-10.

External links

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