Carbon Recycling International

Carbon Recycling International (CRI) is an Icelandic limited liability company which has developed a technology designed to produce renewable methanol from carbon dioxide and hydrogen, using water electrolysis or, alternatively, hydrogen captured from industrial waste gases. The technology is trademarked by CRI as Emissions-to-Liquids (ETL)[2][3] and the renewable methanol produced by CRI is trademarked as Vulcanol.[4] In 2011 CRI became the first company to produce and sell liquid renewable transport fuel produced using only carbon dioxide, water and electricity from renewable sources.[5]

Carbon Recycling International Inc.
TypePrivate
IndustryRenewable fuels
Founded2006 (2006)
HeadquartersReykjavík, Iceland
Key people
Ingolfur Gudmundsson CEO
Omar Sigurbjornsson
(Sales and Marketing)
Benedikt Stefansson
(Business Development)[1]
ProductsRenewable methanol
WebsiteCRI.is

History

CRI, incorporated in 2006, was founded by Fridrik Jonsson, Art Shulenberger, Oddur Ingolfsson, and KC Tran.[6] In addition to Icelandic individuals and funds, investors include Canadian multinational methanol supplier and distributor Methanex and Chinese multinational automotive manufacturing company Geely.

CRI's first commercial scale plant, the George Olah Plant (named after George Andrew Olah,[7] the 1994 Nobel Prize Laureate in chemistry), was completed in 2011.[8] CRI is currently working on several new projects in parallel, including in an EU Horizon 2020 research programme funded MefCO2 consortium[9] to build a renewable methanol demonstration plant in Germany and in the FreSME consortium[10] to build a renewable methanol demonstration plant in Sweden.

Renewable methanol

Renewable methanol can be used as a fuel, chemical feedstock (including various types of fuels) or blended with gasoline. Fuels which are produced partially or fully from methanol include biodiesel, dimethyl ether or oxymethylene ether, as well as synthetic gasoline from the Mobil methanol-to-gasoline (MTG) process. Gasoline blends range from 3% methanol, which is allowed in European standard gasoline, to 56% methanol, a blend for flexible fuel vehicles[11] which has the same energy density and oxygen content as E85 gasoline. CRI has run fleet tests with a range of lower blends and higher blend options in cars from different manufacturers, including 100% methanol in special flexible fuel vehicles manufactured by Geely.[12][13] Renewable methanol is compatible with internal combustion engines as well as methanol fuel cells. Internal combustion engines that operate on 100% methanol are in production both for light vehicles, trucks and ships. Methanol fuel cells of varying energy density are available from multiple manufacturers in North America, Europe and Asia.

Production

CRI's first CSP, the GO Plant

Production of renewable methanol does not depend on agricultural resources, as hydrogen and carbon dioxide are the primary inputs. CRI's emissions-to-liquids production process is based on three main modules, carbon dioxide purification, hydrogen generation and the methanol synthesis and purification system.[14] The catalytic conversion process from hydrogen and carbon dioxide occurs in one step, while production of methanol from fossil fuels, such as natural gas or coal, involves several reforming steps to obtain syngas followed by the catalytic step.[15] Unlike some other power-to-fuel technologies, which use carbon dioxide and hydrogen as inputs, CRI's emissions-to-liquids process also does not require the carbon dioxide to be 'shifted' prior to the synthesis step.

Plants

The George Olah Plant, or the GO Plant, has a name-plate capacity of 5 million liters per year.[16] It is located close to the Blue Lagoon spa facility and HS Orka's Svartsengi power station. The plant can capture and utilize around 10% of the carbon dioxide emitted by the Svartsengi power station.[17]

Legislation

The European Union's renewable energy directive recognizes renewable methanol as a renewable transport fuel from non-biological sources, which means that it can be used as an advanced renewable transport fuel under the EU's renewable fuel blending mandates.

Impact

Carbon dioxide is a major cause of global warming. By removing carbon dioxide from industrial emissions and increasing the availability of energy derived from electricity or low-carbon intensity hydrogen, CRI's process helps to mitigate climate change. Renewable methanol burns cleanly as a fuel and substituting renewable methanol for gasoline and diesel fuels reduces urban emissions of particulate matter, sulphur oxides (SOx) and nitrous oxides (NOx).[18]

CRI's process can also be used to store energy in the form of methanol, especially in cases where the energy source is intermittent. For example, wind and solar power are intermittently available. By storing energy from these sources in liquid chemical form, the generation of electricity and utilization of electricity does not have to be linked in time and space.. Methanol is also a good energy carrier. As a liquid fuel it is easier and cheaper to store and transport than gaseous fuels such as hydrogen or methane.

Future projects

CRI plans to implement standardized CSPs (commercial scale plants), each with a capacity of at least 50,000 tons of methanol production per year.[19]

See also

References

  1. "Management". Carbon Recycling International. Archived from the original on September 29, 2013. Retrieved 11 July 2012.
  2. "ETL-Technology". CRI - Carbon Recycling International. Archived from the original on October 26, 2018. Retrieved October 25, 2018.
  3. US 8198338B2, "Process for producing liquid fuel from carbon dioxide and water", issued 2012-06-12 2007-03-20
  4. "Vulcanol". CRI - Carbon Recycling International. Retrieved October 25, 2018.
  5. "Framleiðsla hafin á nýju vistvænu eldsneyti". Morgunblaðið. Retrieved July 24, 2012.
  6. "About Us". Carbon Recycling International. Archived from the original on September 29, 2013. Retrieved 11 July 2012.
  7. Matthew Knight. "Electric car concept drives progress with extended 500-mile range". CNN. Retrieved July 24, 2012.
  8. "First Commercial Plant". Carbon Recycling International. Archived from the original on July 3, 2013. Retrieved 11 July 2012.
  9. "MefCO₂". www.mefco2.eu. Retrieved December 5, 2019.
  10. "FReSMe". www.fresme.eu. Retrieved December 5, 2019.
  11. "Products". Carbon Recycling International. Retrieved July 13, 2012.
  12. "Eldsneyti úr útblæstri". RÚV. Retrieved July 24, 2012.
  13. "Methanol car fleet test yields positive results". CRI - Carbon Recycling International. Retrieved October 25, 2018.
  14. "ETL-Technology". CRI - Carbon Recycling International. Archived from the original on October 26, 2018. Retrieved October 25, 2018.
  15. Ingham, Alan (October 1, 2017). "Reducing the Carbon Intensity of Methanol for Use as a Transport Fuel". Johnson Matthey Technology Review. 61 (4): 297–307. doi:10.1595/205651317x696216. ISSN 2056-5135.
  16. "First Commercial Plant". Carbon Recycling International. Archived from the original on July 3, 2013. Retrieved 11 July 2012.
  17. Paul Fontaine (February 28, 2012). "Carbon Recycling In Effect Near Blue Lagoon". The Reykjavík Grapevine. Retrieved July 24, 2012.
  18. "Methanol Fuels". methanolfuels.org. Retrieved October 25, 2018.
  19. "Commercial Scale Plants". CRI - Carbon Recycling International. Archived from the original on October 26, 2018. Retrieved October 25, 2018.
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