Difference between revisions of "Fischer-Tropsch reaction"
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− | The '''[[w:Fischer–Tropsch_process|Fischer-Tropsch reaction]]''' converts [[hydrogen]] and [[carbon monoxide]] into various [[hydrocarbons]] | + | The '''[[w:Fischer–Tropsch_process|Fischer-Tropsch reaction]]''' converts [[hydrogen]] and [[carbon monoxide]] into various [[hydrocarbons]]. The process is likely to be an essential part of the [[In-situ resource utilization|In Situ resource utilization]] of a Martian settlement. |
− | :(2n+1)[[hydrogen|H<sub>2</sub>]] + n[[carbon monoxide|CO]] → C<sub>n</sub>H<sub>(2n+2)</sub> + n[[water|H<sub>2</sub>O]] 'n' is any positive number. | + | :The process follows the bellow equation: |
+ | :(2n+1)[[hydrogen|H<sub>2</sub>]] + n[[carbon monoxide|CO]] → C<sub>n</sub>H<sub>(2n+2)</sub> + n[[water|H<sub>2</sub>O]] where 'n' is any positive number. | ||
− | Hydrogen can be obtained from [[water]] through [[electrolysis]]. Carbon monoxide | + | Hydrogen for the process can be obtained from [[water]] through [[electrolysis]]. Carbon monoxide on Mars will be available through the [[Reverse Water-Gas Shift Reaction]]. |
+ | |||
+ | It is also possible to use [[Syngas]] to feed the reaction. | ||
__NOTOC__ | __NOTOC__ | ||
− | ==Process== | + | ==Fischer Tropsch Process== |
− | The process is carried out in reactors at various temperatures and pressures depending on the catalysts and the desired products. Reactor cooling is an important part of the process to obtain the desired products. | + | The process is carried out in reactors at various temperatures and pressures depending on the catalysts and the desired products. Reactor cooling is an important part of the process to obtain the desired reactions. The end result is a mixture of hydrocarbons, and further processing is required to separate the mixture into individual usable products. |
===Reactors=== | ===Reactors=== | ||
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===Process efficiency=== | ===Process efficiency=== | ||
− | Using conventional Fischer-Tropsch technology, the process ranges in carbon efficiency from 25 to 50% and a thermal efficiency of about 50%. For CTL facilities idealized at 60% with GTL facilities at about 60% efficiency is idealized to 80% efficiency. | + | Using conventional Fischer-Tropsch technology, the process ranges in carbon efficiency from 25 to 50% and a thermal efficiency of about 50%. For CTL facilities idealized at 60% with GTL facilities at about 60% efficiency is idealized to 80% efficiency (from Wikipedia). |
− | + | ==Existing examples== | |
− | A large scale implementation of Fischer–Tropsch technology is a series of plants operated by Sasol in South Africa, a country with large coal reserves, but little oil. The first commercial plant opened in 1952. Sasol uses coal and now natural gas as feedstocks and produces a variety of synthetic petroleum products, including most of the country's diesel fuel. there are multiple other examples. | + | A large scale implementation of Fischer–Tropsch technology is a series of plants operated by Sasol in South Africa, a country with large coal reserves, but little oil. The first commercial plant opened in 1952. Sasol uses coal and now natural gas as feedstocks and produces a variety of synthetic petroleum products, including most of the country's diesel fuel. there are multiple other examples. Historically, the process was used in Germany during the Second World War to produce gasoline from coal. |
− | + | ==On Mars== | |
The process would be a path to the synthesis of complex hydrocarbons on Mars from abundant Water and CO2 resources. It will be in competition with synthesis from [[biomass]] as this resource builds up from the presence of humans on Mars and [[Food|food production]]. Fischer–Tropsch catalysts are sensitive to poisoning by sulfur-containing compounds. Cobalt-based catalysts are more sensitive than their iron counterparts. As [[sulfur]] in more common on Mars than on Earth precautions may need to be taken in the preparation of the feedstocks to the reaction. | The process would be a path to the synthesis of complex hydrocarbons on Mars from abundant Water and CO2 resources. It will be in competition with synthesis from [[biomass]] as this resource builds up from the presence of humans on Mars and [[Food|food production]]. Fischer–Tropsch catalysts are sensitive to poisoning by sulfur-containing compounds. Cobalt-based catalysts are more sensitive than their iron counterparts. As [[sulfur]] in more common on Mars than on Earth precautions may need to be taken in the preparation of the feedstocks to the reaction. | ||
− | + | Small scale versions adapted to Mars may be similar to packaged products from Ineratec<ref>Website: https://ineratec.de/en/home/</ref>. Containerized equipment could be an appropriate format for the equipment. However, heat transfer and implementation in either pressurized or unpressurized enclosures will change implementation. Equipment in packaged units are often themselves skid mounted in sub-modules, and the use of the sub modules might be more appropriate than entire containers. | |
+ | |||
+ | ==See Also== | ||
*[[Hydrocarbon synthesis|Hydrocarbon Synthesis]] | *[[Hydrocarbon synthesis|Hydrocarbon Synthesis]] | ||
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[[w:Fischer–Tropsch_process|Wikipedia article]] | [[w:Fischer–Tropsch_process|Wikipedia article]] | ||
[[Category:In-situ Resource Utilization]] | [[Category:In-situ Resource Utilization]] | ||
+ | <references /> |
Latest revision as of 05:26, 2 June 2021
The Fischer-Tropsch reaction converts hydrogen and carbon monoxide into various hydrocarbons. The process is likely to be an essential part of the In Situ resource utilization of a Martian settlement.
- The process follows the bellow equation:
- (2n+1)H2 + nCO → CnH(2n+2) + nH2O where 'n' is any positive number.
Hydrogen for the process can be obtained from water through electrolysis. Carbon monoxide on Mars will be available through the Reverse Water-Gas Shift Reaction.
It is also possible to use Syngas to feed the reaction.
Fischer Tropsch Process
The process is carried out in reactors at various temperatures and pressures depending on the catalysts and the desired products. Reactor cooling is an important part of the process to obtain the desired reactions. The end result is a mixture of hydrocarbons, and further processing is required to separate the mixture into individual usable products.
Reactors
The processes are highly exothermic and efficient cooling is required in the reactors. Multi tubular fixed-bed reactors, Entrained flow reactors, Slurry reactors and fluid-bed and circulating catalyst (riser) reactors are the main types of reactors used.
Processes are generally carried out at 150–300 °C. Production of paraffin is one of the products of the reaction and care must be taken not to create blockages in the equipment. Higher temperatures have higher production rates but tend to create methane, which is counter productive as methane can be more effectively produced by the Sabatier reaction.
Catalysts
Catalysts for this reaction include iron, cobalt, ruthenium, and nickel.
Process efficiency
Using conventional Fischer-Tropsch technology, the process ranges in carbon efficiency from 25 to 50% and a thermal efficiency of about 50%. For CTL facilities idealized at 60% with GTL facilities at about 60% efficiency is idealized to 80% efficiency (from Wikipedia).
Existing examples
A large scale implementation of Fischer–Tropsch technology is a series of plants operated by Sasol in South Africa, a country with large coal reserves, but little oil. The first commercial plant opened in 1952. Sasol uses coal and now natural gas as feedstocks and produces a variety of synthetic petroleum products, including most of the country's diesel fuel. there are multiple other examples. Historically, the process was used in Germany during the Second World War to produce gasoline from coal.
On Mars
The process would be a path to the synthesis of complex hydrocarbons on Mars from abundant Water and CO2 resources. It will be in competition with synthesis from biomass as this resource builds up from the presence of humans on Mars and food production. Fischer–Tropsch catalysts are sensitive to poisoning by sulfur-containing compounds. Cobalt-based catalysts are more sensitive than their iron counterparts. As sulfur in more common on Mars than on Earth precautions may need to be taken in the preparation of the feedstocks to the reaction.
Small scale versions adapted to Mars may be similar to packaged products from Ineratec[1]. Containerized equipment could be an appropriate format for the equipment. However, heat transfer and implementation in either pressurized or unpressurized enclosures will change implementation. Equipment in packaged units are often themselves skid mounted in sub-modules, and the use of the sub modules might be more appropriate than entire containers.
See Also
References
- ↑ Website: https://ineratec.de/en/home/