Difference between revisions of "Carbon Dioxide Scrubbers"

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(Created page with "[This is an article in progress, and is currently being written] A steady supply of oxygen alone is insufficient to keep astronauts breathing. While the intake of oxygen is es...")
 
(Why Must C02 Be Removed?)
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[This is an article in progress, and is currently being written]
 
[This is an article in progress, and is currently being written]
A steady supply of oxygen alone is insufficient to keep astronauts breathing. While the intake of oxygen is essential for respiration, the by-product of this respiration is the exhalation of about one kilogram of carbon-dioxide per day.[1]
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==Why Remove C0<sub>2</sub>?==
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A steady supply of oxygen alone is insufficient to keep astronauts breathing. While the intake of oxygen is essential for respiration, the by-product of this respiration is the exhalation of approximately one kilogram of carbon-dioxide per day.<ref name=":1">James, J. T., & Macatangay, A. (2009). ''Carbon Dioxide – Our Common “Enemy.”'' 8.</ref> The concentration of this gas in Earth's atmosphere is roughly 0.04%, but in the close confines endured by astronauts, accumulations of CO<sub>2</sub> can quickly reach toxic levels.<ref name=":0">Freudenrich, C. (2011). How is carbon dioxide eliminated aboard a spacecraft? | HowStuffWorks. Retrieved August 15, 2019, from HowStuffWorks website: <nowiki>https://science.howstuffworks.com/carbon-dioxide-eliminated-aboard-spacecraft.htm</nowiki></ref>
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{| class="wikitable"
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|+Symptoms Experienced According to CO<sub>2</sub> Level<ref name=":0" />
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!CO<sub>2</sub> Concentration
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!Symptoms
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|-
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|1%
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|Drowsiness
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|-
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|3%
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|Impaired hearing, increased heart rate and blood pressure, stupor
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|-
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|5%
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|Shortness of breath, headache, dizziness, confusion
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|-
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|8%
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|Unconsciousness, muscle tremors, sweating
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|-
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|>8%
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|Death
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|}
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NASA has set strict limits of acceptable CO<sub>2</sub> concentration on spacecraft. The longer the duration of the flight, the lower the permissible maximum: for example, while allowing a maximum of 2% for a one-hour period, NASA recommends that the concentration not exceed 0.5% over a 1000-day stay<ref name=":1" /> (an as-yet hypothetical duration, as the record for longest consecutive stay in space at the time of writing is held by Russian cosmonaut Valery Polyakov at 438 days<ref>Wall, M. (2019). Most Extreme Human Spaceflight Records of All Time | Space. Retrieved August 15, 2019, from Soace.com website: <nowiki>https://www.space.com/11337-human-spaceflight-records-50th-anniversary.html</nowiki></ref>). The proportionate decrease in concentration acceptability in accordance with duration accounts for the fact that the longer the period of time, the higher the likelihood of CO<sub>2</sub>-induced behavioral changes negatively affecting missions requiring close personal contact in confined spaces.
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Moderating CO<sub>2</sub> levels over such a long period of time naturally implies weight and power demands, yet NASA has adopted more stringent regulations than the Navy, which allows up to 2.5% concentrations for submarine personnel over a 24-hour period.<ref name=":1" /> While both types of crews operate in a confined area with an artificially-regulated atmosphere, repairing a CO<sub>2</sub> removal system in space constitutes a potentially more complex task where one cannot simply surface in the event of an unsuccessful attempt brought on by concentration difficulties. Hypothetically, a well-developed Mars colony could relax such limitations slightly once it is large enough to contain multiple fail-safes and back-ups, thereby reducing the energy demands on the colony as a whole.
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==Biological C0<sub>2</sub> Scrubbers==
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On Earth,plant life removes carbon dioxide from the air and replaces it with oxygen. This elegant solution has yet to feature as the primary form of CO<sub>2</sub> scrubbing for spacecraft, principally because of the number of plants required in conjunction with the costs of providing optimized lighting and air conditioning.<ref>Closing the Loop: Recycling Water and Air in Space. (n.d.). Retrieved August 15, 2019, from NASA.gov website: <nowiki>https://www.nasa.gov/pdf/146558main_RecyclingEDA(final)%204_10_06.pdf</nowiki></ref> The International Space Station, for example, has plants aboard, but not in the quantities necessary to have any appreciable impact on CO<sub>2</sub> concentrations.<ref>Dunn, T. (2015). Dissecting the Technology of “The Martian”: Air—Tested. Retrieved August 15, 2019, from Tested.com website: <nowiki>https://www.tested.com/science/538792-dissecting-technology-martian-air/</nowiki></ref> Yet, such a system could potentially fill the air-recycling needs of future Mars habitats or even spacecraft.
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==References==
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*
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<references />

Revision as of 20:57, 15 August 2019

[This is an article in progress, and is currently being written]

Why Remove C02?

A steady supply of oxygen alone is insufficient to keep astronauts breathing. While the intake of oxygen is essential for respiration, the by-product of this respiration is the exhalation of approximately one kilogram of carbon-dioxide per day.[1] The concentration of this gas in Earth's atmosphere is roughly 0.04%, but in the close confines endured by astronauts, accumulations of CO2 can quickly reach toxic levels.[2]

Symptoms Experienced According to CO2 Level[2]
CO2 Concentration Symptoms
1% Drowsiness
3% Impaired hearing, increased heart rate and blood pressure, stupor
5% Shortness of breath, headache, dizziness, confusion
8% Unconsciousness, muscle tremors, sweating
>8% Death

NASA has set strict limits of acceptable CO2 concentration on spacecraft. The longer the duration of the flight, the lower the permissible maximum: for example, while allowing a maximum of 2% for a one-hour period, NASA recommends that the concentration not exceed 0.5% over a 1000-day stay[1] (an as-yet hypothetical duration, as the record for longest consecutive stay in space at the time of writing is held by Russian cosmonaut Valery Polyakov at 438 days[3]). The proportionate decrease in concentration acceptability in accordance with duration accounts for the fact that the longer the period of time, the higher the likelihood of CO2-induced behavioral changes negatively affecting missions requiring close personal contact in confined spaces.

Moderating CO2 levels over such a long period of time naturally implies weight and power demands, yet NASA has adopted more stringent regulations than the Navy, which allows up to 2.5% concentrations for submarine personnel over a 24-hour period.[1] While both types of crews operate in a confined area with an artificially-regulated atmosphere, repairing a CO2 removal system in space constitutes a potentially more complex task where one cannot simply surface in the event of an unsuccessful attempt brought on by concentration difficulties. Hypothetically, a well-developed Mars colony could relax such limitations slightly once it is large enough to contain multiple fail-safes and back-ups, thereby reducing the energy demands on the colony as a whole.

Biological C02 Scrubbers

On Earth,plant life removes carbon dioxide from the air and replaces it with oxygen. This elegant solution has yet to feature as the primary form of CO2 scrubbing for spacecraft, principally because of the number of plants required in conjunction with the costs of providing optimized lighting and air conditioning.[4] The International Space Station, for example, has plants aboard, but not in the quantities necessary to have any appreciable impact on CO2 concentrations.[5] Yet, such a system could potentially fill the air-recycling needs of future Mars habitats or even spacecraft.

References

  1. 1.0 1.1 1.2 James, J. T., & Macatangay, A. (2009). Carbon Dioxide – Our Common “Enemy.” 8.
  2. 2.0 2.1 Freudenrich, C. (2011). How is carbon dioxide eliminated aboard a spacecraft? | HowStuffWorks. Retrieved August 15, 2019, from HowStuffWorks website: https://science.howstuffworks.com/carbon-dioxide-eliminated-aboard-spacecraft.htm
  3. Wall, M. (2019). Most Extreme Human Spaceflight Records of All Time | Space. Retrieved August 15, 2019, from Soace.com website: https://www.space.com/11337-human-spaceflight-records-50th-anniversary.html
  4. Closing the Loop: Recycling Water and Air in Space. (n.d.). Retrieved August 15, 2019, from NASA.gov website: https://www.nasa.gov/pdf/146558main_RecyclingEDA(final)%204_10_06.pdf
  5. Dunn, T. (2015). Dissecting the Technology of “The Martian”: Air—Tested. Retrieved August 15, 2019, from Tested.com website: https://www.tested.com/science/538792-dissecting-technology-martian-air/