Carbon dioxide recorder

A carbon dioxide recorder (or CO₂ recorder) is a machine that can record the level of carbon dioxide at different times. It is more sophisticated than a carbon dioxide detector which only has to indicate the presence of carbon dioxide. There are three main types of carbon dioxide recorder: chemical, physical, and electrical.

Mechanism[edit]

Chemical[edit]

The chemical carbon dioxide recorder, sucks the gas through a chemical that absorbs carbon dioxide. They include the Simmance combustion recorder;^[1] Hays automatic CO₂ recorder, and electroflo CO₂ recorder.

The Arndt carbon dioxide recorder used a potassium hydroxide solution to absorb carbon dioxide.^[2]

The Uehling recorder uses the chemical, sodium hydroxide to absorb the carbon dioxide, and measures the change in volume of the gas.^[3]

Physical[edit]

The physical carbon dioxide recorder, includes Webster CO₂ recorder. The Remarex carbon dioxide recorder uses vanes spinning in the gas under test and the air.^[4]

Electrical[edit]

Electrical recorders use a thermal conductivity method, where the resistance of a heated wire is measured.^[5]^[6]

Form[edit]

Carbon dioxide recorders can be handheld, or wall mount. They can have an audible or light indicator alarm if level is too high. Units can also measure humidity and temperature.^{[citation needed]}

Application[edit]

Carbon dioxide recorders have been used in schools and hospitals to determine whether enough fresh air is being circulated. A carbon dioxide recorder can be used to measure the composition of flue gas to check if combustion is at its most efficient.^[3] In agriculture, they can be used to measure levels of carbon dioxide in greenhouses, where the levels are deliberately elevated.^[6]

References[edit]

^ Levy, Leonard A. (1922). Gasworks recorders, their construction and uses. London: Benn Brothers. pp. 174–178.
^ Levy, Leonard A. (1922). Gasworks recorders, their construction and uses. London: Benn Brothers. pp. 171–174.
^ ^a ^b Uehling, E. A. (February 1912). "The Carbon Dioxide Recorder as a Factor in Fuel Economy". Journal of Industrial & Engineering Chemistry. 4 (2): 123–124. doi:10.1021/ie50038a012.
^ Bellman, Richard; Kalaba, Robert (8 November 2017). Classic Papers in Control Theory. Courier Dover Publications. p. 602. ISBN 978-0-486-82593-9.
^ Palmer, P. E.; Weaver, E. R. (7 January 1927). "Thermal-Conductivity Method for the Analysis Of Gases" (PDF). Technologic Papers of the Bureau of Standards. 18 (249): 36–99.
^ ^a ^b Rosecrans, Crandall Z. (1 June 1927). "Automatic Gas Analysis Recorder for the Range of 0 to 35 per cent of CO_2 in Air". Journal of the Optical Society of America. 14 (6): 479–490. doi:10.1364/JOSA.14.000479.

[1] Levy, Leonard A. (1922). Gasworks recorders, their construction and uses. London: Benn Brothers. pp. 174–178.

[2] Levy, Leonard A. (1922). Gasworks recorders, their construction and uses. London: Benn Brothers. pp. 171–174.

[Ue-3] Uehling, E. A. (February 1912). "The Carbon Dioxide Recorder as a Factor in Fuel Economy". Journal of Industrial & Engineering Chemistry. 4 (2): 123–124. doi:10.1021/ie50038a012.

[4] Bellman, Richard; Kalaba, Robert (8 November 2017). Classic Papers in Control Theory. Courier Dover Publications. p. 602. ISBN 978-0-486-82593-9.

[5] Palmer, P. E.; Weaver, E. R. (7 January 1927). "Thermal-Conductivity Method for the Analysis Of Gases" (PDF). Technologic Papers of the Bureau of Standards. 18 (249): 36–99.

[rose-6] Rosecrans, Crandall Z. (1 June 1927). "Automatic Gas Analysis Recorder for the Range of 0 to 35 per cent of CO_2 in Air". Journal of the Optical Society of America. 14 (6): 479–490. doi:10.1364/JOSA.14.000479.

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