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Molecular drag pump

From Wikipedia, the free encyclopedia

A molecular drag pump is a type of vacuum pump that utilizes the drag of air molecules against a rotating surface.[1] The most common sub-type is the Holweck pump, which contains a rotating cylinder with spiral grooves which direct the gas from the high vacuum side of the pump to the low vacuum side of the pump.[2] The older Gaede pump design is similar, but is much less common due to disadvantages in pumping speed.[3] In general, molecular drag pumps are more efficient for heavy gasses, so the lighter gasses (hydrogen, deuterium, helium) will make up the majority of the residual gasses left after running a molecular drag pump.[4]

The turbomolecular pump invented in the 1950s, is a more advanced version based on similar operation, and a Holweck pump is often used as the backing pump for it. The Holweck pump can produce a vacuum as low as 1×10−8 mmHg (1.3×10−6 Pa).

History

Gaede

The earliest molecular drag pump was created by Wolfgang Gaede, who had the idea of the pump in 1905, and spent several years corresponding with Leybold trying to build a practical device.[5] The first prototype device to meet expectations was completed in 1910, achieving a pressure of less than mbar.[6] By 1912, twelve pumps had been created, and the concept was presented to the meeting of the Physical Society in Münster on 16 September of that year, and was generally well received.[5]

Gaede published several papers on the principles of this molecular pump,[7][8] and patented the design.[9] The working principle is that the gas in the chamber is exposed to one side of a rapidly spinning cylinder. Collisions between the gas and the spinning cylinder gives the molecules of gas momentum in the same direction as the surface of the cylinder, which designed to turn away from the vacuum chamber and toward a fore-line. A separate backing pump is used to lower the pressure at the fore-line (output of the molecular pump), since in order to function, the molecular pump needs to operate under pressures low enough that the gas inside is in free molecular flow. One important measure of the pump is the compression ratio, . This is the ratio of the pressure of the vacuum, to the pressure to the outlet, and is roughly constant across different pressures, but depends on the individual gas.[10]

The compression ratio can be estimated using the kinetic theory of gases by calculating the flow due to collisions with the rotating surfaces, and rate of diffusion in the reverse direction.[11] The compression ratio tends to be better for heavy molecules, since the thermal velocity of lighter gasses is higher and speed of the rotating cylinder has a less effect on these faster moving, lighter gasses.

This "Gaede molecular pump" was used in an early experiment testing vacuum gauges.[12]

Holweck

The improved Holweck design was invented in the early 1920s by Fernand Holweck[13][14] as part of his apparatus for his work in studying soft X-rays. It was manufactured by French scientific instrument maker, Charles Beaudouin.[15] He applied for a patent on the device in 1925.[16] The main difference from the Gaede pump was the addition of a spiral, cut into either to the spinning cylinder, or to the static housing. Holweck pumps have been frequently modeled theoretically.[2][17][18] Holweck's classmate and collaborator, H. Gondet, would later suggest other improvements to the design.[5][19]

Siegbahn

Another design was given by Manne Siegbahn.[20] He had produced a pump which was used in 1926.[21] About 50 of Siegbahn's pumps were made from 1926 to 1940.[5] These pumps were generally slower than comparable diffusion pumps, so were rare outside of Uppsala University. Larger, faster pumps of the Siegbahn type began to be made around 1940 for use in a cyclotron.[22] In 1943, Seigbahn published a paper regarding these pumps, which were based on a rotating disk.[23]

Use in turbomolecular pumps

Main article: Turbomolecular pump

While the molecular drag pumps of Gaede, Holweck, and Siegbahn are functional designs, they have remained relatively uncommon as stand-alone pumps. One issue was pumping speed: alternatives such as the diffusion pump are much faster. Secondly, a major issue with these pumps is reliability: with a gap between moving parts in the tens of micrometers, any dust or temperature change threatens to bring the parts into contact and cause the pump to fail.[24]

The turbomolecular pump overcame many of these disadvantages. Many modern turbomolecular pumps contain built-in molecular drag stages, which allows them to operate at higher foreline pressures.

As a stage in turbo molecular pumps, the most widely used design is the Holweck type, due to a significantly higher pumping speed than the Gaede design. While slower, the Gaede design has the advantage of tolerating a higher inlet pressure for the same compression ratio, and being more compact than the Holweck type.[3] While the Gaede and Holweck designs are significantly more widely used, Siegbahn-type designs continue to be investigated, due to their significantly more compact design compared with Holweck stages.[25]

See also

References

  1. ^ Duval, P.; Raynaud, A.; Saulgeot, C. (1988). "The molecular drag pump: Principle, characteristics, and applications". Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films. 6 (3). American Vacuum Society: 1187–1191. Bibcode:1988JVSTA...6.1187D. doi:10.1116/1.575674. ISSN 0734-2101.
  2. ^ a b Naris, Steryios; Koutandou, Eirini; Valougeorgis, Dimitris (2012). "Design and optimization of a Holweck pump via linear kinetic theory". Journal of Physics: Conference Series. 362 (1): 012024. Bibcode:2012JPhCS.362a2024N. doi:10.1088/1742-6596/362/1/012024. ISSN 1742-6596.
  3. ^ a b Conrad, A; Ganschow, O (1993). "Comparison of Holweck- and Gaede-pumping stages". Vacuum. 44 (5–7). Elsevier BV: 681–684. Bibcode:1993Vacuu..44..681C. doi:10.1016/0042-207x(93)90123-r. ISSN 0042-207X.
  4. ^ A. Bhatti, J; K. Aijazi, M; Q. Khan, A (2001). "Design characteristics of molecular drag pumps". Vacuum. 60 (1–2). Elsevier BV: 213–219. Bibcode:2001Vacuu..60..213A. doi:10.1016/s0042-207x(00)00374-2. ISSN 0042-207X.
  5. ^ a b c d Redhead, P. A. (1994). Vacuum science and technology : pioneers of the 20th century : history of vacuum science and technology volume 2. New York, NY: AIP Press for the American Vacuum Society. pp. 114–125. ISBN 978-1-56396-248-6. OCLC 28587335.
  6. ^ Henning, Hinrich (2009). "Renaissance einer Hundertjährigen. Die Molekularpumpe von Wolfgang Gaede" [Renaissance of a century: the molecular pump of Wolfgang Gaede]. Vakuum in Forschung und Praxis (in German). 21 (4). Wiley: 19–22. doi:10.1002/vipr.200900392. ISSN 0947-076X. S2CID 94485485.
  7. ^ Gaede, W. (1912). "Die äußere Reibung der Gase und ein neues Prinzip für Luftpumpen: Die Molekularluft-pumpe" [The exterior friction of gasses and a new principle for air pumps: the molecular air pump]. Physikalische Zeitschrift (in German). 13: 864–870.
  8. ^ Gaede, W. (1913). "Die Molekularluftpumpe" [The molecular air pump]. Annalen der Physik (in German). 346 (7). Wiley: 337–380. Bibcode:1913AnP...346..337G. doi:10.1002/andp.19133460707. ISSN 0003-3804.
  9. ^ US patent 1069408, Wolfgang Gaede, "Method and apparatus for producing high vacuums", issued 1913 Aug 05 
  10. ^ Dushman, Saul (July 1920). "The Production and Measurement of High Vacua: Part II Methods for the production of low pressures". General Electric Review. 23 (7): 612–614.
  11. ^ Jacobs, Robert B. (1951). "The Design of Molecular Pumps". Journal of Applied Physics. 22 (2). AIP Publishing: 217–220. doi:10.1063/1.1699927. ISSN 0021-8979.
  12. ^ Dushman, Saul (1 February 1915). "Theory and Use of the Molecular Gauge". Physical Review. 5 (3). American Physical Society (APS): 212–229. Bibcode:1915PhRv....5..212D. doi:10.1103/physrev.5.212. ISSN 0031-899X.
  13. ^ Holweck, M. (1923). "Physique Moléculaire - pompe moléculaire hélicoïdale" [Molecular physics - helical molecular pump]. Comptes rendus de l'Académie des Sciences (in French). 177: 43–46.
  14. ^ Elwell, C. F. (1927). "The Holweck demountable type valve". Institution of Electrical Engineers - Proceedings of the Wireless Section of the Institution. 2 (6). Institution of Engineering and Technology (IET): 155–156. doi:10.1049/pws.1927.0011. ISSN 2054-0655.
  15. ^ Beaudouin, Denis (2006). "Charles Beaudouin, a story of scientific instruments". Bulletin of the Scientific Instrument Society. Vol. 90. p. 34.
  16. ^ FR patent 609813, Fernand-Hippolyte-Lo Holweck, "Pompe moléculaire" 
  17. ^ Skovorodko, Petr A. (2001). Free molecular flow in the Holweck pump. AIP conference proceedings. Unsolved Problems of Noise and Fluctuations. Vol. 585. AIP. p. 900. doi:10.1063/1.1407654. ISSN 0094-243X.
  18. ^ Naris, S.; Tantos, C.; Valougeorgis, D. (2014). "Kinetic modeling of a tapered Holweck pump" (PDF). Vacuum. 109. Elsevier BV: 341–348. Bibcode:2014Vacuu.109..341N. doi:10.1016/j.vacuum.2014.04.006. ISSN 0042-207X.
  19. ^ Gondet, H. (1945). "Étude et réalisation d'une nouvelle pompe rotative à vide moléculaire". Le Vide (in French). 18: 513. ISSN 1266-0167.
  20. ^ GB 332879A, "Improvements in or relating to rotary vacuum pumps", published 1930-07-31, assigned to Karl Manne Georg Siegbahn 
  21. ^ Kellström, Gunnar (1927). "Präzisionsmessungen in derK-Serie der Elemente Palladium und Silber" [Precision measurements of the K series of Palladium and Silver]. Zeitschrift für Physik A (in German). 41 (6–7). Springer Science and Business Media LLC: 516–523. Bibcode:1927ZPhy...41..516K. doi:10.1007/bf01400210. ISSN 0939-7922. S2CID 124854698.
  22. ^ von Friesen, Sten (1940). "Large Molecular Pumps of the Disk Type". Review of Scientific Instruments. 11 (11). AIP Publishing: 362–364. doi:10.1063/1.1751585. ISSN 0034-6748.
  23. ^ Siegbahn, M. (1943). "A new design for a high vacuum pump". Arkiv för Matematik, Astronomi och Fysik. 30B (2): 261. ISSN 0365-4133. via Power, Basil Dixon (1966). High Vacuum Pumping Equipment. Chapman and Hall. p. 190.
  24. ^ Henning, Hinrich (1998). "Turbomolecular Pumps". Handbook of Vacuum Science and Technology. Elsevier. pp. 183–213. doi:10.1016/b978-012352065-4/50056-0. ISBN 978-0-12-352065-4.
  25. ^ Giors, S.; Campagna, L.; Emelli, E. (2010). "New spiral molecular drag stage design for high compression ratio, compact turbomolecular-drag pumps". Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films. 28 (4). American Vacuum Society: 931–936. doi:10.1116/1.3386591. ISSN 0734-2101.

Further reading

This page was last edited on 18 May 2023, at 23:34
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