Difference between revisions of "Sorbs"

Latest revision as of 09:20, 22 February 2010

I have typed up a summary of important information about sorbs:

Charcoal as a Helium Cryopump, Version 1.0

Here is a summary of key points:

The bonding agent does indeed have a very significant effect on the pumping abilities of a sorb. Data shows that poor thermal conductors like SS or ZrO2 cements have little or no pumping speed, while Ag-Sn braze bonds and copper cements have the best pumping speed. This would suggest that using Stycast as a bonding agent is not ideal, since it has very poor thermal conductivity (~1/5 that of 316 SS at 4K).

Baking out sorbs is always a good idea, but heating them too much can be bad. Experiments have shown that charcoal heated to very high temperatures (~900 Celcius) in preparation had a reduced pumping speed. However, heating to moderate temperatures (<250 Celsius) seems to be fine.

Contamination of sorbs by pump oil is significant enough that after a few weeks under vacuum, pumping speed can drop by almost an order of magnitude. Sorbs should be baked out and cooled in the presence of a cold surface onto which contaminants can condense, for example a clean metal surface at or below LN2 temperatures.

This is a first draft. There is more that I would like to add to it, but there is enough in it for now. The references are listed below. -- Nick Hutzler, 28 October 2008

1. Sedgley et al, Characterization of charcoals for helium cryopumping in fusion devices. J. Vac. Sci. Technol. A 5(4) (1987).
2. Tobin et al, Evaluation of charcoal sorbents for helium cryopumping in fusion reactors. J. Vac. Sci. Technol. A 5(1) (1987).
3. Sedgley et al, Development of Charcoal Sorbents for Helium Cryopumping. 10th Symposium on Fusion Engineering (1983), pp. 454–458.
4. Wes Campbell's Thesis, sec. 3.2.5
5. Hseuh et al, Cryosorption Pumping of He by Charcoal. 8th Symposium on Engineering Problems of Fusion Research (1979), pp. 1578–1562.
6. Hands, Recent developments in cryopumping. Vacuum 32(10/11) (1982).
7. Lessard, Cryogenic Adsorption of Noncondensibles in the High-Vacuum Regime. J. Vac. Sci. Technol. A 7(3) (1989).
8. Gurevich et al, Helium Cryopumping. Plasma Devices and Operations 1 (1990).
9. Sedgley et al, Cryopumping for Fusion Power Applications. 11th Symposium on Fusion Engineering (1985), pp. 958–962.
10. Coupland et al, Experimental Performance of a Large-Scale Cryopump. J. Vac. Sci. Technol. A 5(4) (1987).

Some other good papers that did not yet make it into the summary:

Halama et al, Cryopumping of Hydrogen and Helium

@@ Line 1: / Line 1: @@
 I have typed up a summary of important information about sorbs:
-* [http://cua.harvard.edu/~edm/papers/sorbs/sorbs.pdf Charcoal as a Helium Cryopump, Version 1.0]
+* [http://www.doylegroup.harvard.edu/files/sorbs/sorbs.pdf Charcoal as a Helium Cryopump, Version 1.0]
 Here is a summary of key points:
@@ Line 13: / Line 13: @@
 This is a first draft. There is more that I would like to add to it, but there is enough in it for now. The references are listed below. -- Nick Hutzler, 28 October 2008
-* 1. [http://cua.harvard.edu/~edm/papers/sorbs/Characterization%20of%20charcoals%20for%20helium%20cryopumping%20in%20fusion%20devices.pdf Sedgley et al, Characterization of charcoals for helium cryopumping in fusion devices.] J. Vac. Sci. Technol. A 5(4) (1987).
+* 1. [http://www.doylegroup.harvard.edu/files/sorbs/Characterization%20of%20charcoals%20for%20helium%20cryopumping%20in%20fusion%20devices.pdf Sedgley et al, Characterization of charcoals for helium cryopumping in fusion devices.] J. Vac. Sci. Technol. A 5(4) (1987).
-* 2. [http://cua.harvard.edu/~edm/papers/sorbs/Evaluation%20of%20charcoal%20sorbents%20for%20helium%20cryopumping%20in%20fusion%20reactors.pdf Tobin et al, Evaluation of charcoal sorbents for helium cryopumping in fusion reactors.] J. Vac. Sci. Technol. A 5(1) (1987).
+* 2. [http://www.doylegroup.harvard.edu/files/sorbs/Evaluation%20of%20charcoal%20sorbents%20for%20helium%20cryopumping%20in%20fusion%20reactors.pdf Tobin et al, Evaluation of charcoal sorbents for helium cryopumping in fusion reactors.] J. Vac. Sci. Technol. A 5(1) (1987).
-* 3. [http://cua.harvard.edu/~edm/papers/sorbs/Development%20of%20Charcoal%20Sorbents%20for%20Helium%20Cryopumping%20-%20No%20Cover.pdf Sedgley et al, Development of Charcoal Sorbents for Helium Cryopumping.] 10th Symposium on Fusion Engineering (1983), pp. 454–458.
+* 3. [http://www.doylegroup.harvard.edu/files/sorbs/Development%20of%20Charcoal%20Sorbents%20for%20Helium%20Cryopumping%20-%20No%20Cover.pdf Sedgley et al, Development of Charcoal Sorbents for Helium Cryopumping.] 10th Symposium on Fusion Engineering (1983), pp. 454–458.
-* 4. [http://cua.harvard.edu/~edm/papers/sorbs/Campbell%20Thesis.pdf Wes Campbell's Thesis, sec. 3.2.5]
+* 4. [http://www.doylegroup.harvard.edu/files/sorbs/Campbell%20Thesis.pdf Wes Campbell's Thesis, sec. 3.2.5]
-* 5. [http://cua.harvard.edu/~edm/papers/sorbs/Cryosorption%20Pumping%20of%20He%20by%20Charcoal.pdf Hseuh et al, Cryosorption Pumping of He by Charcoal.] 8th Symposium on Engineering Problems of Fusion Research (1979), pp. 1578–1562.
+* 5. [http://www.doylegroup.harvard.edu/files/sorbs/Cryosorption%20Pumping%20of%20He%20by%20Charcoal.pdf Hseuh et al, Cryosorption Pumping of He by Charcoal.] 8th Symposium on Engineering Problems of Fusion Research (1979), pp. 1578–1562.
-* 6. [http://cua.harvard.edu/~edm/papers/sorbs/Recent%20Developments%20in%20Cryopumping.pdf Hands, Recent developments in cryopumping.] Vacuum 32(10/11) (1982).
+* 6. [http://www.doylegroup.harvard.edu/files/sorbs/Recent%20Developments%20in%20Cryopumping.pdf Hands, Recent developments in cryopumping.] Vacuum 32(10/11) (1982).
-* 7. [http://cua.harvard.edu/~edm/papers/sorbs/Cryogenic%20Adsorption%20of%20Noncondensibles%20in%20the%20High-Vacuum%20Regime.pdf Lessard, Cryogenic Adsorption of Noncondensibles in the High-Vacuum Regime.] J. Vac. Sci. Technol. A 7(3) (1989).
+* 7. [http://www.doylegroup.harvard.edu/files/sorbs/Cryogenic%20Adsorption%20of%20Noncondensibles%20in%20the%20High-Vacuum%20Regime.pdf Lessard, Cryogenic Adsorption of Noncondensibles in the High-Vacuum Regime.] J. Vac. Sci. Technol. A 7(3) (1989).
-* 8. [http://cua.harvard.edu/~edm/papers/sorbs/Helium%20Cryopumping%20-%20No%20Cover.pdf Gurevich et al, Helium Cryopumping.] Plasma Devices and Operations 1 (1990).
+* 8. [http://www.doylegroup.harvard.edu/files/sorbs/Helium%20Cryopumping%20-%20No%20Cover.pdf Gurevich et al, Helium Cryopumping.] Plasma Devices and Operations 1 (1990).
-* 9. [http://cua.harvard.edu/~edm/papers/sorbs/Cryopumping%20for%20Fusion%20Power%20Applications%20-%20No%20Cover.pdf Sedgley et al, Cryopumping for Fusion Power Applications.] 11th Symposium on Fusion Engineering (1985), pp. 958–962.
+* 9. [http://www.doylegroup.harvard.edu/files/sorbs/Cryopumping%20for%20Fusion%20Power%20Applications%20-%20No%20Cover.pdf Sedgley et al, Cryopumping for Fusion Power Applications.] 11th Symposium on Fusion Engineering (1985), pp. 958–962.
-* 10. [http://cua.harvard.edu/~edm/papers/sorbs/Experimental%20Performance%20of%20a%20Large-Scale%20Cryopump.pdf Coupland et al, Experimental Performance of a Large-Scale Cryopump.] J. Vac. Sci. Technol. A 5(4) (1987).
+* 10. [http://www.doylegroup.harvard.edu/files/sorbs/Experimental%20Performance%20of%20a%20Large-Scale%20Cryopump.pdf Coupland et al, Experimental Performance of a Large-Scale Cryopump.] J. Vac. Sci. Technol. A 5(4) (1987).
 Some other good papers that did not yet make it into the summary:
-* [http://cua.harvard.edu/~edm/papers/sorbs/Cryopumping%20of%20Hydrogen%20and%20Helium.pdf Halama et al, Cryopumping of Hydrogen and Helium]
+* [http://www.doylegroup.harvard.edu/files/sorbs/Cryopumping%20of%20Hydrogen%20and%20Helium.pdf Halama et al, Cryopumping of Hydrogen and Helium]

Difference between revisions of "Sorbs"

Latest revision as of 09:20, 22 February 2010

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