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특허 상세정보

Thermo-siphon method for providing refrigeration to a refrigeration load

국가/구분 United States(US) Patent 등록
국제특허분류(IPC7판) F25D-017/02   
미국특허분류(USC) 62/099; 62/119; 62/434; 165/10421
출원번호 US-0107787 (2002-03-28)
발명자 / 주소
출원인 / 주소
대리인 / 주소
    Stanley Ktorides
인용정보 피인용 횟수 : 16  인용 특허 : 8
초록

A method wherein refrigeration is generated, preferably using a pulse tube cryocooler or refrigerator, to produce cold working gas which is used to liquefy coupling fluid circulating between a coupling fluid liquid reservoir and a refrigeration load, such as superconductivity equipment, using thermo-siphon effects.

대표
청구항

1. A method for providing refrigeration to a refrigeration load comprising:(A) generating a cold working gas, warming the cold working gas by indirect heat exchange with coupling fluid vapor to produce coupling fluid liquid, and forming a coupling fluid liquid reservoir having a liquid level; (B) passing coupling fluid liquid from the coupling fluid liquid reservoir to a refrigeration load using a thermo-siphon effect, said refrigeration load being at a lower elevation than the liquid level of the coupling fluid liquid of the coupling fluid liquid reserv...

이 특허를 인용한 특허 피인용횟수: 16

  1. Frank, Michael; Van Hasselt, Peter. Apparatus and method for cooling a super conducting machine. USP2015028948828.
  2. Bonaquist,Dante Patrick; Royal,John Henri; Rampersad,Bryce; Jibb,Richard J.. Biological refrigeration system. USP2006067059138.
  3. Frank, Michael; Kummeth, Peter; Nick, Wolfgang; Schmidt, Heinz. Cooling device for a super conductor and super conducting synchronous machine. USP2016069377220.
  4. Samadiani, Emad; Wong, Eehern J.; Imwalle, Gregory P.; Farshchian, Soheil. Cooling electronic devices in a data center. USP2017019552025.
  5. Samadiani, Emad; Wong, Eehern J.; Imwalle, Gregory P.; Farshchian, Soheil. Cooling electronic devices in a data center. USP2018059961803.
  6. Acharya, Arun; Royal, John Henri; Roberge, Raymond Paul; Arman, Bayram; Meredith, Brian Michael. Cryogenic system for providing industrial gas to a use point. USP2003126668581.
  7. Schmidt, Heinz. Device and method for cooling a unit. USP20181110132560.
  8. Black, Randall; Martien, Dinesh; Neils, William; Diederichs, Jost. Method and apparatus for controlling temperature in a cryocooled cryostat using static and moving gas. USP2016019234691.
  9. Swift, Gregory W.; Wollan, John J.. Method and apparatus for fine tuning an orifice pulse tube refrigerator. USP2003126666033.
  10. Bonaquist, Dante Patrick; Rampersad, Bryce Mark; Royal, John Henri. Method for providing cooling to superconducting cable. USP2004056732536.
  11. Bonaquist, Dante Patrick; Rampersad, Bryce Mark; Royal, John Henri. Method for providing cooling to superconducting cable. USP2005056895765.
  12. Jibb, Richard J.. Method for providing refrigeration using capillary pumped liquid. USP2005036865897.
  13. Kapsha, Christopher. Multistage refrigeration system. USP20181210156385.
  14. Fuchs, Thomas; Ornot, Leo; Reck, Markus; Reuter, Matthias. Passive two-phase cooling circuit. USP2018019874406.
  15. Akiba,Takesada; Ueda,Shigeki; Tachibana,Toshikazu; Horiguchi,Masashi. Semiconductor memory circuit. USP2006087088636.
  16. Sone, Kazuya. Thermosiphon. USP2004046725907.