Densifier for simultaneous conditioning of two cryogenic liquids
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F25B-009/00
F17C-013/02
F17C-013/00
F17C-005/00
출원번호
US-0159743
(2005-06-23)
등록번호
US-7347053
(2008-03-25)
발명자
/ 주소
Haberbusch,Mark Steven
Culler,Adam John
출원인 / 주소
Sierra Lobo, Inc.
대리인 / 주소
Pearne & Gordon LLP
인용정보
피인용 횟수 :
9인용 특허 :
49
초록▼
A densifier is provided which in one embodiment can simultaneously densify two cryogenic liquids at different temperatures. The densifier has an oscillatory power source for generating oscillatory power and a two stage pulse tube refrigerator. The oscillatory power source can be a thermoacoustic he
A densifier is provided which in one embodiment can simultaneously densify two cryogenic liquids at different temperatures. The densifier has an oscillatory power source for generating oscillatory power and a two stage pulse tube refrigerator. The oscillatory power source can be a thermoacoustic heat engine or a mechanical oscillatory power source such as a linear flexure bearing compressor. The first stage densifies a first cryogenic liquid to a first cryogenic temperature, and the second stage densifies a second cryogenic liquid to a second, lower cryogenic temperature. A densified propellant management system also is provided which has a densifier for simultaneously densifying two cryogenic liquids at different temperatures, and a cryogenic temperature probe for measuring the temperature gradient in a cryogenic liquid.
대표청구항▼
What is claimed is: 1. A densifier for densifying two cryogenic liquids, said densifier comprising an oscillatory power source for generating oscillatory power and a pulse tube refrigerator, said pulse tube refrigerator being a two-stage pulse tube refrigerator having a first stage refrigeration un
What is claimed is: 1. A densifier for densifying two cryogenic liquids, said densifier comprising an oscillatory power source for generating oscillatory power and a pulse tube refrigerator, said pulse tube refrigerator being a two-stage pulse tube refrigerator having a first stage refrigeration unit and a second stage refrigeration unit, said first stage refrigeration unit being adapted to supercool a first cryogenic liquid to a first cryogenic temperature, said second stage refrigeration unit being adapted to supercool a second cryogenic liquid to a second cryogenic temperature, wherein said second cryogenic temperature is lower than said first cryogenic temperature. 2. A densifier according to claim 1, said densifier being a fully acoustic densifier wherein said oscillatory power source is an acoustic heat engine and said oscillatory power is oscillatory acoustical power. 3. A densifier according to claim 2, said acoustic heat engine being a thermoacoustic prime mover. 4. A densifier according to claim 2, wherein heat energy is supplied to said acoustic heat engine from a radioactive thermal generator. 5. A densifier according to claim 2, wherein heat energy is supplied to said acoustic heat engine from an electric resistance heating element. 6. A densifier according to claim 1, said oscillatory power source being a mechanical pressure oscillator. 7. A densifier according to claim 6, said mechanical pressure oscillator being a linear flexure bearing compressor. 8. A densifier according to claim 6, said mechanical pressure oscillator being a dual opposed linear flexure bearing compressor. 9. A densifier according to claim 6, said mechanical pressure oscillator being a valved rotary compressor. 10. A densifier according to claim 1, wherein at least one of said first stage refrigeration unit and said second stage refrigeration unit is an orifice pulse tube refrigeration unit. 11. A densifier according to claim 1, said first stage refrigeration unit comprising a first stage cold heat exchanger, said second stage refrigeration unit comprising a second stage cold heat exchanger, wherein said first cryogenic liquid is densified in said first stage cold heat exchanger and said second cryogenic liquid is densified in said second stage cold heat exchanger. 12. A densifier according to claim 11, said first stage refrigeration unit further comprising a first stage regenerator and a first stage pulse tube, said second stage refrigeration unit further comprising a second stage regenerator, wherein said first stage cold heat exchanger is a common thermal block. 13. A densifier according to claim 12, wherein said common thermal block is a shell-and-tube heat exchanger having a shell-side to accommodate a working fluid and a tube-side to accommodate said first cryogenic liquid, said shell-side having an inlet, a first outlet and a second outlet, said inlet of said shell-side being connected to said first stage regenerator, said first outlet of said shell-side being connected to said first stage pulse tube, and said second outlet of said shell-side being connected to said second stage regenerator, wherein said common thermal block delivers oscillatory flow of said working fluid from said first stage regenerator to each of said first stage pulse tube and said second stage regenerator. 14. A densifier according to claim 1, said first stage refrigeration unit comprising a first stage regenerator, a first stage cold heat exchanger and a first stage pulse tube, said first stage regenerator having a first stage regenerator housing and a second heat absorptive material disposed within said housing, said second heat absorptive material having a volumetric heat capacity of at least 1 J/cm3K between 60-90 K. 15. A densifier according to claim 14, said second heat absorptive material comprising a plurality of layers of stainless steel screen mesh. 16. A densifier according to claim 1, said second stage refrigeration unit comprising a second stage regenerator, a second stage cold heat exchanger and a second stage pulse tube, said second stage regenerator having a second stage regenerator housing and a third heat absorptive material disposed within said housing, said third heat absorptive material having a volumetric heat capacity of at least 0.23 J/cm3K at 13-14 K. 17. A densifier according to claim 16, said third heat absorptive material having a volumetric heat capacity of at least 0.5 J/cm3K at 18-20 K. 18. A densifier according to claim 16, said third heat absorptive material comprising a material selected from the group consisting of rare earth metals and rare earth metal compounds. 19. A densifier according to claim 18, said third heat absorptive material comprising an erbium-praseodymium compound. 20. A densifier according to claim 16, said third heat absorptive material being in the form of spheres having a mean diameter of 60-100 microns. 21. A densifier according to claim 1, wherein said first cryogenic liquid is liquid oxygen and said second cryogenic liquid is liquid hydrogen. 22. A densifier according to claim 1, said densifier being adapted to densify at least one of said first cryogenic liquid and said second cryogenic liquid to a slush cryogenic fluid. 23. A densifier according to claim 1, further comprising a low temperature jacket, said jacket substantially enclosing said pulse tube refrigerator. 24. A densifier according to claim 1, said densifier further comprising a low pressure chamber evacuated to below 10-2 torr. 25. A densifier according to claim 1, said densifier further comprising a secondary heat exchanger and an inert recycle passage, wherein said secondary heat exchanger is connected to said first stage refrigeration unit by said inert recycle passage. 26. A densified propellant management system comprising a densifier, and a cryogenic temperature probe, wherein said densifier comprises an oscillatory power source for generating oscillatory power and a pulse tube refrigerator, said pulse tube refrigerator being a two-stage pulse tube refrigerator having a first stage refrigeration unit and a second stage refrigeration unit, said first stage refrigeration unit being adapted to supercool a first cryogenic liquid to a first cryogenic temperature, said second stage refrigeration unit being adapted to supercool a second cryogenic liquid to a second cryogenic temperature, wherein said second cryogenic temperature is lower than said first cryogenic temperature. 27. A system according to claim 26, said system further comprising a first cryogenic liquid storage dewar, wherein said cryogenic temperature probe is disposed within said storage dewar and is effective to measure a temperature gradient of said first cryogenic liquid within said storage dewar. 28. A system according to claim 26, wherein said cryogenic temperature probe comprises a dielectric strip and a series of temperature sensing units disposed at spaced intervals along said strip, said temperature sensing units being effective to measure a temperature gradient within a cryogenic liquid. 29. A system according to claim 26, comprising a plurality of said densifiers arranged in a configuration selected from the group consisting of parallel configuration and serial configuration. 30. A system according to claim 26, said oscillatory power source being a linear flexure bearing compressor. 31. A system according to claim 26, said oscillatory power source being a dual opposed linear flexure bearing compressor. 32. A system according to claim 26, said oscillatory power source being a valved rotary compressor. 33. A densifier comprising an oscillatory power source for generating oscillatory power and a pulse tube refrigerator, said pulse tube refrigerator comprising a first stage refrigeration unit that is adapted to supercool a first cryogenic liquid to a first cryogenic temperature. 34. A densifier according to claim 33, further comprising a second stage refrigeration unit that is adapted to supercool a second cryogenic liquid to a second cryogenic temperature, said first and second stage refrigeration units cooperating such that during operation the cooling duty of the first stage refrigeration unit reduces the cooling load on the second stage refrigeration unit necessary to cool the second cryogenic liquid. 35. A method comprising: a) providing a densifier comprising an oscillatory power source for generating oscillatory power and a pulse tube refrigerator, said pulse tube refrigerator being a two-stage pulse tube refrigerator having a first stage refrigeration unit and a second stage refrigeration unit, said first stage refrigeration unit being adapted to supercool a first cryogenic liquid to a first cryogenic temperature, said second stage refrigeration unit being adapted to supercool a second cryogenic liquid to a second cryogenic temperature, wherein said second cryogenic temperature is lower than said first cryogenic temperature; and b) operating said densifier thus simultaneously supercooling said first cryogenic liquid to said first cryogenic temperature in said first stage refrigeration unit and said second cryogenic liquid to said second cryogenic temperature in said second stage refrigeration unit. 36. A method according to claim 35, further comprising densifying at least one of said first and said second cryogenic liquids in the associated refrigeration unit. 37. A method according to claim 35, further comprising simultaneously densifying each of said first and said second cryogenic liquids in the associated refrigeration unit.
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이 특허에 인용된 특허 (49)
Swift Gregory W. (Santa Fe NM) Martin Richard A. (Los Alamos NM) Radenbaugh Ray (Louisville CO), Acoustic cryocooler.
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Lak Tibor I ; Rogers Gene ; Weber James F. ; Merlin Michael V. ; Gaynor ; III Timothy L. ; Davis John E. ; Gerhardt David L., Cryogenic liquid heat exchanger system with fluid ejector.
Chrysler Gregory M. (Poughkeepsie NY) Vader David T. (New Paltz NY), Electronics package with improved thermal management by thermoacoustic heat pumping.
Butler David A. (Macungie PA) Moore Robert B. (Allentown PA), Method and apparatus for maintenance of slush mixture at desired level during melt conditions.
Arun Acharya ; John H. Royal ; Dante P. Bonaquist ; Bayram Arman ; Christian F. Gottzmann, System for providing cryogenic refrigeration using an upstream pulse tube refrigerator.
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