RU2000104114A - SUPERCONDUCTOR COOLING METHOD AND DEVICE - Google Patents

Claims (80)

1. A method of cooling a superconductor by means of a refrigerant, comprising the steps of cooling the refrigerant to or below a freezing point determined by a stationary state refrigerant in a cooling system for a superconductor, providing a refrigerant system having a temperature equal to the freezing point in the fluid state, or lower temperature, by means of physical influence exerted on the cooled refrigerant, and cool the superconductor to, or below, the critical temperature of the superconductor in redstvom refrigerant system in a fluid state.  2. The cooling method according to claim 1, which also includes the steps of measuring the viscosity of the refrigerant and modulating the flow rate of the refrigerant system in a fluid state according to the measured viscosity.  3. The cooling method according to any one of claim 1 or 2, in which the viscosity is estimated by the load applied to the stirring motor, which mixes the refrigerant.  4. The cooling method according to any one of claims 1 to 3, in which the physical effect exerted on the refrigerant is to mix the refrigerant.  5. The cooling method according to any one of claims 1 to 3, in which the physical effect exerted on the refrigerant is the movement or circulation of the refrigerant using a pump.  6. The cooling method according to any one of claims 1 to 3, in which the physical effect on the refrigerant is mixing the refrigerant in a container containing refrigerant and / or moving or circulating the refrigerant using a pump, the refrigerant is cooled by a refrigerator or a refrigeration system, and a liquid refrigerant system having a temperature equal to the freezing point or lower temperature is directed by a pump through a piping system from the tank to the assembly in which the superconductor is located.  7. The cooling method according to any one of claims 1 to 3, in which the physical effect exerted on the refrigerant is convection of the refrigerant in the tank.  8. The cooling method according to any one of claims 1 to 7, in which the refrigerant is selected from the group consisting of liquid nitrogen and a mixture of liquid nitrogen and solid nitrogen.  9. The cooling method according to any one of claims 1 to 7, in which the refrigerant is selected from the group consisting of liquid air and a mixture of liquid air and solid air.  10. The cooling method according to any one of claims 1 to 7, in which the refrigerant is selected from the group consisting of a mixture of liquid oxygen and liquid nitrogen, and a mixture of liquid oxygen, liquid nitrogen and at least one hardened substance from among liquid oxygen and liquid nitrogen .  11. The cooling method according to any one of claims 1 to 10, wherein the superconductor is at least one conductor selected from the group consisting of an oxide high temperature superconducting cable, an oxide high temperature superconducting magnet, and an oxide high temperature superconducting device.  12. The cooling method according to claim 11, in which the superconductor is an oxide high temperature superconducting cable, and the step of cooling the refrigerant is carried out in several places in the cooling system for the oxide high temperature superconducting cable.  13. The cooling method according to claim 6, in which the superconductor is part of a device selected from the group consisting of a transformer, a locomotive, a superconducting magnetic energy storage device, an imaging device based on the principle of magnetic resonance, SRI, a logic circuit and a current limiter, and a refrigerant sent from the cooling system regardless of the operating unit of the device to the operating unit through a piping system.  14. The cooling method according to any one of claims 1 to 7, 9, 11-13, which also includes the steps of liquefying the air with a refrigerator, circulating the liquefied air while cooling it, and cooling the superconductor with cooled and circulated liquefied air.  15. The cooling method according to 14, in which the circulation is carried out by moving liquefied air by mechanical means, or by convection of liquefied air in a container.  16. The cooling method according to 14, in which the circulation is a cycle between the evaporation of liquefied air and the condensation of the evaporated air by cooling.  17. The cooling method according to any one of paragraphs.14-16, in which the refrigerator uses a refrigeration cycle in which gas is compressed and expanded, and the air is cooled and condensed by gas circulating in the refrigeration cycle.  18. The cooling method according to 17, in which the gas expandable in the refrigeration cycle cools the circulated liquefied air and cools the air for condensation.  19. The cooling method according to any one of paragraphs.17 or 18, in which the refrigeration cycle is a Brighton cycle.  20. The cooling method according to any one of claims 17-19, wherein the gas used in the refrigeration cycle is helium gas.  21. The cooling method according to any one of paragraphs.14-20, which also includes the step of removing gaseous material from the air, which cures at a temperature above the liquefaction temperature of the air, and in which the air thus obtained is liquefied with a refrigerator.  22. The cooling method according to any one of paragraphs.14-21, which also includes the step of introducing liquefied air as a material to lower the freezing point of liquefied air.  23. The cooling method according to any one of claims 14 to 22, wherein the material for lowering the freezing point is an oil-based organic solvent or zeolite.  24. The cooling method according to any one of paragraphs.14-23, which also includes the step of introducing liquid oxygen into liquefied air, and in which the thus obtained mixture of refrigerant is used to cool the superconductor.  25. The cooling method according to any one of paragraphs.14-18, 20-24, according to which a refrigerator of the accumulating cold type is used to condense air and / or to cool circulated liquefied air.  26. A device for cooling a superconductor by means of a refrigerant, comprising a refrigeration device or a refrigeration system for cooling the refrigerant to or below a freezing point determined by a stationary state refrigerant in the superconductor cooling system, means for providing the flow of the cooled refrigerant, means for measuring the viscosity of the refrigerant, and means for modulating the fluid state of the refrigerant according to the measured viscosity.  27. The cooling device according to claim 26, wherein the means for providing the flow of refrigerant is at least one agent selected from the group consisting of a pump and a mixing machine.  28. The cooling device according to any one of paragraphs.26 or 27, which also contains a refrigerator having a cryogenic unit, providing a temperature that is lower than the temperature of the liquefied air, a storage capacity of liquefied air, in which at least part of the cryogenic node is located, the first piping system for the release of liquefied air in a specified container, a second piping system for directing the released liquefied air into the superconductor and for circulating the liquefied air, and means installed in Ora piping system for liquefied cooling air directed to the superconductor.  29. The cooling device according to claim 28, wherein a valve is installed in the first piping system and a pump for moving liquefied air is installed in the second piping system.  30. The cooling device according to any one of paragraphs 28 or 29, wherein the refrigerator uses a refrigeration cycle in which gas circulates, being compressed and expanded, and a heat exchanger for cooling liquefied air and / or a liquefied air storage tank is installed in the cryogenic unit of the refrigerator, through which passes expandable gas.  31. The cooling device according to claim 30, wherein the cooling cycle is a Brighton cycle.  32. The cooling device according to any one of claims 30 or 31, wherein the gas used for the refrigeration cycle is helium gas.  33. The cooling device according to any one of paragraphs 28-32, in which the system for supplying air to the storage tank of liquefied air is also installed, a cleaning device for removing gaseous material from the air, which cures at a temperature higher than the temperature of the liquefied air.  34. The cooling device according to any one of paragraphs.28-33, in which a heat exchange fin is also installed in the cryogenic assembly of the refrigerator installed in the liquefied air storage tank.  35. The cooling device according to any one of paragraphs. 28-34, in which a heater is also installed in the cryogenic assembly of the refrigerator installed in the liquefied air storage tank, and an ejection device is connected to the liquefied air storage tank.  36. The cooling device according to any one of paragraphs. 28-35, which also contains means for introducing additives into the container to lower the freezing point of liquefied air; and means for mixing liquefied air containing the additive.  37. The cooling device according to any one of paragraphs. 28-36, which also contains means for introducing liquid oxygen into the container.  38. The cooling device according to any one of paragraphs 28-30, 32-37, in which the cooling stage of the refrigerator type accumulating cold is installed in a container for condensing air in the tank, and the cooling stage of the refrigerator type accumulating cold is installed in a second piping system for cooling liquefied air .  39. The cooling device according to p. 26, which also contains a refrigerator having a cryogenic assembly, providing a temperature that is lower than the liquefaction temperature of the air and a container in which at least part of the cryogenic assembly and a cooled superconductor are simultaneously located, the container contains liquefied air for cooling the superconductor and convection of the liquefied air occurs in the vessel between the cryogenic assembly of the superconductor, or the evaporation of the liquefied air and the condensation of the vaporized air occur in the vessel.  40. The cooling device according to claim 39, wherein the refrigerator is a Braithon type refrigerator, Stirling type, GM type, Solway type, or a refrigerator of any combination of these types.  41. The cooling device according to claim 39, wherein the refrigerator uses a refrigeration cycle in which the gas circulates, being compressed and expanded, and a heat exchanger for cooling the liquefied air is installed in a cryogenic unit of the refrigerator through which the expandable gas passes.  42. The cooling device according to any one of paragraphs 39-41, which also contains a cleaning device for removing gaseous material from the air, which cures at a temperature higher than the temperature of the liquefied air.  43. The cooling device according to any one of paragraphs 39-42, in which the heat exchange rib is installed in the cryogenic node of the tank.  44. The cooling device according to any one of claims 39-43, wherein a heater is installed in the cryogenic assembly of the vessel, and the vessel is connected to an ejection device.  45. The cooling device according to any one of paragraphs 39-44, which also contains means for introducing into the container additives to lower the freezing point of liquefied air and means for mixing liquefied air containing the additive.  46. The cooling device according to any one of paragraphs 39-45, which also contains means for introducing liquid oxygen into the tank.  47. A method of cooling a superconductor, comprising the steps of liquefying air, or a mixture of nitrogen and oxygen by a refrigerator, the refrigerator using a refrigeration cycle to perform its cooling function, and the air or mixture is cooled outside the refrigeration cycle using a cooling unit in the refrigeration cycle circulate the liquefied air, while simultaneously cooling it, and cool the superconductor by means of a circulated liquefied material.  48. The cooling method according to claim 47, in which the circulation is determined by the movement of the liquefied material by mechanical means, or by convection of the liquefied material in the tank.  49. The cooling method according to clause 47, in which the circulation is a cycle between the evaporation of a liquefied material and the condensation of the evaporated material by cooling it.  50. The cooling method according to any one of claims 47-49, wherein the refrigerator uses a cooling cycle in which gas is compressed and expanded, and air, or a mixture of nitrogen and oxygen, is cooled and condensed by the gas circulating in the refrigeration cycle using a cooling unit.  51. The cooling method according to claim 50, wherein the gas expandable in the refrigeration cycle cools the circulating liquefied material and cools the material, or a mixture of nitrogen and oxygen for condensation.  52. The cooling method according to any one of claims 50 or 51, wherein the refrigeration cycle is a Brighton cycle.  53. The cooling method according to any one of claims 50 to 52, wherein the gas used in the refrigeration cycle is helium gas.  54. The cooling method according to any one of claims 47-53, which also includes the step of removing from the air, or from a mixture of nitrogen and oxygen, a gaseous material that cures at a temperature higher than the liquefaction temperature of the air, or said mixture, and according to which thus obtained air, or a mixture of nitrogen and oxygen, is liquefied with a refrigerator.  55. The cooling method according to any one of claims 47-54, which also includes the step of introducing some material into the liquefied material to lower the freezing point of the liquefied air.  56. The cooling method according to claim 55, wherein the material for lowering the freezing point is an oil-based organic solvent or zeolite.  57. The cooling method according to any one of claims 47-56, which also includes the step of modulating the composition of the liquefied material.  58. The cooling method according to any one of claims 47-57, which also includes the step of introducing liquid oxygen into the liquefied material, and according to which the resulting refrigerant mixture is used to cool the superconductor.  59. The cooling method according to any one of claims 47-51, 53-58, wherein the cooling head of the refrigerator of the cold storage type is used to condense air, or a mixture of nitrogen and oxygen, and / or to cool the circulated liquefied material.  60. A cooling device for a superconductor, comprising a refrigerator using a refrigeration cycle to perform its cooling function, and having, in the refrigeration cycle, a cryogenic assembly that provides a temperature lower than the temperature of liquefying air, or a mixture of nitrogen and oxygen, in which contains at least a portion of the cryogenic assembly, a first piping system for discharging liquefied air, or a mixture of nitrogen and oxygen from said container, a second piping system for guiding exhaust liquid material to the superconductor and for circulating the liquefied material, and the means installed in the second piping system for cooling the liquefied material directed to the superconductor, the air, or a mixture of nitrogen and oxygen in the vessel, is cooled to liquefaction outside the refrigeration cycle using a cryogenic unit, and the superconductor is cooled liquefied air, or a mixture of nitrogen and oxygen.  61. The cooling device according to claim 60, wherein a valve is installed in the first piping system and a pump is installed in the second piping system to transport liquefied air, or a mixture of nitrogen and oxygen.  62. The cooling device according to any one of claims 60 and 61, wherein the refrigerator uses a refrigeration cycle in which gas circulates, being compressed and expanded, and a heat exchanger for cooling liquefied air, or a mixture of nitrogen and oxygen, and / or the tank is installed in a cryogenic the refrigerator assembly through which the expandable gas passes.  63. The cooling device according to claim 62, wherein the refrigeration cycle is a Brayton cycle.  64. A cooling device according to any one of claims 62 or 63, wherein the gas used in the refrigeration cycle is helium gas.  65. The cooling device according to any one of paragraphs 60-64, in which in the system for supplying air, or a mixture to the tank, a cleaning device is also disposed to remove from the air, or from a mixture of nitrogen and oxygen, a gaseous material that cures at a temperature, higher than the liquefaction temperature of the air, or mixture.  66. The cooling device according to any one of paragraphs 60-65, in which a heat exchange fin is also installed in the cryogenic unit of the refrigerator located in the tank.  67. The cooling device according to any one of paragraphs 60-66, in which a heater is also installed in the cryogenic unit of the refrigerator located in the tank, and the discharge device is connected to the tank.  68. The cooling device according to any one of paragraphs 60-67, which also contains means for introducing into the container additives to lower the freezing point of liquefied air, or a mixture of nitrogen and oxygen, and means for mixing liquefied air, or a mixture of nitrogen and oxygen containing the additive .  69. The cooling device according to any one of paragraphs 60-68, which also contains means for modulating the composition of the liquefied material.  70. The cooling device according to any one of paragraphs 60-69, which also contains means for introducing liquid oxygen into the tank.  71. The cooling device according to any one of paragraphs 60-62, 64-70, in which the cooling stage of the refrigerator type accumulating cold is installed in the specified tank for condensing air, or mixture, in the tank; and the cooling stage of the refrigerator of the cold storage type is installed in the second piping system for cooling the liquefied air, or mixture.  72. A device for cooling a superconductor containing a refrigerator using a refrigeration cycle to perform its cooling function, and having a cryogenic assembly providing a temperature lower than the temperature of liquefying air, or a mixture of nitrogen and oxygen, and a container that simultaneously contains at least part of the cryogenic assembly and a cooled superconductor, the container contains liquefied air, or a mixture of nitrogen and oxygen, for cooling the superconductor, and convection of the liquefied air, or mixture, occurs in the container between the cryogenic assembly and the superconductor, or the evaporation of liquefied air and the condensation of the vaporized air through the cryogenic assembly occur in the vessel.  73. The cooling device according to claim 72, wherein the refrigerator is a Braithon type refrigerator, Sterling type, GM type, Solway type, or any combination of these types of refrigerators.  74. The cooling device of claim 70, wherein the refrigerator uses a refrigeration cycle in which gas circulates, being compressed and expanded, and a heat exchanger for cooling liquefied air, or a mixture, is installed in the cryogenic assembly of the refrigerator through which the expandable gas passes.  75. The cooling device according to any one of paragraphs 72-74, which also includes a cleaning device for removing from the air, or a mixture of nitrogen and oxygen, a gaseous material that cures at a temperature above the liquefaction temperature of the air, or mixture.  76. The cooling device according to any one of paragraphs 72-75, in which a heat exchange rib is installed in the cryogenic unit of the tank.  77. The cooling device according to any one of claims 72-76, wherein a heater is installed in the cryogenic assembly of the vessel, and the discharge device is connected to the vessel.  78. The cooling device according to any one of paragraphs 72-77, which also contains means of introducing into the container additives to lower the freezing point of liquefied air, or a mixture of nitrogen and oxygen, and a means of mixing liquefied air, or a mixture of nitrogen and oxygen containing the additive.  79. The cooling device according to any one of paragraphs 72-78, which also contains means for modulating the composition of liquefied air, or a mixture of nitrogen and oxygen.  80. The cooling device according to any one of paragraphs 72-79, which also contains means for introducing liquid oxygen into the tank.