Passive flow direction biasing of cryogenic thermosiphon

The invention claimed is: 1. A cooling device comprising: a heat exchanger; a first flow loop connecting a cold sink and the heat exchanger; a second flow loop connecting a hot sink and the heat exchanger; a first passive one-way valve disposed on the first flow loop and oriented to allow flow in an allowed direction of flow (F 1 ) in the first flow loop and to block flow in an opposite blocked direction of flow in the first flow loop; and a second passive one-way valve disposed on the second flow loop and oriented to allow flow in an allowed direction of flow (F 2 ) in the second flow loop and to block flow in an opposite blocked direction of flow in the second flow loop; wherein the combination of flow in the allowed direction of flow in the first flow loop and flow in the allowed direction of flow in the second flow loop produces counter-flow in the heat exchanger. 2. The cooling device of claim 1 wherein the first passive one-way valve comprises a first Tesla valve and the second passive one-way valve comprises a second Tesla valve. 3. The cooling device of claim 2 wherein the first Tesla valve and the second Tesla valve each comprises: a first stainless steel block having a milled Tesla valve conduit pattern; a second stainless steel block having a milled Tesla valve conduit pattern; the first and second stainless steel blocks hermetically sealed together with the Tesla valve conduit patterns of the first and second stainless steel blocks defining a Tesla valve conduit ( 80 ) passing though the hermetically sealed first and second stainless steel blocks. 4. The cooling device of claim 3 wherein the first and second stainless steel blocks of each Tesla valve are hermetically sealed together by a brazed joint. 5. The cooling device of claim 1 further comprising: helium fluid disposed in the first flow loop; and helium gas disposed in the second flow loop. 6. The cooling device of claim 1 wherein no mechanical pump is connected to drive flow in the second flow loop. 7. The cooling device of claim 1 further comprising: a superconducting magnet winding, the hot sink comprising the superconducting magnet winding; and a cryogenic cold head, the cold sink comprising the cryogenic cold head. 8. The cooling device of claim 7 further comprising: a vapor-liquid phase separator, the cold sink further comprising the vapor-liquid phase separator. 9. A magnetic resonance imaging (MRI) device comprising: a magnet comprising one or more superconducting magnet windings; a cryogenic cold head; and the cooling device of claim 1 wherein the hot sink of the cooling device comprises the one or more superconducting magnet windings and the cold sink of the cooling device comprises the cryogenic cold head and a liquid helium tank. 10. A cooling method comprising: flowing first coolant fluid through a first flow loop that connect a cold sink and a heat exchanger; flowing second coolant fluid through a second flow loop that connects a hot sink and the heat exchanger; and constraining the flowing of the first coolant fluid and the flowing of the second coolant fluid to produce counter-flow in the heat exchanger by: using a first passive one-way valve to allow the flowing of the first coolant fluid in the first flow loop in an allowed direction (F 1 ) while blocking flow in an opposite blocked direction, and using a second passive one-way valve to allow the flowing of the second coolant fluid in the second flow loop in an allowed direction (F 2 ) while blocking flow in an opposite blocked direction. 11. The cooling method of claim 10 wherein the first passive one-way valve comprises a first Tesla valve and the second passive one-way valve comprises a second Tesla valve. 12. The cooling method of claim 11 further comprising constructing each of the first Tesla valve and the second Tesla valve by: milling a Tesla valve conduit pattern in a first stainless steel block; milling a Tesla valve conduit pattern in a second stainless steel block; and hermetically sealing the first and second stainless steel blocks together with the Tesla valve conduit patterns of the first and second stainless steel blocks arranged to define a Tesla valve conduit passing though the hermetically sealed first and second stainless steel blocks. 13. The cooling method of claim 12 wherein the hermetically sealing comprises brazing the first and second stainless steel blocks together. 14. The cooling method of claim 10 wherein the first coolant fluid is helium fluid and the second coolant fluid is helium gas. 15. The cooling method of claim 14 further comprising: collecting a liquid helium phase of the helium fluid flowing through the first flow loop in a helium tank connected with the first flow loop. 16. A cryogenic magnet comprising: a heat exchanger; a cryogenic cold head; one or more superconducting magnet windings; a first flow loop connecting the cryogenic cold head and the heat exchanger; a second flow loop connecting the one or more superconducting magnet windings and the heat exchanger; a first passive one-way valve disposed on the first flow loop and oriented to allow flow in an allowed direction of flow (F 1 ) in the first flow loop and to block flow in an opposite blocked direction of flow in the first flow loop; and a second passive one-way valve disposed on the second flow loop and oriented to allow flow in an allowed direction of flow (F 2 ) in the second flow loop and to block flow in an opposite blocked direction of flow in the second flow loop; wherein the combination of flow in the allowed direction of flow in the first flow loop and flow in the allowed direction of flow in the second flow loop produces counter-flow in the heat exchanger. 17. The cryogenic magnet of claim 16 wherein the first passive one-way valve comprises a first Tesla valve and the second passive one-way valve comprises a second Tesla valve. 18. The cryogenic magnet of claim 16 further comprising: helium fluid disposed in the first flow loop and flowing in the allowed direction of flow (F 1 ) in the first flow loop; and helium gas disposed in the second flow loop and flowing in the allowed direction of flow (F 2 ) in the second flow loop. 19. The cryogenic magnet of claim 18 wherein the helium fluid disposed in the first flow loop is one of helium gas, liquid helium, and a two-phase mixture of helium gas and liquid helium. 20. The cryogenic magnet of claim 16 further comprising: a vapor-liquid separator connected with the first flow loop. 21. A magnetic resonance imaging (MRI) device comprising: a cryogenic magnet as set forth in claim 16 arranged to generate a static magnetic field in an examination region; and magnetic field gradient coils arranged to superimpose magnetic field gradients on the static magnetic field in the examination region.