CRYOGENIC FLUID CIRCUIT DESIGN FOR EFFECTIVE COOLING OF AN ELONGATED THERMALLY CONDUCTIVE STRUCTURE EXTENDING FROM A COMPONENT TO BE COOLED TO A CRYOGENIC TEMPERATURE

US 20170038123A1
Filed: 04/16/2015
Published: 02/09/2017
Est. Priority Date: 04/17/2014
Status: Abandoned Application

First Claim

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1. A cryogenic system comprising:

a housing of a cryogenic chamber for containing a component to be cooled having an elongated thermally conductive structure extending from the component to be cooled to a warmer environment;

a cold source in the cryogenic chamber; and

a circulation loop for circulating cryogenic fluid between the cold source and the component in the cryogenic chamber, wherein the circulation loop includes a flow path conduit for directing an incoming stream of the cryogenic fluid along a length of the elongated thermally conductive structure extending from the component, a first outgoing stream conduit branching from the flow path conduit at a first location along the length of the flow path conduit for conducting a first outgoing stream of the cryogenic fluid to return to the cold source, and a second outgoing stream conduit extending from the flow path conduit at a second location for conducting a second outgoing stream of the cryogenic fluid to return to the cold source, and at least one adjustable valve coupled to at least one of the first outgoing stream conduit and the second outgoing stream conduit for adjusting a fraction of the incoming stream of the cryogenic fluid that becomes the second outgoing stream of cryogenic fluid.

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Abstract

A cryogenic system includes a housing of a cryogenic chamber, a cold source in the cryogenic chamber, and a circulation loop for circulating cryogenic fluid between the cold source and a component to be cooled in the cryogenic chamber. The component has an elongated thermally conductive structure extending to a warmer environment. For adjustable cooling of the structure, an incoming stream of the cryogenic fluid is directed along a length of the structure extending from the component, and this stream is split into a first outgoing stream at a first location from the component and a second outgoing stream at a second location further from the component, and an adjustable valve adjusts the fraction of the incoming stream that becomes the second outgoing stream.

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20 Claims

1. A cryogenic system comprising:
- a housing of a cryogenic chamber for containing a component to be cooled having an elongated thermally conductive structure extending from the component to be cooled to a warmer environment;
  
  a cold source in the cryogenic chamber; and
  
  a circulation loop for circulating cryogenic fluid between the cold source and the component in the cryogenic chamber, wherein the circulation loop includes a flow path conduit for directing an incoming stream of the cryogenic fluid along a length of the elongated thermally conductive structure extending from the component, a first outgoing stream conduit branching from the flow path conduit at a first location along the length of the flow path conduit for conducting a first outgoing stream of the cryogenic fluid to return to the cold source, and a second outgoing stream conduit extending from the flow path conduit at a second location for conducting a second outgoing stream of the cryogenic fluid to return to the cold source, and at least one adjustable valve coupled to at least one of the first outgoing stream conduit and the second outgoing stream conduit for adjusting a fraction of the incoming stream of the cryogenic fluid that becomes the second outgoing stream of cryogenic fluid.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12)
- - 2. The cryogenic system as claimed in claim 1, wherein said at least one adjustable valve includes a three-port adjustable valve having a first port connected to the first outgoing stream conduit for receiving the first outgoing stream of the cryogenic fluid, a second port connected to the second outgoing stream conduit for receiving the second outgoing stream of the cryogenic fluid, and a third port for expelling a combined stream of the cryogenic fluid.
  - 3. The cryogenic system as claimed in claim 2, wherein the circulation loop includes a cryogenic pump in the cryogenic chamber, and the cryogenic system further includes a conduit connecting the third port of the adjustable valve to an inlet of the cryogenic pump for conveying the combined stream of cryogenic fluid to the inlet of the cryogenic pump.
  - 4. The cryogenic system as claimed in claim 1, wherein said at least one adjustable valve includes a two-port adjustable valve in one of the first outgoing stream conduit and the second outgoing stream conduit for providing an adjustable restriction to the flow of cryogenic fluid through said one of the first outgoing stream conduit and the second outgoing stream conduit.
  - 5. The cryogenic system as claimed in claim 4, wherein the two-port adjustable valve is a needle valve.
  - 6. The cryogenic system as claimed in claim 1, wherein said at least one adjustable valve includes a first two-port adjustable valve in the first outgoing stream conduit for providing an adjustable restriction to the flow of the first outgoing stream of the cryogenic fluid and a second two-port adjustable valve in the second outgoing stream conduit for providing an adjustable restriction to the flow of the second outgoing stream of the cryogenic fluid.
  - 7. The cryogenic system as claimed in claim 6, wherein the two-port adjustable valves are needle valves.
  - 8. The cryogenic system as claimed in claim 1, wherein the circulation loop includes a gas pump outside of the housing, and a counter-flow heat exchanger coupled between the first outgoing stream conduit and the gas pump for directing an out-flow of the cryogenic fluid through the counter-flow heat exchanger from the first outgoing stream conduit to an inlet of the gas pump, and the counter-flow heat exchanger is also coupled between the gas pump and the cold source for directing an out-flow of the cryogenic fluid from an outlet of the gas pump to the cold source, and the second outgoing stream conduit is coupled to the inlet of the gas pump to direct the second outgoing stream of the cryogenic fluid to the inlet of the gas pump.
  - 9. The cryogenic system as claimed in claim 8, wherein the second outgoing stream conduit terminates at a tap on the counter-flow heat exchanger.
  - 10. The cryogenic system as claimed in claim 1, further including a temperature sensor for sensing temperature of the elongated thermally conductive structure.
  - 11. The cryogenic system as claimed in claim 10, further including a valve actuator mechanically coupled to the adjustable valve for automatic adjustment of the adjustable valve, and a temperature controller electronically coupled to the temperature sensor and electronically coupled to the valve actuator for automatic control of the adjustable valve to maintain the sensed temperature at a temperature set-point.
  - 12. The cryogenic system as claimed in claim 10, wherein the temperature sensor is located in the cryogenic chamber at a location along the length of the elongated thermally conductive structure between the second location and a location further along the elongated thermally conductive structure from the component.

13. A method of cooling an elongated thermally conductive structure in a cryogenic system, the cryogenic system including a housing of a cryogenic chamber containing a component from which the elongated thermally conductive structure extends to a warmer environment, a cold source in the cryogenic chamber, and a circulation loop circulating cryogenic fluid between the cold source and the component in the cryogenic chamber, said method comprising:
- directing an incoming stream of the cryogenic fluid from the cold source along a length of the elongated thermally conductive structure extending from the component; and
  
  splitting the steam of the cryogenic fluid along the length of the elongated thermally conducive structure into a first outgoing stream of the cryogenic fluid branching away from the length of the elongated thermally conductive structure at a first location along the length of the elongated thermally conductive structure, and a second outgoing stream of the cryogenic fluid departing from the length of the elongated thermally conductive structure at a second location further along the length of the elongated thermally conductive structure than the first location; and
  
  adjusting an adjustable valve to adjust a fraction of the incoming stream of the cryogenic fluid that becomes the second outgoing stream of cryogenic fluid.
- View Dependent Claims (14, 15, 16, 17, 18, 19, 20)
- - 14. The method as claimed in claim 13, which further includes sensing temperature of the elongated thermally conductive structure, and adjusting the adjustable valve to maintain the sensed temperature at a temperature set-point.
  - 15. The method as claimed in claim 14, wherein the sensed temperature is responsive to temperature of the elongated thermally conductive structure at the second location.
  - 16. The method as claimed in claim 14, wherein the sensed temperature is temperature of a temperature sensor disposed along the elongated thermally conductive structure at a location between the second location and a location further along the elongated thermally conductive structure from the component.
  - 17. The method as claimed in claim 14, wherein the adjustable valve is disposed in the cryogenic chamber and the cryogenic system includes a control knob outside of the cryogenic chamber and a control shaft mechanically connecting the control knob to the adjustable valve, and the control knob is adjusted manually to adjust the adjustable valve.
  - 18. The method as claimed in claim 17, wherein the cryogenic system includes a temperature sensor sensing temperature of the elongated thermally conductive structure, and a display for displaying temperature sensed by the temperature sensor, and the method includes adjusting the control knob manually in response to observing the display of the temperature sensed by the temperature sensor.
  - 19. The method as claimed in claims 14, wherein the cryogenic system further includes a valve actuator mechanically coupled to the adjustable valve for automatic adjustment of the adjustable valve, and a temperature controller electronically coupled to the temperature sensor and electronically coupled to the valve actuator for automatic control of the adjustable valve, and the method includes operating the temperature controller to maintain the sensed temperature at a temperature set-point.
  - 20. The method as claimed in claim 13, wherein the elongated thermally conductive structure includes a current lead carrying electrical current between the component and the environment outside the housing, and the current lead includes a segment of superconductor extending from the component and contained within the housing, and the superconductor has a transition temperature below which the superconductor becomes superconducting, and the method includes adjusting the adjustable valve to maintain a highest temperature of the segment of superconductor just below the transition temperature.

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Current Assignee
Victoria Link Limited (Victoria University)
Original Assignee
Victoria Link Limited (Victoria University)
Inventors
Strickland, Nicholas, Wimbush, Stuart

Application Number

US15/304,154
Publication Number

US 20170038123A1
Time in Patent Office

Days
Field of Search
US Class Current

1/1
CPC Class Codes

F25B 9/00   Compression machines, plant...

F25B 9/10   with several cooling stages

F25D 19/00   Arrangement or mounting of ...

F25D 29/001   for cryogenic fluid systems

H01F 6/04   Cooling

CRYOGENIC FLUID CIRCUIT DESIGN FOR EFFECTIVE COOLING OF AN ELONGATED THERMALLY CONDUCTIVE STRUCTURE EXTENDING FROM A COMPONENT TO BE COOLED TO A CRYOGENIC TEMPERATURE

First Claim

1 Assignment

0 Petitions

Accused Products

Abstract

31 Citations

20 Claims

Specification

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CRYOGENIC FLUID CIRCUIT DESIGN FOR EFFECTIVE COOLING OF AN ELONGATED THERMALLY CONDUCTIVE STRUCTURE EXTENDING FROM A COMPONENT TO BE COOLED TO A CRYOGENIC TEMPERATURE

First Claim

1 Assignment

Subscription Required

Subscription Required

0 Petitions

Subscription Required

Accused Products

Subscription Required

Abstract

31 Citations

20 Claims

Specification

Subscription Required

Use Cases

Quick Links

Others