Method and apparatus for isothermal cooling

12203,686

18/543612

December 18, 2023

A cooling apparatus includes a first fluid flowpath and a second fluid flowpath. The first fluid flowpath includes a subcooler having a first side in fluid communication with the first fluid flowpath; a flow control valve; a primary evaporator assembly including at least one evaporator configured to be disposed in thermal communication with a heat load; and a pressure regulator operable to control a saturation pressure within the at least one evaporator. The second fluid flowpath is in fluid communication with a second side of the subcooler.

Rolls-Royce North American Technologies Inc. (Indianapolis, IN, US)

Rolls-Royce North American Technologies Inc. (Indianapolis, IN, US)

1. A cooling apparatus comprising: a source of cooling fluid; a first fluid flowpath in fluid communication with the source of cooling fluid to receive the cooling fluid from the source of cooling fluid, the first fluid flowpath including: a subcooler having a first side in fluid communication with the first fluid flowpath; and a flow control valve; a primary evaporator assembly downstream of the flow control valve, the primary evaporator assembly including at least one primary evaporator configured to be disposed in thermal communication with a primary heat load; a pressure regulator downstream of the primary evaporator assembly, the pressure regulator operable to maintain a saturation pressure within the primary evaporator at a predetermined set point; a compressor downstream of the pressure regulator to pressurize the cooling fluid; and a cooler downstream of the compressor for removing heat from the cooling fluid; and a second fluid flowpath in fluid communication with the source of cooling fluid and diverging from the first fluid flowpath downstream of the primary evaporator assembly and configured to pass a portion of the cooling fluid through a second side of the subcooler and return the portion of the cooling fluid to the first fluid flowpath downstream of the primary evaporator assembly and upstream of the compressor such that the portion of the cooling fluid passes through and is pressurized by the compressor before the portion of the cooling fluid is returned to the source of cooling fluid, the second fluid flowpath includes a flow restrictor located upstream of an inlet to the second side of the subcooler and the flow restrictor is configured to expand the portion of the cooling fluid flowing to the second side of the subcooler.

2. The cooling apparatus of claim 1 , wherein the source of cooling fluid includes a separator vessel located upstream of an inlet to the first side of the subcooler.

3. The cooling apparatus of claim 2 , further comprising a third fluid flowpath fluidly connecting the separator vessel with the first fluid flowpath at a location downstream of the pressure regulator to extract vapor from the separator vessel.

4. The cooling apparatus of claim 3 , wherein the first fluid flowpath further includes a suction accumulator located downstream of the pressure regulator and the second fluid flowpath diverges from the first fluid flowpath downstream of the suction accumulator.

5. The cooling apparatus of claim 4 , wherein the first fluid flowpath further includes a heat exchanger having a first side located between the primary evaporator and the compressor and a second side located between the cooler and the source of cooling fluid.

6. The cooling apparatus of claim 5 , wherein the first fluid flowpath further comprises one or more secondary evaporators downstream of the primary evaporator assembly and the one or more secondary evaporators is configured to be disposed in thermal communication with a secondary heat load.

7. The cooling apparatus of claim 6 , wherein the primary evaporator assembly and the one or more secondary evaporators are connected in series.

8. A cooling apparatus comprising: a source of cooling fluid; a first fluid flowpath in fluid communication with the source of cooling fluid to receive the cooling fluid from the source of cooling fluid, the first fluid flowpath including: a subcooler having a first side in fluid communication with the first fluid flowpath; and a primary evaporator assembly located downstream of a flow control valve, the primary evaporator assembly including at least one primary evaporator configured to be disposed in thermal communication with a primary heat load; and a second fluid flowpath in fluid communication with the source of cooling fluid and diverging from the first fluid flowpath downstream of the primary evaporator assembly and configured to pass a portion of the cooling fluid through a second side of the subcooler and return the portion of the cooling fluid to the first fluid flowpath downstream of the primary evaporator assembly and upstream of the compressor such that the portion of the cooling fluid passes through and is pressurized by the compressor before the portion of the cooling fluid is returned to the source of cooling fluid.

9. The cooling apparatus of claim 8 , wherein the second fluid flowpath includes a flow restrictor located upstream of an inlet of the second side of the subcooler and the flow restrictor is configured to expand the portion of the cooling fluid flowing to the second side of the subcooler.

10. The cooling apparatus of claim 8 , wherein the source of cooling fluid includes a separator vessel located upstream of the subcooler.

11. The cooling apparatus of claim 10 , further comprising a third fluid flowpath fluidly connecting the separator vessel with the first fluid flowpath at a location downstream of a pressure regulator to extract vapor from the separator vessel.

12. The cooling apparatus of claim 11 , wherein the first fluid flowpath further includes a compressor downstream of the primary evaporator assembly and the third fluid flowpath is fluidly connected with the first fluid flowpath upstream of the compressor.

13. The cooling apparatus of claim 8 , wherein the first fluid flowpath further includes the flow control valve located upstream of the primary evaporator assembly to meter a flow of the cooling fluid and a pressure regulator located downstream of the primary evaporator assembly to maintain a saturation pressure within the primary evaporator at a predetermined set point.

14. The cooling apparatus of claim 13 , wherein the first fluid flowpath further comprises a compressor downstream of the primary evaporator assembly and a cooler downstream of the compressor.

15. The cooling apparatus of claim 14 , wherein the first fluid flowpath further includes a heat exchanger having a first side located between the primary evaporator and the compressor and a second side located between the cooler and the source of cooling fluid.

16. The cooling apparatus of claim 8 , wherein the first fluid flowpath further includes a suction accumulator located downstream of a pressure regulator.

17. The cooling apparatus of claim 16 , wherein the second fluid flowpath diverges from the first fluid flowpath downstream of the suction accumulator.

18. The cooling apparatus of claim 8 , wherein the second fluid flowpath returns the portion of the cooling fluid to the first fluid flowpath upstream of the source of cooling fluid.

19. The cooling apparatus of claim 18 , wherein the first fluid flowpath further comprises one or more secondary evaporators downstream of the primary evaporator assembly and the one or more secondary evaporators is configured to be disposed in thermal communication with a secondary heat load.

20. The cooling apparatus of claim 19 , wherein the primary evaporator assembly and the one or more secondary evaporators are connected in series.

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