Flowrate controller for hybrid capillary/mechanical two-phase thermal loops
First Claim
1. A closed-loop heat transfer system adapted to transfer heat from a heat source to a heat sink by means of a working fluid having a liquid phase and a vapor phase, said heat transfer system comprising:
- at least one evaporator having a plurality of capillaries adapted to accept heat from said heat source and to receive a flow of said liquid phase working fluid, with heat from said heat source causing at least a portion of said working fluid flowing through said capillaries to convert to said vapor phase;
a condenser adapted to receive said working fluid from said evaporator, and to reject heat from said working fluid to said heat sink and thereby convert said vapor phase working fluid to its liquid phase;
a sensor having;
(a) a conductive tube with an inside diameter substantially greater than the inside diameters of said evaporator capillaries, connected in parallel with said evaporator;
(b) a conductive wire extending within said tube insulated from electrical contact with said tube; and
(c) capacitance measuring means adapted to measure the electrical capacitance between said tube and said wire and thereby indicate the amount of liquid phase working fluid within said tube; and
a pump adapted to receive and pump liquid phase working fluid from said condenser to said evaporator, the output of said pump being regulated as a function of the capacitance measured by said capacitance measuring means to maintain a substantially constant amount of liquid phase working fluid within said sensor.
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Accused Products
Abstract
A hybrid capillary/mechanical two-phase thermal loop has a sensor connected in parallel with a number of evaporators to regulate the flowrate of a booster pump providing working fluid to the evaporator capillaries. This sensor is made of a coiled, conductive tube connected in parallel with the evaporators, with an inside diameter substantially greater than the inside diameters of the evaporator capillaries. A conductive wire extends within said tube, but is insulated from electrical contact with the tube. The working fluid contained within the tube acts as a dielectric between the tube and wire. The amount of liquid phase working fluid within the tube can be determined by measuring the electrical capacitance between the tube and wire. The flowrate of the booster pump is then regulated as a function of the measured capacitance to maintain a substantially constant amount of liquid phase working fluid within the sensor tube. The sensor thereby effectively regulates the flowrate of working fluid from the pump to match the aggregate demand of the evaporators.
110 Citations
32 Claims
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1. A closed-loop heat transfer system adapted to transfer heat from a heat source to a heat sink by means of a working fluid having a liquid phase and a vapor phase, said heat transfer system comprising:
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at least one evaporator having a plurality of capillaries adapted to accept heat from said heat source and to receive a flow of said liquid phase working fluid, with heat from said heat source causing at least a portion of said working fluid flowing through said capillaries to convert to said vapor phase; a condenser adapted to receive said working fluid from said evaporator, and to reject heat from said working fluid to said heat sink and thereby convert said vapor phase working fluid to its liquid phase; a sensor having; (a) a conductive tube with an inside diameter substantially greater than the inside diameters of said evaporator capillaries, connected in parallel with said evaporator; (b) a conductive wire extending within said tube insulated from electrical contact with said tube; and (c) capacitance measuring means adapted to measure the electrical capacitance between said tube and said wire and thereby indicate the amount of liquid phase working fluid within said tube; and a pump adapted to receive and pump liquid phase working fluid from said condenser to said evaporator, the output of said pump being regulated as a function of the capacitance measured by said capacitance measuring means to maintain a substantially constant amount of liquid phase working fluid within said sensor. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14)
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15. A closed-loop heat transfer system adapted to transfer heat from a number of heat sources to a heat sink by means of a working fluid having a liquid phase and a vapor phase, said heat transfer system comprising:
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a plurality of evaporators connected in parallel, each evaporator having a plurality of capillaries adapted to accept heat from a heat source and to receive a flow of said liquid phase working fluid, with heat from at least one of said heat sources causing at least a portion of said working fluid flowing through said capillaries to convert to said vapor phase; a condenser adapted to receive said working fluid from said evaporators, and to reject heat from said working fluid to said heat sink and thereby convert said vapor phase working fluid to its liquid phase; a pump adapted to receive and pump liquid phase working fluid from said condenser to said evaporators; a sensor having; (a) a conductive tube with an inside diameter substantially greater than the inside diameters of said evaporator capillaries, connected in parallel with said evaporators; (b) a conductive wire extending within said tube insulated from electrical contact with said tube; and (c) capacitance measuring means adapted to measure the electrical capacitance between said tube and said wire and thereby indicate the amount of liquid phase working fluid within said sensor tube; and control means adapted to regulate the output of said pump as a function of the electrical capacitance measured by said capacitance measuring means, to thereby maintain a substantially constant amount of liquid phase working fluid within said sensor. - View Dependent Claims (16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26)
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27. A closed-loop heat transfer system adapted to transfer heat from a number of heat sources to a heat sink by means of a working fluid having a liquid phase and a vapor phase, said heat transfer system comprising:
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a plurality of evaporators, each evaporator having an inlet and an outlet connected in parallel with the remaining evaporators, and containing a capillary structure adapted to act as a wick for liquid phase working fluid entering through said evaporator inlet, with heat from at least one of said heat sources causing at least a portion of said liquid phase working fluid to convert to said vapor phase and exit through said evaporator outlet; a temperature sensor means adapted to monitor the temperature of said evaporators; a condenser adapted to receive said working fluid from said evaporator outlets, and to reject heat from said working fluid to said heat sink and thereby return a substantial portion of said vapor phase working fluid to its liquid phase; a reservoir adapted to receive and store a quantity of liquid phase working fluid returned from said condenser; a pump adapted to receive and pump liquid phase working fluid from said condenser and said reservoir to said evaporator inlets; a liquid sensor having; (a) a coiled, conductive tube with an inside diameter substantially greater than the inside diameters of said evaporator capillaries, connected in parallel with said evaporators; (b) a conductive wire extending within said tube insulated from electrical contact with said tube, such that working fluid acts as a dielectric material between said tube and said wire; and (c) capacitance measuring means adapted to measure the electrical capacitance between said tube and said wire and thereby indicate the amount of liquid phase working fluid within said tube; and control means having; (a) a normal mode of operation in which said control means regulates the output of said pump as a function of the electrical capacitance measured by said capacitance measuring means, to thereby maintain a substantially constant amount of liquid phase working fluid within said liquid sensor tube; and (b) a repriming mode of operation triggered when the temperature for any evaporator measured by said temperature sensor exceeds a predetermined limit, in which said control means causes said pump to substantially increase the flowrate of working fluid to flood said evaporators. - View Dependent Claims (28, 29, 30, 31, 32)
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Specification