SYSTEM AND METHOD FOR PROVIDING AIR-COOLING, AND RELATED POWER GENERATION SYSTEMS
First Claim
1. A cooling system for providing chilled air, comprising(a) a cooling coil configured to accept air at a higher temperature and emit air at a lower temperature by passage through a flow of coolant water in the coil, resulting in a content of relatively warm water;
- (b) an evaporator contained within a vacuum chamber, and in communication with the cooling coil;
said evaporator configured to allow the passage of the relatively warm water therethrough, and to absorb heat from the warm water, thereby reducing the temperature of the water, while also forming a content of water vapor;
(c) an absorber contained in the vacuum chamber, and configured to accept the water vapor formed in the evaporator;
while also configured to accommodate the flow of a concentrated desiccant that is capable of absorbing the water vapor and thereby becoming diluted and heated;
(d) an external heat source in contact with at least a portion of the desiccant, so as to further heat the desiccant;
(e) a regenerator that is capable of receiving at least a portion of the further-heated desiccant, said regenerator configured to accept and direct external air to the desiccant, thereby causing a release of at least some of the water content in the desiccant, to the atmosphere, so as to re-concentrate the desiccant to a selected concentration value;
(f) at least one heat exchanger that is capable of accepting the re-concentrated desiccant and lowering the temperature of the desiccant to a temperature that allows the desiccant to absorb water vapor formed in the evaporator, said heat exchanger being in communication with the absorber, to allow the return of the lower-temperature desiccant to the absorber; and
(g) a source of make-up water in communication with the cooling coil, configured to replenish water lost during operation of the cooling system.
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Accused Products
Abstract
A cooling system for providing chilled air is disclosed, including a cooling coil; an evaporator and absorber contained within a vacuum chamber; and a desiccant that absorbs water vapor from the cooling process. The system also includes an external heat source for treating the desiccant; along with a regenerator to make the desiccant re-useable. At least one heat exchanger is also included, along with a source of make-up water in communication with the cooling coil. Related processes are also disclosed, along with a gas turbine engine that includes or is arranged in association with the cooling system.
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Citations
15 Claims
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1. A cooling system for providing chilled air, comprising
(a) a cooling coil configured to accept air at a higher temperature and emit air at a lower temperature by passage through a flow of coolant water in the coil, resulting in a content of relatively warm water; -
(b) an evaporator contained within a vacuum chamber, and in communication with the cooling coil;
said evaporator configured to allow the passage of the relatively warm water therethrough, and to absorb heat from the warm water, thereby reducing the temperature of the water, while also forming a content of water vapor;(c) an absorber contained in the vacuum chamber, and configured to accept the water vapor formed in the evaporator;
while also configured to accommodate the flow of a concentrated desiccant that is capable of absorbing the water vapor and thereby becoming diluted and heated;(d) an external heat source in contact with at least a portion of the desiccant, so as to further heat the desiccant; (e) a regenerator that is capable of receiving at least a portion of the further-heated desiccant, said regenerator configured to accept and direct external air to the desiccant, thereby causing a release of at least some of the water content in the desiccant, to the atmosphere, so as to re-concentrate the desiccant to a selected concentration value; (f) at least one heat exchanger that is capable of accepting the re-concentrated desiccant and lowering the temperature of the desiccant to a temperature that allows the desiccant to absorb water vapor formed in the evaporator, said heat exchanger being in communication with the absorber, to allow the return of the lower-temperature desiccant to the absorber; and (g) a source of make-up water in communication with the cooling coil, configured to replenish water lost during operation of the cooling system. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13)
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14. A gas turbine engine, comprising:
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I) a compressor; II) a combustor; III) a turbine, coupled in flow communication with the compressor; and IV) a cooling system coupled in flow communication with an inlet region of the compressor;
so as to provide cooling air to the inlet region;
wherein the cooling system comprises;(a) a cooling coil configured to accept air at a higher temperature and emit air at a lower temperature by passage through a flow of coolant water in the coil, resulting in a content of relatively warm water; (b) an evaporator contained within a vacuum chamber, and in communication with the cooling coil;
said evaporator configured to allow the passage of the relatively warm water therethrough, and to absorb heat from the warm water, thereby reducing the temperature of the water, while also forming a content of water vapor;(c) an absorber contained in the vacuum chamber, and configured to accept the water vapor formed in the evaporator;
while also configured to accommodate the flow of a concentrated desiccant that is capable of absorbing the water vapor and thereby becoming diluted and heated;(d) an external heat source in contact with at least a portion of the desiccant, so as to further heat the desiccant; (e) a regenerator that is capable of receiving at least a portion of the further-heated desiccant, said regenerator configured to accept and direct external air to the desiccant, thereby causing a release of at least some of the water content in the desiccant, so as to re-concentrate the desiccant to a selected concentration value; (f) at least one heat exchanger that is capable of accepting the re-concentrated desiccant and lowering the temperature of the desiccant to a temperature that allows the desiccant to absorb water vapor formed in the evaporator, said heat exchanger being in communication with the absorber, to allow the return of the lower-temperature desiccant to the absorber.
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15. A method for providing chilled air to a gas turbine engine that includes a compressor;
- a combustor; and
a turbine coupled in flow communication with the compressor, comprising the steps of;(i) flowing relatively warm air through coolant water in a cooling coil, and then into an inlet in the compressor, wherein the cooling coil transforms the relatively warm air into chilled air; and
wherein the interaction of the warm air with the coolant water transforms the water into relatively warm water;(ii) directing the relatively warm water through an evaporator contained within a vacuum chamber, and in communication with the cooling coil;
wherein the evaporator is configured to allow the passage of the relatively warm water therethrough, and to absorb heat from the warm water, thereby reducing the temperature of the water so that it can be directed back to the cooling coil;
while also forming a content of water vapor;(iii) directing the water vapor from the evaporator to an absorber;
while also directing a concentrated desiccant to the absorber, so that the desiccant absorbs the water vapor and becomes diluted with a content of water.(iv) contacting the heated, diluted desiccant with an external heat source, so as to further increase the temperature of the desiccant; (v) directing at least a portion of the further-heated desiccant to a regenerator and exposing the desiccant to external air directed into the regenerator, so as to cause a release of at least some of the water content in the desiccant, thereby re-concentrating the desiccant to a selected concentration value; and (vi) directing the re-concentrated desiccant to the absorber.
- a combustor; and
Specification