Methods and systems for desiccant air conditioning
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F25D-023/00
F24F-003/14
H01L-031/052
B01D-053/26
H02S-020/00
H01L-031/042
H02S-040/44
F24F-013/02
F28D-021/00
F28F-003/10
F28F-019/00
H02S-010/30
출원번호
US-0869504
(2015-09-29)
등록번호
US-9631823
(2017-04-25)
발명자
/ 주소
Vandermeulen, Peter F.
Hanoka, Jack I.
출원인 / 주소
7AC Technologies, Inc.
대리인 / 주소
Foley Hoag LLP
인용정보
피인용 횟수 :
0인용 특허 :
119
초록▼
A desiccant air conditioning system for treating an air stream entering a building space includes a conditioner having structures arranged in a substantially vertical orientation with an air stream gap between adjacent structures. An air stream flows through the air stream gaps and is exposed to the
A desiccant air conditioning system for treating an air stream entering a building space includes a conditioner having structures arranged in a substantially vertical orientation with an air stream gap between adjacent structures. An air stream flows through the air stream gaps and is exposed to the liquid desiccant and dehumidified when in some of the flow paths and exposed to water and humidified when in other flow paths. Each structure further includes a separate collector at a lower end of the at least one surface of that structure for collecting the liquid desiccant or water that has flowed across the at least one surface of the structure. The system also includes a diverter for diverting a portion of the air stream that has been dehumidified to a flow path where it is exposed to water where it absorbs a portion of the water and is thereby cooled.
대표청구항▼
1. A desiccant air conditioning system for treating an air stream entering a building space, comprising: (a) a conditioner including: (i) a plurality of structures arranged in a substantially vertical orientation, said structures being spaced apart from each other with an air stream gap between each
1. A desiccant air conditioning system for treating an air stream entering a building space, comprising: (a) a conditioner including: (i) a plurality of structures arranged in a substantially vertical orientation, said structures being spaced apart from each other with an air stream gap between each pair of adjacent structures defining flow paths between structures for passage of the air stream therethrough, each structure having at least one outer surface facing an air stream gap across which either a liquid desiccant or water can flow, wherein the air stream flows through the air stream gaps between the structures such that the air stream is exposed to the liquid desiccant and dehumidified when in some of the flow paths and exposed to water and humidified when in other flow paths, each structure further including a separate collector at a lower end of the at least one surface of that structure for collecting the liquid desiccant or water that has flowed across the at least one surface of the structure, said collectors being spaced apart from each other to permit airflow therebetween; and(ii) one or more diverters for diverting a portion of the air stream that has been dehumidified to a flow path where it is exposed to water where it absorbs a portion of the water and is thereby cooled;(b) a regenerator connected to the conditioner for receiving liquid desiccant from the collectors in the conditioner, said regenerator causing the liquid desiccant to desorb water, and returning the liquid desiccant to the conditioner;(c) an apparatus for moving the air stream through the conditioner; and(d) an apparatus for circulating the liquid desiccant through the conditioner and regenerator. 2. The desiccant air conditioning system of claim 1, wherein each of the plurality of structures includes a passage through which heat transfer fluid can flow, and further comprising a cold source for cooling the heat transfer fluid. 3. The desiccant air conditioning system of claim 1, wherein the structures are configured such that the air stream is exposed to liquid desiccant and water in alternating flow paths. 4. The desiccant air conditioning system of claim 1, wherein the one or more diverters can selectively control the amount of the air stream diverted. 5. The desiccant air conditioning system of claim 1, wherein the structures are substantially identical to each other, with each structure having opposite first and second sides, wherein the first side of each structure faces the second side of an adjacent structure. 6. The desiccant air conditioning system of claim 1, wherein the plurality of structures are secured within the conditioner in a way that permits the structures to expand or contract in a direction that is generally parallel to the thermal gradient to alleviate thermal-induced stress on the structures. 7. The desiccant air conditioning system of claim 1, further comprising a sheet of material positioned proximate to the outer surface of each structure between the liquid desiccant and the air stream or between the water and the air stream, said sheet of material guiding the liquid desiccant into a collector and permitting transfer of water vapor between the liquid desiccant and the air stream or between the water and the air stream. 8. The desiccant air conditioning system of claim 7, wherein the surface tension of the liquid desiccant or water and the sheet of material facilitate transfer of the liquid desiccant or water to a collector. 9. The desiccant air conditioning system of claim 7, wherein for each structure, a lower edge of the sheet of material is not fixedly connected to a lower portion of the structure to reduce pressure buildup of liquid desiccant or water. 10. The desiccant air conditioning system of claim 7, wherein the sheet of material comprises a membrane or a hydrophilic material. 11. The desiccant air conditioning system of claim 7, wherein the sheet of material comprises a hydrophobic micro-porous membrane. 12. The desiccant air conditioning system of claim 7, wherein the sheet of material comprises a layer of hydrophobic material and a layer of hydrophilic material between the hydrophobic material and the at least one surface of the structure. 13. The desiccant air conditioning system of claim 7, wherein each structure includes two opposite surfaces across which the liquid desiccant can flow, and wherein a sheet of material covers the liquid desiccant on each opposite surface, each sheet of material comprising an outer layer of a hydrophobic material and an inner layer of hydrophilic material, said inner layer facing one of the surfaces of the structure. 14. The desiccant air conditioning system of claim 7, further comprising one or more vent holes in the sheet of material of each structure to enable liquid desiccant or water to freely flow between the sheet of material and the structure and inhibit vacuum lock. 15. The desiccant air conditioning system of claim 1, wherein said plurality of structures comprises a plurality of plate assemblies arranged in a substantially vertical orientation and spaced apart to permit flow of the air stream between adjacent plate assemblies. 16. The desiccant air conditioning system of claim 15, wherein each plate assembly includes a convoluted plate. 17. The desiccant air conditioning system of claim 1, wherein the plurality of structures comprises a plurality of tubular members arranged in a substantially vertical orientation, at least some of which include an annular passage through which the liquid desiccant can flow and a central passage surrounded by the annular passage through which the air stream can flow. 18. The desiccant air conditioning system of claim 1, further comprising an apparatus for causing turbulence in the air stream flowing through or between the structures in the conditioner. 19. The desiccant air conditioning system of claim 1, wherein each structure comprises a thermally conductive plastic material. 20. The desiccant air conditioning system of claim 1, further comprising a tank connected to the conditioner for storing the liquid desiccant used in the conditioner, wherein the liquid desiccant varies in concentration along the height of the tank, and further comprising a mechanism for drawing liquid desiccant from the tank at different selected heights of the tank in order to obtain liquid desiccant having a given concentration. 21. The desiccant air conditioning system of claim 1, wherein the regenerator includes a plurality of structures arranged in a substantially vertical orientation, each structure having at least one surface across which the liquid desiccant can flow, wherein the air stream flows through or between the structures causing the liquid desiccant to desorb water, each structure further includes a desiccant collector at a lower end of the structure for collecting liquid desiccant that has flowed across the at least one surface of the structure. 22. The desiccant air conditioning system of claim 21, further comprising a heat source for heating the liquid desiccant. 23. The desiccant air conditioning system of claim 21, wherein each of the plurality of structures in the regenerator includes a passage through which heat transfer fluid can flow, and further comprising a heat source for heating the heat transfer fluid. 24. The desiccant air conditioning system of claim 23, wherein the liquid desiccant and the heat transfer fluid flow in generally opposite directions in the regenerator. 25. The desiccant air conditioning system of claim 21, wherein the plurality of structures are secured within the regenerator in a way that permits the structures to expand or contract in a direction that is generally parallel to the thermal gradient to alleviate thermal-induced stress on the structures. 26. The desiccant air conditioning system of claim 21, further comprising a sheet of material positioned proximate to the at least one surface of each structure in the regenerator between the liquid desiccant and the air stream, said sheet of material guiding the liquid desiccant into a desiccant collector and permitting transfer of water vapor between the liquid desiccant and the air stream. 27. The desiccant air conditioning system of claim 26, wherein the surface tension of the liquid desiccant and properties of the sheet of material facilitate transfer of the liquid desiccant to a desiccant collector. 28. The desiccant air conditioning system of claim 26, wherein in each structure, a lower edge of the sheet of material is not fixedly connected to a lower portion of the structure to reduce pressure buildup of liquid desiccant. 29. The desiccant air conditioning system of claim 26, wherein the sheet of material comprises a membrane or a hydrophilic material. 30. The desiccant air conditioning system of claim 26, wherein the sheet of material comprises a hydrophobic micro-porous membrane. 31. The desiccant air conditioning system of claim 26, wherein the sheet of material comprises a layer of hydrophobic material and a layer of hydrophilic material between the hydrophobic material and the at least one surface of the structure. 32. The desiccant air conditioning system of claim 26, wherein each structure includes two opposite surfaces across which the liquid desiccant can flow, and wherein a sheet of material covers the liquid desiccant on each opposite surface, each sheet of material comprising an outer layer of a hydrophobic material and an inner layer of hydrophilic material. 33. The desiccant air conditioning system of claim 32, wherein each structure includes an internal passage through which a heat transfer fluid can flow for transfer of heat between the heat transfer fluid and the liquid desiccant or the air stream. 34. The desiccant air conditioning system of claim 26, further comprising one or more vent holes in the sheet of material of each structure to enable liquid desiccant to freely flow between the sheet of material and the at least one surface of the structure and inhibit vacuum lock. 35. The desiccant air conditioning system of claim 21, wherein said plurality of structures in the regenerator comprises a plurality of plate assemblies arranged in a substantially vertical orientation and spaced apart to permit flow of the air stream between adjacent plate assemblies. 36. The desiccant air conditioning system of claim 21, wherein each plate assembly includes a convoluted plate. 37. The desiccant air conditioning system of claim 21, wherein the plurality of structures in the regenerator comprises a plurality of tubular members arranged in a substantially vertical orientation, at least some of which include an annular passage through which the liquid desiccant can flow and a central passage surrounded by the annular passage through which the air stream can flow. 38. The desiccant air conditioning system of claim 21, wherein the plurality of structures comprises a plurality of sets of structures, said sets of structures being vertically stacked to further treat the air stream or being horizontally stacked to increase capacity of the desiccant air conditioning system. 39. The desiccant air conditioning system of claim 1, further comprising a photovoltaic-thermal (PVT) module connected to the conditioner and the regenerator for heating liquid desiccant to be introduced in the regenerator in the warm weather operation mode and for heating liquid desiccant to be introduced in the generator in the cold weather operation mode, the photovoltaic thermal module also including one or more photovoltaic cells for generating electrical power used in operating the desiccant air conditioning system. 40. The desiccant air conditioning system of claim 1, wherein the air stream entering the building space flows in a generally horizontal direction through the conditioner and a return air stream from the building space or outdoor air flows in a generally horizontal direction through the regenerator. 41. The desiccant air conditioning system of claim 1, wherein the air stream entering the building space flows in a generally vertical direction through the conditioner and a return air stream from the building space or outdoor air flows in a generally vertical direction through the regenerator. 42. The desiccant air conditioning system of claim 1, wherein the regenerator and the conditioner are physically separated to form a split air conditioning system. 43. The desiccant air conditioning system of claim 1, wherein the system is installable in a vehicle.
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이 특허에 인용된 특허 (119)
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