TH135757A - Systems and methods for effective air dehumidification and fluid recovery through evaporative cooling. - Google Patents

Abstract

DC60 (17/07/56) This invention relates to systems and methods for removing moisture from the air. By providing a moisture difference in one or more dehumidification units. Water vapor from the relatively moist atmospheric air entering the dehumidification unit is extracted by The dehumidification unit is not condensed into the vacuum volume of low pressure steam, for example, in a way, the steam is extracted through the water vapor permeable membrane of the unit. Eliminate moisture into the vacuum volume of low pressure steam. In such a way, the air that exits The dehumidification unit contains less moisture than the air entering the dehumidification unit. Low pressure steam The extracted air is compressed to a slightly higher pressure, then condensed and removed from the system. At the state of the environment In addition, each individual dehumidification unit may also be related to One or more evaporative cooling units. Where air is controlled to flow The evaporation cooling unit is upstream and / or downstream of the dehumidification unit. In one manner, the dehumidification unit reduces the ratio of humidity and temperature to the The final required by the method of the ideal moisture ratio versus temperature curve. The invention relates to systems and methods for removing moisture from the air. By providing a moisture difference in one or more dehumidifying units. Water vapor from the relatively moist atmospheric air entering the dehumidification unit is extracted by The dehumidification unit is not condensed into the vacuum volume of low pressure steam, for example, in a way, the steam is extracted through the water vapor permeable membrane of the unit. Eliminate moisture into vacuum volume, low pressure steam. In such a way, the air that exits The removal unit from the air is exposed to less moisture than the air entering the dehumidification unit. Low pressure steam The extracted air from the air is compressed to a slightly higher pressure, condensed and removed from the system. At the state of the environment In addition, the dehumidification unit Each unit may also be related to One or more evaporative cooling units. Where air is controlled to flow The evaporation cooling unit is upstream and / or downstream of the dehumidification unit. In one manner, the dehumidification unit reduces the ratio of humidity and temperature to the The final required by the cyclic method of the ideal moisture ratio relative to the temperature curve.

Claims (1)

Disclaimer (all) which will not appear on the advertisement page: Edit 17/07/2015 1. Dehumidification system. (dehumidification system) for removing water vapor from the air It consists of: the first compartment and the second compartment separated by a membrane. It is structured to help remove water vapor from the air flow through the first cavity by facilitating the passage of H2O from the steam to the second through the permeable area of the inner membrane. While blocking other components All significant air tubes do not penetrate the membrane; The first evaporative cooling unit that is structured. To cool the air at the end of the membrane; A second evaporative cooling unit that is structured to cool the The air at the source side of the membrane; A structured pressure booster to create a sub-steam pressure inside the second chamber. Below the first cavity in such a way that H2O will travel through the membrane to the second vent. Where the device The pressure booster is also structured to increase the steam pressure at the outlet of the pressure booster until Sub-pressure of the steam in the range suitable for Subsequently, liquid condensation, and controller (controller) incorporates a microprocessor, is structured for Control the operation of this dehumidification system 2. System according to claim 1, where the operation consists of a cooling operation by evaporating the first evaporated from the cooling unit. By evaporating the first unit, performing moisture removal at One is obtained from the pressure boosting device and the cooling operation is performed by the second evaporation obtained from the second evaporation chiller. During operation 3. System according to claim 2, where the control device is structured to control the operation. Of this dehumidification system to achieve the results of temperature control based on a psychometric diagram. (Psychrometric chart) of the dehumidification system 4. System according to claim 1, which consists of a condensation apparatus provided. Structure to receive steam from the pressure booster and condense the steam to water in a liquid state 5. System according to claim 4, which consists of a water transport device that is structured for Convey water in the liquid state from the condensing apparatus 6. System according to claim 1 where the membrane is made up of zeolite 7. System including: humidification unit for removing H2O vapor from the stream Air, which includes: an air chamber that is structured to receive the incoming air stream and release the air flow: and the H2O-permeable material adjacent to the air chamber. Where the material that H2O can penetrate It is structured so that H2O can be selected from the H2O vapor in the incoming air stream to pass through the material that H2O can penetrate to the absorbent side of the material that H2O can penetrate. And significantly blocks other components in the incoming air stream from passing through the H2O-permeable material to the The suction side of the material that H2O can penetrate; A structured evaporative cooling unit to cool the air stream; Pressure boosting device It is structured to create a fractional pressure of H2O vapor on the suction side of the material that H2O can penetrate lower than the fractional pressure of H2O vapor in the incoming air stream. To drive the H2O flow out of the H2O vapor in the incoming air stream through the material that H2O can penetrate. And to increase the pressure at the outlet of the pressure booster up to the suitable H2O vapor digestion pressure for condensing H2O vapor to liquid H2O; And a control device, which consists of a microprocessor, is structured to control Operation 1 of the dehumidification unit 8. System according to claim 7, which includes Cooling unit by evaporation unit at Two are located at the source side of the dehumidification unit 9. System according to claim 7, where the control device is structured to control the operation at Two of the evaporative cooling units 1 0. System according to claim 7, which consists of a condensation device supplied. Structure to receive H2O vapor from the outlet of the pressure booster device. And to condense H2O vapor to liquid H2O. 11. System according to claim 10, which consists of a structured liquid pump to transport liquid H2O from the condensation equipment 12. System according to claim 7 where the material That H2O is permeable, consisting of a membrane that can be permeable 13. System according to claim 7, where H2O-permeable materials are composed of zeolite 14. System according to claim 7 Where dehumidification unit is a variable speed dehumidification unit and a cooling unit. Where evaporation is the cooling unit 15. Methods which include: intake of an air stream containing H2O vapor into the air inlet of the dehumidification unit where the air stream has the first sub-pressure of the H2O vapor. Air with a cooling unit by evaporation; Adsorption of H2O into the H2O vapor chamber of the dehumidification unit, through the permeable material H2O of the dehumidification unit. The pressure difference is applied across the H2O permeable material, where the H2O permeable material consists of zeolite and the H2O vapor chamber. The second value of the H2O vapor that is lower than the first sub-value of the H2O vapor of the air stream; And getting H2O vapor from the H2O vapor channel into the pressure booster device And increasing the pressure of H2O vapor from the pressure booster to the third sub-pressure of the second H2O vapor pressure is higher than the second sub-pressure of the H2O 1 6. Method of claim 15, which includes Cooling the air stream with the unit Cooling by evaporation Before controlling the air flow into the dehumidification unit 1 7. Method of claim 15, which includes air flow cooling. Refrigeration unit By evaporation after taking the air stream from the dehumidification unit. 18. Method of claim 15, which includes air current cooling. Refrigeration unit By evaporation unit one Before controlling the air flow into the dehumidifying unit And cooling the air flow with the refrigeration unit By evaporating the second unit after receiving Air flow from dehumidification unit 1 9. Method according to claim 15, which consists of receiving H2O vapor from a pressure booster device. Enter the condensation apparatus and condensate H2O vapor to liquid H2O 2 0. Method according to claim 19, where the air stream has the first sub-pressure H2O vapor in the range of approximately 0.2-1.0 psia, the The second subpressure of the H2O vapor ranged from approximately 0.1-1.0 psia, and the third sub-pressure H2O was approximately 0.25-1.1 psia. 21. Claim 3 system where the control According to the psychometric diagram Included Adjusting at least one point on the psychometric chart. ------------------------------------------------ 1. Dehumidification system (dehumidification system) for removing water vapor from the air Which consists of Channel one and the second channel that is separated from each other by the main (membrane), where this membrane It is structured to help remove water vapor from the air flow through the first cavity by running the HO path from the steam to the second through the permeable area of the main membrane. While blocking Other components Most of all the tubes are not allowed to pass through the membrane. The first cvaportive cooling unit is structured. To cool the gas downstream of the membrane Second evaporation cooling unit structured to cool the gas. The upstream side of the membrane A structured pressure booster to create a sub-steam pressure inside the second chamber. Below the first cavity in such a way that HO will travel through the membrane to the second vent. Where the device The pressure booster is structured to increase the steam pressure at the outlet of the pressure booster until the Sub-pressure of the steam in the range suitable for Subsequently, a water condensation and a controller are structured to control the operation of the dehumidification system.