Abstract: A hypersonic aircraft includes one or more leading edge assemblies that are designed to cool the leading edge of certain portions of the hypersonic aircraft that are exposed to high thermal loads, such as extremely high temperatures and/or thermal gradients. Specifically, the leading edge assemblies may include an outer wall tapered to a leading edge or stagnation point. A coolant supply provides a flow of cooling fluid to a porous tip that is joined to the forward end of the outer wall and defines variable porosity and/or internal barriers to direct a flow of cooling fluid to the regions of the leading edge experiencing the highest thermal loading.

Abstract: A chilled water cooling system includes a natural cooling circuit and a mechanical cooling circuit. The natural cooling circuit includes a natural cooler, a chilled water main pump, at least one first pipeline, and a terminal heat exchanger connected in series. The terminal heat exchanger is disposed at a location in need of cooling. The mechanical cooling circuit includes a chilled water main machine, a chilled water auxiliary pump, and at least one second pipeline connected in series. The mechanical cooling circuit is connected in parallel with the natural cooling circuit through a controllable connecting device.

Abstract: A cooling device for cooling a fluid comprises a vertical cooling tower, into an upper area of which the fluid to be cooled is fed and from a lower area of which the cooled fluid is discharged. The fluid in the cooling tower is cooled by a cooling gas flowing from the bottom to the top. At least one installation in which the fluid is conducted is provided in the gas space of the cooling tower through which cooling gas flows. Each installation comprises at least one fluid channel that is separated at least in part from the gas space of the cooling tower by a fluid-tight membrane wall that is permeable to vapor on both sides.

Abstract: A space-environment dedicated cooling device includes a first flow path to which coolant to be cooled is fed, a second flow path thermally coupled to the first flow path and a water absorbing body which is exposed to the space environment when the cooling device is used in the space environment. The second flow path is fed with feedwater. The water absorbing body is fed with the feedwater from the second flow path. The water absorbing body includes a water absorbing member made of water-absorbing material.

Abstract: A cooling device includes an electroosmotic liquid transport membrane and a passage through which a fluid to be cooled can flow. The passage has a wall which includes the electroosmotic liquid transport membrane. The membrane is arranged to transport liquid to effect evaporative cooling such that the fluid in the passage can be cooled. The fluid in the passage is a liquid and the cooling device is arranged so that in use, the liquid being transported to effect evaporative cooling is transported through the electroosmotic liquid transport membrane out of the passage.

Abstract: A semiconductor fabrication apparatus includes a semiconductor wafer mounting table having a cavity therein; and a nozzle which jets a liquefied temperature adjustment medium having a temperature equal to or less than a targeted temperature to an inner wall of the cavity in order to adjust a temperature of the semiconductor wafer mounting table to the targeted temperature. The semiconductor fabrication apparatus further includes a pressure detecting unit for detecting an internal pressure of the cavity; and a vacuum pump which discharges gas within the cavity such that a pressure detected by the pressure detecting unit becomes equal to or more than a saturated vapor pressure related to the temperature of the temperature adjustment medium jetted from the nozzle and equal to or less than a saturated vapor pressure related to the targeted temperature.

Abstract: A counter flow indirect evaporative heat exchanger (10) having vertically stacked alternate counter flow wet (14) and dry (12) passages where the wet passages are wetted during operation of the heat exchanger by wetting means (50, 52, 53, 54, 70, 72, 74, 76) travelling vertically of the stack. Elongately wetting of a small plurality of the total number of passages (14, 12) of the heat exchanger (10) occurs at a time during vertical travel of the wetting means.

Abstract: Heat exchanger, in particular for use in a climate chamber, as well as to a climate chamber provided with such a heat exchanger. The heat exchanger essentially comprises a panel-shaped body (21) of heat-conducting material, which body is provided with fluid lines (22, 23, 24) for the passage of a fluid. The panel-shaped body (21) is provided with perforations (25, 26) for the passage of a gas stream (A) directed transversely to the plane of the panel-shaped body. The heat exchanger is furthermore provided with a medium, supply duct. (27) for supplying a gaseous medium to a plurality of gassing ducts (28). The gassing ducts (28) run parallel to one another along the panel-shaped body (21) and the interior of each gassing duct in each case touches a part of the panel-shaped body (21).

Abstract: Aspects of the present invention relate to a textile fibre, thread or yarn. The fibre, thread or yarn is generally for production into a fabric. Alternative aspects are described for achieving a cooling effect, energy harvesting, heating, energy generation, energy emission, and others.

Abstract: A solar air conditioner provides cooling by way of liquid evaporation. The solar air conditioner includes a liquid evaporation unit, a heat exchange unit, and a solar power generation unit. The liquid evaporation unit includes an outer housing and an inner housing. The outer housing includes a fan affixed to the top and an plurality of openings on the side wall. The inner housing inside the outer housing has a plurality of porous holes through which the liquid therein penetrates to the outer surface. The penetrated liquid comes in contact with the warm air drawn by the fan and evaporation subsequently occurs cooling the liquid inside the inner housing. The cooled liquid is then provided to the heat exchange unit for cooling a target area. The pumps and fans are powered by the solar power generation unit.

Abstract: A space-environment dedicated cooling device includes a first flow path to which coolant to be cooled is fed, a second flow path thermally coupled to the first flow path and a water absorbing body which is exposed to the space environment when the cooling device is used in the space environment. The second flow path is fed with feedwater. The water absorbing body is fed with the feedwater from the second flow path. The water absorbing body includes a water absorbing member made of water-absorbing material.

Abstract: An evaporative cooler may include an evaporative cooler housing with a duct extending therethrough, a plurality of cooler louvers with respective porous evaporative cooler pads, and a working fluid source conduit. The cooler louvers are arranged within the duct and rotatably connected to the cooler housing along respective louver axes. The source conduit provides an evaporative cooler working fluid to the cooler pads during at least one mode of operation.

Abstract: An evaporative cooling device (40) is disclosed for cooling water or other liquids comprising a vessel (50) adapted to receive water or another liquid, said vessel comprising a vessel wall (53, 54, 55), an outer layer (90) of absorbent material and a wick (85) extending through said vessel wall, such that said wick is positioned to contact said water or other liquid within the vessel and is adapted to transport a portion of said water or other liquid through the wall by capillary action to said absorbent material, said wick being substantially impermeable to gas or vapor, so that the cooling device (40) can be connected in-line in an hydration system of the kind comprising a reservoir (12) and a drinking tube (32).

Abstract: A thermal transfer system, a heat sink, and a method for transferring heat are provided. The thermal transfer system includes a fuel cell that can produce a fluid. A wick is provided to transfer the fluid to a destination at which a heat source is present. An enclosure having a porous fluid-permeable external wall can surround the fluid at the destination. When the fluid permeates or condenses on the external wall exterior surface, air exposure of that external wall will cause evaporative cooling of the fluid, and thereby enhance the cooling effect at the heat source. The fluid is a natural byproduct of the fuel cell. Accordingly, the thermal transfer system not only cools a heat source, but produces electric current. The heat sink can be thermally coupled to the heat source, and can have a plurality of fins extending from a base. One or more fins can have a fluid-permeable external wall for evaporative cooling.

Abstract: A thermal transfer system, a heat sink, and a method for transferring heat are provided. The thermal transfer system includes a fuel cell that can produce a fluid. A wick is provided to transfer the fluid to a destination at which a heat source is present. An enclosure having a porous fluid-permeable external wall can surround the fluid at the destination. When the fluid permeates or condenses on the external wall exterior surface, air exposure of that external wall will cause evaporative cooling of the fluid, and thereby enhance the cooling effect at the heat source. The fluid is a natural byproduct of the fuel cell. Accordingly, the thermal transfer system not only cools a heat source, but produces electric current. The heat sink can be thermally coupled to the heat source, and can have a plurality of fins extending from a base. One or more fins can have a fluid-permeable external wall for evaporative cooling.

Abstract: A modular electronic cooling system with moving parts, composed of a base unit and individual modules inserted into this base unit in respect to the expected upper limit of the heat load may utilize thermoelectric power generation and the heat load itself to allow for operation independent of any external power source. By the same mechanism the cooling system scales within a range automatically reacting to and dissipating a dynamic heat load via forced convection, and doing so passively, without the need for specific programming. This cooling system uses porous material or multi-layered mesh parts, thermoelectric components, a modular assembly system and independent enclosure parts for described porous material or multi-layered mesh, an electronics control system that may be passively activated, and a motor assembly. Altogether the system provides maximum efficiency in terms of form factor.

Abstract: An evaporative cooling device (40) is disclosed for cooling water or other liquids comprising a vessel (50) adapted to receive water or another liquid, said vessel comprising a vessel wall (53, 54, 55), an outer layer (90) of absorbent material and a wick (85) extending through said vessel wall, such that said wick is positioned to contact said water or other liquid within the vessel and is adapted to transport a portion of said water or other liquid through the wall by capillary action to said absorbent material, said wick being substantially impermeable to gas or vapour, so that the cooling device (40) can be connected in-line in an hydration system of the kind comprising a reservoir (12) and a drinking tube (32).

Abstract: A sealed, double walled water packet has an inner packet filled with potable water that has a porous outer surface layer containing absorbed water and an outer packet that encloses the inner packet and is connected to the inner layer. The inner packet (which may contain as little as a swallow of water) is connected to the outer packet (both of which can be made as envelopes with tearable sections or peel off corners) along one side or by a string so that the inner packet can be twirled or waved to cause rapid evaporation of water in the porous outer surface layer (which can include hydrogel) to thereby cool the potable water contained inside the inner packet before it is opened.

Abstract: A heat exchanger having a plurality of tubes that define refrigerant passages extending vertically from a lower end to an upper end. A bottom header is in fluid communication with the passage at the lower end of the tube, and a top header is in fluid communication with the passage at the upper end of the tube. A plurality of plates extends rearwardly from the tubes to a distal edge. Adjacent plates extending from adjacent tubes are closed off at the distal edges by a connector, and adjacent plates extending from the same tube have a rear opening between the distal edges for receiving air into the assembly. A plurality of orifices is disposed along the plates to allow air from the rear opening to flow downstream between the tubes. A water tank and wicking material are provided for wetting the plates.

Abstract: An automotive air conditioning system is disclosed comprising an evaporative cooler in series with the conventional vapor compression system. The evaporative cooler comprises an array of dry channels and a contiguous array of wet channels. The primary air stream to be conditioned by the evaporator of the conventional air conditioning system is preconditioned by the evaporative cooler by lowering its dry bulb temperature without changing its absolute humidity. An evaporator core is supported downstream of the evaporative cooler for receiving the primary air from the dry channels and thereby produces liquid condensate. The system is distinguished by conducting the liquid condensate from the evaporator core to the wicking tank for use in the wet channels of the evaporative cooler.

Abstract: A temperature-humidity exchanger comprising: a moisture permeable membrane which transmits moisture therethrough; a dry gas separator in which low-temperature dry gas is caused to flow; and a wet gas separator in which high-temperature wet gas is caused to flow, in which the moisture permeable membrane, the dry gas separator, the moisture permeable membrane, and the wet gas separator are repeatedly stacked in the stated order, wherein in the dry gas separator and the wet gas separator: a plurality of channel grooves which are divided by half in the stacking direction, are open to a direction in which the channel grooves come into contact with the moisture permeable membrane, and are arrayed parallel to one another are provided; an aggregate communication groove which is made to communicate with both end portions of the plurality of channel grooves, for aggregating gas caused to flow through the channel grooves to at least one is provided; and a supply manifold and an exhaust manifold which are made to communi

Abstract: Disclosed are cooling tubes or straws for beverages and other liquids. The tubes or straws comprise a porous matrix to effect the cooling a liquid contained within by pervaporation.

Abstract: Disclosed are cooling jackets for containers for beverages and other liquids. Such a jacket comprises a porous matrix as an element of the jacket body to effect the cooling of the jacket by pervaporation of a liquid contained within the jacket body. The jacket therefore cools a liquid within a container maintained in direct contact with the jacket.

Abstract: Air cooling assembly (ACA) 100 uses AC section 300 that comprises AC compressor unit 30, AC channel 32, AC condensation unit 33 and AC evaporator 31. ACA 100 integrates the AC section 300 with an IWC section 200 that comprises IWC compressor unit 20 that is used to cool a refrigerant that runs through IWC compressor unit channel 24, where IWC compressor unit channel 24 cools water that further evaporate through IWC evaporator 21 and IWC condensation unit 23. Cross-flow-fan (CFF) 40 draws the cooled air that results from both IWC section 200 and AC section 300 and disperses the cooled air into an indoors environment. AC condensation unit 33 and IWC condensation unit 23 provide a strata manifold of pieces for the accumulation of condensed water.

Abstract: Disclosed are self-cooling containers for beverages and other liquids. Such containers comprise porous matrices as elements of the container bodies to effect the cooling of contained liquids by pervaporation. The liquid vapor can pass through the porous matrix directly to the environment or to a collector or trap comprising an absorbent material in contact with the container. Also disclosed are self-cooling containers incorporating insulative sleeves that reduce radiative warming of container surfaces yet permit sufficient pervaporative flux to cool containers residing within such sleeves.

Abstract: Cooling of an enclosed space is effected by a cooling system including a plurality of cooling units forming ducts having an internal surface on which a layer of liquid is developed, e.g. by a wicking material, and through which air from the enclosed space is passed in contact with the liquid layer whereby the liquid is exposed to and evaporates into the air-flow with consequent cooling of the duct wall on which the liquid layer is developed.

Abstract: An evaporative cooling system that can be easily transported and set up quickly in indoor or outdoor environments to provide effective cooling to a sizable area in a short time period. The system can be operated from standard AC household electrical power, or from a 12-volt DC power source, such as a car or marine battery. The system water tank can be filled with water, or connected to a water source for continual refilling. The system can also be used with a light-weight water source, holding approximately 2 liters of water for temporary cooling, or without water to move large volumes of air.

Abstract: The operating efficiency of indirect evaporative cooling processes and indirect evaporative cooling apparatus employing a dry side channel and a wet side channel separated by a heat exchange plate are improved by placement of holes in the heat exchange plate. Further improvements are obtained when the flow direction in the wet side channel is cross-current to the flow direction in the dry side channel. Placement of desiccant materials in the dry side channel also serve to improve the operating efficiencies of these processes and apparatus.

Abstract: An air conditioner comprises a plurality of plates arranged in a successively stacked configuration with portions thereof having a spaced apart arrangement, and defining between successive adjacent pairs of plates at the spaced apart portions a first and second series of discrete alternating passages wherein a first air stream is passed through the first series of passages and a second air stream is passed through the second series of passages; and said stacked configuration of plates forming integrally therewith a liquid delivery means for delivering from a source a sufficient quantity of a liquid to the inside surfaces of the first series of fluid passages in a manner which provides a continuous flow of the liquid from a first end to a second end of the plurality of plates while in contact with the first air stream.

Abstract: The invention is generally directed to an evaporative humidifier having a water distribution system capable of quietly maintaining a continuously saturated wicking element through the use of a pump and water distribution troughs that allow water to be continuously flushed onto the tops of the wicking elements such that greater humidification of the air is achieved and the life of the wicking elements are extended.

Abstract: An evaporative cooling apparatus is provided that may be quickly deployed to cool an area. The apparatus is preferably self-contained or substantially self-contained. The apparatus can be either a dedicated trailer with a conventional draft vehicle or a vehicle itself or a permanently dedicated apparatus. The apparatus creates an evaporatively cooled volume of air with fine entrained water droplets suspended therein. The apparatus transfers the cooling suspension to an area to be cooled proximate the apparatus.

Abstract: The present invention relates to a method and an apparatus for providing enhanced indirect evaporative cooling of air, water, fuel, or other fluids while controlling the humidity. The design makes cooling down to the dew point possible without energy input other than the energy to produce the fluid flow needed. The design makes use of stacked composite plates (7) with channels (1, 2) for fluid flow between adjacent plates. On opposing surface areas of these plates, there are wet areas (4) or dry areas (3). The wet areas (4) provide cooling by conventional evaporation which is in turn used to cool the fluids in contact with the dry areas (3). The benefit is controlled heat transfer, which allows selected cooling of fluid flow such that the temperature as low as dew point are reachable.

Abstract: A cooling device is constructed by a water impermeable member defining a water passage, the water impermeable member being provided with a vapor permeable member which is permeable to water vapor and impermeable to water, and has the form of a mesh and made of a material having water repellency. The cooling device has a long-life operation while preventing wear-out of the vapor permeable member. Further, optimally setting the size of an opening of the mesh member enables to securely dissipate water vapor outside of the cooling device through the vapor permeable member while efficiently suppressing water leak.

Abstract: Cooling of an enclosed space is effected by means of a cooling system comprising a plurality of cooling units forming ducts having an internal surface on which a layer of liquid is developed, e.g. by means of a wicking material, and through which air from the enclosed space is passed in contact with the liquid layer whereby the liquid is exposed to and evaporates into the air-flow with consequent cooling of the duct wall on which the liquid layer is developed.

Abstract: In a refrigeration system (10), an evaporator (11) and a condenser (15) are each formed of a container-like member (55). The inside of the container-like member (55) is divided into a liquid side space (12, 16) and a gas side space (13, 17) by a moisture permeable membrane (14, 18). Both the gas side spaces (13, 17) are held in a predetermined reduced-pressure condition. Both the liquid side spaces (12, 16) are placed in an atmospheric pressure condition. Water vapor provided by evaporation of water in the liquid side space (12) of the evaporator (11) passes through the moisture permeable membrane (14) and moves to the gas side space (13). The water vapor in the gas side space (13) is sucked by a compressor (21) so as to be pumped to the gas side space (17) of the condenser (15). In the condenser (15), the water vapor in the gas side space (17) moves to the liquid side space (16) and then condensates therein.

Abstract: The present invention relates to a method and an apparatus for providing enhanced indirect evaporative cooling of air, water, fuel, or other fluids while controlling the humidity. The design makes cooling down to the dew point possible without energy input other than the energy to produce the fluid flow needed. The design makes use of stacked composite plates (7) with channels (1, 2) for fluid flow between adjacent plates. On opposing surface areas of these plates, there are wet areas (4) or dry areas (3). The wet areas (4) provide cooling by conventional evaporation which is in turn used to cool the fluids in contact with the dry areas (3). The benefit is controlled heat transfer, which allows selected cooling of fluid flow such that the temperature as low as dew point are reachable.

Abstract: An improved method and apparatus for indirect evaporative cooling of a fluid stream to substantially its dew point temperature. Plate heat exchanger has perforations 11 and channels 3, 4 and 5 for gas or a low temperature for liquids on a dry side and wet side. Fluid streams 1 flow across the dry side 9, transferring heat to the plate. Gas stream 2 flows across the dry side and through perforations to channels 5 on wet side 10, which it then cools by evaporative cooling as well as conductive and radiative transfer of heat from plate. A wicking material provides wetting of wet side. In other embodiments, a desiccant wheel may be used to dehumidify the gas, air streams may be recirculated, feeder wicks 13 and a pump may be used to bring water from a water reservoir, and fans may be used to either force or induce a draft. The wicking material may be cellulose, organic fibers, organic based fibers, polyester, polypropylene, carbon-based fibers, silicon based fibers, fiberglass, or combinations of them.

Abstract: The final segment in one-half or one-third circuit tube assemblies are arranged in a concurrent manner with the air flow in a closed-circuit cooling tower to more fully utilize spray-water cooling that occurs in the region below the tube assembly but above the sump water surface.

Abstract: A cooling device is constructed by a water impermeable member defining a water passage, the water impermeable member being provided with a vapor permeable member which is permeable to water vapor and impermeable to water, and has the form of a mesh and made of a material having water repellency. The cooling device has a long-life operation while preventing wear-out of the vapor permeable member. Further, optimally setting the size of an opening of the mesh member enables to securely dissipate water vapor outside of the cooling device through the vapor permeable member while efficiently suppressing water leak.

Abstract: An evaporative process employing an undulating flexible membrane (4) as an evaporative surface onto which a vaporizing gas (2) such as, but not limited to, air, contacts a liquid solution (1, 5) such as, but not limited to, water, and evaporation occurs. The membrane (4) is supported (3) with sufficient laxity to permit wavelike undulating motion of the membrane brought about primarily by the evaporative airflow (2) itself. The differential flexing and motion of the undulating membrane (4) results in a breaking and peeling away of any normally fouling scaling or plugging solids which have precipitated or accumulated on the membrane surface (4). The undulation of the flexible membrane (4) thereby providing a self cleaning action. The self cleaning action of the membrane (4) assures successful application to evaporative processes with solutions (1, 5) which are prone to scaling, fouling, plugging or solutes buildup.

Abstract: An improved method and apparatus for indirect evaporative cooling of a fluid stream to substantially its dew point temperature. Plate heat exchanger has perforations 11 and channels 3, 4 and 5 for gas or a low temperature for liquids on a dry side and wet side. Fluid streams 1 flow across the dry side 9, transferring heat to the plate. Gas stream 2 flows across the dry side and through perforations to channels 5 on wet side 10, which it then cools by evaporative cooling as well as conductive and radiative transfer of heat from plate. A wicking material provides wetting of wet side. In other embodiments, a desiccant wheel may be used to dehumidify the gas, air streams may be recirculated, feeder wicks 13 and a pump may be used to bring water from a water reservoir, and fans may be used to either force or induce a draft. The wicking material may be cellulose, organic fibers, organic based fibers, polyester, polypropylene, carbon-based fibers, silicon based fibers, fiberglass, or combinations of them.

Abstract: An evaporative cooling apparatus (20) includes a housing (22) and cooling media (48) contained in the housing (22). The cooling media (48) has an air inlet portion (46) and an air outlet portion (60). The air inlet portion (46) is positioned adjacent an air entry side (42) of the housing (22). A fresh water delivery system (54, 136) delivers fresh water (34) to a face (126) of the air inlet portion (46) of the cooling media (48). A recirculated water delivery system (56) delivers sump water (38) from a sump (40) to the air outlet portion (60). A fan section (26) is proximate an air exit side (44) of the housing (22). The fan section draws outside air (50) through the air entry side (42) of the housing (22) and into the cooling media (48) from the air inlet portion (46) through the air outlet portion (60) to produce cooled air (52).

Abstract: The present invention relates to a device for increasing the efficiency of an air-cooled condenser by using condensation from an evaporator to reduce the energy consumption of an air conditioning system.

Abstract: A water vaporization type cooling apparatus for cooling a heat-generating unit comprises a container which is made of a good thermal conductive material and has an opening, a selective water vapor permeable membrane which is mounted to the container so as to cover the opening and forms a closed space cooperatively with the container, and water charged in the closed space. In the water vaporization type cooling apparatus, the container is thermally connected to the heat-generating unit and dehydrated air flows along the outer surface of the selective water vapor permeable membrane, whereby the heat-generating unit is cooled down.

Abstract: An automatic flush water distribution system for use in an evaporative cooling system includes a water distribution pipe adapted to be connected to a source of pressurized water. The pipe has a plurality of water distribution ports formed therein and a vertical flush pipe is connected at a first end to the water distribution pipe in liquid communication therewith. The flush pipe includes a second lower end and contains at least one valve seat and at least one buoyant float valve located therein between the valve seat and the water distribution pipe.

Abstract: The compact rotary evaporative cooler of this invention includes a case containing a powered rotor mounting a partition that divides the case longitudinally into a wetted chamber and a nonwetted chamber. An annular array of elongated Perkins tubes is supported for rotation with the rotor and each Perkins tube extends through the partition, with the evaporation end section extending into the nonwetted chamber and the condensing end section extending into the wetted chamber. Each Perkins tube mounts a plurality of closely spaced heat conductive fins along its length, and a layer of porous metal is bonded to the entire inner surface of the evaporation section of the tube. A first inlet port introduces hot, dry outside air into the wetted chamber and a first outlet port vents the cooled but humidified air from the wetted chamber to the atmosphere or to a space to be conditioned.

Abstract: An automatically inflatable, deflatable and foldable solar-powered cooler mattress with a sunshade, including an auxiliary device for automatically inflating and deflating the mattress, which device includes an array of photovoltaic cells (1) for supplying the power needed to operate a motor (2) driving a turbine (4) which rotates to draw air in through a channel (9) in the mattress (5), said motor (2) also being operable to deflate the mattress (5) when the polarity of the motor power supply is reversed; a beverage cooler device comprising a water-soaked foam cylinder (17) so that when the turbine (4) is driven by the motor (2) to generate an air flow, said air flow causes evaporation of the water, thereby cooling the cylinder and an ultra-lightweight adjustable sunshade (10), one edge of the mattress being provided with a guide rail and a clamping system enabling the sunshade to be used in a variety of positions.

Abstract: The invention provides extreme convenience and flexibility in providing for cooled beverages at inconvenient places and times. This flexibility is provided by the invention's use of a cooling process which is not dependent on chemicals or power sources, that is, the evaporative process which can utilize any type of water: potable, non-potable, brackish, salt, etc. etc. This provides conservation of valuable potable water in locations where potable water is scarce, i.e., hiking and camping trips. In one embodiment, the container structure has holes in the outer wall to facilitate the evaporative process and the to be cooled beverage contained in a standard can is elevated off the container structure floor to also facilitate the evaporative process.

Abstract: An evaporative cooling membrane device is disclosed having a flat or pleated plate housing with an enclosed bottom and an exposed top that is covered with at least one sheet of hydrophobic porous material having a thin thickness so as to serve as a membrane. The hydrophobic porous material has pores with predetermined dimensions so as to resist any fluid in its liquid state from passing therethrough but to allow passage of the fluid in its vapor state, thereby, causing the evaporation of the fluid and the cooling of the remaining fluid. The fluid has a predetermined flow rate. The evaporative cooling membrane device has a channel which is sized in cooperation with the predetermined flow rate of the fluid so as to produce laminar flow therein. The evaporative cooling membrane device provides for the convenient control of the evaporation rates of the circulating fluid by adjusting the flow rates of the laminar flowing fluid.

Abstract: A contra flow air to air heat exchanger, and an evaporative air conditioner employing such a heat exchanger, wherein the heat exchanger (10) utilises a series of stacked plates (24), each having curved deep groove corrugations which form channels (27) with an adjacent plate which are inclined at a small angle with the channels (28) of the first plate (24), each stack of plates (24) having two inlet ducts (14, 16) and two outlet ducts (18, 20) and (19, 21).