Desiccant air conditioner
2) The heat exchange device of claim 1 wherein said first fluid is a liquid and said surrounding fluid is air and said opening is near the top of said first enclosure.
3) The heat exchange device of claim 2 wherein said fluid forces are hydrostatic forces that result from the relative density of the first fluid and the surrounding fluid.
4) The heat exchange device of claim 3 further comprising a second enclosure that contains a second fluid that comprises a second liquid that surrounds a portion of said first enclosure and a second path in said second enclosure that allows flow of said second liquid.
5) The heat exchanger of claim 4 wherein said second enclosure is made of a flexible material that is inflated by hydrostatic forces.
6) The heat exchange device of claim 5 wherein the flow of the liquids is approximately counterflow.
7) The heat exchange device of claim 6 further comprising means for circulating air over said second enclosure.
8) The heat exchange device of claim 7 wherein said airflow is approximately counterflow to flow of said second liquid.
 This application is a continuation-in-part of application Ser. No. 10/189,089 entitled "Desiccant Air Conditioner with Thermal Storage", filed on Jul. 3, 2003, and application Ser. No. 09/549,329 entitled "Solar Air Conditioner" filed on Apr. 14, 2000, which has issued as U.S. Pat. No. 6,513,339.
FIELD OF THE INVENTION
 This invention is in the field of air conditioning, specifically thermally driven air-conditioners that are capable of accepting a thermal input from solar or off-peak electricity.
BACKGROUND OF THE INVENTION
 Solar air conditioning has great potential to reduce energy use from air conditioning. Sunlight is most plentiful in the summer when air conditioning is required.
 The problem is that existing solar technologies have not produced systems that are economically competitive with conventional electrically driven systems. Prior work with solar air conditioning has not produced practical systems. Solar air conditioning systems have used two basic approaches in an attempt to capture the sun's energy for cooling--thermal and photovoltaic.
 The photovoltaic systems use photovoltaic panels to convert solar radiation directly into DC electricity. Photovoltaic systems have two major advantageous attributes: they can use conventional electrically driven air-conditioning equipment which is widely available and inexpensive with the addition of the solar panels that use an inverter to produce AC power, and they can use the utility grid for backup power during dark or cloudy periods.
 Unfortunately there are other attributes: the high cost of manufacturing, the low conversion efficiencies, and the need for a continual stream of photons to produce power, create three major disadvantages. First electricity from solar cells is very expensive because of the high cost of the solar panels. (Panels for a residential air conditioner can cost well over $10,000.) Second the space needed for powering the air conditioning units is large. And third the panels provide no energy storage, which creates a need for use of grid-based electricity at night and on cloudy day. In fact, the peak output from the solar panels occurs around solar noon, while peak air-conditioning load occurs several hours later, resulting in a significant mismatch between supply of needed power and demand. This mismatch greatly reduces the value of the system in reducing peak power demand to the utility, demands which recently deregulated markets is demonstrating are much more expensive to meet than had heretofore been obvious. For off-grid locations, the only viable energy storage system to match the provision of power to times when demand is high (later in afternoon and at night) is batteries. Batteries have a high first cost, require periodic replacement, and normally use toxic and/or corrosive materials. These problems have prevented the use of photovoltaic systems in other than a few high-cost demonstration systems.
 Thermal systems use heat from the sun to drive an air conditioner. Typical approaches use a high-temperature flat-plate collector to supply heat to an absorption system. Systems with concentrating collectors and steam turbines have also been proposed. Natural gas or other fuel is used for backup heat. While thermal systems have the advantage of eliminating the need for expensive photovoltaic panels, they have attributes that produce major disadvantages.
 One problem is the high cost and large size of the solar collectors. Flat-plate collectors running at about 190.degree. F. (90.degree. C.) require double-glazing and selective surface to achieve reasonable efficiency levels, which greatly increases the collector cost. This high collector cost reduces the comparative attractiveness of such systems to standard vapor compression systems driven by grid electricity. Large collector size also reduces the potential market size by eliminating many locations from possible use of the systems.
 Furthermore, existing thermal technologies also suffer from the poor COP of absorption systems, typically around 0.5. When combined with a typical collector efficiency of 20 to 50%, this inefficiency, besides creating a need for large collector areas, makes the whole system much less economically and environmentally attractive.
 Another important problem introduced by the performance attributes of current solar thermal air-conditioning concepts is the high-cost and large size of high-temperature thermal storage. Large thermal storage is required to reduce backup energy (typically gas) that would be used much of the time when their was a mismatch between demand for cooling and solar inputs. This mismatch is the discrepancy between high solar input at noon and large demands for cooling during late afternoon, at night, and on cloudy days. A related problem with existing concepts for thermally driven solar cooling is the need for significant power input for circulating pumps and fans, which further reduces the possible energy savings.
 Together these attributes for current concepts for thermally driven solar cooling imply that the large majority of their energy input would come from the backup fuel and electrical input for fans and pumps. In essence, these various problems mean that these solar systems are effectively very expensive gas-driven systems.
 No commercially available or conceptually proposed system has been demonstrated that has the attributes that would be needed for commercially viable solar air conditioner. Commercial success will require the system to have the following attributes: low first cost (The market tends to be first cost driven so it is critical that the cost and thus ultimate selling price not be too high.); small collector area (critical to cost and to finding many locations in which installation is practical); small storage size (The mismatch between solar supply and cooling demand requires storage if the system is not to become a glorified means for using fossil energy and if it is to be practical to install in many locations--as well as low cost to manufacture.); easy to incorporate backup capability (Regardless of storage capacity, the ability of the system to meet demand in extreme and unusual circumstances will be critical to market acceptance; customers demand perfection and then some.).
 Evaporative coolers are a related technology with a long history. Direct evaporative coolers are the simplest and most common. They consist of a means for moving air over a wet pad. Water evaporates from the pad and thereby cools and humidifies the air. They are commonly used for comfort cooling in warm, dry climates such as those found in the southwest U.S.
 Indirect evaporative coolers are more sophisticated. An indirect evaporative cooler means that air is cooled by contact with a dry surface that is in turn cooled evaporatively.
 Desiccant systems dry air for air-conditioning purposes. A typical system uses a solid desiccant impregnated on a wheel of corrugated metal or plastic.
 Some more obscure systems appear in the patent literature, but each has its own problems. U.S. Pat. Nos. RE 20,469; 4,660,390; 4,854,129 describe regenerative indirect evaporative coolers that use a portion of the air exiting the dry cooler as inlet air to the wet side. U.S. Pat. No. RE 20,469 describes a cumbersome arrangement of coils and cooling towers this complicated and expensive. U.S. Pat. No. 4,660,390 describes another system that uses tubes in a crossflow configuration to transfer heat between a wet side and a dry side. U.S. Pat. No. 4,854,129 also uses a system that uses a cooling coil with water from a cooling tower.
 U.S. Pat. No. 5,050,391 describes another option for the desiccant system. This system uses solid desiccant material and a true counterflow arrangement for the heat exchangers. It also has essentially a single stage of cooling which limits it performance and its ability to use inexpensive desiccant materials.
DESCRIPTION OF THE FIGURES
 FIG. 1 shows a basic embodiment of the invention.
 FIG. 2 shows a design of an indirect evaporative cooler used in this invention.
 FIG. 3 is a schematic psychrometric chart that shows how this cooler works.
 FIG. 4 is drawing of a simple air-lift pump that is preferred for use in the invention.
 FIG. 5 shows a diagram of a combination evaporative-desiccant cooler that is a component of this system.
 FIG. 6 shows another cooler configuration that uses a water mist for evaporative cooling.
 FIGS. 7, 8, and 9 shows solar collectors that may be used in the invention.
 FIG. 10 shows another embodiment of the invention.
 FIGS. 11 and 12 are plots of temperatures through the coolers used in the invention.
 FIG. 13 is an embodiment that can use exhaust heat from a gas turbine for cooling inlet air to the turbine.
 FIGS. 14a, 14b, and 14c show details of heat exchanger design that may be used in the invention.
 FIG. 15 shows another preferred embodiment that is suitable for use as a dehumidifier.
 FIG. 16 is a preferred embodiment of the invention that uses a counterflow liquid-to-liquid heat exchanger and counterflow liquid-to-air heat exchangers.
 FIG. 17 is a preferred embodiment of the invention that is suitable for producing cooled water.
 FIG. 18 is an alternate embodiment showing a single-stage cooler that rotates.
 FIG. 19 is a multistage embodiment that is assembled from the stages as shown in FIG. 18.
 FIGS. 20A, 20B, 20C, 21A, 21B, 21C, and 22 show a heat exchanger that is suitable for use in the desiccant system described in FIG. 23.
SUMMARY OF THE INVENTION
 The present invention is a liquid desiccant cooling system.
DESCRIPTION OF THE INVENTION
 Description a Preferred Embodiment: FIG. 1 shows a preferred embodiment of the invention. A flow of desiccant fluid 1 is pumped by pump 9 to a solar collector 15 that acts as a regenerator for the desiccant fluid. The fluid trickles over a collector surface 2 in the form of a thin sheet 3. A cover 4 transmits solar radiation 11, which warms the desiccant fluid as it flows over the collector surface. A flow of air 10 removes water vapor that evaporates from the desiccant fluid. The concentrated desiccant 5 leaves the collector and flows to a mass-transfer device 6 that allows the desiccant to absorb moisture from an air stream 8. The mass-transfer device is preferably a direct-contact exchanger similar to those used for direct evaporative coolers and may also include a pump for recirculating the desiccant liquid through the device to ensure good mass transfer. A supply air fan 8 moves the moves the air stream through the mass-transfer device.
 An indirect evaporative cooler 14, cools the air stream 8 without adding moisture to it. A fan 12 draws a secondary air stream 13 through the cooler. The secondary air stream may be exhaust air from a building, ambient air, or a portion of the conditioned air leaving the evaporative cooler or mass-transfer device. This indirect evaporative cooler is optional and may be eliminated in cases where no sensible cooling is required.
 Indirect Evaporative Cooler Design: FIG. 2 shows the one heat exchanger system that is suitable for use as an indirect evaporative cooler for this system. The cooler has two basic parts--mass transfer means 50 and an air-to-air heat exchanger 51. The cooler is shown without a top cover for clarity. Corrugated panels 20 for secondary air are oriented so that corrugations run from side to side while corrugated panels 21 for primary air have corrugations that run from end to end. Channels 35 formed by the corrugations in panels 21 allow for free flow of air through the panels. Likewise similar channels run in a perpendicular direction through panels 20. The panels 20 are stacked alternately with panels 21 so that the channels for each panel are perpendicular to the channels for the adjacent panels. The outside surface of the sheets may be covered with an adhesive or filler material to ensure good contact between the sheets. For maximum durability the panels are preferably made of polypropylene or polyethylene plastic. Metals, such as aluminum, are also possible materials.
 Another option is to use corrugated cardboard and paper. Waterproof adhesive material, such as one based on acrylic or linseed oil, can coat the paper or cardboard and joins the layers together to form a single unit. The advantage of cardboard or paper is its very low cost. The disadvantage is that it is may be less durable. One advantage of this system is that it is not possible to create condensation within the heat exchanger, which allows the possible use of cardboard in some applications. This is especially true in desiccant applications since it is possible to keep both air streams above their respective dew point temperatures even when outdoor conditions are at 100% relative humidity (such as rain or fog conditions).
 The main fan 29 moves primary air stream 38 through a single pass through channels 35. The stacked panels 20 and 21 form a heat exchanger that cools the primary air without addition of humidity. A portion of the cooled primary air splits off and forms a secondary air stream 39, which is moved by secondary fan 30. The secondary air first flows through multiple passes of the air-to-air heat exchanger to cool the primary air stream. The dashed arrows show the direction of the secondary airflow through the heat exchanger.
 The passes of the secondary air stream are preferably arranged in a counter crossflow configuration with a mass transfer means ahead of each pass of the heat exchanger. The mass transfer means is preferably a direct evaporative cooler. The direct evaporative cooling sections 23 form U-bends that direct the secondary air through each pass. As shown in the figure three triangular pieces fit together to form two mitered elbows, which make each U-bend. Pass dividers 27 would normally be included to prevent excessive leakage between passes in the wet media in each pass. Housing 31 ensures that excessive air does not leak in or out of the heat exchanger.
 The chief use of this system is as an evaporative air cooler, but many other applications are possible. In addition to air, this system can work equally well with any number of nonreactive gasses such as nitrogen, carbon dioxide, inert gasses, etc. This system can also be used as a heater. For example if a desiccant liquid is substituted for water and the entering gas stream has a high relative humidity, the system would act to heat the gas stream. Volatile liquids other than water-based solutions can be used in the system, but they are very expensive and may pose risks with flammability or toxicity.
 The direct evaporative cooling sections need to be thoroughly wetted to ensure good evaporation while minimizing mineral deposits. In addition there is normally a large change in the wet-bulb temperature from one end of the heat exchanger to the other, so that water circulation between passes needs to be minimized to reduce undesirable heat exchange. These factors make it desirable to use multiple water circuits with multiple pumps.
 For large systems using multiple pumps does not introduce a significant cost penalty, but for small systems multiple pumps can add greatly to the cost. One possible solution is to have multiple pumps that share a common shaft and motor. Seals separate the pumps from each other to minimize leakage and heat transfer.
 FIG. 2 shows another possible option for circulating liquid using air-lift pumps 42. Air pump 38 supplies pressurized air through air line 36. Drain 37 removes water from the bottom of the direct evaporative cooling sections 23. Air bubbles into the water to create a pumping action. Extra water can be supplied to the pumps to make up for that lost to evaporation or blow down.
 Other configurations of the air-to-air heat exchanger are possible. For example instead of stacking corrugated panels on top of each other, it may be possible on use spacers between the panels that are oriented in the same direction. The spacer could separate the passes of the secondary air and allow free flow of the secondary air over the panels. In this configuration the primary air would flow inside the channels of the panels. This alternative configuration should reduce material cost and reduces thermal resistance of the walls between the two air streams.
 Another configuration would simply stack sheets with spacers to direct airflow. For example sheets of paper can be separated by corrugated cardboard spacers. The spacers would be on the order of 0.1 inches thick to form a flow channel for air. The orientation of the spacers would alternate so that the airflow for the secondary air is perpendicular to that for the primary air. This arrangement would use a minimum amount of material and is a simple design and would be the preferred configuration for materials, such as paper, that are easily glued together.
 Indirect Cooler Theory of Operation: FIG. 3 is a psychrometric diagram showing how the idealized behavior of the system. For the case of conventional direct evaporative cooler, the process start at entering air 80 and follow the constant wet-bulb temperature line 87 (which is also essentially a line of constant enthalpy) and approach ideal exit condition 81 which is along saturation curve 88. For the new system used as a cooler there are two exit conditions, the supply air 82 and exhaust air 83. The primary air stream follows the line of constant absolute humidity 90 and approaches the saturation condition at point 82. A portion of this air exits system as supply air and the rest moves along the saturation line 88 as it is heated and humidified until it approaches the ideal exhaust condition 83. This exhaust condition is ideally at the intersection of the saturation line 88 and the constant dry-bulb temperature line 91. The result is a colder supply air temperature than is possible with a simple direct evaporative cooler.
 For the case of a heater, the conventional direct contact system would again follow constant wet-bulb line 87. The process would start at the entering air condition 80 and approach ideal equilibrium point 84, which is on the desiccant equilibrium curve 89. For the new system, there are again two ideal exit conditions, the supply air condition 85 and the exhaust condition 86. As with the cooler, the ideal supply air temperature is the point along the constant absolute humidity line 90 that is in equilibrium with the liquid. In both cases only a fraction of the primary air stream needs to be exhausted, typically 30 to 50%, which leaves the rest as supply air.
 Air-Lift Pump: FIG. 4 shows detailed drawing of an air-lift pump that is suitable for pumping liquid desiccant and water. Air pump 100 supplies pressurized air 103 to air line 101. The air pump is preferably an aquarium pump or similar design. The air line 101 discharges inside water pipe 104 and creates a flow of air bubbles 102. The bubbles lower the average density of the fluid column which causes the air and water mixture to move upward. This upward movement draws intake water 105. On the top end a separator 108 allows outlet air 107 and outlet water 106 to discharge from the pump in separate flows. The advantages of this pump include low cost, simple design, reliability, no moving parts. This pump is excellent for handling small liquid flows with a small head requirement. A single air pump can drive many air-lift pumps an thus create many liquid circuits.
 Evaporative-Desiccant Heat Exchanger: FIG. 5 shows a heat exchanger that adds the use of a desiccant. This arrangement has eight stages of cooling, 170, 171, 172, 173, 174, 175, 176, and 177. The incoming primary air 140 enters the rightmost stage 177. It then flows through the eight stages in a straight path where it is cooled and dehumidified. The exiting primary air 141 splits into two flows. A secondary flow 142 goes back through the heat exchanger in a counter-crossflow arrangement. The remaining primary air 143 is supplied to the load.
 As shown in this figure each stage of cooling includes an evaporative pad for cooling and humidifying the secondary air and an air-to-air heat exchanger that transfers heat between the two air streams. In addition some of the stages include desiccant, which dries the primary air stream. The desiccant is preferably a liquid, such as an aqueous solution of calcium chloride, lithium chloride, lithium bromide, glycol, or similar material. Materials such as sodium hydroxide and sulfuric acid have excellent physical properties but are very corrosive and dangerous to handle. Calcium chloride is very inexpensive, has acceptable thermodynamic properties, has relatively low toxicity, and is generally the preferred desiccant material for this system.
 Starting with the rightmost stage 177 secondary air flows over evaporative pad 158 and through air-to-air heat exchanger 159. The primary air flows through the other side of the air-to-air heat exchanger 159. The flow directions of the two air streams are perpendicular to each other with the primary air going is a straight line through the heat exchanger.
 Next to the left is stage 176, which includes a desiccant 161 that is in the primary air stream. The desiccant is preferably provides a surface that is wetted by a liquid desiccant that is in direct contact with the primary air stream. The evaporative pad 56 cools and humidifies the secondary air stream. The secondary air stream cools the primary air stream in air-to-air heat exchanger 157.
 The stages 170, 175, 173, and 171 are similar to stage 177 with evaporative pads 154, 150, 146, and 144 in the secondary air stream and air-to-air heat exchangers 155, 151, 147, and 145 transferring heat between the two air streams.
 The stages 174 and 172 are similar to stage 176. They include desiccants 162 and 163 which dehumidify and increase the temperature of the primary air stream. The evaporative pads 148 and 152 cool and humidify the secondary air which cools the primary air in air-to-air heat exchangers 149 and 153.
 Mist Cooling Option: FIG. 6 is another heat exchanger configuration that uses a mist cooling system. Fan 220 draws in the main air stream 200. The air moves in a straight line through interior channels 209 in panels 208 and is cooled by evaporating water mist 205 on the outside of panels 208. The mist is supplied by nozzles 204 that are connected by way of pipe 212 to a source of pressurized water 213. The water is preferably demineralized and filtered to prevent clogging and fouling of the nozzles and the heat exchanger surfaces. As the main air stream leaves the heat exchanger, a portion of the air forms a secondary air stream 202, which returns on the wet side of the heat exchanger. Dividers 207 direct the secondary air in multipass counter crossflow arrangement as shown by the arrows. Housing 210 and wall 211 prevent undesirable air leakage. Fan 221 moves the secondary air out of the heat exchanger in exhaust stream 203. Drains 222 may be included at the bottom of the housing to remove excess water.
 Simple Solar Collector: FIG. 7 is a simple solar collector for regenerating a desiccant solution. Liquid header, 230 trickles desiccant liquid 238 over collector surface 231 which is tilted at an angle to allow drainage through trough 234. Solar radiation 233 is transmitted through cover 235 and warms the desiccant liquid 238. The collector surface is preferably black and is backed by thermal insulation 232 to maximize energy collection.
 The cover is preferably of a transparent material such as polycarbonate, polyvinyl chloride (pvc), fluoropolymers (such as Tedlar), acrylic, or other plastic. For rigid matericals, the cover may be flat or corrugated. Flexible films such as Tedlar would normally be held taught in a frame. Glass is another option for a cover material. The selection of optimum collector material depends on the cost and durability of the different materials. The duty is similar to that for greenhouses, windows, skylights, etc. with temperatures that are much lower than those for most other types of solar collectors.
 Incoming air 239 flows by natural convection between the cover and the collector surface and absorbs moisture that evaporates from the desiccant liquid. The leaving air 237 exits the collector between end piece 236 and cover 235. The end piece is shaped so as to prevent rain from entering the collector.
 The desiccant solution 238 preferably flows in a sheet that wets the entire collector surface. One way of achieving this flow is to use a screen, cloth, or other roughness on collector surface 231. Another option is to use a relatively large flow of liquid to create a continuous film of liquid. A third option is to add a detergent or other wetting agent to the solution to enhance wetting. Combinations of these three alternatives are also possible.
 The orientation of the collector is preferably such that the rays of midday summer sun is approximately normal to the collector surface. For the most of the US this corresponds to a tilt of angle of 5 to 30 degrees from horizontal towards the south. In tropical areas the collector surface can be nearly horizontal with only a few degrees of tilt to allow adequate drainage. In the Southern Hemisphere the collector is preferably tilted to face north.
 The operation of this collector is quite simple. When solar radiation is available to raise the collector surface to a temperature that is sufficiently high, desiccant liquid is allowed to flow through the collector. At other times no liquid would flow. A simple thermostat that controls the circulating pump can accomplish this control.
 This collector has several advantages. First the temperatures necessary to regenerate the desiccant liquid are quite low, in the range of about 110 to 140 degrees Fahrenheit, which allows the use of inexpensive materials such as plastic, wood, asphalt roofing material, etc. Second the operation is very simple with no moving parts. Third the collector can be mounted on an existing roof or other surface.
 While the preferred embodiment of the solar collector includes a cover, the collector would also function without a cover. The main advantages eliminating the cover are reduced cost and complexity. The collector can, in fact, be as simple as a section of dark roof or other surface with the addition of a system desiccant liquid over the surface. The chief problem with operation without a cover is that rain would tend to wash away any residual desiccant solution. The resulting diluted desiccant would have to be discarded or else it would dilute the solution in storage. Wind or leaves may also carry desiccant solution away when no cover is present. Loss of large quantities of desiccant solution is costly, may damage nearby plants or metals, and may create unsightly salt deposits on surrounding surfaces. A simple cover should greatly reduce or eliminate these problems, but it is not absolutely necessary for operation.
 In dry climates an evaporation pond is an alternative to a solar collector. A pond is an inexpensive way of regenerating a desiccant solution. The chief problems are related to control over the salt concentration. An extended rainy period can dilute the solution excessively, while long periods of dry, sunny conditions can result in crystallization. Another issue is the possibility of high winds blowing droplets of desiccant solution onto surrounding surfaces which may create problems with corrosion, plant damage, etc.
 Solar Still with Automatic Shut-Off Feature: FIGS. 8a and 8b shows a solar still with an automatic shutdown feature that can regenerate the desiccant liquid. FIG. 8a shows the still in normal operation. Solar radiation 260 warms desiccant liquid 250. Water vapor evaporates from the desiccant liquid and form condensate 252 on cover 251. The condensate trickles down the inside of the cover and collects in troughs 253 and 254. An insulated tank 256 forms the bottom and the sides of the collector and holds the desiccant liquid.
 Float 255 provides a simple control mechanism. As shown in 7a, the desiccant solution is relatively dilute, which reduces its density and causes the float to sink to the bottom of the tank 256. FIG. 8b shows a situation where the desiccant solution is quite concentrated, which increases its density and causes the float to rise to the top of the pool of desiccant liquid. Water evaporates out of any remaining desiccant liquid on the surface of the float and eventually creates a thin layer of salt crystals 257, which helps to reflect solar energy and controls the temperature inside the collector. The action of the float thus provides an automatic shutdown feature that prevents excessive crystallization of the desiccant solution.
 The float should be of nearly neutral buoyancy with respect to the desiccant solution, so that the change in solution density is enough determine whether the float rises or sinks. The float materials should be resistant to high temperatures and compatible with the desiccant solution. Foam glass, ceramics, high-temperature plastics, and metals that are compatible with the desiccant are likely choices. The float may be divided into smaller pieces to simplify handling.
 The sealed cover has the advantage of keeping ambient moisture out of the desiccant during dark or cloudy periods. A cover without a seal would allow free movement of humid air, which can add undesirable moisture to the desiccant solution.
 High-Performance Solar Collector with Electric Back-Up: FIG. 9 is a high-performance solar collector with electric backup for use in regenerating the desiccant liquid. This collector provides three stages of regeneration and would operate with peak temperatures of around 200 to 240.degree. F. The three stages of regeneration are arranged so the waste heat from higher-temperature stage drives a lower temperature stage. Desiccant liquid 301 flows from bottom header 304 over collector surface 300. Electric heater elements 302 are located just under the collector surface and provide an auxiliary source of heat. Insulation 303 prevents excessive heat loss through the back of the collector.
 The collector has three covers. The bottom cover 311 and middle cover 312 fit tightly with frames 309 and 310 to minimize air leakage. The top cover 313 has large gaps at each end, which allow for air movement under the cover. The bottom and middle covers 311 and 312 are preferably of glass or other heat resistant material. The top cover is preferably made of a tough plastic material to minimize risks of hail damage or other hazards. The top cover experiences much lower temperatures, so heat resistance is not an important issue.
 Covers 311, 312, and 313 transmit solar radiation 321 which warms collector surface 300. At night or during cloudy periods, electric heater elements 302 provide an auxiliary heat source for warming the collector surface. The warm temperatures cause moisture in the bottom stream of desiccant liquid 301 to evaporate. The water vapor thus produced is moved by convection and/or diffusion to bottom cover 311 where it condenses to form condensate 305. The condensate flows down the undersurface of bottom cover and collects in a trough formed by catch member 307 and frame 309. The condensate then flows out of the collector and can be used in an evaporative heat exchanger, as distilled drinking water, or discarded. Likewise a portion of the desiccant liquid that collects at the bottom of the collector can be returned to storage and the rest can be recirculated.
 The middle stream of desiccant liquid 317 flows from middle header 314 over the top of the bottom cover 311. The heat transmitted to the bottom cover from below evaporates moisture from the middle stream of desiccant liquid 317. The moisture condenses on the bottom surface of the middle cover 312 to form the middle condensate stream 306 which drains through the trough formed by catch piece 308.
 The top header 315 supplies the top desiccant liquid stream 316 that flows across the top surface of the middle cover 312. Moisture that evaporates from the top desiccant liquid stream 316 is removed by natural convection of air and does not normally condense on the top cover 313. Entering air 323 flows through the collector and receives the evaporating water vapor. End piece 320 prevents excessive amounts of rain from entering the collector and air leaves the collector as exhaust stream 322.
 While this figure shows an electric heater as the backup heating system other heat sources are possible. Hot water, steam, and direct heating with a fuel are also possible. The surface may be heated directly or the desiccant liquid can be heated in a separate heat exchanger. For small systems, a gas water heater may provide the heat source. The selection of the heat source would be determined by fuel cost and availability, installed cost and other factors. If electric power is used it would preferably used at night to take advantage of lower off-peak electric rates.
 The optimum collector temperatures depend on the desiccant concentration, the ambient conditions, and other factors. For calcium chloride a minimum temperature difference of about 30.degree. F. is necessary to evaporate a desiccant solution and condense the resulting water vapor. Assuming a temperature difference of about 40.degree. F. in each stage, temperature of the middle cover would be about 120.degree. F., the bottom cover would be 160.degree. F. and the collector surface would be 200.degree. F. If the peak temperature is a problem, a two-stage system can be used instead but with a performance penalty. Of course four or more stages are also possible, but the collector temperature is normally limited to the boiling point of the desiccant liquid which would be roughly 230.degree. F. or somewhat higher.
 This collector requires a means for circulating the desiccant liquid. Air-lift pumps or conventional pumps are possible alternatives. The desiccant liquid would normally be recirculated several times through the collector before returning to the storage tank. This recirculation ensures sufficient movement of liquid for adequately wetting the surfaces inside the collector without creating excessive heat loss. A heat exchanger between liquid entering and leaving the collector would further reduce heat losses, but this feature is not required for operation of the system.
 The covers need to be tilted by roughly 10 degrees or more to ensure proper drainage of condensate. Smaller angles could result in excessive drainage of condensate back into the desiccant, which would create a large performance penalty.
 The actual collector surface can be horizontal, which can allow desiccant to pool inside the collector. This arrangement allows the collector to also function as storage tank. Using a float as a shut-off control as shown earlier would be desirable for this system. This configuration may be especially desirable in tropical areas where the sun's rays are nearly vertical during much of the day.
 Preferred Embodiment: FIG. 10 is a schematic drawing of a complete solar air-conditioning system. Solar collector 400 concentrates desiccant solution using heat input from solar radiation 424 or auxiliary heat source as explained in the description of FIGS. 8A and 8B. A tank 401 stores a large quantity of desiccant solution 402. The weak desiccant solution 420 leaves tank 401 and flows through the solar collector 400 and returns as a concentrated desiccant solution 421.
 The amount of desiccant solution in the tank depends on the size and efficiency of the system and the length of operation required. A reasonable objective would be to achieve one to three days of storage capability. For a system with a rated capacity of 12,000 Btu/hr system with a 50% duty cycle over two days, corresponds to storage requirement of 288,000 Btu of cooling (24 ton-hours). For a cooling COP of 1 and heat of vaporization of 1000 Btu/lbm mean that this cooling requirement could be met by the ability to absorb 288 lbm of water vapor. For calcium chloride solution with a starting concentration of 50% and an ending concentration of 40% CaCl.sub.2 by weight, requires two pounds of calcium chloride to absorb one pound of water. This analysis means that 576 lbm of calcium chloride is required to store the required cooling. For a 40% final concentration, this corresponds to a tank capacity to handle 1440 pounds of solution or about 150 gallons.
 The energy storage density per unit volume is almost twice that of ice and requires no special insulation. With proper sealing, the tank can store this cooling capacity indefinitely with essentially zero loss. The cost of calcium chloride is on the order of $0.20/lbm so that the cost of the salt for the above example is a little over $100. The cost of storage tank is similar. These costs work out to be roughly $10 per ton-hour, which is roughly 10 to 20% of the cost of conventional ice storage or cold-water storage. This storage system thus has major cost and performance advantages compared to other systems. This inexpensive, compact storage capability combined with simple, efficient solar recharging is a tremendous improvement over the prior art.
 Theory of Operation of the Coolers: FIG. 11 shows how temperatures vary through a system for supplying outside air. The layout of the modeled system is similar to that shown in FIG. 4. This system has 12 stages. Each stage has an air-to-air heat exchanger between primary and secondary, a direct evaporative cooling section on the secondary side, and a desiccant section on the primary side. In this analysis only stages 1, 2, and 4 have active desiccant sections. The mass flow rate on the secondary air stream is approximately half of that of the primary air stream for this analysis. The entering air conditions are 95.degree. F. dry bulb and 75.degree. F. wet-bulb temperature, which is a typical design condition for the eastern US.
 The system in FIG. 11 can be used to supply outside air to laboratories or other applications that have a large outside air requirement and limitations on heat recovery or other energy-saving technologies. It has the advantage of conditioning outside air with extremely high efficiency and requires no access to exhaust air. Changes in the details of the design can give different supply-air conditions as required for a particular application.
1TABLE 1 Temperature Enthalpy Location (degrees F) (Btu/lbm) Stage Location Primary Air Stream: 500 95.0 38.6 1 Inlet 501 91.6 37.8 1 After heat exchanger 502 93.3 37.8 1 After desiccant 503 89.9 37.0 2 After heat exchanger 504 92.1 37.0 2 After desiccant 505 88.6 36.1 3 After heat exchanger 506 88.6 36.1 3 After desiccant 507 85.6 35.4 4 After heat exchanger 508 89.7 35.4 4 After desiccant 509 85.9 34.5 5 After heat exchanger 510 85.9 34.5 5 After desiccant 511 82.6 33.7 6 After heat exchanger 512 82.6 33.7 6 After desiccant 513 79.8 33.0 7 After heat exchanger 514 79.8 33.0 7 After desiccant 515 77.2 32.3 8 After heat exchanger 516 77.2 32.3 8 After desiccant 517 75.0 31.8 9 After heat exchanger 518 75.0 31.8 9 After desiccant 519 73.0 31.3 10 After heat exchanger 520 73.0 31.3 10 After desiccant 521 71.3 30.8 11 After heat exchanger 522 71.3 30.8 11 After desiccant 523 69.9 30.5 12 After heat exchanger 524 69.9 30.5 12 After desiccant (supply air) Secondary Air Stream: 525 88.1 45.9 12 After direct evaporative cooler 526 81.2 44.3 12 After heat exchanger 527 86.5 44.3 11 After direct evaporative cooler 528 79.7 42.7 11 After heat exchanger 529 85.0 42.7 10 After direct evaporative cooler 530 78.0 41.0 10 After heat exchanger 531 82.6 41.0 9 After direct evaporative cooler 532 76.7 39.6 9 After heat exchanger 533 82.2 39.6 8 After direct evaporative cooler 534 74.7 37.8 8 After heat exchanger 535 79.4 37.8 7 After direct evaporative cooler 536 72.9 36.2 7 After heat exchanger 537 77.0 36.2 6 After direct evaporative cooler 538 71.4 34.9 6 After heat exchanger 539 74.8 34.9 5 After direct evaporative cooler 540 69.9 33.7 5 After heat exchanger 541 72.9 33.7 4 After direct evaporative cooler 542 68.7 32.7 4 After heat exchanger 543 71.2 32.7 3 After direct evaporative cooler 544 67.5 31.8 3 After heat exchanger 545 69.7 31.8 2 After direct evaporative cooler 546 66.6 31.0 2 After heat exchanger 547 68.6 31.0 1 After direct evaporative cooler 548 66.0 30.4 1 After heat exchanger (exhaust)
2TABLE 2 Temperature Enthalpy Location (degrees F) (Btu/lbm) Stage Location Primary Air Stream: 600 74.0 30.2 1 Inlet 601 73.6 30.1 1 After heat exchanger 602 81.1 30.1 1 After desiccant 603 78.6 29.5 2 After heat exchanger 604 80.7 29.5 2 After desiccant 605 77.9 28.8 3 After heat exchanger 606 77.9 28.8 3 After desiccant 607 75.5 28.2 4 After heat exchanger 608 78.4 28.2 4 After desiccant 609 75.4 27.5 5 After heat exchanger 610 75.4 27.5 5 After desiccant 611 72.6 26.9 6 After heat exchanger 612 72.6 26.9 6 After desiccant 613 70.2 26.3 7 After heat exchanger 614 70.2 26.3 7 After desiccant 615 68.0 25.7 8 After heat exchanger 616 68.0 25.7 8 After desiccant 617 65.9 25.2 9 After heat exchanger 618 65.9 25.2 9 After desiccant 619 64.1 24.8 10 After heat exchanger 620 64.1 24.8 10 After desiccant 621 62.4 24.3 11 After heat exchanger 622 62.4 24.3 11 After desiccant 623 60.9 24.0 12 After heat exchanger 624 60.9 24.0 12 After desiccant (supply air) Secondary Air Stream: 625 73.2 36.0 12 After direct evaporative cooler 626 72.5 35.8 12 After heat exchanger 627 76.1 35.8 11 After direct evaporative cooler 628 71.2 34.7 11 After heat exchanger 629 75.1 34.7 10 After direct evaporative cooler 630 69.5 33.3 10 After heat exchanger 631 73.0 33.3 9 After direct evaporative cooler 632 68.2 32.1 9 After heat exchanger 633 72.3 32.1 8 After direct evaporative cooler 634 66.3 30.7 8 After heat exchanger 635 69.9 30.7 7 After direct evaporative cooler 636 64.5 29.4 7 After heat exchanger 637 67.8 29.4 6 After direct evaporative cooler 638 62.9 28.2 6 After heat exchanger 639 65.8 28.2 5 After direct evaporative cooler 640 61.4 27.2 5 After heat exchanger 641 63.9 27.2 4 After direct evaporative cooler 642 60.0 26.2 4 After heat exchanger 643 62.3 26.2 3 After direct evaporative cooler 644 58.7 25.4 3 After heat exchanger 645 60.7 25.4 2 After direct evaporative cooler 646 57.5 24.6 2 After heat exchanger 647 59.5 24.6 1 After direct evaporative cooler 648 56.7 23.9 1 After heat exchanger (exhaust)
 FIG. 12 shows air temperatures for a system for cooling return air. This system is similar to that of FIG. 11 except for the different entering-air conditions. Table 2 describes each location. This system is capable of providing a supply air temperature of 61.degree. F., which is sufficiently low to be compatible with most conventional air-distribution systems. The supply air is at about 75% relative humidity, which is sufficiently low to prevent mold growth in ducts and maintain comfortable space humidity.
 These supply-air conditions are illustrative of what is possible with this system. Changes in the details of the design can change the supply air conditions to whatever is required. For example this system is suitable for use in an application which uses a 65 to 70.degree. F. supply air temperature such as is described in my co-pending application entitled "High Efficiency Air Conditioning System with High Volume Air Distribution." Low temperature air is also possible, but with reduced performance.
 A complete cooling system is a combination of the system in FIGS. 10 and 11. The system in FIG. 12 exhausts approximately half of the return air. The system in FIG. 11 supplies the make-up air required to replace this exhaust air.
 High System Efficiency: The efficiency of these systems is quite high. For these systems the coefficient of performance (COP) is defined as cooling output divided by latent heat absorbed by the desiccant. For the system in FIG. 11, the COP is approximately 2.1. For the combined system including ventilation load the efficiency is about 1.5.
 Note that this configuration requires the introduction of outside air. If the basis of comparison is system with no outside air, then there should be no credit for the load associated with cooling the outside air to the building conditions. On this basis the system COP is approximately 0.8.
 If the desiccant is recharged using a solar collector, the collector efficiency must be considered. For the three-stage collector shown if FIG. 9, the waste heat from one stage is used to drive the next, which theoretically can triple the output of concentrated desiccant solution. In real life, the collector loss would reduce the effect. Assuming a 50% collector loss, the total system efficiency based on solar input to cooling output can exceed 2.0. This performance is much better than what is possible with expensive absorption chillers with high-performance solar collectors, which gives a system efficiency of 0.2 to 0.5 at best. This efficiency advantage translates into a massive reduction in collector cost and area required to drive the new system compared to the prior art. Even with the use of low-cost collectors such shown in FIG. 7, the new system has a massive efficiency advantage compared with the prior art.
 This high performance allows the use electric resistance as a back-up heat source. The efficiency with electric backup should be higher than that for a solar input, since transmission and reflection losses are not a factor. This means that system efficiency in the range of 2 to 3 based on electric input is possible. This efficiency is comparable to that of conventional electric air conditioners. If combined with a suitable storage system, electric back up can take advantage of inexpensive, off-peak electric rates. These rates can be as much as a factor of 10 lower than peak rates. The combination of solar input and off-peak rates can result in a massive reduction in energy cost compared to conventional systems.
 Gas Turbine Inlet Cooler: FIG. 13 shows a system for cooling inlet air to a gas turbine that uses heat from the turbine for regenerating the desiccant solution. Ambient air 701 enters a regenerative desiccant cooler 700, which cools the air. The cooler includes pumps for circulating water and desiccant solution inside the cooler. The cooler receives make up water 710 and used water 711 drains from the cooler. Exhaust fan 714 draws the exhaust air 709 from the cooler and discharges away from the turbine to prevent recirculation. The turbine inlet air 702 leaves the cooler 700 and enters the gas turbine 713. Fan 715 adds ambient air 704 to the turbine exhaust air 703 to form mixed air 705. The mixed air 705 enters regenerator 706 where it evaporates water from the desiccant solution. The regenerator comprises an extended surface that is wetted with desiccant liquid. It may be made of materials similar to that used in direct evaporative coolers. Mixing ambient air with turbine exhaust lowers the temperature of air entering the regenerator, which allows the use of inexpensive low-temperature materials. Pump 716 moves diluted desiccant solution 708 from the cooler 700 to the regenerator 706. The regenerator can include a pump or circulating desiccant liquid inside the regenerator. Concentrated desiccant 707 returns to the cooler from the regenerator. Outlet air 712 exits from the regenerator.
 This system can increase turbine output power by roughly 20 percent at summer peak conditions. The capacity gas turbine declines by about 0.4 percent per degree Fahrenheit. A 20% improvement in capacity corresponds to cooling the inlet temperature is reduced from 100 to 50.degree. F. at peak conditions. The system can also control relative humidity to the turbine. Turbine efficiency improves by roughly 0.1%/.degree. F. which corresponds to as much as 5% improvement at peak conditions. Input power for fans and pumps needed to operate the desiccant system is small and should not significantly effect these figures.
 Heat-Exchanger Details: FIGS. 14a, 14b, and 14c show an alternate gas-to-gas heat exchanger design using paper and cardboard. Sheets of paper 800 are supported between first spacers 801 and second spacers 802. The spacers are preferably made of corrugated cardboard or similar material. As shown in FIG. 14b, first spacers 801 are oriented to allow primary air stream 803 to flow the length of the paper in a single pass. Second spacers 802 are set to form multiple passes of secondary air stream 804. The whole heat exchanger is coated with a material such as linseed oil, acrylic, wax, etc. which serves as both an adhesive and a protective coating. While this drawing shows a two-pass arrangement on the secondary side, similar geometries can accommodate any number of passes. This heat exchanger construction has many applications including exhaust-air heat recovery in addition to use in evaporative and desiccant systems.
 Dehumidifer Embodiment: FIG. 15 shows another preferred embodiment that is acts as a dehumidifier. Desiccant fluid 900 is contained in an insulated container 904 and is heated by solar radiation that is transmitted through a cover 902. Moisture evaporates from the fluid and forms condensate 906 on the bottom side of the cover. The condensate flows down the underside of the cover and collects in a channel 908. The desiccant fluid moves by natural convection through channels 910 and 912 to a tank 918. An air pump 914 blows air through a tube 915 into the desiccant fluid 900 forming bubbles 916. The flow of air mixes the desiccant liquid in the tank. A fan 922 draws air over the desiccant fluid, which dehumidifies the air stream. A baffle 920 directs the air to toward the surface of the liquid. The baffle also acts to cut off air flow if the liquid level gets too high, thus preventing and overflow of desiccant liquid. A level switch may also be included to turn off the air pump and fan at high liquid levels.
 This embodiment may be useful as a small dehumidification system that can fit in a window. It may be especially useful for bathrooms or basements in homes.
 FIG. 16--Preferred embodiment with liquid-to-liquid heat exchange: FIG. 16 shows a preferred embodiment desiccant cooler with a heat exchanger between desiccant liquid and water. The system comprises a desiccant cooler 1008, a desiccant tank 1061 and a solar collector 1090. A fan 1022 draws ambient air and moves an air stream 1024 through desiccant-gas heat and mass exchanger 1012 that cools and dehumidifies the air. Air stream 1024 moves through an evaporative cooler to form a supply air stream 1026, which is enters a conditioned space 1050. A fan 1052 moves air from the conditioned space as an air stream 1028, which then moves through a water-gas heat and mass exchanger 1014. The water-gas heat and mass exchanger humidifies and adds thermal energy to the air stream to create an exhaust air stream 1030, which is discharged to the ambient. It also acts to cool water 1046, which flows through the exchanger.
 There are two liquid loops that supply these two heat and mass exchangers. A desiccant loop includes a pump 1036, which draws liquid desiccant 1018 from a reservoir 1019 and supplies it at the top of the desiccant-gas heat and mass exchanger 1012 as a drops of water 1038 that wets media that forms the exchanger. The air and desiccant are preferably in a counterflow configuration with the desiccant flowing down while the air flows upward. Desiccant collects in a drain pan 1032 and then flows through a liquid-to-liquid heat exchanger 1010. The heat exchanger 1010 cools the desiccant, which then flows back to reservoir 1019.
 The water loop is formed by a pump 1020 which draws warm water 1042 from liquid-to-liquid heat exchanger 1010, which preferably has a counterflow arrangement. Water 1046 is distributed at the top of the water-to-gas heat and mass exchanger 1014 and accumulates in a drain pan 1040 and returns to the heat exchanger 1010 as cooled water 1044. As with the desiccant side, the water and air are preferably arranged in a counterflow configuration to maximize thermal performance. Make-up water 1049 enters through a valve 1051 to replace blow-down water 1047 which drains from the system and water that evaporates. The valve 1051 may be a float valve or other device to maintain an approximately constant volume of water in the water loop.
 The solar collector 1090 comprises a cover 1068 that transmits solar radiation 1078 to warm a pool of desiccant liquid 1070. The pool of desiccant liquid is preferably is contained by a liner 1082 which is supported by a layer of support material 1072 which sits on top of a roof 1076 or other flat surface. The support material is preferably stone or ceramic granular material such as pea-sized gravel, pearlite, sand, or polystyrene foam beads. Closed-cell foam in another option. The liner is preferably made of a black plastic material such polyvinyl chloride, polyethylene, rubber such as is used in pools liners or landfill liners. It preferably includes a cloth or foam underlay for improved life and reduced heat transfer. These liners are typically about 20 to 40 mils thick and are designed to withstand years of ultraviolet radiation from the sun. A frame 1074 supports the cover 1068. The frame may be made of pressure-treated lumber or other material suitable for outdoor use. Ambient air 1080 enters the collector through holes in the frame 1074 and flow through the collector to remove moisture evaporated from the desiccant and leaves as an exhaust stream 1082. The walls formed by the liner 1082 slope slightly to allow liquid to drain to a pump 1066.
 A desiccant storage tank 1061 contains a quantity of desiccant 1060 sufficient for at least two hours of operation of the cooler 1008. The preferred quantity depends on the climate conditions, but would normally be at least sufficient to allow operation from late afternoon to the next morning when solar input is limited or not existent. A pump 1064 moves desiccant liquid to the solar collector during period when solar energy is available and the desiccant solution needs to be further concentrated. A pump 1062 moves liquid to the cooler 1008 as required to maintain a proper desiccant concentration in the cooler. An optional heat exchanger may be included between the desiccant entering the reservoir 1019 and leaving the reservoir so as to reduce thermal losses associated with the fluid transfer.
 The system preferably includes a controller 1092 that controls operations of the fans and pumps. The controller is in communication with a solar sensor 1094 and liquid-level sensor 1093. The solar sensor may comprise a black thermistor or other temperature sensor that is exposed to solar radiation. The liquid-level sensor is preferably a simple liquid-level switch. The controller also receives input from a desiccant concentration sensor 1095 that preferably comprises a float switch that closes when the desiccant density reaches a predetermined value. Other options include more sophisticated sensors such as density sensor or electrical conductivity measurements or a simple liquid level sensor.
 The controller uses the input from these two sensor to determine when operate the solar collector. When the solar sensor 1094 senses a sufficiently high temperature (about 100 to 130 F.) and the concentration sensor shows that the desiccant is sufficiently dilute, the controller turns on pump 1064 to move a quantity of desiccant to the collector 1090. Once the liquid level reaches a predetermined limit, the liquid-level sensor 1093 communicates to the controller and the control turns off the pump 1064. The collector preferably has sufficient liquid holding capacity, that in the event of a failure of the liquid level sensor would not result in overflow of desiccant liquid. The controller activates the pump 1066 and pump 1062 to periodically move concentrated desiccant back to the tank 1061, which accumulates concentrated liquid desiccant. A heat exchanger may be included between the desiccant entering and leaving the collector to improve thermal performance.
 During extended periods of very dry weather, it may be necessary to include a means for adding water to the desiccant to prevent crystallization of salt. This situation may occur in desert climates where ambient dewpoint temperatures are lower than about 55 F., but sensible cooling is still required. The water addition is preferably accomplished by diverting circulating a portion of the exhaust stream 1030 into the air entering fan 1022, which raises the dewpoint of air entering the desiccant-gas heat and mass exchanger 1012. Alternatively, the evaporative cooler 1016 may be operated without the rest of the cooler 1008 during periods of sufficiently low humidity without diverting exhaust air.
 A humidity sensor 1096 and a temperature sensor 1098, which are located in the conditioned space 1050, provide input to control the operation of the cooler 1008. The humidity sensor may be a humidistat and the temperature sensor may be a thermostat. If the temperature or humidity exceeds predetermined limits, then the controller turns on the cooler 1008. If the humidity is sufficiently low but the space is too warm, then the controller may activate the evaporative cooler 1016 to provide a lower temperature for the supply air stream 1026, otherwise the evaporative cooler is normally off.
 For good performance of the cooler 1008, it is necessary to maintain proper flow for the fluids. In a typical application, the flow rate of the air stream 1028 should be close to that for the supply air stream 1026. In addition the flows of the water and the desiccant liquid should be adjusted to maintain close the same temperature change across the heat exchanger 1010. The liquid temperature change should also be close the airside temperature changes for good performance of the heat exchangers. For simplicity, these adjustments are preferably made manually and set at a design value. Alternatively, for optimum performance, the adjustments can be made continuously with an automatic controller that receives input from appropriate temperature sensors.
 FIG. 17--Chiller embodiment: FIG. 17 shows an embodiment that is suitable for producing chilled water for air conditioning. A cooler 1100 comprises a desiccant-gas heat and mass exchanger 1104 and water-gas heat and mass exchanger 1102 in an enclosure 1112. The enclosure is preferably gas-tight and capable of withstanding atmospheric pressure when a partial vacuum is created inside. A fan 1110 circulates gas between the two exchangers. A vacuum pump 1114 draws gas 1116 from the space and discharges it to the atmosphere 1118.
 The operating pressure inside the enclosure 1112 is preferably about 1 to 5 psia. Gas filling the enclosure is mixture a mixture of air and water vapor. Lowering the atmospheric pressure has several advantages. First it greatly improves the heat- and mass-transfer coefficients. These coefficients are approximately inversely proportional to the partial pressure of the air, which means they get very large as the pressure of the gas mixture approaches the vapor pressure of the water. A second advantage is that the lower pressure reduces the thermal losses associated with circulating the gas between the two exchangers. A third advantage is that the lower pressure reduces the fan energy required to circulate the gas.
 While air is preferred for simplicity and low-cost, low-molecular-weight gas such as hydrogen or helium may be used instead to improve heat transfer, in which case gas should be recovered from the exit of the vacuum pump. While operation at below atmospheric pressure is preferred, the system can work at atmospheric pressure, but with a large performance penalty.
 Dry gas 1120 leaves the top of the desiccant-gas exchanger 1104 and enters the bottom of the water-gas exchanger 1102. The exchangers are arranged in a counterflow configuration with liquid entering at the top and gas entering as the bottom. The temperature of water drops as it flows through the water-gas exchanger 1102 and the exit temperature approaches the wet-bulb temperature of the gas entering the exchanger. Humid gas 1122 leaves the top of the water-gas exchanger 1102 and enters the bottom of the desiccant-gas exchanger 1104.
 The cooler include provisions for changing the working liquids. A pump 1136 removes a small portion of the circulating water to prevent excessive accumulation of salts. Make-up water 1134 replaces water withdrawn by the pump along with water evaporated in the water-gas exchanger 1102. Likewise a pump 1140 removes a quantity of the circulating desiccant solution, which is replaced by concentrated desiccant 1142 to ensure a proper concentration of desiccant.
 Pumped fluid transfers heat outside of the cooler. Cooled water 1126 is circulated by pump 1124 through a coil 1128. A fan 1130 moves air over the coil 1128 to cool a conditioned space 1132. A pump 1148 moves desiccant 1126 through a heat exchanger that is cooled by water from a cooling tower 1144. A pump 1146 circulates water through heat exchanger 1150 to the cooling tower 1144.
 The cooler 1100 differs from an conventional absorption chiller in that it is designed to handle a gas-vapor mixture. In conventional chillers, the systems are designed to operate with extremely low levels of non-condensable gases. Any appreciable quantity of non-condensable gas creates large heat transfer penalties because there is no fan for moving the gas across the heat exchange surfaces. By comparison the present invention uses fan and an extended heat/mass exchange surface to allow operation with a large amount of non-condensable. This ability to handle large quantities of non-condensable gas greatly improves the ability to use storage of desiccant and regeneration of desiccant at atmospheric pressure without special concerns about contact with air.
 The present cooler is designed to take advantage of a temperature glide inherent in a gas-vapor mixture. In a conventional absorption chiller, the vapor pressure of the evaporator and the absorber is a single value. In contrast, air or other non-condensable gas allows the vapor pressure to vary, while maintaining close to a constant total pressure. This difference increases the available temperature lift from the desiccant by an amount that roughly corresponds to the temperature change of the cooling water across the absorber.
 The optimum performance of the cooler 1100 occurs when the temperature change of each fluid is approximately the same value. This setup minimizes the temperature drop through each heat exchanger and improves the temperature lift capability.
 For calcium chloride the maximum available temperature lift (entering desiccant temperature minus leaving chilled water temperature) is about 25 F. For temperatures lifts greater than this amount a two-stage system or a different desiccant is required.
 For climates with relatively low design wet-bulb temperatures (such as those in California), the cooler should be able to provide sensible cooling in a single-stage configuration. For example, for a design wet-bulb temperature of 70 F., a leaving cooling-tower water temperature of 75 F. is reasonable (5 F. approach temperature). A temperature of 77 F. for the desiccant leaving heat exchanger 1148 should allow a water temperature to the coil of about 60 F., which should allow a supply air temperature of about 68 F. This setup is especially suitable for use with the air conditioning system described in U.S. Pat. Nos. 6,405,543 and 6,185,943, which use high-temperature air distribution system with separate dehumidification.
 FIGS. 18 and 19--Rotating Embodiment: FIGS. 18 and 19 show an alternate embodiment of a cooler with rotating heat exchangers, which preferably comprises multiple stages. FIG. 18 shows a detail of a single stage. A pipe 1200 encloses a first direct-contact heat exchanger 1202. The interior of the pipe also contains a liquid, preferably the desiccant 1210 with end pieces 1206 that prevent leakage from the ends.
 A second direct-contact heat exchanger 1212 is located around the outside of pipe 1202. Tubing 1208 is wrapped around the second direct contact heat exchanger and is connect at each end through fittings 1204 and 1205 to the inside of pipe 1202. The bottom portion of the tubing and the second direct-contact heat exchanger sit in pool of liquid, which is preferably water, which is located below liquid level line 1214.
 The whole assembly rotates as a unit, which provides a means for circulating the liquids. Liquid desiccant 1210 enters into tube 1208 through fitting 1204. The rotation and the force of gravity move the desiccant through the tubing and it eventually returns to the inside of pipe 1200 through fitting 1205. The turning action also submerges portions of the first direct-contact heat exchanger in desiccant 1210 and portions of the second direct-contact heat exchanger 1212 into water located below liquid line 1214. These setup allows circulation of liquid for heat and mass transfer without the use of a pump.
 FIG. 19 shows a multi-stage assembly for this cooler. A first, second, and third stage 1244, 1246, and 1248 are all connected together a rotate as a unit. Each stage has a geometry that is similar to that in FIG. 18. Pans 1241 are connected together with tubes 1242 and are filled with water. Make up water 1254 enters the pan for the first stage 1244 and blow-down water 1252 exits the pan for the third stage. Rollers 1242 support the stages and allow them to rotate freely. A motor 1260 that is connected to the rotating stages by a shaft 1262 turns the assembly. Ambient air 1270 is drawn by fan 1250 and moves through the desiccant side of the stages. Supply air 1272 exits the first stage and cools a conditioned space 1264. Return air 1274 flow through the waterside of the assembly and exits as exhaust air 1276. While three stages are shown the cooler may use twelve or more stages, depending on the design requirements.
 Alternate thermal-energy input: While solar energy input is preferred in many applications, there are situations where solar is not practical because of space limitations, climate, or other factors. In those situations the preferred embodiment uses an alternate source of thermal energy. While natural gas or other fuel is one alternative, availability and/or cost may limit its use. Another alternative is to use waste heat from a conventional vapor-compressor or absorption refrigeration system.
 Resistance heat from off-peak electricity is yet another alternative. The system can regenerate the desiccant at night or on weekends during periods of low electric prices for use during periods of high electric prices.
 For these systems without solar input, no collector is required. Instead a regenerator, preferably with multiple stages of regeneration, may be included. Various arrangements similar to those found in the prior art for distillation of seawater, absorption chillers, etc. are possible. For a regenerator that is limited to atmospheric pressure and peak temperatures of about 200 to 250 F., three stages of regeneration should be possible with calcium chloride. This temperature and pressure is achievable using relatively inexpensive and corrosion-resistant material such as plastic and ceramic in the construction of the regenerator.
 For more stages, higher pressures and temperatures are required. Theoretically ten stages or more of regeneration are possible. More stages of regeneration increase cost and complexity of the regenerator, but improve the efficiency of the system. The optimum design depends on material costs, pressure-vessel code considerations, cost of the thermal input, temperature limits of available materials, and so on.
 FIGS. 20A, 20B, and 20C, Heat Exchanger: This figure shows a heat exchanger that is suitable for use in a cooler that will be described in detail later in FIG. 23. The idea is to create a flow path for water or other liquid through channels formed by a plastic enclosure. A first enclosure 1320 is preferably approximately rectangular.
 FIG. 20A shows a flat cutout of the first enclosure before assembly. The material of construction is preferably a plastic sheet, such as polyethylene, that is strong, water-tight, and weldable or heat sealable. Possible materials include woven polyethylene (such as Dupont's Tyvek) with a suitable impermeable heat-seal coating, high-density polyethylene, linear polyethylene, polypropylene. Preferred material thickness is approximately 1 to 10 mils, although thicker materials or thinner are possible depending on the size of the heat exchanger and the properties of the material. Metal is also an option, though not preferred. The material is preferably inflated by the weight of the liquid, but formed pieces with the desired shape for channels are also possible. A fold line 22 is preferably an axis of symmetry. FIG. 20B shows the enclosure after it is folded and joined together using a heat welding to form an outer seal 1324 and bonds 1328 and bonds 1326. The bonds are preferably form by heat welding using a bag sealer or similar equipment.
 FIG. 20C shows the heat exchanger after it is filled with liquid. The weight of the liquid acts to inflate the heat exchanger. A top surface of a first liquid 1330 is below the top of the plastic enclosure 1320. Entering liquid 1332 forms a stream of liquid 1336 that leaves the heat exchanger as exiting liquid 1340. An external fluid 1340 flows over the surface of the heat exchanger. The external fluid preferably flows horizontally over the heat exchanger in a direction that is approximately counter that of the liquid inside the heat exchanger. Natural convection is also an option. The external fluid may be air or another liquid depending on the particular requirements. A base 1342 supports the heat exchanger.
 Alternatively the liquid inside the heat exchanger may be replaced with gas and the surrounding fluid would be a liquid, in which case the heat exchanger would be inverted in order to trap the gas. Likewise, if the surrounding fluid by a liquid that were immiscible with the liquid inside the heat exchanger and the orientation of the heat exchanger would depend on the relative densities of the two liquids.
 FIGS. 21A, 21B, and 21C, Liquid-To-Liquid Heat Exchanger: FIGS. 21A, B, and C show an embodiment that uses the heat exchanger of FIGS. 20A, B, and C as a component to form a liquid-to-liquid heat exchanger that can also exchange heat with a gas, such as air. The basic idea is to use a second enclosure 1350 that fits around the heat exchanger shown in FIGS. 20A, B, and C. As shown in FIG. 21A, the enclosure 1350 is approximately rectangular with provision for drain members 1380 and 1382. As with the first enclosure, a fold line 1352 is an axis of symmetry.
 An important difference between the enclosures is that the distance from the fold line 1352 to the top and bottom edge of the blank is smaller for the second enclosure than that for the first enclosure. This will allow liquid to fill the second enclosure without deflating the first.
 FIG. 21B shows a top view a filed heat exchanger that includes the second enclosure and FIG. 21C shows a side view of the same heat exchanger. The first liquid 1330 fills the inside of the first enclosure 1320. A second liquid 1360 fills the second enclosure 1350. Exiting first liquid 1390 leaves to the right and exiting second liquid 1392 leaves to the left. A spacer 1360 allows multiple heat exchangers to be placed side-by-side while allowing free flow of air over the outside surface. An outer seal 1354 seals the second enclosure. Bonds 1358 attach the second enclosure to the first. The result is a heat exchanger that closely approximates counterflow for the two liquids.
 FIG. 22, Heat Exchanger Assembly: FIG. 22 shows a cross-section of heat exchanger assembly that includes multiple heat exchangers as shown in FIGS. 21A, B, and C. An air stream 1450 flows horizontally through the heat exchanger through passages 1454 formed between spacers 1456. A first liquid 1450 flows approximately counter to that of a second liquid 1452, which flows approximately counter cross flow to that of the air stream 1450. An enclosure 1458 supports the liquid enclosures and provides a flow path for the air.
 Liquids enter through a manifold that that distributes the liquid and exit through a drain. As shown in FIG. 22, the second liquid enters through a manifold 1462 and a drain 1464 draws the first fluid as it leaves one end of the heat exchanger.
 FIG. 23, Cooler Using the Heat Exchanger in FIG. 22: FIG. 23 shows a schematic diagram of a cooler that uses the heat exchanger in FIG. 22. A fan 1401 moves an outside air stream 1400 through a heat exchanger 1402 that is of the type described in FIG. 22. A cooled air stream 1412 leaves the heat exchanger 1402 and enters a first heat and mass transfer device 1404. The first heat and mass transfer dehumidifies and cools the air further to form a supply air stream 1414 that enters a conditioned space 1406. The conditioned space is normally a building, but could also be a food storage compartment or other enclosure. An optional evaporative cooler may be included in the supply air stream to lower the temperature of the air before it enters the conditioned space, if maximum sensible cooling is required. A return air stream 1416 flows through a second heat and mass transfer device 1408 and exits as an exhaust stream 1418.
 The cooler uses two liquid circuits. A pump 1427 moves warm desiccant liquid leaves first heat and mass transfer devise 1404 and enters the heat exchanger 1402. Cooled desiccant liquid 1426 leaves the heat exchanger 1402 and circulates to goes through the first heat and mass transfer device 1404 to complete one circuit. A concentrated desiccant solution 1421 is added and a diluted desiccant solution 1419 is removed from the circuit to keep the proper desiccant concentration.
 Water is the liquid in the second circuit. Cooled water 1424 drains from the second heat and mass transfer device 1408 and enters the heat exchanger 1402. A pump moves warm water form the heat exchanger 1402 to the second heat and mass transfer device 1408 to complete the second circuit. Make-up water 1427 is added replace blow-down water 1425 that carries away excess minerals to prevent excessive formation of a scale and other fouling problems.
 Careful design of the quantity and distribution of fluid flows is important for optimum operation of this system. The fan and pumps are preferably variable capacity with the flows matched so that the temperature changes of the air and the liquids are approximately the same. In addition the effectiveness of the heat exchanger and the heat and mass transfer devices should be as high as possible, which requires a close approximation to counter flow and even distribution of fluid throughout the heat exchanger.
 Alternatively, multiple heat exchangers and/or heat and mass transfer devices in series can be used in place of a single exchange device. Another approach is to use multiple stages of cooling to reduce the effectiveness requirements. These approaches allow for performance that is less sensitive to distribution problems, but at the expense added complexity and probably an increase in overall cost.
 The heat and mass transfer devices are preferably direct-contact liquid-to-gas heat exchangers that also allow for mass transfer. Evaporative pads or cooling tower fill materials are suitable for the exchange surface. Selection of material of construction should consider the corrosive effects of desiccant material and potential for scaling and biological fouling with water.
 One advantage of this system is that it can act as an efficient indirect evaporative cooler. The outside air is cooled by water that is in turn cooled by evaporation into the exhaust air stream. This configuration allows the supply-air temperature to approach the ambient dewpoint, with the need for operating the desiccant loop. This feature reduces the need for regeneration of desiccant and can prevent problems with crystallization of desiccant during dry weather conditions.
 Advantages Summary: Overall this invention has many advantages over the prior art:
 1) Simple, low-cost, reliable designs
 2) Counter cross flow configuration reduces cost an achieves good performance
 3) Evaporative system with the ability to approach the dewpoint temperature
 4) Desiccant system can act as a heat pump to raise supply air temperatures
 5) Ability to use low-cost, safe, desiccants such as calcium chloride for air-conditioning
 6) Compact energy, inexpensive, low-cost, energy-storage capability in the form of a concentrated desiccant solution
 7) Low-cost solar regeneration
 8) Ability to use off-peak electricity for back-up or alternate to solar
 9) Ability to separate the wet portions of the system so as to allow easy replacement
 10) Use of reliable, low-cost air-lift pumps which allow the use of many different liquid circuits
 11) Extremely high efficiency possible
 12) Simple controls
 13) Ability to use readily available components
 14) Low-cost paper-based or plastic heat exchangers
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