DE102017127011A1 - Method and device for obtaining water from the ambient air - Google Patents

Abstract

The present invention describes a method for obtaining water from an ambient air, the method comprising at least the following method steps: conveying a liquid absorbent (20) diluted by means of water absorbed from the ambient air to and through at least one solar module (28), wherein the absorbent ( 20) serves as a heat transfer medium of the solar module (28); Transfer of the at least one solar module (28) heated and diluted absorbent (20) in at least one evaporator (34), wherein the evaporator (34) at least one evaporation structure (36) and at and / or in the evaporation structure (32) a Evaporation of at least a portion of the water contained in the heated, dilute absorbent (20); and returning the absorbent to the at least one solar module (28). The invention further relates to a device (10) for recovering water from an ambient air (14).

Description

The present invention relates to a method for recovering water from an ambient air. The invention further relates to a device for recovering water from an ambient air.

Such methods and apparatus for recovering water from ambient air are known in a wide variety. In particular, corresponding absorption methods are known from the dehumidification technique. Moisture from the air is absorbed in so-called liquid desiccants, for example in concentrated, hygroscopic salt solutions. A highly hygroscopic salt is eg lithium chloride. Subsequently, by heating, vacuum distillation, reverse osmosis or similar methods, the water is partially removed again from the salt solution, so that the solution can be used again for dehumidifying the air. Industrially, this process is offered, for example, by Kathabar (see http://www.kathabar.com/liquid-desiccant/system-features-benefits). Other systems, for example, marketed under the name "Ducool" direct process air by means of a blower through a honeycomb structure soaked with the saline solution so that water vapor from the air is absorbed by the cool and concentrated saline solution. A separate regeneration air stream is passed through the honeycomb impregnated with the warm salt solution. In this case, part of the water evaporates again from the salt solution and the water vapor is removed from the regeneration air. The above methods can be used for the construction of an atmospheric water generator, the aim of these methods being the dehumidification and not the recovery of liquid water from the ambient air. From the WO 2009/135618 A1 For example, a method and apparatus for recovering water from the ambient air is known.

All the above-mentioned methods and devices disadvantageously have a very high energy input, in particular of electrical energy. If one were to supply the known atmospheric water generators exclusively with regenerative energy, for example in desert regions, this would mean the need for a very large area of photovoltaic modules with a correspondingly high cost per liter of recovered water. So far, therefore, for the operation of the known systems with evaporators heat from the following sources used: combustion of fossil fuels, with the known disadvantages for the environment; conventional thermal solar modules, often even with vacuum tubes, in order to achieve correspondingly high temperatures and with correspondingly high investment costs; and condensation heat in the process of so-called vapor compression, which in turn requires a lot of electrical energy.

The heat generated by the condensation of water following the evaporation / distillation of the brine must be dissipated into the environment. For this purpose, heat exchangers, typically gas / gas heat exchangers, for example plate heat exchangers (cross-flow or countercurrent heat exchangers) or cooling devices are used in conventional systems, which in turn increase the system costs.

Also the DE 10 2013 013 214 A1 describes a device for recovering water from atmospheric air with a flowable sorbent for sorption of the water. In an evaporator, the absorbed water is removed from the so-diluted sorbent by evaporation. In the evaporator while the dilute sorbent is subjected to negative pressure. In Sorbtionsweg at least one heat exchanger is arranged as a preheating unit. However, a disadvantage of this prior art is that a more expensive, corrosion-resistant heat exchanger is always used as the preheating unit for the diluted sorbent.

It is therefore the object of the present invention to provide a generic method and a generic device which are easier and less expensive to operate or manufacture and require less energy input than known methods and devices.

To achieve these objects is a generic method according to the features of claim 1 and a device according to the features of claim 14. Advantageous embodiments with expedient developments of the invention are specified in the respective dependent claims, wherein advantageous embodiments of the method as advantageous embodiments of the device and to look at the other way around.

A method according to the invention for obtaining water from an ambient air comprises at least the following method steps: conveying a liquid absorbent diluted by means of the ambient air to and through at least one solar module, wherein the absorbent serves as a heat transfer medium of the solar module and transferring the heated by the at least one solar module and diluted absorbent in at least one evaporator, wherein the evaporator comprises at least one evaporation structure and at and / or in the evaporation structure evaporation of at least a portion of the water contained in the heated, diluted absorbent occurs. Advantageously, in the method according to the invention can be dispensed with a heat exchanger in Sorbtionsweg before the solar module and the evaporator. As a result, the process is simple and inexpensive to operate and requires less energy than known methods. The diluted absorbent is fed directly, ie without the interposition of a heat exchanger, a corresponding line system within the solar module. The diluted liquid absorbent serves as a heat transfer fluid or solar fluid in the solar module. The heating of the diluted absorbent increases the efficiency of evaporation of the absorbed water within the evaporator. As a result, the amounts of water obtained from the ambient air can be significantly increased. The vaporization structure is designed such that large-area evaporation of the water contained in the heated, diluted absorbent occurs. For example, honeycomb structures may be used for the vaporization structure. Since the vaporization structure is formed with a large surface area, evaporation of the water contained in the diluted and heated absorbent may occur at relatively low temperatures. Cost-intensive arrangements for improving the evaporation rate at the evaporation structure can advantageously be dispensed with. The term "liquid absorbent" is understood to mean any type of liquid desiccant that leads to absorption of at least part of the water contained in the ambient air in the absorbent. The liquid absorbents may in particular be salt solutions, such as, for example, a lithium chloride solution or mixtures of different salt solutions. The terms "conveying" and "transferring" mean an active conveying or transferring, for example by means of at least one pump, but also conveying or transferring by means of gravity.

In further advantageous embodiments of the method according to the invention, the absorbent is returned from the evaporator to the at least one solar module. The steps of conveying, transferring and returning the absorbent can be carried out several times. In particular, the multiple execution of the steps of conveying, transferring and returning the absorbent in a predetermined time interval, in particular during the day, take place. This ensures a particularly high rate of heating as well as desorption of the absorbent or the absorbed water. The return of the absorbent to the at least one solar module can also be done with the interposition of at least one reservoir, wherein the reservoir is liquid-conductively connected to the evaporator and the solar module. Furthermore, according to the invention there is the possibility that the method comprises a delivery to and a recording and storage of the recovered from the ambient air diluted absorbent in the at least one reservoir. The dilution structure of the evaporator is subjected to concentration of the diluted absorbent to obtain a concentrated absorbent, whereby the concentrated absorbent can be supplied to an absorbent structure in contact with the ambient air with or without the interposition of a heat exchanger. In this case, the (concentrated) concentrated absorption medium can be temporarily stored in the storage container and fed to the absorption structure in a predetermined time interval, in particular at night. Advantageously, this embodiment of the method according to the invention utilizes the different daytime and nighttime temperatures to optimize the process flow, as the temperature difference between absorption and desorption increases with increasing day-night temperature difference and thus the water yield per unit volume of salt solution increases or a lower salt concentration in the absorbent is needed. Both processes (absorption and desorption) can also occur alternately or simultaneously during the day. The absorption and desorption cycle can be controlled via the inflow and outflow of the diluted and / or concentrated absorbent to and from the storage container as a buffer.

In further advantageous embodiments of the method according to the invention, the diluted absorbent is obtained by contacting the ambient air with a liquid and higher concentrated absorbent via spraying the absorbent in the ambient air or by passing the ambient air through an absorbent structure soaked with the absorbent. This ensures that the ambient air is brought into contact with the liquid absorbent over a large area. In the case of the use of an absorbent structure impregnated with the absorbent, honeycomb structures or other large-area structures are used over which the absorbent can flow and which are flowed through and / or around the ambient air. Other structures are conceivable, it should be ensured that the ambient air is always brought into contact over a large area with the liquid absorbent. As a result of the mentioned method steps, the greatest possible absorption of the water contained in the ambient air is ensured.

In further advantageous embodiments of the method according to the invention, the water evaporated by means of the evaporation structure is supplied to at least one condenser. In this case, the capacitor may comprise at least one condensation structure for the condensation of the water vapor.

In this case, the condensation structure may be impregnated with water for condensation of the water vapor. By these measures, the invention ensures that at least a majority of the evaporated water condenses on the condensation structure and can be removed as liquid water from the condenser. The condensation structure in turn has the largest possible surface, as is fulfilled, for example, by a honeycomb structure. But other structures are conceivable. In further advantageous embodiments of the method according to the invention, a negative pressure to support the supply of the evaporated water to the condensation structure and within the evaporator, a negative pressure in support of the evaporation of the heated, diluted absorbent is applied within the capacitor. Advantageously, this also increases the efficiency of the process.

In a further advantageous embodiment of the method according to the invention at least a portion of the desorptierten water is removed in the flow direction after the capacitor via at least one suitable device from the system cycle. As a result, it is avoided on the one hand that the amount of water in the system steadily increases due to the continuous condensation of water in the condenser. So that the water cycle does not overflow, at least part of this desorptierten water is removed continuously or at predetermined times.

In a further advantageous embodiment of the method according to the invention, at least a portion of the water obtained by means of the condenser is fed to a heat exchanger arranged downstream of the condenser, whereby by means of the heat exchanger cooling of the recovered water by means of at least a portion of the diluted absorbent obtained by the absorption structure and the cooled, recovered water is fed to the condenser for cooling and / or impregnation of the condensation structure. As a result, it is possible according to the invention to dispense with additional, expensive cooling devices.

The present invention further relates to a device for obtaining water from an ambient air comprising at least one conveying device for conveying an absorbent diluted by means of the ambient air to and through at least one solar module, wherein the absorbent serves as a heat transfer medium of the solar module, and the solar module fluidly with at least one evaporator is connected, wherein the evaporator comprises at least one evaporation structure and takes place at and / or in the evaporation structure evaporation of at least part of the water contained in the heated by the solar module, the diluted absorbent. The inventive design of the device can be dispensed with a heat exchanger in Sorbtionsweg before the solar module and the evaporator. As a result, the device is simple and inexpensive to operate and manufacture. It requires less energy input than known devices. The diluted absorbent is injected directly, i. supplied without the interposition of a heat exchanger, a corresponding line system within the solar module. The diluted liquid absorbent serves as a heat transfer fluid or solar fluid in the solar module. The line system and / or other elements of the solar module advantageously consist of a corrosion-resistant material, in particular plastic. The heating of the diluted absorbent increases the efficiency of evaporation of the absorbed water within the evaporator. As a result, the amounts of water obtained from the ambient air can be significantly increased. The vaporization structure is designed such that large-area evaporation of the water contained in the heated, diluted absorbent occurs. For example, honeycomb structures may be used for the vaporization structure. Since the vaporization structure is formed with a large surface area, evaporation of the water contained in the diluted and heated absorbent may occur at relatively low temperatures. Cost-intensive arrangements for improving the evaporation rate at the evaporation structure can advantageously be dispensed with. Thus, the device according to the invention on the one hand can be produced inexpensively and easily and also a lower energy consumption is needed.

As already stated, the term "liquid absorbent" is used for all types of liquid desiccants that can serve to absorb at least part of the water contained in the ambient air. The liquid absorbent may be, for example, a hygroscopic saline solution or a mixture of such saline solutions. The term "conveying" means an active conveying, for example by means of at least one pump, but also conveying by means of gravity.

In further advantageous embodiments of the device according to the invention, the evaporator is liquid-conducting with or without interposition of at least one storage container for receiving a recirculated from the evaporator absorbent, connected to the solar module. This can be done a return of the absorbent from the evaporator to the at least one solar module. The result is a delivery cycle of the absorbent. The conveying, transferring and recycling of the absorbent can be carried out several times. In particular, the multiple execution of the steps of conveying, transferring and returning the absorbent in a predetermined time interval, in particular during the day, take place. This ensures a particularly high rate of heating as well as desorption of the absorbent or the absorbed water. Furthermore, according to the invention there is the possibility that the reservoir receives and / or stores the diluted absorbent obtained from the ambient air. Furthermore, there is a possibility that a dilution of the dilute absorbent may occur at the evaporation structure of the evaporator to obtain a concentrated absorbent, whereby the concentrated absorbent may be supplied to an absorbent structure in contact with the ambient air with or without the interposition of a heat exchanger. In this case, the (concentrated) concentrated absorption medium can be temporarily stored in the storage container and fed to the absorption structure in a predetermined time interval, in particular at night. Advantageously, this embodiment of the device according to the invention uses the different daytime and nighttime temperatures to optimize the process flow, as the temperature difference between absorption and desorption increases with increasing day-night temperature difference and thus the water yield per unit volume of the salt solution increases or a lower salt concentration in the absorbent is needed. Both processes (absorption and desorption) can also occur alternately or simultaneously during the day. The absorption and desorption cycle can be controlled via the inflow and outflow of the diluted and / or concentrated absorbent to and from the storage container as a buffer.

The absorption structure is designed to absorb at least part of the water contained in the ambient air. In doing so, the diluted absorbent is obtained by contacting the ambient air with the liquid and higher concentrated absorbent via spraying the absorbent in the ambient air or by passing the ambient air through the absorbent structure soaked with the absorbent. This ensures that the ambient air is brought into contact with the liquid absorbent over a large area. In the case of the use of an absorbent structure impregnated with the absorbent, honeycomb structures or other large-area structures are used over which the absorbent can flow and which are flowed through and / or around the ambient air. Other structures are conceivable, it should be ensured that the ambient air is always brought into contact over a large area with the liquid absorbent. The passage of the ambient air can be enhanced by means of suitable devices, for example blowers.

In further advantageous embodiments of the device according to the invention, the evaporator is medium-conductively connected to at least one condenser, wherein the condenser has at least one condensation structure for condensing the water evaporated by means of the evaporating structure. The condensation structure can be soaked in water. This technical embodiment ensures according to the invention that at least a majority of the evaporated water can be condensed on the condensation structure and removed as liquid water from the condenser. The condensation structure in turn has the largest possible surface, as is fulfilled, for example, by a honeycomb structure. But other structures are conceivable. The formation of large surfaces increases the yield of water vapor or water both at the evaporation structure as well as the condensation structure. In addition, it is ensured that the said operations can be carried out efficiently at relatively low temperatures. Furthermore, there is the possibility that at least one droplet separator is arranged downstream of the evaporator and upstream of or in the condenser. Due to the mist eliminator, escaping salt particles are reliably removed from the water vapor from the evaporator. Contamination of the water obtained by the device according to the invention by this particle is thus reliably prevented.

In a further advantageous embodiment of the device according to the invention this comprises at least one arranged downstream of the condenser heat exchanger, wherein at least a portion of the water obtained by the condenser is cooled in the heat exchanger by at least a portion of the obtained by the absorbent structure diluted absorbent and the cooled water the Condenser for cooling and / or impregnation of the condensation structure is supplied. Due to the at least partial return of the desorpted water from the Ambient air can be dispensed with additional water sources. This ensures cost-effective extraction of the water from the ambient air.

In further advantageous embodiments of the device according to the invention, this device comprises means for generating a negative pressure in the evaporator and / or the condenser. By the mentioned design possibilities. The means for generating a negative pressure on the one hand support the evaporation of the heated, diluted absorbent in the evaporator and promote the supply of water vapor to the condensation structure in the condenser.

In a further advantageous embodiment of the device according to the invention, the device comprises at least one device for removing the recovered / desorptierten water from the system cycle. In this case, this removal device can be arranged in the flow direction after the capacitor. By the at least partial removal of the recovered / desorptierten water on the one hand ensures that the water cycle in the device does not overflow, on the other hand, the extracted water can be used for other purposes. The removal of desorptierten water can be done continuously or at predetermined times.

In further advantageous embodiments of the device according to the invention, this device comprises means for controlling a conveying, transferring and the return of the absorbent in a predetermined time interval to predetermined elements of the device. As a result, the device according to the invention can be optimally, i. be operated with in particular the external conditions adaptive parameters.

Further features of the invention will become apparent from the claims, the embodiment and the drawings. The features and combinations of features mentioned above in the description as well as the features and combinations of features mentioned below in the exemplary embodiments can be used not only in the particular combination specified, but also in other combinations, without departing from the scope of the invention.

The figure shows a schematic representation of a device according to the invention.

The device 10 for recovering water from an ambient air 68 includes in the illustrated embodiment, a device (not shown) for dispensing a liquid absorbent 16 on an absorption structure 12 , For applying or applying the liquid absorbent 16 a suitable pipe system with appropriate openings or valves or similar spray devices may be used. The liquid absorbent 16 is in particular over an entire upper surface of the absorbent structure 12 distributes and so impregnates the absorption structure 12 , The absorbent 16 then flows slowly into the lower regions of the absorbent structure 12 where it flows out of this again and through a tub system 18 is caught again. It can be seen that in the illustrated embodiment, the absorption structure 12 is honeycomb-shaped. This results in a very large surface at the absorption of at least a portion of the ambient air 68 contained water can take place. The absorption of water from the ambient air 68 takes place in the liquid absorbent 16 , wherein the resulting heat of condensation through the large surface of the honeycomb absorbent structure 12 from the absorbent 16 immediately back to the ambient air 68 is delivered. By absorbing water from the ambient air 68 becomes the liquid absorbent 16 diluted and occurs as a diluted absorbent 20 from the absorption structure 12 out.

In the illustrated embodiment, the ambient air 68 large area with the liquid absorbent 16 brought into contact. With the liquid absorbent 16 it is at least one hygroscopic saline solution or a mixture of different saline solutions. For example, a concentrated lithium chloride solution is used. The absorption structure 12 can be designed such that it can be set up outdoors and can be traversed by natural wind. This saves energy and installation costs, as no additional blowers are needed. However, should the natural wind conditions not sufficiently large flow of ambient air 68 through the absorption structure 12 Of course, appropriate tools, such as blowers, can be used 14 additionally be used. The absorption structure 12 should be chosen with suitable permeability, suitable thickness and suitable size. Such structures are available, for example, in a robust and protected against decomposition carton design very inexpensive and are nowadays used for example in the evaporative cooling of chicken coops.

In the further description of the embodiment, the straight lines provided with arrows represent fluid conduits, such as tubes or hoses, in which the fluids used in the device flow in the direction of the arrow. The necessary pumping devices are known in the art and shown in the figure only in one embodiment.

It is the conveyor or pump 22 for conveying the absorbent diluted by the absorbed water 20 to a solar module 28 , It can be seen that in the conduction path 24 between the pump 22 and the solar module 28 a storage container 60 for intermediate storage of the diluted absorbent 20 is arranged. But there is also the possibility that the diluted absorbent 20 directly to the solar module 28 is supplied. In the flow direction to the reservoir 60 is another pump 26 arranged that from the reservoir 60 effluent dilute absorbents 20 to the solar module 28 and passes through it. The solar module 28 has for this purpose a conduit system which consists of a corrosion-resistant material, in particular plastic. Also other elements of the solar module 28 exist in the illustrated embodiment of plastic and are compared to the diluted absorbent 20 corrosion-resistant. The diluted absorbent 20 serves as heat transfer fluid of the solar module 28 , After a corresponding warming in the solar module 28 becomes the now heated dilute absorbent 20 via a pipe system 30 in an evaporator 34 brought in. This is the solar module 28 liquid-conducting with the evaporator 34 connected. In addition one recognizes that the evaporator 34 an evaporation structure 36 wherein at and / or in the vaporization structure 36 an evaporation of at least a portion of the in by the solar module 28 heated, diluted absorbent 20 contained water takes place. The evaporation structure 36 is honeycomb-shaped in the illustrated embodiment, so as to provide the largest possible evaporation surface.

The evaporator 34 is again via a pipe system 40 fluid-conducting with the reservoir 60 connected. The storage tank 60 also serves to hold the now concentrated absorbent. For this purpose, the reservoir is formed, for example, as a layer memory, so there is no mixing of the diluted absorbent 20 with the now concentrated absorbent 16 comes. The semicircular arrows indicate that this construction results in a circulation for the diluted or later concentrated absorbent. About a repeated cycling through the reservoir comprising 60 , Solar module 28 and evaporator 34 results in a high yield of water vapor and a further concentrated absorbent 16 , Per circulation, the yield of water vapor from the absorbent can be about 5 to 10%. The said cycle is carried out in particular during the day, since here the solar module 28 can be operated particularly efficiently. At night, that is usually at lower temperatures then the concentrated absorbent 16 via a pump 62 and a liquid-conducting between the reservoir 60 and the absorption structure 12 arranged pipe system 64 back into the absorption structure 12 be introduced so that in turn water through the absorbent 16 can be absorbed and thereby the diluted absorbent 20 arises, which in turn in the sump 18 is caught.

Furthermore one recognizes that the evaporator 34 via a pipe system 38 medium conducting with a capacitor 44 connected is. Between the evaporator 34 and the capacitor 44 is also a mist eliminator 42 arranged. The mist eliminator 42 separates them in the evaporator 34 formed and carried by the resulting water vapor particles, such as salt particles, even before the entry of water vapor into the condenser 44 , dependable. The capacitor 44 again has a condensation structure 46 on, which is honeycomb-shaped and thus forms a very large surface. The condensed water is removed from the condenser 44 discharged and in a downstream collection container 48 added. The water thus obtained can from the collecting container 48 be removed by means of suitable devices. In the illustrated embodiment is also shown that at least a portion of the recovered water via a conduit system 50 and one in the pipe system 50 arranged pump 52 to a heat exchanger 54 is directed. The heat exchanger 54 is also with the collection container 18 liquid-conducting via a pipe system 56 connected. In the pipe system 56 is a pump 58 arranged, which when operated the diluted absorbent 20 through the heat exchanger 54 conducts and thus that from the capacitor 44 or the collection container 48 originating water cools. The cooled water can in turn via a pipe system 66 the capacitor 44 for impregnation of the condensation structure 46 be supplied. The diluted absorbent 20 is after exiting the heat exchanger 54 again via a pipe system 56 the absorption structure 12 fed. This cooling process is carried out mainly during the day, since here the temperature difference between the diluted absorbent 20 and through the capacitor 44 recovered water is highest.

Furthermore, one recognizes that inside the evaporator 34 and inside the capacitor 44 by means of a vacuum device 32 a negative pressure to assist the supply of the evaporated water to the condensation structure 46 and in support of evaporation of the heated, dilute absorbent 20 is provided.

In addition, the device 10 Means for controlling delivery, transfer and return of the absorbent at a predetermined time interval to predetermined elements of the device 10 on. Thus, the water extraction process can be optimally adapted to the ambient conditions, in particular the temperature conditions. For example, both the absorption and the desorption of the water from the ambient air 68 run alternately or at the same time during the day. All these pumps would then run simultaneously. In order to avoid high heat losses in this case, can then in the flow and return of the absorbent 16 . 20 be arranged in the absorption cycle at least one heat exchanger for heat recovery.

In order to produce drinking water from the opted-out water, a filtration and disinfection process or a mineralization process may have to be stored downstream. These processes are state of the art. It should be noted that the concentrated absorbents or salt solutions proposed in the present invention already have a strong disinfecting effect. The mineralization of the water extracted from the air could for simplicity be done by passing the water through a gravel bed.

It should be made clear at this point that the term "water vapor" describes the gaseous state of aggregation of water and not a mixture of air and water droplets.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• WO 2009/135618 A1 [0002]
• DE 102013013214 A1 [0005]

Claims (25)

Process for obtaining water from an ambient air, the process comprising at least the following process steps: Conveying a liquid absorbent (20) diluted by means of absorbed water from the ambient air to and through at least one solar module (28), the absorbent (20) serving as a heat transfer medium of the solar module (28); and Transferring the absorbent (20) heated and diluted by the at least one solar module (28) into at least one evaporator (34), wherein the evaporator (34) comprises at least one evaporation structure (36) and / or in the evaporation structure (32) an evaporation of at least part of the water contained in the heated, diluted absorbent (20) takes place. Method according to Claim 1 , characterized in that the absorbent (20) from the evaporator (34) is recycled into the at least one solar module (28). Method according to Claim 1 or 2 , characterized in that the steps of conveying, transferring and returning the absorbent are performed several times. Method according to Claim 3 , characterized in that the multiple implementation of the steps of conveying, transferring and returning the absorbent takes place in a predetermined time interval, in particular during the day. Method according to one of the preceding claims, characterized in that the return of the absorbent to the at least one solar module (28) with the interposition of at least one reservoir (60), wherein the reservoir (60) liquid-conducting with the evaporator (34) and the solar module (28) is connected Method according to Claim 5 , characterized in that the method comprises a promotion, absorption and storage of the recovered from the ambient air diluted absorbent (20) to the at least one reservoir (60). Method according to one of the preceding claims, characterized in that on the evaporation structure (36), a concentration of the diluted absorbent (20) to obtain a concentrated absorbent (16), wherein the concentrated absorbent (16) of an absorbent structure in contact with the ambient air (12) is supplied with or without the interposition of a heat exchanger. Method according to Claim 7 , characterized in that the concentrated absorbent (16) is temporarily stored in the storage container (60) and supplied to the absorption structure (12) in a predetermined time interval, in particular at night. Method according to one of the preceding claims, characterized in that the diluted absorbent (20) by contacting the ambient air with a liquid and higher concentrated absorbent (16) by spraying the absorbent (16) in the ambient air or by passing the ambient air through an absorption structure (12) impregnated with the absorbent (16) is obtained. Method according to one of the preceding claims, characterized in that the vaporized by means of the evaporation structure (36) water is supplied to at least one capacitor (44). Method according to Claim 10 , characterized in that the condenser (44) comprises at least one condensation structure (46) for condensing the water vapor. Method according to Claim 10 or 11 characterized in that a vacuum is applied within the condenser (44) to assist in feeding the vaporized water to the condensation structure (46) and within the evaporator (34) a vacuum to assist in vaporization of the heated dilute absorbent (20) , Method according to one of Claims 10 to 12 , characterized in that at least part of the by means of the capacitor (44) desorptierten water in the flow direction after the capacitor (44) via at least one suitable device is removed from the system circuit. Method according to one of Claims 10 to 13 , characterized in that at least a portion of the water obtained by means of the condenser (44) is supplied to a heat exchanger (54) arranged downstream of the condenser (44), wherein by means of the heat exchanger (54) cooling of the recovered water by means of at least one part the diluted absorbent (20) obtained through the absorbent structure (12) is provided and the cooled water is supplied to the condenser (44) for cooling and / or impregnating the condensation structure (46). Apparatus (10) for obtaining water from an ambient air comprising at least one conveying device (26) for conveying a by means Absorbed from the ambient air absorbed water absorbent (20) to and through at least one solar module (28), wherein the absorbent (20) serves as a heat transfer medium of the solar module (28), and the solar module (28) fluidly connected to at least one evaporator (34) wherein the evaporator (34) comprises at least one vaporization structure (36) and at and / or in the vaporization structure (32) evaporation of at least a portion of the water contained in the dilute absorbent (20) heated by the solar module (28) he follows. Device after Claim 15 , characterized in that the evaporator (34) liquid-conducting with or without the interposition of at least one reservoir (60) for receiving one of the evaporator (34) recirculated absorbent, with the solar module (28) is connected. Device after Claim 15 or 16 , characterized in that the liquid absorbent (16) is a hygroscopic saline solution or a mixture of different saline solutions. Device according to one of Claims 15 to 17 characterized in that the device (10) comprises at least one device for applying and / or directing a liquid absorption medium (16) not diluted by ambient water to and / or to an absorption structure (12), the absorption structure (12 ) is formed for absorbing at least part of the water contained in the ambient air. Device according to one of Claims 15 to 18 , characterized in that the solar module (28) at least one conduit system for receiving the diluted absorbent (20), wherein the conduit system and / or other elements of the solar module (28) made of a corrosion-resistant material, in particular plastic. Device according to one of Claims 15 to 19 , characterized in that the evaporator (34) is medium-conducting connected to at least one capacitor (44), wherein the capacitor (44) has at least one condensation structure (46). Device after Claim 20 , characterized in that in the flow direction after the evaporator (34) at least one droplet separator (42) is arranged. Device after Claim 20 or 21 characterized in that the device (10) comprises at least one heat exchanger (54) arranged downstream of the condenser (44), at least part of the water obtained by means of the condenser (44) in the heat exchanger (54) passing through at least part of the water cooled by the absorption structure (12) diluted absorbent (20) is cooled and the cooled water is supplied to the condenser (44) for cooling and / or impregnation of the condensation structure (46). Device according to one of Claims 15 to 22 , characterized in that the device (10) comprises means for generating a negative pressure in the evaporator (34) and / or the condenser (44). Device according to one of Claims 15 to 23 characterized in that the device (10) comprises means for controlling delivery, transfer and return of the absorbent at a predetermined time interval to predetermined elements of the device (10). Device according to one of Claims 15 to 24 , characterized in that the device (10) comprises at least one device for removing the desorptierten water from the system cycle.

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