EP3710136A1

EP3710136A1 - Method and device for obtaining water from ambient air

Info

Publication number: EP3710136A1
Application number: EP18807242.5A
Authority: EP
Inventors: Philippe Verplancke
Original assignee: Aquahara Technology GmbH
Current assignee: Aquahara Technology GmbH
Priority date: 2017-11-16
Filing date: 2018-11-15
Publication date: 2020-09-23
Also published as: MA50894A; WO2019096898A1; DE102017127012A1; CN112020390A; US20200346164A1; AU2018368539A1; CL2020001219A1

Abstract

The invention relates to a method for obtaining water from ambient air (14), said method having at least the following steps: bringing the ambient air (14) into contact with at least one liquid absorption agent (16) in order to absorb at least part of the water contained in the ambient air (14); conveying an absorption agent (18) diluted by the absorbed water to a first heat exchanger (20); and transferring the diluted absorption agent (18) into at least one desorption device (30). Water (42) desorbed in the desorption device (30) is conveyed to the first heat exchanger (20), wherein the desorbed water (42) is cooled by means of the first heat exchanger (20) using the diluted absorption agent (18). The invention additionally relates to a device (10) for obtaining water from ambient air (14).

Description

Process and apparatus for recovering water from the

ambient air

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 e.g. Lithium chloride. Subsequently, by heating He, 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, which is soaked with the salt solution, so that there

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 are used, the aim of these methods is the dehumidification and not the extraction of liquid water from the ambient air. From WO 2009/135618 A1 a method and a device 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.

DE 10 2013 013 214 A1 also describes a device for obtaining 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. The heat generated by the condensation of water following the evaporation / distillation of the brine must be dissipated into the environment. For this purpose, separate cooling devices are used in conventional systems in the line system after the capacitor, which in turn increase the cost of equipment.

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: supplying a water vapor generated by at least one evaporator from a dilute liquid absorbent to a condenser, the condenser comprising at least one heat exchanger for condensing the water vapor; Conveying at least one cooling medium to the heat exchanger and conveying the emerging from the condenser and heated cooling medium to at least one device for large-scale contacting the cooling medium with the ambient air for cooling the cooling medium by means of the ambient air. By the invention Procedure, first, a cooling of the capacitor is ensured without additional separate cooling devices. In addition, the heated cooling medium is again supplied to the device for large-area contacting of the cooling medium with the ambient air for cooling. As a result, the process is simple and inexpensive to operate and requires less energy than known methods. In advantageous embodiments of the method according to the invention, the steps of feeding and conveying the cooling medium to form a cooling circuit are performed several times. In addition, there is the possibility that the multiple implementation of the steps of feeding and conveying the cooling medium takes place in a predetermined time interval, in particular during the day. In this case, the cooling of the cooling medium by spraying the cooling medium in the ambient air and / or by means of a passage of the ambient air through the device having a large surface, take place.

The term "cooling medium" is understood to mean any kind of liquids with low vapor pressure.

In further advantageous embodiments of the method according to the invention, the cooling medium is the absorbent diluted by the absorbed water of the ambient air, wherein at least a portion of the diluted absorbent in at least one separate flow circuit is supplied to the evaporator with or without the interposition of a reservoir. Advantageously, by means of a solution, both the water taken up from the ambient air can be conducted to the evaporator and, on the other hand, the condenser can be cooled. Thus, the inventive method can be operated extremely inexpensively. The liquid absorbent may be at least one hygroscopic salt solution or a mixture of different hygroscopic salt solutions his. 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. The term "conveying" means an active conveying, for example by means of at least one pump, but also conveying by means of gravity. But it is also possible that the cooling medium is a liquid with low vapor pressure, in particular an oil. This has the advantage that the heat exchanger arranged inside the condenser can also consist of non-corrosion-resistant and thus usually more favorable material. If the dilute absorbent is not used as the cooling medium, this will be promoted in a separate flow loop from a dilute absorbent flow loop. Thus, unwanted mixing or contamination of the different media can be reliably avoided.

In further advantageous embodiments of the method according to the invention, the diluted absorbent is supplied to the evaporator with or without the interposition of a reservoir. There is thus the possibility that the method according to the invention provides for delivery and storage and storage of the diluted absorbent obtained from the ambient air in the at least one storage container. At the evaporation structure of the evaporator, a concentration of the diluted absorbent to obtain a concentrated absorbent, wherein the concentrated absorbent of the device in contact with the ambient air for large-scale contacting the cooling medium with the ambient air - supplied - with or without the interposition of a heat exchanger can be. In this case, the (concentrated) concentrated absorbent in the reservoir cached and in a predetermined time interval, in particular at night, the device, which then serves as an absorption structure, are supplied. 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 a further advantageous embodiment of the invention

Method, the cooling medium before being conveyed to the condenser in at least one of the device for large-scale contacting the ambient air with the cooling medium downstream buffer transferred. This advantageously results in the possibility of individual, in particular time-dependent, control of the quantities of cooling medium supplied to the condenser.

In a further advantageous embodiment of the invention

Method is taken at least a portion of the desorptierten water in the direction of flow after the capacitor via at least one suitable device from the system cycle. This avoids, on the one hand, that the amount of water in the system steadily increases due to the continuous condensation of water in the desorption device. So that the water cycle does not overflow, at least part of this desorptierten water is removed continuously or at predetermined times. The present invention further relates to an apparatus for recovering water from an ambient air, the apparatus comprising at least one evaporator for generating water vapor from a dilute absorbent, at least one condenser operatively connected to the evaporator, the condenser including at least one heat exchanger for condensing the water vapor comprises at least one conveying device for conveying a cooling medium to the heat exchanger for cooling the condenser and means for conveying the cooling medium exiting and heated from the condenser to at least one device for contacting the cooling medium with the ambient air over a large area for cooling the cooling medium by means of the ambient air. By means of the device according to the invention, cooling of the capacitor is initially possible without additional external and separately arranged cooling devices. In addition, the heated cooling medium is again supplied to the device for large-area contacting of the cooling medium with the ambient air for cooling. This results on the one hand a very simple and inexpensive construction of the device, on the other hand, requires a relatively low energy consumption for operation. The term "cooling medium" is understood in turn any type of liquids with low vapor pressure.

In further advantageous embodiments of the device according to the invention, the cooling medium is the dilute absorption solution, wherein the device according to the invention has at least one separate flow circuit to the evaporator with or without the interposition of a reservoir and at least a portion of the diluted absorption solution is fed to the evaporator. The absorption solution may in turn be at least one hygroscopic saline solution or a mixture of different hygroscopic saline solutions. By the device according to the invention Advantageously, by means of a solution, namely the diluted absorption solution, both the water taken up from the ambient air can be led to the evaporator and, on the other hand, the condenser can be cooled. Thus, the device according to the invention can be operated extremely inexpensively. Under 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 absorbent may be, for example, lithium chloride solutions. However, there is also the possibility that the cooling medium is a liquid with a low vapor pressure, in particular an oil. This, in turn, has the advantage that the heat exchanger arranged inside the condenser can also consist of non-corrosion-resistant and therefore usually more favorable material. If the diluted absorption medium is not used as the cooling medium, the device according to the invention comprises at least one separate flow circuit for conveying the cooling medium, separate from a flow circuit of the dilute absorption medium. Thus, unwanted mixing or contamination of the different media can be reliably avoided.

In a further advantageous embodiment of the device according to the invention this comprises at least one of the device for large-area contacting the cooling medium with the ambient air downstream buffer for the cooling medium. This advantageously results in the possibility of individual, in particular time-dependent, control of the quantities of cooling medium supplied to the condenser. In further advantageous embodiments of the device according to the invention, the device has means for controlling a conveying of the cooling medium in a predetermined time interval. As a result, the operation of the device according to the invention can be individually controlled and adapted to the parameters encountered on site.

In a further advantageous embodiment of the invention

Device comprises the device for large-scale contacting the cooling medium with the ambient air at least one spray nozzle and / or at least one honeycomb structure and / or at least one absorption structure and / or at least one plate structure. Other structures are conceivable, and these also have to provide on the one hand the largest possible cooling surface and / or absorption surface. In a further advantageous embodiment of the invention

Device, the device comprises at least one device for removing the desorptierten water from the system circuit. In this case, this removal device can be arranged after the capacitor. By at least partially removing the desorptierten water on the one hand ensures that the water cycle in the device does not overflow, on the other hand, the removed water can be used for other purposes. The removal of desorptierten water can be done continuously or at predetermined times. Further features of the invention will become apparent from the claims, the

Embodiments and with reference to the drawings. The features and combinations of features mentioned above in the description as well as the features and feature combinations mentioned below in the exemplary embodiments are not only given in the respectively indicated Combination, but also usable in other combinations, without departing from the scope of the invention.

It shows

Figure 1 is a schematic representation of an inventive

Device according to a first embodiment; and

Figure 2 is a schematic representation of an inventive

Device according to a second embodiment.

Figure 1 shows a schematic representation of a device 10 for recovering water from an ambient air 26. The apparatus 10 comprises in the illustrated first embodiment, a device (not shown) for dispensing a liquid absorbent 16 on an absorbent structure 12. The absorbent structure 12 provides in the illustrated first embodiment is also an apparatus for large-scale contacting a cooling medium, as will be explained in detail below. For application of the liquid absorbent 16, a suitable pipe system with corresponding openings or valves or similar spray devices can be used. The liquid absorbent 16 is thereby distributed in particular over an entire upper surface of the absorbent structure 12 and so impregnates the absorbent 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 collected by a tray system 18 again becomes. It can be seen that in the illustrated embodiment, the absorption structure 12 is honeycomb-shaped. This results in a very large surface at which an absorption of at least part of the water contained in the ambient air take place can. The absorption of the water from the ambient air 26 takes place in the liquid absorbent 16, wherein the resulting heat of condensation is released by the large surface of the honeycomb absorbent structure 12 of the absorbent 16 immediately back to the ambient air 26. By absorbing water from the ambient air 26, the liquid absorbent 16 is diluted and exits the absorbent structure 12 as a dilute absorbent 20.

In the illustrated embodiment, the ambient air 26 is brought into contact with the liquid absorbent 16 over a large area. The liquid absorbent 16 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 flowed through by natural wind. This saves energy and installation costs, as no additional blowers are needed. However, should the natural wind conditions not allow a sufficiently large flow of ambient air 26 through the absorbent structure 12, of course, appropriate tools, such as blower 14 may be used in addition. The absorbent structure 12 is to 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 the Known specialist and shown in the figure only in one embodiment.

These are, inter alia, a conveying device or pump 22 for conveying the absorbent 20 diluted by the absorbed water to an evaporator 34. It can be seen that in the line path between the pump 22 and the evaporator 34 there is a reservoir 60 for intermediate storage of the diluted absorbent 20 is arranged. But there is also the possibility that the diluted absorbent is fed directly to the evaporator 34. In the direction of flow after the reservoir 60, a valve 28 is arranged.

In the evaporator 34, a heat exchanger 36 is also arranged, which is liquid-conductively connected via a line system 38 to a solar module 42. Other heat transfer systems may be disposed in the evaporator 34. In the line system 38 circulates a moving means of a pump 40 heat transfer fluid. For this purpose, the solar module 42 has a line system, which may consist of an ideally corrosion-resistant material, in particular plastic. By means of the heat exchanger 36, heating and / or evaporation of at least part of the water contained in the diluted absorbent 20 heated by the solar module 42 takes place.

The evaporator 34 is connected via a line system 44 liquid-conducting with the reservoir 60. The reservoir 60 also serves to receive the now concentrated absorbent. For this purpose, the reservoir 60 is formed, for example, as a stratified storage, so that there is no mixing of the diluted absorbent 20 with the now concentrated absorbent 16. With the semicircular arrows is indicated that this construction a cycle for the diluted or later concentrated absorbent results. By repeatedly passing through the circuit comprising the reservoir 60 and the evaporator 34 results in a high yield of water vapor and a further concentrated absorbent. 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 42 can be operated particularly efficiently. At night, that is to say at usually lower temperatures, the concentrated absorbent can then be reintroduced into the absorbent structure 12 via a pump 70 and a liquid conduit arranged between the reservoir 60 and the absorbent structure 12, so that water can be absorbed by the absorbent 16 again This results in the dilute absorbent 20, which in turn is collected in the sump 18.

Furthermore, it can be seen that the evaporator 34 is connected via a line system 48 medium-conducting with a capacitor 52. Between the evaporator 34 and the condenser 52, a mist eliminator 50 is also arranged. The droplet separator 50 reliably separates the particles formed in the evaporator 34 and carried by the water vapor formed, such as salt particles, even before the water vapor enters the condenser 52. The condenser 52 comprises a heat exchanger 54 which serves to cool the condenser 52 and thus also to increase the condensation of the steam introduced. Other heat transfer systems may be disposed in the condenser 52. It can be seen that the heat exchanger 54 is connected to a line system 62. Via the line system 62 and a pump 66 disposed therein, the diluted absorbent 20 is at least partially passed through the heat exchanger 54. After leaving the Capacitor 52, the diluted absorbent 20 is again passed over the absorbent structure 12. Since the temperature of the diluted absorbent 20 is significantly lower than the temperature within the condenser 52, cooling of the condenser 52 takes place via the heat exchanger 54. The diluted absorbent 20 heated after exiting the condenser 52 is then cooled again via the absorption structure 12. In addition, there is the possibility that the absorbent 20 receives additional amounts of water from the ambient air 26. In the illustrated embodiment, a collecting container 64 is formed in front of the pump 66. In particular, the quantities of diluted absorbent 20 that are fed to the condenser 52 can thus be regulated. Furthermore, it can be seen that the dilute absorbent 20 can circulate multiple times in the conduit system 62 and the absorbent structure 12. This is indicated in the figure 1 by the corresponding semi-circular arrows.

This cooling process is carried out according to the embodiment shown mainly during the day, since the temperature difference between the diluted absorbent 20 and the water collected by the condenser 52 is highest here.

The condensed water is discharged from the condenser 52 and received in a downstream collecting container 58. The removal of the water can be controlled by a pump 56. The water thus obtained can be removed from the collecting container 58 by means of suitable devices.

Furthermore, it can be seen that within the evaporator 34 as well as within the condenser 52 by means of a vacuum device 32, a negative pressure to support the supply of the evaporated water to the Capacitor 52 and to assist in the evaporation of the heated, diluted absorbent 20 is provided.

In addition, the device 10 has means for controlling a conveyance of the liquid, diluted absorbent or the cooling medium 20 in a predetermined time interval to predetermined elements of the device 10. In this way, 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 26 can occur alternately or simultaneously during the day. All these pumps would then run simultaneously. In order to avoid high heat losses in this case, at least one heat exchanger for heat recovery can then be arranged in the supply and return of the absorbent 16, 20 in the absorption cycle. For example, there is the possibility in the line system between the evaporator 34 and a reservoir for receiving and storing the concentrated, coming from the evaporator absorbent to arrange a heat exchanger. This heat exchanger would then be in operative connection, for example, with a further line system, which starts from a second storage container for receiving the relatively cool diluted absorbent (not shown). This results in a relatively inexpensive method for preheating the diluted absorbent to be introduced into the evaporator.

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 proposed in the present invention or saline solutions 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.

Figure 2 shows a schematic representation of an apparatus 10 for recovering water from an ambient air 26 according to a second embodiment. The device 10 according to the second embodiment is basically the same as the device 10 according to the first embodiment. In this respect, like reference numerals in Figure 2 denote the corresponding same features in Figure 1. In contrast to the first embodiment shown in Figure 1, the device 10 here has two separate circuits for a cooling medium 80 and the diluted liquid and the concentrated absorbent 20, 16th on. This is particularly due to the fact that in the illustrated embodiment, the cooling medium 80 is an oil, which should not mix with the diluted absorbent 20. It will be appreciated that the diluted absorbent 20 is again collected in a containment system 18 and diluted with water from the ambient air 26 via the absorbent structure 12 by spraying the more concentrated liquid absorbent, respectively. Via the line system 24 and the pump 22 arranged therein, the diluted absorbent is again supplied to the evaporator 34 with the interposition of the reservoir 60. Via the evaporator 34 formed in the heat exchanger 36, which is arranged in the conduit system 38 of the solar module 42, the diluted absorbent 20 is heated in the evaporator 34 and evaporated. The concentrated absorbent 16 is in turn fed via a line system 44 and a pump 46 arranged therein, with the interposition of the reservoir 60 and the line system 68 emanating therefrom, and the pump 70 arranged therein, to the absorption structure 16. A second circuit, namely a cooling circuit for the condenser 52, is formed by the line system 62 and the pump 66 arranged therein as well as the heat exchanger 54 arranged in the condenser 52. It can be seen that the cooling medium 80 is used in the said circuit and by flowing through the heat exchanger 54 for cooling the condenser 52. The cooling medium 80, namely an oil in the illustrated embodiment, is in turn passed via the line system 62 via the device 72, wherein in the device 72, the cooling medium 80 is cooled by means of the ambient air 26. To enhance this effect, a fan 74 is arranged in the illustrated embodiment in the region of the device 72. The thus cooled cooling medium 80 is collected in a collecting container 76 and, if necessary, fed to the line system 62. In line system 62, in turn, a collecting container 64 is arranged, wherein among other things, the amount of cooling medium 80, which is to be supplied to the heat exchanger 54, can be controlled by the collecting container 64.

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.

Claims

Claims:

A method for recovering water from an ambient air (26), the method comprising at least the following method steps:

Supplying a water vapor generated by at least one evaporator (34) from a dilute liquid absorbent (20) to a condenser (52), the condenser (52) comprising at least one heat exchanger (54) for condensing the water vapor;

Conveying at least one cooling medium (20, 80) to the heat exchanger (54); and

Conveying the cooling medium (20, 80) exiting the condenser (52) to at least one device (12, 72) for contacting the cooling medium (20, 80) over a large area with the ambient air (26) for cooling the cooling medium (20, 80 ) by means of the ambient air (26).

2. The method according to claim 1,

characterized,

in that the steps of feeding and conveying the cooling medium (20, 80) are carried out several times to form a cooling circuit.

3. The method according to claim 2,

characterized,

in that the multiple execution of the steps of feeding and conveying the cooling medium (20, 80) takes place in a predetermined time interval, in particular during the day.

4. The method according to any one of the preceding claims,

characterized, in that the cooling of the cooling medium (20, 80) takes place by spraying the cooling medium (20, 80) in the ambient air (26) and / or by passing the ambient air (26) through the device (12, 72).

5 method according to one of the preceding claims,

characterized,

in that the cooling medium is the absorbent (20) diluted by the absorbed water of the ambient air, wherein at least part of the diluted absorbent (20) is supplied in at least one separate flow circuit to the evaporator (34) with or without the interposition of a reservoir (60).

6 method according to claim 5,

characterized,

the absorbent (20) is at least one hygroscopic saline solution or a mixture of different hygroscopic saline solutions. 7 Method according to one of claims 1 to 4,

characterized,

the cooling medium (80) is a liquid with a low vapor pressure, in particular an oil. 8 method according to claim 7,

characterized,

the cooling medium (80) is conveyed in a separate flow circuit from a flow circuit of the dilute absorbent (20).

9. The method according to claim 8,

characterized,

that the diluted absorbent (20) with or without the interposition of a reservoir (60) to the evaporator (34) is guided.

10. The method according to any one of claims 5 to 9,

characterized,

in the evaporator (34), a concentration of the dilute absorbent (20) to obtain a concentrated one

Absorbent (16), wherein the concentrated absorbent (16) of the device (12) for large-area contacting of the absorbent (16) with the ambient air (26) is supplied, wherein the device (12) serves as an absorbent structure.

1 1. A method according to claim 10,

characterized,

in that the concentrated absorbent (16) is temporarily stored in the reservoir (60) and in a predetermined time interval, in particular at night, of the device (12) with or without

Intermediate circuit of a heat exchanger is supplied.

12. The method according to any one of the preceding claims,

characterized,

the cooling medium (20, 80) downstream of the condenser (52) before being conveyed into at least one of the devices (12, 72)

Latch (64) is transferred.

13. The method according to any one of the preceding claims,

characterized, in that at least part of the desorpted water is removed from the system circuit in the direction of flow downstream of the condenser (52) via at least one suitable device. 14. Device (10) for recovering water from an ambient air

(26)

at least one evaporator (34) for generating water vapor from a dilute liquid absorbent (20); at least one condenser (52) operatively connected to the evaporator (34), the condenser (52) comprising at least one heat exchanger (54) for condensing the water vapor;

at least one conveying device (66) for conveying a cooling medium (20, 80) to the heat exchanger (54) for cooling the condenser (52); and

Means for conveying the cooling medium (20, 80) exiting the condenser (52) to at least one device (12, 72) for contacting the cooling medium (20, 80) with the ambient air (26) over a large area to cool the cooling medium (20 , 80) by means of the ambient air (26).

15. Device according to claim 14,

characterized,

the cooling medium is a liquid absorbent (20) diluted by the absorbed water of the ambient air (26), and the

Device (10) at least one separate flow circuit to the evaporator (34) with or without the interposition of a reservoir (60), wherein at least a portion of the diluted absorbent (20) is fed to the evaporator (34).

16. The device according to claim 15,

characterized,

the absorbent (20) is at least one hygroscopic saline solution or a mixture of different hygroscopic saline solutions.

17. Device according to claim 14,

characterized,

the cooling medium (80) is a liquid with a low vapor pressure, in particular an oil.

18. Device according to claim 17,

characterized,

in that the device (10) has at least one flow circuit separate from a flow circuit of the dilute absorbent (20)

Promotion of the cooling medium (80) includes.

19. Device according to one of claims 14 to 18,

characterized,

in that the device (10) comprises at least one of the device (12, 72) for contacting the cooling medium (20, 80) with the surrounding air (26) over a large area (64) for the cooling medium (20, 80). 20. Device according to one of claims 14 to 19,

characterized,

in that the device (10) comprises means for controlling a delivery of the cooling medium (20, 80) in a predetermined time interval. 21. Device according to one of claims 14 to 20, characterized,

in that the device (10) comprises at least one device for removing the desorpted water from the system circulation. 22. Device according to one of claims 14 to 22,

characterized,

in that the device (12, 72) for contacting the cooling medium (20, 80) with the ambient air (26) over a large area has at least one spray nozzle and / or at least one honeycomb structure and / or at least one absorption structure and / or at least one

Plate structure includes.