KR20110068976A - Device and method for drying an air stream - Google Patents

Abstract

The device for dehumidifying the air flow comprises at least one first module 7 with at least one Peltier element 13 and at least one second module 8 with at least one Peltier element 13. Include. The entire first module 7 forms a first zone 4 for cooling the air stream. The entire second module 8 forms a second zone 5 for dehumidifying the air stream. The entirety of the first module 7 and the second module 8 form air channels for air flow. The drainage channel 9 is arranged under the entire second module 8 and receives water from the second zone 5 upon dehumidification of the air stream. At least one sensor 30 transmits at least one output signal for the measurement of the temperature and / or humidity of the air flow. A controller having at least one controller controls the Peltier element 13 based on at least one output signal of at least one sensor 30.

Description

DEVICE AND METHOD FOR DRYING AN AIR STREAM

The present invention relates to an apparatus and method for dehumidifying an air stream.

Such a device may be used in an air conditioner to dehumidify one or a plurality of air streams circulating in such a device. Air conditioning systems are also to be understood as the term air conditioner.

The present invention seeks to develop an airflow dehumidifier that operates as efficiently as possible.

This object is achieved through the features of claims 1 and 5. Preferred forms are specified in the dependent claims.

An apparatus for dehumidifying an air stream includes an air channel having an inlet through which air to be dehumidified is supplied and an outlet through which dehumidified air is discharged. The air channel according to the invention is divided into at least two zones, and at the end of the first zone it is possible to control the temperature of the first zone so that the air flow is cooled to a dew point temperature or slightly above the dew point temperature corresponding to the air flow. And temperature control of the second zone is possible such that the air flow in the second zone discharges moisture as water.

The material and / or surface structure of the side walls defining the air channel is preferably formed differently in the first zone and the second zone.

The air channel is illustratively divided into at least four zones, the temperature of the third zone being able to be removed so that the air flow in the third zone discharges moisture as water and the waste heat generated in the third zone is the air flow of the fourth zone. Supplied to.

The temperature control of the third zone is preferably via at least one Peltier element. In operation, the cold Peltier element face cools the third zone and in operation the hot face heats up the fourth zone.

Preferably the temperature control of the air channel sidewalls is via a Peltier element controlled by a controller having at least two controllers. The first controller controls one Peltier element or a plurality of Peltier elements in the first zone such that the air flow is cooled in the first zone without condensation of water, and the second controller allows the second stream to release water in the second zone. One Peltier element or a plurality of Peltier elements in the zone are controlled.

Correspondingly, the method according to the invention for dehumidifying the air stream comprises the following steps:

a) allowing the air stream to flow through the first zone, where the air stream is cooled such that at the end of this zone its temperature reaches a value corresponding to dew point temperature or slightly above the dew point temperature.

b) allowing the air stream to flow through the second zone, where the air stream is cooled to the extent that water condenses.

To achieve this, the temperature of the first zone side wall must be higher than the air flow dew point temperature, which is determined according to its current temperature and current relative humidity, and the temperature of the second zone side wall must be lower than the "local" dew point of the air flow. It should be noted that the dew point temperature of the air stream decreases as it progresses along the second zone since the air stream condenses moisture as water. The dew point temperature in the second zone varies from place to place and is therefore referred to as the "local" dew point temperature.

Preferably, the process is carried out with the following additional steps, i.e. cooling to or below the local dew point temperature, allowing the air stream to flow through the third zone where the water is condensed and then the air stream is heated by the heat generated in the third zone. Flowing an air stream through the fourth zone.

The present invention has the effect of providing an airflow dehumidifier that is operated as energy as efficiently as possible.

The invention is illustrated in detail by the following examples and figures. The drawings are schematic and not to scale.
1 shows a schematic diagram showing the structure of the device according to the invention for dehumidification of an air stream as well as the method according to the invention for dehumidification of an air stream.
2 shows a Mollier diagram.
FIG. 3 shows an enlarged partial view of the Molle diagram of FIG. 2 and an example of a dehumidification process.
4 shows a schematic perspective view of an embodiment of a device for dehumidification of an air stream.
5 shows the individual parts of the first module.
6 shows a side view of the details of the first module.
7 shows a perspective view of a first module.
8 shows the individual parts of the second module.
9 shows a perspective view of a second module.
10 shows individual parts of a second part of another embodiment.
11 shows a circuit diagram for the control of the device according to FIG. 4.

1 shows a schematic diagram showing on the one hand the structure of a device according to the invention for dehumidification of an air stream and on the other hand a method according to the invention for dehumidification of an air stream. The device comprises an air channel with an inlet 1 through which air to be dehumidified and an outlet 2 through which dehumidified air is discharged. The air flow is shown through arrow 3. The air channel is divided into two zones 4, 5 or four zones 4, 5, 6A, 6B as shown, the zones being directly next to each other or slightly spaced from each other. The first zone 4 functions to cool the supplied air stream, which is cooled to a temperature slightly above the dew point temperature or dew point temperature at the end of the first zone 4. The dew point temperature is the temperature of the wet air in saturated water vapor, which corresponds to the temperature at which water condenses. The dew point temperature is therefore the temperature of wet air with an air relative humidity phi of 100 percent. In the first zone 4 the air is mainly cooled and no water condenses. It is also possible for some water to condense already at the end of the first zone 4 on condition that water condensation does not cause a rundown. This is for example the case when the temperature is below the dew point temperature, which may of course appear because the temperature must be controlled. The second zone 5 functions to further cool and dehumidify the air stream. Moisture is removed from the air stream and condensed with water. Water reaches the drain channel. The temperature of the second zone 5 should therefore be below the local dew point temperature of the air stream throughout. The third zone 6A and the fourth zone 6B are optional and serve to heat the dehumidified cold air stream to the desired temperature in an efficient manner. The use of these two zones depends on how the air conditioner operates.

The device also comprises at least one sensor for operating the device in a method according to the invention described below. At least one sensor is used to measure the temperature and / or relative humidity of the air flow.

Correspondingly, the method according to the invention for dehumidifying the air stream comprises the following steps:

a) flowing the air stream through the first zone (4), in which the airflow is such that at the end of the zone (4) its temperature reaches a value corresponding to the dew point temperature or slightly above the dew point temperature; Is cooled.

b) flowing the air stream through the second zone (5), in which the air stream is cooled to dew point temperature to the extent that water condenses.

c) Optionally, the air stream is cooled to dew point temperature to allow air flow through the third zone 6A where water is condensed, and then the air stream is heated by heat generated in the third zone 6A. Allowing air flow through zone 4B.

In this regard, the following points should be noted:

The dew point temperature of the air depends on various factors, in particular the temperature of the air, the moisture content of the air and the pressure of the air. Air relative humidity (phi) in% represents the ratio of the current moisture content in the air to the maximum possible moisture content at the same temperature.

The dew point temperature in zones 5 and 6A decreases as it progresses along the zone, because water condenses in this zone because the water content of the air stream and thus the air relative humidity (phi) continue to decrease. to be.

By way of example, the dew point temperature of the air stream at any location in zones 5 and 6A is determined by measuring the temperature and relative humidity (phi) of the air stream via a sensor and calculating the dew point temperature of the condition. . Dew point temperature (T _p1 ) can be calculated by way of example the following equation.

Here, the unit of measure for temperature (T, T _p1 ) is degrees Celsius, and percentages should be used for air relative humidity (phi). However, dew point temperature (T _p1 ) can also be calculated from the Molly diagram.

The Mollie diagram also shows the dehumidification process of the air flow and is also suitable for inferring how the temperature of zones 4, 5, or zones 4, 5, 6A is controlled. 2 shows the Molly diagram. This plot includes various curves showing the transition of dew point temperature T _p1 as a function of the water content X and the temperature T of the air for various values of various air-phase humidity phi. In the following the dehumidification process is described in detail by way of example including the values of the temperature T and the air-condition humidity of a randomly selected air flow based on FIG. 3, which is an enlarged partial view of the Molley diagram according to FIG. 2. The process for dehumidifying the air stream is shown by four arrows connected to each other. Each of the four arrows is assigned one of the zones 4, 5, 6A, 6B of the device for dehumidification of the air flow. In this example the inlet of the air flow into the first zone 4, ie the air flow at the inlet 1, has a temperature T of 30 ° and an air phase humidity phi of 50%. In this example the air flow at the outlet of zone 6B, ie at the outlet 2 of the device for dehumidification of the air flow, reaches a temperature T of 22 ° and an air phase humidity phi of 30%. In the first zone 4 the air stream is only cooled without the discharge of water. Thus, the first arrow runs vertically and points down. In the first zone 4 the air stream must be cooled to a temperature T ₁ corresponding to its dew point temperature T _p1 (T _p1 = 18.5 ° C. in the example). If water should not condense in the first zone 4, the temperature T ₁ should be higher than the dew point temperature T _p1 . However, in the first zone 4, in particular in the end zone of the first zone 4, if the water can condense, the temperature of the air stream T ₁ is the dew point temperature in the end zone of the first zone 4. May fall below T _p1 ). In the second zone 5 the air stream is continuously dehumidified. Since water is removed from the air stream here, the dew point temperature continues to decrease along the second zone 5 as can be clearly seen in the Molly diagram. Even in the third zone 6A, the air flow is continuously dehumidified, with the result that the dew point temperature continues to decrease along the third zone 6A. In the example the air flow should reach a temperature T ₂ of 3.5 ° C. at the end of the third zone 6A. In the example the air temperature in the fourth zone 6B is heated to the desired temperature of 22 ° C., where he also reaches the desired air relative humidity (phi) of 30%.

Both zones 6A, 6B are connected to each other so that heat to be discharged, which is generated in zone 6A to heat the air stream to the desired temperature, is supplied to zone 6B. The dew point temperature at the transition from the second zone 5 to the third zone 6A should be set or adjusted to meet this requirement.

At the heart of the invention is the cooling and dehumidification of the air stream, where the cooling takes place in the first zone 4 where water is not yet condensed in the air stream, and the relative air humidity is almost ideal at the outlet of the first zone 4. Up to 100%, dehumidification takes place in the subsequent second zone 5. This partitioning optimizes the material and surface structure of the air channel sidewalls defining the first zone 4 for optimal heat transfer without condensation and the material and surface structure of the air channel sidewalls defining the second zone 5. It is possible to optimize for optimal heat transfer where condensate or droplet formation takes place and for rapid discharge of condensed water. Ideally, a water monolayer is formed on the side wall of the second zone 5 because this very thin film serves to quickly drain water on the one hand and only forms a weak thermal resistance on the other. A possible embodiment of the side wall of the second zone 5 is that it is coated with a material with varying proportions of hydrophobic and hydrophilic effects in the direction of gravity from top to bottom, with the hydrophobic ratio at the top and the hydrophilic ratio at the bottom.

If the air flow leaves the second zone 5, the air flow is cold and relatively dry. This air stream is now illustratively supplied directly to the air conditioning space or mixed with outside air to the space or mixed with exhaust air discharged from the space to be supplied back to the space or to the space as heated and treated supply air. Can be. In addition, the present invention relates to any one device, in which an air channel is divided into at least four zones (4, 5, 6A, 6B), such that the air flow in the third zone (6A) discharges moisture as water. Temperature removal of the third zone 6A is possible and waste heat generated in the third zone 6A is supplied to the air stream in the fourth zone 6B. Preferably this comprises at least one Peltier element on the one hand whose cold side cools the sidewall of the third zone 6A to the required temperature and on the other hand its warm side heats the sidewall of the fourth zone 6B. Is done through.

4 shows a possible embodiment of the device for dehumidification of the air flow. The first zone 4 is formed via at least one module 7 of the first type, in which two modules 7 are arranged in succession. The second zone 5 is formed via at least one module 8 of the second type, in which five modules 8 are arranged in succession. Modules 7 and 8 have a similar structure and show differences only in certain details.

5 shows the individual parts that make up the module 7. These individual parts are the frame 10, the first perforated plate 11, the second perforated plate 12, the Peltier element 13 and the cooling member 14. The frame 10, the first perforated plate 11 and the second perforated plate 12 have the same outer contour. The perforated plates 11, 12 comprise a plurality of holes which are circular in the example. The holes of the first perforated plate 11 are alternately arranged with respect to the holes of the second perforated plate 12. The plurality of frames 10, the first perforated plate 11, and the second perforated plate 12 may include the frame 10, the first perforated plate 11, the frame 10, the second perforated plate 12, the frame 10, The first perforated plate 11, the frame 10, the second perforated plate 12, and the like are coupled to each other in order to form a channel for the air flow. FIG. 6 shows this structure: the figure shows a side view of the frame 10, the first perforated plate 11 and the second perforated plate 12, and FIG. 6 expands in the horizontal direction for easier identification of the individual parts. It became. 7 shows a perspective view of the module 7. In this example, six Peltier elements 13 are arranged on each sidewall 16 of the channel, two of which are shown in FIG. 6. The channel has a bottom 15, two side walls 16 and one cover 17. At least one Peltier element 13 is attached to at least one of the side walls 16, preferably to both side walls 16. When the module 7 is operated, a flow that cools the surface opposite the channel side of the Peltier element 13 and heats the channel corresponding side of the Peltier element 13 flows through the Peltier element 13. This heat must be released to the surroundings. This can be done in a variety of ways such as for example air cooling or water cooling. In the example, the Peltier element 13 is equipped with a cooling member 14 which is circulated in the circuit and cooled by water or other medium which exhausts the heat contained in the Peltier element 13 to the surroundings at a suitable location. In the example shown in FIG. 7, six Peltier elements 13 and two cooling elements 14 are mounted on each sidewall of the channel (one of which is omitted).

The perforated plates 11 and 12 are flow obstructions arranged transverse to the air flow or channel direction. The air flowing through the channel flows through the holes in the perforated plate without hitting or disturbing the perforated plate. The holes of the first perforated plate 11 are staggered with respect to the holes of the second perforated plate 12 so that the air is continuously deflected in the channel of the module 7 so that the air is in constant contact with the perforated plate and is cooled at this time. .

8 shows the individual parts that make up the module 8. These individual parts comprise a frame 10, a specific number of different plates with a tip, in this example four different plates: first tooth plate 18, second tooth plate 19, third tooth plate 20 ), Fourth tooth plate 21, Peltier element 13 and cooling member 14. 9 shows a perspective view of the module 8. The plurality of frames 10, the first tooth plate 18 and the second tooth plate 19, the third tooth plate 20, and the fourth tooth plate 21 may include the frame 10 and the first tooth plate 18. ), Frame 10, second tooth plate 19, frame 10, third tooth plate 20, frame 10, fourth tooth plate 21, frame 10, first tooth plate 18, the frame 10, the second tooth plate 19, the frame 10, the third tooth plate 20, the frame 10, the fourth tooth plate 21, etc. , They form a channel for air flow. The frame 10 and the four tooth plates 18, 19, 20, 21 have the same outer contour, but the tooth plates 18, 19, 20, 21 face down, i.e., facing the bottom 15 of the channel. The open, channel bottom 15 of the assembled module 8 comprises a plurality of slots each formed between adjacent frames 10. The tooth plate 18, 19, 20, 21 has a surface 22, the bottom edge 23 of the module 15 channel opposite the edges 23 having a tip and typically formed in tooth shape. The Peltier element 13 and the cooling member 14 are attached in the same manner as the module 7. The three tooth plates 18, 19, 20, 21 differ in the spacing at which the surface 22 is arranged from the bottom 15 of the channel of the module 8.

The tooth plates 18, 19, 20, 21 are flow obstructions arranged transverse to the air flow or module 8 channel direction. Air flowing through the channels of the module 8 impinges on the surface 22, and the moisture contained in the air condenses as water on the surface 22 and flows down due to the influence of gravity, Gather, detach from it, fall down and pass through a slot at the bottom of the channel of module 8 to reach drain channel 9 (FIG. 4) attached below module 8 in zone 5. The drain channel 9 is sealed to the periphery. In order to prevent the air flowing through the air channel from being discharged to the surroundings through the slot of the channel bottom 15 and the opening of the drain channel 9, the drain channel 9 preferably has water through a siphon or An opening that exits through a thin, long tube with a correspondingly large friction force. In this example the drainage channel 9 extends over all three zones 4, 5, 6A.

In this embodiment, the frame 10, the perforated plates 11 and 12 and the toothed plates 18, 19 and 20 have holes, so that they can be attached to the modules 7 and 8 or the entire air channel using screws. The frame 10, the perforated plates 11, 12 and the toothed plates 18, 19, 20 are made of a material having excellent thermal conductivity. The lower the thermal conductivity, the thicker this frame and plate. The Peltier element 13 is attached to the outer wall of the channel formed by the frame 10 and the perforated plate 11, 12 or the frame 10 and the tooth plate 18, 19, 20, 21, thereby cooling the perforated plate 11, 12) and toothed plates 18, 19, 20, 21 are thermally connected. The cooling member 14 is attached to the Peltier element 13.

The third zone 6A of the device according to the invention for dehumidification of the air flow is an option as described above. This zone likewise comprises a second type of module 8, in which air flow flows through the interior of the module 8 and then in the channel formed on the outer side of the module 8. It is formed such that it flows through the hot side of the element 13 and is heated at this time. The inside of the module 8 forms a third zone 6A, which is not visible in FIG. 4, and the outside of the module 8 forms a fourth zone 6B.

로도 불린다). 마찬가지로 라멜라(26)의 열전도도는 적어도 하나의 히트 파이프(28)를 통해 증가될 수 있다. 본 예시에서 라멜라(26)는 냉각부재(14)(도 4)를 형성한다. The modules 7 and 8 may have other structures. An example of another structure is shown in FIG. 10 in which a tooth plate 19 is used. The tooth plate 19 is made of two different materials, a material suitable for the formation of the outer frame 24 and a good thermally conductive material for the surface 22 which has to cool air and remove moisture. On the left and right edges of this surface 22 are attached one Peltier element 25, each of which cools the surface 22 to the desired temperature during operation. In this example, the surface of the Peltier element 25 against the surface 22 is equipped with a lamella 26 which dissipates the generated heat to the periphery. The lamella 26 is preferably cooled by means of a separate air stream consisting of external air or exhaust air and discharged to the surroundings as discharge air. Thus, in this example, the lamellas 26 form a cooling member 14 (FIG. 4). This embodiment is also suitable for combining the tooth plate 19 into a single component together with the frame 10 (FIG. 8) by correspondingly forming the frame 24. Since the same design applies to the other tooth plates 18, 20, 21 (FIG. 8), the module 8 is framed in between by means of successive arrangements of this type of tooth plates 18, 19, 20, 21. It can be formed without arranging 10. This design has two important advantages. That is, it is used only where a good thermal conductivity material is needed, and since each Peltier element 25 is disposed on each tooth plate, it is possible to individually adjust the temperature of each tooth plate. Attaching at least one "heat pipe" 27 to the surface 22 may increase the thermal conductivity of the surface 22. (Heat pipe is in German

Also called). Likewise, the thermal conductivity of lamellas 26 can be increased through at least one heat pipe 28. In this example, the lamellas 26 form a cooling member 14 (FIG. 4).

The perforated plates 11, 12 (FIG. 5) can have a structure similar to the tooth plate 19 described on the basis of FIG. 10, so that the Peltier elements are individually assigned to each perforated plate.

As an example is shown in FIG. 4, when the modules 7, 8 are assembled in an apparatus, each channel of the modules 7, 8 together forms an air channel for the air flow to dehumidify together. The device according to the invention furthermore comprises at least a control device 29 for the control of the Peltier element 13 and the temperature T and / or the humidity, preferably the air relative humidity phi, for the control of the modules 7, 8. It includes one sensor. 11 shows a circuit diagram of such a control device. The output signal or output signals of the at least one sensor 30 are transmitted to the controller 29 and used for the control of the Peltier element 13 of the modules 7, 8. In this example, the control device 29 controls the first controller 31 and the Peltier element 13 of the module 8 of the zone 5 for controlling the Peltier element 13 of the module 7 of the zone 4. It includes a second controller 32 to. Temperature control of the modules 7 and 8 in both zones 4 and 5 is complex. In the following the basic principles of control are described.

Such a sensor 30 is illustratively located at the inlet of the air channel and measures the temperature T and the relative humidity phi of the air stream to be dehumidified. However, the sensor 30 may be placed in another suitable location. Ie it may be arranged between the two zones 4, 5, for example as shown in FIG. 4. In the measured values T, phi the control device is for example using the formula (1) or in the control unit 29 a Molie diagram (e.g. stored as a function, a plurality of curves or a table) (Fig. 2). Calculate the corresponding dew point temperature (T _p1 ) on the basis of The controller 31 controls the flow through the Peltier element 13 of the module 4 of the zone 4 so that at least at the next perforated plate at the outlet of the zone 4 is cooled to a temperature T ₁ . Where temperature T ₁ is a slightly higher temperature than the calculated dew point temperature T _p1 or dew point temperature T _p1 . Preferably the temperature T ₁ is chosen such that no condensate has yet occurred in zone 4 and / or the condensate generated evaporates again in the air stream. The relative humidity of the air flow at the inlet of zone 5 reaches at least nearly 100%.

In zone 5 moisture is removed from the air stream. This reduces the moisture content and relative humidity of the air stream. The dew point temperature changes as it progresses along the zone 5: the dew point temperature at the exit of the zone 5 is lower than at the inlet of the zone 5. In order for the moisture of the air stream to be condensed with water, the temperature of the tooth plate must be lower than the local dew point temperature at all locations in the zone 5.

The dehumidified air stream should have a previously set temperature (T ₂ ) and a previously set relative humidity (phi ₂ ) when leaving the zone. Using the equation (1) or the Molly diagram, it is possible to calculate the dew point temperature (T _p2 ) that the tooth plate of the module 8 which is next next at the outlet of the air channel should have.

In order for the tooth plate temperature of the module 8 to be lower than the local dew point temperature in order to allow the moisture contained in the air stream to be discharged as water, the controller 32 is adapted to the module of the zone 5 and optionally the zone 6. The flow through the Peltier element 13 of 8) is controlled.

Preferably the controller 31 comprises a plurality of sub-controllers 33 and preferably the controller 32 comprises a plurality of sub-controllers 34, so that the individual control of the flow flowing through the modules 7, 8 is possible. Is possible.

The efficiency of the Peltier element 13 is determined by various factors, in particular the temperature difference between its warm side and its cold side. The controller 33 and the controller 34 preferably operate the Peltier elements of the modules 7 and 8 within the optimum operating range, and depending on the situation, only a few modules 7 and 8 operate and some modules (7, 8) may turn off.

The dew point temperature that must be reached to remove moisture corresponding to temperature T and relative humidity phi in the air entering the device can be calculated using the Molly diagram shown in FIG. Similarly, the Mollie diagram can be used to calculate the dew point temperature required for each individual module 8 in zone 5 and optionally in zone 6.

1 Inlet with air to be dehumidified
2 Outlet from which dehumidified air is discharged
3 air flow arrows
4 first zone
5 second zone
6A Zone 3
6B Zone 4
7 modules
8 modules
9 drainage channel
10 frames
11 1st perforated plate
12 2nd perforated plate
13 Peltier Elements
14 Cooling element
Bottom of 15 channels
16 sidewalls
17 cover
18 first tooth plate
19 2nd tooth plate
20 3rd tooth plate
21 4th tooth plate
22 surfaces
23 corners
24 frames
25 Peltier Elements
26 lamellas
27 heat pipe
28 heat pipe
29 controls
30 sensors
31 first controller
32 2nd controller
33 lower controller
34 lower controller

Claims (8)

An apparatus for dehumidifying an air stream, comprising an air channel having an inlet 1 through which air to be dehumidified is supplied and an outlet 2 through which dehumidified air is discharged.
The air channel is divided into at least two zones (4, 5), and at the end of the first zone (4) the first zone (so that the air flow is cooled to a dew point temperature or slightly above the dew point temperature corresponding to the air flow) Temperature control of the second zone (5) so that the air flow in the second zone (5) discharges moisture as water. 2. Device according to claim 1, characterized in that the material and / or surface structure of the side walls defining the air channel are formed differently in the first zone (4) and the second zone (5). 3. The air conditioner according to claim 1 or 2, wherein the air channel is divided into at least four zones (4, 5, 6A, 6B) and the air flow in the third zone (6A) discharges the moisture into the water. 6A) temperature control and waste heat generated in the third zone (6A) is supplied to the air flow in the fourth zone (6B). The temperature control of the third zone (6A) is made via at least one Peltier element (13), wherein the cold side during operation cools the third zone (6A) and the hot side during operation. Device for heating the fourth zone (6B). The temperature control of the air channel is made via the Peltier element 13, which is controlled by a control device 29 with at least two controllers 31, 32. The first controller 31 controls one Peltier element or a plurality of Peltier elements 13 of the first zone 4 so that the air flow is cooled in the first zone 4 without condensation of water, and the second controller ( 32 is characterized in that the air flow in the second zone 5 controls one Peltier element or a plurality of Peltier elements 13 in the second zone 5 such that the air flows out of the drainage channel 9. . Dehumidification method of air flow comprising the following steps,
a) allowing an air stream to flow through the first zone (4), in which air at the end of this zone (4) is such that its temperature reaches a value corresponding to the dew point temperature or slightly above the dew point temperature; The flow is cooled, and
b) allowing the air stream to flow through the second zone 5, in which the air stream is cooled to the extent that water condenses. A method according to claim 6 comprising the following additional steps,
Cooling the air stream to or below dew point temperature, causing the air stream to flow through third zone 6A where water is condensed, and then the fourth, where the air stream is heated by heat generated in third zone 6A. Flowing air flow through zone 6B. 8. The method according to claim 7, wherein the air flow is cooled through at least one Peltier element in the third zone (6A), wherein the waste heat generated heats the air flow in the fourth zone (6B). 9.

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