KR20140022791A - System for drying and/or cooling an airflow - Google Patents

Abstract

The present invention relates to a system for drying and / or cooling an airflow, comprising at least one cooling device for cooling the airflow and a drying device for drying the airflow, the cooling device for cooling At least one cooling channel having an inlet opening for the airflow and an outlet opening for the cooled airflow, separated from the cooling channel by a transfer wall and connected for media through flow to the outlet opening of the cooling channel At least one evaporation channel having an inlet opening and an outlet opening and means for wetting the side of the delivery wall facing the evaporation channel, the drying device comprising: an inlet for the airflow for drying; A drying channel having an opening and an outlet opening for said dried airflow. And is the outlet opening of the cooling device or the evaporation channel of the outlet openings and / or cooling device or the cooling device of the cooling channel of the cooling device is connected to the medium through-flow to the inlet opening of the drying device.

Description

SYSTEM FOR DRYING AND / OR COOLING AN AIR FLOW {SYSTEM FOR DRYING AND / OR COOLING AN AIRFLOW}

The present invention relates to a system for drying and / or cooling an airflow, comprising at least one cooling device for cooling the airflow and a drying device for drying the airflow, wherein the cooling device is configured to provide cooling. At least one cooling channel having an inlet opening for the airflow and an outlet opening for the cooled airflow, separated from the cooling channel by a transfer wall and connected for media through flow to the outlet opening of the cooling channel At least one evaporation channel having an inlet opening and an outlet opening and means for wetting the side of the delivery wall facing the evaporation channel, the drying device comprising: an inlet for the airflow for drying; A drying channel having an opening and an outlet opening for said dried air flow. It should.

Such cooling devices are known, for example, from NL-C-1030538. Reference is made by this patent publication for example of the operation of a cooling device which can be applied in the system according to the invention. A drying device known for example in NL-C-10239822 is referred to by this patent publication for example of the operation of a drying device that can be applied in a system according to the invention, such that the airflow is dried before flowing into the cooling device. It is usually arranged upstream of the cooling device. Warm, moist airflow can in this way be drawn from the area surrounding the system into the inlet opening of the drying channel of the drying device and dried thereafter, after which the airflow can be used for any purpose. It is cooled in a cooling device with a dry air stream. The cold, dry air stream can be supplied to the space, for example. Other types of dryers and cooling devices may also be suitable for the system according to the invention.

It is an object of the present invention to provide a system for drying and / or cooling an airflow, wherein the airflow is dried effectively, or at least effectively in a drying device.

A system of another type of the invention mentioned in the text for this purpose is characterized in that the outlet opening of the cooling channel of the cooling device and / or the outlet opening of the evaporation channel of the cooling device are connected for the medium through-flow to the inlet opening of the drying device. It is provided.

Applicants have found that the efficiency of the drying device of wet airflow increases with the relative humidity of the airflow. The airflow coming from the outlet opening of the cooling channel of the cooling device and / or the outlet opening of the evaporating channel of the cooling device usually has a higher relative humidity than the ambient air, and the drying device can effectively dry the airflow coming from the cooling device. have. The relative humidity of the airflow is increased in the cooling channel in that the temperature of the airflow decreases at a constant absolute humidity of the airflow, which leads to an increase in the relative humidity. The relative humidity of the airflow is increased in the evaporation channel of the cooling device in that the airflow is cooled by the evaporation of moisture acting on the delivery wall and absorbs heat through the delivery wall from the airflow flowing through the cooling channel. The temperature of the airflow in the evaporation channel will increase by heat absorption, which can absorb more moisture. The evaporation of moisture and the increase in temperature both increase the absolute and relative humidity of the air in this way, and the relative humidity will be higher than the relative humidity of the ambient air.

The relative humidity of the airflow in the system according to the invention is therefore increased in the cooling device, after which the airflow is dried in the drying device. Effectively dried air can be supplied in this way to a space that can be used for any application, for example if dry air is desired or desired. The air to be dried can be for example ambient air, which is for example drawn into the inlet opening of the cooling channel of the cooling device.

Optionally or additionally, the ambient air can also be any other airflow.

The system according to the invention is therefore distinguished from the known system in that it is strictly a cooling device arranged upstream of the drying device instead of downstream. It may be contradictory to first increase the relative humidity of the airflow before drying it, but it is strictly possible according to the invention to increase the efficiency of the drying device. Air effectively dried in this way can be used for air cooling processes or air drying processes.

In another embodiment according to the invention the outlet opening of the drying device is connected for the medium through-flow to the inlet opening of the cooling channel of the cooling device.

The dried air is once again cooled by a cool dry air stream and can be used as required. The cold, dry air stream can be supplied to the space, for example.

In an embodiment of the system according to the invention the system comprises two cooling devices, the outlet opening of the drying device being connected for the medium through-flow to the inlet opening of the cooling channel of one cooling device and the cooling channel of the other cooling device. The outlet opening of and / or the outlet opening of the evaporation channel of the other cooling device is connected for the medium through flow to the inlet opening of the drying device.

In another embodiment of the system according to the invention the system comprises a heat exchanger, the heat exchanger being on one side for medium through-flow to the outlet opening of the cooling channel of the cooling device and / or the outlet opening of the evaporation channel of the cooling device. Connected to the inlet opening of the cooling channel of the cooling device and / or to the inlet opening of the drying device on the other side for flow through the medium.

In such a system the cooled airflow is brought in heat-transfer contact with a heat exchanger having a heat or a cooling-transfer medium without being supplied to the space. The temperature of the cooled airflow increases here, while the heat or cool-transfer medium will be cooled. The heat or cooling-transfer medium may be a second airflow, for example ambient air, drawn into the heat exchanger, cooled and then supplied to the space. The heat or cold-transfer medium may also be water, which is cooled in a heat exchanger. Cooled water can be used, for example, to cool the building.

The heat exchanger can be any type of heat exchanger, and the flows are in counterflow.

The heat exchanger is for example connected on one side for the medium through flow to the outlet opening of the cooling channel of the cooling device and the other side for the medium through flow to the inlet opening of the drying device and / or the inlet opening of the cooling channel of the cooling device. Connected to the outlet, the outlet opening of the evaporation channel of the cooling device and / or the outlet opening of the cooling channel are connected for inlet flow of the medium to the inlet opening of the drying device.

The system is configured such that the cooled air stream exits the heat exchanger from the outlet opening of the cooling channel of the cooling device and at the same time the air flow has a higher temperature than the air flow coming from the cooling channel. The advantage is that the air flow is transferred to the inlet opening of the drying device.

The system is for example a system that is at least closed to airflow. This has the advantage that the system is independent of the external climate.

In a closed system it may further be present to regulate the air pressure in the system. The value of the air pressure in the system can lie between 0.5 bar-3 bar, for example. The air pressure can in particular be 0.5 bar, 1 bar or 2 bar.

Higher air pressures have the advantage that less grams of water per kilogram of air may be extracted from the airflow to cool the air by a given temperature than at lower air pressures. Lower air pressures, on the other hand, have the advantage that lower airflow temperatures can be obtained at a constant absolute humidity than at higher pressures. Therefore, it is possible to select a fixed air pressure in the application of the system.

In a practical embodiment the drying device comprises drying means for drying the airflow. The drying means is hygroscopic and absorbs moisture from the air stream through absorption and / or adsorption. Examples of such drying means are, for example and not exclusively, silica gel, ammonium nitrate, calcium chloride, carbonyl fluoride, magnesium sulfate, sodium chloride, sodium sulfate, sodium propionate, (p (AA)) sodium salt.

The drying means is preferably of a type in which the amount of moisture which the drying means can absorb with respect to the dry weight of the drying means increases with an increase in the relative humidity of the air.

With drying means the drying device will be able to absorb more moisture from the airflow in an effective manner at higher relative humidity of lower air than at lower relative humidity of lower air.

From the defined value of the relative humidity of the air the amount of moisture which the drying means can absorb with respect to the dry weight of the drying means increases at least almost exponentially, in particular with an increase in the relative humidity of the air.

For example, a given salt may show a nearly exponential curve from a given value of the relative humidity of the air, and the moisture absorption of the drying means takes place in a very effective way at the relative humidity of the high air of the air stream above the given value. .

Are included herein.

The invention will become more apparent below with reference to those shown in the following figures:
1-5 schematically show other embodiments of a system according to the invention;
6A-6C show 0.5 bar (FIG. 6A); 1 bar (Figure 6b); And Molle diagram at 2 bar (FIG. 6C); And
FIG. 7 schematically shows the amount of moisture the drying means can absorb with respect to dry weight as a function of the relative humidity of air to silica gel and sodium salt.

Airflows are designated in the figures with arrows. Where an arrow is divided into two or more consecutive arrows means that parts of the airflow are separated and these partial airflows flow to different destinations. The flow rates of the other partial airflows and the ratios of the other partial airflows can vary and in that case can be adjusted as desired.

1a shows a system for cooling an airflow, comprising a cooling device 1 for cooling the airflow, the cooling device comprising an inflow opening for the airflow for cooling and At least one cooling channel (10) having an outflow opening for cooled airflow, separated from the cooling channel (10) by a transfer wall (11), the outlet of the cooling channel At least one evaporating channel 12 having an inlet opening connected to the opening for medium throughflow, and an outlet opening, and a side of the delivery wall 11 facing the evaporating channel 12. Means for wetting. The system further comprises a drying device 2 for drying the airflow, the drying device having a drying channel having an inlet opening for the airflow for drying and an outlet opening for the dried airflow. 13).

The air, which flows into the inlet opening of the cooling channel 10 and whose relative humidity is increased in the cooler 1, may be, for example, ambient air. In the system according to FIG. 1 a a part of the airflow coming from the cooling channel 10 flows into the inlet opening of the drying channel 13 and the other part of the flow into the inlet opening of the evaporation channel 12. The air with the relative humidity increased by the cooling device 1 is dried in the drying device 2. This air can for example be supplied to the space where dry air is required via the outlet opening of the drying channel 13.

In the system according to FIG. 1A, but instead or additionally, with respect to the outlet opening of the evaporation channel 12, it can be connected for the medium through-flow to the inlet opening of the drying channel 13. At least a portion of the warm, moist air stream coming from the evaporation channel 12 can be dried in the drying device 2.

FIG. 1B shows the system according to FIG. 1A with the outlet opening of the drying channel of the dryer 2 connected to the inlet opening of the cooling channel 10 of the cooler 1 for flow through the medium, so that the dryer 2 A portion of the dried air stream in the feed is fed back into the inlet opening of the cooling channel 10 of the cooling device 1. Since at least a portion of the airflow can be guided back through the dryer 2 in this manner, the absolute humidity of the airflow can be low compared to other systems in FIG. 1A and the airflow is guided once through the dryer 2. . This can be beneficial when air with low absolute humidity is required.

2 shows a system with two coolers 1a and 1b. The outlet opening of the drying device 2 is connected for the medium through-flow to the inlet opening of the cooling channel 10b of one cooling device 1b and the outlet opening of the cooling channel 10a of the other cooling device 1a is To the outlet opening of the drying device 2 for flow through the medium. In the system according to FIG. 2, a part of the airflow coming from the cooling channel 10a flows through the outlet opening of the drying channel 13 into the drying device 2, and the other part passes through the outlet opening of the evaporation channel 12a. Flow into the cooling device 1a. Alternatively or additionally, the outlet opening of the evaporation channel 12a of the other cooling device 1a can be connected for the medium through-flow to the inlet opening of the drying device 2. The ambient air is drawn to it via the inlet opening of the cooling channel 10a of the other cooler 1a. The cooled air is supplied to the space from the outlet opening of the cooling channel 10b of the cooler 1b.

In FIG. 3A the outlet opening of the drying device 2 is connected for the medium through-flow to the inlet opening of the cooling channel 10 of the cooling device 1 and the outlet opening of the cooling channel 10 of the cooling device 1 is dried. It is connected to the inlet opening of the device 2 for the medium through flow. The airflow coming from the outlet opening of the cooling channel of the cooling device 1 is separated into three partial airflows, the first partial airflow is directed into the drying device 2 and the second partial airflow is an example. For example, it is supplied to the space, and the third partial air flow is guided into the inlet opening of the evaporation channel 12 of the cooling device 1. For illustration, about one third of the cooled air is for example supplied to the space, about one third of the cooled air is supplied to the dryer 2 and one third of the cooled air is also cooled by the cooler 1. Is supplied to the evaporation channel 12, and the humid air stream is then supplied to the outer region of the space. These ratios may also be different. For example, one half of the air cooled in the dryer 2 and half in the space and / or in the evaporation channel 12 can be fed. In the system according to FIG. 3A ambient air is drawn into the inlet opening of the cooling channel 10 of the cooler 1 and mixed with the dried air coming from the dryer 2 and / or the ambient air is broken down. As shown by the arrows, it is drawn into the inlet opening of the drying channel 13 of the dryer 2.

3B shows the system of FIG. 3A with the outlet opening of the evaporation channel 12 of the cooler 1 connected to the inlet opening of the drying channel 13 of the dryer 2 for flow through the evaporation channel 12. Warm, moist air coming from is dried in the dryer 2.

FIG. 4 shows a system with one cooler 1, one dryer 2 and one heat exchanger 3. The heat exchanger 3 is connected on one side for the medium through-flow to the outlet opening of the cooling channel 10 of the cooling device 1 and through the medium to the inlet opening of the drying channel 13 of the drying device 2. It is connected on the other side for flow. In the system according to FIG. 4, the cooled airflow is not supplied to the space, but with the second airflow in the second channel 15 of the heat exchanger 3 via a heat-transferring partition wall 16. Brought into the first channel 14 of the heat exchanger 3 in heat-transfer contact. While the second air stream is cooled, the temperature of the cooled air stream will increase here. The second air stream is, for example, ambient air that is drawn into the heat exchanger 3, cooled and eventually supplied to the space. Ambient air may be drawn further into the inlet opening of the cooling channel 10 of the cooler 1 and / or into the inlet opening of the drying channel 13 of the dryer 2. Air flow from the evaporation channel of the cooler 1 is released to the surrounding area outside the system.

5a and 5b show systems which are at least closed to airflow and have cooling 1, a dryer 2 and a heat exchanger 3. Since airflow remains in the system, the cooling capacity of the system is at least less affected by the climate of the surrounding area. The cooled airflow coming from the outlet opening of the cooling channel 10 of the cooler 1 passes through the heat-transfer partition wall 16 and the second airflow and heat- in the second channel 15 of the heat exchanger 3. Bringed into the first channel 14 of the heat exchanger 3 in transfer contact, the second airflow is supplied to the space. The air flow coming from the evaporation channel 12 of the cooler 1 is directed to the inlet opening of the drying channel 13 of the dryer 2. In the system according to FIG. 5A the air flow coming from the evaporation channel 12 is mixed with the air flow coming from the first channel 14 of the heat exchanger 3. In the system according to FIG. 5b the air flow coming from the first channel 14 of the heat exchanger 3 is directed to the inlet opening of the cooling channel 10 of the cooler 1. As shown by the intermittent arrows, the part of the cooled airflow coming from the cooling channel 10 of the cooler 1 in the systems according to FIGS. 5a and 5b is the inlet of the drying channel 13 of the dryer 2. It can be guided to the opening. The airflow for regeneration of the dryer 2 and / or the second airflow flowing through the second channel 15 of the heat exchanger 3 may optionally be located in closed or open systems.

The distribution of airflows can be adjusted in other ways as required. In FIGS. 5A and 5B about 1/3-2/3 of the air flow from the evaporation channel 12 of the cooler 1 can be guided to the outlet opening of the dryer 2 and the cooling channel 10 of the cooler 1. About 1/3-2/3 of the cooled air flow coming from the outlet opening of the can be guided to the heat exchanger (3).

In addition, a portion of the cooled airflow coming from the outlet opening of the cooling channel 10 of the cooler 1 is mixed with the airflow coming from the evaporation channel 12 of the cooler 1, and the mixture is transferred to the dryer 2. There may be cases where it is guided. Thus, the amount of moisture to be dried in grams per kilogram of air is reduced, and by drying the increase in temperature of the airflow is relatively relative to the warm, moist airflow coming from the evaporation channel 12 being directed to the dryer 2. low.

The Molie diagrams of FIGS. 6A-6C show that at an air pressure of 2 bar (FIG. 6C), less water, expressed in g water / kg air, than at an air pressure of 1 bar (FIG. 6B) or 0.5 bar (6a) It shows that it must be extracted from the airflow to reach the determined temperature of the airflow. 6A-6C further show that at a constant absolute humidity a lower absolute temperature can reach an air pressure of 0.5 bar 6a than at 1 bar (FIG. 6B) or 2 bar 6c.

FIG. 7 shows the amount of moisture which the drying means can absorb with respect to the dry weight Am as a function of the relative humidity RH of the air with respect to the silica gel and the sodium salt. This shows that the amount of moisture that can be absorbed in the case of sodium salts increases almost exponentially, or at least gradually, from the relative humidity of about 50% of air. Therefore, sodium salt effectively absorbs moisture from the air when the airflow has a relative humidity of air between 50% and 100%, and an air humidity of 90% is a practical value. The amount of moisture the sodium salt can absorb increases exponentially from the relative humidity of about 50% air to the relative humidity of about 100% air, and the relative humidity of the air is preferably as high as possible.

The invention is not limited to the embodiments shown, but also extends to modifications within the scope of the appended claims.

The ratios of airflows mentioned and shown are for illustrative purposes and should not be construed as limiting.

1, 1a, 1b: cooling device
2: drying device
3: heat exchanger
10, 10a, 10b: cooling channel
11: conveying wall
12, 12a, 12b: evaporation channel
13: drying channel
14: first channel
15: second channel
16: heat-transfer partition wall

Claims (10)

At least one cooling device for cooling the airflow and a drying device for drying the airflow,
The cooling device,
At least one cooling channel having an inlet opening for airflow for cooling and an outlet opening for the cooled airflow;
At least one evaporation channel having an inlet opening, which is separated from the cooling channel by a transfer wall and connected for media through flow to the outlet opening of the cooling channel, and an outlet opening; And
Means for wetting the side of the delivery wall facing the evaporation channel;
/ RTI >
The drying device,
A drying channel having an inlet opening for said airflow and an outlet opening for said dried airflow for drying;
/ RTI >
The outlet opening of the cooling channel of the cooling device and / or the outlet opening of the evaporation channel of the cooling device is connected to the inlet opening of the drying device for a media through flow. And / or a system for cooling. The method of claim 1,
The outlet opening of the drying device is connected for media through flow to a cooling device or to the inlet opening of the cooling channel of the cooling device. 3. The method according to claim 1 or 2,
Two cooling devices, said outlet opening of said drying device being connected for medium through flow to said inlet opening of said cooling channel of one cooling device, said outlet opening of said cooling channel of another cooling device and / or Or the outlet opening of the evaporation channel of the other cooling device is connected for media through flow to the inlet opening of the drying device. 3. The method according to claim 1 or 2,
A heat exchanger, said heat exchanger being connected on one side for medium through flow to said outlet opening of said cooling channel of said cooling device and / or said outlet opening of said evaporating channel of said cooling device, and said drying A system connected to the inlet opening of the device and / or the other side for media through flow to the inlet opening of the cooling channel of the cooling device. 5. The method of claim 4,
The heat exchanger is connected on one side for a media through flow to the outlet opening of the cooling channel of the cooling device and has a medium at the inlet opening of the cooling channel of the cooling device and / or the inlet opening of the drying device. Connected on the other side for through flow, wherein the outlet opening of the evaporation channel of the cooling device and / or the outlet opening of the cooling channel is connected for media through flow to the inlet opening of the drying device. The method of claim 5,
The system is a system at least closed to the airflow. The method according to claim 6,
The value for air pressure in the system is between 0.5 bar and 3 bar. 8. The method according to any one of claims 1 to 7,
The drying device comprises drying means for drying the airflow. 9. The method of claim 8,
The amount of moisture the drying means can absorb with respect to the dry weight of the drying means increases with increasing relative humidity of the air. 10. The method of claim 9,
The amount of moisture that the drying means can absorb with respect to the dry weight of the drying means from a predetermined value of the relative humidity of the air increases at least nearly exponentially with an increase in the relative humidity of the air.

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