NL1021953C2 - Method and system for dehumidifying air in a greenhouse. - Google Patents

Description

Method and system for dehumidifying air in a greenhouse

The present invention relates to a method for dehumidifying air in a greenhouse, comprising sucking in an air stream and passing it through a heat exchanger for lowering the temperature during condensation removal of moisture and blowing it out in that greenhouse of that dehumidified air, wherein an air stream for blowing out into said greenhouse is led through a heating heat exchanger.

Such a method is known from WO 00/76296. With reference to Fig. 4, the use of a relatively large cooling heat exchanger is described with which moisture present in the greenhouse is removed from the air by cooling the air and subsequent condensation thereof. A heating heat exchanger is installed downstream. As a result, the air returned to the greenhouse is heated.

Although it has been found that this method is often satisfactory, crop damage has been observed under certain circumstances. As a result, a considerable reduction of the yield occurs, so that such a method is not generally applicable.

It is the object of the present invention to avoid this drawback and to provide a method with which it is possible to dehumidify air in an efficient manner without damaging the crop.

This object is achieved in a method described above in that, as a result, the temperature of that dehumidified air blown out in the greenhouse is at most 10 ° C lower than the temperature of the air in that greenhouse.

According to the present invention, the air blown out of the dehumidification system is precisely controlled in temperature thereof. This air is at most 10 ° C colder than the air that is brought out of the greenhouse into the system, that is, the "ambient air" that prevails in the greenhouse. It has been found that with such a temperature difference crop damage can be prevented. This environment is in particular the crop or fruits thereof. Airflow gives an advantageous microclimate with optimum (relative) humidity, temperature and CO2%.

According to the invention, before it is blown into the air distribution system, the air is brought to such a temperature that even under the most unfavorable conditions when this air leaves the air distribution system no damage can be caused to the crop. Research has shown that for this purpose the temperature difference with the ambient air, that is to say the non-treated air present around the crop, is less than 10 ° C, preferably less than 8 ° C, and more in particular. without 3 ° C or less. All this depends, among other things, on the crop grown and the way in which it is grown. There is also a difference between growing with cultivation tables and with (hanging) gutters. The air flow from the air distribution system is different in both cases.

According to an advantageous embodiment of the method, carbon dioxide is added to the air exiting the air distribution system. The carbon dioxide is preferably supplied downstream of the heating heat exchanger. Here, upstream / downstream, reference is made to the direction of movement of the air through the air distribution system.

In principle, the position of the fan or other blowing device relative to the two heat exchangers is free. That is, it can be placed upstream of, downstream of or between both heat exchangers. However, according to an advantageous embodiment of the invention, it is placed downstream of the heat exchangers.

The air that is moved can either come from the greenhouse or from the environment, that is, from outside the greenhouse.

The invention also relates to a system for dehumidifying H air in a greenhouse, comprising a cooling heat exchanger placed in that greenhouse as a dehumidifier for the air flowing through from the greenhouse or surroundings, as well as a fan both arranged in a greenhouse with said greenhouse a connected pipe system, which pipe system comprises an air-distribution system for dehumidified air, wherein a heating heat exchanger is arranged downstream of said cooling heat exchanger.

H Heating or cooling takes place in a heat exchanger. Preferably for the other medium water or any other heat / refrigerant can be used H. Both cooling and heating can be achieved in any way known in the art. Use of underground cold heat storage as well as heat pumps are preferred variants of the invention.

The air distribution system, as described above, preferably consists of a flexible tube of at least 20 m. According to the invention, the length of such a tube can be up to hundreds of meters. Such a tube preferably has a relatively large diameter (tens of centimeters) and is provided with a large number of air outflow openings arranged distributed over its length. According to an advantageous preferred embodiment of the invention, these are placed at the top of the tube. All this is arranged in a greenhouse such that a number of such systems, comprising a dehumidifier / heating part and an air distribution system, are arranged parallel to each other.

It has been found that with the present invention it is possible in a simple manner to limit the moisture content in a greenhouse, so that fungal infections, pests and diseases are prevented or minimized, as well as the resulting damage. Moreover, the crop is not damaged by heating the dried air. Finally, there is the option of adding ingredients to the outflowing air, such as CO2 and / or crop protection agents.

The invention will be explained in more detail below with reference to an exemplary embodiment shown in the drawing. Show:

FIG. 1 shows very schematically a greenhouse with the system according to the invention;

FIG. 2 is a schematic side view of a system according to the invention;

FIG. 3 a variant of the system according to the invention; and

FIG. 4 shows, in end view, a part of the interior of a greenhouse.

In Fig. 1, 1 denotes a greenhouse consisting of a number of caps. Two sets of systems 2 are indicated schematically.

Details of these systems 2 appear from Fig. 2. A housing 3 is present in which a cooling heat exchanger 12 and a heating heat exchanger 13 are arranged. Arrows indicate the direction of flow of the air moving through the system 2. This shows that the heating heat exchanger 3 is located downstream of the cooling heat exchanger. A condensation trap may be present under / in addition to the cooling heat exchanger 12. Both heat exchangers are provided with schematically illustrated connection stubs that can be connected to a respective cooling / heating network.

Downstream of heating heat exchanger 13 there is a connecting stub 11 for supplying carbon dioxide and / or crop protection agents and / or other gas. Denoted at 14 is a fan which draws in the air through the housing or through the heat exchangers 12 and 13 and subsequently blows it out of the housing 3 into the flexible tube 4. This flexible tube or the air distribution system can have a considerable length of a meter to hundreds of meters. The flexible tube 4 is provided with outflow openings 5.

Fig. 3 shows a variant of the system shown in Fig. 2. The system is indicated in its entirety by 22 and comprises a housing 23 in which are included a cooling heat exchanger 32 and a heating heat exchanger 33. Arrows 35 and 36 indicate the air flow. The design of the flexible tube 14 substantially corresponds to what is shown in FIG. The same applies to the fan 34.

Fig. 3 shows that two air flows are sucked in by fan 34, one air flow being cooled and dehumidified with the aid of cooling heat exchanger 32 and the other air flow being heated exclusively with the heating heat exchanger 33. Subsequently, these two air flows are mixed in fan 34 and the resulting air streams 35, 36 have the same temperature and humidity. In addition, the air humidity will be lower than the air humidity in the greenhouse and the temperature will be higher than that of the air leaving the cooling heat exchanger 32. A desired air velocity, relative humidity and temperature at the location of the crop or its fruit can also be achieved in this way.

Fig. 4 shows two air distribution systems, respectively flexible tubes 4 lying next to each other. These are placed on bottom 10. At some distance from the bottom 10, a pipe rail network 6 is present. This serves for additional heating. In this example the cultivation of crops takes place with the help of gutters. The crop is indicated by 8 and the troughs by 7. Arrow 9 shows the air flow of the cold air emerging from opening 5. Due to its speed, this air will initially move upwards. Due to the small difference in temperature with the "ambient air", however, the downward movement of air observed with very cold air will not be detected. The positioning of flexible tube 4 relative to the crop and the cooling by heat exchanger 12, respectively heating and heat exchanger 13, are chosen such that if the air reaches the crop according to arrow 9, the temperature difference with the environment is less than 10 ° C and is preferably less than 8 ° C and more particularly less than about 3 ° C. In this way it can be guaranteed that no damage to the crop occurs.

5 i i

The heating of the exiting air described above can take place in any way known in the state of the art. Use can be made of the same heat source with which the pipe rail network is operated. Combination with heat pumps / geothermal heat is also possible. These and similar variants will immediately occur to those skilled in the art when reading the above description and are within the scope of the appended claims.

1021853

Claims (13)

Method according to claim 1, wherein CO2 is added to said air flow. 3. Method according to claim 2, wherein said CO2 is supplied downstream of said heating heat exchanger. Method according to one of the preceding claims, wherein said air stream is sucked through both heat exchangers and blown into said distribution system. I 20 5. A method according to any one of the preceding claims, wherein an air flow is passed through said heat exchanger for removing moisture and an air flow is passed through said heating heat exchanger, whereafter said air flows are combined. Method according to one of the preceding claims, wherein said air is drawn in from said greenhouse. 7. System (2) for dehumidifying air in a greenhouse (1), comprising a cooling heat exchanger (12) placed in that greenhouse as a dehumidifier, and a fan (14) both arranged in a pipe system connected to said greenhouse, which tube - system comprises an air distribution system for dehumidified air, characterized in that a heating heat exchanger (13) is arranged downstream of said cooling heat exchanger. 8. System as claimed in claim 7, wherein at least one of said heat exchangers is connected to a heat pump. System according to one of claims 7 or 8, wherein said air distribution system comprises a flexible tube (4) with a length of at least 20 m and provided with air outflow openings (5) arranged distributed over the length thereof. 10 System as claimed in claim 9, wherein said air outflow openings are arranged on the top of said tube. System according to any of claims 7-10, wherein said heat exchangers 15 are arranged adjacent to each other and are arranged downstream of said heat exchangers and said fan (14). 12. System as claimed in any of the foregoing claims 7-11, wherein said heat exchangers are arranged in parallel. 20 A system according to any of claims 7-12, comprising a CO2 supply opening (11) in said tubular system downstream of said heat exchangers. 14. Greenhouse (1), comprising a number of systems arranged side by side according to one of claims 6-11. 1021953