NL9001874A - Plant-growing system in enclosed space - generates upwards current of conditioned air round each plant - Google Patents

Abstract

The system grows plants in a mainly enclosed space, these being supplied with water and fertiliser, while the air in the space is conditioned. A current of conditioned air (16) in the upwards direction is generated and maintained round each plant (3). Air can be extracted from the current, at least partly conditioned, and returned to the current. During conditioning, the carbon-dioxide content, temperature and/or humidity of the air can be brought to the desired level.

Description

METHOD AND APPARATUS FOR CULTIVATING A CROP IN A SPACE CLOSED

The invention relates to a method for growing a crop in a substantially closed space, comprising arranging the crop, applying water and fertilizers to the crop and conditioning the air in the space.

Growing a crop in a substantially closed space, such as a department store or greenhouse, is generally known. By growing the crop in a substantially closed space, the weather influences can be controlled to a certain extent. In the room a climate can be created that is optimal for the growth of the crop.

The object of the invention is to improve the known method by more efficient climate control.

In the method according to the invention this is achieved in that an upward air flow of conditioned air is generated around each plant of the crop.

The plants of the crop are surrounded by the air of the upward air flow, so that the quality of the climate experienced by each plant depends directly on the air in the air flow. Instead of having to control the climate in the entire room, only the microclimate at the location of the plant needs to be optimized, which can be done in a more efficient manner.

It is not necessary to use fresh air for the air-conditioned conditioned air. Air is preferably extracted from the room and after reconditioning; fed back into the upward airflow.

Preferably, the conditioning of the air includes bringing at least the carbon dioxide content, temperature and / or humidity to a desired value. According to the prior art it is usual, when the temperature in the greenhouse threatens to become too high due to solar radiation, to open ventilation windows, whereby the air to be heated can escape and can be replaced by cooler outside air. As a result, however, air is lost which is qualitatively better than the fresh air in terms of moisture and carbon dioxide content, for example. By sucking air from the space according to the invention, bringing the temperature thereof to the desired value by cooling and then bringing this sucked air back into the air flow surrounding the plants, no good quality air is lost. To compensate for leakage losses, a small amount of fresh air will of course be added each time.

By further adjusting the humidity of the supplied air to a desired value, spraying of the crop is unnecessary. Thus, with the invention a saving can be achieved on the investment costs, since a sprinkler installation and air windows in the greenhouse are therefore unnecessary. Operational costs can also be saved. Since only small amounts of moist air with a suitable carbon dioxide content are lost through leaks, only little clean water and carbon dioxide need be added. The savings thus obtained more than offset the additional costs of generating the air flows and conditioning the air. In addition, the better control of the climate at the location of the crop results in a higher yield. Bringing the humidity to the desired value can of course also involve drying the air at too high a humidity.

The invention also relates to and provides a device for growing a crop in a substantially closed space comprising containers for supporting the crop, supply means for water and fertilizers and air conditioning agents.

According to the invention, an air supply pipe provided with blow-out openings is arranged under the holders and air guides are provided which can conduct the blown out air in an upward air flow surrounding the holders.

The measure according to claim 5 is preferably applied. The air supplied via the air supply line is, of course, conditioned in such a way that the mixture of blown out air and sucked-in ambient air has the optimum condition for the crop.

When a heating pipe is arranged at a height between the blow-out openings and the container, the supplied air is heated by passing the heating pipe, while, moreover, the crop in the container itself is heated on the "root side", which is favorable for certain crops.

The measure of claim 7 is preferably applied. This allows good control of the water and fertilizer supply to be achieved. The plants can be grown in a so-called substrate cultivation, in which a substrate is placed in the container, in which the crop grows.

Preferably, however, a hydroponics is used according to the invention, wherein the measure as set out in claim 8 is applied in an advantageous manner. The water with the fertilizers therein can thus circulate well, while, moreover, the waste is very limited after the end of the cultivation period.

The air conditioning means are preferably designed as characterized in claim 9. Because only little conditioned air is lost, only little carbon dioxide needs to be replenished to keep its content at a suitable level. The measure of claim 10 is therefore preferably applied. Carbon dioxide from pressure containers is very pure, so that no undesirable substances are released into the air, as can be the case with the flue gas supply which is used according to the prior art, for maintaining the carbon dioxide content.

When the air conditioning means additionally comprise cooling means for the air drawn in, the temperature of the plants surrounding the air can be accurately kept at an optimum value, despite possible strong solar radiation in the greenhouse. For the cooling of the air, the lower temperature of the soil beneath the space under cultivation can advantageously be used, by applying the measures of claim 12. In order to prevent "cold loss" by penetrating heat from above , the measures of claim 13 are further advantageously applied.

The invention will be further elucidated in the following description with reference to the attached figures.

Fig. 1 shows in partly broken away perspective view a greenhouse in which the method according to the invention is applied.

Fig. 2 shows a partly broken away detail view of a preferred embodiment of the device according to the invention.

Fig. 3 schematically shows part of the device according to the invention.

Fig. 4 partly shows one with FIG. 2 corresponding view of an embodiment variant.

In a greenhouse 1, which comprises a substantially closed space, a number of holders 4, in which plants 3 are accommodated, are arranged on the ground 2.

In the shown embodiment, the holders 4 are formed by elongated tubes, in a top surface of which openings 9 are formed. In these openings 9, supports 5 are placed, in which the plants 3 are rooted.

At one end, water 7 with fertilizers is supplied to the container 4 via a supply line 8. This water can circulate through the system and be discharged at the opposite end of the container 4. Roots 6 of the plants 3 hang in the water 7 and can absorb the fertilizers therefrom.

The fertilizers can be fertilizers to be added separately, but the water can also come from reservoirs in which fish are grown and thus contain fertilizers.

The holders 4 are supported by regularly spaced brackets 10, which rest on supports 11, which are attached to a base plate 12 lying on the ground 2.

The base plate 12 also supports on either side a rail 13 formed by a tube. A carriage 21 can drive over two adjacent rails 13, in which products to be harvested from the crop are collected.

The supports 11 also support air guides 14, which define a Y-shaped flow channel 15. An air supply pipe 17 is provided under the leg of the Y and is provided with blow-out openings 18. Air can be blown into the air duct 15 through these blow-out openings. As indicated by the arrow 16, this air flows around the container 4 on both sides, so that the plants 3 are surrounded by air from the upward air flow 16.

The air guides 14 leave a slit-shaped opening 22 near the bottom 2. Ambient air can be drawn in through this opening 22. This ambient air can be sucked in by the air from the blow-out openings 18. Ambient air can also be drawn in because a natural draft is created and as a result of the heating of the air in the ascending section of the duct 15 by a heating pipe 19 carried by the supports 11 This heating pipe 19 is provided with surface-enlarging fins 20.

The heating pipe 19 can in this way heat the air surrounding the plants 3 to the desired temperature. Moreover, the container 4 with the feed water 7 present therein is heated by the heat output of the heating pipe 19. As is known, it is advantageous for some crops if their root system is surrounded by medium with an elevated temperature.

In the embodiment shown in Fig. 2, a layer of insulating material 23 is provided around the lower part of the holder 4, which makes it possible to pass heating water with a high temperature through the heating pipe 19, without the danger of the feed water 7 becoming too hot.

In addition to conditioning the air supplied to the crop by heating, the conditioning may also include cooling, humidification and CO2 addition. Fig. 3 shows a diagram of such conditioning agents.

The conditioning means here comprise a cooling device 25 which can cool air drawn in from the space by means of a heat exchanger 26. The cooling medium, which may be water, flows through a recirculation pipe, an important part of which is a pipe 31 buried in the bottom 2. In this way, the low temperature of the bottom is used to cool the air .

The low temperature of the soil can be maintained by also passing water through the pipe 31 at night, which is cooled with the cool outside air.

Alternatively, the cooling water can be pumped through line 19, so that the air supplied through line 17 is cooled as it passes.

The air is sucked in with the aid of a suitable air pump 28. Carbon dioxide from cylinders 30 is supplied to the sucked in air in order to keep the carbon dioxide content at a value suitable for the crop. Furthermore, in the mixing device 27, the humidity of the air is brought to a suitable value by water supplied from a water pipe 29.

In order to prevent heat from penetrating into the ground 2 from above, an insulating layer 32 can advantageously be applied at a small depth. The operation of the cooling device 25 can hereby be guaranteed for a long time.

Fig. 4 shows an embodiment variant which is distinguished by a particularly economical construction of the substrate. The plant holder, air guide and heating pipe are indicated with the same reference numbers as in Fig. 2.

The surface is structured as follows. An insulating layer 36 is provided on the hard ground 35. A floor 37 of cement mortar has been poured on this insulating layer. Tiles 38 are laid on this floor 37. The cement floor 37 with the tile floor 38 together form the load-bearing floor.

The tiles 38 are laid such that they are at some distance at the location of a planter 4. A U-shaped profile 39, preferably a plastic profile, is placed in the slot thus formed. In this U-profile 39 the air conduit 40 is arranged, which in this embodiment is formed by a perforated spiral tube, which is known per se for drainage purposes. The upright walls of the U-profile 39 guide the air exiting from the perforation openings of the air tube 40 upwards between the air guides 14. The planter 4, air guides 14 and heating pipe 19 are supported at regular distances by supports placed on the tile floor . As Fig. 4 still shows, in the earth ground 35, a bottom pipe 41 is arranged under the insulating layer 36, corresponding to the bottom pipe 31 shown in Fig. 3.

Since the crop 3, as previously noted, is completely surrounded by the conditioned air in the upwardly directed air flow, the climate at each plant 3 of the crop is optimal. Since the humidity of the air is set to a suitable value, spraying the crop is unnecessary. Since the air can be cooled in the manner described, the greenhouse 1 in which the method according to the invention is applied need not have air windows. With strong sunlight, an upper layer of the air in the greenhouse 1 can have a considerably higher temperature than the air at the location of the crop, without this being harmful to the crop.

Claims (13)

Method for growing a crop in a substantially enclosed space, comprising arranging the crop, applying water and fertilizers to the crop and conditioning the air in the space, characterized in that each plant of the crop generates and maintains an upward airflow of conditioned air. A method according to claim 1, characterized in that the air is extracted from the air stream, is reconditioned at least partially and is fed back into an upward air stream. Method according to claim 1 or 2, characterized in that the conditioning of the air comprises bringing at least one of the parameters to a desired value: carbon dioxide content, temperature, humidity. 4. Device for growing a crop in a substantially closed space comprising containers for supporting the crop, supply means for water and fertilizers and air conditioning means, characterized in that an air supply pipe provided with blow-out openings is arranged under the holders and that air guides are provided which can conduct the blown out air into an upward air flow surrounding the containers. 5. Device as claimed in claim 4, characterized in that air openings for ambient air are present at a height between the blow-out openings and the holder. 6. Device according to claim 4 or 5, characterized in that a heating pipe is arranged at a height between the blow-out openings and the container. Device according to any one of claims 4-6, characterized in that the container is gutter-shaped and that supply and discharge means for water with fertilizers are connected at both ends. 8. Device as claimed in claim 7, characterized in that the holder comprises a tube in a top surface of which openings are formed in which plants of the crop rooted in a carrier material can be placed. 9. Device as claimed in any of the claims 4-8, characterized in that the air-conditioning means comprise suction means for sucking air from the room, wetting means for humidifying the sucked air and supply means for supplying the air to the air supply line. 10. Device as claimed in claim 9, characterized in that the air-conditioning means furthermore comprise means for adding carbon dioxide from pressure containers with compressed carbon dioxide to the sucked-in air. 11. Device as claimed in claim 9 or 10, characterized in that the air conditioning means additionally comprise cooling means for the air drawn in. 12. Device as claimed in claim 11, characterized in that the cooling means comprise a heat exchanger with a through-flow channel for the air drawn in and a through-flow channel for a coolant which is in heat-exchanging contact, wherein the coolant-through-flow channel is accommodated in a circulating pipe provided with a pump. , a substantial part of which extends into the bottom of the space. Device according to claim 12, characterized in that the bottom of the space is covered with a layer of insulating material.