NL8700015A - Method of cultivating crop in desert climate - has crop placed in cultivation house with 50 per cent of sun rays reflected by roof structure and with humid air blown over crop - Google Patents

Abstract

The method comprises placing the crop in e.g. a cultivation house with a regular supply of fertilizer. The crops are exposed to day-light and cooled during the day. Half of the sun rays shine into the house interior so that the remaining intensity is in the order of 100 W per m squared. Air from near the crop is sucked-up with water vaporised by the crop and blown out over the crop which freely combines with external air. The cultivation area has a frame (11), walls and a roof (17) of non-translucent reflective material with sizeable holes and a saw-tooth cross section. The spaces between two sepd. roof layers contains strips of reflective material.

Description

T-1 METHOD FOR CULTIVATING A CROP IN A DESERT CLIMATE / AND GROWTH FOR IT.

The invention relates to a method for growing a crop in a desert climate / comprising placing the crop in a cultivation hall such as a horticultural greenhouse, regularly supplying water and fertilizers to the crop, exposing the crop to daylight and cooling the cultivation hall interior at least during the day.

Horticulture in desert climates, such as in North Africa, the Middle East and parts of North America and Asia, is carried out in traditional horticultural greenhouses equipped with an evaporative cooling installation. In these cooling installations, water is evaporated adiabatically, so that the desired cooling effect is achieved. These cooling installations require a lot of water, which is scarce in the relevant areas. Moreover, these cooling installations use a relatively large amount of electrical energy. When the electricity fails, the cooling system stops, which can cause damage to the crop or worse very quickly. Growing a crop in a desert climate therefore requires large investments and is associated with high operating costs as well as a significant operating risk.

The object of the invention is to provide a method of the type described in the opening paragraph, which entails less costs and a lower operational risk.

In the method according to the invention this object is achieved by reflecting at least half of the incoming daylight, extracting air near the crop with water evaporated by the crop, blowing this air above the crop and blowing it above the crop. blown air providing a free connection to the outside air.

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Although in traditional horticulture the rule applies: "One percent less light = one percent less yield" / reflecting at least half of the incoming daylight in a desert climate only results in a minimal reduction in the yield of the crop. Above a certain light intensity / on the order of 80-100 W / m2 /. hardly any increase in yield occurs. However, by reflecting at least half of the incoming daylight in such a desert climate, the heat load is reduced proportionally. The cooling effect that occurs through the evaporation of water through the crop / is sufficient to compensate for this limited heat load. A separate evaporative cooling installation is therefore unnecessary. Evaporation through the crop is stimulated by extracting air near the crop. Due to the free connection to the outside air, an amount of dry air can be supplied / which is mixed with the air blown out above the crop.

With the measure of claim 2, the method according to the invention can be optimally applied.

In a desert climate, the temperature can drop significantly at night / even close to freezing. This drop in temperature is the result of the strong radiation. The measure of claim 3 prevents the temperature in the cultivation hall from dropping too much at night. In many cases, additional heat supply can be eliminated at night / at least greatly saved on this.

The invention also relates to and provides a cultivation hall for carrying out the method according to the invention. This cultivation hall comprises a frame and a roof / and according to the invention this roof comprises non-transparent / reflective material / and has openings / for forming a free connection with the outside air over a considerable part of its surface. Through the use of non-translucent reflective material alternating with openings in the roof, an accurate light transmission can be obtained / independent of any dust or sand deposits on the roof.

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The measure of claim 5 supports the air management desired according to the method.

A very favorable embodiment is obtained when the roof comprises spaced apart strip-like elements of reflective material placed at intervals. This makes the roof easy to manufacture and assemble.

According to a further development, the roof comprises two / mutually displaced layers of strip-shaped elements. This makes it possible to prevent / or at least reduce direct solar radiation.

If one of the layers is supported relative to the other / in the direction transverse to the strip length / slidable, the desired solar irradiation can moreover be easily set.

When the strip-shaped elements are gutter-shaped, they acquire a considerable self-stiffness and can moreover serve for collecting and guiding rainwater.

A particularly favorable construction of the cultivation hall 20 according to the invention is characterized in claim 10.

The strip-shaped elements are preferably made of aluminum. This material can remain highly reflective for a long time and is electrically conductive, so that it can be prevented from becoming statically charged by means of a suitable earth connection. Static charge would cause dust to stick to the slats / which would reduce the reflective properties.

The invention will be further explained hereinafter with reference to some exemplary embodiments shown in the figures.

Fig. 1 schematically shows a cultivation hall for applying the method according to the invention.

Fig. 2 shows a partly broken away perspective view of a preferred embodiment of a cultivation hall according to the invention.

Fig. 3 shows a schematic section according to line III-III in FIG. 2.

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Fig. 4 shows a schematic section according to line IV-IV in fig. 2.

Fig. 5 shows a partly broken away perspective view of a constructional detail of the device 5 according to FIG. 2.

Fig. 6 and FIG. 7 show alternative embodiments for the roof of a cultivation hall according to the invention.

Fig. 8 schematically shows a preferred construction of the cultivation hall according to the invention.

FIG. 9 shows a partly broken away perspective view corresponding to FIG. 2 of another embodiment of the cultivation hall according to the invention.

The cultivation hall 1 schematically shown in Fig. 1 comprises a roof 2 which comprises reflective material and has openings over a considerable part of its surface. Crop 3 has been planted in cultivation hall 1. According to the invention, at least half of the incoming daylight 4 is reflected. The reflecting daylight is indicated with the arrow 5. By admitting less daylight into the cultivation hall 1, only a very small decrease in the yield of the crop 3 occurs, but the heat load in the cultivation hall is very considerably reduced. By means of a schematically indicated ventilation device 6, air is extracted near the crop 3 with water evaporated by the crop / indicated by arrow 7 /. This air is recirculated and blown out above the crop by means of air distributors 8. In the roof 2, as already noted, there are openings, so that a free connection to the outside air is present above the blown out air. As a result, part of the air blown out of the distributors 8 is expelled from the cultivation hall and replaced by outside air / which mixes with the remaining ventilation air. The outside air is very dry, so that the relative humidity of the mixed air is lower. Hereby the evaporation by the crop 3 is stimulated. 35 This evaporation / which can amount to one liter of water per square meter / extracts an amount of heat from the environment / which more than compensates for the heat load as a result of the remaining irradiating daylight. A separate 6700015 "* 9 5.

cooling device is therefore unnecessary. The moisture exchange through the roof 2 is indicated by the arrows 9.

It is clear that with the method according to the invention only an amount of water corresponding to the consumption of the plants needs to be supplied, and that in addition there is only a small dependence on electrical energy. Should the ventilation device 6 fail, then the open roof 2 will still exchange moist air in the cultivation hall with dry air outside the cultivation hall, so that the crop 3 is not endangered.

Fig. 2 shows a cultivation hall 10 for application of the method according to the invention. This cultivation hall comprises a number of uprights 11 and has a sawtooth-shaped roof in cross section, which comprises so-called gutter beams 12 and ridge beams 13. These beams each consist of two parts, a fixed profile part 15 and a sliding profile part 14 which can be slid in the longitudinal direction. As shown, a number of slots 16 are arranged in each of the profile parts 14, 15, through which 20 slats 17 are guided. These slats, which are preferably made of aluminum, form the reflective roof part.

When the fins are made of a conductive material, such as aluminum, they can be grounded so that they cannot build up a static charge. Static charge is unfavorable because it retains dust particles that reduce reflection.

As shown in Fig. 3, with the construction of the roof as shown in Fig. 2, in which two mutually displaced layers of strip-shaped elements 17 are present, it can be achieved that the incident daylight 4 is diffused into the interior of the cultivation hall. Direct sun irradiation, with the possible danger of leaf burn, is thereby avoided.

It will be clear that by shifting the lamella layers transverse to the strip length, as possible with the embodiment of fig. 2, a desired degree of direct radiation can be set. For example, in the middle of the day when the sun is strongest, the in fig.

8700015 r 6 3 shown mutually offset position of the slats can be set to avoid direct radiation, while at the beginning and the end of the day the slats can be adjusted relative to each other, so that direct sunlight is possible. . Optionally, the slats of the bottom layer can be rotatable, as indicated by 18, so that an even stronger reflection is obtained, as indicated by the dotted lines.

Fig. 4 clarifies the ventilation principle. Due to the sawtooth shape of the roof, a flow of air blowing across the roof, as indicated by arrows 23, will create a suction through which the moist air, indicated by arrows 24, is sucked out of the interior of the cultivation hall. In this embodiment, the gutter beams 21 and ridge-15 beams 20 are non-slidable. The slats 22 are set at a fixed position from each other.

They are tensioned to prevent the slats from sagging or flapping due to the influence of the wind. An example of a tensioning device is shown in Fig. 5. The frame 30 of the cultivation hall carries heads 29 at a number of places on the longitudinal ends of the slats 38 over which a sliding guide 31 can slide. In this sliding guide, a turnbuckle 35 is rotatably received, which rests against a pressure plate 36. On the other side of the pressure plate 36, there is included a spring system 37 that rests against a face of the head 29. The springs 37 can be, for example, a series of disc springs. Tensioning the turnbuckle 35 pushes the sliding guide 31 to the left as seen in Fig. 5. A girder 33 is mounted on the sliding guide 31 by means of bolts 34. The bolts protrude through slotted holes in a support 32 which is fixedly connected to the beam 33. The slats 38 are provided at their end with a recess that fits over a projection 39 connected to the beam 33. A cap 40 is mounted over this projection 39, thereby enclosing the relevant slat 38. When mounting the roof of the cultivation hall, the turnbuckle 35 is first loosened as far as possible, after which the bolts 34 are tightened. Then the clamping screw 35 is tensioned so that the slats 38 come under a suitable pretension. Due to the spring tensioning device, the slats remain tensioned even when the slats 38 expand due to temperature influences.

Pig. 6 shows an alternative embodiment of a roof for a cultivation hall according to the invention. The roof 43 includes a plurality of adjacent fixed slats 49 and a plurality of gutter-shaped slats 44 disposed therebetween and below. Each of the gutter-shaped slats 44 carries at its opposite ends a pin 45 which projects into a slot 10 / which is provided in a the frame of the cultivation hall connected part. The channel-shaped slat 44 can therefore be moved from the open position as indicated by dotted lines 47 / to a closed position indicated by solid lines. Also, as indicated by 46, an arbitrary inclined intermediate position can be set in order to obtain a certain desired reflection.

As shown in Fig. 7, gutter profiles can also advantageously be used in a two-layer embodiment. Rainwater that falls between two gutter profiles 51 in the top layer 20 collects in a gutter profile underneath / and is discharged to the lowest side / at the location of a gutter beam /.

When the profiles 51 are used in a two-layer system with mutually displaceable layers /, a suitable adjustment of the radiation can be obtained in the same manner as in Fig. 2.

The cultivation hall construction 52 shown diagrammatically in Fig. 8 comprises a number of uprights 53 # arranged in parallel rows and carrying a ridge girder 56 at their top end. Between the uprights 53 of two adjacent rows, at a lower level, cross beams 54 are provided, which in the middle bear a gutter beam 55 extending parallel to the ridge beam. At least a number of slats 57 are firmly connected under tension to both the gutter beams 55 and the ridge beams 56. This results in a rigid truss construction of the cultivation hall 52. In this way, forces # exerted by the crop on the cross beams 54 are partially absorbed by the slats 57 and passed on to the ridge beams 56 and the uprights 53.

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In combination with the advantage of the cultivation hall according to the invention / which is not very sensitive to pressure differences as a result of strong wind / a very rigid light construction can hereby be obtained.

The embodiment variant of a cultivation hall 60 according to the invention shown in Fig. 9 is provided with a roof with blades 61 extending in the longitudinal direction of the sawtooth profile of the roof. The slats 61 are attached to strips 62 arranged at regular intervals. A cultivation hall such as the cultivation hall 60 / with blades 61 / extending in the longitudinal direction of the sawtooth profile can be used when the prevailing wind direction relative to the position of the sun makes this desirable. .

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Claims (11)

Method for growing a crop in a desert climate / comprising placing the crop in a cultivation hall such as a horticultural greenhouse / regularly adding water and fertilizers to the crop / exposing the crop to daylight and cooling at least during the day of the cultivation hall interior / characterized by reflecting at least half of the incoming daylight / extracting air near the crop with water evaporated by the crop / blowing this air above the crop and providing a blown air above the blown air free connection to the outside air. 2. Method as claimed in claim 1 / characterized in that such an amount of irradiated daylight is reflected / that an intensity in the order of magnitude of 100 W / m2 remains near the crop. 3. A method according to claim 1, characterized by reflecting a corresponding part of the heat radiating from the hall interior. Production hall for carrying out the method according to one of the preceding claims / comprising a frame / walls and a roof / characterized in that the roof comprises non-translucent / reflective material and over a considerable part of its surface openings. 5. Production hall according to claim 4, characterized in that the roof is sawtooth-shaped in cross section. The production hall according to claim 4 or 5, characterized in that the roof comprises spaced apart strip-shaped elements of reflective material spaced apart. 7. Production hall according to claim 6, characterized in that the roof comprises two mutually displaced layers of strip-shaped elements. 8. W V Ü l ό P * 10 the direction transverse to the strip length / slidable is supported. Cultivation hall according to claim 7, characterized in that one of the layers relative to the other / in Cultivation hall according to any one of claims 6-8 / characterized in that the strip-shaped elements are gutter-shaped. Production hall according to any one of claims 6-9 / characterized in / that the frame comprises a number of uprights arranged in parallel rows / connecting the upright ends of the uprights of each row / connecting uprights 10 of adjacent rows in transverse direction thereto / at an intermediate level to these mounted sleepers and to the sleepers connected / gutter beams extending parallel to the ridge beams / wherein the strip-shaped elements extend transversely to the ridge and gutter beams and at least some of them under tension voltage are permanently connected to these. Cultivation hall according to any one of claims 6-10 / characterized in that the strip-shaped elements are made of aluminum. £ 7 0 0 0 15 '