WO2019043341A1 - Device for soilless cultivation of plants and kit comprising such a device - Google Patents

Abstract

The invention concerns a device (1) for the soilless cultivation of plants comprising at least one longitudinal planar face (21) comprising cells (3) comprising a window (30), a top plate (31) and a bottom plate (32). The top plate (31) is turned towards the inside of the column (2) and downwards. The bottom plate (32) is turned towards the outside of the column (2) and upwards. The cell (3) allows a plant pot (4) to be partially inserted into the window (30), holding it with an upward inclination. Each cell (3) is formed by cutouts in the face (21) that allow the window (30) to be formed, a top flap (35) and a bottom flap (36). The top plate (31) is formed by the top flap (35), which is folded inwards from the planar face with a downward inclination, and the bottom plate (32) is formed by the bottom flap (36), which is folded outwards from the planar face with an upward inclination.

Description

 SURFACE PLANT CULTURE DEVICE AND KIT COMPRISING SUCH A DEVICE

Technical area

The present invention relates to the field of above-ground plant culture devices that equip installations such as hydroponic or aquaponic installations.

State of the art

Hydroponic and aquaponic facilities have been developed for above ground crop cultivation, such as vegetables or plants. Hydroponics and aquaponics generally use a much lower amount of water than is required for traditional land crops.

In the case of hydroponics, plants are grown directly in a water-based nutrient solution and chemical or organic liquid fertilizer containing all the essential nutrients, minerals and trace elements required for the development of these plants. In the case of a liquid fertilizer of organic origin, it is called bioponics.

Aquaponics allows the recycling of nitrogenous waste generated in aquaculture by fish or crayfish, as fertilizer for plants grown on the principle of hydroponics. The nitrogenous waste, loaded with ammonia, is transported by the water of the basin then transformed by bacteria and worms in nitrite then nitrate, the latter being able to be absorbed by the plants. The water is further purified and returned to the basin, which turns in a closed circuit.

It is known to use devices serving as a support for aboveground crop cultivation, for example the device described in international patent application WO 2011/016856 A1. This device is presented as a vertical column in the form of a four-sided tower, with a slot arranged along one of its faces. A media is inserted into the tube and allows rooting plants that pass into the slot to push out of the column. This media also allows the retention of the nutritive aqueous solution.

It is also known the following patent applications and patents: US 4,070,793; US 2004/0103583 A1; US 2006/0032128 A1 and US 4,175,355. In the US Pat. No. 4,070,793 and in the patent application US 2004/0103583 A1, the above-ground plant cultivation devices comprise a tube provided with cross cuts allowing the passage of the plants, the roots of these plants developing in a medium inserted into the plant. said tube. In the patent application US 2006/0032128 A1, the above-ground plant cultivation device comprises a cylindrical vertical column. Cells are arranged around and on the height of the column. These cells each consist of a tip opening out of the column with an inclination upwards. The column is filled with media. The plant plants are inserted into the cells and supported by them, their roots clinging and developing in the media.

In US Pat. No. 4,175,355, the above-ground plant cultivation device comprises a tube to which pots are attached. The tube comprises orifices which receive irrigation tips, these irrigation tips being housed in the bottoms of the pots which are positioned against the outer face of the tube. Above ground vegetable cultivation devices are also used in the patent applications published under the numbers WO2017058116A1, WO2011145619A1, US2016120141A1, FR2968890A1 and FR2959387A1 among which, in particular, the international patent application WO2017058116A1 discloses an aboveground plant cultivation device. comprising a hollow column of polygonal shape provided with at least one planar face extending vertically on which cells are arranged. Each cell defines a window and includes a curved top wall and a curved bottom wall. The top wall is oriented towards the inside of the column with a downward inclination and the bottom wall is oriented towards the outside of the column with an upward inclination. The window and the upper and lower walls allow the insertion in part in said window of a cylindrical pot for plant plant, maintaining it with an inclination upwards.

Summary of the invention.

The present invention aims to design a variant of above ground plant culture device, which comprises at least one longitudinally extending flat face on which cells are arranged. Each cell defines a window and includes an upper plate and a lower plate. The top plate is configured to face the inner side of the planar face with a downward orientation and the bottom plate is configured to face the outer side of the planar face with an upward orientation. In further, the window and the upper and lower plates are configured to partially insert into said window a pot for plant plant, maintaining it with an upward inclination. Of course this inclination of the pot in the window is variable according to the orientation of the upper and lower plates, this inclination of the pot may vary between a first extreme position, lying horizontally, and a second extreme position, standing upright.

According to the invention, each cell is formed by cutouts on the flat face. These cuts allow the formation of the window, an upper flap and a lower flap. The upper plate is formed by the upper flap which is configured to be folded towards the inner side of said flat face with a downward inclination and the bottom plate is formed by the lower flap which is configured to be folded towards the outer side of said flat face with an upward inclination.

Thus, the design of the above-ground plant culture device according to the invention facilitates the preparation of plant plants in pots which are then reported in the cells on said flat face. This preparation of a plant plant will be done by placing a substrate in the pot in which we have introduced the roots of the plant plant. It is then sufficient to position the plant growing device above ground at the desired location and to insert cells into the cells containing plant plants. This design of the device also facilitates the diversification of plant plants, to have for example in some pots salads and in other pots of herbs. The introduction of a nutritive aqueous solution into the device, on the side of the inner wall of the flat face and on the upper plates, will ensure irrigation of the pots and the growth of the plant plants. It goes without saying that the pots will be perforated to allow irrigation of the roots arranged inside these pots. One can also provide a pot whose material ensures in itself a retention of water.

According to one embodiment of the device according to the invention, the upper plate comprises perforations. These perforations will facilitate the irrigation of the pot disposed under the upper plate.

According to one embodiment of the device according to the invention, each cell comprises water retention means configured to come into contact with a plant plant pot inserted in said cell. In one embodiment, the means for retaining a nutrient aqueous solution comprise a strip whose material ensures retention of this aqueous nutrient solution. One could consider having a retention foam inside the device and coming into contact with the pots inserted in the cells. Preferably, the strip of material is positioned under the upper plate so as to come into direct contact with a pot for plant plant inserted into the cell. One could consider arranging this band above the top plate and let it hang so as to come into contact with the pot.

According to one embodiment of the device according to the invention, each cell comprises a tongue which is arranged at the upper side of the upper plate and which extends towards the outer side of the flat face with a downward inclination. This tab is configured to hold a plant pot inserted in the window to prevent its release. Thus, when the plant plant has developed, the tab ensures the maintenance of the pot which tends to tilt towards the outside of the cell under the effect of the weight of the vegetation. According to this embodiment of the device, the tongue is also formed by a cutout implemented on the flat face. Preferably, this cutout for forming the tongue is arranged in a portion of the upper flap located at a fold line of the upper flap.

According to a first embodiment of the device according to the invention, the latter comprises the shape of a polygonal section tube, at least one of the faces comprises cells. Preferably, the tube has a rectangular or square section, two opposite faces of said tube being provided with cells. One could also consider a tube of rectangular or square section with only one of the four faces which would be provided with cells. One could also provide a triangular section tube with only one of the three faces that would be provided with cells. One could also provide cells on each side or on some sides of the tube, this tube having any polygonal section or any section with at least one rectilinear side constituting the at least one plane face. Preferably, when two opposite faces are provided with cells, the cells on the first face and the cells on the second face are arranged in staggered rows. This ensures a better distribution of the pots inserted on the tube. According to a second embodiment of the device according to the invention, it comprises two inclined faces forming a vertex, at least one of the two faces comprising cells. In one embodiment, these two inclined faces comprise cells. This implementation makes it possible to keep the pots arranged in the windows with an upward inclination more or less vertically, which allows the development of the plant plant more or less vertically, without any hindrance of the neighboring plant plants. Indeed, some plants grow strongly and could bend and break or could stifle plants placed directly below, if the pots were positioned with a stronger inclination, as is the case when the plane face comprising said cells is arranged vertically. By tilting said face of the device, it makes it possible to restore a more or less vertical position of the pots arranged in the cells, which reduces the risk that bulky plants bend and break and that said bulky planes encumber the surrounding space occupied by the cells. other nearby plants.

According to one embodiment of the device according to the invention, the at least one plane face extends longitudinally upwards. In addition, all the cells on the same plane face are distributed one above the other over the height of said flat face on at least one row. In one embodiment, the cells on a flat face will be arranged in a single row, but one could consider several rows on the same flat face, according to the width thereof on the device.

According to one embodiment of the device according to the invention, the at least one plane face extends longitudinally horizontally. In addition, all the cells on the same plane face are distributed next to each other along said plane face in at least one row. According to a preferred embodiment of the device according to the invention, the window of each cell is of square shape. Other variants of shapes could be envisaged, in particular a rectangular shape or even a circular shape.

According to one embodiment of the device according to the invention, it is made of polypropylene material (PP), preferably of alimentary alveolar polypropylene (PPAA). The use of this material makes it possible to lighten the device. This will further facilitate the cutting of planar faces on the device for the formation of the window, the upper flap and the lower flap.

According to one embodiment of the device according to the invention, the latter consists of at least one plate configured to be folded so as to form said device. In other words, the at least one plate comprises at least one fold line defining faces once the plate bent at the level of the at least one fold line, at least one of said faces comprising cells. Other embodiments are conceivable, for example a device consisting of several panels constituting different faces of said device, some or all of which are provided with said cells, said plates being assembled together by means of assembly means, for example a control system. snap between the edges of the adjoining panels. According to one embodiment, the device comprises a lining of the inner wall of the at least one face comprising cells. Preferably, this liner is dark in color, preferably black, while the at least one face comprising the cells is light in color, preferably white in color. This liner advantageously makes it possible to reduce the leakage of nutrient aqueous solution through the cell windows.

Of course, it is possible to envisage a variant of the device according to the invention combining one and / or the other of the characteristics of the aforementioned embodiments.

The invention also relates to a kit comprising at least one above-ground plant culture device which has one and / or the other of the aforementioned characteristics. The kit also includes as many plant plant pots as cells on the at least one device. These pots are of a shape adapted to that of the window of the cell. These pots will be perforated and / or in a material ensuring in itself a retention of the aqueous nutrient solution.

Preferably, the kit according to the invention also comprises substrate which will be placed in the pots during the preparation of the plant plants.

Preferably, the kit according to the invention further comprises a pump and an irrigation circuit. This pump and this irrigation circuit will allow the distribution of the aqueous nutrient solution inside the device.

Brief description of the figures The features and advantages of the invention will appear on reading the following description based on figures, among which:

FIG. 1 illustrates an overall view of the above-ground plant culture device, in one embodiment, in the form of a vertical tube with a square section;

 FIG. 2 illustrates two opposite faces of a tube similar to that of FIG. 1, the only difference being the number of cells present on the opposite faces, which are brought together in the same plane in this FIG. 2 in order to show the disposition in FIG. stagger cells on both sides;

 FIG. 3 illustrates a pot inserted into a cell of the device according to the invention;

Figures 4 and 5 schematize two other variants of the device according to the invention, one having a triangular shape and the other a form of horizontal duct; FIG. 6 partially illustrates cells receiving pots on both inclined faces of a device according to FIG. 4;

 Figure 7 illustrates two opposite faces of a horizontal duct similar to that of Figure 5, which are brought in the same plane in this figure 7 to show the staggered arrangement of the cells on both sides;

 Figures 8 and 9 illustrate the presence of a double skin inside the device which has the shape of a vertical square tube;

 Figures 10 and 11 illustrate a preferred embodiment in the form of plates of the device of Figures 8 and 9.

detailed description

In the remainder of the description, the above-ground plant culture device of the invention is referred to as "device", unless otherwise indicated. In addition, the same references are used to define the same characteristics or their equivalents, according to the different variants of the device.

In Figure 1, the device 1 comprises a column 2 which is hollow and which extends vertically. Column 2 is in the form of a square section tube having four faces 21, 22, 23, 24. However, it would be possible to provide a rectangular section tube (also with four faces 21, 22, 23, 24) or triangular (With only three faces), or other sections of polygonal shapes or sections of any shape with at least one plane face. In FIG. 1, cells 3 are arranged in a vertical row on a first face 21 and, likewise, on a second face 23 opposite the first face 21. In FIG. 2, these two opposite faces 21, 23 have been brought back in the same plane in order to highlight the staggered arrangement of the cells 3 on the first face 21 vis-à-vis the cells 3 on the second face 23. All the cells 3 are preferably of identical designs. One could envisage a variant of the device 1 with cells 3 only on the face 21 of the column 2. One could also consider a variant of the device 1, with a column 2 having any other shape and a flat face similar to the face 21 , on which the cells 3 are arranged. Another variant of the device 1 could be envisaged with a column 2 provided with one or two flat faces, similar to the faces 21 and 23, several vertical rows of cells 3 being arranged on each face. plane of greater width in order to be able to implement these several rows of cells 3. These examples are not limiting; at the limit, cells 3 could be provided on all the plane faces present on the column 2, by consequently dimensioning the section of this column 2. FIG. 3 shows a cell 3 on the face 21 of the column 2. This cell 3 comprises a window 30, an upper plate 31 which is inclined downwards inside the column 2, and a lower plate 32 which is tilted upwardly outside column 2, as shown in FIG. 3. The window 30 is preferably square in shape, but other shapes could be envisaged depending on the shape of the pot 4. receives, for example a rectangular shape, cylindrical or oval. The upper side 310 of the upper plate 31 is attached to the upper side 300 of the window 30. Similarly, the lower side 320 of the lower plate 32 is attached to the lower side 301 of the window 30. The upper plates 31 and lower 32 are more or less parallel to each other in the position of use illustrated in Figure 3. The cell 3 also comprises a tongue 33 which is inclined downwards and outside the column 2, as 3, the upper side 330 of this tongue 33 is attached to the upper side 310 of the upper plate 31, said tongue 33 being more or less disposed at right angles to the upper plate 31, as illustrated in FIG. 3. According to this configuration, the cell 3 can receive a pot 4 of plant plant comprising a rim 40. When the pot 4 is in position in the window 30, the lower portion 400 of the rim 40 comes resting against the upper side 321 of the lower plate 32 and the upper part 401 of the flange 40 is disposed under the tongue 33 and bears against the lower face 311 of the upper plate 31, at its upper side 310, as shown in FIG. FIG. 3 illustrates. Of course, the lower portion 41 of the contour of the pot 4, adjacent to the inner face 322 of the lower plate 32, may bear on said inner face 322 under the effect of the weight of the vegetation. developing. The pot 4 is held in position in the window 30, with an upward inclination, thanks to these abovementioned supports on the upper plate 31 and on the lower plate 32. In addition, the tongue 33 makes it possible to prevent the pot 4 from switch outward from cell 3 under the action of vegetation weight.

The following passage will describe the implementation of the window 30, the upper plate 31, the lower plate 32 and the tongue 33 on the cell 3. As illustrated in Figure 2, the cell 3 comprises two lateral cutouts 340, 341, a transverse cutout 342 disposed halfway up the cell 3, and two fold lines 343, 344, one 343 at the upper end of the cell 3 and the other 344 at the lower end of the cell 3, which defines the square-shaped window 30 delimited by the lateral cutouts 340, 341 and by the fold lines 343, 344 and allows forming an upper flap 35 and a lower flap 36. upper flap 35 can be folded at the upper fold line 343, towards the inside of the column 2 with a downward inclination, thus forming the upper plate 31. Similarly, the lower flap 36 can be folded at the lower fold line 344, out of the column 2 with an upward inclination , thereby forming the lower plate 32. The cell 3 also comprises a cutout 345 in U extending on the upper flap 35 from the upper fold line 343, this cutout 345 allowing the formation of a small flap 37. This small flap 37 can be folded at the upper fold line 343, outward of the column 2 with a downward inclination, thus forming the tongue 33.

In FIG. 3, the cell 3 comprises a strip 38 made of a material providing a retention of water, for example a geotextile material. This band 38 is positioned under the lower face 311 of the upper plate 31, upper edge 380 being attached to the upper side 310 of said upper plate 31. The band 38 hangs under the action of gravity. When the pot 4 is inserted into the cell 3, this band 38 comes into contact with the upper part 42 of the outline of the pot 4, as shown in FIG. 3. The length of the band 38 is dimensioned so that its upper part 380 covers completely the upper portion 42 of the pot contour and its lower portion 381 hangs behind the bottom 43 of the pot 4, as shown in Figure 3. The upper plate 31 comprises perforations 312 which pass through its thickness. When the aqueous nutrient solution is injected inside the column 2 by its upper end 20, this aqueous nutrient solution flows along the inner wall 210 of the face 21 and on the upper face 313 of the upper plate 31. The Nutrient aqueous solution passes through the perforations 312 and impregnates the strip 38 which ensures retention of said aqueous nutrient solution. The pot 4 is either perforated or consists of a material providing water retention, to allow irrigation of the roots of the plant plant 5 disposed in the pot 4, through the band 38. Of course, the aqueous nutrient solution can also flow directly on the strip 38 and / or on the pot 4 by the lateral sides of the upper plate 31. It is also possible to use a sock of geotextile material which wraps the pot 4, instead of band 38.

One could consider, in a variant, to position the band 38 on the top of the upper plate 31, that is to say in abutment against the upper face 313 of the upper plate 31 and provide the band 38 sufficiently wide and long so that it falls on the lateral sides of the upper plate 31 and covers the contour of the pot 4, the lower portion 381 of the band 38 also for the rear of the bottom 43 of the pot 4.

Preferably, the column 2 is made of polypropylene (PP) material, preferably of alimentary alveolar polypropylene (PPAA), which makes it possible to lighten this column considerably. 2. This further facilitates the making of the cuts 340, 341, 342, 345 on the cell 3. However, it is possible to envisage the use of the column 2 in other materials offering characteristics comparable to polypropylene in order to constitute the cells. 3 and allow the realization of the device 1 in the form of a plate, as detailed below. A base (not shown) attached to the lower end 25 of the column 2 can be provided so as to stabilize this column 2. Alternatively, a hook (not shown) attached to the upper end 20 of the column can be provided. 2, so as to suspend said column 2. It is also possible to provide anchoring means (not shown) on a wall, in particular in a variant of the column 2 where only one face 21 has cells 3, the opposite face 23 for anchoring on the wall.

It is also possible to replace or replace the band 38, a media (not shown) disposed within the column 2 over its entire height, the media ensuring retention of the aqueous nutrient solution so as to irrigate the pots 4 openwork arranged in the cells

3. For example, this media may consist of an aerated foam, a geotextile, clay balls.

It is also conceivable that the pots 4 themselves are made of a material ensuring retention of the aqueous nutrient solution, which will also irrigate the roots of the plant plants 5 in these pots 4. It is also possible to use peat pots wrapped in geotextile socks. In FIG. 1, the faces 21, 23 each comprise four cells 3, but this number is not limiting. By way of example, in FIG. 2, eight cells 3 are represented on each of the two faces 21, 23. Preferably each row of cells 3 will comprise between two and ten cells 3.

The outside of the column 2 is preferably white in color to allow reflection of the light. This also helps repel some insects.

In the remainder of the description based on FIGS. 4 to 11, the variants of the device 1 comprise cells 3 whose implementation is identical to that described above with regard to FIGS. 1 to 3. The description of the cells 3 n is therefore not detailed again for these variants of the device 1. In the variant of Figures 4 and 6, the device 1 has a triangular shape with two faces 61, 62 planes which extend longitudinally upwards with an inclination and 63. On these two faces 61, 62 are implemented cells 3. For each cell 3, it is found that the upper plate 31 is oriented towards the inner side 611, 621 of the face 61, 62 with an inclination down more or less vertically. Similarly, the bottom plate 32 is oriented towards the outer side 612, 622 of the face 61, 62 with an upward inclination more or less vertically. Thus, the pot 4 is more or less disposed upright, vertically, once housed in the window 30 of the cell 3. This implementation is advantageous especially for plant plants that grow strongly or with long stems . It is possible to envisage variants of the device 1 on this principle of implementation of FIGS. 4 and 6, with only one of the two faces 61, 62 which includes cells 3. The device 1 may comprise only these two faces 61, 62. However, , as shown in FIG. 4, the device 1 may comprise a third face 64 which constitutes a base and which connects the lower edges 613, 623 of the two inclined faces 61, 62. It is also possible to envisage several rows of cells 3 on each of these two inclined faces 61, 62, according to their width.

In the variant of Figures 5 and 7, the device 1 in the form of a hollow conduit 7 which extends horizontally. The duct 7 is in the form of a square section tube having four faces 71, 72, 73, 74. However, it would be possible to provide a rectangular section tube (also with four faces 71, 72, 73, 74) or triangular (With only three faces taking the principle of the device 1 of Figures 4 and 6 extending over the length in the horizontal), or other sections of polygonal shapes or sections of any shape with at least one planar face. Cells 3 are arranged next to each other on a first face 71 and, likewise, on a second face 73 opposite the first face 71. In FIG. 7, these two opposite faces 71, 73 have been brought back into a same plane to highlight the staggered arrangement of the cells 3 on the first face 71 vis-à-vis the cells 3 on the second face 73. One could consider a variant of the device 1 with cells 3 only on the face 71 7. Another embodiment of the device 1 could also be envisaged, with a conduit 7 having any other shape and a flat face similar to the face 71, on which the cells 3 are arranged. Another variant of the device could be envisaged. 1 with a duct 7 provided with one or two flat faces, similar to the faces 71 and 73, several horizontal rows of cells 3 being disposed on each planar face of greater height. The lower face 74 constitutes a support base of the device 1; this does not exclude however to hang or suspend this device 1. It could also be considered to float the device 1, providing a floating sole (foam thickness, inflated gasket ...) under this underside 74 ( sole not shown). In these two variants of FIGS. 4 and 6 and FIGS. 5 and 7, the device 1 also comprises means for retaining the aqueous nutrient solution, for example a retention foam (not shown) disposed inside the device 1 and contacting the pots 4 inserted into the cells 3. It is also possible to provide strips similar to the band 38 in FIG. 3. There will also be provided an irrigation circuit for this aqueous nutrient solution, for example a pipe (no illustrated) provided with perforations along its length to spread the aqueous nutrient solution inside the device 1, this nutritive aqueous solution soaking the retention foam.

In the variant of Figures 8 and 9, the device 1 comprises a column 2 identical in design to that described above with reference to Figures 1 to 3. The device 1 further comprises a jacket 8 of identical shape to the column 2, c ' that is to say with four faces 81, 82, 83, 84, this jacket 8 conforming to the internal walls 210, 220, 230, 240 of the faces 21, 22, 23, 24 of said column 2. While the column 2 is preferably of light color, preferably white, so as to reflect the light, the jacket 8 is preferably dark in color, preferably black, so as to absorb heat. In FIG. 8, the jacket 8 comprises on its face 81 windows 9 of dimensions slightly greater than the windows 30 of the cells 3 on the column 2; these windows 9 allow to let the upper flap 35 inside the column 2 and the liner 8, when it is folded for the formation of the upper plate 31. It is therefore understood that the windows 9 on the jacket 8 and windows 30 on column 2 are in agreement. Of course, such windows 9 are also provided on the face 83 of the jacket 8 opposite the face 81, in the presence of cells 3 on the face 23 of the column 2 opposite the face 21.

In the presence of this jacket 8, the nutrient aqueous solution no longer flows along the inner wall 210 of the face 21 of the device 2, but along the inner wall 810 of the face 81 of the jacket 8, then on the face upper 313 of the upper plate 31 of the cell 3, said nutrient aqueous solution then passing through the perforations 312 to soak the strip 38 which ensures retention of said aqueous nutrient solution. This implementation reduces leakage of nutrient aqueous solution from the windows 30 on the face 21 of the column 2. The principle is the same with the inner wall 830 of the face 83, opposite to the face 81, when cells 3 are present on the face 23 of the column 2, opposite to the face 21. Other retention means that a band 38 are possible, as previously.

As illustrated with reference to FIGS. 9 to 11, the column 2 and the jacket 8 of the device 1 are implemented from plates 200, 800 made preferably of polypropylene (PP), preferably of alimentary alveolar polypropylene (PPAA). The plate 200 constituting the column 2 comprises fold lines 201, 202, 203 for defining the four faces 21, 22, 23, 24 of the column 2; on the faces 21, 23 are implemented the cells 3 with a staggered arrangement. Similarly, the plate 800 forming the liner 8 comprises fold lines 801, 802, 803 for defining the four faces 81, 82, 83, 84 of said liner 8; on the faces 81, 83 are implemented the windows 9 with a staggered arrangement. The free longitudinal edges 804, 805 of the plate 800 forming the liner 8 are arranged opposite the free longitudinal edges 204, 205 of the plate 200 constituting the column 2, once said plates 200, 800 folded and the device 1 constituted as shown in Figure 9. This improves the sealing of the device 1. In Figure 10, the plate 200 constituting the column 2 comprises notches 10 arranged along the first free longitudinal edge 204 which cooperate with fastening lugs 11 arranged along the second free longitudinal edge 205, during the folding of the plate 200 for the constitution of said column 2. Other fastening means are conceivable. The establishment of these fastening means on the column makes it possible to maintain the sleeve 8 housed in said column 2.

In a manner comparable to the above, a jacket can be implemented inside the conduit 7 for the device 1 of FIGS. 5 and 7. It is also possible to envisage a liner (not shown) of preferably dark color, preferably black, and of triangular shape for the device 1 of Figures 4 and 6, this liner matching the inner walls 610, 620 of the two inclined faces 61, 62 each provided with cells 3 and having windows 9 with a similar arrangement to said cells 3.

The device 1 of FIGS. 4 and 6 and that of FIGS. 5 and 7 are also implemented by means of a plate with fold lines, comparable to the device 1 of FIGS. 1 to 3 or FIGS. 8 to 11.

The device 1 according to the invention can be marketed independently. However, it is also possible to consider the marketing of an above ground crop kit (not shown in detail) comprising one or more devices 1 and pots 4 of a shape adapted to that of the window 30 on each cell 3. The number of pots 4 will correspond at least to the total number of cells 3 present on the device 1. The pots 4 will be perforated and / or in a material providing water retention. The kit may also include a substrate (not shown) which will be placed in each pot 4, for example clay balls, coconut fiber, rock wool, perlite or chili sphagnum. This substrate will anchor the roots of the plant and their development, while protecting them from light.

The kit may also include retention means, for example a geotextile foam, which will be inserted inside the device 1 and will contain the aqueous nutrient solution.

The kit may also include a pump (not shown) and a circuit (not shown) for irrigating the nutrient aqueous solution that circulates in this circuit through the pump. The circuit will spray the aqueous nutrient solution on the inner walls 210, 230 of the two opposite faces 21, 23 comprising the cells 3 and / or in the retention means housed inside the device 1. It can also be envisaged that the circuit comprises nozzles arranged inside the device 1, close to the cells 3, so as to spray the pots open 4 directly.

Other characteristics are possible on the device 1, without departing from the scope of the invention.

Claims

1. Device (1) of aboveground plant culture comprising at least one face (21, 23, 61, 62, 71, 73) extending longitudinally on which are arranged cells (3), each cell (3) defining a window (30) and comprising an upper plate (31) and a lower plate (32), the upper plate (31) being configured to face the inner side of said face with a downward orientation and the lower plate ( 32) being configured to face the outer side of said face with an upward orientation, the window (30) and the upper (31) and lower (32) plates being configured to partially insert into said window (30). a plant pot (4), holding it at an upward inclination, characterized in that each cell (3) is formed by cut-outs (340, 341, 342, 345) on said face (21, 23) , these cuts allowing the formation of the window (3 0), an upper flap (35) and a lower flap (36), the upper plate (31) being formed by the upper flap (35) which is configured to be folded towards the inner side of said face with a downward inclination and the lower plate (32) being formed by the lower flap (36) which is configured to be folded towards the outer side of said face with an upward inclination.

 2. Device (1) according to claim 1, wherein the upper plate (31) comprises perforations (312).

 3. Device (1) according to any one of claims 1 to 2, wherein each cell (3) comprises means (38) for retaining a nutritive aqueous solution configured to come into contact with a pot (4) for plant plant inserted in said cell (3).

 4. Device (1) according to claim 3, wherein the means for retaining a nutrient aqueous solution comprises a strip (38) whose material ensures retention of the aqueous nutrient solution.

 5. Device (1) according to claim 4, wherein the strip (38) is positioned under the upper plate (31) to come into direct contact with a plant pot (4) inserted in the cell (3).

6. Device (1) according to any one of claims 1 to 5, wherein each cell (3) comprises a tongue (33) which is arranged at the upper side (310) of the upper plate (31) and which extends to the outer side of the face (21, 23, 61, 62, 71, 73) with a downward inclination, said tongue being configured to hold a pot (4) of plant plant inserted in the window (30) so as to prevent its release.

 7. Device (1) according to claim 6, wherein the tongue (33) is formed by a cutout (345) implemented on the flat face (21, 23).

 8. Device (1) according to claim 7, wherein the cutout (345) for forming the tongue (33) is arranged in a portion of the upper flap (35) located at a fold line (343). of this upper flap.

 9. Device (1) according to any one of claims 1 to 8, which comprises the shape of a polygonal section tube, at least one of the faces (21, 23, 71, 73) comprises cells (3).

 10. Device (1) according to claim 9, wherein the tube has a rectangular or square section, two faces (21, 23, 71, 73) opposite said tube being provided with cells (3).

11. Device (1) according to claim 10, wherein the cells (3) on the first face (21, 71) and the cells (3) on the second face (23, 73), opposite to the first face, are arranged in staggered rows.

 12. Device (1) according to any one of claims 1 to 8, which comprises two inclined faces (61, 62) forming an apex (63), at least one of the two faces having cells (3).

 13. Device (1) according to claim 12, wherein the two inclined faces (61, 62) comprise cells (3).

 14. Device (1) according to any one of claims 1 to 13, wherein the at least one face (21, 23, 61, 62) extends longitudinally upwards, all the cells (3) on a same face (21, 23, 61, 62) being distributed one above the other over the height of said face (21, 23, 61, 62) on at least one row.

 15. Device (1) according to any one of claims 9 to 11, wherein the at least one face (71, 73) extends longitudinally to the horizontal, all the cells (3) on the same face ( 71, 73) being distributed next to one another along said face (71, 73) in at least one row.

 16. Device (1) according to any one of claims 1 to 15, wherein the window (30) of each cell (3) is square.

17. Device (1) according to any one of claims 1 to 16, which is designed polypropylene material (PP), preferably alimentary alveolar polypropylene (PPAA).

18. Device (1) according to any one of claims 1 to 17, which consists of at least one plate (200, 800) configured to be folded so as to form said device (1) ·

 19. Device (1) according to any one of claims 1 to 18, which comprises a lining (8) of the inner wall (210, 230, 610, 620) of the at least one face (21, 23, 61). , 62, 71, 73) comprising cells (3).

 20. Kit comprising at least one device (1) according to any one of claims 1 to 19 and as many pots (4) for plant plant as cells (3) present on the at least one device (1), said pots (4) being of a shape adapted to that of the window (30) of the cell (3).

 21. Kit according to claim 20, which further comprises a pump and an irrigation circuit.