EP3908101A1 - Module for soil-free growing - Google Patents

Abstract

The invention relates to a module for soil-free growing, the module consisting of a prismatic support member (2 to 5) having two angled panels (6, 7). The medial planes of the panels (6, 7) form an angle of between 30 and 40° with the horizontal plane and the panels (6, 7) constitute a watertight barrier between the space for roots and the space for shoots, and a plurality of openings pass through said panels in order to support a growing medium or a plug for sealing the openings that are not occupied by a growing medium.

Description

DESCRIPTION

TITLE: ABOVE GROUND CULTURE MODULE

Field of the invention

The present invention relates to the field of soilless cultivation, in particular of plants having at maturity a voluminous stem part, in particular of shape

spherical or of low height but extended in a transverse direction, such as lettuces or cauliflowers.

Above-ground cultivation, by hydroponics or aeroponics, makes it possible to very precisely control nutrient supply by soaking the root system in tubs containing a nutritive solution for cultivation in hydroponics, or by misting the root system with a pulverized nutritive solution. There are many advantages:

- It is a cleaner culture, which reduces the presence of insects and the risk of diseases, particularly in

aeroponics due to the absence of contact between the roots.

- Plants are not in contact with soil or potting soil but with water and nutrients

concentrated.

- Culture can be largely automated.

- Plants grow faster because all the growth energy is directed towards the foliage. Consequently, the weak development of the root system allows a

much higher concentration of plants in a limited growing space.

- The control of fertilization is simpler and more precise. The nutrient supply is perfect, the

growth is rapid and the yield optimal.

- Irrigation can easily be automated using a pump. State of the art

The international application W02008122290A2 describing a system is known in the state of the art.

hydroponics which comprises: an upper panel capable of carrying plants intended to grow in the hydroponic system; and a lower panel arranged under the upper panel so as to form between the panels a space allowing the roots of the plants to extend through the panel

higher into space.

The aforementioned panels each include a panel surface inclined downward, and a nutrient solution dispenser arranged to allow the

distribution of a nutritive solution between the above-mentioned upper and lower panels. The surfaces of the panels have a shape such that at least three, preferably at least four planes tangential to each aforementioned panel surface can be defined, none of said tangential planes of each panel surface being parallel or coincident.

This solution is not very satisfactory because the pyramidal shape of the culture supports creates significant variations in the density of the roots and therefore in the needs of misted nutrients depending on whether the plants are close to the tip or the top of the pyramid support. The dosage of

the misted nutrient supply is therefore particularly delicate and inevitably leads to excess nutrients, and to areas of insufficient nutrient supply.

Also known is the European patent application EP0361701A1 describing a cultivation installation formed by a first panel element and a first element

collector. The first panel element includes

first and second sheet portions, the first sheet portion having a plurality of openings. The first panel member also includes spacer means for holding the second sheet portion spaced from the first part of the sheet in order to define an interior space between them. The panel member also has first and second end portions in which at least one of the end portions has a first edge opening, the first edge opening and the

plurality of openings communicating with said space

interior. The first manifold includes a wall with an interior portion defining an interior space and an exterior portion. The dispensing member also has an end opening communicating with the interior space and connection means for sealingly connecting the dispensing member to the first panel member.

Also known is the Australian patent AU3767978 describing a support for growing plants comprising a plurality of elongated containers held by a support frame so that the containers are aligned in a generally parallel relationship with each other and the tallest containers being each located in a

position further back than the container immediately below to allow plants to grow freely.

Also known in the prior art is the international patent application WO2012050449 describing another example of a culture assembly for growing cultures,

comprising a series of reservoirs, each provided with a supply and a discharge of water provided with nutrients and other additives for growing crops, and a sealed bottom. A support is provided to support a plurality of cultures and support components to maintain the cultures in the tanks at a defined working height above the water. The support components include floating bodies with adjustable buoyancy.

Finally, the patent application US20130160362 describing an apparatus for cultivating one or more plants is known, which apparatus comprises at least a first and a second chamber separated from one another by a first wall of partition, the interior spaces of the first and second chambers being connected by one or more connection openings in the first partition wall, and in which the second chamber comprises one or more outlet openings which are arranged on a second partition wall

separation.

Disadvantages of the prior art

The solutions of the prior art using sloping structures aim to improve the exposure to natural sunshine and therefore provide for a slope calculated as a function of the zenith height of the sun, of the order of 48 ° in France, even a vertical slope.

Such an angle is not well suited for growing plants with large vegetation such as lettuces, or

other varieties of salad (escarole, curly, ...) which occupy a large radius near the substrate of

culture .

The solution, for those skilled in the art, consists of cultivation on horizontal flat supports, which allow sufficient spacing of the culture supports in order to

reserve room for growth. The disadvantage is then the low density of culture, requiring large greenhouses. To overcome this problem, horizontal culture supports have also been proposed with a mechanism

allowing to gradually increase the spacing, with supports close together at the start, and increasing spacing as the salad grows. However, these are complex and costly achievements because the mechanisms must be designed to allow

robust and faultless operation 24/7, in adverse environments due to ambient humidity in the lower part of

1 installation. Furthermore, the solutions of the prior art are not entirely suitable for ensuring misting.

regular and homogeneous plants, with a simple and robust solution.

Solution provided by the invention

In order to remedy these drawbacks, the present invention relates, in its most general sense, to an above-ground cultivation module constituted by a support.

prismatic having two inclined panels connected by an edge characterized in that the median planes of said panels form with the horizontal plane an angle between 30 and 40 ° and preferably an angle of 36 ° ± 1 °, and in that said panels constitute a tight barrier between the root space and the stem space, and are crossed by a plurality of openings for the maintenance of a culture support. Optionally, the openings not occupied by a culture support are closed by stoppers.

closing .

The invention also relates to an above-ground cultivation installation comprising a plurality of above-ground cultivation module constituted by a support having two inclined panels connected by an edge whose median planes form with the horizontal plane an angle between 30 and 40 ° and in that said panels constitute a tight barrier between the root space and the stem space, and are crossed by a plurality of openings for maintaining a culture support or a closure plug for the openings not occupied by a growing medium, said modules being juxtaposed to form a corrugated surface separating the root space from the stem space, said installation

further comprising means for supplying nutritive fluid to the root zone. Detailed description of a nonlimiting example of embodiment

The present invention will be better understood on reading the description which follows, relating to nonlimiting exemplary embodiments illustrated by the appended figures in which:

[Fig. l] Figure 1 shows a perspective view of an installation according to the invention

[Fig. 2] FIG. 2 represents an enlarged perspective view of a module according to an exemplary embodiment of the invention

[Fig. 3] Figure 3 shows a perspective view of an alternative embodiment of an installation according to the invention

[Fig. 4]

[Fig. 5] Figures 4 and 5 show views in

perspective of seed support and plug according to

1 invention.

[Fig. 6] Figure 6 shows a three-quarter view below of a culture medium

[Fig. 7] Figure 7 shows a top view of a

misting set

[Fig. 8] Figure 8 shows a top view of a detail of the misting assembly

[Fig. 9] Figure 9 shows a schematic overview of the support and the misting system. General description of the installation

FIG. 1 represents a general view of an installation according to a first example of implementation of the invention.

The installation comprises a frame (1) intended to raise the growing area to a height facilitating handling by a standing operator, and freeing up a lower space for the circulation of misting robots, in the case of growing in aeroponics.

The culture is carried out on modules (2 to 5) of prismatic shape, each having a front inclined panel (6) and a rear inclined panel (7) and closing side faces (8).

These panels (6, 7) are in the example described without limitation plan and has circular lights for the insertion of culture media of a salad, or a closure cap for the lights not used, in order to provide a barrier between the lower space, subject to misting of the roots, and the upper space, subject to a contribution of natural and / or artificial light energy.

The modules (2 to 5) made of material can be produced by thermoforming or folding of a sheet of plastic material or by folding of a metal sheet, for example an aluminum sheet.

The lights for the insertion of the culture supports are aligned horizontally with a constant pitch corresponding to the nominal section of a salad at maturity.

The consecutive lines are shifted by half a step to form a matrix of lights arranged in anyone, making it possible to optimize the space available for the

development of foliage of cultivated varieties and crop density. The optimal distance between salads is between 20 and 32 cm. It can go down to 10 cm for aromatic, medicinal plants, or certain fruits and vegetables.

The two panels (6, 7) each form with the horizontal plane an angle of 36 °, respectively + 36 ° and -36 °, and an angle at the top of 108 °.

The modules are prepared in an area of

upstream preparation (10) where they are deposited to be loaded with the culture supports, or already loaded with the

culture media.

They are then pushed back against the module

previous by a jack driving claws (11) exerting a push against the front transverse edge (12) upstream module. This thrust leads to the advancement of the series of modules of the same line, the most downstream module ending in a harvesting area similar to the upstream preparation area (10). There are other thrust systems, for example with worms, or large conveyor systems adapted to these modules.

For salads such as lettuce, aromatic and medicinal plants, certain fruits and vegetables, the determining factors for production include temperature and radiation, and the intensity of lighting. The sensitivity of lettuce to acidity is an important factor. It is therefore essential to regulate and control the acidity level of the nutrient solution.

Generally a romaine lettuce takes between 40 and 100 days to reach its ideal size after planting, and growing in hydroponics or aeroponics can reduce this period between 25 and 50 days. The nutrient solution is

maintained at a temperature between 18 and 20 ° C and subjected to natural lighting supplemented by artificial lighting, for example by LEDs, ensuring a

photoperiodism with lighting for 12 to 16h. The intensity is between 80 and 300 micromol / m2 / s. The nutrient supply by misting or by soaking the roots in a reserve has an optimum pH of 5.2 to 6.4), and a salinity with resistivity of between 700 and 2200 s / cm / cm2. This level of acidity can be obtained by adding nitric acid (or phosphoric acid) in small amounts in the nutrient solution, until reaching the desired pH level.

The minerals that the plant consumes in large quantities include nitrogen, phosphorus, potassium, calcium. Plants need other minerals, but in much smaller quantities. These are trace elements (from the Greek oligos, small, few in number) composed of iron, magnesium, sulfur, manganese, zinc, boron, copper, molybdenum, chlorine and nickel.

Lettuces are known to be vegetables that need water but not a lot of nutrients. An example of a nutrient solution is constituted by (in mol m_3)

12 molecules of nitrate (N03-N), 1.3 molecules of phosphorus (P), 8.7 molecules of potassium (K +) 5 molecules of Calcium (Ca ++) 1.7 molecules (Mg ++) 5 molecules of sodium (Na +) 5 molecules of Chlorine (Cl_) 0.04 Iron molecules (Fe ++)

The culture supports have a housing whose bottom has a light of increasing width from the center to the periphery, and in that each of said

culture media is movable relative to the cut in which it is inserted, in a direction corresponding to the median longitudinal axis of said light between a closed position of said light and an open position.

Preferably, said culture support is a molded part having a planar blade of a section

greater than the section of the cutout of the receiving area, said blade having an opening under which said blade is extended by a housing having said lumen of increasing width, said flat blade and said housing defining a hollow space whose height corresponds to the thickness of said reception area.

Detailed description of an alternative embodiment of the module

2 shows a schematic perspective view in partial section of another form of module.

The module consists of a thermoformed form having two inclined panels (6, 7) forming at the top an angle of about 108 °.

These panels have hollow protuberances (14, 15, 18) raising the lights (24, 25) intended to receive the culture support in order to allow the salads (represented in FIG. 2 diagrammatically with an ovoid shape) to grow with a vertical stem and a horizontal expansion of the foliage.

The openings (24, 25) are thus positioned in tiers and staggered to optimize the horizontal density and the space available for the growth of the salad.

The thermoformed panels (6, 7) are extended by a horizontal strip (16, 17) having fixing holes (20, 21).

Variant of realization

FIG. 3 represents an alternative embodiment in which each culture module (2, 3, 4, 5) is formed by a shell with four inclined sides, including two main faces (6,

7) and two side faces (26, 27) also inclined with lights to receive the plane supports.

Each culture module (2, 3, 4, 5) rests on a hollow tank (30), having a curved bottom (31) to form two lateral channels (32, 33). This tank contains the liquid

nutritious which is misted by a nozzle placed in the tank. The trays rest on longitudinal rails (34, 35) placed on the ground, which therefore does not require earthworks. The tanks (30) have fluid connections on the front and rear faces to allow the transmission of the nutritive fluid over the entire series of aligned tanks.

Plan support and plug

Figures 4 and 5 respectively represent a plane support and a plug. The plan support is

consisting of a disc (40) of a section greater than the section of the lights formed on the receiver module, with flexible tabs (41 to 46) allowing clipping into the lights intended to receive the plant supports.

The central part has radial incisions (49) defining flexible petals converging towards a central well (48) intended to receive a seed in a hollow area (47). During germination, the roots are

extend downward and the stem causes the spacing of the petals which continue to provide a seal between the root part and the stem part.

Variant of realization

FIGS. 6 to 9 relate to an alternative embodiment of an aeroponic culture system, with a series of modules (2 to 5) of prismatic shape, each having a front inclined panel (6) and a rear inclined panel (7) and lateral closing faces (8).

Each of the prismatic modules (2 to 5) is formed by a folded sheet having a top strip (51) also having slots for the insertion of a culture element, and two folded strips (56, 57) ensuring the rigidity of the support.

The installation includes a frame (1) intended to raise the growing area to a height facilitating manipulations by a standing operator, and freeing up a lower space for the circulation of misting robots, in the case of culture in aeroponics.

The misting robot consists of a misting head (60) supported by a trellis (65)

moving on two rails (61, 62).

The trellis structure (65) is fixed at each end to a chassis (66) supporting wheels (67 to 69) driven by motors (77, 78).

Pairs of rollers (70, 71; 72, 74) provide guidance relative to the rails.

Claims

Claims

1 - Above-ground cultivation module consisting of a support (2 to 5) having two inclined panels (6, 7) characterized in that said support has a shape

prismatic, in that the median planes of said panels (6, 7) form an angle between 30 and 40 ° with the horizontal plane and in that said panels (6, 7) constitute a tight barrier between the root space and the 'space

stem, and are crossed by a plurality of openings (24, 25) for maintaining a culture medium.

2 - Above ground cultivation module according to the

claim 1 characterized in that said openings (24, 25) are capable of receiving a closure cap for

openings not occupied by a growing medium.

3 - Soilless cultivation module according to claim 1 or 2 characterized in that the median planes of said panels (6, 7) form with the horizontal plane an angle of 36 ° ± 1 °.

4 - Soilless cultivation module according to claim 1 characterized in that each of the panels (6, 7) has a plurality of rows of openings and in that the openings of two consecutive rows are laterally offset by half a step .

5 - Soilless cultivation module according to claim 1 characterized in that said panels (6, 7) have a stepped shape.

6 - Soilless cultivation module according to claim 1 characterized in that said panels (6, 7) are extended at their lower edges by a horizontal flat border.

7 - Soilless cultivation module according to the preceding claim characterized in that said horizontal planar borders have complementary assembly areas.

8 - Soil-less cultivation module according to claim 1 and its growing medium (s) characterized in that said panels (6, 7) have cutouts for the insertion of growing media characterized in that said growing media culture have a housing whose bottom has a light of increasing width from the center to the periphery, and in that each of said

culture media is movable relative to the cut in which it is inserted, in a direction corresponding to the median longitudinal axis of said light between a closed position of said light and an open position.

9 - Soil-less cultivation module according to claim 1 and its culture medium (s) characterized in that said culture medium is a molded part having a flat blade with a cross section greater than the cross section of the area receiving, said blade having an opening under which said blade is extended by a housing having said lumen of increasing width, said planar blade and said housing defining a hollow space whose height corresponds to the thickness of said receiving area.

10 - Above-ground cultivation installation comprising a plurality of above-ground cultivation module constituted by a prismatic support having two inclined panels (6, 7) connected by a transverse edge whose planes medians form an angle between 30 and 40 ° with the horizontal plane and in that said panels (6, 7) constitute a tight barrier between the root space and the space

stem, and are crossed by a plurality of openings for the maintenance of a culture support, said modules being juxtaposed to form a corrugated surface separating the root space from the stem space, said installation further comprising a means of supply of nutritive fluid to the root zone.

11 - Above-ground cultivation installation according to the preceding claim characterized in that said openings (24, 25) are capable of receiving a plug for closing openings not occupied by a culture medium

12 - Soilless culture installation according to the preceding claim 10 in that it comprises a

juxtaposition of an assembly formed by a tank (30) and by a support module (2 to 5).

13 - Above-ground cultivation installation according to the preceding claim, characterized in that said tank (30) rests on longitudinal rails (34, 35) and

have connection means for the passage of the nutritive fluid from one tank to another.

14 - Above-ground cultivation unit consisting of a prismatic support (2 to 5) having two inclined panels (6, 7) connected by a transverse edge characterized in that the median planes of said panels (6, 7) form with the horizontal plane an angle between 30 and 40 ° and in that said panels (6, 7) constitute a tight barrier between the root space and the stem space, and are crossed by a plurality of openings (24, 25) for the maintenance of a culture support or a closure plug for the openings not occupied by a culture support and by a culture support assembly formed by a disc part having a split zone defining deformable petals to receive a seed and allow the passage of the roots towards the lower part of said support.