WO2021160600A1

WO2021160600A1 - Vertical hydroponic growing system

Info

Publication number: WO2021160600A1
Application number: PCT/EP2021/053058
Authority: WO
Inventors: Saif EL KATI; Mohamed Ali KETARI; Taoufik TAHAR
Original assignee: Babylone Growers Agritech
Priority date: 2020-02-13
Filing date: 2021-02-09
Publication date: 2021-08-19
Also published as: FR3107160B1; FR3107160A1

Abstract

One aspect of the invention relates to a vertical hydroponic growing system, comprising: - a framework; - a plurality of growing tubes (1040); - a plurality of supports (1060) comprising a plurality of first supports (1060) and a plurality of second supports (1060) fixed to the framework, each first support (1060) being configured to accept a first end (1041) of a growing tube (1040) and being aligned along a horizontal axis (X) with a second support (1060) configured to accept a second end (1042) of the growing tube (1040); each growing tube (1040) comprising at least a first row (1051) of holes (1050) and a second row (1052) of holes (1050), at least one hole (1050) of the first row (1051) of holes (1050) being offset from at least one hole (1050) of the second row (1052) of holes (1050) along the horizontal axis (X).

Description

DESCRIPTION

TITLE: Vertical hydroponics system

TECHNICAL FIELD OF THE INVENTION

[0001] The technical field of the invention is that of hydroponics, and more particularly that of hydroponics on a vertical structure.

The present invention relates to a hydroponics system and in particular to a vertical hydroponics system.

TECHNOLOGICAL BACKGROUND OF THE INVENTION

[0003] In the field of soil-less agriculture, also called hydroponics, it is known to use vertical structures to multiply the number of plants cultivated simultaneously and thus increase the crop yield. For example, in the case of hydroponics of lettuce, using a vertical structure rather than a conventional structure can increase crop yield.

[0004] As the infrastructure for implementing soilless farming is very expensive, there is a need for producers to further increase crop yields.

SUMMARY OF THE INVENTION

[0005] The invention offers a solution to the problems mentioned above, by making it possible to increase the number of plants grown simultaneously on a structure for vertical hydroponics.

The invention relates to a vertical hydroponics system comprising: a frame comprising a plurality of support elements comprising at least a first support element and a second support element, each support element comprising at least a first upright and at least a second post, the first post and the second post each including a first post end and a second post upright end, the first upright and the second upright being interconnected via their first upright ends; a plurality of culture tubes each configured to receive a plurality of plants, each culture tube having a first tube end and a second tube end; a plurality of supports including a plurality of first supports attached to the first support member and a plurality of second supports attached to the second support member, each first support being configured to receive the first tube end of a culture tube and being aligned along a horizontal axis with a second support configured to receive the second tube end of the culture tube; each grow tube having at least a first row of holes and a second row of holes, each hole allowing a plant from the grow tube to grow out of the grow tube, at least one hole from the first row of holes being offset by at least one hole from the second row of holes along the horizontal axis.

[0007] Thanks to the invention, each grow tube has two rows of holes that can accommodate a plant in each hole, rather than a single row, which doubles the crop yield per tube. The offset between the holes in the first row and the holes in the second row ensures sufficient spacing between each plant, allowing them to grow.

[0008] The supports make it possible to keep the culture tubes horizontally rather than on a slope, which makes it possible to prevent the drying out of the roots of the plants in the event of stopping the flow of water in the tube of culture.

[0009] In addition to the characteristics which have just been mentioned in the previous paragraph, the system according to the aspect of the invention may have one or more additional characteristics among the following, considered individually or in any technically possible combination.

According to an alternative embodiment, the first row of holes is located on a first horizontal face of the culture tube and the second row of holes is located on a second horizontal face of the culture tube. [0011] Thus, the space between each plant in the first row and the closest plant or plants in the second row is maximized to allow their growth.

[0012] According to an alternative embodiment compatible with the previous alternative embodiment, for each support element, the second upright is movable relative to the first upright.

[0013] Thus, the system according to the invention is retractable, that is to say that its width varies between an open position and a closed position. The system therefore occupies a minimal surface area on the ground in the closed position and makes it possible to facilitate operations, such as planting, harvesting and maintenance operations, on plants located at height.

[0014] The supports make it possible to keep the culture tubes horizontal regardless of the position of the system.

The system thus makes it possible to achieve a maximum culture density of 80 plants per m ² , a conventional vertical hydroponics system making it possible to achieve only an average culture density of 25 plants per m ² .

[0016] According to a sub-alternative embodiment of the previous alternative embodiment, each support element comprises a guide system configured to guide the movement of the second post relative to the first post. Thus, the passage from the closed position to the open position of the system is facilitated.

According to an alternative embodiment of the previous embodiment sub-alternative, the guide system comprises at least one rail configured to receive the second end of the upright of the first upright and / or of the second upright.

[0019] According to an alternative embodiment compatible with the previous alternative embodiments, each support element comprises an adjustment system configured to adjust the value of an angle between the first upright and the second upright.

Thus, the adjustment of the position of the system between the closed position and the open position is facilitated. According to a sub-alternative embodiment of the previous alternative embodiment, the adjustment system comprises at least one adjustment element comprising a first adjustment bar and a second adjustment bar, the first adjustment bar and the second adjuster bar each having a first bar end and a second bar end, the first adjuster bar and the second adjuster bar being interconnected via their first bar ends, the adjuster being connected to the first upright via the second bar end of the first adjuster bar and to the second upright via the second bar end of the second adjuster bar.

[0022] According to an alternative embodiment compatible with the previous alternative embodiments, each support comprises a tube orientation system configured to rotate the culture tube supported by the support around the horizontal axis.

[0023] Thus, the orientation of each grow tube can be adjusted individually depending on the size of the plants grown and / or to optimize the lighting of the plants in the grow tube.

[0024] According to an alternative embodiment compatible with the previous alternative embodiments, the system according to the invention comprises a stabilization system configured to stabilize the frame.

Thus, the frame is stabilized and the system can be adjusted between the closed position and the open position even during production.

According to a sub-alternative embodiment of the previous alternative embodiment, the stabilization system comprises at least one stabilization bar extending along the horizontal axis.

[0027] Thus, horizontal stabilization of the system is ensured.

According to an alternative embodiment of the previous embodiment sub-alternative, the stabilization system comprises at least a first stabilization bar fixed to the first upright of at least one support element and / or at least a second bar stabilization fixed on the second upright of at least a support member and / or at least one third stabilizer bar fixed at the first post end of the first post and the second post of at least one support member.

According to a sub-alternative embodiment of the alternative previous embodiment compatible with the sub-alternative of the previous embodiment, the stabilization system comprises at least one stabilization rod having a first rod end fixed to the first upright or the second post of a support member and a second rod end attached to the first post or the second post of another support member.

[0030] Thus, a vertical stabilization of the system is ensured.

According to an alternative embodiment compatible with the previous alternative embodiments, the system according to the invention comprises at least one irrigation system configured to supply water and / or nutrient solution to the plants of a set of tubes of culture.

According to a sub-alternative embodiment of the previous alternative embodiment, the irrigation system comprises for each culture tube of the set of culture tubes, a first pipe configured to supply the culture tube with water and / or nutrient solution and a second pipe configured to empty the culture tube of water and / or nutrient solution, the first pipe and the second pipe being each located at a different tube end, the second pipe being 'a first culture tube corresponding to the first pipe of a second culture tube located below the first culture tube along a vertical axis.

[0033] Thus, the irrigation of the plants is carried out by gravity, which makes it possible to reduce the electricity consumption and to optimize the oxygenation of the plants.

According to a sub-alternative embodiment of the alternative of the previous embodiment compatible with the sub-alternative of the previous embodiment, the irrigation system comprises for each culture tube of the set of culture tubes, a system of Level setting configured to adjust the level of water and / or nutrient solution in the culture tube. [0035] Thus, the water level in each culture tube can be adjusted individually, for example according to the growth phase of the plants, which makes it possible to use the same culture tube for all the growth phases of the plants and avoid transplanting plants into a culture tube with a larger diameter depending on their growth phase.

According to a sub-alternative embodiment of the previous alternative embodiment compatible with the previous sub-alternatives of embodiment, the system according to the invention comprises: a first irrigation system configured to supply the plants with nutrient solution. a first set of tubes comprising each culture tube supported by supports fixed to the first uprights of the support elements; a second irrigation system configured to supply nutrient solution to plants in a second set of tubes comprising each grow tube supported by brackets attached to the second uprights of the support members.

According to an alternative embodiment compatible with the previous alternative embodiments, each support element comprises two first uprights and two second uprights, the first uprights and the second uprights being interconnected via their first upright ends, each support being attached to the first two uprights or to the second two uprights.

[0038] Thus, the horizontality of the supports is ensured.

According to a sub-alternative embodiment of the previous alternative embodiment, each support is fixed on each of the first two uprights or on each of the two second uprights via a pivot connection.

[0040] Thus, the horizontality of the supports is ensured regardless of the position of the system between the closed position and the open position.

The invention and its various applications will be better understood on reading the following description and on examining the accompanying figures. BRIEF DESCRIPTION OF THE FIGURES

[0042] The figures are presented as an indication and in no way limit the invention.

Figure 1A shows a schematic representation of the vertical hydroponic growing system according to the invention, with culture tubes.

Figure 1B shows a schematic representation of the vertical hydroponic growing system according to the invention, without culture tubes.

Figure 2A shows a schematic cross-sectional view of the vertical hydroponic growing system according to the invention in an intermediate position.

Figure 2B shows a schematic cross-sectional view of the vertical hydroponic growing system according to the invention in the open position.

Figure 3 shows a schematic representation in sectional view of a culture tube supported by a support fixed to two posts of a support member of the frame of the vertical hydroponics system according to the invention.

Figure 3bis shows a schematic representation of the stresses exerted on the culture tube support and on the two support member posts shown in Figure 3 when a force is exerted on the support member to pass the system according to the invention in a closed position.

Figure 4 shows a schematic representation of the irrigation system for two culture tubes arranged one above the other along the vertical axis.

Figure 5 shows a schematic representation of the tube orientation system for a culture tube.

Figure 6 shows a schematic representation of a culture tube illustrating the operation of the system for adjusting the level of water and / or nutrient solution inside the tubes.

DETAILED DESCRIPTION

Unless otherwise specified, the same element appearing in different figures has a single reference. The invention relates to a vertical hydroponics system, and more particularly to a vertical hydroponics system allowing the implementation of NFT ("for Nutrient Film Technique") cultivation methods.

The term "vertical cultivation system" is understood to mean a system for cultivating plants on several floors, each floor being distributed along a horizontal axis.

The plants can be leaf or semi-climbing plants and in particular fruits or vegetables.

[0047] [Fig. 1 A] Figure 1A shows a schematic representation of the vertical hydroponics system 100 according to the invention.

The system 100 according to the invention comprises a frame comprising several support elements 1011, 1012, 1013.

[0049] [Fig. 1 B] Figure 1B shows a schematic representation of the frame of the vertical hydroponics system 100 according to the invention.

In Figures 1A and 1B, the system 100 comprises three support elements 1011, 1012, 1013 each extending in a substantially vertical plane having a vertical Y axis perpendicular to the ground surface. The vertical Y axis is perpendicular to a horizontal X axis.

A first support element 1011 is located at a first end of the frame along the horizontal axis X and a second support element 1012 is located at a second end of the frame along the horizontal axis X.

[0052] In Figures 1A and 1B, the support member 1013 is located substantially equidistant along the horizontal axis X of the first support member 1011 and the second support member 1012.

The distance along the horizontal axis X between the first support element 1011 and the second support element 1012 is for example greater than 1 meter, for example 12 meters. Each support element 1011, 1012, 1013 comprises at least a first upright 1021 and at least a second upright 1022 identified only on the first support element 1011 in Figures 1 A and 1 B.

The first upright 1021 and the second upright 1022 each have a first upright end 1031 and a second upright end 1032. The first upright 1021 and the second upright 1022 are interconnected via their first upright ends 1031, that is, the first post end 1031 of the first post 1021 and the first post end 1031 of the second post 1022 are interconnected.

Each support element 1011, 1012, 1013 comprises for example two first uprights 1021 and two second uprights 1022 interconnected via their first upright ends 1031, as illustrated in Figures 1A and 1B.

In Figures 1A and 1B, each support element 1011, 1012, 1013 only comprises first uprights 1021 and second uprights 1022 but each support element 1011, 1012, 1013 could for example include at least one other upright , for example a third upright placed along the horizontal axis X and connected to the middle of a first upright 1021 via its first upright end and to the middle of a second upright 1022 via its second upright end so that the element support 1011, 1012, 1013 has an "A" shape. This type of support element 1011, 1012, 1013 is commonly referred to as an "A-frame".

Each upright 1021, 1022 is for example a tube of dimension of 3 meters.

The frame is for example metallic, made of square section steel tubes.

The frame can include a stabilization system.

The stabilization system comprises for example at least one stabilization bar extending along the horizontal axis X.

In Figure 1B, the stabilization system comprises a first stabilization bar 1111 attached to the first upright 1021 of each support element 1011, 1012, 1013 also shown in Figure 1A, a second stabilization bar attached to the second post 1022 of each support element 1011, 1012, 1013 also shown in Figure 1A and a third stabilizer bar 1113 attached to the first post end 1031 of the first post 1021 and the first post end 1031 of the second post 1022 of each support member 1011, 1012 , 1013 so as to form a cross connecting each support element 1011, 1012, 1013.

Each stabilization bar 1111, 1112, 1113 is for example a square section tube having a side of dimension 20 mm and a length of 6 meters.

The stabilization system comprises for example at least one stabilization rod 1114 having a first rod end and a second rod end, the first rod end being fixed to the first upright 1021 or the second upright 1022 of a support member 1011, 1012, 1013 and a second rod end being fixed to the first post 1021 or the second post 1022 of another support member 1011, 1012, 1013.

In Figures 1A and 1B, the stabilization system comprises eight stabilization rods 1114, only six stabilization rods 1114 being visible in Figure 1A and four stabilization rods 1114 in Figure 1 B. The rod stabilizer 1114 marked in Figure 1A or in Figure 1B has a first rod end connected to the second post 1022 of the first support member 1011 and a second rod end connected to the second post 1022 of the third support member

1013.

Each stabilization rod 1114 is for example a rod of square section having a side of dimension 20 mm and a length of 6 meters.

The system 100 according to the invention comprises a plurality of supports 1060 comprising a plurality of first supports 1060 fixed on the first support element 1011 and a plurality of second supports 1060 fixed on the second support element 1012. Each first support 1060 is aligned along the horizontal X axis with a second support 1060.

Figures 1A and 1B, the first support element 1011 comprises 16 first supports 1060, eight first supports 1060 being fixed on the first upright 1021 and eight first supports 1060 being fixed on the second upright 1022. Likewise , the second support element 1012 comprises 16 second supports 1060, eight second supports 1060 being fixed on the first upright 1021 and eight second supports 1060 being fixed on the second upright 1022.

The plurality of supports 1060 can also include other supports 1060 apart from the first supports 1060 and the second supports 1060 fixed on other support elements 1013 than the first support element 1011 or the second support element 1012 , for example a plurality of third supports fixed to the third support element 1013. Each other support 1060 is aligned along the horizontal axis X with a first support 1060 and a second support 1060. [0071] Each support 1060 is for example produced into a plurality of square section tubes having a side dimension of 103 mm and a length of 12 meters. The tubes are for example made of food grade PVC.

System 100 includes a plurality of culture tubes 1040 having a first tube end 1041 and a second tube end 1042.

In Figure 1A, the system 100 comprises 16 culture tubes 1040.

Each culture tube 1040 is supported at its first tube end 1041 by a first support 1060 and at its second tube end 1042 by a second support 1060. Each culture tube 1040 therefore extends along the horizontal axis X.

Each culture tube 1040 may for example be of circular, square, rectangular or even parallelepipedal section.

Each culture tube 1040 has for example a dimension of 6 m along the horizontal axis X.

Each culture tube 1040 is for example made of PVC and in particular of food grade PVC.

[0078] [Fig. 4] Figure 4 shows a schematic representation of two culture tubes 1040 arranged one above the other along the vertical Y axis.

Each culture tube 1040 has at least a first row 1051 of holes 1050 and a second row 1052 of holes 1050, each hole 1050 allowing a plant planted in the culture tube 1040 to grow out of the tube of culture 1040. In Figure 4, the culture tubes 1040 have a parallelepipedal shape of square section having four horizontal faces extending along the horizontal axis X. The first row 1051 of holes 1050 is located on a first horizontal face and the second row 1052 of holes 1050 is located on a second horizontal face, the first horizontal face and the second horizontal face being separated by an angle substantially equal to 45 °.

At least one hole 1050 of the first row 1051 of holes 1050 is offset from at least one hole 1050 of the second row 1052 of holes 1050 along the horizontal axis X, that is to say that the position along the horizontal axis X of at least one hole 1050 of the first row 1051 of holes 1050 is different from the position along the horizontal axis X of at least one hole 1050 of the second row 1052 of holes 1050. [ For example, as shown in Figure 4, each hole of the first row 1051 of holes 1050 is offset from each hole 1050 of the second row 1052 of holes 1050, that is to say that the position according to the horizontal X axis of each hole 1050 of the first row 1051 of holes 1050 is different from the position along the horizontal X axis of each hole 1050 of the second row 1052 of holes 1050.

In Figure 4, each hole 1050 of the second row 1052 is located between two holes 1050 of the first row 1051 along the horizontal axis X. The distance between a hole 1050 of the second row 1052 and a hole 1050 of the first row 1051 along the horizontal axis X is for example between 20 and 25 cm.

The first row 1051 of holes 1050 comprises for example 60 holes and the second row 1052 of holes 1050 comprises for example 60 holes. Thus, if the system 100 has eight stages, the system 100 allows 1920 plants to be grown simultaneously.

For each support element 1011, 1012, 1013, the first amount

1021 can be linked to the second post 1022 so that the second post

1022 is movable relative to the first upright 1021 and more particularly so that the value of the angle between the first upright 1021 and the second upright

1022 varies between a closed position and an open position of the system 100. The connection between the first upright 1021 and the second upright 1022 at their first ends 1031 is then a pivot connection having as an axis of rotation, the horizontal axis X. [0086] [Fig. 2A] FIG. 2A shows a schematic representation in section view of the system 100 according to the invention in an intermediate position between the closed position and the open position. [0087] [Fig. 2B] FIG. 2B shows a schematic representation in sectional view of the system 100 according to the invention in the open position.

In the closed position, the angle Q between the first upright 1021 and the second upright 1022 has for example a value between 0 and 10 °. The dimension of the system 100 along a Z axis perpendicular to the horizontal X axis and to the vertical Y axis, later called width, is for example 58 cm in the closed position.

In the open position, the angle Q between the first upright 1021 and the second upright 1022 for example has a value between 40 and 50 °. The width of the system 100 is for example 1 meter in the open position.

[0090] In Figure 2A, the angle Q is substantially 20 °.

[0091] In Figure 2B, the angle Q is substantially 45 °.

Each support element 1011, 1012, 1013 may include a guide system configured to guide the movement of the second post 1022 relative to the first post 1021.

The guide system comprises for example at least one rail 1070 in which can slide the second end of upright 1032 of the first upright 1021 and / or the second end of upright 1032 of the second upright 1022 of a support element 1011, 1012, 1013.

In Figures 1B, 2A and 2B, the guide system comprises a rail 1070 receiving the second end of post 1032 of the first post 1021 and the second end of post 1032 of the second post 1022 of the support element 1011 , 1012, 1013 shown. The guide system could also include a first rail 1070 receiving the second end of upright 1032 of the first upright 1021 and a second rail 1070 receiving the second end of upright 1032 of the second upright 1022 of the support element 1011, 1012 , 1013. Each support element 1011, 1012, 1013 may include an adjustment system configured to adjust the value of the angle Q between the first upright 1021 and the second upright 1022.

The adjustment system comprises for example an adjustment element 1080 comprising a first adjustment bar 1081 and a second adjustment bar 1082, the first adjustment bar 1081 and the second adjustment bar 1082 each having a first bar end 1091 and a second bar end 1092.

The first adjustment bar 1081 and the second adjustment bar 1082 are interconnected via their first bar ends 1091, that is to say that the first bar end 1091 of the first adjustment bar 1081 and the first bar end 1091 of the second adjustment bar 1082 are interconnected.

The first adjustment bar 1081 and the second adjustment bar 1082 are interconnected so that the first adjustment bar 1081 is movable relative to the second adjustment bar 1082 and more particularly so that the value of l The angle a between the first adjustment bar 1081 and the second adjustment bar 1082 varies between the closed position and the open position of the system 100. The connection between the first adjustment bar 1081 and the second adjustment bar 1082 at their first bar ends 1081 is then a pivot link having as axis of rotation, the horizontal axis X.

[00100] The adjuster 1080 is connected to the first post 1021 via the second bar end 1092 of the first adjuster bar 1081 and to the second post 1022 via the second bar end 1092 of the second adjuster bar 1082.

[00101] In Figures 1B, 2A and 2B, the support element 1011, 1012, 1013 comprises two adjustment elements 1080 having an "X" shape in the intermediate position. This type of support element 1011, 1012, 1013 is commonly referred to as an "X-frame".

In the closed position, the angle a between the first adjustment bar 1081 and the second adjustment bar 1082 has for example a value between 10 and 30 °. In the open position, the angle a between the first adjustment bar 1081 and the second adjustment bar 1082 has for example a value between 30 and 180 °.

[00104] In Figure 2A, the angle a is substantially 45 °.

[00105] In Figure 2B, the angle a is substantially 180 °.

[00106] Each support 1060 may include a tube orientation system configured to rotate the culture tube 1040 supported by the support 1060 about the horizontal X axis.

[00107] [Fig. 3] Figure 3 shows a schematic sectional view of a culture tube 1040 supported by a support 1060 attached to two first uprights 1021 or two second uprights 1022 of a support member 1011, 1012, 1013.

[00108] [Fig. 3bis] Figure 3bis shows a schematic representation of the stresses exerted on the support 1060 of the culture tube 1040 and on the first two uprights 1021 or the two second uprights 1022 of the support element 1011, 1012, 1013 shown in Figure 3 when a force is exerted on the support element 1011, 1012, 1013 to pass the system 100 according to the invention in the closed position.

[00109] In Figures 3 and 3a, the support 1060 of the culture tube 1040 is fixed on each first post 1021 or each second post 1022 of the support element 1011, 1012, 1013 via a pivot connection, that is, that is, a link which only allows rotation along the X axis perpendicular to the Y and Z axes.

When a force, shown in Figure 3a by a horizontal black arrow, is exerted on the support element 1011, 1012, 1013 to pass the system 100 according to the invention in the closed position, an upward stress s 'exerts on the support element 1011, 1012, 1013. As the support 1060 is fixed via a pivot connection to the first two uprights 1021 or to the two second uprights 1022, the support 1060 will pivot in a counterclockwise direction and thus maintain the support 1060 horizontally. [00111] [Fig. 5] Figure 5 shows a schematic representation of the tube orientation system for a 1040 culture tube.

In Figures 3 and 5, the tube orientation system 1053 comprises a first vertical structure 1053 having a first end fixed to the support 1060 and a second end connected to the culture tube 1040 by a pivot connection having the axis of rotation, the horizontal axis X, and a second vertical structure 1054 having a first end fixed to the support 1060 and a second free end, and having a vertical notch. The culture tube 1040 is connected to a screw 1055 configured to slide into the notch and held at a desired height in the notch by a system of nuts.

[00113] The term "height" is understood to mean the dimension along the vertical axis Y.

In the case where each culture tube 1040 is of square section, each culture tube 1040 is for example inclined by 15 ° by default.

[00115] The system 100 according to the invention may include at least one irrigation system configured to supply water and nutrient solution to the plants of a set of culture tubes 1040.

The irrigation system comprises for example for each culture tube 1040 of the set of culture tubes 1040, a first pipe 1121 configured to supply the culture tube 1040 with water and nutrient solution and a second pipe 1122 configured to empty the culture tube 1040 of water and nutrient solution. The first pipe 1121 and the second pipe 1062 are each located at a different tube end 1041, 1042.

The second pipe 1122 of a culture tube 1040 corresponds to the first pipe 1121 of another culture tube 1040 located below the first culture tube 1040 along the vertical axis Y, as shown in Figure 5 .

The system 100 comprises for example a first irrigation system configured to supply water and / or nutrient solution to the plants of a first set of tubes 1040 comprising each culture tube 1040 supported by supports 1050 fixed on the first uprights 1021 of the support elements 1011, 1012, 1013 and a second irrigation system configured to supply water and / or nutrient solution to the plants of a second set of tubes 1040 comprising each culture tube 1040 supported by supports 1050 attached to the second posts 1022 of the support members 1011, 1012, 1013.

Each irrigation system comprises, for example, for each culture tube 1040 of the set of culture tubes 1040, a level adjustment system configured to adjust the level of nutrient solution in the culture tube 1040.

[00120] [Fig. 6] Figure 6 shows a schematic representation of a culture tube 1040 illustrating the operation of the level control system 1130.

The level adjustment system 1130 comprises for example the second pipe 1122 of the irrigation system of the culture tube 1040 having a length located in the culture tube 1040 adjustable by thread, as illustrated in Figure 6.

Claims

[Claim 1] A vertical hydroponics system (100) comprising:

- a frame comprising a plurality of support elements (1011, 1012, 1013) comprising at least a first support element (1011) and a second support element (1012), each support element (1011, 1012, 1013) comprising at least a first post (1021) and at least a second post (1022), the first post (1021) and the second post (1022) each comprising a first post end (1031) and a second post end (1032 ), the first post (1021) and the second post (1022) being interconnected via their first post ends (1031);

- a plurality of culture tubes (1040) each configured to receive a plurality of plants, each culture tube (1040) comprising a first tube end (1041) and a second tube end (1042);

- a plurality of supports (1060) comprising a plurality of first supports (1060) fixed on the first support element (1011) and a plurality of second supports (1060) fixed on the second support element (1012), each first support (1060) being configured to receive the first tube end (1041) of a culture tube (1040) and being aligned along a horizontal axis (X) with a second support (1060) configured to receive the second tube end ( 1042) from the culture tube (1040); characterized in that each grow tube (1040) has at least a first row (1051) of holes (1050) and a second row (1052) of holes (1050), each hole (1050) allowing a plant in the tube to grow culture (1040) to grow outward from the culture tube (1040), at least one hole (1050) of the first row (1051) of holes (1050) being offset by at least one hole (1050) of the second row (1052) of holes (1050) along the horizontal axis (X), the first row (1051) of holes (1050) being located on a first horizontal face of the culture tube (1040) and the second row (1052 ) of holes (1050) being located on a second horizontal face of the culture tube (1040).

[Claim 2] System (100) according to claim 1, characterized in that, for each support element (1011, 1012, 1013), the second post (1022) is movable relative to the first post (1021).

[Claim s] System (100) according to claim 2, characterized in that each support member (1011, 1012, 1013) comprises a guide system (1070) configured to guide the movement of the second post (1022) relative to the first amount (1021).

[Claim 4] A system (100) according to claim 3, characterized in that the guide system (1070) comprises at least one rail configured to receive the second post end of the first post and / or of the second post.

[Claim s] System (100) according to any one of the preceding claims, characterized in that each support member (1011, 1012, 1013) comprises an adjustment system configured to adjust the value of an angle (Q) between the first post (1021) and the second post (1022).

[Claim 6] A system (100) according to any one of the preceding claims, characterized in that each support (1060) has a tube orientation system (1053, 1054, 1055) configured to rotate the culture tube ( 1050) supported by the support (1060) around the horizontal axis (X).

[Claim 7] System (100) according to any one of the preceding claims, characterized in that it comprises a stabilization system configured to stabilize the frame.

[Claim 8] System (100) according to claim 7, characterized in that the stabilization system comprises at least one stabilization bar (1111, 1112, 1113) extending along the horizontal axis (X).

[Claim 9] System (100) according to any one of claims 7 or 8, characterized in that the stabilization system comprises at least one stabilization rod (1114) having a first rod end fixed to the first post. (1021) or the second post (1022) of a support member (1011, 1012, 1013) and a second rod end attached to the first post (1021) or the second post (1022) of another support member support (1011, 1012, 1013).

[Claim 10] System (100) according to any one of the preceding claims, characterized in that it comprises at least one irrigation system configured to supply water and / or nutrient solution to the plants of a set of tubes. of culture (1040).

[Claim 11] System (100) according to claim 10, characterized in that the irrigation system comprises for each culture tube (1040) of the set of culture tubes (1040), a first pipe (1121) configured. to supply the culture tube (1040) with water and / or nutrient solution and a second pipe (1122) configured to empty the culture tube (1040) of water and / or nutrient solution, the first pipe ( 1121) and the second tube (1062) each being located at a different tube end (1041, 1042), the second tube (1122) of a first culture tube (1040) corresponding to the first tube (1121) of a second culture tube (1040) located below the first culture tube (1040) along a vertical axis (Y).

[Claim 12] System (100) according to any one of claims 10 or 11, characterized in that the irrigation system comprises for each culture tube (1040) of the set of culture tubes (1040), a Level control system (1130) configured to adjust the level of water and / or nutrient solution in the culture tube (1040).

[Claim 13] System (100) according to any one of the preceding claims, characterized in that each support element (1011, 1012, 1013) comprises two first uprights (1021) and two second uprights (1022), the first uprights (1021) and the second uprights (1022) being interconnected via their first upright ends (1031), each support (1060) being fixed on the first two uprights (1021) or on the two second uprights (1022). [Claim 14] System (100) according to claim 13, characterized in that each support (1060) is fixed on each of the two first uprights (1021) or on each of the two second uprights (1022) via a pivot connection.