WO2019171175A1 - Hydroponic culture method - Google Patents

Abstract

The present invention corresponds to a method for obtaining at least one hydroponic culture that comprises the following steps: a) placing at least one seed in at least one container and arranging same in a frame; b) arranging one or more frames in a closed environment; c) supplying a composition of nutrients and ozone to the closed environment; d) removing the frame from the closed environment and arranging it in a tray that contains the composition of nutrients and ozone until achieving the germination of the seeds of at least one of the containers; e) removing the frame from the tray and placing it outdoors; and f) removing the germinated plantlet from each frame and arranging same in a plurality of hollow tubes that contain the composition of nutrients and ozone.

Description

 METHOD FOR HYDROPONIC CULTURE Technical field of the invention

The present invention relates to methods for hydroponic cultures, specifically a method for at least one hydroponic culture that does not use pumping elements, temperature control systems and electrical energy.

Description of the state of the art.

Hydroponics is a system known in today's world, where it is sought to take advantage of small spaces to obtain different vegetables and fruits, for example, fruits and vegetables. Hydroponics is a system in which plant development is achieved without the need for soil following germination protocols.

Hydroponic crops are useful in countries or regions where they do not have fertile soils and appropriate for traditional agriculture (e.g., deserts, arid lands and spaces where building construction has occupied most of the land available for some type of crop ). It will be understood that a hydroponic culture uses construction materials for the elaboration of channels where hydroponic cultivation will be carried out, for example, channels and pipes.

One of the current problems of hydroponics or hydroponic crops is the continuous use of natural resources, such as water in a pumping system. By constantly using water in hydroponic crops, this natural resource is increasingly used up.

Water is essential for hydroponics because it is intended that the plant obtain all the nutrients contained in the water and thus grow to the point of collection In the state of the art there are methods and / or devices for a hydroponic culture, such as those disclosed in patent documents CN 103636473B and CN102884974A.

CN 103636473B discloses a method for seedling cultivation. The method is to sow the seeds in a tray that contains rock wool and broken plum leaves. The document discloses several examples for e! hydroponic cultivation and shares some characteristics of crops in different types of seed, in which the seeds are arranged in a square foam tray. Subsequently the fluid tray is arranged and this tray floats on the fluid. The seeds come into contact with the fluid because it is in the tray. After 12 to 18 days the germinated seeds are transplanted to a plantation field. However, the document did not disclose that ozone is available in the middle of the plant germination process. Therefore it would depart from the present invention.

On the other hand, the CN102884974A patent discloses im Jecho apparatus of sponge seedlings that solves hydration and ventilation problems in the soilless cultivation process. The apparatus comprises a spongy planting bed, which includes a plurality of units of blocks of sponges for sowing interconnected with each other. Each sowing block unit has a groove in the center where a seed is arranged. One of the advantages of the block is that the sponge has good water retention capacity and air permeability; Another advantage of the unit is that the seed can be removed at any time during germination, with which a new seed can be placed. However, the document does not disclose that they use a cover in the seedling germination process, nor does it disclose the availability of ozone in the blocks where the seedlings are arranged.

Brief Description of the Invention

The present invention corresponds to a method for a hydroponic culture in which no pumping elements, temperature control systems and electrical energy are used. This allows the invention to be friendly with e! environment using less water than other traditional hydroponic crops. By not using pumping elements or temperature control systems, it allows the present invention to be able to develop in any location, thus achieving that people living in places with arid terrain and with little accessibility to water can use this method as an alternative crop option. In addition, the method of the present invention uses a composition of nutrients and ozone which allows to reduce the amount of water and the germination time of the planted seed.

Brief description of the figures

I., to FIG. 1 corresponds to an embodiment of the invention with the containers arranged in a rack. FIG. 2 corresponds to a front view and an ysometry cut of the invention where the frame is housed inside a closed environment.

FIG. 3 corresponds to an embodiment of the invention where the frame is arranged on a tray.

FIG. 4 corresponds to an embodiment of the invention, where the tray is outdoors.

FIG. 5 corresponds to an embodiment of the invention where the container with the already germinated seed is arranged in a plurality of hollow pipes.

Detailed description of the invention.

The present invention corresponds to a method for obtaining at least one hydroponic culture comprising the following steps: step a) locating at least one seed in at least one container (1) and arranging them in a frame (2), step b) arrange one or more racks (2) in a closed environment (6), step c) supply a composition of nutrients and ozone to the closed environment (6), step d) remove the frame (2) from the closed environment (6) and arrange it in a tray (7) containing the composition of nutrients and ozone, until germination of the seeds of at least one of the containers (1) is achieved, step e) remove the frame (2) from the tray (7 ) and place it outdoors, step í) extract from each frame (2) the germinated seedling and place it in a plurality of hollow pipes (8) containing the composition of nutrients and ozone. It will be understood in the present invention that at least one container (1) is a body that can house one or more seeds. These containers (1) have a geometric shape selected from the group between rectangular shape, square shape, round shape, elliptical shape, regular shape and irregular shape.

In one embodiment of the invention, at least one container (]) is made of a material that is selected from the group consisting of polyester fiber, polyester bi-component fibers, aero fibers, polyamide fibers, polyethylene fibers, fibers of polypropylene, easi-prepoiomeric polyester, foams, polyurethane foams, peeler, DI 5 foam, D 18 foam, 1 foam) 20, D23 foam, D26 foam, D26 antibacterial foam, D30 foam, D36 foam, fire foam, polypropylene , memory foam, cellulosic foam, polyethylene foam, alveolar polyethylene film, polyurethane foam, dastomeric foam, aerbgel or combinations of the above.

In an example of the present invention, at least one container (1) is made of polyurethane and has a square shape with a length between 2mm to 50m, in addition, a height between 20mm to 5 Omni and a width between 20mm to 500mm

Referring to FIG: 1, and in relation to step a), on the face of at least one container (1) a first opening is made with a depth up to the medial distance with respect to the length of the height of at least one container (1), and a second opening perpendicular to the first opening with the same depth. Bn the. intersection of the two openings there is preferably a seed, preferably vegetable seeds such as lettuce, cabbage and vegetables that grow from the ground without branches.

After arranging the seeds in the containers (1), these containers (1) are arranged in a rack (2),

It will be understood in the present invention that a frame (2) is a frame or structure that holds the containers in an orderly and separate manner, preferably the construction form of! Frame (2) is selected from closed and open. In one embodiment of the invention, the frame material (2) is made of a material selected from carbon steel, iron foundries, galvanized iron, chromium steels, chromium nickel steels, eromo-mquel-litamO steels , nickel-cynol-rnolibdenum-timgstene alloy, ferrous alloys to chromium-molybdenum, A.ISI 301, A1SI 302, AIS! 304, AISI 316, AISI 405AIS1 410, AISI 430, AISI 442, alloy steel with manganese and combinations of the above.

In one embodiment of the invention, the frame (2) is made of a plastic material selected from polyvinylchloride (PVC); of chlorinated viriyl polychloride (CP VC); polyethylene terephthalate (PET), polyainides (RL) (e.g. PAÍ 2, PA6, PA66); polychlorotrifluoroethylene (PC FE); vinylidene polyfluoride (PV.DF); ethylene polytetrafluoride (PTFE); etHeno-elorotri (1 uoroetií no (ECTFE)); plastics (polyester, vinyl, epoxy, vindic resins) reinforced with fibers (e.g., glass, aramid, polyester).

Making reference to the FIO. 1, ropes and / or cables (5) are connected in the frame (2) forming at least one interwoven mesh in the space generated in the frame (2). In an embodiment of the invention, the interlaced mesh generates spaces where at least one container (1) is arranged. Preferably, the frame (2) has between 20 and 30 spaces where at least one container (1) is arranged. These spaces allow at least one container to be kept firm in case of frame deployments (2) to different spaces.

The containers (1) can be arranged one by one leaving a space of the same size as the container (1), this in order to leave space to arrange a plastic element and interlace it with the ropes and / or cables (5) .

Placing reference to the FIO. 1, in one embodiment of the invention the frame (2) is constructed by connecting at least four rigid elements (3) forming a frame or frame, and where at least one of the four rigid elements (3) a through hole (4) is made ). Subsequently, ropes or cables (5) are disposed in the through holes forming a panel type mesh. In one embodiment of the invention at least one of the four rigid elements (3) has a cross section! selected from circular cross section, square cross section, oblong cross section, elliptical cross section, rectangular cross section, regular cross section and irregular cross section.

In an example of the present invention, at least one of the four rigid elements (3) has a circular cross section. In one embodiment of the invention, one of the rigid elements (3) has a diameter selected from 50 mm to Oinm and is a material such as polyvinyl chloride (PVC).

In one embodiment of the invention, at least one of the four rigid elements (3) has a length selected between 0.40m to 0.50m, and a width selected between 0.40ra and 0.45in

With respect to the ropes and / or cables (5), these are made of a material that is selected from the polychloride of the title (PYC); chlorinated vinyl polychloride (CPVC); polyethylene terephthalate (PEI ^' ), polyamides (PA) (eg PA12, PA6, PA66); polyelorotritluorethylene (PCTPE); Vinyldene Polyilluoride (PVDF); ethylene polytetrafluoride (PTFE); ethylene-elorotrifluoroethylene (ECTPE); plastics (polyester, viniiester, epoxy, vinyl resins) reinforced with fibers (eg glass, aramid, polyester) and bule.

In the embodiment of the invention, the diameter of the ropes and / or cables (5) is selected from 2mm to 1mm. In one embodiment of the invention, the cnerdas and / or cables (5) have a diameter between 8mm to ÍOmm.

Making reference to the FIO. 2, in step b), at least one or more racks (2) are arranged in a dinner environment (or). It will be understood in the present invention that a closed environment (6) is any device that encloses a certain volume such as a volume between 0.1 L. to 5001. In one embodiment of the invention it has a volume between 100E to 3501. ,

The closed environment (6) has a geometric shape selected from cylindrical, square, rectangular, elliptical, oblong, regular and irregularly shaped and has a cross section selected from a circular cross section, square cross section, rectangular cross section or combinations of the previous. In one embodiment of the invention, the closed environment (6) has a cylindrical shape and has a circular cross section.

In one embodiment of the invention, the closed environment (6) has a height selected from O. lrn to 2m, and a diameter between O. lm to lm.

In one embodiment of the invention, the closed environment (6) is made of a plastic material that is selected from polyvinylchloride (PVC); chlorinated polyvinylchloride (CPVC); polyethylene terephthalate (PET), polyamides (PA) (v, g. PA12, PA6, PA66); polyelorotrifluorctylene (PCTFE); polyvinylidene fluoride (PVDF); ethylene polytetrafluoride (PTFB); ethylene-cyclootrifluoroethylene (FCTFE); plastics (polyester, vinyl, epoxy, vinyl resins) reinforced with pounds (e.g. glass, aramid, polyester).

In a further embodiment, the dinner environment (or) is of a material selected from carbon steel, iron foundries, galvanized iron, chromium steels, chromium-nickel steels, croino-nickel-titanium steels, alloy nickel-Cfóitío-tiólibdeno-tungsleiio, ferrous alloys to the chromium-molybdenum, AIS1 301, A1SI 302, AI SI 304, AIS! 316, AIS! 405, AÍSi 410, A1SI 430, AISI 442, alloy steel with manganese or combinations of the above.

Preferably, the closed environment (6) is made of a material such as vi ni lo polychloride (PVC). This material is chosen because it resists chemical attacks such as the composition of nutrients and ozone, this material has an advantage over materials with some Carbon composition because it does not oxidize and endures over time. An additional advantage of this material is that it does not give off particles that contaminate the nutrient composition and therefore does not affect the growth or development of the seeds.

Inside the closed environment (or) the frames (2) are arranged in such a way that they occupy the smallest possible space, that is to say that they are stacked vertically or horizontally along at least one of the four rigid elements (3). In one embodiment of the invention, 10 frames (2) to 20 frames (2) a! interior of the dinner environment (6).

In step c) a nutrient and ozone composition is supplied to the closed environment (6).

In one embodiment of the invention, at least one container (1) disposed in at least one frame (2) remains within the closed environment (6) a selected time between 24 hours to 60 hours.

During this time, the seeds deposited in at least one container (1) manage to take full advantage of the absorption of the nutrient and ozone composition, allowing to accelerate their germination process.

In a modality of the invention the composition of the nutrients is selected from nitrates and sulfates. In one embodiment of the invention, the nitrates have a proportion between 60% and 80%, and a proportion of sulfates between 1-5% and 30%.

The proper proportion of the nutrient composition depends on which objective the user has about their hydroponic culture, if you want your culture to take 10% less than a normal hydrophilic culture you will have to modify the aforementioned proportions.

In an embodiment of the invention, the nitrates are selected from magnesium nitrate, calcium nitrate, potassium nitrate or combinations of the foregoing. In one embodiment of the invention, sulfates are selected from potassium sulfate, copper sulfate, manganese sulfate, zinc sulfate or combinations of the foregoing.

In one embodiment of the invention, the nutrient composition may comprise monoammonium phosphate, boric acid, iron chelate, ammonium molinate or combinations of the foregoing.

In one embodiment of the invention ozone is supplied to the nutrient composition, this in order to reduce the harvest time of the humidonic crop.

It is to be understood in the present invention that the different types of nutrient composition depend directly on what type of vegetable it is desired to grow, because each seed needs different types of compositions in different concentrations.

In one embodiment of the invention ozone is supplied to the nutrient composition as an additional component, with the aim of accelerating the seed germination process.

Referring to the F1G. 3, in step d), the frame (2) is removed from the closed environment (6) of stage b) and placed in a tray (7) containing the composition of nutrients and ozone, until germination of the seeds in the containers (1), In one embodiment of the invention, the tray (7) has the same dimensions as the frame (2).

In one embodiment of the invention, the tray (7) has a length selected between 40 to 0.55m, a width selected between 0.40m and Q.45m, a height selected between 0.0hn and 0.05m, and a thickness selected between O.OÍ and 0, Q5.

The tray (7) fulfills these characteristics since what is sought is to have at least one frame (2) in a simple and practical way, but it could contain more than one frame, In one embodiment of the Invention, the material of the tray (7) is selected from carbon steel, iron foundries, galvanized iron, chromium steels, chromium-nickel steels, chromium-nickel-titanium steels, quel alloy -erorno-molybdenum-tungsten, ferrous alloys to chromium-molybdenum, AIS1 301, / MSI 302, AIS! 304, AISI 316, AIS! 405, AIS I 410, AIS! 430, AISI 442, alloy steel with manganese and combinations of the above, Preferably the tray (7) is made of a material like AISI 304.

Before placing the frame (2) in the tray (7), the nutrient composition with ozone is supplied to the tray (7). Preferably, the amount of nutrient and ozone composition should not exceed three quarters of the medial distance of the tray height (7).

To place the racks (2) inside the tray (7), the containers (1 j with the seeds must be exposed to the weather and part of the containers (1) must be in contact with the nutrient composition and the ozone .

In one embodiment of the invention, the frame (2) remains in the tray (7) for a period of 10 days to 20 days. Preferably 1 5 days.

In one embodiment of the invention, the tray (7) with the frame (2) is protected by a cover (not illustrated) for the established time which is between 10 days and 20 days. The objective of having the cover is to protect: the containers (1) with seeds from the sun, rain and possible external agents that can damage the germination of the seeds.

In one embodiment of the invention, the cover is at a distance from the trays (7) between lin and

5m.

Referring to FIG. 4, in step e), the racks (2) are removed from the trays (7) after germination of the seeds and they are arranged outdoors. This is done so that the already germinated seed that we will now call a seedling, adapts to the possible variations of the climate and the possible effects that this may bring to the seedling.

It will be understood in the present invention that weathering is related to a natural environment with variations and inclement weather that may affect unprotected places or things, specifically related to leaving something exposed to the free air.

The racks (2) with the containers (1) and the seeds already germinated remain outdoors for a time between 3 days to 5 days.

It is to be understood that the time to remain outdoors depends on the type of vegetable that is sown.

Making F1G. 5, in step f), each frame (2), the containers (1) are removed and arranged in a plurality of hollow pipes (8) containing the nutrient and ozone composition.

It will be understood in the present invention that plurality of hollow pipes (8) comprises at least one hollow pipe (8) in which at least one container (1) can be arranged inside.

The plurality of pipes (8) depends on the amount of seedlings to be sown, for example, in one embodiment of the invention, the amount of hollow pipes (8) is selected from 1 tube to 30 tubes. Preferably, 20 tubes are selected for 1440 seedlings.

In one embodiment of the invention, the plurality of hollow pipes (8) has a length selected between 1 m to 30m, preferably between 1 2 to 15 meters.

In one embodiment of the invention, the material of the plurality of hollow pipes (8) is selected from carbon steel, iron foundries, galvanized iron, chromium steels, steels a! chrome-nickel, chrome-nickel-titanium steels, nickel-chrome-molybdenum-tungslene alloy, alloys Chromium-N-Polybdenum Ferrous, AISI 301, A1S1 302, AISI 304, AISI 316, AIS1 405, Ai SI 410, AIS1

430, AlSi 442, alloy steel with manganese and combinations of the above.

In one embodiment of the invention, the plurality of hollow pipes (8) is made of a plastic material that is selected from polyvinylchloride (PVC); of chlorinated vinyl polychloride (CPVC); polyethylene teréfíaíato (PET, for its acronym in English), poly amides (PA) (e.g., PA12, PA6, PA66); polychlorotrifluoroethylene (PCTFE); polyvinylidene fluoride (PVDF); ethylene polytetraíluoride (RΊTΈ); ethylene-chlorotrilluoroethylene (ECTFE); plastics (polyester, vinyl ester, epoxy, vindica resins) reinforced with fibers (e.g. glass, aramid, polyester).

In one embodiment of the invention, the cross section of the plurality of hollow pipes (8) is selected from circular cross section, square cross section, oblong cross section, elliptical cross section, rectangular cross section, regular cross section and cross section irregularly shaped In one embodiment of the invention, the cross section of the plurality of hollow pipes (8) is circular and its thickness is selected from 2inm 20mm.

At the longitudinal ends of the pluralities of hollow pipes (8), a plug (not illustrated) or a sealing object is connected, this in order to contain what is to be disposed within the plurality of hollow pipes (8) , for example, the composition of nutrients with ozone.

Referring to the F1G. 5, in one embodiment of the invention, the plurality of hollow pipes (8) comprises a plurality of through holes (10) along their length.

It will be understood in the present invention that a plurality of through holes (10) refers to the plurality of hollow pipes (8) having at least one through holes along the length of the hollow pipe (8), and being It will also be understood in the present invention that a through hole pierces a solid or hollow body. In one embodiment of the invention, the through holes (10) have a through diameter between hnm to 3 ( ⁾ mm. In one embodiment of the invention, the through diameter is 15mm.

Through holes (10) are repeated along the pipe. In one embodiment of the invention it is repeated between O. lrn at 0.3.

After having the plurality of hollow pipes (8) with the through holes (10), the seedling obtained in step e) is moved or transplanted in the different through holes (10) already explained above.

Referring to the F1G. 5, In one embodiment of the invention, after placing the seedlings in the through holes (10) in the plurality of hollow pipes (8), a retention object (1 1) is placed in the through holes (1 0) surrounding the seedling, in order to sustain and / or secure the seedling so that it does not fall to the ground, or slips to! interior of the plurality of hollow pipes (8).

Finally, one embodiment of the invention, the retention object (1 1) can be any object that serves to sustain or secure seedlings without damaging its structure, for example they can be rubber scraps or some biodegradable material.

In an embodiment of the invention, the retention object (1 1) has a length equal to or greater than the development of the diameter of the through hole (10) of the plurality of hollow pipes (8).

In one embodiment of the invention, the nutrient and ozone composition is supplied within the plurality of pipes (8), so that the seedling comes into contact with these nutrients and ozone and thus can grow until it is collected. The seedlings are in the plurality of hollow pipes (8) for an estimated time between 20 days and 30 days, or until the person moderately versed in the matter is convenient to remove or make use of fas plants already obtained during stage í),

In the end of the present method, the fact that it does not include pumping elements, temperature control systems and electrical energy stands out. This allows the present invention to be developed in fields where service flushes do not abound, such as water and where the acquisition of electromechanical elements is scarce.

Example l Method for a hydroponic culture.

A method for a hydroponic culture was developed without the need to use electromechanical elements such as a re-circulating pump or other types of pump and where the water used during the method is less than the current hydroponic cultures.

For this, the following stages are followed:

Stage a) locate seeds in a square container with measurements of 0.025mx 0.025m, preferably of polyurethane, where the container (1) has a first opening with a depth to the medial distance with respect to the length of the container, and a second opening perpendicular to the first opening with the same depth. arranging the containers (1) in a frame (2), where the frame (2) comprises at least four rigid elements (3), and the union of these forms the frame (2); at least one of four rigid elements (3) have the following characteristics; width: 0.4 ( ⁾ m;

length: 0.45m; material: polyvinyl chloride (PVC);

Where the frame (2) comprises through holes along at least one of the four rigid elements (3) and ropes and / or cables (5) are provided for the purpose of placing or arranging the containers (1) and avoiding that these slide down the frame (2).

Stage b) arrange the racks (2) with the containers (1) in a closed environment (6), preferably the closed environment (6) has the following characteristics: volunten: 200L; geometric shape: cylindrical; cross section: circular; height: lm; diameter: O.óm; material: polyvinylchloride;

Stage c)

In the closed environment (6) a nutrient composition with ozone is supplied, the nutrient composition can be: magnesium nitrate, calcium nitrate, potassium nitrate, potassium sulfate, monoammonium phosphate, copper sulfate, manganese sulfate , zinc sulfate, boric acid, iron chelate and ammonium moinate; in a mixture where the proportion of nitrates is 75%, and sulfates of 25%.

The racks (2) are left inside the closed environment (6) for a period of 30 hours.

Step d) remove the frame (2) from the closed environment (6) and place it in a tray (7), when it is placed on the tray (7), the semi-lines must be exposed to the weather. The tray (7) has the following characteristics: length: 0.45m; width. 0.43m; tall. 0.03m; thickness; 0.03m; material: polyvinyl oruro (PVC);

The trays (7) must have a cover (not illustrated) that protects them from sun and rain, preferably the cover can be zinc or plastic plates at a height measured from the tray (7) vertically of 1.5 meters.

The frame (2) must be in the tray (7) in contact with the nutrient and ozone composition within a certain period of 15 days or until the germination of the seeds is achieved!

remove the racks (2) from the tray (7) after the seed has germinated, and they are arranged outdoors for a period of 3 days.

Stage f)

The germinated seedling is extracted from each frame (2) and arranged in a plurality of hollow pipes (8) in its through holes (10), the plurality of hollow pipes (8) has the following characteristics: length: 12m; diameter: 0.07m; cross section: circular;

The plurality of hollow pipes (8) has perforations: passages (10) along their length with the following characteristics: diameter: Q.07m; distance I entered perforations; 0.07;

In the through holes (1.0) there is a retention object (1 1) between the seedling and the diameter of the through hole (4).

A plurality of nutrients and ozone composition is supplied in the plurality of hollow pipes (8).

After 20 days you can take out the plant for e! human consumption.

It should be understood that the present invention is not limited to the modalities described and illustrated, nor limited to the materials and / or measures set forth, since as or will be apparent to a person versed in the art, there are possible variations and modifications that are not They depart from the spirit of the invention, which is only defined by the following claims.

Claims

1. A method for obtaining at least one hydroponic culture comprising the following steps; a) place at least one seed in at least one container (1) and arrange them in a rack (2);  b) arrange one or more racks (2) in a closed environment (6);  e) supply a composition of nutrients and ozone to the closed environment (6); d) remove the frame (2) from the closed environment (6) and place it in a tray (7) containing the composition of nutrients and ozone, until germination of the seeds in at least one of the containers (I);  e) remove the frame (2) from the tray (7) and place it outdoors; t) extract from each frame (2) the germinated seedling and place it in a plurality of hollow pipes (8) containing the composition of nutrients and ozone. 2. E! method according to claim 1, wherein in step e) the nutrient composition is selected from nitrates and sulfates 3. The method according to Claim 2, wherein the nutrient composition has a proportion of nitrates between 60% and 80% and a proportion of sulfates between 15% and 30%. 4. The method according to Claim 2, wherein the nitrates are selected from magnesium nitrate, calcium nitrate, potassium nitrate or combinations of the foregoing. 5. The method according to Claim 2, wherein the sulfates are selected from potassium sulfate, copper sulfate, manganese sulfate, zinc sulfate or combinations of the foregoing. 6. The method according to Claim 2, wherein the nutrient composition further comprises monoammonium phosphate, boric acid, iron chelate, ammonium molinate or combination of the foregoing. 7. The method according to Claim 1, wherein in step b) the frame (2) remains in the closed environment (6) for a time between 24 hours to 60 hours. 8. The method according to Claim 1, wherein in step c), it is characterized by supplying ozone to the nutrient composition 9. The method according to Claim i, wherein in step d) the frame (2) remains in the tray (7) for a time between 10 days to 20 days. 10. The method according to Claim I, wherein in step e) the frame (2) remains outdoors for a time between 3 days to 5 days. The method according to Claim I, in step f) wherein in each tube the plurality of hollow pipes (8) comprises a plurality of through holes (10) along its length. 12. The method of Claim 1, wherein the method does not comprise pumping elements, temperature control system and electrical energy.