ITVI20070006A1 - ELEMENT FOR AEROPONIC AND HYDROPONIC CULTIVATIONS AND ITS MANAGEMENT SYSTEM - Google Patents

Description

DESCRIPTION

of the patent for industrial invention entitled "ELEMENT FOR AEROPONIC AND HYDROPONIC CROPS AND RELATIVE MANAGEMENT SYSTEM"

The invention concerns aeroponic and hydroponic crops. More in detail, the invention relates to an element for the construction of plants for aeroponic and hydroponic crops, as well as a relative plant, particularly suitable for the cultivation of vegetables, flowers and seedlings in general.

As is known, aeroponic and hydroponic crops make use of devices in which the crops are usually arranged in specific containers made of synthetic or other material equipped with means designed to irrigate and fertilize the roots of the seedlings with a concentration of nutrients dissolved in the water.

In these devices the function of supporting the soil is carried out by means of supporting and supporting the plants which can be a panel and / or a sheet and / or a gauze and / or a net and / or inert material to be used as substrate or other. A known embodiment of devices for aeroponic and hydroponic crops provides that the means that distribute the nutrient solution are located on the bottom of the container and are equipped with a plurality of holes or nozzles capable of delivering this nutritional solution to the roots that develop inside. of the container itself.

In particular, these holes or nozzles spray and nebulize the nutritional elements in solution towards the roots suspended in the air below the support surface of the seedlings.

A first drawback of this embodiment is constituted by the fact that any particles, soil and other debris can detach from these roots and obstruct the holes or nozzles of the nutrient solution distribution means, moreover the roots themselves, growing and developing towards downwards, they can clog these holes or nozzles.

This prevents an adequate and uniform delivery of the nutrient solution to the roots and therefore an optimal growth of the plants.

Another drawback is the fact that the root system that develops inside the container over time tends to form a barrier that is interposed between the nebulizers and the roots.

This has the consequence that these are not wetted in all their surface and extension but only the lower ends of the roots are touched and wet, therefore the quantity of nutrients absorbed also decreases to the detriment of an optimal growth of the seedlings and the efficiency of the system as a whole.

A further drawback of known embodiments of devices for aeroponic and hydroponic crops is the fact that they do not have an efficient system for recycling the nutrient solution, with consequent waste and dangerous dispersion of pollutants into the environment. Another drawback is constituted by the fact that these realizations do not have an efficient, simple and economical feeding and management system of the nutritive solution.

Various solutions have been proposed for the realization of devices for aeroponic and hydroponic crops, but the results obtained from them are not those hoped for and theoretically possible.

It is an object of the present invention to overcome or at least limit the aforementioned drawbacks.

In particular, a first purpose of the invention is to create an element and a relative plant for aeroponic and hydroponic crops, particularly suitable for the cultivation of vegetables, flowers and seedlings in general, which allow to overcome the aforementioned drawbacks.

It is another purpose to create an element and a plant capable of spraying and fertilizing the roots of vegetables, flowers and seedlings in general with a nutrient solution so that particles, soil, various debris, the roots themselves and anything else do not go. to hinder and / or limit this action or at least this is more difficult to happen.

It is a further purpose to create an element and a plant that allow these roots to be wet substantially over their entire surface and extension.

It is another purpose to create an element and a system that allow to recover and recycle the nutrient solution that is not absorbed by the root system of the seedlings. vegetables, flowers and seedlings in general, in the field of aeroponic and hydroponic crops.

Another purpose is to create a system that allows you to automatically control and correct the quantities of nutrients in solution in order to maintain an optimal concentration of these nutrients over time.

It is a further purpose to create an element and a plant for aeroponic and hydroponic crops in which the crops have a continuous production cycle.

It is a further purpose to create an element configured to combine easily and quickly with other similar elements for assembly in series.

Last but not least, the aim is to create a relative element and a relative plant that are economical, as well as easy to build and assemble.

The said purposes are achieved by an element for the construction of plants for aeroponic and hydroponic crops, as well as by a relative plant, particularly suitable for the cultivation of vegetables, flowers and seedlings in general expressed and characterized in the respective independent claims.

Advantageous embodiments are the subject of the dependent claims.

The proposed solution advantageously allows you to create an element and a plant that allow you to spray and fertilize the roots of vegetables, flowers and seedlings in general in a substantially uniform manner regardless of the development of the root system.

Still advantageously, the proposed solution allows to realize an element and a plant capable of increasing the quantity of nutrients which come into contact and which are absorbed by the roots of the plants.

Still advantageously, the proposed solution allows to create an element and a system that minimize the dispersion of polluting substances, meeting the favor of the anti-pollution regulations, also safeguarding the health of the operators.

Still advantageously, the proposed solution allows to realize a device which, by minimizing waste, allows to contain production costs.

Still advantageously, the proposed solution allows for the creation of an element and a system that reduce the intervention of human operators to a minimum.

Still advantageously, the proposed solution allows to realize an element and a plant which can obtain optimal performance conditions, which lead to achieve high productions.

The aforementioned purposes and advantages will be better highlighted during the description of some preferred embodiments of the invention, given as an indication and not a limitation, referring to the attached drawing tables where:

- Figure 1 represents a schematic view in perspective of an element object of the invention;

- figure 2 represents an exploded and perspective view of the element of figure 1;

- figure 3 represents a view of a cross section of the element of figure 1;

- Figure 4 represents a schematic view in perspective of another example of realization of an element of the invention;

- figure 5 represents an exploded and perspective view of the element of figure 4;

- figure 6 represents a view of a cross section of an element of the element of figure 4;

figure 7 represents a plan view of the element of figure 6;

figure 8 represents a view of another cross section of the element of figure 7;

Figures 9 and 10 represent a front view and a side view of another component of the element of Figure 4;

Figures 1 1 and 12 represent a front view and a side view of a further part of the element in the figure

Figure 13 represents a schematic view in perspective of a further example of embodiment of an element of the invention;

figure 14 represents a longitudinal section of the element of figure 13;

figure 15 represents a cross section of the element of figure 13;

figure 16 represents an exploded and perspective view of the element of figure 13;

figures 17 and 18 represent a front view and a side view of an element of the element of figure 13; Figures 19a, 19b and 19c each represent a cross section of as many examples of embodiment of an element of the invention;

Figure 20 represents a schematic view of a plant for aeroponic and / or hydroponic crops, also object of the present invention.

By way of introduction, it is pointed out that the equal parts of the single embodiment examples are provided with the same reference numbers. The position indications mentioned in the individual executive examples are to be transferred to the new position in the event of a change in position.

An example of embodiment of an element for aeroponic and hydroponic crops object of the present invention is schematically represented in figures 1 to 3, where it has been indicated as a whole with the number 1.

It comprises a box-like body 2 open at the top in which a bottom 3 and side walls 4 are identified.

The body 2 develops mainly along a longitudinal axis 5 and is provided with support means 6 suitable for supporting a support element E for the plants P to be cultivated.

According to the invention, the nutrient solution S is brought to the roots R of the plants P grown in the element 1 through delivery means 8 preferably arranged on at least one of the side walls 4 of the element 1 itself.

This advantageously allows to ensure that the nutrient solution S always reaches the roots R even when these have developed. During growth, in fact, the roots R tend to move towards the bottom 3 of the element 1 and not to affect the side walls 4 where the means 8 are advantageously arranged, thus avoiding obstruction.

Furthermore, this expedient allows the nutrient solution S to advantageously also reach the upper part of the roots R allowing the solution S itself to descend by gravity along the entire root R affecting substantially every part of it, thus increasing the quantity absorbed by the plant P.

More specifically, the dispensing means 3 comprise, in the preferred non-limiting embodiment shown in Figures 1 to 3, two dispensing ducts 9 which involve the element throughout its longitudinal development and are each provided with one or more nozzles. 10 suitable for spraying and / or nebulising the nutrient solution to direct it towards the center of the box-like body 2, towards the roots R of said plant products P.

Each delivery duct 9 is removably applied to the side wall 4 and more precisely it is housed in a longitudinal seat made on each side longitudinal wall of the element 1, as visible in figure 3.

Each duct 9 can be fixed to the corresponding side part 4 by means of fixing means 6 which, in the preferred embodiment shown, comprise the two aforementioned seats which extend longitudinally on the side walls 4 of the body 2, as can also be seen in figure 3. In other embodiments, the pipes are made in a single fusion with the entire channel and / or with the side walls.

It is clear, however, that in other embodiments these fastening means may also include other systems, for example of the preferably snap-fit type.

The element 1 also comprises at least one inlet duct 11 for the nutrient solution communicating with each delivery duct 9.

Still according to the invention, element 1 also comprises means 12 for collecting the nutrient solution S which is not absorbed by the roots R and is deposited on the bottom 3 of element 1.

In particular, these collection means 12 comprise at least one collection channel 13 arranged near the bottom 3 of the main body 2 which communicates with the outside via a discharge duct 14 which allows the evacuation of the excess liquid collected.

More precisely, in the preferred non-limiting embodiment shown, the collection channel 13 comprises a groove which extends longitudinally on the bottom of the main body 2.

It should also be noted that, in the preferred non-limiting solution shown, the main body 2 substantially has a substantially V-shaped cross section. More particularly in the embodiment shown, the side walls 4 are inclined with respect to the bottom 3 with an angle preferably comprised between 90 ° and 120 °. This advantageously allows to facilitate the collection and subsequent evacuation of the excess nutrient solution S which is deposited on the bottom 3 of the main body 2.

However, it is clear that this main body 2 may also have cross sections having geometric shapes different from the previous one, such as for example a U-shaped or mixtilinear or polygonal or semicircular or curved cross section as represented for example in the embodiments shown in figures 19a, 19b and 19c.

Still according to a preferred embodiment of the invention, the body 2 is made of a preferably synthetic material inert to the nutrient solution S, such as for example a plastic, and is obtained with an extrusion process, as also shown below.

As regards the support means 6 of the support element E of the plants P, generally consisting of a plastic film, they comprise a projection 61 which extends longitudinally to the element 1 and more precisely in the upper external part of the side walls of the body 2. In this case the support element E can cling to the projection 61. Alternatively, the projection 61 can be replaced by a longitudinal groove.

A further embodiment of an element of the invention, indicated as a whole with the number 100 in figures 4 to 12, differs from the previous one in that it comprises a main box-like body 2a open laterally on at least one side. The body 2a can be closed laterally by means of corresponding removable closing elements 15 and 16, as shown in figure 5.

This advantageously allows to realize the body 2a also with an extrusion process.

Furthermore, the preferred non-limiting embodiment shown in Figures 4 to 12 differs from the previous one in that the delivery duct 9a, as visible in particular in Figures 6 and 8, forms an integral part of the main box-like body 2a.

This allows to further simplify the production steps of the element 100 and in particular of the main box-like body 2a.

It should also be noted that in this embodiment, again according to the invention, the body 2a is preferably provided, at at least one end, with first connection means 17, suitable for coupling to second connection means 18 belonging to at least one closing element 15 and 16. More particularly, in the non-limiting embodiment shown in Figures 4 and 5, the first connecting means 17 are arranged on both ends of the body 2a, and consist of the end part of the ducts 9a and of the discharge channel 13.

The second connection means 18 belonging to the two lateral closing elements 15, 16, visible in detail respectively in Figures 9, 10 and 11, 12, comprise, in the preferred non-limiting embodiment shown, tubular elements 18a, 18b, suitable for to snap-fit to the aforementioned ducts 9a and 13.

It should also be noted that at least one lateral closure element 16 also has at least one inlet duct 11 adapted to communicate with the ducts 9a of the dispensing means 8 to allow the feeding of the nutritive solution S and at least one discharge duct 14 adapted to communicate with the collection channel 13 to allow the evacuation of the excess solution S which settles on the bottom 3. It should also be noted that advantageously, in the embodiment shown, the tubular elements 18a and 18b put the inlet ducts 11 in communication with the delivery means 8 and the discharge ducts 13 with the discharge channel 14.

This advantageously allows to simplify the construction of the element, thus reducing production costs and facilitating its installation.

It is clear that in other embodiments not shown, the connection means 17, 18 may include tabs or screws or equivalent systems and the connection between the ducts obtained for example by means of special tubular elements.

It should be noted that the element 100 is also provided with support means 20, suitable for supporting it and keeping it raised from the ground. This advantageously allows to obtain evacuation by gravity of the excess solution through the discharge ducts 14.

In the preferred non-limiting embodiment shown, these support means 20 comprise support feet 21 integral with the main box-like body 2a. More particularly, these supporting feet 21 belong to the lateral closing elements 15, 16.

A further non-limiting embodiment of an element of the invention, indicated as a whole with the number 200 in figures 13 to 18, differs from the previous one in that it comprises a plurality of main bodies 2b, two in the example represented, connected together by means of an intermediate element 25 and closed at the ends by the closing elements 15 and 16.

Said intermediate element 25 is provided on both sides, as can be seen in particular in Figures 17 and 18, with the aforementioned second connection means 18 which comprise tubular elements 1 8 b suitable for coupling in the delivery ducts 9b and in the discharge ducts 13 of each main body 2b, ensuring its hydraulic connection.

This allows to realize an element 200 of desired length by assembling several main bodies 2b of standard size, thus realizing a modular system.

It should also be noted that in the contact surfaces between two adjacent elements connected to each other, there may be one or more hydraulic sealing elements, consisting for example of gaskets, designed to prevent the residual liquid not absorbed and the solution brought by the dispensing means does not go out of their respective pipelines.

It is also clear that, in all the connection points between the various parts described, hydraulic sealing gaskets, not shown, may be provided to prevent any liquid leaks.

It should also be noted that the element 200 has both ends closed by corresponding side elements 15 and 16, one of them presenting the inlet 11 and discharge conduits 14 closed by respective caps 30 as shown in figures 14 and 16.

Figure 20 schematically represents an aeroponic and / or hydroponic plant cultivation plant, indicated as a whole with the number 500 which also forms the subject of the present invention, in which elements of the type described above have been used.

It is clear, however, that this culture system can also use elements of different types as long as they are provided with inlet ducts 11 for the supply of the nutrient solution S and with exhaust ducts 14 for the excess solution present inside each element 1. , 100, 200.

More particularly regret 500 comprises an element 200, storage means 501 of the various chemical products to be mixed to obtain a nutritive solution for the cultivated plants P comprising containers 501a, 501b, - 50 1 i communicating through ducts 502 with at least one storage tank 503 of the nutrient solution S.

The tank 503 also communicates through an adduction duct 504 of the nutrient solution S with the delivery means 8 with which the element 200 is provided.

The system also includes a return pipe 505 of the nutrient solution S in hydraulic communication with at least one discharge pipe 14 for the evacuation of the excess solution of the element 200.

Advantageously, the proposed regrind is of the closed and automated cycle type and further comprises means 506 suitable for withdrawing the nutrient solution from the tank 503 and conveying it to the dispensing means of the element 200. Again according to the invention, regretting 500 also comprises means 507 adapted to withdraw the solution S in excess present in the element 200 and to convey it towards the tank 503 of the nutrient solution S.

This advantageously allows to realize a closed cycle plant in which the nutritive solution is not dispersed but rather recovered for subsequent reuse. This solution also makes it possible to avoid contact with the soil T of the nutrient solution S and / or of the solution S in excess, thus avoiding any pollution due to the chemical substances present in the solution and / or the insecticides that are used during the various phases of cultivation and are collected at the bottom of each element,

Said means 506 and 507 comprise at least a first hydraulic pump 508 suitable for withdrawing the nutrient substance and for pushing it towards the delivery means of the element 200, as well as at least a second pump 509 suitable for sucking the excess nutrient evacuated through the ducts drain 14 and convey it towards the tank 503.

The system 500 also includes means 510 suitable for regulating the flow of substances from containers 501a, 501b,. .. 50 1 i towards the tank 503. Said means comprise, in the preferred embodiment, valve means 51 l a, consisting of solenoid valves, and pumps 51 1b controlled through a control unit 512. Said control unit 512 preferably comprising a processor electronic through which the operator can set the percentages of chemical products to add to achieve the desired nutrient solution S.

It is clear that regret 500 may not even provide for the presence of pumps designed to force the passage of the solution through the various supply and / or discharge ducts.

It should be noted that the control unit 512 controls the means 506 and 507 comprising, as previously mentioned, the pumps 508, 509 and the relative solenoid valves.

In fact, it is clear that by arranging the tanks and containers of chemical compounds on various levels, it is also possible to exploit the force of gravity, advantageously simplifying regret. The reservoirs of concentrated mother nutrient solutions of macroelements and microelements preferably have inside them both air and mechanical agitators which are able to keep the solutions agitated to avoid the formation of precipitations. The agitators can operate both continuously and at intervals and can be controlled by the 512 control unit.

The plant 500 also advantageously allows to carry out a check and possibly correct and / or integrate and / or regenerate the nutrient solution S contained in the collection tank 503 in a completely automatic way. This is achieved with at least one transducer element, preferably arranged in the tank. 503, suitable for providing information about the composition of the nutrient solution S contained in the collection tank 503, cooperating with the control unit 512.

The control unit is designed to control the various pumps and the opening / closing of the solenoid valves, according to the parameters set by the user and the data provided by the aforementioned transducer.

The operation of the element and of the plant object of the invention will now be described with reference to the plant in figure 20.

The user sets in advance through the control unit 512 the type of nutrient solution S suitable for the plants P to be grown, housed in element 200.

By way of example, the solution can be obtained by suitably mixing two concentrated mother nutrient solutions of macroelements, a concentrated mother nutrient solution of microelements, a pH corrective acid solution and a pH corrective basic solution stored in as many 501 a, 501b, .. 5 0 1 i.

Subsequently, the operator activating regret starts the pumps and the respective solenoid valves which continuously withdraw the various substances in the proportions set by the corresponding containers, conveying them into the tank 503. The nutrient solution S is then taken from the tank 503 by means of the pump 508 and conveyed towards the duct 1 1 of the element 200 through the duct 504.

The solution S through the inlet ducts 11 then reaches the delivery ducts 9b and the nozzles 10 through which it is directed towards the roots of the plants P.

The excess solution, falling by gravity, reaches the bottom 3 of the element 200 and, also thanks to the inclinations of the side walls, reaches the discharge channel 13. Here, also thanks to the evacuation pump 509, it is picked up and conveyed back into the tank 503 for subsequent reuse after any filtering. From what has been said it is clear how the proposed solution allows to achieve the intended purposes and to solve the aforementioned drawbacks.

Although the invention has been described by referring to the attached drawing tables, it may undergo changes during the construction phase, all falling within the same inventive concept expressed by the claims set out below and therefore protected by this patent. It should also be noted that where the features mentioned in the claims listed below are followed by reference signs, they are to be understood as useful for improving the intelligibility of the claim itself and not as limitations in its interpretation. It should also be emphasized that all the details can be replaced by other technically equivalent elements and that the materials used, so long as they are compatible with the contingent use, as well as the dimensions of the various elements, may be any according to requirements.

Claims (8)

CLAIMS 1) Element (1, 100, 200) for aeroponic and hydroponic crops comprising a box-like body (2, 2a, 2b) open at the top in which a bottom (3) and side walls (4) are identified, characterized by the fact that the nutrient solution (S) is carried to the roots (R) of the plants (P) grown in said element (1, 100, 200) by means of delivery means (8) arranged on at least one of said side walls (4). 2) Element according to claim 1) characterized by the fact that said delivery means (3) comprise at least one delivery duct (9) provided with one or more nozzles (10) suitable for spraying and / or nebulising the nutrient solution to direct it in direction of the roots (R) of said plant products (P). 3) Element according to claim 2) characterized in that said at least one delivery duct (9) is housed in a longitudinal seat made on each lateral longitudinal wall of said element (1). 4) Element according to claim 2) characterized in that said at least one delivery duct (9) is made in said box-like body (2, 2a, 2b). 5) Element according to claim 2) characterized in that said at least one delivery duct (9) is removably applied to said side wall (4). 6) Element according to claim 5) characterized in that said at least one delivery duct (9) fixed to the corresponding side part (4) by means of fixing means (6). 7) Element according to claim 6, characterized in that said fixing means comprise two seats which extend longitudinally on the side walls (4) of said box-like body (2). 8) Element according to claim 6, characterized by the fact that said fixing means comprise systems of the preferably snap-in type. Element according to any one of the preceding claims characterized in that said element (1, 100, 200) further comprises at least one inlet duct (11) for the nutrient solution communicating with said delivery means (8). 1100)) Element according to any one of the preceding claims characterized in that it further comprises means (12) for collecting the nutrient solution (S) which is not absorbed by the roots (R) and is deposited on said bottom (3). 11 11)) Element according to claim 10) characterized by the fact that said collection means (12) comprise at least one collection channel (13) arranged in proximity to said bottom (3) which communicates with the outside through a discharge duct (14) which allows the evacuation of the excess liquid collected. 12) Element according to claim 1 1) characterized in that said collection channel (13) comprises at least one groove which extends longitudinally on said bottom. 13) Element according to any one of the preceding claims characterized in that said main body (2) substantially has a substantially (V) cross section. 14) Element according to claim 13) characterized in that said side walls (4) are inclined with respect to said bottom (3) with an angle preferably comprised between 90 ° and 120 °. 15) Element according to any one of claims 1) to 13) characterized by the fact that said main body (2) substantially has a substantially U-shaped or mixtilinear or polygonal or semicircular or curved cross section. 16) Element according to any one of the preceding claims characterized in that said box-like body (2) is obtained with an extrusion or injection process. 17) Element according to any one of the preceding claims, characterized in that it further comprises support means (6) suitable for supporting a support element (E) for the plants (P) to be cultivated. 18) Element according to claim 17) characterized in that supporting means comprising a projection (61) which extends longitudinally preferably in the upper part of said box-like body (2, 2a, 2b). 19) Element according to any one of the preceding claims characterized in that said box-like body (2a) is open laterally on at least one side, said body (2a) being closable laterally by means of corresponding removable closing elements (15, 16). 20) Element (200) any one of claims 1) to 18) characterized in that it comprises at least two main box-like bodies (2b) connected to each other preferably by means of an intermediate element (25) and closed at the ends by at least one element closing (15). 21) Element (200) according to claim 20) characterized in that said intermediate element (25) is provided on the two sides with the aforementioned second connection means (18) which comprise tubular elements (18b) suitable for coupling in the delivery ducts ( 9b) and in the exhaust ducts (13) of each main body (2b), ensuring their hydraulic connection. 22) Element according to claims 19) 0 20) or 21) characterized by the fact that said box-like body (2a) is provided, at at least one end, with first connection means (17), suitable for coupling to second connection means (18) ) belonging to said at least one closing element (15, 16) or to another adjacent element (1, 100, 200). 23) Element according to claims 19) O 20) or 21) characterized by the fact that said main body (2a) is provided, on both ends, with first connection means (17) suitable for coupling to second connection means (18) belonging to at least one closing element (15, 16). 24) Element according to claims 22) or 23) characterized in that said connection means comprise an end part of the ducts (9a) and / or an end part of said at least one discharge channel (13). 25) Element according to claims 22) or 23) or 24) characterized in that said second connecting means (18) comprise tubular elements (18a, 18b). 26) Element according to any one of claims 19) to 25) characterized by the fact that said at least one lateral closing element (16) also has at least one inlet duct (11) adapted to communicate with the ducts (9a) of the means delivery pipe (8) to allow the feeding of the nutrient solution (S) and at least one discharge duct (14) able to communicate with the collection channel (13) to allow the evacuation of the excess solution (S) deposits on the bottom (3). 27) Element (1) according to claim 26) characterized in that said tubular elements (18a, 18b) put the inlet ducts (11) in communication with the delivery means (8). 28) Element according to any one of the preceding claims, characterized in that it comprises supporting means (20), suitable for supporting it and keeping it raised from the ground. 29) Plant (500) for the aeroponic and / or hydroponic cultivation of vegetables comprising at least one element for aeroponic and hydroponic cultivation provided with at least one inlet duct (1 1) for the supply of a nutrient solution (S) for the plants (P) to be cultivated characterized by the fact that it also includes: - storage means (501) of the various chemical products to be mixed to obtain said nutrient solution, comprising at least one container (501 a, 50 lb, ... 501i); - at least one storage tank (503) of said nutrient solution (S) communicating through one or more ducts with said at least one container (50 la, 501b, ... 501i) and through at least one supply duct (504) of the solution nutrient (S) with the delivery means (8) with which said at least one element (1, 100, 200) is provided. 30) Plant according to claim 29) characterized in that it further comprises a return duct (505) of the nutrient solution (S) in hydraulic communication with at least one discharge duct (14) for the evacuation of the excess solution present in said at least one element (1, 100, 200). 31) Plant according to claims 29) or 30) characterized by the fact that it also comprises means (506) suitable for withdrawing the nutrient solution from the tank (503) and conveying it towards said dispensing means of said at least one element (200), said plant being of the closed and automated cycle type. 32) Plant according to claim 31) characterized by the fact that said means (506, 507) comprise at least a first hydraulic pump (508) adapted to withdraw the nutrient solution and to push it towards the dispensing means (8) of said at least one element (200). 33) Plant according to claims 29) or 30) or 31) or 32) characterized in that it further comprises means (507) in communication with said return duct for withdrawing the excess solution (S) present in said at least one element ( 1, 100, 200) and convey it towards said storage tank (503). 34) Plant according to claim 33) characterized by the fact that said means (506, 507) comprise at least a second pump (509) adapted to suck the excess nutrient solution evacuated through said discharge ducts (14) and to convey it towards said tank storage (503). 35) Plant according to any one of claims from 29) to 34) characterized in that it further comprises means (510) adapted to regulate the flow of substances from said at least one container (501a, 501b, - 501 i) towards said tank ( 503) for storage, said means comprising valve means (51 1) controlled by a control unit (512). 3 6) Plant according to claim 35) characterized by the fact that said control unit (512) preferably comprises an electronic processor through which the operator can set the percentages of chemical products to be added to achieve said nutrient solution (S). 3377)) Plant according to any one of claims from 29) to 36) characterized in that said tanks comprise agitator means adapted to keep the solutions agitated to avoid the formation of precipitations. 3388)) Plant according to any one of claims 29) to 37) characterized in that it further comprises means suitable for controlling the composition of said solution (S) cooperating with a control unit (512) to correct and / or integrate and / or regenerating said nutrient solution (S) in said storage tank 3399)) Plant according to claim 38) characterized in that said means comprise at least one transducer element suitable for providing information about the composition of said nutrient solution (S). 4400)) Plant according to any one of claims 29) to 39) characterized by the fact that said at least one element is made according to any one of the