AND OPERATING METHOD THEREOF"

CROSS-REFERENCE TO RELATED APPLICATIONS

This Patent Application claims priority from Italian Patent Application No . 102020000021334 filed on September 9 , 2020 , the entire disclosure of which is incorporated herein by reference .

TECHNICAL FIELD

The present invention relates to a vertically built cultivation system for cultivating plants and to the operating method thereof .

In particular, the present invention relates to the distribution of climatised/conditioned air in a vertically built cultivation system (vertical farm) to which the following discussion will explicitly refer without losing generality .

BACKGROUND ART

As is known, vertically built cultivation systems , so- called "vertical- farms" , are structured to implement high- density plant cultivation processes , such as plants/vegetables , in closed cultivation containers by means of the so-called arti ficial cultivation systems which di f fer from traditional cultivation systems at least in that they use soil- free cultivation trays , use controlled lighting and power systems , and conditioning systems to feed conditioned air into the closed cultivation container . Generally, the cultivation trays are mounted on support frames and are arranged on a series of cultivation planes superimposed on more height levels so as to conveniently exploit , in addition to the traditional hori zontal space , also the vertical space available in the cultivation container .

In the cultivation systems described above , the conditioning system does not guarantee the correct distribution of temperature and humidity inside the cultivation container . In particular, the aforesaid cultivation systems show a certain degree of unevenness in the temperature and humidity of the air in the cultivation container as the height of the cultivation planes varies . This variation leads to the implementation of an optimal cultivation process only in some cultivation planes and exposes the remaining cultivation planes to di f ferent climatic conditions , which signi ficantly af fect the outcome of the cultivation in terms of either the quantity and the qualitative or organoleptic properties of the plants produced .

Cultivation systems are also described in WO2019077571 Al and CN 102318523 A.

DISCLOSURE OF INVENTION

Aim of the present invention is therefore to reali ze a vertically built cultivation system having a conditioning system which is able to distribute the conditioned air uni formly inside the cultivation container so as to guarantee the same conditions of air humidity and temperature at all the cultivation trays independently of the height level of the relative cultivation planes .

This aim is achieved by the present invention in that it relates to a cultivation system for cultivating plants comprising : a closed cultivation container which extends along a hori zontal reference axis and having vertical side walls which extend parallel to said reference axis , a plurality of cultivation trays for cultivating plants , which are arranged in said cultivation container in positions alongside one another approximately hori zontal and lying on a series of cultivation planes arranged one on top the other with respective pre-set heights relative to a hori zontal reference plane so as to form a plurality of vertical columns of cultivation trays , an air-conditioning system which is designed to feed conditioned air into said cultivation container by means of at least one box-shaped air distribution duct , which is vertically interposed between two vertical columns of cultivation trays , said air distribution duct comprises two air di f fusion walls opposite each other, which extend on respective vertical planes which are parallel to each other and to said reference axis , the two air di f fusion walls have support means structured to support said cultivation trays arranged on said two columns of trays in the respective cultivation planes , and have a plurality of through openings for selectively emitting the conditioned air present in said air distribution duct towards said cultivation trays of said two columns of trays .

Preferably the cultivation system is also reali zed as defined in the corresponding accompanying claims .

The present invention further relates to an operating method for a cultivation system for cultivating plants comprising : a closed cultivation container which extends along a hori zontal reference axis and having vertical side walls which extend parallel to said reference axis , a plurality of cultivation trays for cultivating plants , which are arranged in said cultivation container in positions alongside one another approximately hori zontal and lying on a series of cultivation planes arranged one on top the other with respective pre-set heights relative to a hori zontal reference plane so as to form a plurality of vertical columns of cultivation trays , an air-conditioning system which is designed to feed conditioned air into said cultivation container by means of at least one box-shaped air distribution duct , which is vertically interposed between two vertical columns of cultivation trays , said air distribution duct comprises two air di f fusion walls opposite each other, which extend on respective vertical planes which are parallel to each other and to said reference axis , the two air di f fusion walls have support means structured to support said cultivation trays arranged on said two columns of trays in the respective cultivation planes , and have a plurality of through openings for selectively emitting the conditioned air present in said air distribution duct towards said cultivation trays of said two columns of trays .

Preferably the operating method for a cultivation system is provided as defined in the corresponding accompanying claims .

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will now be described with reference to the accompanying drawings , which show a nonlimiting embodiment thereof , wherein :

- Figure 1 is a schematic plan view of a vertically built cultivation system for the production o f plants reali zed according to the dictates of the present invention,

- Figure 2 is a section I- I with parts removed for clarity ' s sake and enlarged scale parts of the vertically built cultivation system shown in Figure 1 ,

- Figure 3 is a schematic side elevation view of an air di f fusion wall included in the vertically built cultivation system subj ect matter of the present invention,

- Figure 4 is a side elevation perspective view with enlarged scale parts , of an air di f fusion wall included in the vertically built cultivation system subj ect matter of the present invention,

- Figure 5 is a side elevation perspective view with enlarged scale parts , of an air di f fusion wall included in the vertically built cultivation system subj ect matter of the present invention,

- Figure 6 is a side elevation perspective view of a detail of the vertically built cultivation system subj ect matter of the present invention .

BEST MODE FOR CARRYING OUT THE INVENTION

The present invention will now be described in detail with reference to the accompanying Figures to enable a skilled person to reali ze and use it . Various modi fications of the embodiment described will be immediately clear to the skilled person and the general principles disclosed can be applied to other embodiments and applications without departing from the protection scope of the present invention, as defined in the accompanying drawings . Therefore the present invention must not be considered as limited to the described and shown embodiments , however it must be granted the widest protection scope complying with the herein described and claimed principles and features .

The present invention is essentially based on the idea of employing air distribution ducts having a box shape , approximately parallelepiped, and are formed by vertical air diffusion walls on which through openings are obtained and which are arranged on the horizontal cultivation planes to diffuse the conditioned air towards the cultivation trays lying on the cultivation planes themselves.

According to an exemplary embodiment shown schematically in Figure 1, number 1 denotes a vertically built cultivation system for cultivating plants.

In the following discussion, the term plant will be understood to mean any plant product. Preferably, the plant product is for food use. By way of non-limiting example, the plants may comprise a choice of: salads, vegetables, herbs (e.g. rocket, basil, mint) or similar. However, it is understood that the cultivation system subject matter of the present invention is not limited to the cultivation of foodgrade plants of the type listed above, but it may be used in addition to, or as an alternative to, the cultivation of other types of plants generally cultivated in conventional greenhouses, such as flowers, plants or the like.

The cultivation system 1 comprises a temperature and/or humidity controlled container, hereafter referred to as climatised/conditioned cultivation container 2. The cultivation container 2 is essentially closed and may comprise, for example, a box-shaped body/module. In the example shown in Figure 1, the cultivation container 2 extends along a reference axis A and has an approximately parallelepiped shape . It is understood that the present invention is not limited to a cultivation container 2 corresponding to a module but it may correspond to a closed room within a building ( shed) .

With reference to the schematic embodiment shown in the accompanying Figures , the vertically built cultivation system 1 comprises one or more support frames 3 arranged inside the cultivation container 2 and preferably arranged to rest on a hori zontal plane Z .

The cultivation system 1 also comprises a series of cultivation trays 5 for cultivating the plants which are mounted on the frames 3 . With reference to the accompanying Figures , the cultivation trays 5 are supported by the frames 3 so that they lie on a series of hori zontal cultivation planes Pi ( i comprised between 1 and n) , which are arranged one on top the other . The cultivation planes Pi are arranged at pre-set distances from each other associated with respective levels or heights Li ( i varying between 1 and n) measured along a vertical axis B with respect to the plane Z .

The cultivation trays 5 may have a polygonal shape and are structured to support and cultivate plants . According to a preferred embodiment , the cultivation trays 5 have a roughly rectangular shape and preferably the same dimensions . The cultivation trays 5 can be structured so that they are stably coupled but easily removable/detachable ( separable ) on the frame ( s ) 3 .

In the example shown in Figure 1 , the cultivation trays 5 lying on the same cultivation plane Pi ( i varying between 1 and n) are arranged approximately coplanar to each other one after the other so as to form one or more rows alongside one another ( only two of which are shown in Figure 1 ) which extend in the cultivation container 2 and are parallel to each other and to the reference axis A. Preferably, the cultivation trays 5 of a row are adj acent to the respective cultivation trays 5 of the other row present in the same cultivation plane Pi .

In the example shown, the rows of cultivation trays 5 of a cultivation plane Pi are arranged below and/or above relative rows of cultivation trays lying in the other cultivation planes Pi so that they are vertically aligned and thus form relative vertical columns of rows of cultivation trays 5 .

It should be noted that Figures 1 and 2 and the following discussion represent , solely for the purpose of increasing the understanding of the present invention without , however, limiting its scope , two vertical columns formed by two rows of cultivation trays 5 , wherein the two columns are vertical and adj acent to each other and extend along the plane Z parallel to the reference axis A. However, it is understood that the cultivation system 1 according to the present invention is not limited to two columns of rows of cultivation trays 5 but it may comprise a plurality of columns . It is further understood that the number of cultivation trays 5 in each row and/or the number of rows of cultivation trays 5 that are present on each cultivation plane Pi , and/or the number of columns of trays and/or the number of cultivation planes Pi , may be varied according to the dimensional and/or production characteristics of the cultivation system 1 .

With reference to Figure 1 , the cultivation system 1 further comprises an air-conditioning system 6 ( or conditioning system) which is configured to condition the air and feed it in the cultivation container 2 .

The conditioning system 6 comprises a conditioning apparatus 20 designed to generate/provide a flow of conditioned air, i . e . a flow of air FA wherein at least the temperature and humidity are automatically controlled based on the cultivation process implemented by the cultivation system 1 .

The conditioning system 6 further comprises , one or more air distribution ducts 9 ( only one of which is shown in the accompanying figures ) that are arranged inside the cultivation container 2 , and at least one delivery duct 7 that connects the conditioning apparatus 20 to one or more air distribution ducts 9 .

With reference to the accompanying figures , the air distribution duct 9 is preferably made of a metallic material (metal sheet ) and extends parallel to the axis A. The air distribution duct 9 has a box shape and has an approximately rectangular vertically elongated section transversal to the axis A.

The air distribution duct 9 is preferably formed by an internally hollow body which is parallelepiped in shape and vertically elongated . In the example shown, the air distribution duct 9 has two preferably flat side air di f fusion walls 10 lying on respective approximately vertical planes spaced apart and parallel to each other and to the axis A. The air distribution duct 9 further has a flat hori zontal lower wall 11 orthogonal to the vertical walls 10 and parallel to the axis A, a flat upper wall 12 hori zontal parallel to the lower wall 11 , and two opposite flat vertical side walls 13 orthogonal to the axis A. Preferably, the air distribution duct 9 may be modular, i . e . it may be divided into a plurality of vertical portions designed in use to be connected at the relative flanks or side walls 13 so that they are coplanar with each other . For this purpose , on the side walls 13 , which are intended to be mutually connected, through openings (not shown) can be obtained, preferably vertical sl its designed to allow the conditioned air to pass through the vertical portions that make up the air distribution duct 9 .

According to a preferred embodiment shown in Figures 1 and 2 , the air distribution duct 9 preferably has the lower wall 11 preferably resting on the plane Z , for example by means of feet or plinths .

In the example shown, the air distribution duct 9 is interposed between the two columns of rows of superposed cultivation trays 5 and has the two air di f fusion walls 10 which are adj acent to the respective two columns of rows of cultivation trays 5 .

Through openings 14 are obtained on the two vertical walls 10 and which are arranged so that they are facing respective cultivation trays 5 that are present in the cultivation planes Pi .

The air distribution duct 9 extends vertically so that its upper wall 12 lies on a plane arranged above the cultivation plane Pn on which the cultivation trays placed at the maximum height Ln from the plane Z lie . The height of the air di f fusion walls 10 is conveniently greater than or equal to the maximum height Ln of the cultivation plane Pi ( i=n) .

The air distribution duct 9 extends hori zontally so that the distance between its side walls 13 is greater than or equal to the length of the rows of cultivation trays 5 measured parallel to the axis A. The length of the air distribution wall s 10 measured hori zontally (parallel to the axis A) is conveniently greater than or equal to the length of the rows of cultivation trays 5 .

It is understood that the vertical and/or hori zontal dimensions of the vertical walls 10 may be varied as desired according to one or more of the following characteristics : the internal dimensions of the cultivation container 2 , the number of cultivation planes Pi and/or the number of cultivation trays 5 , the dimensions and shape of the cultivation trays 5 .

According to a preferred embodiment shown in Figures 2 and 3 , the air distribution duct 9 may be connected at the top to the delivery duct 7 to receive the conditioned air and is structured to selectively di f fuse it to the cultivation trays 5 through the through openings 14 . Preferably, the connection can be made by making through openings in the upper wall 12 which communicate directly with the delivery duct 7 . For example , the upper wall 12 may also define the lower hori zontal wall of the delivery duct 7 and be perforated . Preferably the upper wall 12 may comprise a perforated metal sheet .

A technical ef fect obtained thanks to the air distribution duct 9 is to generate air flows FL that directly brush over the cultivation trays 5 and thus the cultivated plants . By conveying the conditioned air directly towards the cultivation trays 5 through the through openings 14 , it is possible to ensure the uni formity of the characteristics of the air ( at least humidity and temperature ) surrounding the cultivation trays 5 . In this way, a uni form temperature and air humidity condition is conveniently achieved in the space surrounding the cultivation trays 5 and the relative plants .

As shown in the example embodiment in Figures 1 , 2 and 3 , the through openings 14 may conveniently comprise slits 15 . Preferably, the slits 15 extend hori zontally on the air di f fusion wall 10 and rectilinear and parallel to each other and to the axis A. Preferably, the slits 15 of an air di f fusion wall 10 may be approximately coplanar to the slits 15 formed on the other air di f fusion wall 10 of the air distribution duct 9 . Preferably, the slits 15 may be formed on the air di f fusion wall 10 so that they are parallel to , and slightly above , a relative cultivation plane Pi on which the cultivation trays 5 are arranged .

Preferably, the slits 15 may be facing approximately one row of cultivation trays 5 of a plane Pi and be arranged below the row of cultivation trays 5 of the immediately above row associated with the plane Pi+ 1 . Preferably, the slits 15 of each row of cultivation trays 5 of a cultivation plane Pi may be arranged parallel to the slits 15 of the other rows of cultivation trays 5 that are present in the other cultivation planes Pi .

Preferably, the slits 15 that are laterally facing a row of cultivation trays 5 arranged on a cultivation plane Pi may be mutually aligned and longitudinally discontinuous between them, i . e . they may be longitudinally separated from one another by a pre-set stretch .

The Applicant has found that the use of rectilinear slits 15 that extend so as to be immediately alongside the cultivation trays 5 of the rows has the technical ef fect of generating approximately hori zontal laminar air flows that brush over the plant products present in the cultivation trays 5 . The hori zontal laminar flows increase the uni formity of air temperature and humidity as their hori zontal expansion covers the entire upper cultivation surface of the cultivation tray 5 .

In the example shown wherein the cultivation trays 5 of the rows lie on the same cultivation plane Pi , the slits 15 of the two air di f fusion walls 10 may be coplanar and are structured to convey the air flows FL in hori zontal directions with mutually opposite directions .

The width of the slits 15 measured vertically may vary based on the air f lowrate/quantity to be provided to the cultivation tray 5 . Preferably, the width of the slits 15 can be between comprised between about 2 mm and about 3 cm . The length of the slits 15 measured hori zontally may vary based on the dimensions of the relative cultivation tray 5 , e . g . Of the length of its side facing the relative air di f fusion wall 10 .

According to a preferred embodiment (not shown) respective shutters or bulkheads can be arranged slidably on the slits 15 . The bulkheads may be coupled to the relative air di f fusion walls 10 so that they are vertically displaced between a closed position, for example a lowered position wherein they fully close the relative slits 15 and an open position wherein they fully open the relative slits 15 . The bulkheads can be further displaced vertically between the closed and open positions so as to adj ust the quantity of air emitted through the slit 15 . The bulkheads may comprise , for example , elongated rectangular laminar plates of metallic or similar material which are designed to slide vertically resting on one face of the relative air distribution wall 10 between the open and closed positions , and vice versa . The displacement of the bulkheads can be selectively controlled manually or additionally or alternatively through respective actuators controlled electronically by an electronic control system 100 .

A technical ef fect of the movable bulkhead is to be able to selectively close the slits 15 in case of absence of the cultivation trays 5 and/or to adj ust the flowrate of air emitted from each slit 15 according to the type of plant cultivated in the adj acent cultivation tray 5 .

In the example shown, the delivery duct 7 compri ses a tubular element which extends hori zontally in the cultivation container 2 preferably along the entire length of the air distribution duct 9 while remaining above it .

The technical ef fect obtained by feeding air in the upper wall 12 of the air distribution duct 9 through the delivery duct 7 is to increase the uni formity of the air distribution pressure in the air distribution duct 9 itsel f and thus to ensure uni formity in the flowrate of the air flows FL exiting the slits 5 .

According to a preferred embodiment , the cultivation trays 5 are coupled in an easily removable ( separable ) manner to the air distribution duct 9 . Preferably, guides or support elements 18 may be arranged on the air di f fusion walls 10 , for example hori zontal plate-like elements , which are stably fixed on the air di f fusion walls 10 and have a proj ecting hori zontal internal portion on which the cultivation tray 5 is arranged to rest .

With reference to the exemplary embodiments shown in Figures 5 and 6 , preferably the support element 18 of a cultivation tray 5 is arranged on the wall 10 immediately below the slit 15 that emits air towards the tray 5 itsel f . Preferably, the distance measured vertically between the support element 18 and the relative adj acent slit 15 may approximate by excess the vertical thickness of the tray 5 measured, for example , on the resting side . In this way, the laminar flow of air generated by the slit 15 is conveniently oriented so as to flood/cross the plant products in the tray 5 itsel f .

In the example shown, the cultivation trays 5 are substantially rectangular in shape and have one side supported by the air distribution duct 9 and the opposite side supported by a vertical column or wall of the frame 3 ( Figure 5 ) .

According to an embodiment (not shown) , the cultivation system 1 may comprise a plurality of air distribution ducts 9 which extend parallel to each other and to the axis A at pre-set distances from each other corresponding approximately to the width of the cultivation trays 5 measured transversely to the axis A. According to this embodiment , the cultivation trays 5 have opposite sides , parallel to the axis A, which are both supported by two air distribution ducts 9 adj acent to each other . For example , the cultivation tray 5 may comprise one side arranged to rest on the support element 18 o f an air di f fusion wall 10 of a distribution duct 9 and the opposite (paral lel ) side arranged to rest on the support element 18 of the air di f fusion wall 10 of another adj acent air distribution duct

9 .

It is further understood that according to a possible embodiment , the air distribution duct 9 may have the through openings 14 on a vertical wall 10 while the other vertical wall 10 may not have the through openings 14 . This embodiment may comprise , for example , only a column of rows of cultivation trays 5 facing the air di f fusion wall 10 with through openings 14 , while the other air di f fusion wall 10 may not have adj acent cultivation trays 5 .

According to a preferred embodiment shown in Figure 1 , the conditioning apparatus 20 is arranged outside the cultivation container 2 , and the delivery duct 7 extends in the cultivation container 2 so that it crosses a vertical wall 2a of the cultivation container 2 so as to extend with an initial stretch at least partially outside the same so as to be connected with an outlet channel of the conditioning apparatus 20 to receive the conditioned air .

The air-conditioning system 6 further comprises at least one suction duct 8 structured to have one or more suction openings 21 arranged in the cultivation container 2 .

In the example shown, the suction duct 8 extends from the cultivation container 2 through the vertical wall 2a to the outside thereof , and is connected to an inlet channel to the conditioning apparatus 20 to provide it with the air to be treated/conditioned . In the example shown, the suction openings 21 are arranged in the cultivation container 2 approximately vertical and coplanar to each other, one on top the other, at di f ferent heights . It is understood that the suction openings 21 may be placed in the cultivation container 2 also in positions other than those shown in the accompanying figures . For example , according to embodiments (not shown) , the suction openings 21 may be placed on the bottom wall of the cultivation container, i . e . at the plane Z , or at a side wall of the same on a plane parallel to the axis A.

With reference to the preferred embodiment shown in Figures 1 , 2 and 3 , the air-conditioning system 6 further comprises a ventilation assembly 40 which is arranged along the delivery duct 7 and is designed to generate an air flow inside the delivery duct 7 itsel f so as to convey it with a certain f lowrate/pressure in the air distribution duct 9 .

With reference to the preferred exemplary embodiment shown in Figures 1 , 2 and 3 , the ventilation assembly 40 comprises a tubular duct connected to the delivery duct 7 and one or more fans ( only one of which is shown in the accompanying figures ) which are arranged in the tubular duct to receive the conditioned air with a certain f lowrate/pressure from an inlet channel and generate , in an outlet channel , a flow of conditioned air having a pre-set f lowrate/pressure greater than the f lowrate/pressure present in the inlet channel .

Preferably, the ventilation assembly 40 may be integrated into the delivery duct 7 so that the fan is arranged downstream of the conditioning apparatus 20 and immediately upstream of the air distribution duct 9 .

Conveniently, a fan may be arranged at an intermediate stretch of the delivery duct 7 between the vertical wall 2a and the side wall 13 of the air distribution duct 9 .

It is understood that the present invention is not limited to arranging a single fan in the intermediate stretch of the delivery duct 7 , but it may alternatively and/or additionally provide for arranging one or more fans in the end stretch of the delivery duct 7 that extends directly above the air distribution duct 9 i . e . adj acent to the upper wall 12 . Preferably the fan can be an intubated axial fan .

The Applicant has found that the use of the ventilation assemblies 40 along relative delivery ducts 7 close to respective air distribution ducts 9 has the technical ef fect of optimising the emission of conditioned air at the cultivation trays 5 and of ensuring the possibility of conveying high air flowrates into the air distribution ducts 9 , which are higher than the flowrates achievable by using the conditioning apparatus 21 alone .

This solves either the technical problem of high power consumption by the conditioning apparatus 20 or the technical problem of the di f ficulty of generating laminar flows FL having high air flowrates . In fact , in order to guarantee the compensation for the pressure drops along the initial stretch of the delivery duct 7 and the achievement of high flowrates in the air distribution duct 9 and through the slits 15 , it is necessary to use a conditioning apparatus 20 having a particularly powerful ventilation system, whose power consumption, however, has a signi ficant impact on the overall power consumption of the same .

The use of the ventilation assembly 40 in the delivery duct 7 close to the air distribution duct 9 therefore makes it possible , on the one hand, to guarantee a certain flowrate in the air distribution ducts 9 and the ability of being able to generate laminar flows FL characterised by high intensities at the plants , and on the other hand, to use a conditioning apparatus 20 with a ventilation system with reduced power so as to signi ficantly reduce the electrical consumption thereof .

The electronic control system 100 is further configured to selectively control the ventilation assemblies 40 arranged in the relative delivery ducts 7 . Preferably, the electronic control system 100 is configured so as to selectively control the rotational speed of the fans of the ventilation assemblies 40 so as to adj ust the air flowrates emitted from the air distribution ducts 9 towards the relative cultivation trays 5 .

The technical ef fect obtained thanks to either the use of the ventilation assemblies 40 in the respective delivery ducts 7 or the selective control of the ventilation assemblies 40 themselves is that the air distribution in the air distribution ducts 9 can be precisely adj usted . In this way, it is possible to adj ust the flowrates of the laminar flows emitted from the slits 15 of the air distribution ducts 9 according to the implemented cultivation procedures and/or the type of plant products cultivated in the cultivation trays 5 adj acent to the air distribution ducts 9 themselves .

With reference to the preferred embodiment shown in Figure 1 , the cultivation system 1 further comprises a feeding system 22 ( schematically shown in Figure 1 ) for feeding a liquid to the cultivation trays 5 . The feeding system 22 may preferably be aeroponic and is structured so as to selectively nebulise the liquid at the cultivation trays 5 . It is understood that the liquid may be based on a mixture of water and nutrients suitable for plants ( fertiliser ) . The feeding system 22 may be structured to feed selectively and in a controlled manner in terms of quantity and/or type and/or instants , by nebulising, the liquid in the cultivation trays 5 .

According to one embodiment shown in Figure 1 , the feeding system 22 may comprise , for each hori zontal row of cultivation trays 5 , at least one delivery pipe or duct 23 by means of which the liquid circulates , and a series of nebulising devices , for example noz zles (not shown) , which are preferably arranged immediately below the cultivation tray 5 of the cultivation plane Pi so as to nebulise the liquid towards the lower surface of the cultivation trays 5 above , and are hydraulically connected to the delivery duct 23 to receive the liquid from a feeding assembly 24 . The feeding assembly 24 is of a known type and will therefore not be further described except to speci fy that it may comprise liquid containment tanks (not shown) and hydraulic pumps (not shown) which suck in the liquid from the tanks and provide it at input to the delivery ducts 23 .

With reference to the preferred embodiment shown in Figure 1 , the cultivation system 1 may further comprise , a liquid suction system 25 , which is structured so as to suck the dispersed nebulised liquid in each of the cultivation trays 5 . According to a preferred embodiment shown in the accompanying figures , the liquid suction system 25 , comprises liquid collection tanks 26 which are arranged immediately below the cultivation trays 5 and are structured to collect and contain the liquid that precipitates during nebulisation . The liquid suction system 25 may further comprise suction ducts , which extend in the liquid collection tanks 26 and are connected to a suction apparatus 27 which in use is designed to suck in the liquid from the liquid collection tanks so as to empty them .

With reference to the preferred embodiment shown in Figure 1 , the cultivation system 1 further preferably comprises , a lighting system 28 designed for the controlled illumination of the plant products in the cultivation trays 5 . Preferably, the cultivation system 28 may comprise a plurality of LEDs , preferably arranged on support bars 29 arranged above the cultivation trays 5 ( Figure 6 ) .

The electronic control system 100 comprises one or more electronic control units configured to supervise the cultivation process implemented by the cultivation system 1 . In particular, the electronic control system 100 is configured so as to control : the conditioning system 6 , the feeding system 22 , the liquid suction system 25 , and the lighting system 28 .

The operating method for the cultivation system 1 essentially comprises the steps of : activating the conditioning apparatus 20 to feed a flow FA of conditioned air to the air distribution duct 10 through the delivery duct 9 so as to di f fuse air flows FL through the slits 15 at the cultivation trays 5 , and to suck in through the suction duct 8 the air FR from the cultivation container 2 .

The method comprises the step of selectively emitting through the through openings 14 the conditioned air present in the air distribution duct in opposite directions to each other towards the cultivation trays present in the two columns of trays .

Preferably, the method further comprises the step of selectively activating the ventilation assemblies 40 so as to increase the flowrate of the conditioned air flow at the relative air distribution ducts 9 .

Preferably, the method further comprises the step of selectively controlling the rotational speed of the fans of the ventilation assemblies 40 so as to adj ust the flowrate of the conditioned air flow at the relative air distribution ducts 9 .

The cultivation system described above is advantageous because it ensures an even distribution of temperature and humidity of the air in all cultivation planes of the system and guarantees the implementation of the same cultivation conditions in all trays .

In addition, the structure of the air distribution walls of each distribution duct advantageously allows to support trays simultaneously with the distribution of air without the need for additional frames . This makes it possible to : optimise the occupation of the space inside the cultivation container, reduce complexity, simpli fy assembly, and reduce the construction costs of the system . The distribution of a plurality of air distribution ducts in the space inside the container further makes it possible to improve the uni formity of the temperature and humidity of the air and avoids implementing repeated inversions of the air flow directions carried out in the systems wherein the air di f fusion takes place by emission of air from one side wall of the container and the suction of air from the opposite side wall of the container .

Finally, it is clear that modi fications and variations may be made to the cultivation system and the operating method described and shown above without departing from the scope of protection of the present invention in accordance with the appended claims .