PT108117A - PLANTATION UNIT FOR EXTEMPORARY INDUCTION AND MANAGEMENT OF THE TIMES OF BIOLOGICAL CYCLES OF PLANTS IN CULTURE, IN A CONTROLLED ENVIRONMENT - Google Patents

Abstract

The present invention is introduced in the field of the cultivation of plants in a greenhouse, whether in the form of a compact substrate without a glass. THIS IS A PLANTATION UNIT FOR THE EXTENSIVE INDUCTION AND MANAGEMENT OF THE TIMES OF BIOLOGICAL CYCLES OF PLANTS IN CULTURE IN A CONTROLLED ENVIRONMENT, IN ORDER TO OBTAIN FASTEST AND EXTEMPORARY GROWTH, FLOUR OR FRUIT, CONSTITUTED BY FERTIRRIGATION TRAY (1), WHERE CIRCULATE NUTRIENT FLUIDS, VEHICULATED BY INLET PIPES / OUTPUTS (5) COVERED BY RUBBER ILHÓS (4); BY CLIMATIZATION BOX (3), WHERE AR, FLUIDS OR ELECTRIC CABLES FOR CLIMATIZATION, VEHICULATED BY INLET / OUTPUT TUBES OR CONNECTION (12); A MULTICELLULAR PLANTING BOX (14), CONTAINING CELLS FOR PLACEMENT OF PLANTS IN PRODUCTION AND HOLES (15) FOR ABSORPTION / DIFFUSION AND DRAINAGE OF NUTRIENT FLUIDS; Comprising a lighting system by LED technology (7), anchoring cover (9), tilting bands (6); PER SCISSORED FILM (16).

Description

DESCRIPTION " Plantation unit for induction and extemporaneous management of biological cycle times of plants in culture in controlled environment "

TECHNICAL FIELD OF THE INVENTION The present invention is in the general field of horticulture, in particular it relates to a planting unit suitable for the cultivation of greenhouse plants, either in pot or in a compact substrate which does not require potting. The Planting Unit is specifically designed to promote the conditions and ecophysiological factors required for induction and extemporaneous management of the biological cycle times of plants in a controlled environment.

That is, the present invention is suitable for satisfying nutrition heating and / or cooling, as well as photoperiods, of luminosity and shading, specific for each biological cycle of plants in culture, for the induction and management of biological cycle times of the plants, in order to obtain faster and extemporaneous growths, blooms or fruitings.

STATE OF THE TECHNIQUE

In the field of greenhouse cultivation, either in pots or in compact substrates without potting, the factors that normally influence decision making for mass production are productivity, competitiveness and environmental sustainability.

In relation to productivity, the factors of production that are most relevant to costs and productivity levels are the operational times of production, energy costs, especially those related to air conditioning, as well as costs of fertilizers and phytosanitary products.

At present, the common practice is based on the more or less optimized control of the eco-physiological factors required by the contemporaneity of the biological cycles of the plants, the climatization of the total volumetric capacities of the greenhouses, and the fertilization, more or less optimized, by way of sprinkling or flood, a practice that does not allow induction and manage the times of extemporaneous biological cycles and causes considerable waste of energy, water and fertilizers.

As far as competitiveness is concerned, the most important competitive factors, with the exception of promotion and marketing, are prices, which usually derive from productivity and transport gains, plant quality and the extemporaneous supply. To date, most producers use techniques and production methods which do not allow production times and costs to be reduced on the basis of untimely production and, consequently, offer off-season and more competitive prices.

Regarding environmental sustainability - nowadays a relevant factor in the purchase or consumption decision-making - the most important factors in production are the consumption of energy from non-renewable sources, water consumption and the consumption of agrochemicals toxic to the environment.

Today, despite the increased demand for more efficient and environmentally friendly energies and better control of water and toxic agrochemicals, whether fertilizers, plant protection products and others, there is still a huge waste of energy, water, fertilizers and phytosanitary products resulting from massive practices, discoloring the optimized and localized consumption, prophylaxis, prevention and combat circumscribed to pathogens. US 5419080 A discloses a multicellular tray for plant growing, especially useful for plant growth, which has been transplanted with cells of relatively small containers, until the plants are ready to be transplanted in a garden environment.

This document further relates to the assembly of a tray, comprising a multicellular tray, a water reservoir, a capillary conveyor for delivering water through the capillary action from the reservoir through holes in the bottom floor of cells of the tray for transplanting the mixture contained in the cells, and means for supporting the capillary mat and tray in the reservoir.

Another document - US2014283452 - describes closed modular structures, optimized for the hydroponic cultivation of green plants under artificial light.

This document provides that modular structures may include an insulation coating. US2014259908 (A1) relates generally to hydroponic cultivation and, more particularly, to systems and method of improving the design of modular hydroponic systems. The document in question relates to a system comprising a reservoir for the nutrient solution and at least one plant growth area, an optional additional volume for germination of seedlings which can be promoted simultaneously with the growth of plants in a plant vegetative state, in at least one plant growth area, a wall to allow access to the unimpeded interior between the remaining walls to an inner bottom wall of the growth module, an optional light screening screen, a manifold distribution manifold optional fluid in each growth module.

This document states that the invention optionally provides an environmental control system, adapted to induce ventilation within the culture chamber.

This document further states that the invention optionally provides an apparatus for heating and cooling the growth module and nutrient solution as well as a means for adjusting the transparency of the top surface of the growth module.

In the present state of the art there is no production unit which is defined as a specific unit for induction and extemporaneous management of the times of the biological cycles of plants and which, for this reason, is susceptible to provide: - Applicability in the induction and extemporaneous management of times of the biological cycles of plants in culture; - Intermediate tray to carry out air conditioning (heating or cooling) restricted to the tray volume, starting from the base of the substrate; - Cover surface with shading film specific to the photoperiods required by the biological cycles of the plants in culture; - An interconnection / connection system of the various systems generated between units;

Integrated lighting, specifies the biological cycles of plants in production;

DESCRIPTION OF THE DRAWINGS The present invention is hereinafter described in detail, without limitation and by way of example, by means of a preferred embodiment thereof, shown in the accompanying drawings, in which: Figure 1 represents a perspective view of the induction unit and extemporaneous management of the times of the biological cycles of vegetative plants, in which the reference numbers represent: 1- Fertigation tray; 2- Area of fixation of all the trays components of the induction unit and extemporaneous management of the times of the biological cycles of vegetative plants; 4- Rubber eyelet for fitting and sealing of inlet / outlet pipes or fertigation system connection; 5- Inlet / outlet tube or connection of the fertigation system; 6- Covering tip covers; 7- Lighting System by LED technology specifies each biological cycle of the plant in culture; 8- Fixed walls of the cover; 9- Ventilation cover; 10- Plant in culture; 11- Hinge for the roofing tilting bands; 12- Inlet / outlet pipes or connection of the air or fluids of the air conditioning system; 14-Multicellular Plantation Tray; Figure 2 shows a cross-sectional view through the plane of symmetry of the unit for induction and extemporaneous management of biological cycles of plants with all components, in which the reference numerals represent: 1- Fertigation tray; 2- Area of fixation of all the trays components of the induction unit and extemporaneous management of the times of the biological cycles of vegetative plants; 3- Climatization tray 4- Rubber eyelet for fitting and sealing of inlet / outlet pipes or connection of the fertigation system; 5- Inlet / outlet tube or connection of the fertigation system; 6- Covering tip covers; 7- Lighting System by LED technology specifies each biological cycle of the plant in culture; 8- Fixed walls of the cover; 9- Ventilation cover; 10- Plant in culture; 11- Hinge for the roofing tilting bands; 12- Inlet / outlet pipes or connection of the air or fluids of the air conditioning system; 13- Substrate 14- Multicellular Plantation Tray; Figure 3 represents a perspective of the fertigation tray, in which the reference numbers represent: 1-Fertigation tray; 4- Rubber eyelet for fitting and sealing of inlet / outlet pipes or fertigation system connection; 5- Inlet / outlet tube or connection of the fertigation system; Figure 4 represents a perspective of the connection of two fertigation trays, in which the reference numbers represent: 1-Fertigation tray; 4- Rubber eyelet for fitting and sealing of inlet / outlet pipes or fertigation system connection; 5- Inlet / outlet tube or connection of the fertigation system; Figure 5 shows a perspective view of the air-conditioning tray, in which the reference numerals represent: 3-Air-conditioning tray; 12-Inlet / outlet pipes or connection of air or fluids of the air-conditioning system; Figure 6 shows a perspective view of the assembly of the fertigation tray with the air-conditioning tray, in which the reference numbers represent: 1-Fertigation tray; 3- Climate control tray; 4- Rubber eyelet for fitting and sealing of inlet / outlet pipes or fertigation system connection; 5- Inlet / outlet tube or connection of the fertigation system; 12-Inlet / outlet pipes or connection of air or fluids of the air-conditioning system; Figure 7 shows a perspective view of the cross-sectional detail by plane of longitudinal symmetry in the zone of connection of two induction units and extemporaneous management of the times of the biological cycles of plants with the trays of fertigation and air conditioning, in which the reference numbers represent: 1- Fertigation tray; 2- Area of fixation of all the trays components of the induction unit and extemporaneous management of the times of the biological cycles of vegetative plants; 3- Climate control tray; 4- Rubber eyelet for fitting and sealing of inlet / outlet pipes or fertigation system connection; 5- Inlet / outlet tube or connection of the fertigation system; 12-Inlet / outlet pipes or connection of air or fluids of the air-conditioning system; Figure 8 shows a perspective view of the multicellular plantation tray, in which the reference numerals represent: 14-Multicellular Plantation Tray; Figure 9 shows a cross-sectional view through the plane of longitudinal symmetry of the multicellular planter tray, in which the reference numerals represent: 2. Area of fixation of all the trays component of the induction unit and extemporaneous management of the biological cycle times of the vegetative plants; 14- Multicellular Plantation Tray; 15- 0trials of the multicellular plantation tray to promote fertigation and drainage; Figure 10 shows a cross-sectional view of the longitudinal symmetry plane of the fertigation tray, the air conditioning tray and multicellular plantation tray, in which the reference numbers represent: 1- Fertigation tray; 2- Area of fixation of all the trays components of the induction unit and extemporaneous management of the times of the biological cycles of vegetative plants; 3- Climate control tray; 4- Rubber eyelet for fitting and sealing of inlet / outlet pipes or fertigation system connection; 5- Inlet / outlet tube or connection of the fertigation system; 12-Inlet / outlet pipes or connection of air or fluids of the air-conditioning system; 14- Multicellular Plantation Tray; 15- 0trials of the multicellular plantation tray to promote fertigation and drainage; Figure 11 shows a cross-sectional view of the plane of longitudinal symmetry of the assembly between two Units with the fertirrigation, air conditioning and multicellular plantation trays, in which the reference numbers represent: 1- Fertigation tray; 2- Area of fixation of all the trays components of the induction unit and extemporaneous management of the times of the biological cycles of vegetative plants; 3- Climate control tray; 4- Rubber eyelet for fitting and sealing of inlet / outlet pipes or fertigation system connection; 5- Inlet / outlet tube or connection of the fertigation system; 12-Inlet / outlet pipes or connection of air or fluids of the air-conditioning system; 14-Multicellular Plantation Tray; Figure 12 shows a detailed cross-sectional view of the zone of connection between the three trays, in which the reference numerals represent: 1-Fertigation tray; 3-Climate control tray; 14-Multicellular Plantation Tray; Figure 13 shows the cross-sectional detail of the connection between the fertirrigation, air-conditioning and multicellular plantation trays in which the reference numerals represent: 1 - Fertigation tray; 2- Area of fixation of all the trays components of the induction unit and extemporaneous management of the times of the biological cycles of vegetative plants; 3- Climate control tray; 4- Rubber eyelet for fitting and sealing of inlet / outlet pipes or fertigation system connection; 5- Inlet / outlet tube or connection of the fertigation system; 12-Inlet / outlet pipes or connection of air or fluids of the air-conditioning system; 14-Multicellular Plantation Tray; Figure 14 shows a perspective view of two sets of induction tray / units and extemporaneous management of the times of the biological cycles of plants with all the components, in which the reference numerals represent: 1- Fertigation tray; 2- Area of fixation of all the trays components of the induction unit and extemporaneous management of the times of the biological cycles of vegetative plants; 3 - Air conditioning tray 4 - Rubber eyelet for fitting and sealing of inlet / outlet pipes or connection of the fertigation system; 5- Inlet / outlet tube or connection of the fertigation system; 6- Covering tip covers; 7- Lighting System by LED technology specifies each biological cycle of the plant in culture; 8- Fixed walls of the cover; 9- Ventilation cover; 11- Hinge for the roofing tilting bands; 12- Inlet / outlet pipes or connection of the air or fluids of the air conditioning system; 13- Substrate 14- Multicellular Plantation Tray; Figure 15 shows a perspective unit of induction and extemporaneous management of biological cycle times of plants, with all components, in which the reference numbers represent: 16 - Shading film

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a tray unit for promoting the conditions and ecophysiological factors required in the process of induction and extemporaneous management of biological plant cycle times in a controlled environment, consisting of a fertigation tray (1) , positioned at the base of the system, serving as support for the subsequent trays. It consists of lateral walls and a bottom, defined as a reservoir, where the nutrient fluids specific to the biological cycle of the crop plant are circulated (10), which are introduced and drained through holes for introducing inlet / outlet pipes or connection (5) which are buffered by rubber eyelets (4), so as to effect the circulation of the nutrition fluids and their drainage and cleaning of said fertigation tray (1); (3), which is composed of side walls and a base that circulates between the insertions of the plantation tray (14) positioned horizontally with respect to the said fertigation tray (1), consisting of open molded cells in the part (14), and is supported in the fertigation tray (1) by shaped perimeter flaps, the side walls on each of the two opposite sides containing holes, for introducing inlet pipes (12) which pass through the fertigation tray (1) in order to allow the total inlet and outlet of fluids or thermodiffus air or of electrical resistors which may also be used for this purpose, by means of a multicellular tray (14), which is comprised of side walls and a base provided with molded cells / inserts, closed at the bottom, which contain holes (15) for absorption / diffusion and drainage of the nutrient fluids, and open at the top, where the crop plants (10) are placed, which fit into said climate control tray (3) and which is supported by shaped perimeter flaps in the remaining component trays , fertigation (1) air conditioning (3); by means of a covering cover which covers and is supported by perimeter flaps formed in said multicellular plantation climate control (1), which comprises a lighting system by LED technology (7), suitable for the induced biological cycle, and is composed of vertical fixed walls (8) on the tops, in one of which there is an aerating cap (9), to promote air circulation according to plant requirements and good cultural practices, and (6), which have a hinge (11) for allowing, opening and closing in order to place and remove the crop plants (10); (8) and tilting bands (6) of the cover top, with the necessary opacity to generate the appropriate shading to the photoperiods required for the induction of the biological cycles of the crop plant (10).

Said air-conditioning tray (3) and multicellular plantation tray (14) comprise the following characteristics: the length, width or inner diameter of the cells of said climate control tray (3) corresponds to the length, width or outer diameter of the cells of said multicellular planter tray (14), so as to allow a matching engagement between cells to generate better thermodiffusion; the depth of the molded cells of said air conditioning tray 3 is preferably less than the depth of the closed cells of the multicellular planter tray 14 so as to allow a good diffusion capacity of the nutrition fluid and a perfectly coincident interposition between the said trays; The spacings between the cells of said climate control tray (3) and said multicellular plantation tray (14) must correspond to the development requirements of the crop plant (10).

In turn, said irrigation tray (1), climate control tray (3), multicellular planter tray (14), cover element have shaped dimensions and perimeter shapes, so as to allow a matching fit between them, through of the area of fixation of said trays (2), defining its set as an induction unit and extemporaneous management of the biological cycle times of plants in a controlled environment. The unit of induction and extemporaneous management of biological plant cycle times in a controlled environment is characterized in that said fertigation tray (1) may have one or more preferably four holes, two on each of two opposite sides of the side walls for placement of inlet / outlet pipes or connection of the fertigation system (5) through which the nutrient fluids circulate. The unit for the induction and extemporaneous management of biological plant cycle times in a controlled environment is characterized in that said climate control tray (3) can have one or more holes, preferably 4, connected to inlet / outlet pipes or connection of the system (12) through which the air, fluids or electric cables responsible for the air conditioning circulates. The unit for the induction and extemporaneous management of the times of the biological cycles of plants in a controlled environment is characterized in that said multicellular plantation tray (14) can contain in the lower part of the molded closed cells an indefinite number of holes (15) to allow the absorption / diffusion and drainage of nutrient fluids. The unit for the induction and extemporaneous management of the biological cycle times of plants in a controlled environment is characterized in that said fertigation tray (1), climate control tray (3), multicellular planter tray (14), cover element, have shapes and perimeter shapes, so as to allow a matching fit between them. The unit for the induction and extemporaneous management of the times of the biological cycles of plants in a controlled environment is characterized in that said fertigation tray (1) can be made in any material having the same or different characteristics as long as it allows the function. The unit for the induction and extemporaneous management of the biological cycle times of plants in a controlled environment is characterized in that said climate control tray (3) can be made of any material with the same or different characteristics that allows thermal diffusion and of color preferably transparent, but other colors may be used depending on the photoperiod requirements of the plants in culture. The unit for the induction and extemporaneous management of biological cycle times of plants in a controlled environment is characterized in that said climate control tray (3) and said multicellular plantation tray (14) are susceptible to become one only, preferably in case of air conditioning or fluids. The unit of induction and extemporaneous management of the biological cycle times of plants in controlled environment is characterized by being couplable, in line and level, successively, with other units, connected by pipelines that promote the distribution of the fertirrigation and air conditioning. The unit of induction and extemporaneous management of the biological cycle times of plants in a controlled environment is characterized in that said covering element can be compact and removable, or bicomposed by fixed tops and tilting bands or even by only two tilting bands, being in all the cases preferably supported on a lower frame with flaps of dimensions and perimeter shapes conforming to the dimensions and shapes of the preceding trays that make up the unit. The unit of induction and extemporaneous management of the biological cycle times of plants in a controlled environment is characterized in that the height of the cover element can be varied according to the heights corresponding to the maximum growth of the plants in cultivation, increased of 20 to 30% for optimize air circulation and lighting. The unit of induction and extemporaneous management of biological cycle times of plants in a controlled environment is characterized in that the rapid opening and closing system of the tilting bands can be a shaft or other element for the same purpose. The unit of induction and extemporaneous management of biological cycle times of plants in controlled environment is characterized in that the irradiation and the luminous spectrum of the lighting device can be varied according to the needs of the plants and their biological cycles. The unit of induction and extemporaneous management of biological plant cycle times in a controlled environment is characterized in that it can further comprise a plurality of apertures in the cover member for a variety of purposes.

This unit is specifically designed to promote the conditions and ecophysiological factors required for induction and extemporaneous management of biological plant cycle times in a controlled environment.

That is, the present invention is suitable for satisfying nutrition heating and / or cooling, as well as photoperiods of luminosity and shading, specific for each biological cycle of the plants in culture, with a view to the induction and temporal management of these cycles, thereby achieving faster and more rapid growth, flowering or fruiting.

Accordingly, the invention provides a decisive improvement over the prior art, promoting increased productivity gains and competitiveness through a unit enabling production processes based on the induction and extemporaneous management of the biological cycle times of plants in controlled environment of in order to reduce times and consequently operational costs of production and allow extemporaneously to offer the plants in the market at competitively more competitive prices, while still promoting substantial gains in environmental sustainability, since the present invention allows the substantial reduction of water consumption through nutrition localized and optimized as well as allows a substantial reduction of energy consumption either in air conditioning through the circumscription of the same to the confined spaces of the unit (are attached to the volumetric capacity of the unit), or in lighting that is circumscribed to the area of production of the plants, as well as, contributes to a lower consumption of pesticides, are fertilizers through balanced and direct nutrition of the substrates and prolonged retention, are phytosanitary by way of prophylaxis, prevention, dissemination and fight against diseases by from their circumscription to the Units where they occur, avoiding contaminations and dispensing with global treatments.

This invention has application in the industrial production in horticulture, namely in the production of plants with induction and extemporaneous management of biological cycle times in a controlled environment.

Santo Tirso, December 23, 2014.

Claims (16)

A planting unit for the induction and extemporaneous management of biological cycle times of plants in a controlled environment, characterized in that it essentially consists of: - A fertigation tray (1), positioned at the base of the unit, serving as support for subsequent trays, being composed of side walls and a bottom, defining as a reservoir, where the nutrient fluids specific to the biological cycle of the crop plant (10) circulate, which are introduced and drained through inlet / outlet tubes or (5) buffered by rubber grommets (4), to effect circulation, drainage and cleaning of nutrient fluids; An air-conditioning tray (3), which is composed of side walls and a base that circulates between the insertions of the plantation tray (14) and is positioned horizontally with respect to the said fertigation tray (1), consisting of open molded cells in the (14), and which is supported by shaped perimeter flaps in the fertigation tray (1), the sidewalls on each of the two opposite sides of which contain holes , wherein inlet / outlet or connection pipes (12) are connected through the fertigation tray (1) in order to allow the total inlet and outlet of thermodiffustive fluids or air or of electrical resistors which may also be used for this purpose; - A multi-celled plantation tray (14), which is composed of side walls and base with closed closed cells / inserts in the lower part, which contain holes (15) for absorption / diffusion and drainage of nutrient fluids, and open , in the upper part, where the crop plants (10) are placed, which fit into said climate control tray (3) and which is supported by perimeter flaps conforming to the remaining component trays, fertigation (1) and air conditioning (3). ); Said air-conditioning tray (3) and multicellular plantation tray (14) comprise the following characteristics: a) The length, width, outer diameter and inner spacing of the cells of said climate control tray (3) corresponds to the length, width or diameter of the cells of said multicellular planing tray (14), so as to allow a matching engagement between cells to generate better thermodiffusion; b) The depth of the molded cells of said climate control tray 3 is preferably less than the depth of the closed cells of the multicellular planter tray 14 so as to allow a good diffusion capacity of the nutrition fluid and a perfectly coincident interposition between said trays; c) The spacings between the cells of said climate control tray 3 and said multicellular plantation tray 14 should correspond to the development requirements of the crop plant 10; A cover cover which covers and is supported by perimeter flaps conforming to those of said multi-cellular plantation climate control (1), which comprises a lighting system by LED technology (7) , suitable for the induced biological cycle, consisting of fixed and vertical walls (8) on the tops in which an aeration cap (9) is provided, to promote air circulation according to plant requirements and good cultural practices, and by tilting bands (6), which have a hinge (11) for allowing, opening and closing in order to place and remove plants in culture (10); - a melt film adhering to said fixed walls (8) and tilting bands (6) of the cover plate, in order to generate the necessary shading according to the photoperiods required for the induction of the biological cycles of the crop plant (10); Said fertigation tray (1), air conditioning tray (3), multicellular planter tray (14), cover element have shaped perimeter shapes and shapes, so as to allow a coincident engagement therebetween, through the attachment area of the (2), defining itself as a unit of induction and extemporaneous management of the biological cycle times of plants in a controlled environment. A planting unit for the induction and extemporaneous management of biological cycle times of cultured plants in a controlled environment according to claim 1 is characterized in that said fertigation tray (1) can have one or more holes, preferably 4, two on each of two opposite sides of the side walls, for placing inlet / outlet tubes or connection of the fertigation system (5) through which the nutrient fluids circulate. A planting unit for the induction and extemporaneous management of the biological cycle times of cultured plants in a controlled environment according to claim 1 is characterized in that said climate control tray (3) can have one or more holes, preferably 4, connected to the inlet / outlet pipes or connection of the air conditioning system (12) through which the air, fluids or electric cables responsible for the air conditioning circulate. A planting unit for the induction and extemporaneous management of the biological cycle times of cultured plants in a controlled environment according to claim 1 is characterized in that said multicellular plantation tray (14) can contain in the lower part of the closed molded cells an undefined number of orifices (15) for absorption / diffusion and drainage of nutrient fluids. A planting unit for the induction and extemporaneous management of biological cycle times of cultured plants in a controlled environment according to claim 1 is characterized in that said fertigation tray (1), climate control tray (3), tray multicellular plantation (14), top cover, having shaped perimeter shapes and shapes, so as to allow a mating fit between them. A planting unit for the induction and extemporaneous management of biological plant cycle times in a controlled environment according to claim 1 is characterized in that said fertigation tray (1) can be made in any material having the same characteristics or many different. A planting unit for the induction and extemporaneous management of biological plant cycle times in a controlled environment according to claim 1 is characterized in that said climate control tray (3) can be made in any material having the same or similar characteristics. different color permitting diffusion of heat, in a preferably transparent color, but other colors may be used depending on the photoperiod requirements of the plants in culture. A planting unit for the induction and extemporaneous management of biological cycle times of cultured plants in a controlled environment according to claim 1 is characterized in that said climate control tray (3) and said multicellular plantation tray (14) , are likely to become one, preferably, in the case of air or fluid conditioning. A planting unit for the induction and extemporaneous management of biological cycle times of plants in a controlled environment in accordance with claim 1 is characterized in that it is successively couplable, in line and level, with other adjacent, by pipes that promote the distribution of the fertigation and air conditioning, if it is made by thermoconductive solutions or air, and lighting or heating cables if it is made by electric cables, to form industrial production units. A planting unit for the induction and extemporaneous management of biological cycle times of plants in culture in a controlled environment according to claim 1, characterized in that said cover element can be compact and removable, or bicomposed by fixed tops and tilting bands , in all cases being preferentially sustained a lower frame with flaps of dimensions and shapes of the previous trays that make up the unit. Planting unit for induction and extemporaneous management of biological cycle times of plants in culture in a controlled environment according to claim 1 characterized in that the height of the cover element can be varied according to the heights corresponding to the maximum growth of the plants plants in culture, plus 20 to 30% to optimize air circulation and lighting. Planting unit for induction and extemporaneous management of biological cycle times of plants in culture in a controlled environment according to claim 1 characterized in that the opening and closing system of the tilting bands can be a shaft or other element with the same goal. A planting unit for the induction and extemporaneous management of biological cycle times of plants in culture in a controlled environment according to claim 1 characterized in that the irradiation and the spectrum of the lighting component can be varied according to the needs of the plants and their respective biological cycles. A planting unit for the induction and extemporaneous management of biological cycle times of plants in culture in a controlled environment according to claim 1 characterized in that the inner depth of the open molded cells of said climate control tray (3) can be varied more preferably less than the depth of the closed cells of the multicellular planter tray (14), so as to allow a good diffusion capacity of the nutrition fluid and a perfectly coincident interposition between said trays. A planting unit for the induction and extemporaneous management of biological plant cycle times in a controlled environment according to claim 1, characterized in that it further comprises a plurality of openings defined in the cover element. A planting unit for the induction and extemporaneous management of biological cycle times of cultured plants in a controlled environment according to the previous claims characterized in that the tray system can use either a vessel or a compact substrate which does not require a vessel or even without substrate. Santo Tirso, December 23, 2014.