CA2544954A1 - Soilless cultivation system - Google Patents

Abstract

A device allowing the growth of plants above ground comprising (i) a water supply, (ii) a timer coupled to a solenoid valve controlling said supply, which timer makes it possible to control the opening of said solenoid valve, and therefore of the supply circuit, for short periods, (iii) at least one porous or perforated supply pipe, (iv) at least one absorbent material constituting a support for the growth of plants in contact with said supply pipe, which absorbent material exhibits good water-holding capacity, and (v) at least one support for said supply pipe and said absorbent material; the use of such a device in an out-of-soil cultivation method and in an out-of-soil cultivation method using such a device.

Description

OFF-GROW CULTURE DEVICE

The present invention relates to a culture device above ground, the use of such a device in a method of above-ground cultivation and an above-ground cultivation process implement such a device.

For both environmental and aesthetic issues, the current urban planning policy integrates more and more vegetation. However, such a integration is not without technical difficulty. He has have been developed devices consisting of supports on which plants develop and also applying well on the walls of buildings, said devices are then in the form of panels, only in spaces opened, said devices then taking the form of lianas.

If such devices are simple in appearance, the choice of materials, plants and / or watering is not no less complex in order to obtain a device that is all both stable and durable and does not require simultaneous excessive maintenance.

Currently, one of the major problems of these devices arises more specifically from watering which must be sufficient to allow the plants to flourish supports, without causing loss of water excessive. Beyond the only problems of saving water, the constraint of an urban installation requires a device which is not messy for the near environment. So, the totality of the existing devices to date generate heavy water losses on the surrounding surfaces, walls as well as flower beds.

Faced with this problem, devices integrating means of recovery in the form of gutters or bins have been developed. However, such means of recovery, if they avoid significant water losses to

2 the surrounding surfaces, do not avoid a strong loss of water by evaporation and above all prove to be unsuitable for suspended devices in particular.

As a result, there is still a current important need to benefit from devices that allow at the same time an optimal development of the plants they support and whose water loss is minimal.

Unexpectedly, the inventor has shown that he was possible to obtain a device that combines simultaneously optimal growth of the plants it supports and a minimal water loss by feeding intermittent by short periods.

Accordingly, a first object of the invention corresponds to a device allowing the growth of plants above ground comprising:

i) a water supply;

ii) a timer coupled to a solenoid valve said power supply, which timer allows command the opening said solenoid valve, and therefore the feeding circuit, for short periods;
iii) at least one porous or perforated feed pipe;
iv) at least one absorbent material constituting a support for growing plants in contact with said pipe feedstock, which absorbent material has a good water retention capacity and good dissemination capacity; and v) at least one support for said feed pipe and said absorbent material.

Advantageously, said water supply benefits from a pressure between 0.1 and 10 bar, preferably between 0.3 and 5 bars. Depending on the installation site of the device according to the invention, said feed can take, for

3 for example, the shape of a running water supply coupled or not to a pressure reducer or a water tank coupled to a pump.

Many timers and solenoid valves are known to the skilled person and the latter will be able to identify without difficulty timers and solenoid valves suitable for the device according to the invention.

By short periods of opening of the solenoid valve, means an opening of the supply circuit during 1 second to 5 minutes every minute to every 24 hours, preferably for 1 to 120 seconds every 2 to 120 minutes and particularly preferably during 5 to 60 minutes seconds every 5 to 60 minutes.

These times for the short open periods of the solenoid valve agree for a supply circuit that stays full between each watering period. In case the feed circuit would be drained between each period of watering, the opening time of the supply circuit will also include a filling time of the circuit feeding time, which time will depend on the size of the feeding circuit and can be determined simply by the skilled person.

The porous or perforated feed pipe can take the shape of a metal or plastic pipe, preferably made of plastic. Such pipes made of materials plastics are well known to those skilled in the art and the latter will be able to easily identify the pipes with the most appropriate stiffness or elasticity characteristics depending on the type of above-ground crop envisaged, in particular suspended or vertical.

Advantageously, the porous or perforated feed pipe take the form of a drip pipe, preferably a hose with drippers at regular intervals. Very many drippers have been described in the prior art and

4 the skilled person can also easily identify drippers able to be used in the device according to the invention. Positioning at regular intervals of said drippers on the supply pipe will be a function of dimensions of the device according to the invention. For exemple, said regular interval corresponds to a spacing understood between 5 cm and 2m between each dripper, preferably between 10 cm and lm, for example between 10 and 75 cm or between 15 and 50 cm, and particularly preferably between 15 and 35 cm.

By absorbent material having a good ability to water retention means a material with potential water retention greater than 50%, preferably one water retention potential greater than 60% and so particularly preferred is a water retention potential greater than 65%. The water retention value of a material absorbent can be calculated by well known techniques of the skilled person.

By way of example, mention may be made of the measurement method of water retention potential described in application EP-A-1 038 433. In this method, it is a question of measuring the capacity of water retention of an initially saturated substrate, under a depression of 10 cm of water. The test consists of measuring the loss continuous mass (dynamic) of a sample initially saturated (forced immersion for a minute minimum) in water (clean city water, temperature = 10 to 25 C) subjected to a depression (suction) of 10 cm of water. The measurement is stopped at 10 minutes after which, under the conditions of the test and with its measuring device, the measurement accurately reflects the fluid retention obtained in steady state (balanced). The fluid retention is then given under the form of a percentage by volume of water contained in the sample.

In addition to the retention capacity, the absorbent material must have a good diffusion capacity. By absorbent material having a good diffusion capacity, we mean a absorbent material having good spreadability, which absorbent material has a porous structure.
Advantageously, the absorbent material exhibiting good diffusion capacity has a porous structure whose pore sizes are between 1 m and 1 mm,

Preferably between 5 and 100 m, for example between 10 and 50 m, and particularly preferably between 15 and 30 m.
Such absorbent materials are well known to the human example, foams or mineral felts, in particular based on rockwool or glass, including plants based on cotton and / or synthetic, polyurethane, preferably the foams or vegetable felts and particularly preferably foams or felts made of cotton, jute, hemp, flax, coconut, sisal, sphagnum. Preferably, and when the absorbent material is of vegetable origin, this one is treated so as to be rotproof. Such foams or felts advantageously have creped structures, as described in particular in EP-A-310 501, EP-A-388 287 or WO-A-95/04453.

Said absorbent material serves as a support for the development roots. Accordingly, said absorbent material preferably have a low phytotoxicity.

Advantageously, the absorbent material has a thickness between 0.2 and 10 cm, preferably between 0.5 and 5 cm, particularly preferably between 1 and 3 cm.

The absorbent material may take the form of one or several layers, including two or three layers superimposed, preferably two layers. In the case of diapers superimposed, said superposed layers may be made of material materials with potential distinct fluid retention.

Advantageously, the first layer of absorbent material in contact with the supply pipe presents the

6 most water retention and diffusion potential important.

Advantageously again, the contact between the pipe supply and the absorbent material (s) allows the passage of water from the supply pipe to the material (s) absorbent (s) by capillarity.

According to a preferred embodiment, the device according to the invention comprises a film or a micro-perforated tube surrounding the supply pipe and placed between said pipe feeding and the absorbent material.

Unexpectedly, the inventor was able to highlight that such a film or such a micro-perforated tube allow to significantly improve the distribution of water in the absorbent material and thus limit the problems of loss associated with an inhomogeneous distribution of water in the absorbent material. Such a film or such a micro-perforated tube also allow to overcome a little more the risk of obstruction roots inside the drippers.

Advantageously, said micro-perforated film or tube is in plastic material, has a thickness of between 10 m and 2 millimeters and has perforations of a diameter of order of 10 m to 30 m and 1 to 500 perforations per cm 2, preferably in the proportion of 1 to 50 perforations per cm 2.

According to a particular embodiment, the device according to the invention comprises an insulating material positioned on the absorbent material. Said insulating material makes it possible protect the absorbent material and the roots of the plants developing the sun and thus protecting said roots while limiting the evaporation at the level of said material absorbent.

Advantageously, the insulating material is permeable to air and allows the development of plants. Such materials insulators are well known to those skilled in the art. As Examples of insulating materials include materials

7 insulators of plant origin, such as the coconut mat or sisal, or synthetic insulating materials such as canvases made from polypropylene or polyethylene, especially mulch or agrotextile cloths. Preferably, and when the insulating material e.st of plant origin, it is treated so to be rot-proof.

In the case where the insulating material is of synthetic type, the latter may incorporate ornamental motifs, particularly colors, to improve the aesthetic integration of the device according to the invention in the urban landscape or the indoor environment.

The thickness of the insulating material is a function of the composition of the latter. Thus, an insulating material synthetic will have a thickness of a few millimeters (from 1 to 5 mm), while an insulating material of plant origin will have a greater thickness (from 5 to 30 mm).
Advantageously, the insulating material has a thickness between 1 and 30 millimeters.

According to a second particular embodiment, the device according to the invention comprises a filter coupled to food, which filter helps to limit the risks obstruction of the solenoid valve or drippers due to the presence of particulate matter in the circuit Power.

According to a third particular embodiment, the device according to the invention comprises a thermostat also coupled to said solenoid valve or a second solenoid valve, which thermostat is used to shut down the power supply and therefore seedlings below or above a certain value temperature. For example, such a thermostat makes it possible to cut the water supply as soon as the temperature outside is less than 10 C.

According to the fourth particular embodiment, the device according to the invention comprises means allowing

8 regular fertilizer supply to plants growing on the ground absorbent material.

The person skilled in the art can easily identify by his only general knowledge of such means allowing the regular supply of fertilizer.

By way of example, such a means allowing the contribution fertilizer can take the form of a coupled fertilizer tank to a doser, such as the doser DOSATRON, which doser is connected to the water supply.

By way of example also, such means allowing fertilizer can also take the form of marbles or late fertilizer pellets, which balls or pellets can be positioned at the level of the water supply or absorbent material.

The nature and dosage of the fertilizer used are variable depending on the climate and the growth of the seedlings developing on the device according to the invention and may be determined simply by those skilled in the art using his general knowledge.

According to a fifth particular embodiment, the device according to the invention further comprises a sensor of moisture in the absorbent material, which sensor is coupled to the solenoid valve controlling the feed or at a second solenoid valve controlling the supply.

Such moisture sensors can cut feeding when the absorbent material has reached its maximum capacity of water retention and thus optimize even more power management. The threshold value humidity corresponding to the maximum retention capacity in water of the absorbent material is a function of said absorbent material and can be determined simply by those skilled in the art by simple routine experiences. Many moisture sensors are known to those skilled in the art and take particular form of humidity probes.

9 According to a sixth particular embodiment, the device according to the invention further comprises a reservoir specific for adding punctually to the circuit water supply a substance preventing the obstruction of feed pipe porous or perforated by the roots, preferably drippers. As an example of such substances, mention may be made of herbicides such as Treflan (Trifluralin) at a concentration of 0.02%. The diffusion of said substance will be done regularly for example all the months with an injection of 20 seconds per hundred meters tube.

According to a seventh particular embodiment, the device according to the invention comprises plants, which can take the form of seeds that are then placed in or on the layer of absorbent material so as to be directly in contact with moisture.

In the case of sprouted plants or rhizomes, the roots of these develop in the layer of absorbent material and their aerial part develop after their stems have crossed the layer of insulating material.

Very many plants can be used in the device according to the invention. By way of example, mention may be made all kinds of weeds, such as Soleirolia Soleirolii, Veronica filiformis, Viola odorata, Asplenium scolopendrium, Calamintha nepeta, Silene vulgaris, Carex sylvatica, Coronilla varia, Euphorbia cyparissias, Galium palustrine, Lathyrus latifolius and Physalis, from plants horticultural crops such as orchid, pelargonium, Buddleja, caryopteris, choisya, cotoneaster, cytisus, deutzia, forsythia, gaura, fuchsia, jasmine, rosia or saffron bulbs, or forest seedlings such as hornbeam and larch, or berry shrubs such as blueberry or even vine with grapes.

According to a preferred embodiment, the device according to the invention, the absorbent material is wrapped around the pipe and takes the form of a liana on which develops plants.

Advantageously, said liana incorporates elements stiffeners, which preferably take the form of cables, 5 especially steel. Which cables can be coupled with manual or automated tensioning systems, in particular through pulley, so to get lianas that have the desired inclination and whose maintenance, which can to be realized on the ground, is simplified. These stiffening elements

10 can also be internal to the liana and take preferably the shape of a metal rod or a tube. This rod or tube are integral with the water supply pipe and surrounded by layers of absorbent materials that make up the growing medium of plants. The vocation of these elements stiffeners is either to maintain the horizontal liana for to facilitate a homogeneous distribution of water, to weave lianas between them like a wicker basket.

In a liana-type structure, the different materials, especially the absorbent material, can be arranged around of the supply pipe in the form of windings successive.

Maintaining the assembly of different materials absorbent and insulating around the supply pipe can be ensured by means of necklaces, ligatures, glues or using a sheath type structure of the insulating material and, optionally, absorbent material. Can also consider coating the pipe with absorbent material flocking or compression or needling of carded fibers or still use a thermo-fusible product that binds components between them.

According to a second preferred embodiment of the device according to the invention, the support for the plants takes the form of a vertical column or totem, on which is fixed the water distribution pipe, and around which is positioned the absorbent material.

11 Said vertical column is formed of a rigid tube, preferably made of plastic material, in particular PVC, which column is preferably associated with a base allowing maintain said column in a vertical position.

Advantageously, the insulating material and, optionally, the absorbing material form cell-like openings in which seeds or adult plants can be placed. Said cells constitute a support allowing to ensure good vertical growth of the seedlings by minimizing the risk of root rupture.

Advantageously, the vertical column can be associated, preferably at its base, to a gutter of recovery. Said gutter makes it possible to accommodate a possible surplus water and prevent it from spreading over the surrounding area.

Such a vertical column may constitute an element of interior decoration, which vertical column allows maximize the number of plants grown on a minimum of space on the ground.

According to a third preferred embodiment of device according to the invention, the support for the plants takes the shape of a vertical plane, including a curtain.

Said support may consist of a fabric, in particular a plastic web, or a structure of a kind mesh of plastic or metal material, such as a wire mesh.

The water supply pipe is fixed on said support to using appropriate means, in particular by means of necklaces, fasteners or glue, especially silicone glue or it may to be sewn on said support.

Advantageously, the supply pipe is positioned on the support so to cover the maximum surface of the absorbent material, preferably the feed pipe is positioned in a serpentine or laces on the support.

12 Advantageously, the insulating material and, optionally, the absorbing material form cell-like openings in which seeds or adult plants can be placed.

Advantageously, the vertical plane can be associated, preferably at its base, a recovery gutter.
Said gutter makes it possible to recover the surplus water and to prevent it from spreading on the surface surrounding.

Advantageously, the insulating material is printable, preferably said insulating material is made of plastic.

A second object of the invention corresponds to the use of a device as described above in a method of growing plants above ground.

A third subject of the invention corresponds to a method of above-ground plant culture comprising the step water supply and short periods of a hose porous or perforated feed in contact with at least one absorbent material constituting a support for the growth of plants, which absorbent material has a good capacity water retention.

Advantageously, said water supply benefits from a pressure between 0.1 and 10 bar, preferably between 0.3 and 5 bars.

In short periods, we hear an opening of the circuit feed for 1 second to 5 minutes every minute every 24 hours, preferably for 1 to 120 seconds every 2 to 120 minutes and particularly preferred for 5 to 60 seconds every 5 to 60 minutes.

As before, these times for short periods opening of the solenoid valve are for a circuit which remains full between each watering period.
In the event that the supply circuit is drained between

13 each watering period, the opening time of the circuit feed will also include a filling time of supply circuit, which time will depend on the dimension of the supply circuit and can be determined simply by the skilled person.

The porous or perforated feed pipe can take the shape of a metal or plastic pipe, preferably made of plastic.

Advantageously, the porous or perforated feed pipe take the form of a drip pipe, preferably a hose with drippers at regular intervals.

By absorbent material having a good ability to water retention means a material with potential water retention greater than 50%, preferably one water retention potential greater than 60% and so particularly preferred is a water retention potential greater than 65%.

Such absorbent materials are well known to the human example, foams or mineral felts, in particular based on rockwool or glass, including plants based on cotton and / or synthetic, preferably foams or vegetable felts and so particularly preferred foams or felts based on cotton, jute, hemp, flax, coconut, sphagnum. Of preferably, and when the absorbent material is of origin plant, it is treated so as to be rot-proof. Of such felts advantageously have creped structures.
Said absorbent material serves as a support for the development of roots. Accordingly, said absorbent material will exhibit low phytotoxicity.

Advantageously, the material having a good capacity water retention has a thickness of between 0.2 and 10 cm, preferably between 0.5 and 5 cm so particularly preferred between 1 and 3 cm.

14 The absorbent material may take the form of one or several layers, including two or three layers superimposed, preferably two layers. In the case of diapers superimposed, said superposed layers may be made from materials with retention potential distinct water. Preferably, the first layer of absorbent material in contact with the pipe feedstock presents the potential for fluid retention and the most important broadcast.

Advantageously, the contact between the supply pipe and the absorbent material allows the passage of water from the pipe feeding to the absorbent material by capillarity.

According to a particular embodiment, the method according to the invention further comprises the step of feeding fertilizer plants growing on the absorbent material.

For example, such a fertilizer be carried out using a measuring device, such as dosing devices DOSATRON, which doser is coupled to a fertilizer tank and is connected to the water supply.

By way of example also, such a supply of fertilizer may also be carried out using logs or of late fertilizer pellets, which pellets or pellets can be positioned at the level of the water supply or absorbent material.

The nature and dosage of the fertilizer used are function seasons and plants growing on the device according to the invention and can be determined simply by the skilled person using his general knowledge.

According to a second particular embodiment of the method according to the invention, the water supply is controlled in addition by a moisture sensor in the absorbent material.

Said humidity sensor makes it possible to cut off the power supply when the absorbent material has reached its capacity maximum water retention and thus optimize further still the power management.

According to a third particular embodiment, the method according to the invention further comprises a step 5 addition to the circuit in water supply of a substance preventing clogging of the porous feed pipe or perforated by the roots.

Such a supply is made at intervals regular function of seasons and developing plants 10 on the absorbent material. As an example, such a step feeding is carried out with a periodicity of one month to one year, preferably from 3 months to 1 year.

Such a diet is performed for a short period between 5 seconds and 10 minutes, preferably

Between 10 seconds and 1 minute and particularly preferred between 15 and 30 seconds.

Very many plants can be used in the process according to the invention. By way of example, mention may be made all kinds of weeds, such as Soleirolia Soleirolii, Veronica filiformis, Viola odorata, Asplenium scolopendrium, Calamintha nepeta, Silene vulgaris, Carex sylvatica, Coronilla varia, Euphorbia cyparissias, Galium palustrine, Lathyrus latifolius and Physalis, from plants horticultural crops such as orchid, pelargonium, Buddleja, caryopteris, choisya, cotoneaster, cytisus, deutzia, forsythia, gaura, fuchsia, jasmine, rosia or saffron bulbs, or forest seedlings such as hornbeam and larch, or berry shrubs such as blueberry or even vine with grapes.

Other features of the invention will appear in the following examples, without these constitute any limitation of the invention.

Example 1: Feeding System

16 The feeding system used in different devices tested in Examples 2 to 4 is presented in the figure 1.

The latter included - a water inlet (6) corresponding to a water inlet current at a pressure of the order of 6 bars;

- a clear water tap (4) (only for practical reasons for taking water);

a pressure reducer (5) so as to adjust the supply pressure to a value between 2 and 3 bars;

a filter (3) for protecting the doser;

- a doser DI 1500 DOSATRON type (2), which doser is coupled to a reservoir of nutrient solution (11);

a filter (10) for protecting the drippers;

- a programmer (1) for organizing periods supply (watering) up to 1 to 60 seconds every 15 to 60 minutes;

- a thermostat (7) to cut the power supply when the outside temperature is below 10 C;

- a solenoid valve (9) for controlling the opening food; and - an outlet (8) to the water supply pipe presenting drippers at regular intervals.
Example 2: Vine-type device:

1) First embodiment:

17 An example of a liana type aboveground crop support is illustrated in Figure 2. For this one, it was used a plastic feed pipe with a diameter of 20 millimeters. On this pipe had been arranged at intervals regular, of the order of 30 centimeters, type drippers self-regulating, anti-siphoning and self-cleaning. Around this feed pipe, a cotton-based felt (and residue synthetic carpet) with a thickness of 5 millimeters has been wound in three successive layers between which seeds of different varieties like flowering grass and all kinds of grasses have been arranged. Finally, said felt has been surrounded by a layer of treated coconut mat (to avoid its rotting). The whole was finally maintained using iron wires treated against corrosion.

2) Second embodiment An example of a liana type above-ground culture support with internal reinforcement is shown in Figure 3. For this here it was used a plastic feed pipe having a diameter of 20 millimeters. On this pipe had at regular intervals, of the order of 30 centimeters, self-regulating type drippers, anti-siphons and self-cleaning. A high density PVC tube of 20 mm diameter is attached to this pipe so as to make one and the other solidary as shown in Figure 4. Around this supply pipe and this tube, a cotton-based felt (and synthetic carpet residues) with a thickness of 5 millimeters was wound into three successive layers between which seeds of different varieties like turf flowers and all kinds of grasses have been arranged. Finally, said felt has been surrounded by a layer of coconut mat treated (to prevent rotting). The set has finally been maintained using iron yarns treated against corrosion.

Example 3: Device of Column Type:

18 An example of column-type above-ground culture support is shown in Figure 5. In the latter, the column is formed of a rigid PVC tube having a diameter of 20 centimeters, which is held in position by a pedestal metallic. Around the rigid PVC tube is positioned a felt cotton-based 5 millimeters thick. On this felt is spirally wound a drip-type feed pipe drop of 20 millimeters in diameter and with drippers spaced at regular intervals, of the order of 30 centimeters, drippers of the self-regulating, anti-siphon and self-cleaning. Around this feed pipe, a second felt made from cotton (and synthetic carpet residues synthetic) with a thickness of 7 millimeters has been arranged.
Finally, said felt has been surrounded by an insulating material of the type polyethylene, in which openings have been made.
Said openings form cells for placing seeds or young plants.

Example 4 Device of Vertical Plan Type:

An example of non-rigid support of above-ground cultivation of Vertical plane (or curtain) type is shown in Figure 6. for this one it was used a plastic feed pipe having a diameter of 6 millimeters. This pipe is arranged and glued in laces that go on both sides of a canvas waterproof plastic. On this canvas and against this pipe, we just stick a first felt that has an extra thickness between each lace of the pipe. On this felt is sewn a second double-sided felt, with an insulating face and an absorbent face. This double-sided felt has pockets in which plants are arranged. On the canvas side are printed decorative patterns.

Results:

The different devices described in Examples 2 to 4 were powered using the power system described in Example 1 according to two different protocols.

19 A first protocol allowed a water supply (watering period) per period of 15 minutes every 6 hours, four waterings per day.

In the second protocol, the water supply was performed in 45-second intervals every 45 minutes.

The results showed after a few days that the second protocol allowed for a considerable loss of water. We observed in particular with this second protocol unlike the first that surfaces surrounding devices tested remained net, no leakage of water having occurred on these surfaces.

Claims (21)

1. A device allowing the growth of plants out soil comprising:

i) a water supply;

ii) a timer coupled to a solenoid valve said power supply, which timer allows command the opening said solenoid valve, and therefore the feeding circuit, for short periods;

iii) at least one porous or perforated feed pipe;
iv) at least one absorbent material constituting a support for growing plants in contact with said pipe feedstock, which absorbent material has a good water retention capacity and good dissemination capacity; and v) at least one support for said feed pipe and said absorbent material. 2. The device according to claim 1, characterized in what the said short periods correspond to an opening from the power circuit for 1 second to 5 minutes all minutes every 24 hours, preferably during 1 to 120 seconds every 2 to 120 minutes and so particularly preferred for 5 to 60 seconds every 5 at 60 minutes. 3. The device according to any one of the claims 1 or 2, characterized in that the porous feed pipe or perforated is a drip pipe, preferably a pipe presenting drippers at regular intervals. 4. The device according to any of the claims 1 to 3, characterized in that the absorbent material having a good water retention capacity is a material having a water retention potential greater than 50%, preferably a water retention potential higher than 60% and particularly preferably a potential of fluid retention greater than 65%. 5. The device according to any one of the claims 1 to 4, characterized in that said absorbent material having a good diffusion capacity presents a porous structure with pore sizes included between 1 μm and 1 mm, preferably between 5 and 100 μm, for example between 10 and 50 μm, and particularly preferred between 15 and 30 microns. 6. The device according to any one of the claims 1 to 5, characterized in that said absorbent material is selected from the group consisting of foams and felts minerals, plants and synthetics. 7. The device according to any of the claims 1 to 6, characterized in that the absorbent material has a thickness between 0.2 and 10 cm, preferably between 0.5 and 5 cm, particularly preferably between 1 and 3 cm. 8. The device according to any one of the claims 1 to 7, characterized in that said device further comprises an insulating material positioned on the absorbent material. 9. The device according to any one of the claims 1 to 8, characterized in that said device further comprises a film or micro-perforated tube surrounding the pipe feeding tube and placed between said feed pipe and the absorbent material. 10. The device according to any one of the claims 1 to 9, characterized in that said device further comprises a thermostat also coupled to said solenoid valve or a second solenoid valve, which thermostat allows to cut feeding of the device and therefore of the seedlings under or over above a certain temperature value. 11. The device according to any of the claims 1 to 10, characterized in that said device comprises in in addition to providing a means of regular fertilizer plants developing on the absorbent material. 12. The device according to any one of the claims 1 to 11, characterized in that said device comprises in in addition to a moisture sensor in the absorbent material, which sensor is coupled to the solenoid valve controlling the power supply or a second solenoid valve controlling the supply. 13. The device according to any one of the claims 1 to 12, characterized in that said device comprises in besides a specific reservoir allowing to add to the water supply circuit a substance preventing the obstruction of the porous or perforated feed pipe by roots. 14. A use of a device according to any one Claims 1 to 13 in a plant growing process Aboveground. 15. A method of growing above-ground plants comprising the water supply stage and by short periods of a porous or perforated feed pipe in contact with at least one absorbent material constituting a support for the growth of plants, which absorbent material has a good capacity water retention and good diffusion capacity. 16. The process according to claim 15, characterized in that that said water supply is pressurized between 0.1 and 10 bar, preferably between 0.3 and 5 bars. 17. The process according to any of claims 15 or 16, characterized in that said short periods consist of an opening of the water supply circuit for 1 second to 5 minutes every minute to every 24 hours, preferably 1 to 120 seconds every 2 hours at 120 minutes and particularly preferably for 5 minutes.
at 60 seconds every 5 to 60 minutes. 18. The process according to any of claims 15 at 17, characterized in that said absorbent material having a good water retention capacity consists of a material having a water retention potential greater than 50%, preferably a water retention potential higher than 60% and particularly preferably a potential of fluid retention greater than 65%. 19. The process according to any of claims 15 18, characterized in that said method further comprises a fertilizer feeding stage of the plants growing on the absorbent material. 20. The process according to any of claims 15 19, characterized in that the water supply step is further controlled by a moisture sensor in the material absorbent. 21. The process according to any of claims 15 at 20, characterized in that said method further comprises a step of adding to the circuit in water supply of a substance preventing obstruction of the supply pipe porous or perforated by the roots.