FR2914816A1 - Plant container for hydroculture field, has aeration unit generating air circulation inside container and diffusing part of air in substrate, and air circulation unit constituted by vertical air circulation tube with holes at its periphery - Google Patents

Abstract

The container has an inner wall (2) forming a bottom of the container, where the wall extends towards the top by main walls to form a parallelepiped inner chamber opened towards the top. The chamber contains a culture substrate favoring the development and the preservation of plants, and an aeration unit (6) generates the circulation of air inside the container and for diffusing the part of the air in the substrate. The air circulation unit is constituted by a vertical air circulation tube (14) comprising a set of holes at its periphery.

Description

The present invention relates to the field of

  hydro culture. And more particularly an improvement for better air circulation especially in the substrate.

  The hydro culture is a general technique which has the principle of replacing all or part of the nourishing earth by an inert substrate, from the physico-chemical point of view, in which the root system of the plant develops and in which it is added water and a specific nutrient system providing the plant with the essential elements for its development and growth. Unlike indoor hydro-culture, where the roots of plants are washed and replaced by an inert culture substrate of the clay-ball type, in outdoor hydro-culture, the plants are planted in the culture substrate. inert with their clod of soil. The external conditions being traditionally more demanding, the motte avoids a brutal stress of the roots and ensures a faster recovery of the plant. The evolution of outdoor hydro culture in aeroculture corresponds to the principle according to the ventilation of the water reserve by equipment and / or orifices favoring this principle. We can thus qualify the hydro culture of aeroculture.

  This cropping system has many advantages that make it a future-oriented and economically viable system. The systems of hydro culture of known exteriors are also based on a principle of culture in tray. Traditionally, the tray includes a draining layer that surrounds the root ball, a semi-open hollow space to form a bell-shaped water tank in the bottom of the tank or a plate pierced or not with wicks for the capillary rise of the tank. 'water. This equipment is also equipped with a water column to supply the bottom of the tank with water and a gauge to control the water level in the tank. Such a system that has a water reserve bell bottom tray is for example marketed by Leni-Terraponic hydro culture tray system and those with grid are inspired Riviera bins. Nevertheless, it has been found that existing systems have certain major drawbacks. 1 A first problem is the organic decomposition of the root system. After a few months, the root system suffers from rotting in these hydro-culture systems. The rotting may have several origins, such as the direct contact between the roots and the water of the reservoir or the presence of a highly humid environment not directly ventilated. Another problem is the acidification of the medium. During temperature increases, the degradation of mineral elements contained in the nutrient system (fertilizer) within the inert substrate associated with water tends to acidify the culture medium. In particular, the organic compounds of the nutrient system can be converted into solution and / or gas form. These compounds, which are trapped in the inert substrate, degrade and cause root burn because of their more corrosive and / or acidic nature in degraded form when their concentration increases sharply. For example, the presence of nitrogenous organic matter in fertilizers leads to the production of ammoniacal nitrogen (NH 4 organic ion) which is recognized as a powerful pollutant. It is also noted that the acidification of the culture medium and the production of degraded pollutant compounds accelerate during high heat and during water deficiency. Some plants only support alkaline media and a difference in pH can cause death of the plant in a few days. The known systems require very frequent watering, which poses an economic problem for some communities in order to properly provide this service in terms of personnel costs, transport water consumption and others. Watering is frequent because conventional culture substrates have a very low water retention capacity compared to clay balls. In addition frequent watering can refresh the plant and at the same time to ensure oxygenation of the culture medium. In some cases the frequency of watering can be daily every 2 to 3 days maximum in climates like Center France, Val de Loire in particular. There has also been a misuse and transport of water inside the tank by the plant, so the water has more of an effect on the organic decomposition (rotting) of the plant roots and poor transfer by the plant. capillarity of water through the culture medium to the plant and its root system. The present invention aims to provide a container and a method of hydro culture or aeroculture that solves all problems. The present invention improves the quality and integrity of the root system of the plant by limiting the risk of organic decomposition. Another advantage is to reduce the risk of acidification of the environment, as well as to reduce the production of harmful pollutants resulting from the degradation of organic compounds. The container of the invention also makes it possible to make better use of the available water so as to reduce the need for watering, or even to eliminate it. Other features and advantages of the invention will become apparent from the following description with reference to the accompanying drawings which are given by way of non-limiting examples. Figure 1 is a perspective view of the container according to the invention, without the plant. Figure 2 is a perspective view showing more particularly the interior of the container without the plant with its root ball, or the substrate. Figure 3 is a view similar to Figure 2 showing an alternative embodiment Figure 4 is a cross-sectional view of an alternative embodiment. Figure 5 is a cross-sectional view. FIG. 6 is a sectional view illustrating means for visualizing the water level of the water reserve. The container (1) consists of a bottom wall (2) forming the bottom of the container, extended towards 1, e top by a peripheral wall (3), forming an inner chamber (4) open upwards, said enclosure being intended to contain in particular a substrate promoting the development of plants, see a water reserve (12). According to the embodiment shown by way of example, the container is of parallelepipedal shape and is such that it comprises four elementary walls (3a, 3b, 3c, 3d) delimiting a parallelepipedal internal enclosure (4). Of course the container may have a shape other than parallelepiped without departing from the scope of the invention, such as oval or round or other. According to a characteristic of the container (1) of the invention the latter comprises aeration means (6) for generating a flow of air inside the container, and more particularly for diffusing air into the substrate ( 5). The ventilation means (6) are constituted by at least one horizontal air circulation tube (7) extending for example horizontally to open on opposite sides of opposite wall elements (3a-3c, 3b). -3d). In other words, each of the ends (7a, 7b) of the horizontal air circulation tube (7) opens into the air outside the container, and this through holes (8a, 8b) arranged in the opposite peripheral wall elements. The outer wall (9) of the horizontal air flow tube (7) comprises a set of holes (10) thereby diffusing air from the ends into the substrate (5). It should be added that the air circulation means (6) of the container (1) further comprise at least one horizontal tube (7) at least one vertical air circulation tube (14) cooperating with the horizontal air circulation tube. (7). The vertical airflow tube extends vertically from the horizontal airflow tube (7), to extend upwardly, preferably beyond the upper surface (15) of the substrate (5). .

  The vertical air circulation tube (14) comprises at its periphery a set of holes (16) thus ensuring the diffusion of air from the horizontal air circulation tube (7). As mentioned above, the vertical air circulation tube (14) is connected to the horizontal air circulation tube (7) by means of a connection piece (17) which is arranged at the lower end ( 18) of the vertical air circulation tube (14). This connecting piece (17) which can be an independent piece or which can be integral with the vertical tube, is constituted by a portion of connecting tube (19) extending horizontally, the inside diameter is slightly greater than the outside diameter of the horizontal tube. Thus the latter is engaged in the tube portion (19), and can also slide freely, so as to possibly change the position of the vertical tube (14) on the horizontal tube. It will be noted that the inside of the vertical air circulation tube (14) communicates with the inside of the connection tube portion (19), in order to allow the passage of air from the horizontal tube towards the tube vertical (14).

  According to an alternative embodiment, the aeration means comprise, in the extension of the vertical air circulation tube (14), a lower vertical tube portion (20) whose wall comprises a set of holes (21). This lower tube portion extends vertically from the bottom wall (2) to the connection tube portion (19), and is therefore located in the water storage area (12). It will be appreciated that the interior of the lower vertical tube portion communicates with the interior of the connecting tube portion (19) to allow the passage of excess water to the outlet through holes (8a, 8b ).

  It is understood that the vertical tube (14), the connecting tube portion (19) and the lower vertical tube portion (20) form an assembly (22) movable in lateral displacement on the horizontal tube, so as to be able to positioned on the horizontal tube. The substrate (5) can fill the entirety of the inner chamber (4) of the container as illustrated in FIG. 4, but it may be otherwise, and especially as illustrated in FIG. 5. If the water reserve can be contained in the substrate as illustrated in FIG. 4, it can be a true water reserve as illustrated in FIG. 5. Thus, according to a variant, the container (1) comprises an intermediate lower wall (11) extending horizontally at a distance from the bottom and above the horizontal air circulation tube (7) such that in other words the intermediate bottom wall (11) extends for example above the horizontal air circulation tube (7) and allows to support the substrate and thus create in the lower part of the container a water reserve (12). It should be added that wicks (13) passing through the intermediate bottom wall (11) allow water to diffuse by capillarity into the substrate. The intermediate wall is for example constituted by a grid. It should be noted that in the case of a true water reserve as illustrated in FIG. 5, a display means (23) for the quantity of water in the reserve can be provided. For this purpose, the display means consists of a display rod (24) housed in the vertical air circulation tube, the lower end of which comprises a float (25), while the upper end is intended to protruding out of the vertical airflow tube, thus allowing the user to take notice of the water level. Bine heard the horizontal airflow tube comprises at the di passage of the rod a through hole allowing just the passage of the viewing rod. According to a complementary characteristic, the root ball (26) in which the root system of the plant (27) develops is surrounded by a culture substrate made of porous material (5). Thus, the air circulation. The volume of substrate (5) is sufficient to promote root development outside the root ball (26).

  It has been understood that, thanks to the aeration means, there is a flow of air which extends through the volume of the cultivation substrate (5) between the volume of water reserve and the root ball (26). This makes it possible to reduce root rot, root asphyxiation and / or the production of harmful compounds resulting from organic degradation and / or acids. It has also been understood that, thanks to the container (1) and its contents, it is ensured both - a more efficient water transfer by capillarity towards the root system which reduces the need for water for the plant, avoids excess water and stagnant water and thus rotting of the roots - a supply of air by promoting the circulation of air in the culture medium which has the effect of avoiding asphyxiation of roots, organic degradation and / or the formation of compounds from of anaerobic decomposition. In a more general manner, a better water / air balance is ensured in the culture substrate and the natural physiological needs of the plant are favored. It should be added that the culture substrate preferably comprises a set of inert and non-degradable discrete elements such as expanded clay beads and / or hydrophilic rock wool flakes, see hemp. Expanded clay beads are preferred for their macroporosity able to constitute air circulation spaces. The culture substrate constituted by the clay balls, occupying the space of the zone of the enclosure around the root ball of the plant, thus allows a better air circulation. The caliber of the beads may be between 6/8 and 10/20 millimeters with a porosity of about 70 to 80% and a pH (hydrogen potential) close to neutral, namely 7. In the method of the invention, it is preferable to use a nutrient system feed into the slow-release coated fertilizer-type culture substrate or organic-type fertilizer, the manufacture of which shows slow degradation. These nutritive systems are called coated or organic fertilizers. The fertilizer is usually in the form of granules containing a proportion of nutrients such as N, P, K and trace elements embedded in an organic resin capsule that regulates the diffusion of the elements or for the organic their formulation and their nature. make their degradation slow. The substances are gradually released into the substrate depending on the temperature, the water conditions according to an osmosis phenomenon for synthetic chemical fertilizers. Diffusion is also independent of pH, organic matter content, bacterial activity and amount of water spray. The fertilizer used having a release between 3 and 12 months is preferable. The fertilizer dosage may vary depending on the formula and the plant considered. The most appropriate formulas for the invention are, for example, essential proportions of 7 (N) - 14 (P) -21 (K) or 9 (N) - 11 (P) - 18 (K) or (N) - 11 (P) -18 (K) sold under the trade name Osmocote by The Scots Company Of course, the invention is not limited to the embodiments described and shown by way of examples, but it also includes all technical equivalents and their combinations.

Claims (8)

  1. Container (1) for plants consisting of a bottom wall (2) forming the bottom of the container, extended upwards by a peripheral wall (3a, 3b, 3c, 3d), forming an inner chamber (4) open towards the top, said enclosure being intended to contain a substrate promoting the development and conservation of plants, and which comprises aeration means for generating a circulation of air inside the container and for diffusing at least part of the air in the substrate (5), characterized in that the air circulation means are constituted by at least one vertical air circulation tube (14) which comprises at its periphery a set of holes (16).   2. Container (1) for plants, according to claim 1, characterized in that it comprises a horizontal air circulation tube (7) are constituted by at least one horizontal air circulation tube (7) s' extending horizontally to open on opposite sides of opposite wall elements (3a-3c, 3b-3d), namely that each of the ends (7a, 7b) of the horizontal air circulation tube (7) opens at free air outside the container, and this through holes (8a, 8b) arranged in the opposite peripheral wall elements, while the horizontal air circulation tube (7) comprises a set of holes (10). ) thus ensuring the diffusion of air from the ends in the substrate (5).   3. Container (1) for plants, according to the preceding claim, characterized in that the horizontal tube (7) at least one vertical air circulation tube (14) cooperates with the horizontal tube air circulation (7). ), and extends vertically from the horizontal air circulation tube (7), to extend upwards,   Plant container (1) according to claim 30, characterized in that the vertical air circulation tube (14) is connected to the horizontal air circulation tube (7) by means of a connecting piece (9). 17) which is arranged at the lower end (18) of the vertical air circulation tube (14).   5. Container (1) for plants according to the preceding claim, characterized in that the aeration means comprise in the extension of the vertical air flow tube (14), a lower vertical tube portion (20) whose wall comprises a set of holes (21). this lower tube portion extending vertically from the bottom wall (2) to the connecting tube portion (19), and is therefore located in the water storage area (12).   6. container (1) for plants, according to any one of claims 2 to 5, characterized in that it comprises an intermediate bottom wall (11) extending horizontally at a distance from the bottom and above the tube horizontal air circulation (7), said intermediate wall extending above the horizontal air circulation tube (7), which allows to support the substrate and thus create in the lower part of the container a reserve of air water (12), while wicks (13) pass through the intermediate bottom wall (11) to allow diffusion of water by capillarity into the substrate.   7. Container (1) for plants according to any one of the preceding claims, characterized in that the substrate (5) surrounds the clod (26), in which develops the root system of the plant (27), said culture substrate (() being of porous material (5).   8. Container (1) for plants according to any one of the preceding claims, characterized in that it comprises a display means (23) of the amount of water of the reserve, said display means being constituted by a viewing rod (24) housed in the vertical air circulation tube, the lower end of which comprises a float (25), while the upper end is intended to protrude from the vertical air circulation tube, thus allowing the user to take notice of the water level.