NL2000327C2 - Feeding bed for crop incorporates expanded perlite granules to optimise growth of plants, making possible a controlled plant development, with the residue after the harvest period to have a lasting effect - Google Patents

Abstract

The natural material perlite is processed to a fixed form structure without any compostable adhesive being added. The compostable fiber material used is that of organic origin for reciprocal joining of the expanded perlite granules. Preferred compostable materials are cotton fibres, copra fibers, fibers prepared from plant materials such as polylactic acid. The fiber material is recyclable together with the perlite and for further processing does not have to be separated from the perlite. The composition of the perlite granules as the result of the compostable fiber material during the lifetime of the feeding bed will be reduced as the outcome of the partial composting of the fiber material. The compostable fiber material comprises preferably shortened fiber parts of an average length of 8-3 mm and particularly an average length of 4mm (+ or - 0.5mm) in order to constitute an advantageous binding result.

Description

Culture soil for a crop provided with expanded periiet grains

The present invention relates to a nutrient medium for a crop, comprising expanded periiet grains.

5

The large-scale cultivation of plants uses artificially produced nutrient soils to optimize growth and to reduce the risk of infections, unwanted bacterial growth, pests and other unwanted effects. The use of glass wool, among other things, is popular here. Such a glass wool medium is used in particular in department stores (greenhouses) and is metered with water and nutrients. Thus, it becomes possible to accurately control the plant growth. After the harvest, the remaining nutrient medium with the root systems developed therein and possibly other organic residual material is removed. The removal of the (usually voluminous) residual material is expensive.

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The object of the present invention is to provide an improved nutrient medium with which controlled plant development is possible, but the residue of which is easier to process after a harvesting period than according to the prior art.

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To this end, the invention provides a nutrient medium for a crop, comprising a form-retaining structure made from expanded period granules that are kept in relation to each other by means of compostable fiber material. Periiet (known inter alia as EPB) is an inorganic-based material with a brown color that is extracted from volcanic rock. By subjecting particles to heat treatment, they can be expanded. Expanded periiet grains have a more porous structure which implies that the grains can retain excellent water. The volume mass of the expanded period is approximately 150 kg / m3. Expanded periiet grains are used in particular as insulation material. The application as insulation material can be explained by the good fire resistance, the high heat resistance and the low thermal conductivity (in the order of magnitude <0.060 W / mK). In addition, expanded periiet grains are used as soil improvers by mixing them 2 with, for example, humus. This is due in particular to the favorable properties with regard to air and water vapor permeability.

The present invention makes it possible to process the natural material perlite into a form-retaining structure without the need for non-compostable additives such as, for example, adhesives. The compostable fiber material, generally this fiber material is of organic origin, ensures the interrelation of the expanded perlite grains. Examples of compostable fiber material are: cotton fiber, coconut fiber, fibers made from vegetable substances such as, for example, PLA and so on. The compostable fiber material can be recycled together with the perlite and will generally not have to be separated from the perlite for further processing. Depending on the circumstances, it is even possible (but not necessary) that the compostable fiber material will already have at least largely decayed at the moment that the nutrient medium must ultimately be processed. It is thus conceivable that the cohesion of the perlite grains will decrease as a result of the compostable fiber material during the lifetime of the culture medium as a result of (partly) composting the fiber material. However, this does not have to be an objection because the nutrient medium must be manipulable, in particular during the first phases of plant development. For example, the initial cultivation and eventual complete plant development that can take place at other locations, but also with a different mutual distance between adjacent nutrient media (a large plant obviously requires more space than a not yet developed germ). The possible reduction of the cohesion between the perlite grains during the lifetime of a nutrient medium therefore does not have to be an objection. Moreover, a developing root system will also provide additional cohesion between the perlite grains, which compensates for any reduced binding effect of the fiber material.

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The compostable fiber material preferably consists of truncated fiber parts with an average length of 20-2 mm, more in particular of 8-3 mm. Even more particularly, fiber parts with an average length of 4 mm (+ or - 0.5 mm) have been found to lead to a very advantageous binding result. In addition to compostability, compostable fiber material has the advantage that it usually consists of incompletely smooth fibers, so that its binding action is relatively large. Good results have been obtained with cotton, a fiber material that is furthermore advantageously commercially available. In particular, it is preferable to use bleached cotton, partly because this minimizes the chance of contamination of the culture medium by the cotton. In addition, it is also possible to crush the fiber material. The crushed fibers often have a rougher surface with the advantage of a greater binding effect of the fiber material. In addition to the improved processability of this material, it is also possible to limit the material costs relative to the more traditional nutrient media based on non-compostable material. Another advantage of the culture medium according to the present invention is that it generally has an energy balance that is advantageous over traditional products.

In another preferred embodiment, the nutrient medium is at least partially surrounded by a fiber structure composed of compostable fiber material. An external reinforcement is thus additionally applied, which can lead to an even greater and longer-lasting cohesion of the perlite grains. A fiber or pressed fiber layer can be used as the fiber structure. Advantageous fibers that can be used for this purpose include PLA (poly lactid acid), coconut fiber and cotton. On the outside, it is also possible, although less desirable, to provide an external reinforcement that is composed of a non-compostable material such as, for example, a plastic film. After all, the external reinforcement can still be removed during recycling.

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With regard to the design of the culture medium, a substantially rectangular (such as, inter alia, a cube-shaped) structure is envisaged in which at least one holder opening is left clear on one side. The base for a larger plant in the form of, for example, a seed, seed or smaller plant can be introduced into this at least one holder opening. The advantage of the rectangular structure is that many mechanized systems with which conventional nutrient media are processed are arranged to process them. The improved culture medium according to the invention can thus also be processed with existing equipment.

4

A further improvement of the shape of the culture medium can be obtained if the rectangle tapers towards the side with the holder opening. With this shape it is easier to grasp and move densely placed nutrient media.

It is also possible to design the nutrient medium mainly in the form of a pin (also referred to as a plug), a germ of a plant being received centrally in the pin. Such a shaped nutrient medium is already used for growing new plants, such a shaped structure can also be realized with the improved composition of the nutrient medium.

In yet another embodiment, the nutrient medium forms a closed structure for mixing with other soil material. The form-retaining soil can also be mixed in as a more complex structure into other soil material such as, for example, clay, sand, compost, humus or a combination of such materials. Due to the shape-retaining structure, it is also possible to mix larger clusters of expanded perlite in a soil, which further extends the control range for soil improvement with the aid of perlite. To date, the particle size of the perlite expanded to be mixed with a bottom material has not been properly controllable.

The invention also provides a double culture medium, consisting of a rectangular culture medium with a container opening as described above, into which a second pin-shaped culture medium with a germ, as also described, is inserted. After the first cultivation of a seed, a larger nutrient medium is required for the subsequent growth of the plant. By placing the pin in the holder opening, the volume of a growing medium accessible to a plant is now increased.

In addition, the invention also provides a composite nutrient medium for several crops simultaneously, which is provided with a carrier layer with expanded non-interconnected perlite granules, which perlite granules are at least partially surrounded by a casing, and a plurality of nutrient media placed on the carrier layer as described earlier. . The perlite grains in the carrier layer do not need to be interdependent, that is, the carrier layer need not be dimensionally stable. The dimensionally stable nutrient media (for example rectangular ones) can be placed on the carrier layer after the plants in question have grown sufficiently and this gives the roots an even larger area for further growth.

In order to simplify root growth from the form-retaining soil to the support layer, it is desirable that the casing is interrupted where the support layer supports the form-retaining soil. With regard to the jacket, it is also conceivable that it is made from a compostable fiber material such as, for example, PLA (Poly Lactid Acid), coconut fiber or cotton. On the other hand, it is also noted here that the jacket of the carrier layer can optionally also be made of a non-compostable material. After all, this jacket is relatively easy to remove before the remaining residue can be processed in a sustainable way.

The present invention will be further elucidated on the basis of the non-limitative exemplary embodiments shown in the following figures. Herein: figure 1A shows a perspective view of a substantially cube-shaped form-retaining soil according to the invention; figure 1B shows a perspective view of an alternative embodiment variant of a substantially cubic shape-retaining culture medium according to the invention; Figure 2 shows a perspective view of a pin-shaped form-retaining culture medium according to the invention; figure 3 is a perspective view of a double culture medium according to the invention; and figure 4 shows a perspective view of a schematically represented composite nutrient medium according to the invention with a carrier layer on which several form-retaining nutrient media are placed.

Figure 1A shows a substantially cubic form-retaining soil 1 which is composed of expanded perlite grains 2. In the top side 3 of the soil 1 shown in this figure, a recess 4 is provided in which a base for a larger plant (not shown in this figure) is provided a seed, germ or smaller plant) can be placed. The substantially cube-shaped nutrient medium 1 narrows towards the top 3 to some extent. This design has the advantage that when placed on a short distance from another similar like bottom 1, the culture medium 1 is easier to start or to position. This is because the nutrient bottoms 1 can be tilted to a limited extent relative to each other as a result of the narrowed top side 3, so that they can for instance be taken up or put away by a guide track which is at a slight angle of inclination.

Figure 1B shows a substantially cubic form-retaining nutrient medium 10, the top side of which is again provided with a recess 12 for holding the base for a larger plant (for example in the form of seed, seed or smaller plant). Deviating from the nutrient medium 1 shown in figure 1A, the upright sides of the nutrient medium 10 are covered with a foil material 13 which provides the nutrient medium 10 with a greater rigidity. This foil material 13 is preferably made from a compostable material, but can optionally also be made from a non-compostable material (such as plastic) because after use of the culture medium 10 it is relatively easy to separate it from the perlite / fiber mixture 14.

Figure 2 shows a plug 20 which is form-retaining composed of a mixture 21 of expanded perlite and fiber material. As shown by means of broken lines, there is a seed 22 of a plant in the plug.

As shown in Figure 3, the plug 20 (see Figure 2) can at an appropriate moment, that is to say, as soon as the germ 22 has grown such that the plug 20 no longer provides sufficient space for further growth or as soon as the germ 22 extends beyond the plug 20 threatens to grow, to be inserted into the substantially rectangular nutrient medium 10 (see figure 1B). A double culture medium 30 is thus created in which the germ 22 (not visible in this figure) in the plug 20 can further develop beyond the limits of the plug 20. The root system of the germ 22 can now extend into the rectangular nutrient medium 10 extend.

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Figure 4 shows a composite nutrient medium 40 with a carrier layer 41 on which a number of double nutrient media 30 (see Figure 3) are placed. The carrier layer 41 has a filling of expanded perlite granules which are held together without substantial mutual cohesion (i.e. non-shape-retaining) by a bag 42 7 in which openings 43 are provided at the location of the nutrient media 30 for easy passage of developing roots of plants 44. The plants 44 were originally grown in the nutrient soils 30, but after the nutrient soils 30 offered too little space to the developing roots, the nutrient soils 30 were placed on the carrier layer 41. The plants 44 can carry fruits 45 such as tomatoes.

Claims (14)

1. A nutrient medium for a crop, comprising a form-retaining structure made from an expanded perlite granule which is kept in relation to each other by means of compostable fiber material. 2. Culture medium according to claim 1, characterized in that the compostable fiber material consists of truncated fiber parts with an average length of 20-2 mm, more in particular of 8-3 mm. 10 3. Culture medium according to claim 1 or 2, characterized in that the compostable fiber material consists of cotton. 4. Culture medium according to claim 3, characterized in that the cotton is bleached. A culture medium according to any one of the preceding claims, characterized in that the fiber material is bruised. A nutrient medium according to any one of the preceding claims, characterized in that the nutrient medium is at least partially surrounded by a fiber structure composed of a compostable fiber material. 7. Culture medium as claimed in any of the foregoing claims, characterized in that the culture medium is essentially designed as a rectangle in which at least one holder opening is left clear on one side. 8. Culture medium according to claim 7, characterized in that the rectangle tapers towards the side with the holder opening. 30 9. A nutrient medium according to any one of claims 1-6, characterized in that the nutrient medium is essentially in the form of a pin in which a base for a plant is centrally accommodated. The nutrient medium according to any of claims 1-6, characterized in that the nutrient medium forms a closed structure for mixing with other soil material. A double nutrient medium consisting of a cube-shaped nutrient medium according to claim 7 or 8 in the holder opening of which a pin-shaped nutrient medium with a base for a plant according to claim 9 is arranged. 12. Composite nutrient medium for simultaneously several crops, comprising: a carrier layer with expanded perlite granules that are not connected to each other, which perlite granules are at least partially surrounded by a casing, and - multiple nutrient media placed on the carrier layer according to any one of the preceding claims. 15 A composite culture medium according to claim 12, characterized in that the jacket is interrupted where the carrier layer supports the culture medium according to one of claims 1 to 9. A composite nutrient medium according to claim 12 or 13, characterized in that the casing is made from a compostable material.