DE29712629U1 - Plant substrate - Google Patents

Description

B 34.033-DE/AM/hs

Christian Heinrich Sandler GmbH & Co. KG, Lamitzmühle, 95120 Schwärzenbach

Plant substrate

The present invention relates to a plant substrate consisting of a fleece that mainly contains synthetic textile fibers.

In commercial plant cultivation, growing media have been used for some time to cultivate plants with small root space, replace contaminated soils and improve the control of growing conditions.

Porous, absorbent materials that store and conduct liquids are used as culture substrates. There are various requirements for such substrates. The main requirements are the highest possible structural stability, a high water and sufficient air capacity, a high sorption and buffering capacity and a favorable pH value.

Such culture substrates should also be as standardized as possible, free from weed seeds, pests and pollutants and, of course, inexpensive and easy to handle. Organic materials such as

Peat, straw, bark humus, cork, bark humus, mineral substrates such as sand and clay as well as synthetic substrates such as rock wool and foams.

Synthetic substrates are generally preferred because they are easy to manufacture in the form of sheets or blocks and these spatial forms are particularly easy to handle in a commercial plant cultivation operation. Synthetic substrates are also lightweight and easy to remove after use. A particular disadvantage of rock wool and foams, however, is the ecological behavior of these materials. They are particularly problematic when it comes to disposal.

Used rock wool substrates cannot be reused and cannot be subjected to thermal recycling, i.e. waste incineration. Organized disposal is problematic due to the high costs involved, as the used rock wool substrates require a large landfill volume due to their relatively low density and have a high biogenic content due to the roots not being able to be completely removed.

The foam substrates mentioned above can be thermally recycled, but the combustion gases released in the process require extensive post-treatment due to the nitrous gases or hydrogen cyanide gases that are produced. When disposed of in a landfill, the same problems arise as when depositing rock wool substrates due to the low density.

To overcome these disadvantages, plant substrates of the type described above have been proposed. Textile fibers, in particular those made of polyethylene terephthalate and/or its copolymers, polypropylene, viscose,

it · * ·

Cotton or polyamide, for example, are harmless to health, can be recycled and also thermally recycled, whereby the latter produces practically no problematic pollutants.

EP 0 440 033 B1 describes plant substrates made of textile fibers, whereby the disclosed nonwoven fabrics made of polyester or viscose fibers are consolidated using a water jet process. This process achieves a nonwoven fabric thickness of a maximum of 0.9 mm. The disadvantage of this plant substrate, however, is that due to the low substrate thickness, even low-growing plants hardly find sufficient support and often have to be supported. At least with medium and tall plants, there is insufficient plant stability and the plants have to be additionally supported. This represents an additional expense in terms of material and personnel.

DE-OS 44 41 328 describes a two-layer plant substrate, the upper layer of which consists of soil, humus or the like and the lower layer of which is made of a textile fiber recycling material, which can optionally be solidified and structured by a binding agent. The fiber material used is essentially cotton, which is supposed to slowly decompose during the life of the substrate, releasing nutrients. The two-layer structure of the plant substrate disclosed, in particular the use of humus or soil, makes it difficult to reuse the substrate and the decomposition that takes place is disadvantageous because it reduces the support that the plant substrate can offer the plants used; furthermore, the substrate compacts before

Decomposition and the release of nutrients occurs uncontrolled and unregulated.

The object of the present invention is therefore to create a plant substrate that avoids the disadvantages known from the prior art as far as possible, is inexpensive to produce and is easy and problem-free to recycle. Recycling here means both material recycling, i.e. the use of the used plant substrate to produce new fibers, nonwovens or other products, as well as thermal reuse.

This invention is achieved by a plant substrate of the type described above in that the plant substrate has a density of 6-60 kg/m^ and a thickness of 15 - 250 mm.

The plant substrate according to the invention has a high structural stability, a high water capacity and good water conductivity and a sufficient air capacity. In addition, it is able to store sufficient water due to its sorption capacity. Since it has a comparatively low density, it also advantageously provides improved oxygen transport in the direction of the roots. Possible applications include commercial vegetable cultivation, green roofs or as a hydroponic support in greenhouse cultivation, as well as ornamental plant cultivation.

It is preferred, but not absolutely necessary, if the plant substrate has a progressive density gradient from the top to the bottom, because this has the advantage that the initial root penetration of the

Planting substrate can be done easily and quickly due to the relatively lower density in the upper area of the planting substrate, while the relatively higher density in the lower area of the planting substrate provides the correspondingly grown plant with sufficient and improved support.

The plant substrate according to the invention advantageously has the form of mats or blocks, which are particularly easy to handle. This is of particular importance in commercial plant cultivation, since a plant substrate that is easy to handle can significantly reduce the required personnel expenditure. In comparison with other plant substrates, especially with pourable or free-flowing ones, this results in a very large cost advantage.

In a special embodiment, the plant substrate according to the invention has a cover on the top made of a water-permeable film. This is made of ordinary plastic films such as polyethylene and is preferably perforated or slit to ensure a certain amount of water can pass through. This cover serves the purpose of reducing the amount of water evaporating from the plant substrate, but watering can still take place through the film. Instead of the film, a thin covering nonwoven material, such as a spunbond or needle-punched nonwoven or the like, can also be used. The film or nonwoven can be connected to the nonwoven underneath by means of spot gluing, tacking, melting or needling, or it can enclose the nonwoven as a pocket or be laid loosely on top.

The film is preferably white or lightly pigmented. This keeps the root area dark, as is natural, and at the same time the heat radiation or reflection is influenced extremely positively, as this increases the

Temperatures in the substrate advantageously increase quickly compared to the environment and decrease more slowly than in the environment.

The fleece of the plant substrate is preferably made mainly of synthetic textile fibers made of polyester, polyester/copolyester bicomponent fibers, polypropylene or polyamide and/or mixtures thereof. These materials have the advantage that they are easy to reuse, have no adverse effects on the plants and are easy to process.

The fleece that forms the plant substrate is preferably thermally consolidated by means of binding fibers, binding agents or a combination of both, whereby in a particular embodiment of the plant substrate according to the invention, bicomponent fibers made of polyester and copolyester and/or bicomponent fibers made of polypropylene and polyethylene and/or homopolymer binding fibers are contained in the fleece. It is preferred that the binding fibers have a melting point that is at least 20 ^° C lower than the lowest melting fibers that are present in the fleece and are not binding fibers. It is also preferred that the proportion of binding fibers is 10 - 90% by weight of the total fiber content of the plant substrate.

The binding agent, which is also contained in the plant substrate alone or in combination with one or more of the aforementioned binding fiber types, is preferably formed by acrylic acid esters, polyvinyl acetates, ethylene vinyl acetates, butadiene styrenes and/or melamine resins. The binding agent content based on the fiber content is expediently 0-30% by weight.

In a particularly preferred embodiment of the present invention, the plant substrate is formed by a fleece that additionally contains hydrophilic substances. This further increases the ability to store water, which means that the plants have an increased amount of water available without them getting "wet feet". All substances that have the ability to store a minimum amount of water and can be incorporated into the fleece are suitable as hydrophilic substances. Such substances are generally known to those skilled in the art and are not restricted in any particular way as long as they do not have a detrimental effect on the plants, although viscose, cellulose or cellulose derivatives, polyacrylic acid derivatives and/or polyvinyl alcohol, individually or in combination with two or more of them, are preferred as hydrophilic substances. The greatest advantage arises when these hydrophilic substances are contained in the form of fibers and/or particles, because the hydrophilic substances can then be incorporated into the fleece production without an additional work step. However, other forms of hydrophilic substances can also be used. Cellulose derivatives can, for example, be dissolved and sprayed onto the finished fleece. However, the introduction of hydrophilizing substances in this way inevitably leads to the problem of a very inhomogeneous distribution across the fleece cross-section and additional work steps are required, some of which also require a high level of energy, as is the case with drying, for example.

In relation to the fiber structure, a maximum of 30% by weight of hydrophilizing substances is contained in the plant substrate. This allows the plant substrate to be adapted to the requirements or wishes of the user in terms of its ability to bind water, whereby a content of over 30% by weight is generally

offers no further advantage in terms of water storage capacity and, in addition, the susceptibility to microbes increases significantly.

The properties of the fibers that are not binding fibers are also not critical as long as they can be processed into corresponding nonwovens, although for such fibers a fiber titer in the range of 1.7 - 100 dtex is preferred.

The binding fibers are also not critical and are generally known to those skilled in the art. They are preferably used with a fiber titer in the range of 1.7 - 30 dtex.

The present invention is explained and described in more detail below using an embodiment.

Example:

A plant substrate consisting of 25% by weight polyester/copolyester bicomponent binding fiber with a fiber titer of 4.4 dtex and 75% by weight polyester fiber with a fiber titer of 28 dtex, a thickness of 30 mm and a basis weight of 260 g/ ^m2 (8.7 kg/m2) was tested in greenhouse cultivation for its suitability for growing crops. The greenhouse cucumber variety "Samara" was used as the test plant, which, like tomatoes or peppers, has the highest demands on the climate, water and nutrient supply and on the growing substrate. The plants were planted in the young plant stage at a planting density of 1.4 plants/ ^m2 . Irrigation was carried out by drip irrigation, with the water provided containing the nutrients required for plant growth.

In comparison with other types of substrate such as rock wool, perlite and expanded clay, the suitability of the plant substrate according to the invention for the cultivation of crops with high demands was shown, since in comparison with the conventional culture substrates used, no significant difference was discernible in the plants examined and in terms of yield. The cucumber plants took root well in the nonwoven fabric and the growth behavior was essentially the same as on other culture substrates.

The exemplary embodiment therefore clearly shows the advantages of the present invention compared to culture substrates known from the prior art. With comparable results (growth, harvest success), a material is therefore available that is easy to handle, simple to produce and easy to reuse or dispose of.

Claims (18)

&iacgr;&ogr; P 34.124-DE/AM/hs Christian Heinrich Sandler GmbH & Co. KG, Lamitzmühle,95120 Schwarzenbach Claims; 1. Plant substrate consisting of a fleece containing mainly synthetic textile fibres, characterised in that that the planting substrate has a density of 6-60 kg/m ³ and a thickness of 15 to 250 mm. 2. Plant substrate according to claim 1, characterized in that the plant substrate has a progressive density gradient from the top to the bottom. 3. Plant substrate according to claim 1 or 2, characterized in that it has a mat or block shape. 4. Plant substrate according to one of claims 1 to 3, characterized in that the plant substrate has a cover on the top side formed by a film or a thin nonwoven fabric 5. Plant substrate according to claim 4, characterized in that the water-permeable film is pigmented. 6. Plant substrate according to one of the preceding claims, characterized in that the fleece is mainly made of synthetic textile fibers made of polyester, polyester/copolyester bicomponent fibers, polypropylene or polyamide and/or mixtures thereof. 7. Plant substrate according to one of the preceding claims, characterized in that the fleece is thermally solidified by means of binding fibers, binding agents or by a combination of both. 8. Plant substrate according to claim 7,
characterized in that the binding fibers comprise bicomponent fibers made of polyester and copolyester and/or bicomponent fibers made of polypropylene and polyethylene and/or homopolymeric binding fibers. 9. Plant substrate according to claim 7 or 8, characterized in that the binding fibers have a melting point at least 20 ^° C lower than the lowest melting fibers which are present in the fleece and are not binding fibers. 10. Plant substrate according to one of claims 7 to 9, characterized in that the proportion of binding fibers is 10 - 90 wt.% of the total fiber content of the plant substrate. 11. Plant substrate according to claims 7 to 10, characterized in that the binders are acrylic acid esters, polyvinyl acetates, Ethylene vinyl acetate, butadiene styrene and/or melamine resins are included. 12. Plant substrate according to claim 11, characterized in that the fleece contains up to 30% by weight of binder, based on the fiber content. 13. Plant substrate according to one of the preceding claims, characterized in that the fleece contains hydrophilizing substances. 14. Plant substrate according to claim 13, characterized in that viscose, cellulose or cellulose derivatives, polyacrylic acid derivatives and/or polyvinyl alcohol are contained as hydrophilizing substances. 15. Plant substrate according to claim 13 or 14, characterized in that the hydrophilizing substances are contained in the form of fibers and/or particles. 16. Plant substrate according to one of claims 13 to 15, characterized in that hydrophilizing substances are contained in the fleece in a proportion of up to 30% by weight based on the fiber structure. 17. Plant substrate according to one of the preceding claims, characterized in that the fiber titer of the fibers that are not binding fibers is 1.7 - 100 dtex. 18. Plant substrate according to one of claims 7 to 17, characterized in that the binding fibers have a fiber titer of 1.7 - 30 dtex.