DE202006021265U1 - Biosynthetic substrate - Google Patents

Abstract

Biosynthetic substrate containing a cellulose fiber composite based on cellulose fibers and optionally at least one additive.

Description

The spreading of biosynthetic substrates, the z. B. the cultivation and cultivation of plants, or the areal spreading of seeds in practice still means a considerable effort and requires manual skills. To a large extent, the preparatory work to be done is to be assigned to the preparation of the seed areas. In addition, great care must be taken when incorporating the seed into the substrate or soil to achieve a consistent germination and growth result. Furthermore, care must be taken to adapt the nutrient supply and irrigation management to suit the different soil and substrate conditions. The optimal application of seeds places high demands on the external conditions and the skills of the user. Not all these conditions can always be met and are subject to great fluctuations due to a wealth of influences, which has great effects on the development of plants. The principle of the invention is based on providing a biosynthetic substrate. This is especially intended to combine a growing substrate with one or more further components, such as seed, soil improver, nutrient depot, etc., in one product.

The US 2004/0016527 A1 describes a multifunction paper with uneven surface for the cultivation of plants. The paper is used in the form of a thin film of preferably 0.2 to 0.3 mm thickness. Biosynthetic composites and especially seed carriers in the form of composite plates are not described in this document.

The DE 43 42 514 C2 describes recyclable or biodegradable waste paper extrudates, which in addition to recycled paper pulp biopolymers, plasticizable biotechnological residues and optionally contain other components. Due to the contained plasticizable biotechnological residues (digester effluents, separation residues, brewer's yeast, extraction pellets) and, if appropriate, additionally water repellents and / or mineral earths, these compositions have several months of service life in the soil. You should z. B. for mulching with the addition of antagonistically acting spore preparations for combating phytopathogenic fungi and with the addition of fertilizers suitable as long-term fertilizer. Biosynthetic composites and especially seed carriers are not described in this document.

The DE 689 03 955 T2 ( US 5,087,400 ) relates, inter alia, to a method for producing a composite product obtained by defibering wood chips or another wood cellulose-containing raw material, in which a fiber mixture is provided with an adhesive binder and cured. As the binder, polymerizable adhesives such as urea-formaldehyde resins are preferably used. The resulting products thus necessarily contain adhesive dots of a water-insoluble cured polymer. This composite product should be suitable for the production of plant carriers used outside the soil. In a concrete embodiment, the planting carrier is surrounded by a foil which retains liquids. Thus, holes can be left in the plant carrier for planting the seedlings and a nutrient fluid filled to provide the plants with nutrients. This document does not describe plant carriers in which a biosynthetic substrate is applied directly to the natural soil. This document also does not describe plant carriers which consist of a biosynthetic substrate containing a seed contained therein.

The object of the present invention is to provide a biosynthetic substrate which makes it possible to apply nutrients, substances for soil improvement and / or seed in an even and uniform manner, and which can serve as a peat substitute and / or unify the germination conditions in the form of a seed carrier ,

Accordingly, there has been found a biosynthetic substrate containing a cellulose fiber composite based on cellulose fibers.

The biosynthetic substrate according to the invention makes it possible to combine nutrient components, additives and, if appropriate, seed in a product which, because of its construction, permits the planar, uniform application and uniformizes the germination conditions. It is thus particularly advantageous as peat substitute and as a seed carrier. If desired, substrates which serve as peat substitute material or as artificial topsoil can also be applied in a spreadable (that is to say non-plate-like) form. On the other hand, the seed is preferably introduced into a planar, preferably biosynthetic substrate body and can preferably be laid dry on the seed surface in the form of plates. After a washing process, the applied peat substitutes or the plates swell and act as a growth substrate, soil conditioner, water and nutrient storage.

A special version are composite panels, the z. B. serve for the application of nutrients, z. B. as peat substitute. Another special design is seed carriers for simplified sowing of seeds with simultaneous soil improvement, fertilization and water storage, for agriculture, garden landscaping, crop cultivation and other seed areas.

According to the invention, so-called biosynthetic substrates and especially seed carriers are produced from natural, basic and residual materials from industry and from substrate and soil production, which are designed to be used dry or swollen onto the seed surface in the desired shape. The production of the composite mass for composite plate or seed carrier production is carried out according to the respective requirements of the seed area, according to meteorological, geographical and economic criteria.

Consequently, the main constituents of the seed carrier composite are designed variably according to the conditions of determination and use. The basic structure is preferably made of cellulose fiber composites, since these are refined from by-products and waste products of the cellulose-processing industry, and thus represents an excellent recycling economy.

The biosynthetic substrates according to the invention contain a fiber composite material which contains as main component cellulose fibers, a so-called cellulose fiber composite. Polymers are widely used in nature and perform a variety of functions there. Their chemical composition and structure is diverse, including, but not limited to, polynucleotides (nucleic acids), polypeptides (proteins) and polysaccharides. Among these biological polymers, the polysaccharides, and in particular the cellulose, occupy an outstanding position. Cellulose is the most abundant biological polymer. The morphological structure consists of small crystals, the so-called microfibrils, which are surrounded by disordered areas. In this sense, cellulose itself can already be considered as a composite material. Cellulose occurs in the cell walls of all plants as a structuring material in which it is used as a main component together with other biological polymers, eg. As strengths, a composite material forms. The structure of the characteristic composite structure of the cellulose structures is the prerequisite for the preparation of the substrates according to the invention and peat substitutes. In particular, the fibrillar portion is important for the performance properties of the products according to the invention.

As cellulose such different origin can be used, for example, cellulose can be used from non-lignin sources such as cotton or from ligninhaltigen sources such as wood, wherein the cellulose used z. B. wood cellulose can be partially or completely freed from lignin before use.

The lignin removal (delignification) of lignocellulosic cellulose sources can be carried out by customary methods known to the person skilled in the art. This includes the treatment with oxidants, such. As oxygen, ozone, H ₂ O ₂ , peroxides (eg., Na ₂ O ₂ ), peracids (eg, peracetic acid), etc. The subsequent dissolution of the lignin units is preferably carried out in the alkaline, z. B. with aqueous bases.

For the production of the cellulose fiber composites lignin-free cellulose fibers are preferably used. In particular, the use of all types of paper sludge is preferred.

Cellulose fibers from the paper industry, the paper processing industry, textile, wood or vegetable fiber processing or the forest industry can be used to produce the cellulose fiber composite. Also suitable are sludges containing cellulose fibers. As cellulosic base materials for the production of these cellulose fiber composites also fiber compositions from waste paper processing and from wood fiber utilization can serve as a raw material. Also possible is the use of crude cellulose, as it is obtainable by the known production process from wood and vegetable fibers as starting material. It is also possible to use other cellulosic natural fibers such as flax, hemp, sisal, jute, straw, coconut fibers, and other natural fibers.

The substrates according to the invention are preferably in the form of plates or moldings having a substantially rectangular base area (plate-shaped or block-shaped). Their length is preferably in a range of 5 cm to 250 cm, more preferably 10 cm to 200 cm. Their width is preferably in a range of 5 cm to 250 cm, more preferably 10 cm to 200 cm. Its thickness is preferably in a range of 5 cm to 250 cm, more preferably 10 cm to 200 cm. A suitable standard pallet size is z. B. 80 × 120 cm.

A preferred embodiment is a plate-shaped substrate having a thickness in a range of 1 to 40 cm, preferably 5 cm to 30 cm.

The plate-shaped substrates are advantageously dimensionally stable. They are distinguished from foil-shaped substrates and extrudates described in the prior art. The plate-shaped substrates may, for. B. as peat substitute material or seed carriers are placed on an optionally prepared bottom surface, so that a closed surface is formed. The area occupied by the plate-shaped substrates can be watered after application. By contact with moisture from the soil or after washing, the plate-shaped substrates swell and form a uniform substrate surface. Perhaps contained seeds begin to germinate. The result is a homogeneous, uniformly overgrown surface with an already optimal nutrient and water supply. The use of peat substrates and seed carriers according to the invention is particularly suitable for greening of large areas such as lawns and meadows, but also fields and greenhouse crops etc.

In a specific embodiment, the substrates of the invention are in two or more layers, z. B. 3-, 4-ply form before. The two- or multi-layer substrates have z. B. a base plate and at least one functional plate, which has at least one further ingredient relative to the base plate. The further ingredient is z. B. selected from additives, microorganism preparations, seeds and mixtures thereof. The two-layered or multi-layered substrates can have a grid or fabric as a further layer or in one layer. It may be a weatherproof material, eg. As a corrosion-resistant metal or a plastic-coated metal act. These grids or fabrics, which usually form the bottom-side plate or incorporated in the bottom-side plate, serve to protect against pests, such as moles, voles, etc., and / or to improve the mechanical stability. Special versions of multilayer seed carrier plates show the following 1 and 2 ,

• – 80 bis 100 Gew.-%, vorzugsweise 85 bis 99 Gew.-%, Cellulosefaserkomposit,
• – 0 bis 20 Gew.-%, vorzugsweise 1 bis 15 Gew.-%, wenigstens eines Zuschlagsstoffs,
• – 0 bis 5 Gew.-%, vorzugsweise 0,01 bis 2,5 Gew.-%, wenigstens einer Mikroorganismenpräparation.

The substrates according to the invention preferably contain:

• From 80 to 100% by weight, preferably from 85 to 99% by weight, of cellulose fiber composite,
• From 0 to 20% by weight, preferably from 1 to 15% by weight, of at least one aggregate,
• - 0 to 5 wt .-%, preferably 0.01 to 2.5 wt .-%, of at least one microorganism preparation.

The cellulose fiber composite preferably comprises cellulosic fibers as the base material and optionally at least one binder, as defined below. Suitable additives are preferably selected from among nutrients, water-storage materials, cellulosic fiber derivatives other than binders, fillers, excipients, and mixtures thereof. A preferred embodiment are seed carriers which additionally contain at least one seed.

The Celullosefaserkomposit preferably has a residual water content in the range of 0 to 50 wt .-%, preferably 1 to 30 wt .-%, based on the total weight of the substrate on.

• – Cellulosefasern,
• – wenigstens ein Bindemittel,
• – gegebenenfalls wenigstens einen Nährstoff,
• – gegebenenfalls wenigstens einen Wasserspeicherstoff,
• – gegebenenfalls wenigstens ein Cellulosefaserderivat,
• – gegebenenfalls wenigstens einen Füll- und/oder Hilfsstoff,
• – gegebenenfalls Mikroorganismen,
• – gegebenenfalls Wasser.

Preferred is a biosynthetic substrate containing

• Cellulose fibers,
• At least one binder,
• Optionally at least one nutrient,
• If appropriate, at least one water-storing substance,
• Optionally at least one cellulose fiber derivative,
• If appropriate, at least one filling and / or auxiliary substance,
• - optionally micro-organisms,
• - if necessary water.

nutrient

Depending on the requirements, the nutrients used for the production can be adapted in variable parts. In addition to the nitrogen, potassium, phosphate and magnesium fertilizers, trace substances and organic nutrient carriers are also used. The nutrients are then preferably selected from nitrogen fertilizers, phosphate fertilizers, potash fertilizers, calcium fertilizers, magnesium fertilizers, calcium fertilizers, sulfur fertilizers, mineral complex fertilizers, trace nutrients and mixtures thereof.

Preferred nutrients are:

Mineral fertilizers:

• Nitrogen fertilizer: Fertilizers containing nitrogen as the main constituent. In mineral fertilizers, the nitrogen can be present in the basic forms nitrate, ammonia or amide. Suitable Nitrophoska and similar products.
• Phosphate fertilizer: Thomas phosphate, Thomas flour, aluminum calcium phosphate (cadmium content at most 90 mg / kg P ₂ O ₅ , soil pH> 7.5), soft rock phosphate (cadmium content at most 90 mg / kg P ₂ O ₅ ), soft rock phosphate with magnesium, Raw phosphate with carbonate of magnesium lime. Suitable products: Hyperphos 26, grained, Hyperphos 31, fine, Hyperphos-Magnesia 22 + 7 Dolophos.
• Potash fertilizers: potash salt (eg kainite, sylvinite, etc.), magnesium salt-containing potassium sulfate, potash crude salt, magnesia kainite, patent potassium (kalimagnesia).
• Calcium fertilizer and magnesium fertilizer: carbonate of natural origin (eg chalk, marl, limestone powder, algal lime, phosphate chalk, etc.), calcium and magnesium carbonate (eg magnesium lime, magnesium limestone powder), rock flour, industrial lime from sugar production, carbonate lime ( carbonate of lime), carbonate of lime with added peat, carbonate of seaweed, carbonate of lime with sulfur (carbonate of magnesium lime with sulfur), calcium sulphate of natural origin, carbonate of lime with softened rock phosphate ( carbonate magnesium lime with soft-crusted rock phosphate), magnesium rock flour, carbolic lime, natural lime (carbonate lime, carbonate of magnesium lime), north-white pearl garden lime, granucalk, natural lime dolomite, natural lime, Jurassic grain, Kamsdorf Mg marl, AZ carbohydrates, TIMAC T 400g , TIMAC T 400p, sheath lime.
• Calcium, magnesium and sulfur fertilizers (secondary nutrient fertilizers): calcium chloride (also as a solution), magnesium sulphate (eg kieserite, ESTA kieserite fine, ESTA kieserite 'gran'), elemental sulfur, sulfur from natural sources, calcium sulphate (gypsum) , in different degrees of hydration from natural sources), Epsom salts.
• Mineral Complex Fertilizers: Broad spectrum fertilizers based on ion exchangers, liquid broadband fertilizers, broad-spectrum fertilizers in powder form, organic and organic mineral fertilizers, bone meal, deboned bone meal (taken as a mineral fertilizer for its composition), horn shavings / horn meal.
• Micro-nutrient fertilizers: fertilizers containing only micro-nutrients as their constituents (chelates as DTPA, EDTA or EDDHA).
• Bordünger: trace nutrients, according to Directive 89/530 / EEC , Boric acid folicin boron (17.5% B), VYTEL liquid boron (10.9% B), BIESTERFELD liquid boron (10.9% B), sodium borate, calcium borate, boroethanolamine, onion fertilizer solution, boron fertilizer Suspension, Solubor DF (17.4% B), Solubor (20.8% B), Liquibor (11% B), Borax (11% B), BIESTERFELD boron 21-P (21% B), BIESTERFELD Boron DF (18% B), folicin boron liquid (11% B), cobalt salt, cobalt chelate, cobalt fertilizer solution.
• Copper fertilizer: copper salt, copper oxide, copper hydroxide, copper chelate, Cu-oxichloride, Cu-oxichloride suspension, Cu-based fertilizer, copper fertilizer solution, copper sulfate (25% Cu), copper questuran (50% Cu), folicin-Cu (14% Cu) , VYTEL liquid copper (7% Cu), BIESTERFELD liquid copper (7.1% Cu).
• Iron Fertilizer: Iron Salts, Iron Chelates, Iron Fertilizer Solution, Iron Sulphate (20% Fe), Flory 71 (13% Fe), Flory 72 (6% Fe), Flory 73 (11% Fe), Fetrilone (13% Fe), Sequestren ( 6% Fe), Folicin DP (6% Fe), BIESTERFELD Iron 10 FL (7.7% Fe).
• Manganese fertilizers: manganese salts, manganese chelates, manganese oxide, manganese fertilizer solution, manganese sulfate (eg 25% Mn or 31% Mn), VYTEL-MANGRO 150 FL 10.95% Mn, 195-Super Liquid Manganese (13% Mn), Folicin-Mn (13% Mn), folicin-Mn liquid (6% Mn), VYTEL liquid manganese (6% Mn), VYTEL Mn super granules (13% Mn), BIESTERFELD liquid manganese (6% Mn).
• Molybdenum Fertilizer: Sodium molybdate (eg, 40% Mo), ammonium molybdate, molybdenum fertilizer solution, sodium molybdate, folicin-Mo (39.6% Mo).
• Zinc fertilizers: zinc salts, zinc chelates, zinc oxide, zinc fertilizer solution, zinc sulfate (23% Zn), folicin-Zn (15% Zn), VYTEL liquid zinc (7% ZN).

As additives suitable soil additives are z. For example: rock flour, clay (perlite, vermiculite), bentonite, montmorillonite, biolite (diabase rock flour), SKW-MAHLE ^® rock salt, Neudorff's ^® rock salt, Eifelgold (fine-bubble basalt slag), volcanine (phonolite flour) and mixtures thereof.

Other suitable aggregates are soils, peat, compost, dyes, flavors, natural fibers (unless used as binders), etc.

Other possible additives are the additives specified in the applicable Fertilizers Ordinance.

The coordination of the composition of the composites and of the aggregates takes place in compliance with the applicable directives, ordinances and laws for the respective area of application. Contrary to these standards, it is possible to produce substrates for research and study purposes as well as for limited use or with the approval of the authorities. For the production of the seed carrier body a rating according to the Fertilizer Ordinance is not mandatory.

microorganisms preparation

The biosynthetic substrates of the invention may contain a microorganism preparation. In general, this microorganism preparation is used in an amount of 0 to 5% by weight, preferably 0.01 to 2.5% by weight, based on the total weight of the substrate. The microorganism preparation used according to the invention may contain or consist of one or more microorganisms and / or products derived therefrom, such as enzymes. Suitable microorganisms are z. Bacteria, yeasts, etc. The enzymes can be used in (partially) purified form. Methods for the recovery and purification of enzymes from microorganisms are well known to those skilled in the art. The microorganisms or enzymes can be used freely (ie in native form or as spores) or immobilized. An immobilized enzyme is an enzyme which is fixed to an inert carrier. Suitable support materials are, for example, clays, clay minerals, cellulose and synthetic polymers. The amount of microorganism preparation to be added depends on the nature and activity of the microorganisms contained, or Enzymes off. The optimal amount of enzyme for the reaction can be easily determined by simple preliminary tests. The microorganism preparation used according to the invention may additionally contain one or more nutrients and optionally a solvent, generally water.

For adaptation to microorganisms live or dry cultures can be used with regard to their intended use. These are microorganisms, preferably Bacillus subtilis or others, useful for promoting growth development or improving soil conditions, or others as required to reduce harmful microorganisms or fungi or to promote growth characteristics. Bacillus subtilis displaces the formation of decay and mold. Rhizobacteria colonize the milieu of the hair roots and lead to a significantly improved resistance to rhizome damage. Overall, a nutrient absorption improvement is achieved with the adaptation of these eubacteria. Rhizobacteria are symbionts of legumes and have nitrogen-binding ability. Thus, the absorption and utilization of atmospheric nitrogen is thereby improved. Also suitable are the metabolism-promoting bacteria in order to improve the usability of the bound nutrients, preferably in the organic fraction, as well as phosphatase-producing bacterial strains. These result in the nutrients being metabolized and absorbed efficiently, thus significantly reducing the amount of nutrients used compared to conventional fertilization.

hydrogels

By adding so-called hydrogels, the water absorption capacity of the substrate can be controlled. The adaptation of the hydrogels has the primary goal of controlling the water management. This allows the finished product to be precisely adjusted to the respective irrigation conditions. For this purpose, preferably high molecular weight homo- and copolymers with hydrophilic groups, eg. B. used based on acrylic acid. These include copolymers of sodium acrylates and crosslinked acrylic acid polymers. Preference is given, for example, homopolymers of Novus HM Terrabalance ^®, since they are degraded by little to sodium citrate in the soil. But also polymers based on polyacrylamide z. B. Stockosorb ^® Fa. Degussa / Stockhausen GmbH are suitable for use in composite, but show u. U. unfavorable degradation behavior that should be considered in the use. Due to the structural integration of hydrogels, the water storage capacity can be increased from 100% of the starting material to 100 times the dry weight of the substrate. However, application-related loading capacities of less than 4 m ^{3 of} water per 1 m ^{3 of} substrate under soil loading are customary.

binder

The composites of the invention can be stabilized with binders in their mixture structure. Binders are useful if they achieve a temporary or permanent structural stability of the substrate. Suitable binders of the cellulosic fibers used as the base material are various celluloses and cellulose derivatives. Suitable cellulose derivatives are cellulose esters or cellulose ethers. These include z. As carboxymethylcellulose (glycolic acid ethers of cellulose, usually as Na salt), hydroxypropylcelluloses (cellulose ethers, which are obtainable by reaction of alkali metal celluloses with propylene oxide), methylcellulose (cellulose methyl ether, by reacting cellulose with methylating agents, such as dimethyl sulfate, methyl chloride or methyl iodide available), cellulose acetates, cellulose propionates, cellulose butyrates, cellulose acetate propionates or cellulose acetate butyrates. Also suitable are starch and starch derivatives. Preferably, carboxymethylcellulose, hydroxypropylcellulose, hydroxypropylmethylcellulose, methylcellulose and mixtures thereof are used. Also, polymeric, biodegradable, synthetic and natural binders such. As acrylic derivatives or resins and tree resins, are usable. With the admixture of binders in powder form or dry rock flours, the strength of the structural stability can be controlled to a defined, z. B. crumbly or produce a plastically formable pattern structure. For further processing into composite plates, the most plastic matrices are produced.

The binders used according to the invention are preferably biodegradable. Under biodegradability is understood z. B. after DIN V 54900 in that polymeric binders disintegrate under environmental conditions in a reasonable and detectable period of time. According to the invention, the preparation of the composite matrix as in 3 summarized shown.

The production of the composite material can be carried out according to the methods described below. These are also the subject of the invention. The preparation generally comprises the steps of homogenizing, shaping and adjusting the water content. For this purpose, the raw materials, cellulose masses or sludge are homogenized in a mixing plant and mixed with the additives. Aggregates may be the aforementioned, in particular: organic fertilizers, inorganic fertilizers, minerals, chippings, wood fibers, composts, dyes, flavors, polymers, hydrogels as well as microorganisms as live cultures or spores. Depending on the application, the aggregates may be contained in variable proportions in the finished substrate or missing. The raw materials are further processed with the composites by the use of binders, preferably methylcellulose, to a fibrous, uniform mass. With conventional drying devices, eg. As thermal or eddy current drying method, the desired residual water content is set.

The composite matrix produced by the process described is further processed in further processing steps to form the desired composite bodies. For this purpose, preferably chamber filter presses or rolling mills with subsequent thermal residual dewatering are used. In chamber filter presses, the matrix is pressed into the filter chambers. The chambers consist of several horizontally successive filter plates. The plates are on both sides with different fabrics made of cotton, plastics, sintered metal u. a. covered. In between, filter frames of the same size are arranged in which the matrix to be dehydrated is filled. The size and shape of the filter frames used determines the later shape of the composite panels. This is pressed through the filter cloth in the adjacent filter plate. The filter cake can be removed from the fabrics while the excess liquid drains down. The extracted Rohkompositplatten are then fed to the residual drainage. The residual dewatering is preferably carried out thermally, while the binders contained in the composite are solidified, so that a solid, dry plate is formed. Depending on the intended use, the plates may have different shapes and sizes. Also, the degree of compaction can be adjusted with the variation of the press pressure to the desired level. High pressure means very dense plates with low residual water content. Low pressure produces plates of lower density but with correspondingly higher residual water content. The production of plates of lower density is therefore always at the expense of residual drainage.

A continuous process for producing solid composite panels is the rolling / drying process. For this purpose, the plastically deformable raw material is applied by means of screw conveyance via a nozzle on a conveyor belt as a homogeneous strip. The width of the feed nozzle determines the width dimension of the later plate. With the subsequent arrangement of horizontal rolls and counter rolls, the pasty matrix is formed and dewatered. Feed quantity, feed rate and roll distances determine the shape, the residual water content and the density of the later composite board. After rolling the raw matrix, the composite strip is conveyed through a tunnel kiln to achieve complete drying. After drying, the endlessly produced strips are cut to the desired level by means of a cutting device. In this way continuously uniform, uniform plates are created. Plates with still too high residual water content are then stored in drying chambers.

The production of the seed carrier plates from the composite plates is preferably carried out in three ways. Thus, the seed can be added with the same into the matrix of Rohkomposits. In this variant, however, the mechanical, biological and thermal load of the material is very high, pressure and temperature conditions must be met very accurately. In addition, the processing speed must be so high that the seed does not start the germination process. It is better, after a second variant (see 1 ), two plates [ 1 . 3 ] in which the seed is mixed with binders [ 2 ] is introduced in a horizon. A third variant (see 2 ) is the application of a composite / seed mixture [ 5 ] on a dry base plate [ 6 ] and then pressing the paste with the base plate. All variants produce seed carrier plates that contain germinable seeds. Grids or fabrics may be applied to the underside of the seed carrier plates to protect them from moles, vole, etc. [ 4 ] respectively. [ 7 ].

The application of the composite seed carrier is intended primarily in the horticultural and landscaping sector, but also in the cultivation of crops and crops, a use is conceivable. In principle, any type of seed can be incorporated into the composite seed carriers. In practice, the seed carriers are placed on the prepared seed surfaces, so that a closed surface is formed. The area occupied by the seed carriers is then thoroughly watered. After rinsing, the seed plates swell to a uniform substrate surface and the seeds begin to germinate. The result is a homogeneous, uniformly overgrown surface with an already optimal nutrient and water supply. The use of composite seed carriers is particularly suitable for greening of large areas such as lawns and meadows, but also fields and hothouse crops etc.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 2004/0016527 A1 [0002]
• DE 4342514 C2 [0003]
• DE 68903955 T2 [0004]
• US 5087400 [0004]

Cited non-patent literature

• Directive 89/530 / EEC [0025]
• DIN V 54900 [0034]

Claims (25)

A biosynthetic substrate comprising a cellulose fiber composite based on cellulose fibers and optionally at least one additive. A substrate according to claim 1, which has a residual water content in the range of 1 to 30 wt .-%, based on the total weight of the substrate. Substrate according to Claim 1 or 2, cellulose fibers from the paper industry, the paper processing industry, the textile, wood or vegetable fiber processing or the forest industry being used for the production of the cellulose fiber composite. Substrate according to Claim 3, cellulose fibers from the paper industry or waste paper processing being used for the production of the cellulose fiber composite. Substrate according to one of the preceding claims, lignin-free cellulose fibers being used for the production of the cellulose fiber composite. A substrate according to any one of the preceding claims in the form of a spreadable peat substitute. Substrate according to one of the preceding claims in the form of a composite plate or a seed carrier. A substrate according to claim 7 having a length in a range of 5 cm to 250 cm, a width in a range of 5 cm to 250 cm and a thickness in a range of 5 cm to 250 cm. A plate-shaped substrate according to claim 8 having a length in a range of 5 cm to 250 cm, a width in a range of 5 cm to 250 cm and a thickness in a range of 1 cm to 40 cm. Substrate according to one of the preceding claims in two or more layers. Substrate according to one of the preceding claims, comprising a horizontally embedded or applied grid or tissue. Substrate according to one of the preceding claims, comprising From 80 to 100% by weight of cellulose fiber composite, 0 to 20% by weight of at least one aggregate, - 0 to 5 wt .-% of at least one microorganism preparation. Substrate according to one of the preceding claims, comprising Cellulose fibers, At least one binder, Optionally at least one nutrient, If appropriate, at least one water-storing substance, Optionally at least one cellulose fiber derivative, If appropriate, at least one filling and / or auxiliary substance, - optionally micro-organisms, - if necessary water. Substrate according to one of the preceding claims, in the form of a seed carrier containing at least one seed material. Substrate according to claim 14, wherein the seeds are contained horizontally, in a composite in one plane, or homogeneously distributed. Substrate according to one of the preceding claims, which has a loading capacity of at most 4 m ^{3 of} water per 1 m ^{3 of} substrate under Bodenauflast. A substrate according to any one of the preceding claims, each containing 5 to 95% by weight, based on the total weight of the product, of a component selected from natural substrates, soils, peat, natural fibers other than cellulose fibers and mixtures thereof. Substrate according to one of the preceding claims, containing at least one hydrogel. Substrate according to one of the preceding claims, containing at least one microorganism. Seed carrier according to one of the preceding claims, wherein the composition of the substrate constituents is stabilized with binders and forms a homogeneous structure. Seed carrier according to one of the preceding claims having the properties to increase the yield of crops and / or to achieve efficient use of nutrients and / or to allow improved growth of crops and ornamental plants, with the nutrient and water supply management with the variation of the aggregates is adjustable. Seed carrier according to one of the preceding claims having the property to reduce the resistance to harmful influences, such as diseases and weaknesses, wherein the seed carriers contain protective or tonic agents and active substances for healing. A seed carrier according to any one of the preceding claims having the property of reducing the burden of groundwater and pore water by the nutrient holding capacity of the composite, the seed carrier containing nutrient depots. Seed carrier according to one of the preceding claims with the property that due to the stabilized nutrient binding in the composite plants no longer need to be fertilized additionally, the seed carriers containing retardant nutrient carriers. A seed carrier according to any one of the preceding claims, having the property of preventing moles and vole from breaking through, the seed carriers being provided with a horizontally embedded or applied fabric or mesh.

Images