DE102009034137A1 - Liquids storing and expandable composite material and its production and application - Google Patents

Abstract

The present invention relates to a composite material, in particular a composite material designed as a shaped body and / or suitable for the production of shaped bodies, consisting of polymer materials and a matrix of brown coal and / or xylitol, which by the action of liquids, in particular by aqueous liquids and / or aqueous oil emulsions expands and stores these liquids and is characterized in that it contains brown coal and / or xylitol and at least one hydrogel-forming natural and / or synthetic cross-linked and / or partially cross-linked polymer and / or copolymer.

Description

Technical area

The The present invention relates to a composite material, in particular a formed as a shaped body and / or for the production composites suitable composite, consisting from polymer materials and lignite and / or lignite xylitol by the action of liquids, in particular by aqueous liquids and / or aqueous oil emulsions expands and stores these fluids. Preferably The composite material is for use as a soil conditioner product with long-term water storage effect. Be under composite material hereinafter not only finished products, but also intermediates understood, such as composite materials, which for the production of finished products and / or preferably for treatment and / or Incorporation into natural soil and soil substrates and / or Soil and earth structures, in particular for the improvement of soil structures and / or increasing the water storage capacity are provided by dry soil.

About that In addition, the invention includes various embodiments and compositions that allow it for specific applications in each case corresponding combinations of the composite material according to the invention manufacture and use. Furthermore, the invention relates a process for the preparation of the invention Composite material and its preferred applications.

State of the art

It it is known that crosslinked polyacrylic acids and / or copolymers based on polyacrylic acid, in the relevant Technical literature described under the generic term polyacrylates, in particular in their salt form, are capable of many times their own weight on water, aqueous liquids and also oil-water dispersions and / or suspensions and, to form hydrogels, to bind. Polyacrylic acid is a colorless substance that dissolves well in water. The glass transition temperature is> 100 ° C. Above 200 ° C to 250 ° C, the polymer loses Water, resulting in insoluble crosslinked anhydrides. From about 350 ° C it comes to decomposition to carbon dioxide and Hydrocarbons.

For The production of polyacrylic acid can be various Be used method, usually the solution polymerization in water, precipitation or emulsion polymerization, but also the hydrolysis of acrylic acid derivatives (esters, Nitriles, amides) has become more important. A particularly large range of properties is through copolymerization possible with other comonomers. polyacrylic acid is offered as a commercial product in the acid or salt form.

networked or partially crosslinked polyacrylic acids as potassium or sodium salt the polyacrylic acid are preferably as extremely liquid absorbent, so-called superabsorbent polymers (hereinafter referred to as SAP or superabsorber) used, for example in Baby diapers or sanitary napkins. Other applications are in the Packaging moisture-sensitive or liquid secreting food or as gel formers in drug manufacturing. SAP is networked for all these uses and / or partially crosslinked form. The networking is necessary to ensure the insolubility of SAP in water. The gaps and cavities of the network will be filled by water. This creates a hydrogel.

superabsorbent can absorb many times their own weight in water, whereby they swell to a hydrogel. Polymer chains, especially of polyacrylic acid, are characterized by scattered covalent bonds linked together. This easy networking is necessary to ensure the insolubility of SAP in water. A hydrogel is one in water or in aqueous fluids swollen, hydrophilic polymeric network. The properties of this Gels are dependent on the interaction between network and the surrounding liquid. In ionic gels must the osmotic contribution of the ionic groups is taken into account become the major influence on the swelling properties the gels has.

To the For example, in a polyacrylic acid gel, the acrylic acid groups arranged in close proximity to each other. The same Charges of the dissociated carboxylate groups are encountered The polymeric chains stretch and the gel swells in extreme Way. Such networks can hold up to 1000 grams of water take up per 1 gr of polymer. Because of these product features crosslinked polyacrylic acids are referred to as superabsorbent.

It was now obvious to use the water binding capacity of the SAP, that these as Was In dry soils, it is particularly important to regulate the water balance in hot climates and to ensure that the water required for plant growth does not quickly evaporate and is bound for a longer period of time and can be released to the plants ,

Here are manifold in the relevant technical and patent literature Application examples and studies, especially in the last ten years, been published. Basically, always will recommended that SAP use appropriate mechanical devices is incorporated into the soil structure.

adversely However, because SAP tend to stick and tend not a planter structure itself have that, for example, when used in desert areas Although water is bound in the desert sand bottoms but no structure is given or achieved, which is a successful one Planting allows.

conditioned and with sufficient effect, SAP can only be applied if they are already incorporated in soil substrates, whose structure is suitable for planting with crops. in addition comes that SAP give the bound water sometimes very difficult and thus not for plant growth, as desired, is available. Furthermore, to achieve an effect relatively large amounts of SAP required, their use therefore very expensive.

by virtue of These disadvantages have been the application of SAP on the basis of Acrylic acid polymers and other polymers in this area so far can not enforce.

In More recently, products have been made known to remedy this situation should. In these products, for example, in the polymer introduced fine lava powder and incorporated into the polymer.

Such SAP, their manufacture and application areas are for example in WO2003000621 A1 described. Although the application of such filled with lava stone or similar, porous rocks and / or rock flour SAP bring improvements in the application but it is usually spongy, coarse-grained granules that are sticky on the surface and can cake together under pressure. These granules are reminiscent in their consistency of porous rubber granulate. The production of fine granules, which have an earth-like structure, are not possible with this method.

These Products are also due to the complex manufacturing process very expensive. This is their use in dry and desert areas only possible with very high costs and thus economically uninteresting.

Further there are serious disadvantages with the use of such SAP, that when evaporating the water from these SAP the so-called Soil improvers become rock hard and are dehydrated forming mold in appearance and its hardness on pebbles remembered and thus by no means contributes, in particular when applied in the surface area, the soil structure to improve. There is a risk that delicate plant seedlings be crushed.

In the EP0647093B1 It is suggested that the matrix of porous foamed hydrophilic and hydrous hydrogel material which comprises open cells be added as a porous expanded mineral, perlite or vermiculite. The resulting porous, sponge-like structures are indeed suitable as a carrier material with water storage effect for the propagation of plants, but not as a soil improvement product with long-term water storage effect.

It is known and extensively documented by relevant patents, scientific publications, technical literature that based on lignite and / or lignite xylitol soil improvement products and fertilizers can be built. For example, let's look at the writings and publications EP0504644 A1 and DE19825168A1 such as DE10120433C1 directed.

In other patents (eg, published patent application 26 03 771, DE 4137 171 A1 . DE 195 11 319 A1 ) describes the mixing of brown coal with nutrient-rich inorganic substances

About that In addition, potting soils and products are known which are used as soil improvement products and modified, partly modified by chemical treatments Late Tertiary Lignite and / or Lignite Xyilt contained or built on these natural resources are.

For the structure of these known soil improvement products and fertilizers As described, lignite and lignite-xyilt are used or suggested as these base substances in large quantities incurred during the day mining of lignite.

The World production of lignite, with its processing about 15% of the total amount of lignite xylitol accumulates is currently at about 900 million tons per year. The depletion reserves, So the deposits are being transferred to worldwide 280 billion tons figured. Estimated over 90% of the mined lignite is used for energy production.

Brown coal, Lignite and lignite xylitol is defined as follows and described and subsequently named lignite or xylitol, this regardless of an exact definition due to the natural fluctuations and the different periods of origin, the origin and thus different composition not possible is. The usual classification of brown coal types in Lignite, hard lignite, matte lignite and lignite depends on the rising content of carbon and is only a rough type classification.

Prefers for the inventive use is the so-called Lignite from the early Tertiary period and also the use and / or addition of Leonardite. Leonardite is a soft brown coal layer that has not yet reached the stage of Lignite has reached and is characterized by a particularly high content characterized by humic substances and a high degree of oxidation.

The transitions from Leonardite to Lignite are fluent and Leonardite is thus in this application, in the description and in the Claims associated with the brown coal.

Of the The origin of brown coal goes back to the plant world and the peat bogs created millions of years ago, several times were covered by sea sands and river torrents and by the process of incineration of the most diverse species led by Braumkohle. The main components of the natural product Lignite, based on crude lignite, is about 55% water, 40% Carbon and a total of about 5% mineral trace elements, organic sulfur, nitrogen and humic substances. A lignite can, depending on the degree of coalification, 15% or more, based on the Dry matter, containing xylitol.

Lusatian soft lignite index average values Analytical values of dried, treated lignite dust. granulation Residue to 0.20 mm Weight% 13.0 Residue on 0.09 mm Weight% 40.0 water content Weight% 10.5 ash content Wt.% 6.0 Fixed carbon Weight% 38.0 elemental analysis carbon Weight% 56.5 hydrogen Wt.% 4.0 oxygen Weight% 21.5 nitrogen Weight% 0.9 Sulfur, total Wt.% 0.7 Oxide analysis of the ash according to DIN 51729 SiO ₂ Weight% 12.0 Fe ₂ O ₃ Weight% 26.0 Al ₂ O ₃ Weight% 4.5 SO ₃ Weight% 22.0 CaO Weight% 29.0 MgO Weight% 5.0 Na ₂ O + K ₂ O radical Weight% 1.5

xylitol is found in brown coal deposits and is in the process of development separated from the lignite. Xylitol, formerly known as lignite, is not completely carbonated wood or plant material. Its chemical properties are close to that of peat and the pH is slightly acidic and the structure is fibrous. The proportion of organic matter is over 85% on the dry weight. The water retention capacity is not very pronounced. The organic mining rate is in comparison low to other organic substances. Xylitol is thus very stable in structure and the N-immobilization is low despite the high N / C ratio from 80 to 200. Heavy metal residues and others Pollutants are only present in traces and without relevance for ecological, biological safety.

Xylitol, which is separated from lignite from the deposits in Lusatia in Germany during the treatment of lignite, has the following composition and ratios as averages. The content of humic acid-forming complexes is recorded in the organic substance. Lusatian brown coal xylitol key figures average values Analysis values and properties of lignite xylitol prepared in fiber form granulation mm 0-20 bulk density g / l 350-400 water content Wt .-% 45-55 Total pore volume Vol .-% 85-90 water capacity Vol .-% 40-50 air capacity Vol .-% 30-50 shrinkage value % 8-12 PH value 4,5-5.5 organic substance Wt .-% 96-99 in dry matter Salinity, total mg / l <300 Soluble plants available nutrients nitrogen mg / l <30 phosphate mg / l > 40 potassium mg / l <30 carbon Wt .-% 25-36 nitrogen Wt .-% 0.3-0.5 C: N ratio 80-200 Biological properties nitrification none N-budget completely N-bond mg N / l -30 to -70

The production of soil improvement products and fertilizers based on lignite and xylitol is very complex in process technology and cost-intensive and thus expensive, despite the low raw material costs. In addition, these soil improvers and fertilizers are not included in the Able to store large amounts of water and / or aqueous liquids, such as liquid fertilizer or liquid manure, and to give over a long period of time to the plant roots. It is with these products based on lignite and / or xylitol improved the soil structure only insignificantly and a desired binding to the earth crumbs is not possible. As soil improvers with long-term water and nutrient storage effect, these products are also not suitable. In addition, they sometimes lead to hardening of the soil structure and not, as desired, to a loosening.

Presentation of the invention

The Invention has set itself the task of a composite material to create that is inexpensive and the indicated Disadvantages. Ideally, such a composite material, using the water storage properties of SAP, under Exposure of water and / or liquids expand and binding of the water a finished plantable soil substrate form or, when subjugated, into non-plantable soil structures Shaping and loosening them up after incorporating this Composite material and subsequent sprinkling to transforms a plantable soil substrate, which has a the plant growth promoting water storage capacity has and is capable of a multiple of its own weight bind to water and this but again to the plants or give the seed. Furthermore, the composite material should be particularly structurally stable and have a long duration of action, at least over 3 to 5 years unfold, with fertilizers of every kind combine and actively contribute to the formation of humus. Furthermore the composite material has to be simple and inexpensive to produce be.

The Designation Composite material is used as a descriptive name for the homogeneous composite material according to the invention chosen, which always consists of at least two material components is composed.

The Solution of the problem of the invention arises from the features of the characterizing part of the claim 1. Advantageous development of the invention and the method for Production of the composite material according to the invention as well as its use will become apparent from the dependent claims.

After that is a composite material of the aforementioned type characterized in that that this as a lignite and / or xylitol matrix and at least a synthetic and / or natural cross-linked and / or partially crosslinked polymer and / or copolymer contains.

It has now surprisingly found that the inventive Task, is achieved by forming the hydrogel crosslinked and / or partially crosslinked polymers and / or copolymers bound in a matrix of lignite and / or lignite xylitol and / or deposited and / or fixed to these and / or in their Pores are stored.

The novel composite materials according to the invention are homogeneous in the structure and fully meet all the requirements to soil improvement products with an always active Long-term water storage effect can be made and are simple and inexpensive to manufacture.

Embodiment of the invention

Further Objectives, characteristics, advantages and applications of the Invention will become apparent from the following description of exemplary embodiments. All described features form for themselves or in any combination, the subject matter of the invention, independently from the summary in individual claims or their Dependency.

Example 1:

200 kg of lignite with a content of twelve percent by weight Xylitol in dry matter and fifty percent by weight of water in dry matter and with a particle size from 0-2 mm with 100 kg of SAP, called potassium polyacrylate with a grain size <1000 microns, in a fast Homogenous ploughshare mixer homogenized with rotating chopper and formed to the composite material.

The Mixing time is 10 minutes and the temperature rises at 30 ° Celsius. The composite material thus formed is dark brown and homogeneous in structure, crumbly, porous and can be described as earth-moist fine granules be that freely flowing and well dosed in this form is.

The Composite material according to Example 1 is able to increase the volume to take up to 80 times its own weight of water and this to store and deliver again. After delivery of the bound water, So after the suspension of the hydrogel state by evaporation of the absorbed water and / or the delivery of the water, for example to plants, is the composite material is able to absorb water again, too store and deliver.

The Composite material according to Example 1 is for example excellent as an admixture to Pflanzerdemischungen where the water storage capacity should be increased.

Instead of of the potassium polyacrylate polymer used in Example 1 can for building the composite material, as by the invention Subclaim 10 also claims other hydrogel-forming polymers and / or copolymers are used. This makes it possible custom-made composite materials for specific applications manufacture. The selection of hydrogel-forming polymers and / or copolymers depends on the desired product properties and application areas.

This also applies with reference to the subclaims 10 and 11 for the proportion of in the inventive Composite material contained hydrogel-forming polymers and / or Copolymers and with reference to the subclaim 12 for the proportion of lignite and lignite xylitol.

By subsequent drying of the thus assembled and produced Composite material to a residual moisture content below 15 percent by weight the bonding of the polymers to the brown coal matrix is improved.

Example 2:

300 kg of finely ground xylitol with a particle size <500 microns and a water content of 20% by weight, and 200 kg of SAP with a grain size <600 microns and 204 kg open-pore, distended perlite in the form of sharp-edged perklit particles with a particle size of <100 microns will be in a fast running ploughshare mixer with rotating chopper 10 minutes mixed and it will be 300 kg of water over several Nozzles added during the mixing process.

At the Mixing, the temperature rose to 35 ° C. Despite the Water content of 36 weight percent felt in the composite material This very dry and could without subsequent drying be packaged as finished goods.

Of the Addition of perlite particles with reference to dependent claim 7 has proved to be very advantageous, because this additive serves as additional matrix in the composite material and also prevents the caking of the granular composite material whose Particle size between 800 to 1500 microns lying and have a bulk density of 680 grams per liter.

The Inventive composite material according to Example 2 can be used, for example, as soil strengthening agent, for submerging under potting soil or plant substrates whose water storage capacity must be increased. The addition amounts of SAP at these Applications depend on the water binding capacity to be achieved. It is also possible to place this composite directly in to incorporate dry soils. The composite material has an average water binding capacity of more than 40 times its own weight and expands while increasing its volume up to 45 times its original volume.

Example 3:

The Composite material according to Example 2 was in a vacuum dryer and / or Continuous drier to a residual water content <5 weight percent dried and then under pressure application by tablet and pellet presses to form bodies educated. For the formation of compacted moldings but also roller presses, extrusion presses and others shaping technologies are used.

The such shaped composite materials are particularly suitable for use as a long-term water storage when this point, for example for insertion into planting holes for trees or bushes should be used or for use as a water reservoir in planted pots, for example in indoor plants.

Example 4:

Becomes in the preparation of the composite material according to the invention in the mixing process according to Example 2, the water content to more than 50% by weight, it forms a flaky, porous, soft gel-like agglomerate. The particle size becomes essential due to the proportion of water in the composite material affected. To do this:

The following were presented in a rotary mixer:
200 kg of expanded, open-pore perlite particles with a mean particle size of <100 microns and 400 kg of finely ground lignite with a water content of 52 percent by weight and a particle size distribution of 0-2000 microns and 80 kg of water, then 200 kg of SAP were added. This homogeneous, free-flowing, powdery composite material was then added in portions 400 kg of water and the mixing process continued until an agglomeration ceased.

The thus produced agglomerate particles had a particle size, which were between 3000-6000 microns and had one gel-like, soft consistency and a homogeneous but porous Material structure.

These Agglomerate particles may be, for example, directly or in Blend with other substrates in slope greenery and / or Hangverfestigungen be applied. By drying the agglomerate particles, in for example rotary through-flow dryer, at a temperature above 100 ° C results homogeneous irregular shaped, porous free-flowing and pressure-stable Superabsorbent granules capable of up to 40 times their own weight To absorb water and / or aqueous fluids and deliver again. With the inclusion of water and / or aqueous Liquids is an increase in volume connected.

This Composite material formed as agglomerate granules can for example, alone or in combination with other materials used as water-binding drainage for green roofs. The hydrous agglomerate particles may also be, for example easily by screw presses, with upstream perforated discs, are formed into defined granule strands, the by rotating cutter discs to the desired length cut and then dried.

It has proven to be advantageous during processing over Screw presses, with reference to the dependent claim 16, for solidification the granule strands via suitable metering devices organic and / or inorganic binders are incorporated, preferably based on soda water glass and / or potassium silicate glass, but also the addition of lignin compounds and / or lignin derivatives is advantageous, in particular the addition or the training of Ligninsulfonatkomplexen as a reaction product of aqueous Calcium lignosulfonates with calcium oxide brings significant improvements the structural stability of the granulate strands and the granules produced therefrom.

By the addition of binder may additionally Strengths of Kompositmateials and their performance properties be significantly influenced.

at the embodiment of the task according to the invention, to provide a soil conditioner, with structure giving and water-storing properties, must be diverse Factors and requirements are observed. Considered must be basically with a corresponding product design for the field of soil improvement and long-term water storage, that such products in the swelling process large quantities have to absorb and store water and still this Water is returned to the plants or absorbed by the plants can be.

An improvement of the soil capillarity is desired, at the same time the soil quality should be positively influenced by admixtures of the minerals. It is desirable that a corresponding product in submerged under dry soil and subsequent irrigation, not only stores the water but also expands, so that a loose, plantable soil structure is formed, in which seed can be introduced. This total problem is already detailed in WO2003000621A1 described.

It is also advantageous that composite materials according to the invention or moldings formed or produced therefrom can be processed on site with the simplest means and introduced immediately into the surfaces to be processed or by suitable mixing devices, for example with the addition of water, with other earth and / or. or plant substrates can be combined to form a homogeneous composite material, which then only in this form in the example, to be planted, dry soil structures is introduced. This is demonstrated by the following example:

Example 5:

In a mobile rotary forced mixer with discharge device were submitted: 10,000 kg of a soil substrate based on coconut fiber substrate and xylitol fiber, which were mixed in the ratio 80:20. The moisture of the soil substrate was 40% by weight. In this substrate template 200 kg of a mixture was added, which was in the following composition and powder form with a particle size <1000 ym: perlite: 80.00 weight percent SAP 20.00 weight percent

After that In addition, 1000 kg of water were mixed in. That so Composite material prepared with the superabsorbent has now been released the desert-like floor area, so on a sandy soil with a layer thickness of about 5-8 cm applied and in the sandy soil to a depth of about 15 cm incorporated. The discharge per square meter area averaged about 1.4 kg in a total treated area of about 8000 square meters.

To the additional sprinkling with water was detected that the so treated floor area was able to total to absorb and bind about 17,000 kg of water and this, depending on from the wind conditions and the outside temperature, on average at about 38 ° C over a period of 14 hours a day and at night at about 30 ° C, too store, so that after 4 days still a residual moisture can be measured could, at about 30% of the original soil moisture was.

highlight is that there is no Bodenverklumpungen by the inventive Composite material gave, as with the introduction of conventional Superabsorbent is to be determined.

A Development of the invention is given by the fact that the invention Composite material or the trained or produced thereof Shaped bodies of natural minerals and / or granules of rock, preferably microporous minerals and / or granules or under water absorption swellable minerals and / or Rock granules are fed, on the one hand to Serve to improve the soil structure and on the other hand able are the plants with the appropriate mineral nutrients to supply. This can be for example - under Reference to the dependent claim 13 - rock flour from lava rock as well as trass, dolomite, bentonite, magnesite and feldspar.

Especially advantageous is the addition of finely ground lava rock, because This will require the plants to grow natural minerals available, which was previously due to the known methods and products in addition the superabsorbent polymers lava rock and / or lava rock flour, which is added in the polymerization of SAP, not possible was because this is insoluble as a filler in the polymer is bound.

The Composite materials according to the invention are, under Reference to the dependent claim 34, also very suitable for uptake and binding and / or treatment of pollutant-containing and / or odorous liquids and suspensions, such as liquid manure, dirty water and sewage sludge.

by virtue of the material structure and properties of the invention Composite materials it is in further education the invention possible that oil and / or pollutant degrading microorganisms and / or plant growth promoting Repelling microorganisms and / or animal pests and destroying microorganisms and / or their metabolites embedded in the pores of the composite material and / or to this be bound. It is advantageous that these first embedded in the expanded pearlite particles and / or at these are bound.

This also applies to the storage of inorganic and / or organic fertilizers and / or pesticides and / or other functional agents and additives. Preferably should these agents can be activated by water action and / or in water be soluble.

The incorporation of herbicides, fungicides, insecticides, pesticides and bactericides according to dependent claim 16 in the composite material according to the invention or the shaped body formed therefrom are further advantageous developments of the invention.

A Another preferred embodiment of the invention is the incorporation of cellulose fiber, microcellulose, waste paper fiber, wood shavings, Sawdust, wood wool, hay, straw, coconut fiber and coconut shell meal, So in general the incorporation of organic additives and / or Fillers preferably of vegetable origin, in the Composite material. This makes it possible, for example, flat, Cardboard-like structures and mats form, for example can serve as water-storing mats and / or seed carriers or in conjunction with other laminar support materials, for the cultivation of wetland and / or flooded plants Floor surfaces.

In which it is particularly advantageous when with reference to the dependent claim 4 fibers of xylitol are used in particular when the Composite material is to be formed as a mat.

Of Furthermore, these inventive Further developments of the composite materials and / or moldings Use find as oil binder and / or binding agent for water-oil emulsions, especially in the form of pellets and fine granules.

It it is known that lignite and also blown perlite particles, are able to absorb odors.

A further advantageous embodiment of the invention according to claim 16 includes that in the composite material according to the invention natural or synthetic fragrances and / or perfume preparations, preferably based on essential oils, incorporated. Such products find application as liquids storing and odor neutralizing materials in combat from evil smells and exiting evil smelling liquids, such as those in biotonnes, for example attack.

These Products according to the invention can also for odor absorption in the area coverage of landfills used or in the processing of sewage sludge.

It It has also been found that the effect of the invention Composite material that absorbs odors by doing so is achieved that activated carbon, preferably highly porous Activated carbon obtained from coconut shells is added, preferably in particle sizes <5000 Micrometers.

It It was found that another advantageous training achieved by the invention according to dependent claim 20 is that composite formed as an aqueous suspension is that, by means of suitable applicators and / or spraying and injection units can be applied. This is what it is for example possible, easy and unproblematic dust bonds on To carry out walks and squares and also fixtures optimized by sandy slopes and embankments, if these suspensions, for example, additionally herbal Short fibers such as coconut fiber and / or xylitol fiber contains.

Found was, with reference to the dependent claim 6, that another advantageous embodiment of the invention is achieved when the inventive Composite material containing lignite and or xylitol and the humic complexes contained therein at least partially in water-soluble Form present. This significantly favors the desired Humus formation in the soil and is particularly advantageous in this continuing education of the invention that the soluble Humic complexes stored in the composite material and over for a long period of time.

It is complementary perform the invention Composite material is limited in its execution, Manufacture and use not on the above preferred examples. Rather, a variety of design variations, Manufacturing and use conceivable, which from the illustrated solution even in principle use of a different kind. In that sense will expressly to the descriptive part of the claims directed.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• WO 2003000621 A1 [0014, 0059]
• EP 0647093 B1 [0017]
• EP 0504644 A1 [0018]
• - DE 19825168 A1 [0018]
• DE 10120433 C1 [0018]
• DE 4137171 A1 [0019]
• DE 19511319 A1 [0019]

Claims (37)

By fluid action, preferably by water and / or aqueous solutions, expanding, this liquid and / or solution, preferably water and oil emulsions, storing and / or binding composite material, in particular formed as a shaped body and / or suitable for the formation of moldings, characterized that the composite material consists of a porous matrix of lignite, preferably lignite with a natural brown coal xylitol content of more than one percent by weight in dry matter and / or lignite xylitol and at least one hydrogel-forming natural and / or synthetic and cross-linked and / or partially cross-linked Polymer and / or copolymer. Composite material according to claim 1, characterized in that that the hydrogel-forming crosslinked and / or partially crosslinked polymers and / or copolymers to the matrix of lignite and / or lignite xylitol bound and / or deposited and / or fixed to these and / or are embedded in the pores. Composite material according to claims 1 and 2, characterized lignite and lignite xylitol are finely ground, preferably on particle sizes <2000 microns. Composite material according to one or more of the preceding gone claims, characterized in that lignite xylitol is contained in fibrous form. Composite material according to one or more of the preceding gone claims, characterized in that the milled brown coal and / or the lignite xylitol a water content of at least twenty percent by mass. Composite material according to one or more of the preceding gone claims, characterized in that the humic acid complexes contained in lignite and / or lignite xylitol at least partially present in water-soluble form. Composite material according to one or more of the preceding gone claims, characterized in that at least five percent by weight broken and / or ground, open-pored, expanded / expanded perlite in the form of sharp-edged Perlite particles is included. Composite material according to one or more of the preceding gone claims, characterized in that at least a polymer and / or copolymer by water absorption partially, preferably to 10-64% based on the incorporated polymer weight and / or Polymer volume, is designed as a hydrogel and / or completely in hydrogel form. Composite material according to one or more of the preceding gone claims, characterized in that the partial and / or complete hydrogel form of the polymers and / or copolymers after the formation of the composite material Dehydration completely and / or partially canceled is and the proportion of water, as hydrogel and / or in the composite material is below 15% by weight of the total weight of the Polymers and / or copolymers is. Composite material according to one or more of the preceding gone claims, characterized in that the Polymers and / or copolymers crosslinked and / or partially crosslinked polyacrylic acids are preferably potassium-polyacrylate and / or sodium-polyacrylate and / or ammonium polyacrylate base. Composite material according to one or more of the preceding gone claims, characterized in that 0.5-95 Weight percent polymers and / or copolymers are included. Composite material according to one or more of the preceding gone claims, characterized in that 5-95 Percent by weight of lignite and / or lignite xylitol are included. Composite material according to one or more of the preceding gone claims, characterized in that at least a natural, ground mineral rock, such as Eruptive rock, preferably lava rock and sedimentary rocks, such as Trass, dolomite, magnesite, bentonite and feldspar, preferably with a particle size <200 microns. Composite material according to one or more of the preceding claims characterized gekennzeich net, that natural, organic additives and / or fillers, preferably of vegetable origin, with a particle size> 2000 microns and preferably in porous open-pored structure and / or in the form of fibers with a fiber length up to thirty millimeters are contained, preferably cellulose, paper, Wood shavings, sawdust, hay, straw, coconut fiber, coconut fiber substrate and coconut shells. Composite material according to one or more of the preceding gone claims, characterized in that the Total water content> 10 Weight percent. Composite material according to one or more of the preceding gone claims characterized in that organic and / or inorganic binders are contained, preferably on the base of soda water glass and / or potassium water glass and / or Lignin compounds and / or lignin derivatives, preferably lignosulfonate complexes formed as a reaction product of calcium lignosulfonates with Calcium oxide. Composite material according to one or more of the preceding gone claims, characterized in that insecticides and / or pesticides and / or bactericides and / or fungicides are. Composite material according to one or more of the preceding gone claims, characterized in that natural and / or synthetic fragrances and / or perfume preparations, preferably based on essential oils are included. Composite material according to one or more of the preceding gone claims, characterized in that activated carbon is contained, preferably in particle sizes <5000 microns. Composite material according to one or more of the preceding gone claims, characterized in that it as aqueous suspension is formed. Composite material according to one or more of the preceding gone claims, characterized in that it too Tablets, granules, pellets, granular agglomerates and / or Mats is processed. Composite material according to one or more of the preceding gone claims, characterized in that this organic and / or inorganic fertilizers in solid and / or dissolved form. Process for producing a composite material according to one or more of the preceding claims, characterized in that for training and / or for connecting at least one component contained in the composite material Hydrogel-forming polymer and / or copolymer by adding water in the mixing and / or shaping operation as a binder under hydrogel formation is activated. Process for producing a composite material according to one or more of the preceding claims, characterized in that the mixing process by addition of water a porous, in the form of an irregular Agglomerate is formed, preferably with a particle size> 1000 microns. Use of a composite material after one or several of the preceding claims as a water reservoir and nutrient source for growth, germination and culturing plants of all kinds, wherein the composite material either directly to the ground or as an additive in a mixture with the soil and / or growing medium for improving the Soil structure, the soil climate and the water balance, supplied becomes. Use of a composite material after one or several of the preceding claims as a carrier material and / or admixture with fertilizers, plant strengthening substrates and plant growth promoting agents. Use of a composite material after one or several of the preceding claims as slope greenery and / or slope hardening agents and / or admixture with such Products. Use of a composite material after one or several of the preceding claims as roof greening substrate and / or as a drainage substrate in green roofs. Use of a composite material after one or several of the preceding claims as application material for the incorporation of insecticides, pesticides, bactericides and fungicides into the soil and / or other plant substrates. Use of a composite material after one or several of the preceding claims in area-like Training, also in combination with other area-like ones Carrier materials for cultivating plants in wetlands and / or flooded floor areas. Use of a composite material after one or several of the preceding claims as oil binders and / or binders for water-oil emulsions. Use of a composite material after one or several of the preceding claims as water absorbing, expanding and / or active ingredient-releasing material in flood protection and / or Dam construction, especially as an admixture in sandbags for the flood protection. Use of a composite material after one or several of the preceding claims for coverage and / or Recultivation of landfills. Use of a composite material after one or several of the preceding claims for inclusion, binding and / or treatment of pollutant-containing and / or odor-intensive Liquids and / or suspensions, such as Manure, sewage and sewage sludge. Use of a composite material after one or several of the preceding claims as water binders for soil stabilization and dust binding on squares and ways. Use of a composite material after one or several of the preceding claims as a carrier material and / or application material for organic and inorganic water and / or moisture activatable agents, preferably Microorganisms. Use of a composite material after one or several of the preceding claims for surface coverage and / or incorporations into the surface structure the recultivation and / or renaturation of mined lignite mines and / or other brownfields.