CZ309173B6 - Filler for building mixtures and products and producing it - Google Patents

Abstract

The filler for building mixtures and products comprises grains of at least one thermoplastic, shaped as a branch and / or stem fractals and / or combinations of them, the size of the branch and / or stem fractals in one dimension being at most 15 mm. The method of producing fillers for building mixtures and products consists in mixing grains of at least one thermoplastic with an input size of up to 35 mm in air of from 0.1 m3 to 1.5 m3 per 1 kg treated grains and subjected to at least two consecutive collisions with a working body moving at a speed of at least 80 ms-1 to heat and partially melt them and at the same time they are put into turbulent flow to disconnect and form grains as branch and / or stem-shaped fractals .

Description

Filler for building mixtures and products and method of its production

Field of technology

The technical solution relates to a filler for building mixtures, which is created mainly on the basis of thermoplastics. Advantageously, it may also contain cellulosic and lignocellulosic substances.

State of the art

At present, in addition to aggregates, sand, ash, recycled concrete, dust particles and the like, wires (plastic concrete), plastic or glass fibers produced for this purpose, fibers of certain lignocellulosic materials and the like are used as fillers for building mixtures. Attempts to use waste plastics are still in their infancy and their greater use is hindered by the fact that they are mainly available as relatively large colored particles, which visually disturb the surface structure of construction products. The processing of these waste plastics takes place almost exclusively on slow-running crushing equipment (eg gear crushers), without the presence of other additives. This results in only crushed, partially fibrous structures (particles) of plastics, in some cases mixed with the remnants of paper labels. During this grinding, there is usually no appreciable increase in the temperature of the material. Here, too, there is no, or only minimal, roughening of the particle surface. Therefore, as a result of the existing modifications, the processed material does not even melt and fiberize.

The essence of the invention

The above-mentioned drawbacks are eliminated by the filler in building compositions and products according to the invention, which consists in consisting of grains of at least one thermoplastic, treated by heating them to the appropriate temperature into fractal and / or stem fractures, such grains being called grains of a fractal character, the size of these grains in the form of branch and / or stem fractals being at most 15 mm in one dimension.

For the purposes of this application, a fractal is an object with an irregular geometric shape divisible into individual parts, each of which is ideally a reduced copy of the whole, so that they are essentially sets whose geometric motif is repeated in the basic body. This phenomenon is called self-similarity. Thus, a fractal is ideally similar, and if it can be divided into arbitrarily small parts, these are essentially a small replica of the original set. The filler according to the invention consists of fractal grains, which are branch or stem type fractals and their morphology is formed mainly by spatial structures and surface-spatial structures, in this case by branching the protrusions of individual fractal grains in several different scales, whose basic morphological characteristics are repeated to some extent on each scale. Fractals of a fractal nature, hereinafter also referred to as fractals, are, according to the invention, grains with large surface area values, in comparison with conventional smooth unbranched grains. Fractal grains of the invention may be in the nature of individual stochastic, self-similar "branch" or "stem" fractals, or asymmetric aggregates thereof. Grains of fractal character according to the invention from thermoplastic substances most often have the character of separate three-dimensional stem and branch asymmetric stochastic similar fractals with a fractal (so-called Hausdorf) dimension in the range of 2.3 to 2.7. Some, very richly branched fractals aggregates of these fractals then have dimensions mostly from 2.4 to 2.85. Fractals having the character of planar fractals with a dimension below 2, usually 1.6 to 1.82, can also occur much less often. Such fractals are formed by some soft plastics, such as low density polyethylene (LDPE) and other similar plastics, especially those from which plastic films are made. However, since they are very often variously bent and twisted, their shape is considered to be considered for the purposes of the present invention.

- 1 CZ 309173 B6 spatial, mostly with Hausdorf dimension at the level of values 2.3 to 2.5. Thus, planar fractals may also be present in the filler of the invention, but are usually in negligible amounts. One skilled in the art will appreciate that aggregates of such grains are spatial in nature and take on dimensional values in the range of 2.5 to 2.7.

Thus, for the purposes of this application, grains of a fractal nature are considered to be those whose Hausdorf fractal dimension is 1.4 to 1.85, but in particular those whose Hausdorf fractal dimension is 2.3 to 2.85. For simplification, the grains of fractal character, resp. abbreviated fractals, for the purposes of this application also consider their clusters formed by the joining of molten individual fractals before their cooling.

According to a first aspect of the invention, there is provided a builder filler comprising at least 15% by weight, based on the total weight of the filler, of grains of at least one thermoplastic, shaped in the form of branch and / or stem fractals and / or combinations thereof. or tribal character is not more than 15 mm in one dimension. According to a second aspect of the invention, there is provided a process for the production of this filler for building mixtures, according to which grains of at least one thermoplastic with an input size of up to 35 mm are mixed with air in amounts ranging from 0.1 m ³ to 1.5 m ³ per 1 kg. and are subjected to at least two successive collisions with a working body moving at a speed of at least 80 ms ¹ to heat and partially melt them and at the same time be turbulent to disconnect and form grains in the form of branch and / or stem-shaped fractals.

The filler according to the invention contains from 15% by weight to 100% by weight of fractal grains of at least one thermoplastic, any remaining up to 100% of which consists of cellulose and / or lignocellulosic grains and optional other substances such as crystalline or amorphous inorganic substances from the group of carbonates, silicates, aluminosilicates, oxides, phosphates, sulphates and mixtures thereof and, where appropriate, other substances listed below. Since the lignocellulosic materials themselves, with certain exceptions such as flax, hemp or coconut fibers, are not able to provide the building elements with sufficiently high tensile and flexural strength, the fractures of these materials are added to the fractures of the invention. at least one thermoplastic, thereby achieving the advantages described below.

According to one preferred embodiment, the filler consists of 100% by weight of thermoplastic. According to an even more preferred embodiment, the filler consists of a mixture of fractals of different thermoplastics, e.g. polyethylene, low density polyethylene, high density polyethylene, polytetrafluoroethylene, polystyrene, acrylonitrile butadiene styrene, hereinafter referred to as ABS, and others, as described below. According to a further preferred embodiment, the filler is formed by a mixture of fractals of at least one thermoplastic and fractals of cellulose and / or lignocellulose, it being particularly advantageous for it to still contain some of the substances listed below. However, the filler according to the invention must contain at least 15% by weight of fractures made of thermoplastic materials, which guarantees the functionality of the filler in terms of increasing the tensile strength of the resulting material to which this filler is added. As already mentioned, the filler according to some preferred embodiments of the invention may contain, in addition to said fractals of at least one thermoplastic, fractals of cellulosic and lignocellulosic substances. According to another particularly preferred embodiment, the filler according to the invention further comprises at least 15% by weight of cellulose and / or lignocellulosic fractal grains, this content having a significant effect on the hydration quality of the binder during the formation of the building elements.

According to a particularly preferred embodiment of the filler according to the invention, the filler contains at least one of the following inorganic substances which is or are (are) incorporated into the surface of the fractals. The term surface in which said at least one inorganic substance is incorporated for the purposes of this application also includes cracks in the surface in which the grains of such inorganic substance adhere or the branching surface of fractals in which such grains adhere. Due to the presence of tightly bound grains

-2 CZ 309173 B6 relevant inorganic substances in the surface of fractal grains of thermoplastics (and possibly also lignocellulosic substances), ie including grains of these substances adhering in the fractures of the fractal surface or in the surface of fractal branches, on the one hand the electrostatic agglomeration of fractal grains is largely eliminated. the hydrophobicity of most fractal grains of thermoplastic is largely eliminated. In the case of the mechanical treatment of thermoplastics, cellulose or lignocellulosic substances, an inorganic substance with a grain size of up to 15 mm from the group comprising hydraulic substances, latent hydraulic substances, oxides, hydroxides and Ca sulphates is then particularly preferably used in the process for the production according to the invention. and Fe and water-insoluble silicates, aluminosilicates, phosphates, carbonates and / or mixtures thereof. This results in the filling of the filler according to the invention disintegrating and heating, producing fine grains with a relatively rugged surface, but usually several times smaller and also more isometric than in the case of thermoplastics, or, if present, cellulosic and / or lignocellulosic substances. If an inorganic substance is added in powder form, even in grain sizes below 0.1 mm, its changes occur only to a lesser extent during mechanical impulses. However, the environment in which the mechanical treatment takes place is concentrated and the balance of surface charges of the treated material changes. This leads to a more intense heating of these changes. If the turbulent flow of such heated changes treated in the heated air environment also occurs during dynamic compression of the mixture, gluing, sealing and jamming of individual changes, especially fine changes of inorganic substances into the surface of fractures of organic substances, including already mentioned slits in the surface of these fractals or in the branching surface of fractals. Thanks to the substances firmly bound to the surface of the fractals, which react chemically in a humid environment and become part of the binder, the bond between the resulting filler fractals is stronger. In addition, as in the previous point, agglomeration of a fractal nature is eliminated and, in the case of the use of inorganic substances with a negative surface charge, the hydrophobicity of the fractal character of the thermoplastic is eliminated. Conversely, in the case of the use of inorganic substances with a positive surface charge, such as limestone or talc, partial hydrophobization of cellulose and lignocellulosic substances can also occur. According to another particularly preferred embodiment, the filler comprises grains or aluminum particles. When in contact with water in a high pH environment, such as in concrete, aluminum, when the filler phenomenon is present, reacts with water to form aluminum hydroxide and hydrogen, which forms bubbles in the concrete. Aluminum hydroxide can then react with Ca to form calcium aluminate and become part of the binder. Foam concretes usually have a very low tensile strength, which the use of the filler according to this embodiment greatly improves.

The advantage of the filler according to the invention is that after its mixing with the binder and possibly other filler components, for example aggregate, it is able to create a spatial structure which is mechanically interconnected due to surface fracture and is able to provide building elements increased tensile strength without increasing their density or electrical conductivity. The filler according to the invention acts as a very light and effective reinforcement. Another advantage of the filler according to the invention, especially if it preferably contains grains of lignocellulosic and cellulosic substances, is that it significantly improves the hydration quality of hydraulic binders in building materials, as it contributes to even distribution and retention of water in these materials. The filler according to the invention thus improves the hydration quality of the hydraulic binders, which largely eliminates the occurrence of cracks in the construction product. Due to these properties, the filler according to the invention is suitable, for example, for various thin-walled building elements or as a filler in mixtures for 3D printing of buildings.

According to a second aspect of the invention, there is provided a method of making a filler according to the invention in which thermoplastic grains described in the Examples are disengaged by mechanical pulse treatment as described in cellulosic and / or lignocellulosic substances, if present in the filler, will be mechanically pulped. Both thermoplastics and cellulosic and lignocellulosic materials have a fractal character. Due to the turbulent flow in carrying out the method according to the invention, the air medium in which the treatment takes place is compressed, thus increasing the efficiency of fractal formation. Due to the melting of thermoplastic changes, there is a connection - integration of thermoplastic fractals with fractals

Of cellulose and / or lignocellulosic components of the treated material, if present. Furthermore, if other suitable substances are present, as will be described below, which have a sufficiently small particle diameter, they will be fused to the surface of the fractals. For example, in carrying out a preferred embodiment of the filler process of the present invention, the addition of inorganic substances such as cement, clinker, slag dust, limestone, silica sand, limestone, etc. allows the surface charge of the fractal filler to vary according to the type of inorganic substance or agglomeration of the individual fractal binder and significantly improve the storability and transportability of the filler according to the invention. Particularly preferably, a so-called active filler, such as the already mentioned aluminum, is then added in carrying out the preferred embodiment of the filler production method according to the invention, which makes it possible to change the character of the final product which is produced from the filler.

Clarification of drawings

The invention will be elucidated using figures in which:

Fig. 1 is an image of a typical tribal fractal;

Fig. 2 is a simplified drawing of a tribal fractal;

Fig. 3 is an image of a branched fractal;

Fig. 4 is a simplified drawing of a possible example of a branched fractal;

Fig. 5 is a simplified diagram of another possible example of a branched fractal;

Fig. 6 is a fractal image of a polypropylene of a tribal character;

Fig. 7 shows polytetrafluoroethylene fractals of branched character; and Fig. 8 polyethylene fractals with dolomitic limestone integrated into the surface.

Examples of embodiments of the invention

The invention will now be described by way of example. other embodiments, wherein combinations of features from different embodiments are intended to fall within the scope of the invention and form another embodiment, which will be fully understood by those skilled in the art. The claims that follow the detailed description are hereby expressly included in this detailed description, with each claim remaining separately as a particular embodiment of the invention. The filler according to the invention has the shape of fractals of a stem or branch character. To understand what is meant by such fractals, Fig. 1 is an example of a typical tribal fractal, Fig. 2 is a simplified drawing of a tribal fractal, Fig. 3 is an example of a branched fractal, while Fig. 4 is a simplified drawing of a possible example. fractal character, Fig. 5 is a simplified drawing of another possible example of a branch fractal. Giant. Fig. 6 is a fractal image of a polypropylene filler of the invention which is of a tribal nature; Fig. 7 is a fractal character of a polytetrafluoroethylene which is branched in nature.

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Example 1

The filler for building mixtures and products according to the invention is formed only of thermoplastic grains, which is high density polyethylene HDPE, shaped into spatial branch and stem, asymmetric fractals with Hausdorf dimension values in the range of about 2.4 to 2.75 and the longest dimension not more than 15 mm in one direction.

Example 2

Filler for construction mixtures and products, consisting of a mixture of thermoplastics, formed from 25% by weight of PE polyethylene grain, 35% by weight of polytetrafluoroethylene PTFE grain, 15% by weight of PP polypropylene, 15% by weight of high density polyethylene HDPE and 10% by weight of polystyrene PS, adjusted to the shape of spatial branch and stem fractals with Hausdorf dimension values in the range of 2.4 to 2.75 and the longest dimension in one direction of not more than 15 mm, while HDPE consists mainly of branch fractals with Hausdorf dimension values in the range of 2.5 to 2.7, zma LDPE consists of spatial stem fractals with values with Hausdorf dimension values mostly in the range of 2.4 to 2.5, zma PS consists mainly of spatial stem fractals with values of Hausdorf dimension 2.4 to 2.55 and zma PTFE mainly spatial branch fractals with Hausdorf dimension values ranging from 2.5 to 2.75.

Example 3

Filler for building mixtures and products, consisting of 80% by weight of m and recycled paper and paperboard aggregates processed into three-dimensional branch fractals with the longest dimension in one direction 12 mm and Hausdorf dimension values in the range of 2.6 to 2.8, and from 20% by weight of thermoplastics, which are polytetrafluoroethylene, which are formed into three-dimensional branched and stem, asymmetrical, similar fractals with Hausdorf dimension values in the range of 2.4 to 2.75 and the longest dimension in one direction of at most 15 mm.

Example 4

Filler for building mixtures and products, consisting of 80% by weight of PTFE modified into three-dimensional branch and stem, asymmetrical, similar fractals with Hausdorf dimension values in the range of 2.4 to 2.7 and the longest dimension in one direction of not more than 15 mm, and from 20% by weight of sawdust aggregates arranged in the form of three-dimensional branch fractals with the longest dimension in one direction of 6 mm and Hausdorf dimension values in the range of 2.5 to 2.76.

Example 5

Filler for construction mixtures and products, consisting of 50% by weight of m and aggregates of recycled cardboard processed into three-dimensional branch fractals with the longest dimension in one direction 12 mm and Hausdorf dimension values in the range of 2.6 to 2.8, 30% by weight zm grain straw adjusted to the shape of planar and spatial branch fractals with the longest dimension in one direction 15 mm and Harusdorf dimension values in the range of 2.4 to 2.6 and 20% of the weight of wood sawdust modified into the shape of spatial branch fractals with the longest dimension in one direction in one 6 mm and Hausdorf dimension values in the range of 2.5 to 2.76.

Example 6

Filler for building mixtures and products, consisting of 15% by weight of PE PE modified into three-dimensional branch and stem, asymmetrical, similar fractals with values

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Hausdorf dimensions in the range of 2.4 to 2.75 and the longest dimension in one direction of not more than 15 mm and 85% by weight of grains and grain aggregates of recycled paper and paperboard shaped into spatial branch fractals with the longest dimension in one direction of 12 mm and values Hausdorf dimensions in the range of 2.6 to 2.8.

Example 7

Filler for building mixtures and products, consisting of 85% by weight of PET obtained from recycled plastic bottles, shaped into three-dimensional branch and stem, asymmetrical, similar fractals with Hausdorf dimension values ranging from 2.4 to 2.65 and the longest dimension in one direction not more than 15 mm and 15% by weight zm and aggregates zm of recycled paper and paperboard processed into three-dimensional branch fractals with Hausdorf dimension values in the range of 2.5 to 2.8 with the longest dimension in one direction not more than 12 mm.

Example 8

Filler for building mixtures and products consisting of 40% by weight of PTFE modified into flat and three-dimensional branch and stem, asymmetrical, similar fractals 20 with Hausdorf dimension values ranging from 2.4 to 2.65 and the longest dimension in one direction at most 15 mm and 60% by weight of m and aggregates m of recycled paper and paperboard processed into three-dimensional branch fractals with Hausdorf dimension values in the range of 2.5 to 2.8 with the longest dimension in one direction not more than 5 mm, this mixture of fractal changes being suitable as part of the reinforcement of concrete and geopolymic building elements, 25 including building elements and buildings manufactured using linear 3D printing.

Example 9

Fillers for building mixtures and products consist of 35% by weight of polypropylene treated 30 into three-dimensional shapes, mainly stem and branch, asymmetrical, similar fractals with Hausdorf dimension values ranging from 2.4 to 2.65 and the longest dimension in one direction at most 15 mm, 40% by weight of soft PE obtained from recycled PE foils, modified into three-dimensional, asymmetrical, similar fractal shapes with Hausdorf dimension values in the range of 2.455 to 2.7 and the longest dimension in one 35 direction at most 12 mm and 25% by weight dolomitic crystalline limestone up to 150 μm in size, which are baked into the surface, cracks and branches of fractal changes PP and PE.

Example 10

The filler for building mixtures and products consists of 35% by weight of polypropylene modified into three-dimensional shapes, mainly stem and branch, asymmetrical, similar fractals with Hausdorf dimension values ranging from 2.4 to 2.65 and the longest dimension in one direction of not more than 15 mm, 40% by weight of soft PE obtained from recycled polyethylene films, processed into three-dimensional, asymmetrical, similarly similar 45 fractals with Hausdorf dimension values in the range of 2.55 to 2.7 and the longest dimension in one direction of not more than 12 mm and 25% by weight zm dolomitic crystalline limestone up to 150 μm in size, which are baked into the surface of fractal zm PP and PE.

Example 11

The filler for building mixtures and products consists of 20% by weight of polypropylene modified into three-dimensional shapes, mainly stem and branch, asymmetric fractals with Hausdorf dimension values ranging from 2.4 to 2.65 and the longest dimension in one direction of no more than 15 mm, 45% by weight soft polyethylene obtained from recycled polyethylene films, 55 modified into three-dimensional shapes, especially branched, asymmetrical, similar to each other

Fractures with Hausdorf dimension values in the range of 2.55 to 2.7 and the longest dimension in one direction of not more than 12 mm, and 25% by weight of grains of granulite aggregate dust consisting of feldspar, quartz, biotite, almandine garnet and cyanite , up to 80 μm in size, which are baked into the surface of polypropylene and polyethylene fractal grains.

Example 12

The active filler in building mixtures and products consists of 35% by weight of polytetrafluoroethylene grains prepared in the shape of three-dimensional mainly stem and branch, asymmetrical, similar fractals with Hausdorf dimension values in the range of 2.45 to 2.7 and the longest dimension in one direction maximum 15 mm , 40% by weight of soft polyethylene obtained from recycled polyethylene films, shaped in the form of three-dimensional, mainly branched, asymmetrical, similar fractals with Hausdorf dimension values in the range of 2.45 to 2.7 and the longest dimension in one direction of not more than 12 mm, and 25% masses of Portland pozzolanic cement, up to 50 μm in size, which are baked into the surface of fractal changes of polytertrafluoroethylene and polyethylene.

Example 13

The active filler in building mixtures and products consists of 20% by weight of polytetrafluoroethylene PTFE modified into three-dimensional shapes, especially stem and branch, asymmetrical, similar fractals with Hausdorf dimension values ranging from 2.45 to 2.7 and the longest dimension in one direction at most 15 mm, 30% by weight of soft polyethylene obtained from recycled polyethylene PE foils, processed into three-dimensional, asymmetrical, similar fractal shapes with Hausdorf dimension values in the range of 2.45 to 2.7 and the longest dimension in one direction not more than 12 mm, 25 % by weight of m and recycled papermaking and paperboard aggregates converted into three-dimensional branch fractals with the longest dimension in one direction of 12 mm and Hausdorf dimension values ranging from 2.6 to 2.8, 10% by weight of Portland pozzolanic cement, of up to 50 μm, which are baked into the surface of fractal changes of polytetrafluoroethylene and polyethylene and from 15% by weight of opel fluidized bed combustion of brown coal, up to 50 μm in size, which are also baked into the surface of fractal changes PTFE and PE.

Example 14

The active filler in aerated concrete construction products consists of 35% by weight of polytetrafluoroethylene PTFE modified into three-dimensional shapes, especially stem and branch, asymmetrical, similar fractals with Hausdorf dimension values ranging from 2.45 to 2.7 and the longest dimension in one direction at most 15 mm , 40% by weight of soft polyethylene PE obtained from recycled polyethylene films, processed into three-dimensional, asymmetrical, similar fractal shapes with Hausdorf dimension values in the range of 2.45 to 2.7 and the longest dimension in one direction not more than 12 mm and 24, 75% by weight of Portland pozzolanic cement, up to 50 μm in size, which are baked into the surface of PTFE and PE fractal changes, and 0.25% by weight of aluminum, up to 50 μm in size, adhering to the surface of polytetrafluoroethylene fractal changes.

Example 15

Active filler for aerated concrete construction products, consisting of modified municipal waste SRF / RDF, which contains 58% by weight of various thermoplastic materials treated into three-dimensional shapes, especially stem and branch, asymmetrical, similar fractals with Hausdorf dimension values ranging from 2.45 to 2.7 and the longest dimension in one direction not more than 15 mm, 25% by weight of cellulosic materials adapted to spatial shapes, especially branched, asymmetrical, similar fractals with Hausdorf dimension values in the range of 2.55 to 2.8 and the longest dimension in one

-7 CZ 309173 B6 direction of not more than 10 mm, from 16.7% by weight of glass and ceramic grains up to 300 μm and from 0.3% by weight of aluminum grains up to 300 μm.

Example 16

100% by weight of high-density HDPE thermoplastic in the form of chips with an input grain size of up to 35 mm, is fed together with air in an amount of 0.12 m ³ / lkg of input raw material to the center of the flat-cylindrical working space bounded by two oppositely rotating coaxial circular plates at a perpendicular distance of 32 mm and a diameter of 780 mm, between which the grains are subjected to at least two mechanical pulses caused by collision ^of treated grains with working bodies mechanical impulse at the rate of collision of treated grains with working bodies with a speed in the range of 80 to 120 ms ¹ . This mechanical treatment produces a filler for building mixtures and products, from Example 1, consisting of thermoplastic grains, which is HDPE polyethylene, shaped into three-dimensional branched and stem, asymmetrical, similar fractals with Hausdorfb dimension values ranging from 2.4 to 2, 75 and the longest dimension in one direction not more than 15 mm, suitable as a filler in concrete, mortars, geopolymers and other building mixtures and products thereof, increasing their flexural tensile strength.

Example 17% by weight of ABS thermoplastic in the form of isometric granules with an input size of 15 mm, 50% by weight of PP crumb with an average grain size of 10 mm, 50% by weight filled with limestone filler is fed together with air in an amount of 0.75 m ³ / lkg input raw materials to the center of the working space in the shape of a flat cylinder, limited by two oppositely rotating coaxial circular plates at a perpendicular distance of 32 mm and a diameter of 780 mm, between which the grains are subjected to at least two mechanical impulses caused by collision of treated grains with working bodies a pulse at the rate of collision of the grain with the working body in the range of 50 to 70 ms ¹ and a second mechanical pulse at the rate of collision of the treated grains with the working body in the range of 80 to 120 ms ¹ . This mechanical treatment produces a finely ground, partially fibrous material with a rough grain surface, suitable as a filler in construction mixtures or for the production of extruded products. This mechanical treatment produces a filler for building mixtures and products, consisting of thermoplastic grains, which are ABS and PP filled with limestone, whose grains are shaped into three-dimensional branch and stem, asymmetrical, similar fractals with Hausdorfb dimension values ranging from 2.4 to 2.75 and the longest dimension in one direction not more than 15 mm, suitable as a filler in concrete, mortar, geopolymers and other building mixtures and their products, increasing their tensile strength in bending and also, due to the presence of limestone grains present in PP grains also into asphalts and asphalt concretes.

Example 18% by weight of ABS thermoplastic in the form of isometric granules with an input size of 15 mm, 25% by weight of isometric granules PP with an input size of 10 mm, 25% by weight of isometric granules LDPE with an input size of 7 mm, together 20% of crushed crystalline dolomitic limestone in the range of 0 to 5 mm and 5% talc crumb with an input grain size of 0 to 5 mm, is fed together with air in an amount of 1.02 m ³ / lkg of input raw material to the center of the flat cylindrical working space, limited by two in the opposite sense. rotating coaxial circular plates at a perpendicular distance of 32 mm and a diameter of 800 mm, between which the grains are subjected to at least four mechanical pulses caused by collision of treated grains with working bodies, the first mechanical pulse at grain collision with working body in the range of 50 to 70 ms ¹ and the second mechanical pulse at the rate of collision of the treated grains with working bodies with a speed in the range of 70 to 90 ms ¹ , the third mechanical pulse at a collision rate of 90 to 110 ms ¹ and a fourth pulse at a collision rate of 100 to 130 ms ¹ . This mechanical treatment produces a filler consisting of the thermoplastic grains they are

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ABS and PP and LDPE, the grains of which are arranged in the form of three-dimensional branch and stem, asymmetrical, similar fractals with Hausdorfb dimension values in the range of 2.3 to 2.75 and the longest dimension in one direction of not more than 15 mm, which has dolomitic limestone and talc on the surface, ie also in crevices and branches, the fractal shape has a reduced tendency to undesirable agglomeration and is suitable as a filler in concrete, mortars, geopolymers, asphalts and asphalt concrete and other building mixtures and their products or for the production of extruded products . This results in a filler according to the invention which has the properties of a hydrophobic binder, with fine limestone grains glued to the surface of a fractal character made of thermoplastic materials. This filler is suitable for asphalts and asphalt concrete, which reduces the formation of potholes in the winter. It is also suitable for the production of extruded products.

Example 19

100% by weight of sorted municipal waste of the SRF / RDF fraction in the form of chips with an input grain size of up to 35 mm, 60% of which are plastics from the group of thermoplastics, is brought together with air in the amount of 0.35 m ³ / lkg of input raw material a flat-cylinder space bounded by two oppositely rotating coaxial spherical plates at a perpendicular distance of 32 mm and a diameter of 800 mm, between which the grains are subjected to at least three mechanical impulses caused by collisions of treated bodies with the first mechanical impulse at collision speed grains with a working body in the range of 50 to 80 ms ¹ admh mechanical mechanical pulse at the collision rate of the treated bodies with working bodies with a speed in the range of 85 to 100 ms ¹ and a third pulse at the collision speed of the treated zm with working bodies with a speed of 100 to 125 ms ¹ . This mechanical treatment produces a filler for building mixtures and products, especially concrete, consisting of a mixture of fractal character from thermoplastics and cellulosic materials, while these fractal grains are processed into three-dimensional branch and stem, asymmetric fractals with Hausdorf dimension values in the range of 2, 3 to 2.85 and the longest dimension in one direction does not exceed 15 mm, while fine grains of inorganic substances present in SRF / RDS, especially glass and ceramics, are glued in the surface of the fractal shape.

Example 20

100% by weight of solid alternative fuel (TAP), commonly used for heating cement kilns, in the form of chips with an input grain size of up to 35 mm, 75% of which are plastics from the group of thermoplastics, is supplied with air in the amount of 0.45 m ³ / 1 kg of input raw material to the center of the working space in the form of a flat cylinder, bounded by two oppositely rotating coaxial spherical plates at a perpendicular distance of 32 mm and a diameter of 800 mm, between which the grains are subjected to at least three mechanical impulses the first mechanical pulse at the collision rate of the grain with the working body in the range of 50 to 80 ms ¹ and the second mechanical pulse at the collision rate of the modified zm with working bodies in the range of 85 to 100 ms ¹ and the third pulse at the collision rate of the modified zm with working bodies in speed 105 to 130 ms ¹ . This mechanical treatment produces a finely ground material consisting of a mixture of thermoplastics and cellulosic materials, the grains of which are shaped into three-dimensional branched and stem, asymmetrical, similar fractals with Hausdorf dimension values ranging from 2.3 to 2.85 and the longest dimension in in one direction not more than 15 mm, filler for building mixtures and products, especially concrete, consisting of a mixture of thermoplastics, cellulosic materials, which are processed into three-dimensional branch and stem, asymmetrical, similar fractals with Hausdorf dimension values ranging from 2.3 to 2.85 and the longest dimension in one direction not more than 15 mm, usable as a filler in building mixtures and building elements, especially in concrete and asphalt, but also for the production of extruded products.

-9CZ 309173 B6

Example 21% by weight of recycled ABS thermoplastic material, in the form of crumb with an input grain size of up to 15 mm and 30% by weight of crystalline calcitic limestone with an input grain size of up to 5 mm, is fed together with air in an amount of 1.4 m ³ / lkg of feedstock to the center of the flat-cylindrical working space, bounded by two oppositely rotating coaxial circular plates at a perpendicular distance of 32 mm and a diameter of 780 mm, between which the grains are subjected to at least three mechanical impulses caused by collisions of treated grains with their working bodies, a second mechanical pulse at the rate of collision of the grain with the working body in the range of 50 to 80 ms ¹ and a second mechanical pulse at the rate of collision of the treated grains with the working body in the range of 85 to 100 ms ¹ and a third collision with the speed of 105 to 135 ms ¹ . This treatment produces a filler of fractal character according to the invention with limestone grains adhered to the surface of the ABS grains and to the branching of their fractal grains.

Example 22% by weight of grains of sorted municipal waste material containing at least 40% by weight of thermoplastics with a moisture content of 20% by weight, and grain sizes up to 35 mm, together with 20% by weight of 20 mixtures of inorganic substances - artificial pozzolan in a weight ratio of 4: 2: 2: 1 together with air in the amount of 1.25 m ³ / lkg of input raw material lead to the center of the working space in the shape of a flat cylinder, bounded by two oppositely rotating coaxial circular plates at a perpendicular distance of 32 mm and diameter 780 mm, between which the grains are subjected to at least three mechanical pulses caused by 25 collisions of treated grains with working bodies, the first mechanical pulse at the collision rate of grains with working bodies in the range of 50 to 80 ms ¹ and the second mechanical pulse at the collision rate of treated grains with working bodies with working bodies with a velocity between 85 and 100 ms ¹ and a third collision with a velocity between 105 and 135 ms ¹ . This treatment produces an active filler of fractal character according to the invention with grains of inorganic substances adhered to the surface and to the branch 30 fractal grains. The mixture thus prepared is suitable as a dry building mixture, for example for the production of vibro-pressed building elements.

Example 23

76% by weight of solid alternative fuel TAP (RDF) in the form of chips, with a moisture content of 15% by weight, and a grain size of up to 35 mm, together with 24% by weight of crushed Portland clinker with an input grain size of 0 to 6 mm, together with air in quantity 1 , 48 m ³ / lkg per weight of feedstock, are fed to the center of a flat cylindrical working space bounded by two oppositely rotating coaxial circular plates at a perpendicular distance of 32 mm and a diameter of 40 8 00 mm, between which the grains are subjected to at least four mechanical pulses caused by collision of treated grains with working bodies, namely the first mechanical pulse at the collision rate of grain with working bodies in the range of 50 to 70 ms ¹ and the second mechanical pulse at the collision speed of treated grains with working bodies in the range of 70 to 90 ms ¹ and a third collision of 90 to 100 ms ¹ and a fourth collision of 100 to 125 ms ¹ .

This treatment produces the active filler according to the invention with Portland clinker grains adhered to the surface of the fractals, into the cracks and into the branches of the fractal grains of the thermoplastic and cellulosic substances present in the TAP (RDF). The mixture treated in this way is suitable as an active filler, for example, for the production of vibro-pressed building elements.

Example 24

99.5% by weight of solid alternative fuel TAP (RDF) in the form of chips, with a moisture content of 15% by weight, and a grain size of up to 35 mm, together with 0.5% by weight of aluminum powder with an input grain size of 0 to 100 μm, together with air in the amount of 0.72 m ³ / lkg per weight of input raw materials, 55 are brought to the center of the working space in the shape of a flat cylinder, limited by two in opposite

- 10GB 309173 B6 with rotating coaxial circular plates at a perpendicular distance of 32 mm and a diameter of 780 mm, between which the grains are subjected to at least three mechanical pulses caused by collision of treated grains with working bodies, namely the first mechanical pulse 50 to 80 ms ¹ and a second mechanical pulse at a collision speed of the treated grains with working bodies at a speed in the range of 85 to 100 ms ¹ and a third collision at a speed in the range of 105 to 135 ms ¹ . This treatment produces an active filler according to the invention with aluminum grains adhering to the surface of the fractal grains. The mixture treated in this way is suitable as an active filler for the production of aerated concrete building elements.

Example 25% by weight of solid alternative fuel TAP (RDF) in the form of chips, with a moisture content of 15% by weight, and a grain size of up to 35 mm, together with 24.5% by weight of Portland cement 42.5 R with an input grain size of 0 to 70 μm and 0.5% by weight of aluminum powder with an input grain size of 0 to 100 .mu.m, together with air in an amount of 1.05 m ³ / lkg per weight of input raw materials, are fed to the center of the flat cylindrical working space bounded by two oppositely rotating coaxial ones. circular plates at a perpendicular distance of 32 mm and a diameter of 800 mm, between which the grains are subjected to at least four mechanical pulses caused by collision ^of treated grains with working bodies, namely the first mechanical pulse at the collision rate pulse at a collision rate of treated grains with working bodies at a speed in the range of 70 to 90 ms ¹ and a third collision at a speed in the range of 90 to 100 ms ¹ and a fourth collision at a speed of 100 to 125 ms ¹ . This treatment produces an active filler according to the invention with Portland clinker grains adhered to the surface of fractal grains of thermoplastic and cellulosic substances present in TAP (RDF). The mixture treated in this way is suitable as an active filler, eg for the production of aerated concrete products.

Example 26% by weight of grains of sorted municipal waste material containing at least 50% by weight of thermoplastics with a moisture content of 20% by weight, and grain sizes up to 35 mm, together with 24% by weight ^of dry quarry dust from basalt crushing together with air / lkg of feedstocks bring to the center of the working space in the shape of a flat cylinder, bounded by two oppositely rotating coaxial circular plates at a vertical distance of 32 mm and a diameter of 800 mm, between which the grains are subjected to at least three mechanical impulses caused by collisions of treated grains with working bodies the first mechanical pulse at the rate of collision of the grain with the working body in the range of 50 to 80 ms ¹ and the second mechanical pulse at the rate of collision of the treated grains with the working body in the range of 85 to 100 ms ¹ and the third collision at the rate of 105 to 135 ms ¹ , whereby a mixture of the treated substances with air is dynamically compressed between the second and the third mechanical pulse up to 58% of the original volume of the mixture, since the working bodies imparting the second pulse to the treated grains are at the same time designed as accelerator compressor blades and the bodies imparting the third pulse to the treated grains are also designed as braking compressor blades. These bodies are arranged in circular rows of unequal diameter, with the center in the center of rotation of the rotors, each on one of the opposing rotors. Between these rows, a mixture of grains of the treated substances with air is dynamically compressed. This treatment produces an active filler according to the invention with grains of inorganic substances adhered to the surface and to the branches of the fractal grains. The mixture thus prepared is suitable as a dry building mixture, for example for the production of vibro-pressed building elements.

The above examples are intended only as possible examples and do not limit the scope of the invention to the embodiments thus described. The values of the Hausdorf dimension are given as approximate in these examples.

Claims (14)

PATENT CLAIMS A filler for building mixtures and products, characterized in that it contains at least 15% by weight, based on the total weight of the filler, of at least one thermoplastic arranged in the form of branch and / or stem fractals and / or combinations thereof, wherein the size fractals of branching and / or stem character is at most 15 mm in one dimension. Filler for building mixtures and products according to Claim 1, characterized in that it contains 15% by weight, up to 85% by weight, based on the total weight of the filler, of at least one thermoplastic, shaped into branch and / or stem fractals, and wherein the remainder, based on the total weight of the filler, consists of at least one cellulosic and / or lignocellulosic substance adapted to form fractals of a branch and / or stem character. Filler for building mixtures and products according to Claims 1 and 2, characterized in that the fractures are arranged at least partially in clusters. Filler for building mixtures and products according to any one of claims 1 to 3, characterized in that particles with a size of up to 300 μm are thermo-mechanically integrated into the surface of changes in the form of branch and / or stem fractals and / or combinations thereof. at least one substance selected from the group consisting of solid inorganic substances from the group of water-insoluble oxides, silicates, aluminosilicates, carbonates, phosphates and / or mixtures thereof. Filler for building mixtures and products according to any one of claims 1 to 3, characterized in that particles with a size in the range from 10 μm to 100 pm of at least one solid inorganic substance from the group comprising: hydraulic substances, latent hydraulic substances, silicates, aluminosilicates, oxides, hydroxides, carbonates, aluminates, phosphates and sulphates of Ca, Mg, Na, K and Fe and mixtures thereof, for creation of active filler. Filler for building mixtures and products according to any one of claims 1 to 5, characterized in that aluminum with a size of up to 150 pm in an amount of 0.05% to 0.3% by weight, based on the weight of the filler, to form a mixture for the preparation of aerated concrete reinforced with fractal filler. Filler for building mixtures and products according to any one of claims 1 to 6, characterized in that the magnitude of the changes in the spatial fractals of the branch and / or stem form and / or their combinations is at most 5 mm in one dimension. Process for the production of a filler for building mixtures and products as defined in at least one of Claims 1 to 7, characterized in that at least one thermoplastic with an input size of up to 35 mm is mixed with air in an amount ranging from 0.1 m ³ to 1. , 5 m ³ per Ikg of treated changes and subjected to at least two consecutive collisions with a working body moving at a speed of at least 80 ms ¹ for their heating and partial melting and at the same time are introduced into turbulent flow to disconnect and create changes in branch fractal form. and / or tribal tvam. Process for the production of fillers for building mixtures and products according to Claim 8, characterized in that solid solid fuel from sorted municipal waste of the SRF / RDF fraction containing at least 50% by weight of thermoplastics with a size of up to 35 mm is used as the thermoplastic. - 12GB 309173 B6 Process for the production of fillers for building mixtures and products according to Claims 8 and 9, characterized in that at least one SRF / RDF fraction is added to the grains of at least one thermoplastic and / or cellulosic and / or lignocellulosic substance and / or sorted municipal waste. inorganic substances selected from the group consisting of solid inorganic substances from the group of water-insoluble oxides, silicates, aluminosilicates, carbonates, phosphates and / or mixtures thereof. A process for the production of a filler for building mixtures and products according to claims 8 and 9, characterized in that at least one inorganic substance selected from the group consisting of hydraulic substances, latent hydraulic substances, oxides, hydroxides and Ca sulphates is added to the grains of at least one thermoplastic. and Fe and their mixtures, in a mutual ratio of weights and / or cellulose and / or lignocellulosic substances and / or sorted municipal waste of the SRF / RDF fraction to the inorganic substance from 1: 6 to 6: 1, and mixed before their collision with the working body with air in the amount from 0.3 m ³ to 1.2 m ³ of air per 1 kg of the mixture of treated changes. Process for the production of a filler for building mixtures and products according to any one of claims 8 to 11, characterized in that additives or / or dyes in solid or liquid state are added to the grains before they collide with the working body. A process for the production of a filler for building mixtures and products according to any one of claims 8 to 12, characterized in that aluminum with a grain size of at most 0.25 mm in an amount of 0.05% to 0% is added to the grains before they collide with the working body. 25% by weight, based on the weight of the mixture. A process for the production of a filler for building mixtures and products according to claim 9 or 11, characterized in that during the treatment the mixture is compressed to at least 60% of the original volume to increase the heating of the mixture and make its collisions with the working bodies more efficient.