DE29518128U1 - Ecological building material - Google Patents

Description

Ecological building material
Field of technology

The invention relates to an ecological building material which is formed from at least one substance selected from a group comprising fly ash, ash components, slag, waste glass, sand, clay, lime and cement, and a suitable binder.

State of the art

The ever-increasing amount of fly ash, ash components and slag from power plants, combined heat and power stations and waste incineration plants currently represents a major ecological problem. In view of the fact that fly ash from power plants is considered to be hazardous waste due to its content of heavy metals and other toxic contaminants, and in view of the fact that ash components and slag from combined heat and power stations and incineration plants are dangerous from the point of view of leaching and subsequent reactions with other components of the disposal sites, it is essential to protect disposal sites for the above-mentioned waste against wind blowing and groundwater and rainwater leaching, which is a problem that is difficult to solve in view of the large quantities of this waste. A similar problem is posed by dumping sites for all-alloy glass, slag, low-quality waste sands and clays, and waste lime and cement. Recently, this traditional industrial waste has also included waste from thermoplastics, which is formed on the one hand from used food packaging and on the other hand from thermoplastic waste from the thermoplastic materials processing industry. When recycling thermoplastic materials,

a relatively large amount of waste that is no longer economically viable to sort and recycle. It is therefore obvious that in recent years the effort to find new ways to process the waste materials mentioned above into usable products has become increasingly greater. The conversion of the waste materials mentioned above into building materials has shown relatively promising results. Hydraulic binding agents are added to the waste materials mentioned above and the resulting mixtures are converted into concrete-like building materials with the addition of water. The common disadvantage of all these conversion methods is the need to add a relatively large amount of quality cement to the waste; these processes are also quite sensitive to the composition of the waste material, which in most cases requires the use of energetically demanding classification stages. In view of the above, there is currently an acute need to find a process that would solve the described problem of waste materials in a global manner and, if possible, without using subsequent materials that could be used elsewhere.

Core of the invention

The above-mentioned disadvantages are not exhibited by the building material according to the invention, which is formed from at least one substance selected from a group comprising fly ash, ash components, slag, as well as glass waste, sand, clay, lime and cement, and a binding agent and whose essence consists in the fact that it contains as a binding agent at least one thermoplastic waste plastic in a weight proportion of 5 to 97% by weight, based on the total weight of the building material.

The ecological building material according to the invention is

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joint crushing of the components present in the waste or by separate crushing of the components of the individual waste and mixing them in any sequence, whereby at least one component of the resulting mixture forms a thermoplastic plastic contained in this mixture in the above-mentioned amount, after which the mixture is heated during mixing to a temperature which is at least as high as the melting temperature of the contained thermoplastic waste plastic or thermoplastics, but lower than the degradation temperature of the contained thermoplastic waste plastic or thermoplastics, until the waste components other than the thermoplastic plastic are sufficiently saturated with the melt of the thermoplastic plastic, and the mass obtained in this way is pressed into the desired shape.

The advantage of the new building material according to the invention is that the particles of the waste mentioned, other than the thermoplastic, have a porous structure and a large specific surface and therefore also a high absorption capacity, which means that when they come into contact with the melt of the thermoplastic waste, the non-thermoplastic waste components are intensively saturated with the thermoplastic and the pores of the non-thermoplastic material are closed; this prevents the leaching of the non-thermoplastic material and its chemical reactions with the surrounding environment. The content of thermoplastics significantly facilitates pressing, increases the elasticity of the building material obtained and its mechanical and chemical resistance. The presence of the non-thermoplastic components means that the building material obtained has self-extinguishing properties. The inventive

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The building material is fully recyclable and its production produces practically no waste.

Examples of implementation example 1

A waste consisting of power plant fly ash and slag in a weight ratio of 4:1 with a grain size of 0.1 to 3 mm is mixed with 25% by weight (based on the total weight of the mixture obtained) of polyvinyl chloride waste crushed to a grain size of 0.1 to 7 mm until a practically homogeneous mixture of the above-mentioned components is obtained, after which this mixture is heated to 220 ⁰ C with constant kneading until the thermoplastic material completely melts and penetrates the power plant fly ash and the slag (15 minutes). The pliable mass thus obtained is then pressed under 2.5 MPa pressure into multi-purpose waste pipes.

Example 2

A waste consisting of power plant fly ash, ash components from an incineration plant for low-quality hard coal and waste sand in a weight ratio of 4:1:0.5 with a grain size of 0.1 to 3 mm is mixed with 45% by weight (based on the total weight of the mixture obtained) of polyvinyl chloride waste shredded to a grain size of 0.1 to 7 mm until a practically homogeneous mixture is formed, after which this mixture is heated to 250 ⁰ C with constant kneading until the thermoplastic material completely melts and penetrates the individual waste components (10 minutes). The supple mass thus formed is then pressed into roofing parts under 1.7 MPa pressure.

Example 3

Waste consisting of power plant fly ash, ash from an incineration plant for low-quality hard coal and slag from the municipal waste incineration plant in a weight ratio of 5:1:1 with a grain size of 0.1 to 3 mm is mixed in a flotation drum until a practically homogeneous mixture is obtained, whereby the material to be mixed is heated to 230 ⁰ C during mixing, after which the mixed and heated waste is sprinkled with melted polyethylene waste until the power plant fly ash, coal incineration plant ash and slag are saturated with the above-mentioned polyethylene by 30% (based on the total weight of the mixture obtained). The resulting pliable mass is then pressed under 2 MPa pressure into large-sized plates.

Example 4

A waste consisting of power plant fly ash, waste sand, waste glass, waste lime and blast furnace slag in a weight ratio of 1:2:3.5:1:1 with a grain size of 0.1 to 2 mm is mixed in the fluid bed until a practically homogeneous mixture is formed, whereby the material to be mixed is heated to 210 ⁰ C during mixing, after which the mixed and heated material is sprinkled with melted polyethylene waste. The resulting supple mass, which accumulates under the fluid bed and contains 15% by weight (based on the total weight of the supple mass mentioned) of polyethylene, is pressed under 1.5 MPa pressure to form flat GJround tiles.

Claims (1)

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U < · EXPECTATIONS Ecological building material formed from at least one substance selected from a group comprising fly ash, ash components, blast furnace and coal combustion plant slag, waste glass, sand, clay, lime and cement, characterized in that it contains as a binding agent at least one thermoplastic waste plastic in a weight proportion of 5 to 7% by weight, based on the total weight of the building material.