CZ20223A3 - Geopolymer composite for special applications - Google Patents

Abstract

The composite contains cement composed of an alumino-silicate binder based on metakaolin and/or ground blast furnace granulated slag and/or fly ash in a selected unit amount with other additives, which are an alkaline activator consisting of an aqueous solution of sodium or potassium silicate in an amount of 65 to 112% of the weight of the used cement and fireclay with a particle size in the range of 0.1 to 0.5 mm in an amount of 5 to 120% of the weight of the used cement and/or fireclay with a particle size in the range of 0.05 to 0.1 mm in an amount of 5 to 80% of the weight of the used cement. In addition to the mentioned fireclay, it contains an admixture of microsilica with a fineness of 0.1 to 0.3 µm in an amount of 5 to 15% of the weight of the used cement and/or carbon microfibers with a diameter of 6 ± 1 µm and a fiber length of 6 mm in an amount of 1 to 5% of the weight of the used cement and/or sodium disulfite in powder form in the amount of 5 to 10% of the weight of the cement used and/or high-viscosity hydroxyethyl cellulose admixture in powder form in the amount of 1 to 5% of the weight of the cement used and/or gypsum in powder form in the amount of 4 to 5 weight used cement.

Description

Geopolymer composite for special applications

Field of technology

The present invention relates to a composite material based on a geopolymer composite modified for special applications using additional additives that improve its mechanical properties. The modified geopolymer composite is intended for use in applications that require improved mechanical properties compared to conventional geopolymers or concrete.

Current state of the art

Geopolymers are inorganic polymers created by polycondensation of alumino-silicon materials in an alkaline environment, which is usually achieved using special activation solutions consisting of alkali metal hydroxides and oxides. These materials can be of natural (metakaolin) or artificial origin (fly ash). During the reaction, so-called polysialates with a zeolitic structure are formed. This process mimics the natural processes of rock solidification, although it is much faster. Compared to Portland cement (the most commonly used building material), geopolymers have higher compressive strength, resistance to high temperatures, chemical influences, lower energy consumption and lower CO2 emissions during production, and lower thermal conductivity. On the other hand, the tensile strength when bending is lower, which makes it suitable to reinforce geopolymers, similar to concrete, whose tensile strength is also not very high.

Geopolymer composites can be used as an alternative to concrete, especially in environments where their properties are better utilized. For example, their resistance to high temperatures allows them to be used as molds for casting glass or metals, while their low thermal conductivity and the possibility of their simple foaming allows them to be used in passive fire protection.

For example, metal rods or fibers can be used as reinforcement for building materials. Metal rods, usually made of iron or steel, are most often used to reinforce concrete, which improve the tensile and bending strength of the resulting material (reinforced concrete). Alternatives to metal rods are various types of fibers, for example glass, textile, carbon, basalt fibers, etc.

A major disadvantage of geopolymers is the impossibility of using materials that cannot withstand their strong alkalinity, such as light metals or their alloys or glass, for their reinforcement. Glass fibers can only be used to reinforce geopolymers if they are alkali-resistant. For example, carbon fibers are suitable for reinforcing geopolymers, as they are able to withstand an alkaline environment and have a higher tensile strength than, for example, glass fibers. In addition, they are non-flammable, thermally stable, non-toxic and recyclable.

The essence of the invention

The subject of the invention is a geopolymeric composite material intended for special applications with a specific composition, which provide improved mechanical properties to the geopolymeric composite prepared in this way, making the material suitable for applications/in which it is stressed, for example as a road base, building material or material for application protective layers on buildings or other objects.

The geopolymer composite is made of cement composed of an alumino-silicate binder based on metakaolin and/or ground blast furnace granulated slag and/or fly ash in a selected unit quantity with other additives, which in the basic composition of geopolymers are an alkaline activator formed by an aqueous solution of sodium or potassium silicate in an amount forming 65 to 112% of the weight of cement and fireclay used. Alone is used in form

-1 CZ 2022 - 3 A3 coarsely ground fireclay with a particle size in the range of 0.1 to 0.5 mm in an amount of 5 to 120% of the weight of the cement used, or fireclay in the form of finely ground fireclay with a particle size in the range of 0.05 to 0 .1 mm in the amount of 5 to 80% of the weight of the cement used. The basic composition of the geopolymeric composite also contains the simultaneous presence of both coarsely ground fireclay in the indicated amount of 5 to 120% of the amount of geopolymeric cement used, and the simultaneous presence of finely ground fireclay in the indicated amount of 5 to 80% of the amount of geopolymeric cement used. The weight of the activator is in the range of 65 to 112% of the weight of the geopolymer cement used, however, usually 90% of the weight of the geopolymer cement is used.

In addition to the mentioned basic composition of the geopolymer material, the geopolymer may contain other additives, individually or in combination with each other. It is an admixture of microsilica, consisting of silicon dioxide nanoparticles with a fineness of 0.1 to 0.3 pm in an amount of 5 to 15% of the weight of the geopolymeric cement used.

Another admixture is carbon microfibers in the amount of 1 to 5% of the weight of the cement used, whereby the carbon microfibers have a diameter of 6 ± 0.3 pm with a fiber length of 6 mm.

Sodium disulfite in powder form as an emulsifier in the amount of 5 to 10% of the amount of geopolymeric cement used can form another component of the geopolymer, in addition to finely ground fireclay and/or coarsely ground fireclay. Sodium bisulfite is added to the liquid geopolymer mixture to accelerate geopolymerization.

High-viscosity hydroxyethyl cellulose in powder form forms an admixture in the amount of 1 to 5% of the weight of the geopolymeric cement used. Cellulose prevents cracking of the geopolymer and increases the elasticity of the mixture, which improves the possibility of application to different surfaces.

Finally, it is possible to add gypsum in powder form to the geopolymer material in an amount of 4 to 5% of the weight of the geopolymer cement used. Gypsum ensures faster drying and better adhesion to surfaces, especially vertical ones, however too high a content of gypsum (over 5% of the cement weight) would lead to cracking of the geopolymer when drying.

It is also possible, depending on their use and utilization, to reinforce all of the above-mentioned mixtures of geopolymeric material with one or more carbon fiber reinforcing nets with mesh sizes from 10 x 10 mm to 50 x 50 mm with a specific weight of 130 up to 500 g/m ² . Carbon fiber nets are suitable and do not degrade geopolymer mixtures in an alkaline environment.

The networks of carbon fibers and fireclay used in the base of the geopolymer material improve the mechanical properties of the resulting geopolymer composite. Such a network can be used in all geopolymer mixtures of the given composition to improve the mechanical resistance of the composite.

Examples of implementation of the invention

The following examples of embodiments of the invention serve to clarify it without limiting the invention in any way.

All geopolymer composite mixtures were prepared using the same procedure. First, the geopolymer cement was mixed with an alkaline activator and this mixture was thoroughly mixed, at least for a few minutes. Subsequently, finely ground fireclay and/or coarsely ground fireclay was added. Furthermore, the individual listed ingredients were gradually added, or all other ingredients listed, the mixture was further mixed and then applied to the test area and left to cure at room temperature for at least one day. If a carbon network was part of the geopolymer mixture, it was applied to the thickness of the layer together with the geopolymer composite.

-2 CZ 2022 - 3 A3

Example 1

The first geopolymer mixture contained, in addition to the basic ingredients, only fine fireclay with a size of 5 particles up to 0.1 mm in an amount of 80% of the weight of the geopolymer cement used, consisting of an alumino-silicon binder based on metakaolin. The amount of alkaline activator used represented 90% of the weight of the cement used. Geopolymer has a relatively fine structure, which enables the use of this mixture, for example, as building plaster. The properties of the mixture can be further improved by an additional additive or additional ingredients mentioned and ίο listed above.

Example 2

Another geopolymer mixture contained, in addition to the basic ingredients, only coarsely ground fireclay with a particle size of 15 in the range from 0.1 to 0.5 mm in an amount of 100% of the weight of the geopolymer cement used. The amount of alkaline activator used represented 90% of the weight of the cement used. Dull fireclay serves as a reinforcing filler in geopolymer mixtures, and this mixture can therefore be used, for example, as a building plaster with a dull appearance, when its mechanical resistance and low thermal conductivity are used. Geopolymer is also used as a basis for other mixtures, however, the properties of the composite can be improved by the listed additional additives.

Example 3

Another geopolymer mixture contained, in addition to the basic ingredients, coarsely ground fireclay with a particle size of 25 in the range from 0.1 to 0.5 mm in an amount of 80% of the weight of the geopolymeric cement used, and also finely ground fireclay with a particle size of up to 0.1 mm in an amount of 70% of the weight of the geopolymeric cement used, consisting of an alumino-silicon binder based on metakaolin and ground blast-furnace granulated stones. The use of the composite is similar to example 1 or example 2, it depends on the relative amount of both fireclays used. The amount of alkaline activator 30 used represented 90% of the weight of the cement used.

Example 4

Another tested mixture contained, in addition to the basic ingredients, finely ground fireclay with a particle size of 35 in the range from 0.1 to 0.5 mm in an amount of 100% of the weight of the cement used and an admixture of microsilica with a fineness of 0.1 to 0.3 pm in an amount constituting 10% weight of cement. The amount of alkaline activator used represented 90% of the weight of the cement used.

Similar to the previous composite mixture, this mixture can also be used, for example, as plaster 40 with a rough appearance, the silica used additionally strengthens the geopolymer mixture and increases its durability and chemical resistance.

Example 5

In addition to the basic ingredients, another created mixture contained finely ground fireclay with a particle size ranging from 0.1 to 0.5 mm in an amount of 100% of the weight of the cement used and an admixture of carbon microfibers with a diameter of 6 ±1 pm and a fiber length of 6 mm in an amount of 2% weight of cement used. The alkaline activator accounted for 90% of the weight of the cement used.

so Carbon fibers significantly improve the mechanical properties of the geopolymer, especially the tensile strength after bending, which is not very good for the geopolymer itself. In combination with fireclay, this mixture can be used as a building material. Carbon fibers are usually used in combination with silica.

-3 CZ 2022 - 3 A3

Example 6

Another composite mixture contained coarsely ground fireclay with a particle size ranging from 0.1 to 5 0.5 mm and an admixture of sodium disulfite in powder form. It alone represented 100% of the weight of the cement used, sodium disulfite 5% of the weight of the cement used, and the alkaline activator 90% of the weight of the cement used. The geopolymeric composite also contained geopolymeric cement of a selected mass amount, the amount of sodium bisulphite and fireclay used for the selected mass is indicated. Sodium bisulfite serves as an emulsifier of the liquid mixture, it is especially suitable for use with a large amount of other additives in the geopolymeric composite.

Example 7

Another suitable geopolymer mixture contains coarse fireclay and an admixture of high-viscosity 15 hydroxyethyl cellulose in powder form in an amount of 5% of the weight of the geopolymer cement used. Roughly ground fireclay contains 100% of the weight of the cement used in the composite, and 90% of the weight of the cement is used as an alkaline activator. The basis of the geopolymer is a geopolymer cement composed of an alumino-silicon binder based on metakaolin and power plant fly ash. The cellulose used prevents the cracking of the geopolymer and also increases the elasticity of the mixture. The mixture prepared in this way is suitable for the preparation of perfect layers with geopolymer or geopolymer in combination with additives that can cause them to crack, for example gypsum.

Example 8

This other example of an exemplary composite mixture contains finely ground fireclay and sadum in powder form. 60% of the weight of the geopolymer cement used is finely ground fireclay, 5% of the weight of the cement used is powdered gypsum and 90% of the weight of the cement used is an alkaline activator.

Gypsum accelerates the drying of cement and ensures better adhesion to the work surface, which makes geopolymeric composites containing gypsum suitable for use in applications on vertical surfaces. An example of use is plasters, but too high a gypsum content leads to cracking with geopolymer (over 5%).

Example 9

This example demonstrates the use of a carbon network, which is inserted either into the geopolymer form or into the thickness of the geopolymer layer, or to the surface on which the composite mixture is applied. The composite mixture contains geopolymeric cement, 90% of the weight of the used geopolymeric cement 40 alkaline activator and 100% of the weight of the used geopolymeric cement coarsely ground fireclay. A carbon fiber mesh with a mesh size of 30 x 30 mm and a specific weight of 250 g/m ² is used. Carbon meshes generally improve the mechanical properties of the geopolymer, especially the tensile strength. They are suitable practically in general for geopolymer of any composition.

Example 10

The specific feature of this geopolymer mixture is the high content of fine fireclay, specifically 80% of the weight of the geopolymer cement used, which is the highest content in the specified range, and zero content of hmbé fireclay. The mixture had the following composition. Geopolymer cement and alkaline activator 50 in the amount of 90% by weight of the amount of cement used are the basic ingredients of the composite.

Used fireclay with a particle size in the range of 0.05 to 0.1 mm. Other additives are microsilica with a volume of 0.1 to 0.3 pm in an amount constituting 10% of the weight of the cement used, carbon microfibers with a diameter of 6 ±1 pm and an average fiber length of 6 mm in an amount of 1% of the weight of the cement used, sodium disulfite in powder form in an amount of 5% by weight of used 55 cement, high-viscosity hydroxyethyl cellulose in powder form in an amount of 1% by weight

-4 CZ 2022 - 3 A3 of used cement and gypsum in powder form in an amount of 5% of the weight of the amount of cement used.

The geopolymer mixture prepared in this way is suitable, for example, as a material for repairing cracks in walls or as a plaster. Additional additives further improve the mechanical properties, speed up drying and limit cracking of the geopolymer. It is advisable to use the mentioned additives at the same time to significantly improve the mechanical and useful properties of the composite.

Example 11

The specific feature of this geopolymer mixture is also the content of fine fireclay, specifically 60% by weight compared to the mass content of geopolymer cement and zero content of coarse fireclay. Geopolymer cement and alkaline activator in the amount of 90% by weight of the amount of cement used are the basic ingredients of the composite. The mixture had the following composition. Microsilica with a fineness of 0.1 to 0.3 pm in an amount of 10% by weight of the amount of geopolymeric cement used, carbon microfibers with a diameter of 6 ±1 pm with an average fiber length of 6 mm in an amount of 1% by weight of the cement used, sodium disulfite in powder form in an amount 5% of the weight of the cement used, high-viscosity hydroxyethyl cellulose in powder form in the amount of 1% of the weight of the cement used and gypsum in powder form in the amount of 4% of the weight of the amount of cement used.

The geopolymer mixture prepared in this way is also suitable, for example, as a material for repairing cracks in walls or as a plaster. The use of additional additives further improves the mechanical properties, accelerates drying and reduces geopolymer cracking.

Example 12

The specific feature of this geopolymer mixture is the 100% content of heavy fireclay compared to the content of geopolymeric cement and zero content of fine fireclay. Coarse fireclay has a particle size in the range of 0.1 to 0.5 mm. Geopolymer cement and alkaline activator in the amount of 90% by weight of the amount of cement used are the basic ingredients of the composite. The mixture had the following composition. Microsilica with a fineness of 0.1 to 0.3 pm in the amount of 10% of the weight of the amount of geopolymeric cement used, carbon microfibers with a diameter of 6 ±1 pm with an average fiber length of 6 mm in the amount of 1% of the weight of the cement used, sodium disulfite in powder form in the amount of 5% of the weight of the cement used, high-viscosity hydroxyethyl cellulose in powder form in the amount of 1% of the weight of the cement used and gypsum in powder form in the amount of 4% of the weight of the amount of cement used.

The geopolymer mixture prepared in this way is suitable, for example, as a thermal insulation intermediate layer or plaster with a rough appearance, it can also serve, for example, as a basis for mixtures with other additives, for example pebbles to create a natural appearance of the plaster. The application of additional additives to the composite further improves the mechanical properties, accelerates drying and reduces geopolymer cracking.

Example 13

Another geopolymer mixture had the following composition. Its specificity is the combination of the content of hmbé fireclay with 60% of the weight selected from the content of geopolymeric cement and the current content of fine fireclay with 30% of the weight of the contained geopolymeric cement. Coarsely ground fireclay has a particle size in the range of 0.1 to 0.5 mm, finely ground fireclay showed particles in the range of 0.05 to 0.1 mm. Alkaline activator was used for 90% of the weight of the amount of geopolymeric cement used. Other ingredients of the composite are microsilica with a fineness of 0.1 to 0.3 pm in an amount of 10% of the weight of the amount of geopolymeric cement used, carbon microfibers with a diameter of 6 ± 1 pm with an average fiber length of 6 mm in an amount of 1% of the weight of the cement used, sodium bisulfite in in powder form in an amount of 5% of the weight of the cement used,

-5 CZ 2022 - 3 A3 high-viscosity hydroxyethyl cellulose in powder form in the amount of 1% of the weight of the cement used and gypsum in powder form in the amount of 4% of the weight of the amount of cement used.

The geopolymer mixture prepared in this way is, similar to the previous mixture in example 12, suitable for example as a thermal insulation intermediate layer or plaster with a rough appearance, it can also serve, for example, as a basis for mixtures with other additives, for example pebbles to create a natural appearance of the plaster. The above-mentioned composite additives further improve the mechanical properties, speed up drying and limit cracking of the geopolymer.

Industrial applicability

The geopolymer mixtures prepared in this way show improved mechanical and thermal insulation properties compared to the geopolymer itself, which enables their use, for example, as an interlayer for thermal insulation or material for repairing cracks in walls. Mixtures using rough fireclay are especially suitable for this. Mixtures with fine fireclay have a smoother surface, which makes them suitable, for example, as a resistant and insulating plaster, which is also helped by the high adhesion of this mixture to vertical surfaces.

Claims (7)

PATENT CLAIMS 1. Geopolymeric composite for special applications, created on the basis of geopolymeric cement, characterized by the fact that it contains cement composed of an alumino-silicon binder based on metakaolin and/or ground blast furnace granulated slag and/or fly ash in a selected unit quantity with other additives which are alkaline an activator consisting of an aqueous solution of sodium or potassium silicate in an amount of 65 to 112% of the weight of the cement used and fireclay with a particle size in the range of 0.1 to 0.5 mm in an amount of 5 to 120% of the weight of the cement used and/or fireclay with a particle size of range of 0.05 to 0.1 mm in the amount of 5 to 80% of the weight of the cement used. 2. Geopolymer composite for special applications according to claim 1, characterized in that it contains an admixture of microsilica with a fineness of 0.1 to 0.3 pm in an amount of 5 to 15% of the weight of the cement used. 3. Geopolymer composite for special applications according to claim 1, characterized in that it contains an admixture of carbon microfibers with a diameter of 6 ± 1 pm and a fiber length of 6 mm in an amount of 1 to 5% of the weight of the cement used. 4. Geopolymer composite for special applications according to claim 1, characterized in that it contains an admixture of sodium disulfite in powder form in an amount of 5 to 10% of the weight of the cement used. 5. Geopolymer composite for special applications according to claim 1, characterized in that it contains an admixture of highly viscous hydroxyethyl cellulose in powder form in an amount of 1 to 5% of the weight of the cement used. 6. Geopolymer composite for special applications according to claim 1, characterized in that it contains an admixture of gypsum in powder form in an amount of 4 to 5% of the weight of the cement used. 7. Geopolymer composite for special applications according to claim 1, characterized in that at least one carbon fiber network with a mesh size from 10 x 10 mm to 50 x 50 mm with a specific weight of 130 to 500 g/ m ² .