DE2813863C2 - Artificial stone with a wear-resistant top layer and process for its production - Google Patents

Description

The invention relates to an artificial stone with a wear-resistant top layer, which is at least two solid interconnected layers, one of which has a high wear resistance, and a

ii has intermediate mixing zone, also on a Method for producing such an artificial stone.

Artificial stones with a certain wear resistance of the top layer are known. These are

in around stones with hydraulic binding of the inserted Materials. The high wear resistance of the top layer is based on the fact that it contains natural stone, roughly the proportion of fine grit is greater than in the rest of the stone.

v> There are already fire-resistant furnace components made up of two or more layers with different ones physical properties and an intermediate mixing zone became known, one of the layers against mechanical abrasion

Wi is resilient. However, these are also based Furnace components, which can be designed as stones, slabs or linings, on the basis hydraulically bound materials.

This is based on hydraulic binding of the used

hi materials based stones are likely to meet the requirement Sufficient wear resistance of a deck still light with low load and without the influence of temperature suffice. For many uses exists

but the additional requirement for high wear resistance at elevated temperatures and times high thermal shock resistance.

In addition to rock materials with high wear resistance against mechanical influences such as abrasion, materials are also known that have a high resistance to thermal shock to have. On the other hand, cast basalt and copper slag are examples of materials with high wear resistance Clinker or fireclay as a material with high resistance to changes in temperature. However, none of these materials meet the requirement that frequently occurs in practice for both high wear resistance, at least one top layer, and great thermal shock resistance.

There is a lack of cast basalt and copper slag, which are characterized by high wear resistance and thus able to withstand great mechanical stresses with sufficient resistance to temperature changes. This is particularly the case when the material density is high to achieve high wear resistance is realized, so that with mechanical loads as little wear-resistant substance as possible is removed and little or no open porosity roughen the surface and thereby promotes erosive removal.

Such a dense and thus wear-resistant material has the disadvantage that it has a relatively high coefficient of thermal expansion meet with low thermal conductivity. This follows from changes in temperature and gradients internal stresses, which usually damage the material immediately and catastrophically. Such a material therefore does not have a thermal shock resistance which satisfies the requirements in practice.

Clinker and fireclay, on the other hand, are characterized by their high resistance to temperature changes, are in view of their moderate wear resistance, especially against abrasion, only to a small extent mechanically stressable.

The aim of the invention is therefore to provide an artificial stone, which in addition to high wear resistance in one when used as intended mechanically stressed upper layer, great resistance to temperature changes having.

This object is achieved by the invention described in claim 1.

Based on the knowledge that to achieve a wear-resistant covering, a high material density is required, even with materials that are already characterized by high wear resistance, whereas porous material, with the same material data, is able to compensate for the stresses resulting from temperature changes due to the smaller inner cross-sections and suffers no or at least no catastrophic damage, the invention is based on the idea of realizing an artificial stone with the required properties as a sintered composite stone with a substructure of porous nature and a top layer of high wear resistance, whereby the top layer is designed to be relatively thin ^c ( <\ \ "! ow to turn on temperature gradients do not tear. Furthermore, the invention is based on the same kind of materials which are suitable for achieving the desired different densities in the porous base and a wear-resistant top layer but differ in the proportion of a flux that melts at the firing temperature.

The invention is therefore a combination of similar materials in such a way that that on a porous substructure a dense wear layer is applied thin thickness, which in view of its small thickness does not tear at temperature gradients, but nevertheless the stone at its Surface that gives the substructure the lack of high wear resistance. The similar composition

The shortening of the substructure and top layer ensures a good and permanent connection.

Claims 2 and 3 describe useful configurations of the artificial stone according to claim 1. Claim 2 relates to an artificial stone

π from a substructure of relatively great thickness and a thin cover layer applied thereon, the flux portion being in a mixing zone for The substructure is steadily decreasing. According to claim 3, the artificial stone can also be designed so that the river

- ¹ H middle part and thus the density decreases steadily with the distance from the surface of the wear layer, so that in a relatively thin top layer, due to the high flux content, the density required to achieve the required wear resistance

2i is present, but the substructure with increasing Distance from the wear resistance has increasing porosity.

Another object of the invention is to provide a method of making a

iii artificial stone as described in claims 1 to 3 Art. This object is achieved by the invention described in claim 4.

In the method according to the invention it is a question of the fact that on the same or at least similarly

Rock powder mixtures based on raw materials in an aqueous suspension in such a way in a matrix be entered that a partial filling corresponding to the substructure has a high proportion of Support material, but a relatively small

Hi gen proportion of flux and accordingly comparatively has high porosity, while the top layer intended to form the required wear layer In contrast, it has a higher proportion of flux. When firing a previously cold-

r> pressed green body sinters the supporting material, i.e. the rock parts that do not melt at the firing temperature, so that, in view of the low flux content, a largely porous substructure is created while in the top layer as a result of the larger

-, o Flux content high density and thus good wear properties be achieved.

Appropriate refinements of the method according to the invention are set out in claims 5 to 13 described.

-, <; Thus, claims 5 to 8 teach the use appropriate aggregates and rock compositions for the substructure and the top layer. By changing the rock mixture, the properties of the product can be specifically influenced.

ho So can a denser and thus more resistant material against mechanical stresses can be obtained, on the other hand, an increased resistance to temperature changes due to an increased proportion of support material.

_h -, Patent claim 9 teaches the structure of such an artificial stone as a layered body, which comes about that the rock powder mixtures with different flux content in succession

a die is filled and then pressed into a green compact and then fired. The im Claim 8 specified pressure has proven to be useful for precompaction of the die filling proven. It has also proven advantageous to shorten the burning time, initially with a moderate one Temperature over a predetermined period of time during the pressing of the green compact while still in the latter Drive out any remaining water and then start the firing process in successive temperature steps to carry out different exposure times.

Claims 12 and 13 teach the appropriate temperatures and exposure times to be used. By varying the burning time and temperatures, targeted influencing is also possible of the product. This leads to a temperature that is noticeably higher than the sintering temperature of the support material Firing temperature also too high density and thus improved wear resistance. Another Targeted influencing is achieved by varying the duration of exposure to the temperatures used.

In the following, the structural design of an artificial stone according to the invention will be shown on the basis of the 2 'drawings and typical material compositions for the substructure and the top layer are given will. It shows

Fig. 1 in a sectional view through a composite stone according to the invention with its structure a porous substructure of great thickness and a comparatively thin top layer, the great material density and consequently has high wear resistance, and

FIG. 2 shows a view like FIG. 1, but with a drawn in Temperature gradients, with a high temperature load on the wear layer surface is subordinated.

For aggregates of about 0.02 to 1.0 mm, for example, granite, quartz sands and other minerals with a high silicon dioxide content come into consideration as support materials, while basalts, slag, magnesites and other high-melting eruptive stones and slag are used as fluxes. A typical composition is for the
Granite substructure 6 parts by weight

Basalt 3 parts by weight

Top layer of granite 3 parts by weight

Basalt 6 parts by weight

Copper slag 6 parts by weight.

The rock flour of the aforementioned compositions are mixed separately for the top layer and the substructure as an aqueous slurry with a water content of about 50%. The slurry is then poured into a die, the top layer and the substructure one after the other, and precompacted at pressures between 50 and 200 N / mm ² . The green compacts are then first subjected to a temperature load of approx. 200 ° C. for a period of about half an hour in order to drive out the residual water still contained after the pre-compression. The subsequent, actual firing process takes place in two successive temperature steps. The support material is sintered over a period of about three hours at a temperature of 1100 ° C. This is followed by a burning phase at approx. 1200 ° C., which extends, for example, over a period of 15 minutes and during which the flux used melts.

The above temperature information can vary within a range of, for example, ± 50 ° C, in order to influence the material properties in accordance with the requirements. With otherwise the same material data, a higher firing temperature leads to increased wear resistance, on the other hand, one at the lower limit of the melting point of the flux used Temperature in the last firing phase and a lower flux content make it more resistant to temperature changes Material.

In the case of artificial stones produced on the basis of the above material data using the firing temperatures and firing times also specified, compressive strengths of around 200 N / mm ² and thermal shock resistance of up to around 600 ° C. through damage-free quenching in water could be determined. The abrasion resistance achieved was at least equivalent to that of copper slag or cast basalt.

Such a stone, which is designated in its entirety by 10, is illustrated in FIG. 1 in cross section through the substructure 11 and the cover layer 12 connected to it. The porous substructure with A high proportion of support material is connected to the cover layer in the area of the mixing zone 13. the The top layer has only a small thickness, but has a much higher flux content and therefore greater Dense than the substructure. Accordingly, the surface 14 of the cover layer is characterized by high Wear resistance. In the area of the mixing zone 13, the substructure and top layer are in view of their similar compositions permanently connected.

The course of the temperature gradient entered in FIG. 2 illustrates the characteristic property of ceramic and mineral materials of low thermal conductivity at high density. Thus, a temperature T ₁ occurring on the surface 14 of the artificial stone up to the boundary layer only drops relatively little to a temperature T- , which the flat course of the temperature gradient 15 between the surface 14 of the wearing layer 12 and the mixing zone 13 illustrates, but disproportionately more between the boundary layer and the underside of the substructure 11, which is remote from the cover layer 12, to a temperature T ₃ . It is assumed that _{T 1} > T ₂ and (Γ, - T ₇ ) < (T ₂ - T ₃ ).

1 sheet of drawings

Claims (13)

Patent claims: 1. Artificial stone with a wear-resistant top layer, the at least two firmly connected Layers, one of which has high wear resistance and one in between Has mixing zone, characterized by the Construction as a sintered composite stone (10) with a porous substructure (11) with a lower packing density and in that the layer (12) with high wear resistance has a high, but low density Thickness, and that the substructure! and the wear-resistant layer on similar rock flour mixtures which are based on rock that sintered well at the firing temperature and not melting as the support material and at the firing temperature liquid rock or slag was used as flux, with the flux content in the large Dense, wear-resistant layer is much larger than in the porous substructure. 2. artificial stone according to claim 1, characterized in that the flux content in one Mixing zone (13) between the wear-resistant layer (12) and the substructure (11) to the latter decreases towards. 3. artificial stone according to claim 1, characterized in that that the flux content and thus the density at a distance from the surface (14) the wear-resistant layer (12) is lower. 4. A method for producing an artificial stone with a wear-resistant top layer according to one of the Claims 1 to 3, characterized in that rock flour mixtures in aqueous suspension from rock that sintered well at the firing temperature, but not melting, as support material and Entered from burning temperature liquid rock or from slag as a flux in a die in such a way that a wear-resistant layer of small thickness has a higher proportion of flux than the rest of the filling, and that this filling is then cold-pressed to form a green compact and then the latter is burned. 5. The method according to claim 4, characterized by the use of rock flour with a Grain between 0.02 and 1.0 mim. 6. The method according to claim 4 or 5, characterized in that the mixture for the substructure about six parts by weight of non-melting at the firing temperature and about three Parts by weight of rock that melts at the firing temperature, while the mixture for the wear-resistant top layer about three parts by weight made of non-melting support material and about twelve parts by weight of flux. 7. The method according to claim 6, characterized in that it is at the firing temperature non-melting support material around granite, on the other hand with the one used as a flux Stone is basalt and / or copper slag. 8. The method according to claim 6 or 7, characterized in that the mixture for the substructure consists of granite and basalt, while the mixture used for the wear-resistant top layer Flux contains roughly equal parts basalt and copper slag. 9. The method according to any one of claims 4 to 8, characterized in that the rock flour mixtures present in a pulpy consistency after mixing for the formation of the substructure and the wearing layer of small thickness successively filled into the die and then pressed together to form a green compact and then to be burned. 10. The method according to any one of claims 4 to 9, characterized in that the die fillings are pressed into green compacts at a pressure between 50 and 200 N / mm ^{2 and cold.} 11. The method according to any one of claims 4 to 10, characterized in that the green compacts are initially exposed to moderate temperature subjected to expelling the residual water and then in successive temperature steps different exposure times can be fired. 12. The method according to claim 11, characterized in that that to drive out the residual water, the green compacts for a period of about half an hour at a temperature of about 200 ° C subjected and then fired at the sintering temperature of the support material (approx. 1100 ° C), whereupon the firing temperature is briefly increased above the melting temperature of the flux. 13. The method according to claim 11 or 12, characterized characterized in that the green compacts at the sintering temperature of the support material over a period of time Fired for about three hours and then the fin effect one above the melting point of the Flux lying temperature of about 1200 ° C for a period of about 15 minutes will.