DE2701064A1 - Ceramic glazes for decorative floor tiles - with high abrasion resistance, contain hydrothermally hardened aerated cement - Google Patents

Abstract

Ceramic glaze consists of glass formers, fluxes and possibly colorants or pigments and also contains 5-50 (10-35) wt. % hydrothermally hardened aerated cement. The aerated cement is produced by foaming a mixt. of chalk, cement, quartz sand and water followed by hardening in an autoclave. The SEGER formula for the glaze is: Li2O 0-0.1; Na2O 0-0.1; K2O 0-0.2; CaO 0.2-0.7; MgO 0.01-0.4; BaO 0-0.1; ZnO 0.05-0.6; PbO 0-0.2; Al2O3 0.15-0.4; Fe2O3 0-0.1; SiO2 0.8-2.0; ZrO2 0-0.4; TiO2 0-0.4. The hydrothermally hardened aerated cement is cheaper than Wollastonite which is usually used for this application. Aerated cement is readily available and is of uniform compsn. The high specific surface of the cement aids the reactions in forming the glaze.

Description

Ceramic Glaze The invention relates to a ceramic glaze Based on glass formers, melting auxiliaries and, if appropriate, color bodies and / or Pigments.

Glazes are known to be glasses adapted to the ceramic body. They consist essentially of glass formers, so oxides such. B. SiO2, B203 inter alia, and from melting aids such. B. Na 2 O, K 2 O, CaO, MgO, PbO, etc. These Substances are present in the melt in the form of oxidic compounds.

If possible, inexpensive natural substances are used as starting materials used, for example in the form of natural alkaline earth carbonates, which when Burning turns into flux oxides. In particular, lime comes into consideration here, for example in the form of dolomite, calcite and the like. disadvantage this Alkaline earth carbonates lie in the fact that they are used to split off gas above the transformation range tend, which can lead to defects in the glaze. As a result, surface defects arise, which reduce the abrasion resistance.

It is known to eliminate the disadvantages outlined above by natural or artificial wollastonite used instead of alkaline earth carbonates will. In the case of wollastonite, no gas is split off, so that in the finished glaze no errors based on CO2 gas elimination reactions can occur.

Such glazes show good abrasion resistance. The production However, wollastonite is complex and, as a result, wollastonite is expensive. In many In some cases, therefore, the advantages that can be achieved by wollastonite can be omitted Do not realize cost reasons.

The object of the invention is therefore to create a ceramic glaze, which on the one hand avoids errors due to gas separation during firing and Achieves at least as good abrasion resistance as with the addition of wollastonite is available, and on the other hand not to an increase in the price of the glaze in comparison leads to glazes made with alkaline earth carbonate.

According to the invention, this object is achieved by a ceramic glaze based on glass formers, melting aids and, if appropriate, color bodies and / or Pigments, which are characterized by a content of hydrothermally hardened aerated concrete is.

Aerated concrete is a hardened lightweight concrete that consists of a plastic mortar made from lime, cement, aggregate such as quartz sand and water is produced after the addition of gas-forming substances. Mineral supplements are used as surcharges Flours and fine-grain industrial waste products such as coal ashes and their dusts.

Binders and aggregates become intimate when water is added mixed and by adding a gas-generating propellant such as hydrogen peroxide, Chlorinated lime or aluminum powder puffed up into a fine-pored pulp. After the first The still moist mass can be tied and cut to the desired dimensions and is then hydrothermally hardened in pressure vessels. Typical hardening conditions are 8 to 16 hours at 8 to 16 atm. The density of the hydrothermally hardened Aerated concrete is generally between 0.5 and 0.8 g / cm3.

A typical example of one that is particularly suitable within the scope of the invention Aerated concrete product can be obtained from a mixture containing 15 to 30% by weight of fired Lime, 3 to 15% by weight cement and 55 to 82% by weight quartz sand, no more of which than 10 wt .-% are greater than 90 / µm. Aerated concrete generally has something like the following Composition: SiO2 50 to 55% by weight CaO 20 to 25% by weight Fe203 0.5 to 1.5% by weight Al203 3 to 8% by weight MgO 2 to 3% by weight loss on ignition 15 to 20% by weight of the hardened Aerated concrete is finely ground as a component of the ceramic according to the invention Glaze used.

He replaces both a part of the glass formers and one of them Part of the melting aid. It can therefore use common recipes for ceramic glazes be modified according to the invention by corresponding parts of the previously used Glass formers and melting aids are omitted and hardened by the finely divided Aerated concrete to be replaced.

The glazes according to the invention are suitable for both raw glazes as well as for frit glazes. You can use for building ceramics, Sanitary ware, Porcelain glaze as well as for earthenware or

Earthenware glazes are used. Those according to the invention are also suitable ceramic glazes, depending on the composition, for both high and low Firing stages.

The glazes according to the invention can likewise be white or colored getting produced. In the case of white glazes, it is recommended in the invention when the aerated concrete is being ground, it is contaminated by iron particles formed during the grinding process to avoid. In this case, however, it is optionally also possible to use iron particles of this type to be removed again magnetically.

In addition, the glazes according to the invention are with oxides or colored bodies Can be colored in the same way as conventional glazes. The conditions for persistence the color bodies are not changed by the use of aerated concrete according to the invention.

Those used in the manufacture of ceramic casting slips Condensers can also be used in the context of the invention. kaolin can be completely or partially omitted as adjusting means. It is then possible the viscosity with relatively small amounts of liquefiers, such as. B. Soda, water glass, Polyethylene glycol or polyphosphates, to be set precisely reproducible.

The glaze according to the invention expediently contains the hardened aerated concrete in amounts between 5 and 50% by weight. A proportion of aerated concrete from 10 to is preferred 35 wt%.

The molar percentage composition of the glaze according to the invention changes compared to the known glazes through the use of aerated concrete material not essential. Due to the content of alkali oxides and iron oxide in aerated concrete however, the proportion of these substances can generally be higher than in the case of conventional glaze compositions. For example, owns a preferred aerated concrete material, for example the following percentage composition (% by weight): Na20 0.5 to 1.5 K20 0.5 to 1.5 CaO 25 to 33 MgO 1 to 3 Al2O3 2.5 to 4 Fe203 1 to 2 SiO2 45 to 55 TiO2 0.1 to 0.4 Loss on Ignition 12 to 15 In general, therefore, the composition becomes one glaze according to the invention have a composition according to the SEGER formula, such as Listed below (parts by mole): + The basic oxides are multiplied by a factor multiplied so that the sum is 1.

Li20 0 to 0.1 Na20 0 to 0.1 K20 0 to 0.2 CaO 0.2 to 0.7 MgO 0.01 to 0.4 BaO O to 0.1 ZnO 0.05 to 0.6 PbO O to 0.2 Al203 0.15 to 0.4 Fe2O3 0 up to 0.01 SiO2 0.8 to 2.0 Zero, 0 to 0.4 TiO2 0 to 0.4 As part of of the invention, however, glazes can also be used for special purposes, in which individual components are outside the range given above or contain other inorganic components. In addition, as already mentioned above, color bodies and / or liquefiers may be included.

The glaze according to the invention allows the use of a Aerated concrete production resulting waste product, which is generally through especially uniform composition, instead of cheap natural substances of mostly fluctuating composition without increasing the prime costs and with very desirable properties of the finished glaze. Regarding the properties achieved and the reliability in the composition at least equivalent to glazes made using expensive minerals, such as wollastonite. In addition, since aerated concrete depending on the situation on the Hardware store is often in surplus, becomes one in this regard as well Relief achieved. In this way aerated concrete products can be recycled, which are not to be sold in the construction sector. Despite the relatively low specific The weight of the aerated concrete resulted from grinding with the other, heavier ones Components of the glaze no segregation problems. This could be specific to the big one Surface of the aerated concrete, which is due to its high content of essentially spherical pores is caused.

The with the proves to be particularly favorable when firing hydrothermal hardening of the aerated concrete resulted in dissolution of the quartz grain and the clayey Substances that result in increased activation energy. This will be Solid-state reactions are facilitated and flux additives can thereby be reduced will.

The glaze according to the invention can be broken down depending on its composition all areas, such as B. building ceramics, sanitary ware, porcelain glaze, earthenware glaze, Use earthenware glaze, etc.

It also has a very wide range of applications the firing temperatures. For example, a glaze according to the invention can with a composition of about 55% by weight of a commercially available frit (90036 of Degussa) with a composition according to the SEGER formula of 2.0 SiO2, 1.0 B203 and 1.0 Pbo, 5% kaolin and 40% aerated concrete at temperatures between about 940 and 13000C, i.e. in the same area as wollastonite glazes are applicable.

The glaze according to the invention has a surprisingly high abrasion resistance, which at least corresponds to that of corresponding glazes containing wollastonite the abrasion resistance achievable with the addition of other alkaline earths is determined by the Glaze at least achieved. The crazing resistance meets the requirements that are given for example by the autoclave test. Also the acid resistance according to DIN 51092 is fulfilled.

The following examples further illustrate the invention.

EXAMPLE 1 1 to 4 In the following Tables I and II, the Composition of four different glazes according to the invention in% by weight as well as specified according to the SEGER formula.

The glaze of Example 1 is particularly suitable for wear-resistant Floor tiles and is burned in in the temperature range from 1120 to 11800.

The glaze of Example 2 is also suitable for abrasion resistant Floor tiles and is suitable for the same firing temperature range as the glaze of example 1. It differs from the latter in that it is more resistant to alkalis.

The glaze of Example 3 is again a glaze with similar uses as the glaze of example 2. The acid resistance is high, the alkali resistance does not quite reach the values of Example 2.

Example 4 is particularly suitable for an abrasion-resistant glaze.

TABLE I Example No. 1 2 3 4 Aerated concrete1) 26.67 15.12 21.65 14.05 Potash feldspar 30.79 - 16.02 20.36 kaolin 10.42 19.52 2.08 3.88 ZnO 14.60 4.89 5.88 5.21 BaC03 0.84 7.47 - -ZrSiO4 7.79 - 21.44 19.27 TiO2 6.89 8.96 - -Dolomite - 18.58 - -Calc. Alumina - 1.25 6.34 1.61 Petalite - - - 11.51 Quartz - 5.82 - -Calkspar - - 12.34 13.46 Li2CO3 - - 2.20 - bentonite - - 0.5 - frits No. 12) - 9.81 - - frits No. 23) 2.01 0.81 - -Frits No. 34) - 7.77 12.05 10.65 TABEL II Composition according to SEGER formula Example No. 1 2 3 4 Li20 - - 0.07 0.048 Na20 0.031 0.03 0.007 0.038 K20 0.133 0.02 0.07 0.082 CaO 0.372 0.42 0.59 0.554 MgO 0.034 0.23 0.027 0.021 BaO 0.01 0.08 - -ZnO 0.422 0.14 0.17 0.163 PbO - 0.08 0.1 0.095 A1203 0.25 0.20 0.25 0.257 Fe203 0.007 - 0.005 0.002 SiO2 1.72 1.08 1.3 1.859 Zr ° 2 0.1 - 0.275 0.266 TiO2 0.21 0.24 0.005 0.002 Notes: 1) SiO2 49.01; Al203 3.38; TiO2 0.26; Fe203 1.54; CaO 28.92; MgO 1.91; Na20 0.77; K20 0.74; Loss on ignition 11.47 Wt%.

2) so SEGER formula SiO2 2.0; ZnO 0.15; PbO 0.25; CaO 0.2; Na20 0.2; K20 0.2 mole.

3) see SEGER formula SiO2 2.2; Al203 0.2; Na 2 O 1.0 mol.

4) so SEGER formula SiO2 1.0; PbO 1.0 mole.

Example 5 A particularly suitable for wall tiles and for baking Glaze determined at around 960 ° C has the following composition: aerated concrete 40.0 % By weight kaolin 5.0% by weight No. 4 frit 55.0% by weight The aerated concrete had the same Composition as in Examples 1 to 4. Frit No. 4 corresponds to the following SEGER formula: SiO2 2.0; B203 1.0; PbO 1.0 mole.

Example 6 A stoneware glaze for a stoving temperature of 1140 up to 1160 ° C has the following composition in% by weight: aerated concrete 19.1 kaolin 25.7 Calcite 4.8 ZnO 2.9 TiO2 2.9 Quartz 23.8 Frit No. 5 9.6 Color bodies 6.0 Relatin 0.7 frit no. 5 has the following SEGER formula: SiO2 1.8; B203 1.0; Al203 0.1; Na20 0.5; K20 0.5 mole.

Claims (5)

P a t e n t a n s p r ü c h e Ceramic glaze based on glass formers, Melting aids and, if necessary, color bodies and / or pigments, marked through a content of hydrothermally hardened aerated concrete. 2. Glaze according to claim 1, characterized in that the aerated concrete one by foaming a mixture of lime, cement, quartz sand and water and then Autoclave curing product is obtained. 3. Glaze according to claim 1 or 2, characterized in that the Aerated concrete proportion is 5 to 50% by weight. 4. Glaze according to claim 3, characterized in that the aerated concrete portion Is 10 to 35 wt%. 5. Glaze according to one of the preceding claims, characterized through the SEGER formula. Li2O 0 to 0.1 Na2O 0 to 0.1 K20 0 to 0.2 CaO 0.2 to 0.7 MgO 0.01 to 0.4 BaO O to 0.1 ZnO 0.05 to 0.6 PbO O to 0.2 A1203 0.15 to 0.4 Fe203 O up to 0.01 SiO2 0.8 to 2.0 Zur02 O to 0.4 TiO2 0 to 0.4