DD205888A1 - SINTERED FIRE-RESISTANT MATERIALS WITH HIGH CORROSION RESISTANCE - Google Patents

Abstract

THE INVENTION INVOLVES TIN DIOXIDE-CONTAINING FIRE-RESISTANT MATERIALS AND IS USED IN THE GLASS INDUSTRY, ESPECIALLY FOR MELTING AGGRESSIVE OPTICAL SPECIAL GLASSES. THE OBJECTIVE OF THE INVENTION IS THE PREPARATION OF SINTER CORROSION-RESISTANT FIRE-RESISTANT MATERIALS, WHICH OBTAIN A MINIMUM CONTACT EFFECT IN THE MELTING AGGRESSIVE GLASSES. THIS IS ACHIEVED BY THE INVENTIVE OF THE BINDER COMPRISING 20-50% MASS SNO2, INCLUDING SINTER ACCELERATORS NB2O5, LI2O AND ZNO, WHERE THE TOTAL QUANTITY OF THE SINTERED ACCELERATOR RELATED TO THE SNO2 CONTENT IS A MAXIMUM OF 4.0% MASS. AS A RESINANT, CORROSOINT-RESISTANT MATERIALS, SUCH AS KORUND, MULLIT, ZIRCONSILICATE, CIRCON OXIDE, CORONA BADDELEYITE, ARE USED IN THE CONCENTRATION AREA 0-80% MASSES SINGLE OR IIM MIXTURE. OEKONOMICALLY BENEFICIAL WILL BE THE LEVENTS FROM WASTE AND WASTE. ABORT MATERIALS, e.g. MELONGED STONES, WON. AFTER FORMING THROUGH CASTING OR PRESSING, THE INFLUENCE AT TEMPERATURES BETWEEN 1300 DEG C AND 1500 DEGREE C IS DEVELOPED TO GEOMETRICALLY STRUCTURED FORMATS. THE ADVANTAGE OF THE TIN DIOXIDE HOLES OF REFRACTORY MATERIALS FOR CORROSION-RESISTANT PROTECTION LAYERS, IN PARTICULAR AS INTERIOR LAYERS FOR GLASS MELT HOUSING, IS PARTICULARLY BENEFICIAL AND COST-EFFECTIVE.

Description

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Title of the invention

Sintered refractory materials with high corrosion resistance

Field of application of the invention

The invention relates to sintered refractory materials consisting of the binder SnOp, the sintering accelerators NbgO LipO and / or ZnO and Magerungsmittel ^ are used because of their corrosion resistance for melting vessels, in particular for melting optical glasses. The application is particularly favorable for corrosion-resistant protective layers, in particular as inner layers for Glasschmelzhafen. Furthermore, the sintered refractory materials for stones, fittings (feeders, nozzles) and other highly stressed parts that are exposed to the attack of aggressive glass melts up to temperatures of 145O ⁰ G are suitable.

C characteristic of the known technical solutions

For the melting of special glasses, especially optical glasses, in addition to the usual refractory materials based on clay or kaolin and materials from silica, corundum, MuIlit, zirconium dioxide, zirconium silicate, corundum Baddeleyit, chromium oxide u.a. used. For special glasses also platinum is used. For some low-melting glasses, in particular laser glasses, particularly corrosion-resistant melting vessels are needed because these glasses no corrosion products

9ft.llH.1982 * 025695

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may contain. In addition, these refractory materials may not be colored oxides such as Pe ₂ O _3, CuO, MnOg, ^Cr 2 ⁰ · * · ^NiO i ^Co 3 ° 4 'TiO _2, V ₂ O containing · Because of its high corrosion resistance to many glass melting is Tin dioxide (SnO ₂ ) described as a refractory material.

To achieve a dense SnO ₂ ceramic sintering accelerators are required. As in the patents SU 579262, SU 577196 and in the literature Szklo i Ceramika 23 (1972) p. 297-299, 27 (1976) p. 201-202, Steklo i Keramika 3i> (1978) 10, p. 8 - 10, Glastechnische Berichte 54 (1981) 9 R. 166 are used as sintering accelerators MnO ₂ , CuO, Cr ₂ O or combinations of these coloring oxides with other oxides such as ZnO, Sb ₂ O ₅ , Nb ₂ O ₅ ,

However, because of the high combustion pitch of SnO ₂ ceramics, it is very difficult to sinter larger dimensions of components without cracks. Therefore, in Szklo i Ceramika 27, (1976) pp. 201-202, Steklo i Keramika 35 (1978) 10, pp. 8-10, and in the patent SU 579262 for producing refractory materials, a mixture of crude SnO ₂ and granular Sn0 used ₂ ~ chamotte. However, these refractories are very expensive because of the high price of the SnO ₂ and therefore uneconomical for the production of large-sized articles.

It was therefore in Szklo i Ceramika 26 (1975) 8/9, p 226 proposed a mixture of clay and ground SnO ₂ Schamotte. However, this material has the disadvantage that the clay component dissolves much more than the Sn0 ₂ ~ chamotte in the glass and therefore reach SnO ₂ -trap in the glass melt. DE-OS 2644239 describes molten refractory products of SnO ₂ , ZrO ₂ , Al ₂ O- and / or Cr ₂ O-, SiO ₂ and R ₂ O. These products have the disadvantage that they can only be produced by a melting process. For sintered refractory products, this mixture is unsuitable because no offset component can perform the function of ceramic bonding. This excludes the use as a protective layer on other ceramic bodies. A use of refractory Abfallmater'ialien, such as corundum, corundum Baddeleyitbruch and Mullitbruch is not possible.

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Aim of the invention

The aim of the invention is the production of sintered corrosion-resistant refractory materials, which achieve a minimal contact effect when melting aggresiver special glasses in the design of special moldings or protective layers and thereby not reduce the glass quality in terms of light transmission, bubbles and optical parameters.

Explanation of the Weses of the invention

The object of the invention is to provide suitable mixtures of binder, sintering accelerators and leaning agents corrosion resistant refractory materials, which allows by molding, such as casting or pressing and sintering at temperatures between 1300 ⁰ C and 1500 ⁰ C, the production of geometrically structured molded parts or protective layers whose linear thermal expansion and drying and burning shrinkage correspond to the usual ceramic materials based on clay or kaolin and which have a low porosity and a high density.

This is inventively achieved in that the binder consists of SnO ₂ and sintering accelerators, the sum of the concentrations of SnOp and sintering accelerators 20-50 Ma % betet.

The sintering accelerators are used individually or as a mixture in the following concentration ranges based on the SnO ₂ content;

Nb ₂ O ₅ 0.5-2.0 %

Li ₂ O 0.5 - 1.0 Ma%

ZnO 0.5 - 1.0 Ma %,

wherein the total content of the sintering accelerator based on the SnO ₂ content is not more than 4.0 Ma % .

As leaning agents are used individually or in a mixture

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O - 80 Ma % corundum

0 - 80 Ma>% zirconium silicate

0 - 80 Ma % Corundum Baddeleyite Material 0 - 80 Ma % Mullite

0 - 80 Ma% zirconium dioxide (stabilized)

added, where it is convenient to use particle sizes smaller than 1.0 mm.

The SnO ₂ , which takes on the role of ceramic bonding, significantly increases the corrosion resistance of the sintered refractory materials compared to pure fireclay materials. This prevents dissolution and pitting in the glass «

The content of SnO ₂ must not be less than 20 % by mass, since otherwise the binder content becomes too low, as a result of which the sintered refractory materials have lower mechanical strength, higher porosity and thus lower corrosion resistance,

If the SnO ₂ content exceeds 50 mass %, the binder content becomes too high, resulting in a large firing shrinkage, so that the sintered refractory materials can not be combined with conventional chamotte products. In addition, the high SnO ₂ content makes the sintered refractory materials too uneconomical because of the high SnO ₂ price. The addition of sintering accelerators Nb ₂ O, ZnO and Li ₂ O results in high density and minimum porosity for the sintered refractory materials , If the total content of the sintering accelerators exceeds 4 mass% based on the SnO ₂ content used, the density decreases and the porosity increases, which reduces the corrosion resistance. The leaning agents used are synthetic refractory materials, such as sintered corundum, fused corundum, slumpy mullite, enamel mullite, stabilized zirconium dioxide and zirconium silicate.

economically advantageous, the leaning agent may be waste material, e.g. melted corundum Baddeleyitsteinen be recovered.

By targeted combinations within the scope of the invention, sintered refractory materials

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manufactured with certain types of glass matched properties. The advantageous properties, such as low porosity, high corrosion resistance and minimal amount of coloring oxides enable the melting of highly aggressive special glasses. The glass quality in terms of light transmission, content of bubbles and stones and constancy of the optical parameters is increased compared to the use of known refractory materials.

The refractory materials according to the invention are particularly advantageous as protective layers for known fireclay products, in particular Glasschmelzhäfen suitable, with the individual components are initially stirred together with water and cold homogenized, then the mixture applied to the unfired fireclay or poured and then the two-layer product at temperatures between 1300 ⁰ C and 1500 ° C is sintered.

Au s f o hru η cj's be is pi el e

The refractory materials according to the invention are described in more detail with reference to two examples:

Table 1

1 2 SnO 2 al 2 ° 3 Dry composition in % 38, 38, 4 8 60 30 , 0 .4 ZrO ₂ SiO ₂ Na ₀ O Nb _o 0 _c ZnO c. C. 3 Li 2 ° Example example 19.5 9.4 0.8 0.8 0.7 0.8 0.2 0th 2

The sintered refractory materials obtained in Embodiments 1 and 2 have the properties shown in Table 2.

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Table 2 1 2 After a fire at 1450 ⁰ C open in % porosity Burning shrinkage in % Bulk density in / cm 12, 8, 20 50 5,6 5,7 3,84 3,90 Example example

The following starting materials are used for the production:

Example 1 Tin dioxide

niobium pentoxide

zinc oxide

Sintered corundum (smaller 1.0 mm grain size)

Example 2 Tin dioxide

niobium pentoxide

zinc oxide

Lithiumcarbont

Corundum baddeleyite material (smaller 1.0 mm particle size)

With the addition of about 20 % water and about 0.2 % sodium polyphosphate as liquefying agent, the starting materials are mixed thoroughly in a ball mill. Thereafter, the mixture is poured into plaster molds and applied to ordinary chamotte products for the production of moldings or as a protective layer. After drying, the firing takes place at temperatures between 1300 ⁰ C and 1500 ° C.

Claims (3)

239403 invention claim 1. Sintered refractory materials of high corrosion resistance, consisting of binder, sintering accelerator and leaning agent, characterized in that the binder consists of SnOp that are used as sintering accelerator components Nb ₂ O ₁ -, LipO and / or ZnO, wherein the sum of the concentrations of SnOp and NbpO _r , LipO and / or ZnO is 20-50 Ma % , and that leaning agents in the concentration range 50-80 Ma % are added. 2. sintered refractory materials according to item 1, characterized in that the sintering accelerators are used individually or in admixture in the following concentration ranges, based on the SnO ^ content: wherein the total content of the sintering accelerators, based on the SnOp content, is at most 4.0 Ma % , 3. Sintered refractory materials according to item 1 and 2, characterized in that the following leaning agents are used individually or in a mixture: Corundum 0 - 80,0 Ma % Zirconsilicate 0 - 80,0 Ma % Mullite 0 - 80,0 Ma % Corundum Baddel 0 - 80,0 Ma % eyit material Zirconia 0 - 80.0 Ma % (stabilized)