DE2451935A1 - Strong, dense refractory material prodn. - from alumina, chrome-iron ore and phosphoric acid or aluminium phosphate - Google Patents

Abstract

Refractory material is produced from 65-96 wt.% (pref. 70-96 wt.%) of crude alumina (Al2O3 content >=99%), 3-25 wt.% of a chrome-irone ore (iron chromite), and 1-10 wt.% (calculated as P2O5) of H3PO4 and/or aluminium phosphate. The mixt. may contain up to 10 wt.% of calcined alumina. The chrome-irone ore contains 35-50% Cr2O3, 15-35% FeO and 25-40% of oxides of Si, Mg, Ca, Al and/or other metals. The addition of H3PO4 and/or AlPO4 increases the strength and bulk density of the product and reduces its porosity.

Description

Refractory material and process for its manufacture.

The invention relates to a refractory material comprising an alumina raw material, Chrome iron ore (iron chromite ore) and contains a phosphate compound and a low level Has porosity, a high bulk density and a high modulus of rupture.

High alumina refractories have been used for many years made for building materials such as bricks and the like. In the past Attempts have been made to make the products by adding various ingredients to improve the clay material. To refractory products with greater strength and to form longer life, chromium oxide is added in varying amounts been.

This alumina-chromium oxide refractory material is denser and less porous as refractory alumina materials that do not contain chromium oxide.

Another refractory mass has been made, clay and chromium iron ore and which has an even greater strength and denser is known as the alumina-chromium oxide refractory product. This particular clay and refractory material containing chromium iron ore is described in DT-OS 2,358,268 and claimed.

The invention now relates to a refractory material that is 65 to 96 Wt% alumina raw material, 3 to 25 wt% chromium iron ore, 0 to 10 wt% calcined Contains clay and 1 to 10% by weight of a phosphate compound, calculated as P205.

This refractory material is obtained by mixing the alumina raw material with the chromium iron ore and the phosphate compound and burning the mixture at one Temperature from 3500C to 16500C.

This refractory material or composition, which contains alumina, a chromium iron ore 4 and a phosphate compound has a much greater strength than the previously known refractory alumina materials or alumina-chromium oxide materials. In addition, the inventive refractory Material has a higher bulk density than the previously known products.

The alumina raw material that can be used according to the invention, is an alumina raw material made from alumina with an aluminum oxide content of 99% and more (99 +% alumina), alumina ores, alumina compositions and mixtures is selected from the group consisting of and contains at least 50% alumina. These Materials include alumina with an aluminum oxide content of 99% and more (99 +% Alumina), aluminum oxide ores such as bauxite, diaspore and cyanite, and aluminum compounds, such as sillimanite, mullite and the like. All of these materials are chemical mutually compatible and can be used separately or in the form of mixtures can be used together1 making any-alumina percentage equal leaves.

As already mentioned above, the raw alumina material used according to the invention makes 65% to 96% by weight of the total refractory material.

The chromium iron ore used in the present invention usually contains 35 to 50% Cr203, 15% to 35 FeO and 25% to 40% of the oxides of silicon, magnesium, Calcium, aluminum and other metals.

Regarding the phosphate compound used, it should be said that Phosphoric acid and aluminum phosphate are particularly advantageous products. The phosphate compound or the mixture of the phosphate compounds is used in quantities from 1% by weight to 10% by weight, calculated as P205, added. While burning of the material according to the invention can be a part of the phosphate content by evaporation get lost.

The material according to the invention is used either to form the refractory Fired products or using the mixture without firing it, either as a ramming mix or as a plastic mix that is used, for example, for production of refractory monolithic products.

If it is desired to prepare a plastic mixture, if necessary, small amounts of bentonite (1% to 4%) and water (1% to 12%) added to the mixture. The presence of the bentonite increases the plasticity the mix. The plastic mixture contains the following ingredients: 72 to 94 wt% alumina, 3 to 20 wt% chromium iron ore, 1 to 10 wt% phosphate compound (calculated as P205), 1 to 4% by weight bentonite and 0 to 12% by weight water.

The presence of the bentonite in the mixture is not required, if the mixture is used as a ramming mass or if it is used to form the refractory material described above is fired.

In the manufacture of the refractory material according to the invention should preferably all of the constituents have a particle size within certain areas.

The chromium iron ore should have a particle size of SO.043 mm be ground.

65% to 948 of the alumina raw material should have a particle size of <6.35 mm to> 0.043 mm, while the remainder of the alumina raw material should be ground to a particle size of 0.043 mm.

When high quality alumina is used as the alumina raw material becomes (i.e. a material that contains at least 99% or more aluminum oxide), you can only use tabular clay, although it is preferred- to use a mixture of tabular and calcined clay. If tabular If clay is used, it should be used in different sizes. If 99 +% alumina is used, all of the alumina should be of a particle size from t 6.35 mm to) 0.043 mm are used in tabular form, while preferably 1/4 to the total amount of clay with a particle size of (0.043 mm in the tabular form should be used. When using calcined clay it should have a particle size of <0.043 mm.

The raw alumina material, chrome iron ore, is used to manufacture the material and the phosphate compound is sufficiently mixed so that the mixture is annealed in a suitable manner. The molded material is then used during 2 to 8 hours at a temperature of 3500C to 16500C to form the refractory Fired materials.

The following examples are intended to explain the invention further.

Example 1 In this example, a particle size of 1 0.043 mm ground chromium iron ore with the following analytical values was used: Cr203 45.66% Fe 19.98t Al203 15.268 SiO2 1.47% 02 7.26% Mg0 10.24% CaO 0.138 -It both tabular and calcined clay are used.

The tabular clay with a particle size of (6.35 mm to ; 0.043 mm has the following particle size distribution: # 0.246 mm to # 6.35 mm 66%} 0.043 mm to 4 0.246 mm 34.0% To produce the refractory according to the invention Materials, the following ingredients are mixed well to form a homogeneous mixture: 74 kg of tabular clay with a particle size of> / 0.043 mm 6'kg tabular Alumina with a particle size of # 0.043 mm 15 kg of calcined alumina with a Particle size of (0.043 mm 5 kg chrome iron ore with a particle size of < 0.043 mm 5.2 kg 80% phosphoric acid.

From the mass one forms stones with the dimensions 228.6 mm x 114.3 mm x 76.2 mm and burns them for 5 hours at 15600C. The burned stones are examined and have the following properties: modulus of rupture (kg / cm2) 493.8 Porosity (%) 13.9 Bulk density (g / cm3) 3.25 These properties are essential better than the previously known refractory alumina-chromium oxide products.

Examples 2 to 5 The procedure of Example 1 is repeated, with varying amounts of calcined alumina, chromium iron ore and the phosphate compound be used.

Two comparative approaches are also carried out in which no phosphates are used (comparison A) and those instead of chromium iron ore Chromium oxide is used and no phosphates are used (comparison B).

All of these examples give improved results when compared with the products of the prior art obtained according to the comparative batches. The results of these examples together with those of example 1 and the comparative runs are compiled in the following table I.

Table I Material Example No. Comparison Comparison .1 2 '3 4 5 A B Tabular clay} 0.043 mn (kg) 74 74 74 66.5 64.1 64.1 90 Tabular clay # 0.043 nm (kg) 6 6 6 19.4 12.4 12.4 0.0 Calcined clay (0.043 mn (kg) 15 10 5 4.7 6.1 6.1 0.0 Chrome iron ore 0.043 irm (kg) 5 10 15 10.0 17.4 17.4 0.0 phosphoric acid (80%) kg 5.2 0.0 0.0 5.3 6.0 0.0 0.0 Aluminum phosphate (kg) 0.0 4.8 5.0 0.0 0.0 0.0 0.0 Sulphite waste liquor (kg) O 0 0 0.0 0.0 2.3 3.8 Chromium oxide (kg) 0.0 0.0 0.0 0.0 10 Continuation of Table I Properties Example No. Comparison Comparison 1 2 3 4 5 A Modulus of rupture (kg / cm2) 493.8 621.5 460.0 530.1 543.3 406.0 316.4 Apparent Porosity 13.9 13.3 14.1 13.9 15.6 17.1 16.5 ity (%) bulk density (g / cm3) 3.25 3.25 2.03 3.25 3.24 3.17 3.16 Example 6 The procedure for the preceding is repeated Examples with the difference that in the place of the 99 +% alumina one mullite and Cyanite is used as a raw alumina material.

This example uses 5.2% phosphoric acid.

It will be a comparative approach with the same ingredients as that carried out from Example 6, with the difference that no phosphoric acid is used will.

The results of Example 6 and the comparative run are.

compiled in the following Table II: Table II Material Example 6 Comparative set of mullite g4.7 mm to # 0.833 mm 35.0 35.0 Müllit # 1.17 mm up to # 0.246 mm 17.0 17.0 mullite # 0.246 mm 20.0 20.0 ¢ 9anite # 0.147 mm mn 8.0 8.0 Calcined Alumina # 0.043mm 10.0 10.0 Chrome Iron Ore # 0.043mm 10.0 10.0 Phosphoric Acid 5.2 sulphite waste liquor - 2.5 water --- 1.5 Table II continued Material Example 6 Comparative set modulus of rupture (kg / cm2) 406.0 339.1 porosity (%) 13.2 15.5 Absorption (%) 4.1 6.0 It is clear from the above that the presence of a phosphate in the composition gives refractory products, which have an increased modulus of rupture, increased porosity and greater absorption compared to similar compositions that do not contain phosphate.

It has also been shown that the mixture of alumina, chromium iron ore and a phosphate compound can be used as a ramming mass or a ramming mixture and that this mixture is superior to an alumina-phosphate mixture that does not have Contains chromium ore. To illustrate this superiority, the following are provided Ramming masses produced.

Example 7 9 kg of alumina and 1 kg of chrome iron ore are mixed with 0.34 kg of phosphoric acid (calculated as P205).

The particle sizes of the ingredients are essentially those already previously described.

For a direct comparison, mix without using Chrome iron ore 9 kg of alumina with 0.34 kg of phosphoric acid.

When examining these ramming masses in contact with iron oxide at 15600C it can be seen that the mass containing chromium iron ore is only slight or shows no reaction and the stones remain unchanged while the no chromium iron ore ramming mass containing leads to a considerable reaction and one The ramming mass containing no chromium iron ore suffers considerable expansion makes unsuitable. In addition, the iron oxide penetration of the reference mass is double as high as that of the rammed earth, in addition to the clay and the phosphate compound which contains chromium ore.

If you want to make a plastic mass, you use that same mixture, with the difference that you can give it if necessary and preferably 1% to 4% bentonite and 0% to 12% water added. The plastic mass prepares as follows: Example 8 The following ingredients are mixed to form a plastic one Mass or mixture: Tabular clay 4 4.7 mm to> z0.246 mm (kg) 46 Tabular clay Alumina <0.246 mm to <0.043 mm (kg) 18 Tabular alumina 10.043 mm (kg) 19 Calcined clay (0.043 mm (kg) 5 phosphoric acid (80%) (kg) 12 bentonite f0.043 mm (kg) 1 Chrome iron ore (0.043 mm (kg) 10 The investigations show that this plastic Mass compared to masses that either do not have chromium iron ore or phosphate compound included, has a superior lifespan.

From the data obtained it can be seen that the properties of the refractory alumina materials containing chromium iron ore and phosphates, are superior to the comparison products that use chromium oxide instead of chromium iron ore contain and which do not contain phosphates, The inventive Teaching is also suitable for the production of plastic masses or ramming masses, which are also superior to the previously known products.

Claims (12)

P a t e n t a n 5 p rü ch e 1. Refractory material that is not marked t that it contains 65% by weight to 96% by weight of alumina raw material, 3% by weight to 25% by weight of chromium iron ore, 0% by weight to 10% by weight of calcined clay and 1% by weight to 10% by weight of a phosphate compound, calculated as P205, selected from phosphoric acid, aluminum phosphate and mixtures including a comprehensive group. 2. Refractory material according to claim 1, d a d u r c h g e k e n n indicates that it contains 70 wt% to 96 wt% alumina with an alumina content of 99% and more (99 +% alumina), 3% by weight to 20% by weight chromium iron ore and 1% by weight up to 10% by weight of a phosphate compound, calculated as P205, selected from phosphoric acid and aluminum phosphate. 3. Refractory material according to claims 1 or 2, d a d u r c it should be noted that the chromium iron ore present is 35% to 50% Cr203, 15% to 35% FeO and 25% to 40% of the oxides of silicon, magnesium, calcium, aluminum and / or other metals. 4. Refractory material according to one of claims 1 to 3, d a d u It is noted that 65% to 94% of the existing alumina raw material has a particle size of (6.35 mm to 0.043 mm) and the remainder has a particle size of # 0.043 mm. 5. Refractory material according to one of claims 1 to 4, d a d u notify that the alumina raw material consists of the alumina ores, Alumina compositions, alumina with an alumina content of 99% and more (99 +% alumina) and mixtures thereof is selected and one Has an alumina content of at least 50%. 6. Refractory material according to one of claims 1 to 5, d a d u notices that the alumina raw material is alumina with a Contains aluminum oxide content of 99% or more (99 +% alumina) and 65% to 94% of the clay present has a particle size of (6.35 mm to> 0.043 mm and the remainder has a particle size of <0.043 mm, one particle size from & 6.35 mm to> 0.043 mm in the form of tabular Alumina is present while the material with a particle size of (0.043 mm is in the form of tabular and calcined clay. 7 A method for producing a refractory material according to a of claims 1 to 6, d u r c h g e n n -z e i c h n e t that 65 wt .-% up to 96% by weight of alumina raw material, 3% by weight to 25% by weight chromium iron ore, 0% by weight up to 10% by weight of calcined clay and 1% by weight to 10% by weight of a phosphate compound, calculated as P205, mixed, the mixture formed into a ceramic body and the body for 2 to 8 hours at 350 "C to 1650 ° C to form the refractory Material burns. 8. The method according to claim 7, d a d u r c h g e k e n n -z e i c h n e t that one has 70 wt .-% to 96 wt .-% of an alumina with an aluminum oxide content from 99% or more (99 +% alumina), 3% by weight to 20% by weight chromium iron ore and 1% by weight to 10 wt .- * of a phosphate compound mixed, with 65% to 94% of the clay a particle size of # 6.35mm to # 0.043mm, while the remainder of the clay has a particle size of <0.043 mm, the mixture deformed into a ceramic body and the body for 2 to 8 hours a temperature of 3500C to 16500C to the refractory material burns. 9. The method according to claim 8, d a d u r c h g e k e n n -z e i c It should be noted that the alumina with a particle size of 2.043 mm is tabular Alumina uses, while the alumina with a particle size of # 0.043 mm 0% Contains up to 75% calcined clay and the remainder tabular clay. 10. In the non-deformed state for the manufacture of monolithic ceramic mass suitable for refractory products, d u r c h e k e n n z e i c h n e - that they contain 65% by weight to 96% by weight of alumina raw material, 3% by weight to 25% by weight Chrome iron ore, 0 wt. T to to pulled wt.% Calcined alumina and 1 wt.% To 10% by weight of a phosphate compound selected from aluminum phosphate and phosphoric acid and mixtures - the group consisting thereof. 11. Ceramic composition suitable as a plastic mass, d a d u it is noted that they contain 65 wt% to 96 wt% alumina, 3 wt% up to 20% by weight chromium iron ore, 1% by weight to 4% by weight bentonite, 0% by weight to 12% by weight Water and 1% to 10% by weight of a phosphate compound, calculated as P205, contains. 12. Tamped mass, d u r c h e k e n n n e i c h n e t that they 65 wt% to 96 wt% alumina, 3 to 20 wt% chromium iron ore, and 1% to 10% one Contains phosphate compound, calculated as P205.