DE2204531C3 - Process for the production of refractory ceramic moldings - Google Patents

Description

35

The invention relates to a method for producing refractory ceramic molded bodies, for example Casting molds and casting cores for metal casting. According to the method according to the invention Shaped bodies produced are characterized by a particularly high level of resistance to aggressive Melting metal from.

It is known that ceramic casting molds by mixing a finely divided refractory material with a mostly silicate binder. According to such known methods, the Refractory material particles mixed with the binder and by dipping, spraying or pouring over applied to a model.Curing of such forms is done by drying or using a liquid, solid or gaseous hardener, for example ammonia. The liquid Binder converted into a gel and the refractory material particles stuck together A silica gel is formed here as a binding agent! subsequent firing is converted into silica.

With these casting molds and casting cores produced by known methods, however, are not always satisfactory results achieved, especially when casting steel types with a higher carbon content or types with a high chromium content, the molten metal often reacts with them the shape, so that the castings have defective surfaces.

The use of aluminum alcoholates or alcoholates of metals of the 4th subgroup of the periodic table in the known method for the production of ceramic casting molds was previously due to the large Sensitivity of these compounds to moisture not possible. These alcoholates condense as a result of hydrolysis, sometimes even when the air is humid, to higher molecular weight products that act as binders can no longer be used. The corresponding end product of the condensation reaction is always formed Oxides.

There has now been a method for producing ceramic molded bodies by mixing refractories Oxides found with a binder and subsequent shaping and curing that thereby is characterized in that a mixture of aluminum alcoholate and / or alcoholates is used as the binder of metals of the 4th subgroup of the periodic table with 0-diketones and / or hydroxycarboxylic acids or their esters and / or polyhydric alcohols are used

The binders according to the invention are due to the addition of β-diketones and / or hydroxycarboxylic acids or their esters and / or polyhydric alcohols in their sensitivity to moisture weakened so far that they are used in known processes instead of silicate binders can be. Any slight condensation that may occur, leading to dimeric or trimeric condensation products leads, does not interfere with the use according to the invention as a binder.

The binders according to the invention should, if possible, be in liquid form at room temperature. The metal alcoholate component is preferably the propylates and butylates of metals mentioned. However, it is also possible to use the alcoholates of these metals, their alcohol component is an aliphatic alcohol of 1 to 8 carbon atoms, provided the corresponding metal alcoholates are used Be in liquid form at room temperature.

The second component present in the binder according to the invention in addition to the metal alcoholates If possible, it should also be a compound that is liquid at room temperature. In many cases it responds this second component with the metal alcoholates to form chelates or similar complex compounds. A Such a reaction product can also be added to a binder mixture in a prefabricated manner.

The amount of this second component should be chosen so that it does not lead to the precipitation of solids in the binder when mixed with the metal alcoholate. By varying these additives, the rate of hydrolysis of the binder according to the invention can be adjusted as required. Preferably amounts 2 to 25 wt .-%, based on from metal alkoxide may be employed, however, the use of greater amounts is possible.

Both aliphatic and aromatic or mixed aliphatic-aromatic diketones are used. As examples are called acetylacetone, acetoacetic ester, benzoylacetone or di-benzoylmethane.

The hydroxycarboxylic acids which can be used as the second component are preferably liquid aliphatic hydroxycarboxylic acids. These acids can have one or more hydroxyl groups contain. Examples are glycolic acid, lactic acid or oxypropionic acid and their alkyl esters The alkyl radical of the ester is preferably a C1 to Q-alkyl radical. But it can also be higher Hydroxycarboxylic acids or their alkyl esters are used

such as m-oxycaproic acid, or the ω-Oxycaprylic acid ethyl ester.

The polyhydric alcohols are both dihydric and trihydric and higher alcohols. The position of the hydroxyl groups each other does not matter. Of the dihydric alcohols, the glycols are preferred used with 2 to 12 carbon atoms, such as. B. ethylene glycol, 1,4-butanediol, hexylene glycol or octylene glycol; it however, diglycols can also be used, such as. B. Ethylene diglycol or propylene diglycol Furthermore the dialkanolamines can be used as dihydric alcohols, such as B. the diethanolamine.

Examples of trihydric alcohols are glycerine and triethanolamine

The binders according to the invention can be diluted either directly or in a solvent be applied. The addition of a solvent has the advantage that it reduces the concentration of the alcoholates contained in the binder and thus those after the entire shape of the body has been hewn into can adjust this coming to the deposition amount of metal oxide. The use of a solvent is also recommended when the second component of the binder according to the invention, such as e.g. 1,8-octylene glycol, not at room temperature is liquid.

Alcohols, ketones, ethers, aliphatic and aromatic hydrocarbons are suitable as solvents When choosing the solvent in question, however, it must be taken into account that this is not Dissolving power Ijr possesses a possibly to be used wax model in the production of the casting mold Examples of suitable solvents are isopropyl alcohol, Butanone, methyl isobutyl ketone, oxane, toluene, xylene and benzoL

The moldings with the binder according to the invention are produced in a manner known per se by mixing the binder with the refractory oxides. Since the moldings made with these binders are made of high-alloy steel types, such as carbon steel or high-percentage chrome steels, and also of aggressive metals, such as ζ. B. titanium, are not attacked or only to a small extent, they are preferably suitable as lost casting molds in the production of moldings from these metals. The refractory oxides used in the casting molds for these metals should, if possible, _{contain no SiO 2} or only small amounts of SiO ₂ , since this can react with the metals at the high temperatures prevailing during casting.

The refractory oxides which are used with the aid of the binder according to the invention to form ceramic molded bodies with high resistance to aggressive metal melts therefore preferably include corundum, magnesia, TiO ₂ , ZrO ₂ , ThO ₂ , CaO, BeO and CR ₂ Oj.

The molding compositions produced with the binder according to the invention can optionally be mixed with molding compositions, the known binders contain, are combined, for example in such a way that in investment casting molds According to melt-out models, the first two layers of the ceramic form from one Molding material can be applied with the binder according to the invention, while further layers are made Molding material with known z. B. silicate binders exist.

example 1

100 parts by weight of aluminum sea-butoxide are with 30 parts by weight of acetylacetone and 30 parts by weight of butanone mixed There is a slight warming,

Then 320 parts by weight of molten corundum, finely ground, max.grain size 0.07 mm, added. The mixture results in a dipping compound any shaped body can be obtained by drying and curing. It is then z. B. The procedure was that in this liquid models made of wax or polystyrene or urea or the like Material immersed and after immersion with fine-grained corundum with a grain size of 0.12 to 0.25 mm can be sprinkled. After dipping and sanding, the cover is allowed to cure in the air, or it is sprayed with a hardening liquid known per se for the purpose of faster hardening The hardening liquid consists e.g. of a mixture of 1.25% aqueous ammonia and Ethyl alcohol mixed in a volume ratio of 1: 1

After the layer has solidified, the dipping process is repeated and the secondary layer cured in the same way.After the second layer has hardened, additional layers of materials are applied that are used in known processes, e.g. of molten mullite and hydrolyzed ethyl silicate as a binder Molding material with ethyl silicate as a binder can also be hardened with the hardener described above or with gaseous ammonia. After the layers have hardened, the model is removed by melting out, burning out or loosening, and the resulting hollow ^{shape is burned at temperatures of over 1000 °} C. The burned shape is cast with metal either cold or hot. It is suitable for casting high-alloy steels at high casting temperatures

Example 2

100 parts by weight of zirconium n-butoxide are with 10 parts by weight of acetylacetone mixed and in this mixture 275 parts by weight of molten zirconium oxide, finely ground (max. grain size 0.06 mm), stirred in.

With this immersion material, as described in Example 1, two layers are applied and cured analogously to Example 1. The other layers consist of the material described in Example 1. We obtained in ^this: se a hollow mold which is suitable for the casting of metals, which have an increased tendency to reactions with the shape such. B. carbon steel, high percentage chrome steels and titanium.

Example 3

On a split model made of plastic, metal or wood that has been treated with a release agent, a slurry is injected, which is composed of the following substances: 85 parts by weight of zirconium n-propylate, 15 parts by weight of acetoacetic ester and 250 parts by weight of zirconium oxide, grain size 0 to 0.06 mm,

Spraying is carried out using an air-operated spray gun. The sprayed layer is approx. 0.5 mm thick. Then it is sprinkled with coarser-grain zirconium oxide. After sprinkling, it is sprayed a hardener consisting of 1.25% aqueous ammonia and alcohol. After solidifying the Primary layer one brings either a second layer

made of the same material on or backfilled immediately with a ceramic mass consisting of a refractory material and a hardener Binder on the basis of ethyl silicate. This mass corresponds to the mass of the known Shaw process come into play,

After the Shaw compound has set, the model is pulled out of the molding compound. By Post-hardening, flaming and subsequent firing In the mold is ready for pouring after this Process manufactured molds can be castings made of high-alloy steels with high unit weights and flawless surface can be poured.

Example 4

There are 100 parts by weight of tetrahydrofuran, 50 parts by weight of triethanolamine and 45 parts by weight of isopropanol mixed together and stirred molten magnesia into the mixture

With this dipping compound, a wax model is covered by dipping twice, for faster To harden, spray the model with a ίο water / alcohol mixture. After applying the first Both layers one covers the model with further ceramic layers, the ethyl silicate as Contain binders.

Claims (6)

Patent claims: 1. Process for the production of ceramic moldings by mixing refractory oxides with a binding agent and subsequent shaping and curing, characterized in that that a mixture of aluminum alcoholate and / or alcoholates of metals is used as a binder the 4th subgroup of the periodic table with /? - diketones and / or hydroxycarboxylic acids or their esters and / or polyhydric alcohols begins 2. The method according to claim 1, characterized in that there is acetylacetone as the 0-diketone and / or acetoacetic ester used 3. The method according to claim 1, characterized in that the polyhydric alcohol Diethanolamine, triethanolamine, hexylene glycol, octylene glycol or glycerin used alone or in admixture 4. The method according to claim 1, characterized in that glycolic acid or lactic acid and / or their alkyl esters are used. 5. The method according to claim 1, characterized in that the binder in one Solvent used 6. The method according to claim 1, characterized in that the refractory oxides zirconium oxide, Alumina and magnesia used alone or as a mixture