EP0480171B1 - Dust-free investment material for precision casting and process for the preparation of such investment materials - Google Patents

Abstract

Dust-free investment materials for producing precision castings consisting of water-soluble phosphates, magnesium oxide and silicon dioxide are obtained when the investment material is divided into two components a and b, where component a contains all the magnesium oxide, where appropriate a part of the silicon dioxide and, if silicon dioxide is present, 0.4 to 6% by weight of a hydrophilic organic solvent, and component b contains the phosphate, the remainder of the silicon dioxide and at least 0.5% by weight of water.

Description

The invention relates to a water-soluble phosphate, magnesium oxide and silicon dioxide containing, mixed with liquids, non-dusting investment material for the production of precisely fitting castings in dental technology and in the jewelry industry and a method for producing such investment materials.

In dental technology and in the jewelry industry, metallic tooth replacement parts or jewelry parts are usually produced by casting processes. For this purpose, the tooth replacement part or jewelry part is modeled in wax, embedded, the wax is removed by melting and the molten alloy is poured into the resulting mold.

The investment materials used for the production of the molds are subject to high demands with regard to the accuracy of fit of the parts produced therein. Due to the expansion of the setting and the thermal expansion of the investment, the contraction of the cast metal part by cooling after casting must be exactly compensated.

• a) Phosphatgebundene Einbettmassen
• b) Gipsgebundene Einbettmassen
• c) Silikatgebundene Einbettmassen.

In dental technology, three different types of investment materials are used, which differ in the binder system used.

• a) Phosphate-bonded investment materials
• b) Gypsum-bound investment materials
• c) Silicate-bonded investment materials.

The most widespread are the phosphate-bonded investment materials containing magnesium oxide and silicon dioxide, since they are resistant to high temperatures and can also serve as a casting mold for high-melting alloys. Phosphate-bonded investment materials are mixed with water or a water / silica sol mixture. The addition of the water leads to the setting reaction of the two binder components ammonium phosphate and magnesium oxide.

All three types of silica in the form of quartz and its modifications are used as refractory components. In order to achieve a smooth casting surface, the refractory components must also contain very fine grain sizes. When processing (filling, weighing, mixing) the investment material, dust always develops. The released dust represents a considerable health hazard for the dental technician or the goldsmith. Inhalation of dust containing quartz can lead to silicosis (dust lung). The respirable fines in the dusts are particularly dangerous in this regard.

For this reason, the legislator stipulated maximum concentrations of dust pollution at the workplace in the Ordinance on Hazardous Substances dated 26.04.86. The currently valid limit values are 6 mg / m³ total dust pollution, or 4 mg / m³ for quartz-containing fine dust and 0.15 mg / m³ for respirable quartz-containing fine dust.

If currently customary investment materials are used, these values can only be safely and permanently undershot if the work rooms are equipped with complex and expensive extraction and filter systems.

DE-PS 37 07 853 describes a powdered investment material which only shows a low level of dust formation. This is achieved by adding 0.5 - 5% of a wetting agent consisting of liquid hydrophobic hydrocarbons, fatty acid esters or fatty acids to the powder mixture of soluble phosphate, magnesium oxide and quartz. Since these liquids have a low vapor pressure, these are always relatively long-chain, organic compounds which lead to an oily grip in the investment materials and reduce the kneadability, so that anionic, surface-active agents must also be added. However, this can have a negative impact on the technical properties of the investment material (low strength, excessive setting expansion, unpleasant smell).

The addition of a liquid to the investment can also be done for other reasons. For example, an investment is described in Derwent Abstract 84-003437 / 01, to which an aliphatic alcohol is added in amounts of 0.01 to 0.3% by weight in order to prevent the reaction of the binder material due to the atmospheric humidity, and thus to increase the storage stability increase. However, the amounts added are so small that no dust-free is obtained.

It was therefore an object of the present invention to develop a non-dusting investment material containing water-soluble phosphates, magnesium oxide and silicon dioxide, mixed with liquids, for the production of precisely fitting castings in dental technology and in the jewelry industry, the fine dust content of which is reliably below the legally permissible limit value, without the additives have a negative influence on the mechanical and thermal properties of the investment. A process for the production of these investment materials should also be developed.

This object is achieved in that the investment is divided into two components a and b, of which component a contains the entire magnesium oxide and component b contains the entire phosphate, while the silicon dioxide content either only added to component b or to the two components a and b is distributed, component b containing at least 0.5% by weight of water and component a in the presence of silicon dioxide containing 0.4 to 6% by weight of a hydrophilic aliphatic solvent with a vapor pressure of less than 600 Pa.

Component a preferably contains the magnesium oxide, part of the silicon dioxide and 0.4 to 6% by weight of a monohydric alcohol having 4 to 7 carbon atoms or a liquid polyhydric alcohol or the corresponding esters.

Instead of the alcohols or their esters, component a can also contain hydrophilic carboxylic acids having 3 to 7 carbon atoms or their esters.

If only magnesium oxide is present in component a, the organic solvent can be dispensed with, since magnesium oxide is less dusty and far less toxic than silicon dioxide.

The two components a and b can be packed and stored separately in the moist state. Only when they are processed are they mixed together in the correct mixing ratio and mixed with the mixing liquid.

A polyhydric alcohol such as e.g. Ethylene glycol or glycerin. Furthermore, it may be advantageous to add the entire mixing water necessary for the production of the investment to component b. This means that only components a and b are required to prepare the investment material and no additional mixing water.

Components a and / or b advantageously additionally each contain a water-soluble binder, in particular polyvinyl alcohols in amounts of 0.1 to 2% and / or cellulose derivatives in amounts of 0.1 to 5%. This enables the powder mixtures to be agglomerated, with agglomerate diameters of 0.5 to 5 mm having proven best.

This agglomeration has the essential advantage that the two components can then be mixed again after drying, without a reaction taking place or a dust load exceeding the legal limit value being able to occur.

According to the invention, the dust-free investment material is produced by dividing the investment material consisting of water-soluble phosphates, magnesium oxide and silicon dioxide into two components a and b, component a, which contains all of the magnesium oxide and possibly part of the silicon dioxide, in the presence of silicon dioxide with 0.4 to 6% by weight of a hydrophilic aliphatic solvent with a vapor pressure of less than 600 Pa, and component b, which contains the water-soluble phosphate and the remaining part of the silicon dioxide, with at least 0.5% by weight of water is transferred.

The hydrophilic aliphatic solvent used is preferably monohydric alcohols having 4 to 7 carbon atoms, liquid polyhydric alcohols or the corresponding esters.

Advantageously, components a and / or b, optionally with the addition of a water-soluble binder in the form of 0.1 to 2% of a polyvinyl alcohol or from 0.1 to 5% of a cellulose derivative, are agglomerated to form agglomerates of preferably 0.5 to 5 mm in diameter and then dried. This makes it possible to mix the two components again without a setting reaction taking place.

In principle, the refractory components silicon dioxide can be divided arbitrarily between the two components a and b. However, it has proven useful to keep the proportions approximately the same size in order to ensure that the mixing is as homogeneous as possible during the mixing.

Studies have shown that the addition of water to component a changes the dental properties. The investment then shows a typical aging effect, which is expressed in a significant reduction in the setting expansions over a longer storage period. If the water is replaced by a mono- or polyhydric alcohol or an ester, this effect is reduced or avoided entirely. Aging effects can certainly be avoided if, for example, chem. pure ethylene glycol is used.

The amount of liquid required to keep dust-free essentially depends on the grain size of the investment material. The finer the material, the more liquid is required. Since ethylene glycol leads to a reduction in the setting reaction at higher concentrations, it makes sense not to increase the glycol requirement by too much sand or by too large a grain size. A glycol content of 5% should never be exceeded.

Instead of ethylene glycol, butanediol or glycerin can also be used as the binding liquid for component a.

Since glycerin is more viscous than glycol, slightly larger amounts are necessary.

With the b component, the use of water does not have a negative effect on the dental properties of the investment material. Since this is also not quantity-dependent, the water requirement can always be set as required in addition to the a-component due to the fineness of grain and the amount of sand.

The separation of the two components a and b during the addition of liquid and storage has the consequence that the handling of the dust-free investment is somewhat more complex than with conventional investments, since a total of three components (2 solid components + mixing liquid) have to be processed instead of two components . A certain simplification can be achieved in that the entire mixing liquid is completely added to component b from the outset, so that again only two components have to be processed. Such an investment material does not differ in its dental technology data from the usual materials. In this case, component b is a relatively thin slurry. To avoid segregation by sedimentation, component b must be packed in portions.

The handling of the investment material according to the invention can be further improved if the two components are agglomerated separately and mixed together again after drying.

In order to influence the agglomeration behavior, water-soluble binders can still be dissolved in the liquid used in both components. For example, proven: polyvinyl alcohols, tylose, sugar, gum arabic and soluble starch. In addition, however, other binders that are usually used in agglomeration processes are also conceivable. Such binders are e.g. in "Chemical Engineering, December 4, 1967".

The agglomeration of both components takes place in commercially available mixers, with a fine agglomeration of the respective agglomeration liquid leading to a build-up agglomeration. A size of approx. 0.5 -5 mm is permitted for the agglomerates. The liquid requirement for the desired agglomerate formation is 4 to 60 ml / kg solids for component a and 5 to 200 ml / kg for component b. After agglomeration, component b is dried by heating to 50-110 ° C., while component a can be left in the moist state. The two components can then be mixed together without impairing the storage stability and the dental properties.

If component a contains only magnesium oxide and no silicon dioxide, it can be agglomerated or tableted without the addition of organic solvents in the form of alcohols, carboxylic acids or esters.

Such agglomerated investment materials are distinguished from conventional investment materials by significantly reduced dust pollution during processing. To measure the dust load, a sample of the investment was mixed in a vessel in a tumble mixer for one minute.

The vessel was then opened and the dust load was measured immediately using a dust measuring device. It was found that the total amount of dusts released is considerably less than the legally permissible limit values, so that a hazard from inhalable, quartz-containing dusts can be excluded.

The following table summarizes some examples of the investments according to the invention and their properties.

Components a and b were first homogenized in a mixer in the dry state for 3 minutes, then the liquid was added with continuous mixing and mixed again for 5 minutes.

The setting expansion was determined in accordance with DIN draft 13919, part 2. To determine the accuracy of fit, schematic crown rings were cast and then measured optically. To check the storage stability, repeat measurements were carried out after different storage times.

If there are no significant changes during the first 4 weeks, based on previous experience, storage stability can be expected during the usual storage period of 1 year. The minor changes observed with regard to setting expansion and fitting accuracy after a long storage period of the investment materials are usually within the measuring accuracy and are tolerable.

Claims (11)

1. A dust-free embedding compound containing water-soluble phosphates, magnesium oxide and silicon dioxide and added liquids for the production of precision castings in dentistry and in the jewellery industry, characterized in that the embedding compound is divided into two components a and b, of which component a contains all the magnesium oxide and component b all the phosphate while the silicon dioxide component is either added only to component b or is distributed between components a and b, component b containing at least 0.5% by weight water and component a - in the presence of silicon dioxide - containing 0.4 to 6% by weight of a hydrophilic aliphatic solvent having a vapor pressure of less than 600 Pa.
2. An embedding compound as claimed in claim 1, characterized in that component a contains the magnesium oxide, part of the silicon dioxide and 0.4 to 6% by weight of a monohydric alcohol containing 4 to 7 carbon atoms or a liquid polyhydric alcohol or corresponding esters while component b contains the water-soluble phosphate, the rest of the silicon dioxide and at least 0.5% by weight water.
3. An embedding compound as claimed in claim 1 or 2, characterized in that ethylene glycol, butanediol or glycerol is present as the polyhydric alcohol in component a.
4. An embedding compound as claimed in claims 1 to 3, characterized in that component b contains all the mixing water required for the embedding compound.
5. An embedding compound as claimed in any of claims 1 to 4, characterized in that one or both of components a and b additionally contain(s) a water-soluble binder.
6. An embedding compound as claimed in claim 5, characterized in that components a and/or b contain(s) 0.1 to 2% polyvinyl alcohol or 0.1 to 5% of a cellulose derivative as binder.
7. An embedding compound as claimed in any of claims 1 to 6, characterized in that the powder mixtures of components a and/or b are in the form of agglomerates or moldings between 0.5 and 5 mm in diameter.
8. A process for the production of the embedding compounds claimed in claim 1, characterized in that the embedding compound is divided into two components a and b, component a, which contains all the magnesium oxide and optionally part of the silicon dioxide, being mixed in the presence of silicon dioxide with 0.4 to 6% by weight of a hydrophilic aliphatic solvent having a vapor pressure of less than 600 Pa and component b, which contains the water-soluble phosphate and the rest of the silicon dioxide, being mixed with at least 0.5% by weight water.
9. A process for the production of embedding compounds as claimed in claim 8, characterized in that monohydric alcohols containing 4 to 7 carbon atoms, liquid polyhydric alcohols or the corresponding esters are used as the hydrophilic aliphatic solvent.
10. A process as claimed in claim 8 or 9, characterized in that components a and/or b are formed into agglomerates between 0.5 and 5 mm in diameter, optionally with addition of water-soluble binders, and are then dried.
11. A process as claimed in any of claims 8 to 10, characterized in that the dried agglomerates of components a and b are mixed with one another.