Material for facing denture

Abstract

There is provided a material for dentures having metallic matrix, containing 0.5-30 volume % glass having a softening temperature above 650.degree. C. and/or ceramic particles having a maximum grain size of 40 .mu.m.

Description

BACKGROUND OF THE INVENTION

This invention is directed to a material which is useful for veneerable dentures having a metallic matrix.

Metallic, veneerable dentures are produced with the lost-wax-method using alloys with a high noble metal content. These alloys have good processability and have an outstanding biocompatibility. However, these alloys are expensive so that in recent years there have been developed alloys having reduced gold and platinum contents and increasing additives of palladium and non-noble metals. These alloys, however, are frequently difficult to process, especially in regard to the melting and casting behavior and solderability. There are likewise used base metal alloys for metallic dentures, but such alloys are even more difficult to process. To veneer these alloys with ceramic, they must be preoxidized in a suitable manner in order to get good adherence of the ceramic to the alloy. Thereby there is not always obtained an optimum oxide layer so that frequently adherence problems occur.

From German OS 3135034 (and related Heidsiek U.S. Pat. No. 4,476,090, the entire disclosure of the Heidsiek U.S. patent being hereby incorporated by reference and relied upon), there is known a material for jewelry and commodities which consist of noble metal with 1 to 70 vol. % glass which must have a transformation temperature of 300.degree. to 500.degree. C. Such materials are not useful as dentures because deformation occurs during the ceramic baking which deteriorates the fit of the denture.

Therefore, it was the problem of the present invention to develop a material for faceable dentures with a metallic matrix which is cheaper than high noble metal containing alloys, which can be processed without problem and which in any case of necessity can be faced reliably and easily with ceramic or synthetic resin.

SUMMARY OF THE INVENTION

This problem was solved according to the invention by including 0.5 to 30 vol. % of glass with a softening temperature above 650.degree. C. and/or ceramic particles having a maximum grain size of 40 .mu.m.

Preferably, the material contains oxidic particles, especially oxidic particles having melting and sintering temperatures which are above the melting respectively sintering temperatures of the metallic components. In particular, there have proven good materials which contain 1 to 12 vol. % of ceramic particles having a particle size .ltoreq.5 .mu.m, where noble metal or noble metal mixture is preferably used as matrix component. Of course, the metal matrix can also contain or consist of base metal.

The production of this material is carried out by powder metallurgy by intimately mixing metal powder having a maximum particle size of 100 .mu.m with the ceramic or glass powder condensing the powder mixture and subsequently sintering. The pressing pressure and sintering temperature depend on the metal powders used. It is also possible to prepare the powder mixture as a slip and to sinter the shaped and condensed slip composition after drying.

The incorporation of ceramic or glass powder into the metallic matrix makes it possible that in molding the denture a maximum green density can be achieved. Thus the shrinkage during sintering of the model is mimimized with the fit is improved without reducing the strength.

For an alloy having the composition Au 50 Pt 35 Pd 15 Table 1 shows the influence of the addition of different ceramic powders (in each case 10 vol. %) on the density and the 0.2% yield strength after the linear shrinkage during sintering. It can be seen that the shrinkage is less than in the ceramic free variant although the density in the sintered state is clearly higher in some cases. The 0.2% yield strength increases with one exception through the addition of the ceramic.

In Table 2 there is presented for different powder sizes and for different alloy compositions the influence of TiO.sub.2 on the linear shrinkage during and the density after sintering. In this case an increase in density and 0.2% yield strength of the sintered material in the presence of TiO.sub.2 is observed too while the shrinkage in most cases is less than that obtained with the corresponding ceramic free variants. These examples show that by the presence of ceramic powders in the metallic matrix there can be attained an increase of the green density.

To produce dentures, for example, there is used a material which consists of 90 vol. % of a metal powder mixture made of 74.4 wt. % gold powder .ltoreq.90 .mu.m, 18.6 wt. % gold powder .ltoreq.10 .mu.m, and 7 wt.% platinum .ltoreq.15 .mu.m with 10 vol.% titanium dioxide which was sintered at 1200.degree. C. However, there are also usable, e.g., the following materials: 50% gold, 35% platinum, 15% palladium, 50% gold, 35% platinum, 10% palladium, 5% silver, or 95% gold, 3% indium, 1% tin.

The compositions can consist of or consist essentially of the stated materials.

TABLE 1______________________________________ Linear Shrink- age with 0.2% Relative Sinter- Yield Density Powder ing at Stren- Sintered Ceramic Size 1200.degree. C., gth MaterialMetal 10 Vol. % .mu.m air % MPa %______________________________________50% Gold -- .ltoreq.25 21.3 582 91.835% Platinum15% Palla-dium" Bi.sub.2 O.sub.3 <3 21.3 610 92.3" SnO.sub.2 <1 17.5 415 91.6" ZrO.sub.2 <20 18.8 579 95.0" TiO.sub.2 <5 20.0 650 92.5" MgO <10 18.8 590 93.2" Glass <20 20.5 660 93.4 Softening Tempera- ture 680.degree.______________________________________ TABLE 2__________________________________________________________________________ PropertiesComposition 0.2%Gold Platinum Palladium Titanium Linear YieldConcen- Particle Par- Par- Silver Tin + Indium Dioxide Shrink- Rel. Stre-tytration Size Conc. ticle Conc. ticle Conc. Particle Conc. Particle <20 .mu.m age Sint. ngthyWt. % .mu.m Wt. % .mu.m Wt. % .mu.m Wt. % .mu.m Wt. % m Vol. % % % MPa__________________________________________________________________________50 .ltoreq.25 35 .ltoreq.15 15 .ltoreq.15 -- -- -- -- 0 21.3 91.8 58250 .ltoreq.25 35 .ltoreq.15 15 .ltoreq.15 -- -- -- -- 10 20.0 92.0 61050 .ltoreq.25 35 .ltoreq.15 15 .ltoreq.15 -- -- -- -- 20 18.8 91.9 65050 .ltoreq.50 35 .ltoreq.15 15 .ltoreq.15 -- -- -- -- 0 20.0 91.8 63050 .ltoreq.50 35 .ltoreq.15 15 .ltoreq.15 -- -- -- -- 10 20.0 97.2 69250 .ltoreq.100 35 .ltoreq.15 15 .ltoreq.15 -- -- -- -- 0 20.0 92.3 62550 .ltoreq.100 35 .ltoreq.15 15 .ltoreq.15 -- -- -- -- 10 18.8 93.3 62050 .ltoreq.50 35 .ltoreq.15 10 .ltoreq.15 5 .ltoreq.15 -- -- 0 17.5 84.8 55050 .ltoreq.50 35 .ltoreq.15 10 .ltoreq.15 5 .ltoreq.15 -- -- 10 17.5 90.0 58095.5 .ltoreq.50 -- -- -- 4.5 .ltoreq.25 0 17.6 84.7 6095.5 .ltoreq.50 -- -- -- 4.5 .ltoreq.25 2 17.0 89.4 8595.5 .ltoreq.50 -- -- -- 4.5 .ltoreq.25 4 17.0 91.1 95__________________________________________________________________________

Claims

1. A denture consisting of the melted or sintered product made from a metallic matrix material consisting of, in addition to the metallic component 0.5 to 30 vol. % of (1) glass having a softening temperature above 650.degree. C. or (2) ceramic oxide particles having a maximum particle size of 40 .mu.m or (3) a mixture of such glass and ceramic oxide particles.

2. A denture according to claim 1 containing ceramic oxide particles.

3. A denture according to claim 2 wherein the oxide is titanium dioxide, bismuth trioxide, tin oxide, zirconium oxide, or magnesium oxide.

4. A denture according to claim 3 wherein the melting and sintering temperatures of the ceramic oxide particles are above the melting and sintering temperatures of the metallic components.

5. A denture according to claim 4 containing 1 to 12 vol.% ceramic oxide particles having a maximum particle size of 5 .mu.m.

6. A denture according to claim 5 wherein the metal matrix consists of noble metal.

7. A denture according to claim 3 containing 1 to 12 vol.% ceramic oxide particles having a maximum particle size of 5 .mu.m.

8. A denture according to claim 7 wherein the metal matrix consists of noble metal.

9. A denture according to claim 2 wherein the melting and sintering temperatures of the ceramic oxide particles are above the melting and sintering temperatures of the metallic components.

10. A denture according to claim 9 containing 1 to 12 vol.% ceramic oxide particles having a maximum particle size of 5 .mu.m.

11. A denture according to claim 8 wherein the metal matrix consists of noble metal.

12. A denture according to claim 2 containing 1 to 12 vol. % ceramic oxide particles having a maximum particle size of 5 .mu.m.

13. A denture according to claim 12 wherein the metal matrix consists of noble metal.

14. A denture according to claim 1 wherein the melting and sintering temperatures of the ceramic oxide particles are above the melting and sintering temperatures of the metallic components.

15. A denture according to claim 14 containing 1 to 12 vol.% ceramic oxide particles having a maximum particle size of 5 .mu.m.

16. A denture according to claim 7 wherein the metal matrix consists of noble metal.

17. A denture according to claim 6 wherein the metal matrix consists of noble metal.

18. A denture according to claim 1 containing 1 to 12 vol.% ceramic oxide particles having a maximum particle size of 5 .mu.m.

19. A denture according to claim 18 wherein the metal matrix consists of noble metal.

20. A denture according to claim 1 wherein the metal matrix consists of noble metal.