DE10033445A1 - Dental alloy used as a casting alloy or cutting alloy, especially for implants, contains gold - Google Patents

Abstract

Dental alloy contains up to 95 wt.% gold. Preferred Features: The alloy contains further alloying components (in wt.%): 0-90 Pd, 0-30 Ag, 0-20 Pt, 0-20 Cu, 0-20 Co, 0-10 Sn, 0-20 Zn, 0-20 In, 0-20 Ga, 0-20 Mn, 0-10 Ru, 0-10 Re, 0-10 Ir, 0-10 Ge, 0-10 Fe, 0-10 Rh, 0-10 W, 0-10 Ti and 0-10 Ta. The gold content is preferably 65-85 or 70-80 wt.%. The alloy is in the form of cast platelets.

Description

The present invention relates to dental alloys. In particular, the PRESENT INVENTION Dental alloys with a high gold content that are good as Casting alloys and milling alloys are suitable.

It is known to replace dentures, such as. B. crowns or bridges, made of gold. gold pour alloys or other alloys.

In today's computer-controlled era, such products are also out Blocks that can be made from a variety of suitable materials (e.g. made of gold, titanium, zircon, glass, inceram) with the help of CAD / CAM / CNC controlled machines. For conventional technology, but especially for the so-called metal ceramic technology, casting alloys, z. B. gold or Palladium alloys used.

The object of the present invention is to provide new dental alloys with good physical and mechanical properties that are good for Use as a casting or milling alloy, especially for implants.

This task is solved with the present invention.

The invention relates to a dental alloy with a high gold content according to Claim 1.

Appropriate embodiments thereof are the subject of claims 2 to 6.  

Another object is the use of the alloys according to the invention as Casting or milling alloy.

The dental alloys according to the invention are suitable both as casting and as milling alloys. They are more appropriate for use as milling alloys as alloy blocks in a form suitable for milling.

In the dental alloy according to the invention with a high gold content, the gold content is up to 95% by weight, preferably 13 to 92% by weight, primarily 65 to 85% by weight and in particular 70 to 80% by weight. As further alloy components, the dental alloy according to the invention can, for. B. contain one or more of the following components (in% by weight):
Palladium (Pd) 0-90%; Silver (Ag) 0-30%; Platinum (Pt) 0-20%; Copper (Cu) 0-20%; Cobalt (Co) 0-10%; Tin (Sn) 0-20%; Zinc (Zn) 0-20%; Indium (In) 0-20%; Gallium (Ga) 0-20%; Manganese (Mn) 0-20%; Ruthenium (Ru) 0-10%; Rhenium (Re) 0-10%; Iridium (Ir) 0-10%; Germanium (Ge) 0-10%; Iron (Fe) 0-10%; Niobium (Nb) 0-10%; Rhodium (Rh) 0-10%; Tungsten (W) 0-10%; Titanium (Ti) 0-10%; Tantalum (Ta) 0-10%.

As a casting alloy, the dental alloy according to the invention is usually in Form of pouring plate.

As a milling alloy, the alloy is preferably in the form of a rectangular one Blocks in front, but can also be used as bars (by the meter) or divisible plates, or with circular, triangular, diamond-shaped shape, etc.

The dental alloy is preferably in the form of rectangular blocks, in particular with the following dimensions:
Length: 3 to 10 cm;
Width: 0.5 to 5 cm;
Thickness: 0.5 to 2.0 cm.

Figs. 1 shows an embodiment in the form of a rectangular block for milling, wherein the reference numerals denote:
L = length;
B = width;
D = thickness;
F = milled part

The composition of a dental alloy that is well suited for milling, is especially due to the subsequent ceramic firing technique required composition determined.

These requirements are z. B. met with a dental alloy containing the following alloy components (wt .-%):
Gold (Au) 13-92%; Palladium (Pd) 15-85%; Silver (Ag) 5-65%; Platinum (Pt) 0.1-25%; Copper (Cu) 2-20%; Cobalt (Co) 2-20%; Tin (Sn) 0.1-5%; Zinc (Zn) 0.5-5%; Indium (In) 0.1-20%; Gallium (Ga) 0.1-10%; Manganese (Mn) 0.1-5%; Ruthenium (Ru) 0.1-5%; Rhenium (Re) 0.1-5%; Iridium (Ir) 0.01-2%; Germanium (Ge) 0.1-2%; Iron (Fe) 0.01-2%; Niobium (Nb) 0.1-5%; Rhodium (Rh) 0.1-5%; Tungsten (W) 0.1-5%; Titanium (Ti) 0.1-10%; Tantalum (Ta) 0.1-5%.

Such a dental alloy has excellent milling properties.

The following examples relate to preferred embodiments of the present invention without restricting its scope thereto.  

example 1

An alloy which is particularly suitable as a casting alloy has, for. B. the following composition (in% by weight):
Gold 77.6; Platinum 19.6; Zinc 2.1; Tantalum 0.6; Iridium 0.1

The alloys according to the invention are medical devices of class IIa and meet all requirements of the EC directive 93/42 / EEC (1993). consider Standards are: ISO 9002 (1994), EN 46002 (1996), ISO 9693 (1991) and ISO 10993 (1992).

characteristics

Color yellow
Melting interval solidus-liquidus (Ts-Tl) (° C): 1170-1230
Density (g / cm ³

): 19.0
Average coefficient of thermal expansion α (10 ^-6

° C ^-1

): 13.8

Mechanical properties

Young's modulus E (MPa): 102000
Yield strength 0.2% (Rp 0.2) (MPa): 560
Vickers hardness (HV): 220
A (%): 15

The casting alloy is in the form of commercially available casting plates.  

Example 2

This example uses the one described in Example 1 Alloy (composition (% by weight): gold 77.6; platinum 19.6; zinc 2.1; tantalum 0.6; Iridium 0.1) as a milling alloy. Surprisingly, it has been shown that this alloy is also very suitable as a milling alloy.

The alloy was used in the form of a block, as shown in Fig. 1.

It was made with a dental milling system from DCS Dental AG, CH- 4123 Allschwil, worked (Preciscan, Precimill, DSC software Dentform).

Milling cutters with the following diameters were used to mill the alloy used: 3 mm, 2 mm, 1.5 mm, 1.0 mm.

The alloys according to the invention can be applied to one in this field known way, e.g. B. Process as follows:

Model

The corresponding ones are for the area of metal ceramic technology Follow instructions, preferably with a minimum wall thickness of 0.3 mm should be adhered to.

Melt

The alloys mentioned can be in suitable crucibles, for. B. from Ceramic material, made of carbon and glassy carbon, are melted. in this connection all melting techniques can be used. Before submerging in water the cylinder is allowed to cool to a temperature of 400 ° C.

Treatment of fittings for metal-ceramic technology before oxidation

The Fittings are made with the help of ceramic-bonded or hard metal grinding wheels  sanded, sandblasted with aluminum oxide (50 µm), and then carefully with a Ultrasound or steam jet cleaned.

Valve oxidation

Before applying the first ceramic layer (opaque milk) is an oxidation thermal treatment at 980 ° C for approx. 5 to 10 minutes, especially 8 minutes.

Firing the ceramics

The burning of the ceramic elements is under To follow the manufacturer's instructions. When choosing the cooling methods, the coefficients of thermal expansion must be taken into account.

The dental alloys according to the invention have excellent processing and usage properties.

The denture products obtained from the dental alloys according to the invention have excellent dimensional stability, edge stability and torque stability.

They are suitable for the manufacture of all common denture products, such as B. Crowns, bridges, double crowns, telescopic crowns, casting barrels bridges, removable Cash dentures, such as B. inlays, removable bridges, for claw model casting, for implant crowns and bridges, and for bioimplants, which is why they are a big one economic importance.

Due to their good corrosion resistance, they are resistant to influences environment (e.g. by mouth fluid) extremely stable.

The dental alloys according to the invention can be oxidized on the surface, whereby z. B. in metal-ceramic technology, a good connection between ceramics and alloy is obtained.  

The blocks made from the dental alloys of the invention have good and precise millability with milling machines, especially when using of dental milling systems from DCS Dental AG, CH-4123 Allschwil, on; they are therefore particularly suitable for computer-controlled and computer-assisted milling machines, and also for dry milling and uncooled milling.

Because of their good suitability for computer-controlled and computer-aided (CAD / CAM / CNC) milling machines can with the dental alloys according to the invention time-consuming modeling in wax, embedding, casting and sandblasting omitted, whereby investment, modeling waxes, blasting media, workload and high personnel costs can be saved and good economy too to achieve. The dental alloy according to the invention can be used for milling Denture products such as B. Crowns and bridges, with high quality and precision and produce inexpensively within 24 hours.

Claims (11)

1. Dental alloy with a high gold content, the gold content up to 95% by weight is. 2. Dental alloy according to claim 1, characterized in that the gold content 13th is up to 92% by weight. 3. Dental alloy according to claim 1 or 2, characterized in that it contains one or more of the alloy components (in% by weight) as further alloy components:
Palladium (Pd) 0-90%; Silver (Ag) 0-30%; Platinum (Pt) 0-20%; Copper (Cu) 0-20%; Cobalt (Co) 0-10%; Tin (Sn) 0-20%; Zinc (Zn) 0-20%; Indium (In) 0-20%; Gallium (Ga) 0-20%; Manganese (Mn) 0-20%; Ruthenium (Ru) 0-10%; Rhenium (Re) 0-10%; Iridium (Ir) 0-10%; Germanium (Ge) 0-10%; Iron (Fe) 0-10%; Niobium (Nb) 0-10%; Rhodium (Rh) 0-10%; Tungsten (W) 0-10%; Titanium (Ti) 0-10%; Tantalum (Ta) 0-10%. 4. Dental alloy according to claim 1 or 2, characterized in that it contains the following alloy components (in% by weight):
Gold (Au) 13-92%; Palladium (Pd) 15-85%; Silver (Ag) 5-65%; Platinum (Pt) 0.1-25%; Copper (Cu) 2-20%; Cobalt (Co) 2-20%; Tin (Sn) 0.1-5%; Zinc (Zn) 0.5-5%; Indium (In) 0.1-20%; Gallium (Ga) 0.1-10%; Manganese (Mn) 0.1-5%; Ruthenium (Ru) 0.1-5%; Rhenium (Re) 0.1-5%; Iridium (Ir) 0.01-2%; Germanium (Ge) 0.1-2%; Iron (Fe) 0.01-2%; Niobium (Nb) 0.1-5%; Rhodium (Rh) 0.1-5%; Tungsten (W) 0.1-5%; Titanium (Ti) 0.1-10%; Tantalum (Ta) 0.1-5. 5. Dental alloy according to claim 1 or 3 with a gold content of 65 to 85% by weight. 6. Dental alloy according to claim 1 or 3 with a gold content of 70 to 80% by weight. 7. Dental alloy according to one of claims 1 to 6 in the form of casting plates. 8. Dental alloy according to one of claims 1 to 6 in the form of blocks for Milling. 9. Dental alloy according to claim 8 in the form of rectangular blocks with the dimensions:
Length: 3 to 10 cm;
Width: 0.5 to 5 cm;
Thickness: 0.5 to 2.0 cm. 10. Use of a dental alloy according to one of claims 1 to 7 as a casting alloy. 11. Use of a dental alloy according to one of claims 1 to 6, 8 and 9 as Fräslegierung.