The object of the present invention is a palladium alloy with high hardness as compared to pure palladium or to other alloys of the same metal, to be used in goldsmith and jeweller's art, both for obtaining goldsmith semi-finished products and jewels manufactured by lost wax casting. The invention further relates to the process for manufacturing said high-hardness palladium alloy.
It is known that pure palladium (999‰) has very low hardness (about 50-80 Vickers) and that therefore, it cannot be used in the creation of jewels or goldsmith semi-finished products (wires, tubes, bars, plates, etc.). Hardness, which can reach the maximum values with the hardening produced by the mechanical processes, is too low to prevent wear. In particular, a low hardness comes together with poor mechanical properties (breaking stress and yield stress of the material). The material cannot be used as a jewel or semi-finished product as it would tend to wear out too quickly and moreover, it would get deformed by the simple handling or when subject to moderate stress. By adding other alloy elements to palladium it is possible to increase the hardness and improve the mechanical properties. Since the percentage of palladium allowed by the regulations in force for goldsmith alloys is equal to 950‰ by weight, the possible additions of secondary elements cannot exceed the concentration of 50‰. This restricts the possibilities of intervening on the chemical composition of the alloy and makes it necessary to find elements that should be highly efficient in changing the physical and mechanical properties, even with small additions thereof.
An object of the present invention is to provide a high-hardness palladium alloy for use in goldsmith and jeweller's art, whose mechanical features should be such as to make it suitable for mechanical processes, such as drawing, rolling, shearing, pressing, spinning. In particular, the object of the present invention is to provide an alloy of the type mentioned above, which should exhibit a Vickers hardness higher than 170 HV on the alloy still in the raw casting conditions.
Another object of the present invention is to provide a process for manufacturing a high-hardness palladium alloy for use in goldsmith and jeweller's art, which should be simple and safe to obtain.
In view of these objects, the present invention provides a high-hardness palladium alloy for use in the goldsmith and jeweller's art. Moreover, the present invention provides a process for manufacturing a high-hardness palladium alloy for use in the goldsmith and jeweller's art.
Further advantageous features are described herein.
The above claims are intended as integrally reported herein.
The present invention will appear more clearly from the following detailed description made with reference to the annexed pictures provided by way of a non-limiting example only, wherein:
The high-hardness palladium alloy, according to the present invention, for use in goldsmith and jeweller's art, belongs to the family of alloys having the following concentrations of elements, expressed in thousandths (‰):
palladium from 948 to 990‰, copper from 0.0 a 50‰, indium from 0.0 to 50‰, gallium from 1 to 48‰, aluminium from 0.8 to 49.5‰, ruthenium from 0.0 to 50‰, rhenium from 0.0 to 50‰, silicon from 0.1 to 1.2‰, platinum from 0.0 to 40‰, nickel from 0.0 to 50‰, iridium from 0.0 to 40‰. The experimental trials carried out have shown that the best combination of elements of the alloy according to the present invention is as follows (expressed as ‰ by weight):
Preferably, palladium is used in concentrations comprised between 950 and 952‰, in order to ensure the minimum percentage required by law. The contents of ruthenium and rhenium are variable between 0.01 and 0.06‰, in order to ensure sufficient refining of the crystalline grain, which is especially important when the alloy according to the invention is used for fusion with the lost wax casting method.
Gallium and aluminium are the elements that produce an increase of the hardness of the above alloy, both in combination with each other and individually. In fact, the alloy itself exhibits a Vickers hardness equal to 180 HV 10/30 on the raw cast material, that is, not work-hardened further by mechanical processing. The experiments carried out show that the mechanical processing produces a further increase of the hardness of the alloy according to the invention, which can achieve 320 HV 10/30 without any breakage of the semi-finished product. The elements in the alloy do not make the alloy itself become brittle, as it maintains excellent properties of mechanical workability, both in drawing and in rolling.
The alloy according to the invention is also suitable for being welded by arc welding with tungsten gas (TIG or GTAW) and laser beam welding. The chemical composition thereof exhibits no contraindications to the application of these two welding methods.
In the practical use, the component elements of the alloy according to the invention are placed in a crucible made of zirconia or boron nitride or other ceramic material and are melted using the induction method and using a protective atmosphere of argon, nitrogen or other inert gas. The alloy can be cast in a rectangular section plate or in a square section bar and can then be processed by rolling, both in plate and in square, or it can be drawn using die plates with diamond core. In particular, the alloy according to the invention is produced by placing the alloy elements in the form of rolled section or shots in a crucible made of zirconia or boron nitride. The crucible, along with the material, is introduced into a reel belonging to an induction melting furnace. The frequency of the induction field may range from 10 KHz to 1 MHz but, preferably, it is equal to 10 KHz. The material is melted into a chamber first evacuated and then filled with argon gas at the pressure of 0.8 ATM. Once the alloy has melted, the casting is carried out, still in argon atmosphere, in a flask made of copper or copper-beryllium alloy.
The shapes of the ingot obtained by casting may vary from the rectangular section to the square or circular section. The ingot weight may vary from 400 g to a few Kg, based on the crucible capacity.
Number | Date | Country | Kind |
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TO2006A0086 | Feb 2006 | IT | national |
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2478225 | Atkinson | Aug 1949 | A |
4378690 | Stiebritz et al. | Apr 1983 | A |
4580617 | Blechner et al. | Apr 1986 | A |
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56123338 | Sep 1981 | JP |
Number | Date | Country | |
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20080063556 A1 | Mar 2008 | US |