IT201900011781A1 - Master alloy for the production of precious metal alloys and gold alloy including this master alloy - Google Patents

Description

Description of the industrial invention entitled "Master alloy for the production of precious metal alloys and gold alloys including this master alloy"

The present invention relates to a master alloy that can be mixed with a precious metal, in particular with gold, for the creation of an alloy of the precious metal and for the refinement of the crystalline grain of the precious metal. Furthermore, the present invention relates to a gold alloy, obtained starting from the master alloy indicated above mixed with gold.

In the jewelry and goldsmith sector, precious metal alloys, such as gold and platinum, include a predetermined weight quantity of these metals mixed with silver, zinc, nickel, copper or other metals.

In the rest of this description, reference will be made, purely by way of non-limiting example, only to a gold alloy of the type described above.

A gold alloy of the type described above may also include, in addition to silver, zinc, nickel and copper, one or more elements for refining the crystalline grain of gold.

The use of crystalline grain refining elements as chemical elements for improving gold alloys has long been known in the jewelry and goldsmith sector.

As is known, a solid state metal alloy, which is a gold alloy, is presented in the form of a polycrystalline aggregate, composed of single crystalline elements also referred to as grains.

In this description, the expression "crystalline grain refining" means the reduction of the size of the crystalline grain, or rather of the single crystalline element among those that make up a polycrystalline aggregate.

The main benefits attributable to the reduction in the size of the crystalline grain in gold alloys in which grain refiners are used are as follows:

- improvement of the physicochemical properties of the gold alloy, in particular of deformability and elongation;

- increase in corrosion resistance intended, for example, as a decrease in the release of nickel in white gold alloys.

The best known and most used grain refiners, in particular for refining crystalline grain in gold alloys, are iridium and ruthenium.

Iridium is a transition metal belonging to the so-called platinum group metals (also known as platinoids) and has an atomic number of 77, a molecular weight of 192 and a melting temperature of 2466 ° C.

Ruthenium is also a transition metal of the platinoid group and has an atomic number of 44, a molecular weight of 101 and a melting temperature of 2334 ° C.

Both of these metals are high-melting and have limited solubility in gold during the preparation of the alloy. For this reason, it is conceivable that they are present in the form of precipitates within the gold alloy, acting as crystallization nuclei for the formation of crystalline grains during the solidification of the alloy.

Iridium and ruthenium can be added individually and in reduced weight quantities to gold alloys. For example, the quantities of iridium and ruthenium normally added for the aforementioned purpose are equal to a few hundred parts per million compared to the total weight of the gold alloy.

A drawback of these known solutions is represented by the fact that iridium has a very high cost, which significantly affects the overall production costs of the gold alloy.

A further drawback is represented by the fact that ruthenium is much less effective than iridium in the process of refining the crystalline grain of the metal. In particular, ruthenium tends to form structural defects, known in the industry as "hard spots", in 18kt gold alloys.

Another drawback of these solutions is represented by the fact that these individually added metals do not always have a homogeneous distribution in the gold of the alloy.

Alternatively, other metals can also be used as crystalline grain refining elements, such as for example rhodium; however, even these metals do not present an optimal cost / benefit ratio with reference to the reduction of the crystalline grain size.

An object of the present invention is to provide a master alloy and a gold alloy that allow to solve the aforementioned drawbacks.

In particular, an object of the present invention is to provide a master alloy that effectively reduces the size of the crystalline grain in a gold alloy, for example up to a value of 50µm. A further object of the present invention is to make available a master alloy that has a reduced impact on the overall production costs of the gold alloy.

Another purpose of the present invention is to provide a master alloy that has a homogeneous distribution in gold after adding it to the gold alloy.

A further purpose of the present invention is to provide a master alloy that can be mixed with gold to make gold alloys with different colors.

The main purposes described above are achieved with a master alloy according to claim 1 and with a gold alloy according to claim 7.

The present invention relates to a master alloy that can be mixed with a weight quantity of a precious metal for making a metal alloy. In particular, the master alloy can be mixed with a weight quantity of gold to form a gold alloy, which represents a further object of the present invention.

However, even if this description will refer only to gold as a precious metal, this feature does not represent an undue limitation and it cannot be excluded that the master alloy can also be used with other precious metals, such as platinum for example. The preferred fields of application of the gold alloy of the present invention are those of goldsmithing and jewelry, without excluding that this gold alloy can also be used in other fields of application.

In accordance with the examples given below in the description, the gold alloy can have different colors, for example a white color, a yellow color or a red color.

For this purpose, the gold alloy may include, in addition to gold and the parent alloy, also different weight quantities of silver or nickel, zinc and copper. The different combination of the weight quantities of these elements determines the different coloring of the gold alloy.

In addition, the gold alloy can also have different carat values, i.e. include different weight quantities of gold, such as 75% of the total weight of the gold alloy (18kt), 58.3% of the total weight of the gold alloy. gold alloy (14kt), 41.6% of the total weight of the gold alloy (10kt) and 37.5% of the total weight of the gold alloy (9kt).

Some compositions of the gold alloy are indicated in the examples shown below in this description, with particular reference to the color and carat weight of the alloy.

The function of the master alloy of the present invention is to refine the crystalline grain of gold, or to reduce the size of the crystalline grain of the gold alloy to improve its mechanical strength and wear resistance.

As an indication, the crystalline grain of the gold alloy can vary from 1000μm to 50μm, with the same macroscopic composition, after the addition of the master alloy.

Both the master alloy and the gold alloy are prepared by procedures widely known in the field, which will not be further described below.

According to the main feature of the invention, the master alloy comprises a predetermined weight quantity of rhenium. Rhenium is a silvery-white transition metal having an atomic number of 75 and a melting point of 3186 ° C.

The advantage of using a master alloy containing rhenium as a crystalline grain refiner, rather than iridium or ruthenium, consists primarily of having lower costs for the production of the gold alloy, with the same effectiveness in reducing crystalline grain.

The weight quantity of rhenium present in the master alloy can be equal to at least 6.5% with respect to the total weight of the master alloy, preferably between 6.5% and 7.5% and even more preferably close to 7% with respect to the weight overall of the master alloy.

Advantageously, this weight quantity of rhenium was chosen as it represents a reasonable compromise between a maximum weight quantity of soluble rhenium in the master alloy and a minimum quantity effective for refining the crystalline grain in the gold alloy.

Furthermore, the master alloy may include, in addition to rhenium:

- a predetermined weight quantity of nickel;

- a predetermined weight quantity of tin;

- a predetermined weight quantity of copper.

Hence, the master alloy having the above composition can be defined as a quaternary alloy.

Advantageously, the weight quantity of nickel can be between 66% and 70% with respect to the total weight of the master alloy, the weight quantity of copper can be between 1% and 5% with respect to the total weight of the master alloy and the weight quantity of tin can be between 20% and 25% with respect to the total weight of the master alloy. Considering the weight amount of rhenium indicated above, a preferred composition of the master alloy is as follows:

- a weight quantity of copper equal to 1.8% with respect to the total weight of the master alloy;

- a weight quantity of rhenium equal to 7% with respect to the total weight of the master alloy;

- a weight quantity of tin equal to 23% with respect to the total weight of the master alloy;

- a weight quantity of nickel equal to 68.2% with respect to the total weight of the master alloy.

A noteworthy aspect of the present invention is that the master alloy, having a reduced solubility in the gold of the gold alloy, behaves similarly to iridium during the crystalline grain refining process, forming precipitates which they act as crystallization nuclei for the formation of crystalline grains during the solidification of the alloy.

It was also found that the crystalline grain refining efficacy of this master alloy in a gold alloy is comparable to that of iridium and is promoted by rhenium in combination with the other elements that form the master alloy.

In addition, it was found that the composition of the master alloy indicated above helps to keep the rhenium in solution in the master alloy, avoiding its separation after adding it to the gold alloy and promoting the homogeneous distribution of the rhenium in the gold alloy.

The homogeneous distribution of the master alloy in the gold alloy determines the formation of a greater number of crystallization nuclei, and therefore a greater reduction of the crystalline grain.

The master alloy and the gold alloy may also include impurities such as residues resulting from manufacturing processes. These impurities have a negligible effect on the overall weight of the alloy and for this reason they will not be indicated in the compositions reported below.

Below are some examples of different compositions of the gold alloy comprising the master alloy in accordance with the present invention, where the master alloy has the previously indicated preferred composition. The weight quantities reported are all to be understood with reference to the total weight of the gold alloy.

Example I - Gold alloys with a weight of gold equal to 75% (18kt) - white gold alloy: 75% gold, 5% nickel, 3.5% zinc, 0.035% mother alloy, 16.465% copper;

- red gold alloy: 75% gold, 1% silver, 0.75% zinc, 0.035% master alloy, 23.215% copper;

- yellow gold alloy: 75% gold, 5% silver, 3.6% zinc, 0.035% master alloy, 16.365% copper.

Example II - Gold alloys with a weight of gold equal to 58.3% (14kt) - white gold alloy: gold 58.3%, nickel 8.3%, zinc 6.6%, master alloy 0 , 06%, copper 26.74%;

- red gold alloy: 58.3% gold, 5.2% silver, 1% zinc, 0.06% master alloy, 35.44% copper;

- yellow gold alloy: 58.3% gold, 8.3% silver, 6.6% zinc, 0.06% master alloy, 26.74% copper.

Example III - Gold alloys with a weight of gold equal to 41.6% (10kt) - white gold alloy: gold 41.6%, nickel 8.7%, zinc 8.7%, master alloy 0 08%, copper 40.92%;

- red gold alloy: gold 41.6%, silver 5.8%, zinc 1.2%, master alloy 0.08%, copper 51.32%;

- yellow gold alloy: 41.6% gold, 8.7% silver, 8.7% zinc, 0.08% master alloy, 40.92% copper.

Example IV - Gold alloys with a weight of gold equal to 37.5% (9kt) - white gold alloy: gold 37.5%, nickel 9.4%, zinc 9.4%, master alloy 0 09%, copper 43.61%;

- red gold alloy: 37.5% gold, 7% silver, 1.2% zinc, 0.09% master alloy, 54.21% copper;

- yellow gold alloy: 37.5% gold, 9.4% silver, 9.4% zinc, 0.09% master alloy, 43.61% copper.

From the above examples, it is first observed that the weight quantity of master alloy added to the gold alloy and necessary to obtain an effective crystal grain refinement increases as the gold alloy's carat decreases.

In addition, it is observed that in the gold alloys of the above examples a higher weight quantity of copper determines the red color of the gold alloy, while nickel in place of silver determines the white color of the alloy.

However, the whitening agent of the gold alloy can also be different from nickel, without thereby departing from the scope of protection of the present invention.

Finally, it is noted that copper and nickel are present both in the composition of the master alloy and in the composition of the gold alloy (nickel only in the composition of the white gold alloy) independently of the master alloy.

The weight quantities of copper and nickel indicated in Examples I-IV, therefore, do not take into account the weight quantities of copper and nickel already present in the master alloy.

From the foregoing it is now clear that the master alloy and the gold alloy of the present invention allow to advantageously achieve the intended purposes.

In particular, it is clear how the presence of rhenium in the master alloy, in combination with the other elements, allows to obtain a refinement of the crystalline grain of gold comparable to that of iridium.

Furthermore, the elements that form the master alloy have a lower cost compared to the iridium and ruthenium commonly used in the sector as crystalline grain refiners, and therefore the overall production costs of this gold alloy are lower than those of gold alloys. gold notes.

Naturally, the above description of embodiments that apply the innovative principles of the present invention is given by way of example of such innovative principles and must therefore not be taken as a limitation of the scope of protection claimed herein.

In particular, the compositions of the master alloy could also be slightly different from those indicated in the examples, provided that there is always a weight quantity of rhenium, preferably close to 7% with respect to the total weight of the master alloy.

Claims (10)

Claims 1. Master alloy that can be mixed with a predetermined weight quantity of a precious metal for making an alloy of the precious metal and for refining the crystalline grain of the precious metal, characterized by the fact that it includes a predetermined weight quantity of rhenium. 2. Master alloy according to claim 1, characterized in that the weight quantity of rhenium is equal to at least 6.5% with respect to the total weight of the master alloy. 3. Master alloy according to claim 2, characterized in that the predetermined weight quantity of rhenium is comprised between 6.5% and 7.5% with respect to the total weight of the master alloy, preferably close to 7% with respect to the total weight of the alloy mother. 4. Master alloy according to claim 1, characterized in that it comprises a predetermined weight quantity of nickel, a predetermined weight quantity of tin and a predetermined weight quantity of copper. 5. Master alloy according to claim 4, characterized in that the weight quantity of nickel is between 66% and 70% with respect to the total weight of the master alloy, the weight quantity of copper is between 1% and 5% with respect to the weight total weight of the master alloy, the weight quantity of tin is between 20% and 25% with respect to the total weight of the master alloy and the weight quantity of rhenium is at least 6.5%, preferably between 6.5% and 7, 5% with respect to the total weight of the master alloy. 6. Master alloy according to claim 5, characterized in that it has the following composition: - a weight quantity of copper equal to 1.8% of the total weight of the master alloy; - a weight quantity of tin equal to 23% with respect to the total weight of the master alloy; - a weight quantity of rhenium equal to 7% with respect to the total weight of the master alloy; - a weight quantity of nickel equal to 68.2% with respect to the total weight of the master alloy. 7. Gold alloy characterized by the fact of including: - a predetermined weight quantity of gold with respect to the total weight of the gold alloy; - a predetermined weight quantity of a master alloy for refining the crystalline grain of gold in accordance with any of the claims 1 to 6. 8. Gold alloy according to claim 7, characterized in that it comprises a predetermined weight quantity of silver or nickel. 9. Gold alloy according to claim 8, characterized in that it comprises a predetermined weight quantity of zinc and copper. 10. Gold alloy according to claim 9, characterized in that the weight quantity of gold is equal to 75%, or 58.3%, or 41.6% or 37.5% with respect to the total weight of the gold alloy .