IT202100017651A1 - Master alloy for making alloys of a precious metal, method of producing the master alloy and gold alloy including the master alloy - Google Patents

Description

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

The present invention relates to a master alloy which can be mixed with a precious metal, in particular with gold, for making alloys of the precious metal and for refining the crystalline grain of the precious metal.

Furthermore, the present invention relates to a method of producing the master alloy and a gold alloy comprising the master alloy indicated above.

In the jewelery and goldsmith's sector, the alloys of precious metals, such as for example gold and platinum, include a quantity predetermined weight of further metals selected for example from the group comprising copper, silver, zinc, nickel and germanium.

In the continuation of this description, we will do? reference, purely by way of example and not of limitation, only to a gold alloy. A gold alloy can? also include, in addition to the metals indicated above, one or more? elements for refining the crystalline grain of gold.

The use of refining elements of the crystalline grain in the gold alloys? known for some time in the jewelery and goldsmith sector.

A metal alloy in the solid state, which one? an alloy of? gold, comes in the form of a polycrystalline aggregate, composed of single crystalline elements also? defined grains.

In the present description with the expression ?refinement of the crystalline grain? it means the reduction of the size of the crystalline grain, or of the single crystalline element among those that make up a polycrystalline aggregate.

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

- improvement of the properties? gold alloy physico-chemical;

- increased resistance to corrosion.

A grain refiner particularly known and used in the sector, in particular for the refinement of crystalline grain in gold alloys, is ? the iridium. The iridium ? a transition metal belonging to the so-called platinum group metals (also known as platinumoids) and has an atomic number of 77, a molecular weight of 192 and a melting point of 2466?C.

The iridium ? high-melting and has a solubility? limited in gold during league preparation. For this reason, ? conceivable that the iridium is present in the form of a precipitate inside the gold alloy, forming crystallization nuclei for the formation of crystalline grains during the solidification of the gold alloy.

The iridium can? be added individually and in quantity? weights reduced to the gold alloy to be made. For example, the quantities Weights of iridium normally added for the aforementioned purpose are equal to a few hundred parts per million with respect to the total weight of the gold alloy.

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

Another drawback of the aforementioned solutions? represented by the fact that the iridium, if added individually to the gold to make the alloy, does not have a homogeneous distribution in the gold.

Alternatively, other metals can also be used as refining elements of the crystalline grain, such as for example rhodium; however, rhodium also does not present an optimal cost/benefit ratio with respect to the reduction of the crystalline grain size in the gold alloy.

Ruthenium too? known as a refining element of the crystalline grain in gold alloys; however, ruthenium tends to form hard spots after being added to the gold alloy, particularly in the presence of nickel and/or other deoxidizing elements, such as silicon, and/or in high quantities. weights greater than 1400ppm.

In the context of this description, the expression ?hard point? indicates a coarse aggregate that forms in the cooled metal alloy as a result of the precipitation of the components with higher specific gravity in the molten metal alloy.

In particular, hard spots generally have a different composition than the alloy and are very hard; such hard points are formed when components of the alloy present in quantities? reduced substances (such as grain refiners or impurities) combine together to form aggregates of the type described above.

From WO2014/174482 ? note a master alloy for the production of white gold alloys comprising silver, zinc, copper and manganese and a quantity weight of a grain refiner between 0% and 25% of the total weight of the master alloy.

The grain refiner ? chosen within the group including iridium, ruthenium, rhenium, cobalt and rhodium and the master alloy can? further comprising a deoxidizing agent selected from the group comprising silicon, lithium and phosphorus. Furthermore, this master alloy ? nickel and palladium free.

A drawback of this solution? represented by the fact that this master alloy could not be used for the production of yellow gold alloys or red gold alloys with the same efficiency in refining the crystalline grain.

A further drawback of the solution described above? represented by the fact that the presence of deoxidizing agents in the master alloy, in particular silicon, can? cause the formation of hard spots in combination with grain refiner, especially ruthenium.

An object of the present invention ? that of making available a master alloy, a method of producing the master alloy and a gold alloy comprising the master alloy which enable the above mentioned drawbacks to be solved.

In particular, an object of the present invention ? that of providing a master alloy which effectively reduces the size of the crystalline grain in a gold alloy, for example up to a value close to 100?m.

A further object of the present invention ? that of providing a master alloy which has a reduced impact on the overall production costs of the gold alloy.

Another object of the present invention ? that of making available a master alloy which presents a homogeneous distribution in the gold following the addition to create the gold alloy.

A further object of the present invention ? that of providing a master alloy that can be mixed with gold to create gold alloys with different colours.

Another object of the present invention ? that of providing a master alloy that effectively reduces the crystalline grain of the gold regardless of the type of processing carried out by the gold alloy.

A further object of the present invention ? that of providing a method for producing a master alloy which allows for an improvement in the solubilisation of the grain refining element, particularly ruthenium, in the other components of the master alloy.

Another object of the present invention ? that of making available a gold alloy with a crystalline grain refined up to 100?m.

The main purposes described above are achieved with a master alloy for making alloys of a precious metal according to claim 1, with a method for producing a master alloy according to claim 7 and with a gold alloy according to claim 11.

To make more the explanation of the innovative principles of the present invention and its advantages with respect to the prior art is clear, exemplary embodiments of the compositions of the master alloy and of the gold alloy object of the present invention will be described hereinafter, with the aid of the attached drawings. In the drawings:

- figures 1a-1c are images taken under a metallographic microscope at different magnifications (respectively 50X, 100X and 200X) of the crystalline grain of a gold alloy obtained starting from a first embodiment of the master alloy object of the present invention;

- figures 2a and 2b are images taken under a metallographic microscope at different magnifications (respectively 20X and 50X) of the crystalline grain of a gold alloy obtained starting from a second embodiment of the master alloy object of the present invention.

The present invention relates to a master alloy which can be mixed with quantities predetermined weights of a precious metal for the creation of alloys of the precious metal and for the refinement of the crystalline grain of the precious metal.

In particular, the mother league ? intended to be mixed with a quantity? weight of gold for making a gold alloy which is a further object of the present invention.

However, even if the present description refers only to gold alloys, this characteristic does not represent an undue limitation and is not to exclude that the master alloy can also be used in combination with other precious metals, such as for example platinum, subject to possible adjustment of the composition of the master alloy.

The preferred fields of application of the gold alloy of the present invention are those of goldsmithing and jewellery.

In accordance with the examples reported in the present description, the gold alloy can present different colors and preferably a yellow color or a red color.

These colors also depend at least partially on the composition of the master alloy mixed with the gold to make the gold alloy.

Furthermore, the gold alloy object of the present invention preferably has a carat value of 18k, i.e. a weight content of gold equal to 75% with respect to the total weight of the gold alloy and a weight content of master alloy equal to 25% compared to the total weight of the gold alloy.

However, the gold alloy can also present different carat values, obtained by increasing the quantity? weight of master alloy contained in the gold alloy compared to the quantity? weight of gold.

The master alloy preferably comprises the following general composition:

- a quantity? weight of silver (Ag) between 2% and 50% of the total weight of the master alloy;

- a quantity? weight of zinc (Zn) between 1% and 15% with respect to the total weight of the master alloy;

- a quantity? weight of ruthenium (Ru) as refining element of the crystalline grain between 0.05% and 0.14% with respect to the total weight of the master alloy;

- a quantity? weight of germanium (Ge) between 0.2% and 0.9% with respect to the total weight of the master alloy.

The quantity? remaining weight of the master alloy, or the difference between the total weight of the master alloy and the sum of the quantities? weights indicated above with reference to the other components, ? formed from copper (Cu).

How can you? note, the master alloy object of the present invention ? free of nickel and/or silicon.

This expedient avoids adverse reactions for the parts of the user's body that come into contact with the jewel or necklace made with the gold alloy, generally due to the presence of nickel. Furthermore, the exclusion of silicon as a deoxidizing element from the composition of the master alloy makes it possible to avoid or reduce the formation of hard spots in the polycrystalline aggregate of the gold alloy following interaction with ruthenium.

Advantageously, the ruthenium ? present in the mother alloy in quantity? by weight between 0.07% and 0.14% with respect to the total weight of the master alloy and the germanium ? present in the mother alloy in quantity? by weight between 0.25% and 0.6% with respect to the total weight of the master alloy.

Ruthenium and germanium are added to the master alloy according to the modalities? described below with reference to the production method of the master alloy.

Two examples are given below relating to two embodiments of the master alloy object of the present invention which provide for two different compositions. The quantities? weights shown are all to be understood with reference to the overall weight of the master alloy.

Example I

- a quantity? weight of silver equal to 4%;

- a quantity? weight of zinc equal to 3%;

- a quantity? ruthenium weight equal to 0.12%;

- a quantity? weight of germanium equal to 0.48%;

- a quantity? weight of copper equal to 92.4%.

Example II

- a quantity? weight of silver equal to 47%;

- a quantity? weight of zinc equal to 2%;

- a quantity? ruthenium weight equal to 0.08%;

- a quantity? weight of germanium equal to 0.32%;

- a quantity? weight of copper equal to 50.6%.

The two embodiments of the master alloy indicated above are responsible for the crystalline grains of the gold alloys as illustrated respectively in figures 1a-1c and 2a-2b.

In particular, the crystalline grain of the gold alloy obtained starting from the master alloy object of the present invention is less than 500?m and ? preferably between 100?m and 200?m.

This crystalline grain gives the gold alloy a high resistance to corrosion and improves the corrosion properties. physicochemical properties of the gold alloy.

The gold alloy samples of figures 1a-1c and 2a-2b and for which ? been analyzed the crystalline grain are obtained by the same production process, or by:

- investment casting with melting temperature close to 1000?C;

- casting of the molten mass into a plaster mold maintained at a temperature close to 640°C;

- cooling in water after about three minutes from casting to obtain a manufactured article or a series of manufactured articles, preferably strips of 1 cm by 1 cm and a thickness equal to 2 mm;

- metallographic attack, of type in itself? known.

The present invention also relates to a method for producing the master alloy of the type indicated above.

The method mainly comprises the following stages:

i) preparation of a first molten starting alloy comprising a quantity weight of copper equal to 50% compared to the total weight of the first starting alloy, a quantity? weight of germanium equal to 40% compared to the total weight of the first starting alloy and a quantity? weight of ruthenium equal to 10% with respect to the total weight of the first starting alloy;

ii) casting of the first starting alloy in a mold and cooling of the first starting alloy to obtain a manufactured article or a series of manufactured articles, preferably in the form of spheres or ingots;

iii) preparing a second molten starting alloy, said second starting alloy comprising a quantity predetermined weight of copper compared to the total weight of the second starting alloy, a quantity? predetermined weight of silver compared to the total weight of the second starting league and a quantity? predetermined weight of zinc with respect to the total weight of the second starting alloy;

iv) adding the article or articles made in said phase ii) to the second molten starting alloy to obtain the master alloy;

v) stirring and mixing of the molten master alloy.

The quantities? weights of copper, silver and zinc contained in the second starting alloy are such that the quantities? of these elements in the finished master alloy correspond to those previously indicated for the two embodiments of the master alloy.

Furthermore, the quantities weights of copper indicated for the two embodiments of the master alloy indicated above are given by the accumulation of the quantities? weights of copper contained in the first and second starting alloys.

This production method has the advantage of allowing almost complete solubilisation of the ruthenium in the master alloy; therefore, the ruthenium initially present in the first starting alloy, also? defined as a ternary alloy, is found in the same quantity? weigh them in the finished master alloy.

In fact, the ruthenium solubilized in the other components of the master alloy does not form hard spots with them, how? possible to detect, for example, by means of a metallographic microscope investigation of the master alloy.

Such an advantage ? made possible also by the fact that phase i) of preparation of the first starting alloy includes the following sub-phases: vi) melting of the quantity? weight of germanium indicated above; vii) addition of the quantity? ruthenium weight, preferably in powder form, to molten germanium to make a mixture;

viii) stirring the mixture for a predetermined time interval; ix) addition of the quantity? weight of copper fused to the mixture to make the first starting alloy;

x) stirring and mixing of the first starting alloy.

The preparation of the first molten starting alloy, in particular by means of substeps vi)-x), allows the ruthenium to be effectively solubilized with the other components of the master alloy.

What? like the first molten starting alloy obtained following substeps vi)-x), the molten master alloy is also cast into molds having a predetermined profile and cooled to make corresponding manufactured articles, such as for example spheres or ingots of variable dimensions .

These artifacts can be supplied to the gold alloy producer to be used for the production of gold alloys.

The sub-phase vi) of fusion of the quantity? weight of germanium ? preferably made in a graphite crucible heated up to a temperature close to 1200?C.

Conveniently, the predetermined time interval of sub-phase viii) has a duration close to 15 minutes.

Furthermore, the ruthenium powder ? added to molten germanium to make the mixture in the form of copper-coated capsules.

From the above? it is now clear that the master alloy and the gold alloy of the present invention and the production method of the master alloy allow the prefixed objects to be advantageously achieved.

Particularly, ? clear as the quantities? weights of the elements indicated above make it possible to obtain a grain refinement of the gold alloy up to 100?m, avoiding the formation of hard spots.

Furthermore, the production method which provides for the preparation of a first starting alloy in the form of manufactured articles to be added and mixed with a second starting alloy to obtain the master alloy allows ruthenium to be effectively solubilized in the master alloy.

Naturally, the present description of embodiments which apply the innovative principles of the present invention ? given as an example of these innovative principles and must not therefore? be taken to limit the scope of protection claimed here.

Claims (12)

Claims 1. Master alloy mixable with quantity? predetermined weights of a precious metal for the production of alloys of the precious metal and for the refining of the crystalline grain of the precious metal, comprising the following composition: - a quantity? weight of silver between 2% and 50% of the total weight of the master alloy; - a quantity? weight of zinc between 1% and 15% with respect to the total weight of the master alloy; - a quantity? weight of ruthenium as refining element of the crystalline grain between 0.05% and 0.14% with respect to the total weight of the master alloy; - a quantity? weight of germanium between 0.2% and 0.9% with respect to the total weight of the master alloy; in which the quantity? remaining weight of the parent alloy ? formed from copper. 2. Master alloy according to claim 1, characterized in that the quantity? ruthenium weight? between 0.07% and 0.14% with respect to the total weight of the master alloy. 3. Master alloy according to any one of the preceding claims, characterized in that the quantity? weight of germanium ? between 0.25% and 0.6% with respect to the total weight of the master alloy. 4. Master alloy according to any one of the preceding claims, characterized in that it comprises the following composition: - a quantity? weight of silver equal to 4% with respect to the total weight of the master alloy; - a quantity? weight of zinc equal to 3% with respect to the total weight of the master alloy; - a quantity? weight of ruthenium equal to 0.12% with respect to the total weight of the master alloy; - a quantity? weight of germanium equal to 0.48% with respect to the total weight of the master alloy; - a quantity? weight of copper equal to 92.4% with respect to the total weight of the master alloy. 5. Master alloy according to any one of claims 1-3, characterized in that it comprises the following composition: - a quantity? weight of silver equal to 47% with respect to the total weight of the master alloy; - a quantity? weight of zinc equal to 2% with respect to the total weight of the master alloy; - a quantity? weight of ruthenium equal to 0.08% with respect to the total weight of the master alloy; - a quantity? weight of germanium equal to 0.32% with respect to the total weight of the master alloy; - a quantity? weight of copper equal to 50.6% with respect to the total weight of the master alloy. 6. Master alloy according to any one of the preceding claims, characterized in that it is free of nickel and/or silicon. 7. Method of producing a master alloy intended to be used for making alloys of a precious metal and for refining the crystalline grain of the precious metal, comprising at least the following steps: i) preparation of a first molten starting alloy comprising a quantity weight of copper equal to 50% compared to the total weight of the first starting alloy, a quantity? weight of germanium equal to 40% compared to the total weight of the first starting alloy and a quantity? weight of ruthenium equal to 10% with respect to the total weight of the first starting alloy; ii) casting of the first starting alloy melted in a mold and cooling of the first starting alloy to obtain an article or a series of articles; iii) preparing a second molten starting alloy, said second starting alloy comprising a quantity predetermined weight of copper compared to the total weight of the second starting alloy, a quantity? predetermined weight of silver compared to the total weight of the second starting league and a quantity? predetermined weight of zinc with respect to the total weight of the second starting alloy; iv) addition of the article or articles made in said phase ii) to said second molten starting alloy to obtain the master alloy; v) stirring and mixing of the molten master alloy. 8. Method according to the preceding claim, characterized in that said step i) of preparation of said first starting alloy comprises the following sub-steps: vi) merger of said quantity? weight of germanium; vii) addition of said quantity? weight of ruthenium to said quantity? weight of molten germanium to make a mixture; viii) stirring the mixture for a predetermined time interval; ix) addition of said quantity? weight of copper fused to said mixture to make said first starting alloy; x) agitation and mixing of said first starting alloy. 9. Method according to the preceding claim, characterized in that said predetermined time interval in said sub-phase viii) has a duration close to 15 minutes. 10. Method according to claim 7, characterized in that said quantity? predetermined weight of ruthenium ? added to molten germanium in powder form wrapped in copper-coated capsules. 11. 18kt gold alloy, comprising the following composition: - a quantity? weight of gold equal to 75% of the total weight of the gold alloy; - a quantity? weight of master alloy in accordance with any one of claims 1-6 equal to 25% with respect to the total weight of the gold alloy. 12. Gold alloy according to claim 11, characterized in that it has a crystalline grain smaller than 500?m and preferably comprised between 100?m and 200?m.