IT201900006949A1 - Silver alloy and master alloy for the production of silver alloys - Google Patents

Description

Description of the industrial invention entitled "Silver alloy and master alloy for the production of silver alloys"

The present invention relates to a silver alloy and a master alloy suitable to be mixed with a weight quantity of silver for the production of silver alloys.

The use of silver has long been known in the goldsmith and jewelry sector, since of all the precious metals it is the one that has the closest color to white.

In addition, silver is widely used in the goldsmith sector due to the fact that it has a low cost compared to other precious metals, such as gold.

However, pure silver has the drawback of being a soft metal, with a Vickers hardness value of the order of 20-25 HV.

For this reason, silver-based metal alloys have been developed, including a preponderant weight quantity of silver and a reduced weight quantity of other metals other than silver. These alloys have the advantage of having a higher hardness than pure silver.

Generally, these alloys comprise a weight quantity of silver equal to 92.5% of the total weight of the alloy and a weight quantity of other metals equal to 7.5% of the total weight of the alloy.

With reference to the weight quantities indicated above, silver can also be defined as "solvent" in the metal alloy, while all other metals other than silver can be defined as "solute" in the metal alloy. Therefore the solvent is the component present in a preponderant quantity by weight in the alloy and the solute is the component present in a limited quantity by weight in the alloy.

This type of alloys are known as “sterling silver” and have a Vickers hardness of about 60-70 HV after casting and about 120-140 HV after heat-setting heat treatment.

The metals of the alloy other than silver can be initially mixed with each other and with the weight quantity of silver and subsequently can undergo a melting process in order to be workable for the creation of a jewel or necklace.

In particular, metals other than silver can be initially mixed together to form a master alloy which is in turn mixed with silver to form the final alloy.

Metals other than silver contribute to increasing the hardness of the metal alloy by distorting the solvent lattice, namely silver.

These metals can be chosen from within the group including copper, zinc, tin and indium. Among these materials the preferred is copper, since it has a good solubility in silver at high temperatures and allows to significantly increase the hardness of the alloy.

The other metals indicated above have the advantage of being soluble in silver even at room temperature. However, these metals allow to increase the hardness of the alloy only in a limited way and therefore are not very widespread in the goldsmith sector.

Furthermore, other metals such as palladium and platinum, which are by definition precious metals, can also be used to replace copper or in combination with it, so alloys made with these metals have the drawback of having very high costs. elevated.

From WO2017 / 021818 a silver alloy is known for use in the goldsmith and jewelery sector in which the weight quantity of silver is between 92.5% and 96.8% and in which the master alloy comprises a combination of one or more of the following metals: palladium, indium, zinc, germanium or silicon, tin or gallium.

The preferred embodiment described in this document does not provide for the addition of copper in the composition of the alloy; however, the document also discloses compositions which include copper.

A drawback of this solution consists in the fact that the hardness of this silver alloy, despite being comparable to that of sterling silver, i.e. close to 100-120 HV following heat treatment and 50-60 HV following heat treatment. fusion, remains limited for use in the goldsmith industry.

Another drawback of this solution is represented by the fact that the jewel or necklace obtained from the metal alloy having the above composition does not have adequate mechanical strength.

A further drawback is represented by the fact that the presence of some noble metals in the composition, such as palladium, determines a relatively high cost of the alloy.

An object of the present invention is to provide a silver alloy and a master alloy which allow the above mentioned drawbacks to be solved.

In particular, an object of the present invention is to make available a silver alloy that has a higher hardness than the hardness of the silver alloys of the known art.

Another purpose of the present invention is to make available a silver alloy that has a higher hardness than the known alloys of the known art both after melting and following hardening heat treatment.

A further purpose of the present invention is to provide a silver alloy particularly suitable for use in the goldsmith and jewelery sectors.

Another object of the present invention is to provide a silver alloy which allows to make jewels or jewels having an increased mechanical resistance.

The main purposes described above are achieved with a silver alloy according to claim 1 and with a master alloy according to claim 13.

The present invention relates to a silver alloy and a master alloy that can be mixed with a weight quantity of silver to make silver alloys.

The silver alloy can be melted and undergo thermosetting heat treatments and mechanical processing for the production of artifacts, such as jewelry and jewelry.

The melting and thermosetting heat treatment processes, as well as the mechanical processing of the alloy, are widely known in the sector and will not be described further below.

The preferred fields of application of the silver alloy of the present invention are those of goldsmithing and jewelry. However, it is not excluded that this alloy may also be used in other fields of application, without thereby departing from the scope of protection of the present invention.

Conveniently, the process of making the silver alloy provides for the mixing of a weight quantity of a solute, described in detail below, with a predetermined weight quantity of silver, which represents the solvent of the alloy. Subsequently, the solvent and the solute undergo a melting process to allow the machinability of the alloy. This process is known from the state of the art and allows the hardness of silver to be increased in order to make it suitable for the creation of products, which must have high mechanical strength.

Furthermore, as clearly explained below, the composition of the solute in the present invention allows to considerably increase the hardness of the silver alloy with respect to the alloys known in the sector.

In the goldsmith sector, the weight quantity of silver generally used in this type of alloys is equal to about 92.5% with respect to the total weight of the final alloy, and the weight quantity of solute is equal to about 7.5% with respect to to the total weight of the final alloy.

Also in the silver alloy of the present invention, the weight quantity of silver is equal to at least 92.5% and the weight quantity of solute is equal to at least 7.5%. In particular, the quantity of silver is equal to 93% with respect to the total weight of the final alloy and the quantity of solute is equal to 7% with respect to the total weight of the final alloy.

In accordance with the present invention, the solute of the silver alloy comprises antimony, suitable to act as a hardening element of the silver alloy.

Advantageously, antimony, in the weight quantities indicated above, has a solubility in silver at high temperatures similar to that of copper, which is generally used for hardening silver alloys. This behavior is confirmed by comparing the phase diagrams of a binary system containing antimony and silver with the phase diagrams of a binary system containing copper and silver.

Therefore, the composition of the present invention makes it possible to make the silver alloy while maintaining operating conditions similar to those used to make silver alloys containing copper, which are widely known in the sector.

Furthermore, the hardness of the silver alloy of the present invention measured after the melting process and following a heat hardening treatment is much greater than the hardness of silver alloys in which the hardening element is copper, with the same weight quantity. of antimony and copper. For this purpose, it is emphasized that the hardness of antimony is equal to 3 Mohs.

In particular, the hardness of the silver alloy of the present invention following melting is between 160-180 HV 0.5, while the hardness of the silver alloy of the present invention following heat-hardening heat treatment is between 280-320 HV. 0.5.

Below is a comparative table of the hardness values of the silver alloy of the present invention and the hardness values of the silver alloys known from the state of the art.

As can be seen from the table, the hardness values of the silver alloy of the present invention are more than doubled with respect to the hardness values of the silver alloys known from the state of the art.

For this purpose, it is noted that the hardness of the silver alloy was measured in accordance with ISO 6507 and ASTM E384 standards using a durometer with a load of 0.5kg.

In a first embodiment of the present invention, the solute is formed solely of antimony. Therefore, the weight quantity of antimony is equal to 100% of the total weight of the solute to be added to the silver in the silver alloy.

In an alternative embodiment of the invention, the solute is a master alloy which comprises:

- a weight quantity of antimony comprised between 27% -72% with respect to the total weight of the master alloy;

- a weight quantity of zinc comprised between 7% -9% with respect to the total weight of the master alloy;

- the remaining weight quantity of master alloy formed by copper.

Preferably, the weight quantity of antimony in the master alloy is between 27% -57% with respect to the total weight of the master alloy, and even more preferably it is equal to about 28% with respect to the total weight of the master alloy.

Advantageously, the weight quantity of solute, whether it is formed solely of antimony or whether it is a master alloy containing antimony, is always equal to at least 7%.

Furthermore, it is observed that as the weight quantity of antimony in the master alloy increases, the weight quantity of copper decreases, and vice versa. Furthermore, as described below, the master alloy can also comprise other elements, and therefore the weight quantity of copper also varies as a function of the weight quantity of the other elements.

The concomitant presence of antimony and copper in the master alloy makes it possible to justify the hardness values indicated above with greater clarity.

In fact, copper and antimony tend to form an intermetallic compound that precipitates and helps harden the master alloy. In addition, unalloyed antimony and copper also tend to precipitate, and contribute to further increasing hardness.

In other words, it can be said that in this embodiment the hardener element is formed by the combination of antimony with copper.

Furthermore, the master alloy can also comprise a mixture of auxiliary elements in a weight quantity ranging from 7% -9% with respect to the total weight of the master alloy.

This mixture can comprise cobalt in a weight amount ranging from 7% -8% with respect to the total weight of the master alloy and / or silicon in a weight amount ranging from 0.5% -1% with respect to the total weight of the master alloy. These metals are widely used in the goldsmith sector and allow you to regulate the operating conditions of alloy processing. Obviously, the silver alloy can also comprise impurities deriving for example from manufacturing processes. These impurities have a minor effect on the overall weight of the silver alloy and for this reason they will not be indicated in the silver alloy compositions reported below.

Some examples of different compositions of the silver alloy according to the present invention are reported below, both of the embodiment in which the solute is formed solely of antimony, and of the embodiment in which the solute is formed from the master alloy. In particular, example I is the one in which the solute is formed only of antimony, while examples II-IV are those in which the solute is formed by the master alloy.

It is observed that in the various silver alloys reported the weight quantities of silver and solute remain unchanged and are respectively 93% and 7% with respect to the total weight of the silver alloy.

Example I.

93% silver with respect to the total weight of the silver alloy (solvent);

7% antimony with respect to the total weight of the silver alloy (solute). Example II

93% silver with respect to the total weight of the silver alloy (solvent);

0.5% zinc with respect to the total weight of the silver alloy (solute); 0.5% cobalt with respect to the total weight of the silver alloy (solute); 2% of antimony with respect to the total weight of the silver alloy (solute); 0.07% silicon with respect to the total weight of the silver alloy (solute); 3.93% copper with respect to the total weight of the silver alloy (solute). Example III

93% silver with respect to the total weight of the silver alloy (solvent);

0.5% zinc with respect to the total weight of the silver alloy (solute); 0.5% cobalt with respect to the total weight of the silver alloy (solute); 4% of antimony with respect to the total weight of the silver alloy (solute); 0.07% silicon with respect to the total weight of the silver alloy (solute); 1.93% copper with respect to the total weight of the silver alloy (solute). Example IV

93% silver with respect to the total weight of the silver alloy (solvent);

0.5% zinc with respect to the total weight of the silver alloy (solute); 0.5% cobalt with respect to the total weight of the silver alloy (solute); 5% of antimony with respect to the total weight of the silver alloy (solute); 0.07% silicon with respect to the total weight of the silver alloy (solute); 0.93% copper with respect to the total weight of the silver alloy (solute). From the above it is now clear that the master alloy and the silver alloy of the present invention allow to advantageously achieve the intended purposes.

In particular, it is clear how the presence of antimony, in combination with the other metals, allows to increase the hardness of the silver alloy.

In particular, the presence of antimony allows to increase the hardness of the silver alloy both following the melting and following the thermosetting heat treatment.

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 silver alloy could also be different from those indicated in the examples, provided that there is always a weight quantity of antimony.

It is emphasized that the characteristics of the solutions shown can be used only partially according to specific needs.

Claims (14)

Claims 1. Silver alloy comprising a weight quantity of silver in solvent form equal to at least 92.5% with respect to the total weight of the silver alloy and a solute in a weight quantity equal to at least 7% with respect to the total weight of the silver alloy silver; characterized in that said solute comprises antimony. 2. Silver alloy according to claim 1, characterized in that said solute is formed solely of antimony. 3. Silver alloy according to claim 1, characterized in that said solute is a master alloy comprising antimony. 4. Silver alloy according to claim 3, characterized in that said master alloy comprises: - a weight quantity of antimony comprised between 27% -72% with respect to the total weight of the master alloy; - a weight quantity of zinc comprised between 7% -9% with respect to the total weight of the master alloy; in which the remaining weight of the master alloy is made up of copper. 5. Silver alloy according to claim 4, characterized in that the weight quantity of antimony of said master alloy is between 27% -57% with respect to the total weight of the master alloy. 6. Silver alloy according to claim 5, characterized in that the weight quantity of antimony is equal to about 28% with respect to the total weight of the master alloy. 7. Silver alloy according to claim 4, characterized in that it comprises a weight quantity of a mixture of auxiliary elements comprised between 7% -9% with respect to the total weight of the master alloy. 8. Silver alloy according to claim 7, characterized in that said mixture of auxiliary elements comprises cobalt in a weight amount ranging from 7% -8% with respect to the total weight of the master alloy and silicon in a weight amount ranging from 0.5% - 1% with respect to the total weight of the master alloy. 9. Silver alloy according to claim 1, characterized in that it has a hardness between 160-180 HV 0.5 following a casting process. 10. Silver alloy according to claim 9, characterized in that it has a hardness equal to 170 HV 0.5 following a melting process. 11. Silver alloy according to claim 1, characterized in that it has a hardness of between 280-320 HV 0.5 following a thermosetting heat treatment. 12. Silver alloy according to claim 11, characterized in that it has a hardness equal to 300 HV 0.5 following a thermosetting heat treatment. 13. Master alloy that can be mixed with a weight quantity of silver to make silver alloys, characterized in that it comprises a weight quantity of antimony. 14. Master alloy according to claim 13, characterized in that it has the following composition: - a weight quantity of antimony comprised between 27% -72% with respect to the total weight of the master alloy; - a weight quantity of zinc comprised between 7% -9% with respect to the total weight of the master alloy; in which the remaining weight of the master alloy is made up of copper.