CH717070B9 - Quinaria gold alloy, resistant to tarnishing, with color compatible with the 5N standard. - Google Patents

Abstract

Tarnish resistant gold alloy for jewellery, comprising: – Gold in an amount in the range [815-846] ‰ by weight, – Copper in an amount in the range [120-154] ‰ by weight, – Silver in amount in the range [18-35] ‰ by weight, – Platinum in an amount in the range [1-10] ‰ by weight, – Palladium in an amount in the range [7-15] ‰ by weight, where the Lega d'Oro is a quinary alloy, and in which the gold alloy thus composed presents, under the conditions set out in the ISO DIS 8654:2017 standard, a color compatible with the color standard of 5N alloys.

Description

TECHNICAL FIELD

[0001] The present disclosure refers to the sector of gold alloys and in particular concerns a gold alloy, quinaria, with a color compatible with the 5N standard.

[0002] The present disclosure also concerns a method of producing gold alloys having a color compatible with the 5N standard.

The gold alloy and the gold alloy production method according to the disclosure are respectively an alloy and a gold alloy production method for jewelry and watchmaking applications.

BACKGROUND

[0004] Gold is not used in its pure form in the jewelery and watchmaking sector, as it is too ductile. For jewelery and watchmaking applications, gold alloys for jewelery or watchmaking are typically used, characterized by a greater hardness than pure gold and/or low hardness or high ductility gold alloys.

[0005] It is known that, in general, gold alloys can undergo undesired color alterations over time, following interactions with aggressive environments. These interactions lead to the formation of thin layers of reaction products which, remaining adherent to the surface of the alloy, cause an alteration of the color and brightness (document „Observations of onset of sulfide tarnish on gold-base alloys“; JPD, 1971 , Vol. 25, issue 6, pp. 629-637).

[0006] The environments capable of promoting color alterations of gold alloys are numerous and are linked to their applications.

[0007] The standard colors for gold alloys can be uniquely measured in the CIELAB 1976 color space, which defines a color on the basis of a first parameter L*, a second parameter a* and a third parameter b*, where the first parameter L* identifies the luminosity and assumes values between 0 (black) and 100 (white) while the second parameter a* and the third parameter b* represent chromaticity parameters. In particular, in the CIELAB 1976 color chart, the achromatic scale of grays is identified by the points where a*=b*=0; positive values for the second parameter a* indicate a color tending more towards red the higher the value of the second parameter is; negative values for the second parameter a* indicate a color tending more towards green the higher the value of the second parameter a* is in absolute value high, even if negative; positive values for the third parameter b* indicate a color tending more towards yellow the higher the value of the third parameter is; negative values for the third parameter b* indicate a color tending more towards blue the higher the value of the third parameter b* is in absolute value high, even if negative.

[0008] It is also possible to transform the second parameter a* and the third parameter b* into polar parameters defined as follows: The Cab* parameter is defined as "chroma"; the greater the value of the Cab* parameter, the greater the color saturation; the lower the value of the Cab* parameter, the lower the color saturation, which will tend towards the gray scale. As far as the Applicant is aware, alloys with a gold content higher than 750‰, which can be used as such as white or gray gold alloys and do not require rhodium plating surface treatments, arbitrarily have Cab*<8 values. The parameter hab∗ instead identifies the hue of the color.

[0009] In particular, the ISO DIS 8654: 2017 standard defines seven color designations with regard to gold alloys for jewellery. In particular, these alloys are defined according to the following table, in which the color is defined on a standard reference named between 0N and 6N. 0N Yellow-green 1N Dark yellow 2N Light yellow 3N Yellow 4N Pink 5N Red 6N Dark red

[0010] For the measurement of the color of an alloy, in particular, the ISO DIS 8654 standard states that the measuring apparatus for measuring the color of a gold alloy must comply with CIE publication No. 15. In particular , this measuring apparatus is a spectrophotometer with an integrating sphere, capable of measuring a reflection spectrum with a measurement geometry compatible with the designation di: 8° or 8°: di (specular component included). The apparatus is adjusted according to the following parameters: – specular component included – standard illuminant D65 at 6504 K – standard observer 2°The color measurement results from an average of 5 distinct sample measurements, with repositioning, ensuring a pivot between measurements and the other.

[0011] The following table is extracted from the ISO DIS 8654: 2017 standard which shows the nominal values L*, a*, b* in trichromatic coordinates for the 5N standard color alloys, including tolerances. 5N 87.7 8.32 18.58 89.4 9.74 19.55 8.62 16.97 85.9 6.96 17.55 7.89 20.19

[0012] Starting from the standard it is therefore possible to obtain, within the CIE L*a*b* color space, a plurality of areas each of which represents the color ranges within which it is possible to assert that an alloy has a color 0N...6N. This area relative to 5N is represented in figure 1.

[0013] The current accuracy with which it is possible to measure the component quantities of a Gold alloy, typically with an accuracy greater than 0.1 ppt (one part in 10,000) by weight, both before and after the alloy is melted (post-fusion analysis) allow to identify the color with great precision. The ISO DIS 8654: 2017 standard also proposes recommended chemical compositions for each of the 0N-6N alloys. In particular, for 5N colouring, the recommended chemical compositions are those shown in the following table: 5N 75.0 4.5-5.5 Remaining part

[0014] The Applicant has observed that the 5N Gold alloy has a substantial color instability, in particular when exposed to environments in which chlorides or sulphides are present.

[0015] Variations of the color of a gold alloy according to the color as defined on the CIE 1976 color chart and expressed by the coordinate E=f (L*, a*, b*), defined: - as first parameter in original conditions, at time t0=0; - as second parameter in original conditions, at time t0=0; - as third parameter in original conditions, at time t0=0; are defined by the following equation:

[0016] It has also been observed that the human eye of an expert technician in precious materials is capable of distinguishing variations in color ΔE (L*, a*, b*) >1.

[0017] The 5N gold alloy has a color which is highly appreciated in the jewelery sector, but its substantial color instability when exposed to chemically aggressive environments makes the jewelery items which use it particularly delicate and not very suitable for use intensive with sweating or in a marine environment.

[0018] From PCT/IB2019/052092 gold alloys, quaternary or quinary, comprising alternatively platinum or palladium are known. Also from PCT/IB2019/052092 an alloy is known, coded as alloy LRS 494, characterized by: – Au in an amount equal to 791‰ in weight, – Cu in an amount equal to 167‰ in weight, – Ag in an amount equal to 32 ‰ by weight, – Pd in an amount equal to 5‰ by weight, and – Pt in an amount equal to 5‰ by weight.

[0019] The Applicant observed at the time that the addition of Platinum in a Gold alloy, and in particular the replacement of certain parts of Palladium with Platinum, caused a tangible deterioration of the performance in terms of color variation ΔE (L* , a*, b*), in particular in Thioacetamide.

[0020] Document PCT/IB2019/052092 showed that, among the alloys with a gold content substantially equal to or less than 833‰ by weight, the alloy coded with LRS387, quaternary, comprising: Au, in an amount equal to 833‰ by weight , Cu in the amount of 129‰ by weight, Ag in the amount of 23‰ by weight and Pd in the amount equal to 15‰ by weight, had substantially the best performance in Thioacetamide and in air in terms of resistance to color change. The LRS387 alloy is Platinum free.

[0021] Document PCT/IB2019/052092 also discloses an alloy, coded with the reference LRS494, in which Platinum and Palladium are present, each in an amount equal to 5‰ by weight.

SUMMARY

[0022] An object of the present invention is to describe a gold-copper-silver-palladium-platinum quinary alloy, suitable to be used for jewelery applications and having high resistance to tarnishing.

[0023] The subject of the present invention is an alloy according to claim 1 and a jewelery item according to claim 1.

[0024] In order to solve the drawbacks described above, the Applicant has conceived a gold alloy and a jewelery object whose main characteristics are described hereinafter.

[0025] According to a feature of the present disclosure, he has devised a gold alloy for jewelry resistant to tarnishing, comprising: - Gold in an amount in the range [815-846] ‰ by weight, - Copper in an amount in the range [120-154] ‰ by weight, – Silver in an amount between [18-35] ‰ by weight, – Platinum in an amount between [1-10] ‰ by weight, – Palladium in an amount between range [7-15] ‰ by weight, where the Gold alloy is a quinary alloy.

[0026] According to a further characteristic, the gold alloy thus composed has, under the conditions set out in the ISO DIS 8654:2017 standard, a color compatible with the color standard of 5N alloys.

[0027] For the purposes of the present disclosure, a quinary alloy is understood to mean an alloy in which substantially only five elements are present, with the exclusion of unwanted impurities.

[0028] According to a further characteristic, the alloy according to the present disclosure consists of Gold, Copper, Silver, Platinum and Palladium in the following amounts: – Gold in an amount included in the range [815-846] ‰ by weight, – Copper in amount in the range [120-154] ‰ by weight, – Silver in an amount in the range [18-35] ‰ by weight, – Platinum in an amount in the range [1-10] ‰ by weight, – Palladium in an amount in the range [7-15] ‰ by weight.

[0029] According to a further characteristic, a gold alloy is also described, suitable for being used for jewelery applications and having a high resistance to tarnishing, which includes: – Gold in an amount in the range [815-846] ‰ in weight, – Copper in an amount in the range [120-154] ‰ in weight, – Silver in an amount in the range [18-35] ‰ in weight, – Platinum in an amount in the range [1-10] ‰ by weight, – Palladium in an amount in the range [7-15] ‰ by weight, – Iridium and/or Ruthenium and/or Rhenium in a total amount not exceeding 2‰ by weight, optionally not exceeding 1‰ by weight.

[0030] According to a further characteristic, the sum of the amounts by weight of Gold, Copper, Silver, Platinum and Palladium is equal to 1000‰.

[0031] According to a further feature, the gold alloy resistant to tarnishing for jewelery comprises: – Gold in an amount in the range [815-846] ‰ by weight, – Copper in an amount in the range [125-137 ] ‰ by weight, – Silver in an amount in the range [18-35] ‰ by weight, – Platinum in an amount in the range [1-10] ‰ by weight, – Palladium in an amount in the range [7- 15] ‰ by weight.

[0032] According to a further characteristic, the Gold alloy comprises Copper in an amount in the range [125-137] ‰ by weight.

[0033] According to a further feature, the Gold alloy comprises: – Gold in an amount in the range [815-840] ‰ by weight, – Copper in an amount in the range [125-137] ‰ by weight, – Silver in an amount between [18-35] ‰ by weight, – Platinum in an amount between [1-7] ‰ by weight, – Palladium in an amount between [7-15] ‰ by weight.

[0034] According to a further feature, the Gold alloy comprises: – Gold in an amount in the range [815-840] ‰ by weight, – Silver in an amount in the range [18-35] ‰ by weight, – Platinum in an amount in the range [1-7] ‰ by weight.

[0035] According to a further feature, the Gold alloy comprises: – Gold in an amount in the range [815-840] ‰ by weight, – Copper in an amount in the range [125-137] ‰ by weight, – Silver in an amount in the range [20-34] ‰ by weight, – Platinum in an amount in the range [1-7] ‰ by weight, – Palladium in an amount in the range [7-15] ‰ by weight.

[0036] According to a further characteristic, the Gold alloy comprises: – Silver in an amount in the range [18-35] ‰ by weight. According to a further feature, the gold alloy includes: – Silver in an amount in the range [20-34] ‰ by weight. According to a further characteristic, the Gold alloy includes: – Gold in an amount included in the range [815-840] ‰ by weight, – Copper in an amount included in the range [127-137] ‰ by weight, – Silver in amount in the range [20-34] ‰ by weight. According to a further characteristic, the Gold alloy includes: – Gold in an amount included in the range [827-839] ‰ by weight, – Copper in an amount included in the range [127-132] ‰ by weight. According to a further characteristic, the Gold alloy includes: – Gold in an amount included in the range [827-839] ‰ by weight, – Copper in an amount included in the range [127-132] ‰ by weight, – Silver in amount in the range [20-34] ‰ by weight, – Platinum in an amount in the range [1-7] ‰ by weight, – Palladium in an amount in the range [7-15] ‰ by weight.

[0037] According to a further feature, the Gold alloy comprises: – Gold in an amount in the range [830-836] ‰ by weight, – Copper in an amount in the range [127-132] ‰ by weight, – Silver in an amount in the range [20-34] ‰ by weight, – Platinum in an amount in the range [1-7] ‰ by weight, – Palladium in an amount in the range [7-15] ‰ by weight.

[0038] According to a further feature, the Gold alloy comprises: – Platinum in an amount in the range [1-6] ‰ by weight, and – Palladium in an amount in the range [8-13] ‰ by weight.

[0039] According to a further characteristic, the Gold alloy comprises: – Gold in an amount included in the range [815-840] ‰ by weight, – Copper in an amount included in the range [127-137] ‰ by weight, – Silver in an amount in the range [20-34] ‰ by weight, – Platinum in an amount in the range [1-6] ‰ by weight, – Palladium in an amount in the range [8-13] ‰ by weight.

[0040] According to a further characteristic, in the gold alloy, the weight ratio between Platinum and Palladium is between 1⁄2 and 1⁄4, preferably between 9/20 and 1⁄4, more preferably between 4/10 and 1⁄4.

[0041] According to a further feature, the gold alloy comprises: – Gold in an amount in the range [815-840] ‰ by weight, – Copper in an amount in the range [127-137] ‰ by weight, – Silver in an amount between [20-34] ‰ by weight, – Platinum in an amount between [1-5] ‰ by weight, – Palladium in an amount between [9-12] ‰ by weight.

[0042] According to a further characteristic, the Gold alloy comprises: – Gold in an amount included in the range [827-839] ‰ by weight, – Copper in an amount included in the range [127-132] ‰ by weight, – Silver in an amount between [20-34] ‰ by weight, – Platinum in an amount between [1-5] ‰ by weight, – Palladium in an amount between [9-12] ‰ by weight.

[0043] According to a further feature, the gold alloy comprises: – Gold in an amount in the range [830-836] ‰ by weight, – Copper in an amount in the range [127-132] ‰ by weight, – Silver in an amount between [20-34] ‰ by weight, – Platinum in an amount between [1-5] ‰ by weight, – Palladium in an amount between [9-12] ‰ by weight.

[0044] According to a further feature, the Gold alloy comprises: – Gold in an amount in the range [815-825] ‰ by weight, in combination with: – Copper in an amount in the range [129-137] ‰ by weight.

[0045] According to a further feature, the Gold alloy comprises: – Gold in an amount in the range [815-825] ‰ by weight, – Copper in an amount in the range [129-137] ‰ by weight, – Silver in an amount in the range [30-34] ‰ by weight, – Platinum in an amount in the range [2-5] ‰ by weight, – Palladium in an amount in the range [8-13] ‰ by weight.

[0046] According to a further characteristic, the Gold alloy comprises: – Silver in an amount in the range [30-34] ‰ by weight. According to a further characteristic, the Gold alloy includes: – Silver in an amount included in the range [31-33] ‰ by weight. According to a further characteristic, the Gold alloy includes: – Gold in an amount included in the range [815-825] ‰ by weight, – Copper in an amount included in the range [129-137] ‰ by weight, – Silver in amount in the range [31-33] ‰ by weight, – Platinum in an amount in the range [2-5] ‰ by weight, – Palladium in an amount in the range [8-13] ‰ by weight.

[0047] According to a further feature, the Gold alloy comprises: – Copper in an amount in the range [132-136] ‰ by weight, – Silver in an amount in the range [31-33] ‰ by weight, – Platinum in an amount between [3-4] ‰ by weight, – Palladium in an amount between [10-11] ‰ by weight.

[0048] According to a further feature, the Gold alloy comprises: – Gold in an amount in the range [815-825] ‰ by weight, – Copper in an amount in the range [132-136] ‰ by weight, – Silver in an amount in the range [31-33] ‰ by weight, – Platinum in an amount in the range [3-4] ‰ by weight, – Palladium in an amount in the range [10-11] ‰ by weight.

[0049] According to a further characteristic, the Gold alloy comprises: – Gold in an amount included in the range [832-834] ‰ by weight, – Silver in an amount included in the range [22-24] ‰ by weight, – Copper in an amount in the range [129-131] ‰ by weight, – Platinum in an amount in the range [2-4] ‰ by weight, – Palladium in an amount in the range [10-12] ‰ by weight.

[0050] According to a further characteristic, the Gold alloy comprises: – Gold in an amount included in the range [819-821] ‰ by weight, – Silver in an amount included in the range [31-33] ‰ by weight, – Copper in an amount in the range [133-135] ‰ by weight, – Platinum in an amount in the range [3-5] ‰ by weight, – Palladium in an amount in the range [9-11] ‰ by weight.

[0051] According to a further characteristic, the Gold alloy comprises: – Gold in an amount included in the range [819-821] ‰ by weight, – Silver in an amount included in the range [31-33] ‰ by weight, – Copper in an amount in the range [133-135] ‰ by weight, – Platinum in an amount in the range [2-4] ‰ by weight, – Palladium in an amount in the range [10-12] ‰ by weight.

[0052] According to a further characteristic, the gold alloy has an initial hardness, without work hardening, equal to at least 125 points according to the HV5 measurement method, optionally equal to at least 128 points according to the HV5 measurement method, and/or has an initial hardness, without work hardening, of a maximum of 141 points according to measuring method HV5, optionally a maximum of 139 points according to measuring method HV5.

[0053] According to a further characteristic, the gold alloy has a hardness, with work hardening at 75%, equal to at least 223 points according to the HV5 measurement method, optionally equal to at least 224 points according to the HV5 measurement method, and/or has a hardness, at 75% work hardening, of a maximum of 242 points according to measuring method HV5, optionally a maximum of 240 points according to measuring method HV5.

[0054] According to a further characteristic, the gold alloy has a hardness, with work hardening at 50%, equal to at least 194 points according to the HV5 measurement method, optionally equal to at least 197 points according to the HV5 measurement method, and/or has a hardness, at 50% work hardening, of a maximum of 218 points according to measuring method HV5, optionally a maximum of 215 points according to measuring method HV5.

[0055] According to a further characteristic, when subjected to an environment containing Thioacetamide, in particular in an environment containing Thioacetamide in accordance with the UNI EN ISO 4538:1998 standard, the alloy exhibits a color variation ΔE (L*, a*, b*) within the 24 h lower than 2.5, more preferably lower than 2.3 and even more preferably lower than 2.2.

[0056] According to a further characteristic, when immersed in an aqueous solution of 50g/litre of sodium chloride (NaCl) at 35°C for 24 hours, the gold alloy shows a color variation ΔE (L*, a*, b *) lower than 2, preferably lower than 1.9 and even more preferably lower than 1.8.

[0057] According to a further characteristic, said alloy is a homogeneous gold alloy, free of second phases, and in particular free of carbides and/or oxides.

[0058] According to the present disclosure, "free of secondary phases" or "free of second phases" means an alloy free of elements that can generate said second phases, in particular in a melting and subsequent solidification process without further thermal treatments; the second phases which are created in the liquid phase and remain downstream of the solidification of the alloy, are harmful second phases, for example carbides and/or oxides which during the polishing phase are visible to the naked eye on the surface of the polished piece, and which therefore prevent to obtain objects with a high surface quality, compatible with the needs required in the field of fine jewellery. Without prejudice to the possibility of subjecting the alloy to heat treatment processes, capable of imparting hardening, such that by precipitation thin precipitates, children of said heat treatment, may become present; in this case we are dealing with precipitates which prevent the movement of the dislocations by increasing the mechanical properties of the material, and counteract the onset of deformations in the objects made with the present alloys.

[0059] According to a further characteristic, said alloy is a gold alloy free from chemical elements likely to cause the generation of carbides and/or oxides.

[0060] According to a further characteristic, the Gold alloy is characterized by the absence of - or equivalently it is free of - all the metals belonging to the following list: Vanadium, Magnesium, Indium, Silicon, Tin, Titanium, Tungsten, Molybdenum , Niobium, Tantalum, Zirconium, Yttrium, Rhenium, Germanium.

[0061] According to a further characteristic, the gold alloy is a crystalline alloy, optionally 100% crystalline.

[0062] According to a further characteristic, said alloy is free of Nickel, Cobalt, Arsenic and Cadmium.

[0063] According to the present disclosure there is also described a method of producing a gold alloy resistant to tarnishing for jewellery, said method being characterized in that it comprises: a) a mixing and/or homogenization step in which all the elements pure constituents of the alloy, according to one or more of the present aspects, are melted in such a way as to obtain a homogeneous mixture; b) a step of introducing the mixture into a melting pot, and of a subsequent melting by heating until melted.

[0064] According to a further characteristic, the said melting is a continuous or discontinuous melting, comprising a casting phase in which the molten material is poured into a die made of graphite or a graphite flask and in which the said mixture is a mixture of materials with properties chemically unrelated to graphite surfaces.

[0065] According to a further characteristic, the said melting is a continuous melting, in which the molten material is poured into a spinneret made of graphite and in which the said mixture is a mixture of materials with anti-gripping properties on graphite surfaces , in particular at least free of Vanadium.

[0066] According to a further characteristic, following continuous or discontinuous casting, said alloy is subjected to a cooling step followed by one or more hot or cold plastic deformation steps and one or more heat treatments.

[0067] According to a further feature, during said melting, the melting crucible is subjected to a controlled gas atmosphere and in particular is subjected, at least temporarily, to a vacuum condition.

[0068] According to a further characteristic, in said continuous casting phase, said crucible is subjected to a controlled atmosphere, at a pressure equal to or lower than ambient pressure, and said gas is an inert gas, preferably argon, or a reducing agent, preferably forming gas.

[0069] According to a further characteristic, in said discontinuous casting phase, said crucible is subjected to a controlled atmosphere lower than 800mbar, preferably lower than 700mbar, and said gas is an inert gas, preferably argon.

[0070] The present disclosure also relates to an object of jewellery, comprising a gold alloy in accordance with one or more of the previous characteristics.

[0071] According to a further characteristic, said jewelery item comprises a jewel or a watch or a bracelet for a watch or a movement or part of a mechanical movement for a watch.

[0072] According to a further feature, said watch or mechanical watch movement are configured to be respectively worn or installed in wristwatches.

BRIEF DESCRIPTION OF THE DRAWINGS

[0073] The description of the present invention will be carried out in relation to some possible embodiments of the gold alloy in which: - figure 1 shows a table including compositions of specific embodiments of gold alloys in accordance with the present disclosure , expressed in thousandths by weight, – figure 2 shows a table including hardnesses of the alloys according to the HV5 measurement method; – figure 3 shows a table including some embodiments of gold alloys according to the present disclosure and shows the color coordinates of each of these embodiments and the color difference ΔE(L*,a*,b* ), ΔE(L*), ΔE(a*), ΔE(b*) compared to the standard color alloy 5N; figure 4 shows a table including some embodiments of gold alloys in accordance with the present disclosure and shows color variation data and also shows performance improvement factors of said embodiments; – figure 5 shows a graph representing the a* and b* color coordinates for some embodiments of gold alloys, and also shows the tolerance limits for the 5N color as intended by the ISO DIS 8564:2017 standard; Figure 6 shows a graph representing a combined improvement factor for some embodiments of alloys according to the present disclosure, in relation to the color difference that these embodiments possess at the instant t=0 with respect to the standard 5N alloy.

[0074] The invention is not limited to the embodiments illustrated in the accompanying figures. Therefore, it must be understood that where features or parts of the subject matter of the present disclosure are identified by signs, in particular numbers, of reference, such signs are included only for the purpose of increasing the intelligibility of the description and of the claims, and are not intended in any way as limiting.

DETAILED DESCRIPTION

[0075] The Applicant has conceived a family of alloys for jewelery whose Gold fineness is substantially between 19.55kt and 20.3kt; the alloys which form the object of the present disclosure are of the quinary type, and in particular essentially comprise Gold, Copper, Silver, Palladium and Platinum and are resistant to tarnishing.

[0076] Further alloys which are the object of this disclosure are alloys comprising essentially Gold, Copper, Silver, Palladium and Platinum, and in addition an amount of Iridium and/or Ruthenium and/or Rhenium not exceeding 2‰ by weight and more preferably not more than 1‰ by weight.

[0077] Gold alloys according to the present disclosure exhibit a color which is compatible with the color standard according to ISO DIS 8564:2017 for 5N alloys.

[0078] Surprisingly, the Applicant has realized that combinations of Palladium and Platinum, especially for gold titles substantially between 19.55 kt and 20.3 kt (therefore indicatively between 815 ‰ in weight and 846 ‰ in weight), in quinary alloys with Copper and Silver, in which Platinum does not exceed 10‰ in weight, and in particular 7‰ have a color compatible with the 5N standard in accordance with the ISO DIS 8654:2017 standard, and a significantly higher resistance to tarnishing than either that of the standard 5N alloy, and that of quinary Copper-Silver alloys with gold content essentially equal to 791 ‰ and containing Platinum and Palladium in amounts equal to 5‰ and 5‰, such as for example the LRS494 alloy mentioned in the document PCT/IB2019/052092.

[0079] A first series of tests performed by the Applicant concerns quinary gold alloys, with the following mixture: – Gold in an amount included in the range [815-846] ‰ by weight, – Copper in an amount included in the range [120 -154] ‰ by weight, – Silver in an amount in the range [18-35] ‰ by weight, – Platinum in an amount in the range [1-10] ‰ by weight, – Palladium in an amount in the range [ 7-15] ‰ by weight,

[0080] These tests, and furthermore the tests carried out on the sub-families of Gold alloys described below, were carried out both on pure quinary alloys, i.e. in which the amount by weight of Gold, Copper, Silver, Platinum and Palladium is equal to 1000‰, and non-quinary alloys comprising an amount not exceeding 2‰ and more preferably not exceeding 1‰ of Iridium and/or Ruthenium and/or Rhenium.

[0081] The gold alloys thus composed have, under the conditions set out in the ISO DIS 8654:2017 standard, a color compatible with the color standard of 5N alloys.

[0082] Most of the studies carried out by the Applicant have been focused on Gold alloys in which the ratio of the amounts by weight between Platinum and Palladium is substantially between 1⁄2 (0.5), in particular 9/20 and more preferably 4 /10, and 1⁄4 (0.25).

[0083] A further series of tests concerned Gold alloys in a narrower range of Copper contents; these quinarium alloys include the following mixture: – Gold in an amount in the range [815-846] ‰ by weight, – Copper in an amount in the range [125-137] ‰ by weight, – Silver in an amount in the range [18-35] ‰ by weight, – Platinum in an amount between [1-10] ‰ by weight, – Palladium in an amount between [7-15] ‰ by weight,

[0084] Subsequently, the Applicant studied a plurality of quinary gold alloys, in a narrower Gold range than the previous ones, and comprising: - Gold in an amount included in the range [815-840] %o by weight, - Copper in an amount between [125-137] %o by weight, – Silver in an amount between [18-35] %o by weight, – Platinum in an amount between [1-7] %o by weight, – Palladium in an amount in the range [7-15] %o by weight.

[0085] The Applicant therefore concentrated on analyzing the behavior of Gold alloys which, with respect to the previous ones, are enclosed in a more limited range of Silver amounts; these quinarium alloys include: – Gold in an amount included in the range [815-840] %o by weight, – Copper in an amount included in the range [125-137] %o by weight, – Silver in an amount included in the range [ 20-34] %o by weight, – Platinum in an amount between [1-7] %o by weight, – Palladium in an amount between [7-15] %o by weight.

[0086] Further studies by the Applicant focused on analyzing two main subfamilies of Gold alloys, aimed at directing the increasingly selective study towards alloys comprising either Gold in an amount equal to 820% or by weight or in an amount equal to 833% or by weight. A first subfamily is that in which Gold and Copper are present in the following ranges: Gold in an amount included in the range [827-839] %o by weight, and Copper in an amount included in the range [127-132] %o by weight .

[0087] Therefore this first sub-family of Gold alloys is a sub-family of quinary alloys comprising: – Gold in an amount in the range [827-839] %o by weight, – Copper in an amount in the range [127-132 ] %o by weight, – Silver in an amount within the range [20-34] %o by weight, – Platinum in an amount within the range [1-7] %o by weight, – Palladium in an amount within the range [7-15] %o by weight.

[0088] Of this first sub-family, a particular sector with more restricted Gold ranges was analysed, arriving at the study of quinary Gold alloys comprising: – Gold in an amount included in the range [830-836] %o in weight, – Copper in an amount between [127-132] %o by weight, – Silver in an amount between [20-34] %o by weight, – Platinum in an amount between [1-7 ] %o by weight, – Palladium in an amount in the range [7-15] ‰ by weight.

[0089] Subsequent studies were aimed at analyzing the behavior of quinary Gold alloys with more narrower Platinum and Palladium ranges than the previous ones, in particular quinary Gold alloys which include: Platinum in an amount included in the range [1-6 ] ‰ by weight, and palladium in an amount in the range [8-13] ‰ by weight. The Applicant has therefore proceeded to carry out further studies on the Gold alloys conceiving a family of quinary Gold alloys comprising: – Gold in an amount included in the range [815-840] ‰ by weight, – Copper in an amount included in the range [127-137] ‰ by weight, – Silver in an amount between [20-34] ‰ by weight, – Platinum in an amount between [1-6] ‰ by weight, – Palladium in an amount between range [8-13] ‰ by weight.

[0090] This family has been the subject of further studies and analyses, focusing on more restricted Platinum and Palladium values; a particular family of quinary Gold alloys was conceived comprising: – Gold in an amount in the range [815-840] ‰ by weight, – Copper in an amount in the range [127-137] ‰ by weight, – Silver in an amount in the range [20-34] ‰ by weight, – Platinum in an amount in the range [1-5] ‰ by weight, – Palladium in an amount in the range [9-12] ‰ by weight.

[0091] A particular family of quinary gold alloys belongs to the first sub-family previously mentioned, from which the specific example LRS 543 cited in table 1 below was then derived; this family of quinary Gold alloys includes: – Gold in an amount included in the range [827-839] ‰ by weight, – Copper in an amount included in the range [127-132] ‰ by weight, – Silver in an amount included in the range [20-34] ‰ by weight, – Platinum in an amount between [1-5] ‰ by weight, – Palladium in an amount between [9-12] ‰ by weight.

[0092] Subsequent studies have concentrated on analyzing the behavior of the alloys of the family described above with even more restricted ranges of Gold, thus conceiving a family of quinary Gold alloys comprising: – Gold in an amount included in the range [830 -836] ‰ by weight, – Copper in an amount in the range [127-132] ‰ by weight, – Silver in an amount in the range [20-34] ‰ by weight, – Platinum in an amount in the range [ 1-5] ‰ by weight, – Palladium in an amount in the range [9-12] ‰ by weight.

[0093] The second sub-family which then led to the conception of the specific embodiments LRS 544 and LRS545 is a family of gold alloys centered around the specific content of gold at 820 ‰ by weight, and is therefore a second sub-family of alloys of Gold quinaries comprising: Gold in an amount in the range [815-825] ‰ by weight, combined with Copper in an amount in the range [129-137] ‰ by weight.

[0094] The second subfamily of quinary gold alloys therefore includes: – Gold in an amount in the range [815-825] ‰ by weight, – Copper in an amount in the range [129-137] ‰ by weight, – Silver in an amount in the range [30-34] ‰ by weight, – Platinum in an amount in the range [2-5] ‰ by weight, – Palladium in an amount in the range [8-13] ‰ by weight.

[0095] More specifically, this second sub-family includes: – Gold in an amount included in the range [815-825] ‰ by weight, – Copper in an amount included in the range [129-137] ‰ by weight, – Silver in an amount included in the range [31-33] ‰ by weight, – Platinum in an amount in the range [2-5] ‰ by weight, – Palladium in an amount in the range [8-13] ‰ by weight.

[0096] Even more specifically, this second sub-family includes: – Gold in an amount included in the range [815-825] ‰ by weight, – Copper in an amount included in the range [132-136] ‰ by weight, – Silver in amount in the range [31-33] ‰ by weight, – Platinum in an amount in the range [3-4] ‰ by weight, – Palladium in an amount in the range [10-11] ‰ by weight.

[0097] Going back to the first sub-family of Gold alloys, the Applicant's studies have focused on the analysis of quinary Gold alloys with Gold in an amount included in a narrow range around 833 ‰ by weight, which include: – Gold in an amount in the range [832-834] ‰ by weight, – Silver in an amount in the range [22-24] ‰ by weight, – Copper in an amount in the range [129-131] ‰ by weight, – Platinum in an amount between [2-4] ‰ by weight, – Palladium in an amount between [10-12] ‰ by weight.

[0098] In particular, the LRS 543 alloy was derived from these studies, which is substantially a 20kt alloy (20kt would ideally correspond to the periodical 833.3 ‰ in weight of Gold).

[0099] The specific embodiments LRS544 and LRS 545 are part of a particular sub-family belonging to the said second sub-family of gold quinary alloys, comprising: – Gold in an amount included in the range [819-821] ‰ by weight, – Silver in an amount in the range [31-33] ‰ by weight, – Copper in an amount in the range [133-135] ‰ by weight, – Platinum in an amount in the range [3-5] ‰ by weight , – Palladium in an amount in the range [9-11] ‰ by weight.

[0100] In particular, this sub-family has led to a study aimed at the following alloys: – Gold in an amount in the range [819-821] ‰ in weight, – Silver in an amount in the range [31-33] ‰ in weight, – Copper in an amount in the range [133-135] ‰ in weight, – Platinum in an amount in the range [2-4] ‰ in weight, – Palladium in an amount in the range [10-12] ‰ by weight.

[0101] All the alloys described here, subjected to an environment containing Thioacetamide, in particular in an environment containing Thioacetamide in accordance with the UNI EN ISO 4538:1998 standard, show a color variation ΔE (L*, a*, b*) within 24 h lower than 2.5, more preferably lower than 2.3 and even more preferably lower than 2.2.

[0102] The families listed above include some specific embodiments of gold alloys conceived by the Applicant, which are listed in the following table 1.

[0103] The alloys identified with the "ref" code are not the subject of this disclosure, but are shown in the table for reference. ref 5N ref LRS 387 833 23 129 15 ref LRS 494 791 32 167 5 5 LRS 543 833 23 130 11 3 LRS 544 820 32 134 10 4 LRS 545 820 32 134 11 3

Table 1 - alloy compositions ‰ wt

[0104] It is noted that the specific embodiments LRS 543, LRS 544 and LRS 545 have a ratio of amount by weight between Platinum and Palladium substantially between 1⁄2, in particular 9/20 and more preferably 4/10, and 1 ⁄4.

[0105] Gold alloys according to the present disclosure have an initial hardness, without work hardening, equal to at least 125 points according to the HV5 measurement method, in particular equal to at least 128 points according to the HV5 measurement method. Gold alloys in accordance with the present disclosure have an initial hardness, without work hardening, of a maximum of 141 points in accordance with the HV5 measurement method, in particular of a maximum of 139 points in accordance with the HV5 measurement method.

[0106] The Applicant has carried out further tests with hardening at 50% and 75% obtaining the following results.

[0107] With work hardening at 50%, the gold alloys according to the present disclosure have a hardness equal to at least 194 points according to the HV5 measurement method, in particular equal to at least 197 points according to the HV5 measurement method; these alloys, with 50% work hardening, have a hardness of a maximum of 218 points in accordance with the HV5 measurement method, in particular a maximum of 215 points in accordance with the HV5 measurement method.

[0108] With work hardening at 75%, the gold alloys according to the present disclosure have a hardness equal to at least 223 points according to the HV5 measurement method, in particular equal to at least 224 points according to the HV5 measurement method; these alloys, with 75% work hardening, have a hardness of a maximum of 242 points in accordance with the HV5 measurement method, in particular a maximum of 240 points in accordance with the HV5 measurement method.

[0109] Table 2 below shows hardness test results according to the HV5 measurement method for some specific embodiments of the gold alloys which are the object of the present disclosure. The alloys identified with the "ref" code are not the subject of this disclosure, but are shown in the table for reference. ref 5N 155 225 257 ref LRS 387 143 200 259 ref LRS 494 146 225 258 LRS 543 137 198 230 LRS 544 130 210 226 LRS 545 133 210 237

Table 2 - alloy hardness according to the HV5 measurement method

[0110] It is observed that the alloys according to the present disclosure have a hardness substantially compatible with that of the standard 5N alloy, in particular being slightly less hard. Gold alloys with hardnesses in the ranges mentioned above, and in particular with the hardnesses indicated in table 2, are particularly suitable for watchmaking or fine jewelery applications.

[0111] Table 3 illustrates some embodiments of gold alloys according to the present disclosure and shows the color coordinates of each such embodiment and the color difference ΔE(L*,a*,b*) (briefly indicated in the table as ΔE), ΔE(L*) relative to brightness only (briefly indicated in the table as ΔL*), and ΔE(a*), ΔE(b*) (briefly indicated in the table as Δa* and Δb*) , relative to the a* and b* chromaticity coordinates, with respect to the standard color alloy 5N. The alloys identified with the "ref" code are not the subject of this disclosure, but are shown in the table for reference. ref 5N 87.20 8.60 17.90 ref LRS 387 86.00 7.94 17.24 1.52 1.20 0.66 0.66 ref LRS 494 86.23 8.23 17.14 1.29 0.97 0.37 0.76 LRS 543 86.30 8.09 17.48 1.12 0.90 0.51 0.42 LRS 544 86.98 7.87 17.73 0.78 0.22 0 .73 0.17 LRS 545 86.02 7.74 17.66 1.48 1.18 0.86 0.24

Table 3 - color variations compared to the 5N reference alloy (t = 0)

[0112] Although all alloys according to the present disclosure are compatible with the color standard for 5N alloys according to ISO DIS 8564:2017, it can be seen from the present table that the specific embodiments LRS543, LRS 544 and LRS 545 , which are equal to 833‰ by weight in Gold, have a color that is closer to the color ideally proposed by the standard for the standard 5N alloy than what happens for the prior art LRS 387 alloy, again with Gold in amount equal to 833‰ by weight: for this alloy in fact the color difference ΔE(L*,a*,b*) compared to the standard 5N alloy is equal to 1.52, while the LRS543, LRS 544 and LRS 545 alloys have smaller differences, in the range [0.78 - 1.48]. The Applicant has therefore managed to conceive a plurality of embodiments of alloys which with Gold in an amount equal to 833% by weight, with Copper, Silver, Platinum and Palladium, have resistance to tarnishing and have a color more similar to the standard 5N alloy with respect to the color assumed by the LRS 387 alloy of the prior art.

[0113] Table 4 shows, in the first column, the color variations ΔE(L*,a*,b*) in Thioacetamide in accordance with the UNI EN ISO 4538:1998 standard for some specific embodiments of gold alloys. In the third column, this table illustrates color changes ΔE(L*,a*,b*) in NaCl solution as previously described.

[0114] The first three lines of the table illustrate Gold alloy embodiments which are not part of the present disclosure. The column that in the previous tables bore the wording "ref" for the embodiments not forming part of the present disclosure, has been omitted for the sake of compactness of the table.

[0115] The table also illustrates improvement factors which are described below.

[0116] For the purposes of this disclosure, improvement factor FM* (TIO) means the ratio between the color change ΔE(L*,a*,b*) in Thioacetamide according to the reference standard for the 5N alloy and the color variation ΔE(L*,a*,b*) in Thioacetamide according to the reference standard for the alloy under examination (all), at a given instant of time with respect to time zero (t = 0). In equations:

[0117]

[0118] According to the present disclosure, the improvement factor FM* (NaCl) means the ratio between the color change ΔE(L*,a*,b*) in Sodium Chloride according to the reference standard for the alloy 5N and the color variation ΔE(L*,a*,b*) in sodium chloride according to the reference standard for the alloy under examination (all), at a given instant of time (t) with respect to time zero (t = 0). In equations:

[0119] In particular, the tests relating to resistance in an environment containing chlorides are carried out by immersing the gold alloy in a 50g/litre aqueous solution of sodium chloride (NaCl) at 35°C for a predetermined time, for example 24h or 200h .

[0120] For the purpose of the present disclosure, the combined improvement factor FMC* means the product of the improvement factor FM*(NaCl) with the improvement factor FM*(TIO).

[0121] The percentage improvements expressed in table 5 are calculated according to the following equation: i.e. by subtracting the color variation ΔE(L*,a*,b*) undergone by the standard 5N alloy in Thioacetamide (TIO) or in chloride of sodium (NaCI) according to the reference standard in 24h and the color change ΔE(L*,a*,b*) undergone by the alloy under examination (all) in Thioacetamide (TIO) or in sodium chloride (NaCI) according to the reference standard in 24h, dividing the result by the color change ΔE(L*,a*,b*) undergone by the standard 5N alloy in Thioacetamide (TIO) or in Sodium Chloride (NaCl) according to the reference standard in 24h and multiplying the result obtained by 100. 5N 3.62 2.48 3.21 LRS 387 2.27 1.59 1.53 2.45 1.62 1.31 2.58 37.3 57.7 LRS 494 2.84 1.27 2.39 1.04 na 1.32 21.5 34.0 LRS 543 1.48 2.44 1.60 2.26 1.55 1.42 3.79 59.0 55 ,9 LRS 544 2.19 1.65 1.75 2.27 1.41 1.41 2.34 39.6 51.6 LRS 545 1.82 1.99 1.69 2.38 1.47 1, 35 2.91 49.7 53.3

Table 4 - improvement factors

[0122] The alloys according to the present disclosure, in particular the embodiments belonging to the following family [Gold in an amount included in the range [815-840] ‰ by weight, Copper in an amount included in the range [125-137 ] ‰ by weight, Silver in an amount in the range [20-34] ‰ by weight, Platinum in an amount in the range [1-7] ‰ by weight, Palladium in an amount in the range [7-15] ‰ by weight] and in more detail, the specific embodiments coded with LRS 543, LRS 544 and LRS 545 show, when immersed in 50g/litre aqueous solution of sodium chloride (NaCl) at 35°C for 24 hours, a color variation ΔE (L*, a*, b*) lower than 2, preferably lower than 1.9 and even more preferably lower than 1.8.

[0123] In the light of the above, it is observed that the alloys in accordance with the present disclosure, and in particular the specific embodiments of the Gold alloy coded with LRS 543, LRS 544, LRS 545 show a better behavior than the alloy LRS 387 with an equal amount of Gold (833‰ in weight): with respect to this alloy it can therefore be observed that the effect of Platinum in a specific amount between 1‰ and 10‰ and, in particular, in a specific percentage relationship with Palladium in which the amount of Platinum is substantially between 1⁄2, in particular 9/20 and more preferably 4/10 and 1/4 of the amount of Palladium, surprisingly improves the performance of the alloy, in particular in Thioacetamide both with respect to alloys without Platinum and with respect to the reference alloy LRS494 with Platinum and Palladium, where the ratio between Platinum and Palladium is substantially equal to 1 or, equivalently, when Platinum and Palladium are present in the alloy in substantially equal amounts. In percentage ratio, and in Thioacetamide, the alloys object of the present disclosure show a behavior that improves their performance between about 2% and over 20% compared to the LRS 387 alloy with the same amount of Gold (833‰ by weight).

[0124] The Applicant has observed in particular that the alloys in the immediate vicinity of LRS 543, therefore the quinary Gold alloys with Gold in an amount included in the range [832-834] ‰ by weight, Silver in an amount included in the range [22-24] ‰ by weight, Copper in an amount in the range [129-131] ‰ by weight, Platinum in an amount in the range [2-4] ‰ by weight, Palladium in an amount in the range [10 -12] ‰ by weight show a surprisingly optimal behavior in Thioacetamide compared not only to the known Gold alloys, but also compared to the best Gold alloys which are in any case the object of this disclosure: in fact, among the specific embodiments mentioned in the present disclosure, alloy LRS 545 is the one with the best improvement factor in Thioacetamide just before LRS 543 and in spite of everything the performances between these two alloys differ by about 9.5% in favor of LRS 543. The Applicant has realized therefore that passing from the title of Gold 820 ‰ in weight to 833 ‰ in weight, with the same content of Platinum and Palladium, and mainly altering the amount of Silver causes a significant improvement in the behavior in Thioacetamide, which is not so evident instead in Chloride of Sodium (where the difference in optimization of resistance to tarnishing is only about 2.6% in favor of LRS 543 compared to LRS 545).

[0125] It is also noted that the alloys in accordance with the present disclosure, and in particular the specific embodiments of the gold alloy coded with LRS 543, LRS544, LRS 545 show a significant improved behavior compared to the standard 5N alloy also in chloride of Sodium, and their improvement factor is substantially between 1.40 and 1.55 at 24h of exposure, which translates into an average percentage improvement of about 50% compared to the standard 5N alloy.

[0126] The actual goodness of the alloys according to the present disclosure in terms of generic resistance to tarnishing both in Thioacetamide and in Sodium Chloride solution can be observed from the overall improvement factor FMC at 24h, which shows that the specific embodiments around the LRS543 they have an overall improvement factor higher than 3 compared to the 5N alloy, in particular equal to 3.79.

[0127] All alloys according to the disclosure are free of materials capable of generating carbides and/or oxides, and in particular free of Vanadium. This allows the alloys in question to maintain particular quality when worked. In particular, the alloys in accordance with the disclosure are free of Magnesium, Indium, Silicon, Tin, Titanium, Tungsten, Molybdenum, Niobium, Tantalum, Zirconium, Yttrium, Rhenium, Germanium. In particular, it has been observed that silicon greatly dulls the color of the resulting alloy, so that even minimal additions of silicon in an alloy according to the formulations described here would make the resulting alloy have a color that is not compatible with the color tolerances of 5N alloys. , in particular according to the ISO DIS 8654: 2017 standard. Furthermore, silicon causes the formation of inclusions, often of considerable size, which are inconvenient when creating alloys for high quality jewelery objects, such as those described here.

[0128] The Applicant has also found that the silicon-containing alloys show deterioration in terms of resistance to tarnishing, and the phenomenon is easily observable already with very low silicon contents, in the order of a few thousandths.

[0129] All alloys according to this disclosure are also expressly free of Nickel, Cobalt, Arsenic and Cadmium. This makes them suitable to be used also to make jewels or parts of jewels in contact with the skin.

[0130] All alloys according to the present disclosure are iron-free alloys; this makes it possible to optimize the behavior of the alloy in solutions containing NaCl, since iron deteriorates its behaviour, worsening the resistance to tarnishing per unit of time in NaCl solutions when the constituent elements of the alloy and their percentages are those covered by this disclosure.

[0131] Subject to the exclusion of unwanted impurities, the alloys according to the disclosure may include further metals in an overall amount, i.e. in sum, not exceeding 2‰ and more preferably not exceeding 1‰; the list of said additional materials includes Iridium, Ruthenium and Rhenium. Under certain conditions, which will be better explained below, these materials can exhibit grain-refining properties. Finally, this list also includes zinc, as an element capable of reducing the content of oxygen dissolved in the alloy during the fusion process.

[0132] In particular, Iridium is preferably used in alloys containing high Copper contents, since it has a wide range of miscibility with the latter element; preferably, but not limited to, if present, iridium is present in an amount equal to or less than 0.3‰ by weight.

[0133] The use of Ruthenium and Rhenium is rarer, in amounts up to 0.1 ‰ in weight. Ruthenium and Rhenium are preferably used in white or gray gold alloys which contain high levels of palladium.

[0134] However, it is noted that the use of Iridium, Rhenium and/or Ruthenium is subject to the inclusion of these elements in pre-alloys. It has in fact been observed that these elements, if not pre-alloyed with the material similar to them, but directly introduced into the crucible, do not bind, thus contributing to a worsening of the characteristics of the alloy. Otherwise, only if used in a pre-alloy with Copper (Iridium) or Palladium (Rhenium and Ruthenium), taking care to bind the pre-alloy with the rest of the elements making up the alloy itself, does it have grain refinement properties.

[0135] The alloys according to the present disclosure are homogeneous Gold alloys, free of second phases, and in particular free of carbides and/or oxides, and/or are crystalline alloys, in particular 100% crystalline. This allows for high strength and surface quality and uniformity. By „free from secondary phases“ or „free from second phases“ we mean an alloy free from elements capable of causing their onset, in particular in a melting and subsequent solidification process without further heat treatments; the second phases which are created in the liquid phase and remain downstream of the solidification of the alloy, are harmful second phases, for example carbides and/or oxides which during the polishing phase are visible to the naked eye on the surface of the polished piece, and which therefore prevent to obtain objects with a high surface quality, compatible with the needs required in the field of fine jewellery/watchmaking.

Production process

[0136] The subject of the present disclosure is also a process for the production of a gold alloy whose mixture is in accordance with the present description.

[0137] The gold alloys which are the subject of the disclosure are made starting from pure elements, in particular from 99.99% Gold, 99.99% Cu, 99.95% Pd, 99.99% Fe, 99.99% Ag, Pt at 99.95%.

[0138] The smelting process of the pure elements for creating the Gold alloys according to the disclosure can be in detail a batch gold smelting process or a continuous gold smelting process. The discontinuous melting process of Gold is a process in which the mixture is melted and poured into a shape or ingot mold, made of graphite. In this case the above elements are melted and cast in a controlled atmosphere. More particularly, the melting operations are carried out only after having preferably carried out at least 3 conditioning cycles of the atmosphere of the melting chamber. This conditioning first of all provides for the achievement of a vacuum level up to pressures lower than 1×10<-2>mbar and a subsequent partial saturation with Argon at 500mbar. During melting, the pressure of the Argon is maintained at pressure levels between 500mbar and 800mbar. When the complete fusion of the pure elements has been reached, a phase of overheating of the mixture takes place, in which the mixture is heated up to a temperature of about 1250°C, and in any case to a temperature above 1200°C, in order to to homogenize the chemical composition of the metal bath. During the superheating phase, the pressure value in the melting chamber again reaches a vacuum level below 1×10<-2>mbar.

[0139] At this point, in a casting phase, the molten material is poured into a mold or ingot mould, and the melting chamber is re-pressurized with an inert gas, preferably argon, injected at a pressure lower than 800mbar and in particular lower than 700mbar.

[0140] Once solidification has taken place, the bars or spindles are extracted from the flask. After solidification of the alloy, gold alloy bars or spindles are obtained which are subjected to rapid cooling by means of a phase of immersion in water, in order to reduce and possibly avoid phase transformations in the solid state. In other words, the bars or spindles are subjected to a rapid cooling step, preferably but not limited to in water, in order to avoid phase variations in the solid state.

[0141] The continuous smelting process is a process in which the solidification and extraction of solidified Gold is performed continuously from a free end of a Gold rod or spindle. In particular, a graphite die is used in the continuous casting process. The use of graphite spinnerets is known, since graphite is a solid lubricant, and typically has low friction between its surfaces and those of the solidified metal, typically allowing to obtain an easy extraction of the element contained therein without fractures and with the minimum amount of defects present on its surface.

[0142] In the mixing step described above, the pure basic elements are mixed in such a way as to obtain a homogeneous mixture, i.e. free of portions or areas marked, in particular significantly, by an excess of one element compared to others .

[0143] When the inclusion of elements such as Iridium, Ruthenium and Rhenium is present for grain refinement, the production process comprises a step of producing a pre-alloy, wherein said pre-alloy comprises: a) Iridium pre -bonded to Copper in the amounts already indicated, or alternatively b) Rhenium or Ruthenium pre-alloyed to Palladium in the amounts already indicated.

[0144] Subsequently, the bars or spindles obtained by discontinuous or continuous casting are subjected to a hot or cold plastic deformation phase, preferably but not limited to by flat rolling.

[0145] During flat rolling and more generally during the cold plastic working phases, the different compositions melted according to the procedure previously described are deformed by more than 60% and then subjected to a recrystallisation heat treatment at a temperature higher than 650° C, to then be subsequently cooled.

[0146] In the production process of the gold alloy described here, it is in any case possible to subject the alloy to heat treatment processes, suitable for giving it a hardening, such that by precipitation thin precipitates can become present, resulting from said heat treatment ; in this case we are dealing with precipitates which prevent the movement of the dislocations by increasing the mechanical properties of the material, and counteract the onset of deformations in the objects made with the present alloys.

[0147] Finally, the subject of the disclosure is a jewelery item comprising a gold alloy according to the characteristics previously described. Although this piece of jewelery can take on the most varied shapes and characteristics, in particular it includes a piece of jewellery, for example and not limited to a bracelet, also with bezels, a necklace, earrings, rings, or a watch or a watch bracelet or a movement or part of mechanical movement for watch. In particular, said watch or mechanical watch movement are configured to be respectively worn or installed in wristwatches. With the use of the gold alloys object of the disclosure, these jewelery objects have a colour, defined as "red" according to the 5N standard, which is sufficiently stable even for use in particularly aggressive conditions, such as for example in contact with the skin in case of heavy sweating or in a marine environment (the latter being an environment where typically wedding rings and/or diving watches with portions such as a bracelet or case in Gold are typically worn by the user anyway); these jewels, in this way, are also characterized by the absence of components likely to cause allergies, and are furthermore endowed with sufficient hardness.

[0148] Finally, it is clear that modifications, additions or variations, obvious to a person skilled in the art, can be applied to the object of the present disclosure, without thereby departing from the scope of protection provided by the appended claims.

Claims (11)

1. Tarnish resistant gold alloy for jewellery, including: – Gold in an amount in the range [815-846] ‰ by weight, – Copper in an amount in the range [120-154] ‰ by weight, – Silver in an amount in the range [18-35] ‰ by weight, – Platinum in an amount in the range [1-10] ‰ by weight, – Palladium in an amount in the range [7-15] ‰ by weight, in which the gold alloy is a quinary alloy, and in which the gold alloy thus composed presents, under the conditions set out in the ISO DIS 8654:2017 standard, a color compatible with the color standard of 5N alloys. 2. Gold alloy according to claim 1, comprising: – Copper in an amount in the range [125-137] ‰ by weight. 3. Gold alloy according to any one of the preceding claims, comprising: – Gold in an amount in the range [815-840] ‰ by weight, – Silver in an amount in the range [18-35] ‰ by weight, – Platinum in an amount in the range [1-7] ‰ by weight. 4. Gold alloy according to claim 3, comprising: – Silver in an amount in the range [20-34] ‰ by weight. 5. Gold alloy according to claim 4, comprising: – Gold in an amount in the range [827-839] ‰ by weight, – Copper in an amount in the range [127-132] ‰ by weight. 6. Gold alloy according to one of the preceding claims, wherein the weight ratio between Platinum and Palladium is between 1⁄2 and 1⁄4, preferably between 9/20 and 1⁄4, more preferably between 4/10 and 1⁄4. 7. Gold alloy according to one of claims 5 or 6, comprising: – Gold in an amount in the range [832-834] ‰ by weight, – Silver in an amount in the range [22-24] ‰ by weight, – Copper in an amount in the range [129-131] ‰ by weight, – Platinum in an amount in the range [2-4] ‰ by weight, – Palladium in an amount in the range [10-12] ‰ by weight. 8. Gold alloy according to claim 4, comprising: – Gold in an amount in the range [815-825] ‰ by weight, – Copper in an amount in the range [129-137] ‰ by weight, – Silver in an amount in the range [30-34] ‰ by weight, – Platinum in an amount in the range [2-5] ‰ by weight, – Palladium in an amount in the range [8-13] ‰ by weight. 9. Gold alloy according to claim 8, comprising: – Copper in an amount in the range [132-136] ‰ by weight, – Silver in an amount in the range [31-33] ‰ by weight, – Platinum in an amount in the range [3-4] ‰ by weight, – Palladium in an amount in the range [10-11] ‰ by weight. 10. Gold alloy according to one of the preceding claims, characterized in that it is: – a homogeneous gold alloy, free of second phases, and in particular free of carbides and/or oxides, and/or a crystalline alloy, optionally 100% crystalline, and in which in an environment containing Thioacetamide in accordance with the UNI EN ISO 4538:1998 standard, the alloy presents a color variation ΔE (L*, a*, b*) within 24 hours lower than 2.5, more preferably lower than 2.3 and even more preferably less than 2.2; – when immersed in 50g/litre aqueous solution of sodium chloride (NaCl) at 35°C for 24 hours, the gold alloy shows a color variation ΔE (L*, a*, b*) lower than 2, preferably lower than 1.9 and even more preferably lower than 1.8. 11. Article of jewellery, comprising a gold alloy in accordance with one of the preceding claims.