Patent Grant
11970762
The present invention relates to gold alloys. In particular, the present invention relates to gold alloys which are alloyed with Zirconium, Titanium and Magnesium. More particularly, the present invention relates to gold alloys alloyed with at least two out of zirconium, Titanium and Magnesium or all three together for making low-weight jewelry of different caratages.
Gold is one of the most expensive but popular rare metal, predominantly used for manufacturing jewelry and watches etc. Normally, the conventional 22 and 23-carat Gold alloy has gold of fineness 916 (916 part out of total 1000) and 958 (958 ppt or 958 parts out of total 1000) respectively. The remaining 84 part in 22-carat Gold and 42 parts in 23-carat Gold (out of a total of 1000 parts) including Thailand 23-carat Gold consisting 96.15 to 96.55% by weight of Gold and includes several alloying elements, such as Zinc as well as Copper and Silver which are abundantly available in pure metal form. In India, Copper and Silver are the only alloying elements traditionally used for making conventional 22 and 23-carat Gold.
The compositions (by weight) of conventional Gold alloys of different caratage are indicated below:
Although, for commercial and industrial application, few common items are available in Indian market using the terms like Zirconium and Zirconia, they do not actually possess any Zirconium metal in its pure form, which is actually included here as the subject-matter of the present invention.
Normally, Zirconium jewelry is made of Zirconium or alloys thereof containing Zirconium as the main alloying constituent. While cubic Zirconia commonly known as CZ is a synthesized crystalline form of Zirconium Dioxide and is commercially used as a diamond simulant. Another form of zircon falls under the category of gemstones having a chemical formula as ZrSiO4 (Zirconium Silicate).
According to the article “The Au—Zr (Gold-Zirconium) Systems” written by Massalski, T. B., Okamoto, H. & Abriata and published in the J. P. Bulletin of Alloy Phase Diagrams (1985) [6: 519. doi: 10.1007/BF02887148], Zirconium has 7.25% of solubility in Gold. However, for the applications in jewelry manufacture, in which the cold workability in items is very important, in another article “18-carat yellow gold alloys with increased hardness” (page 7) written by Mintek, it is stated that more than 5% of Zirconium solubility in gold leads to cracking of items.
A solid solution strengthening phenomenon is observed in this alloy as seen in a solid-state, there is a different fraction of solubility of 1% of Zirconium in Gold from the temperature between 800-400-degree Celsius, according to the article “Micro-alloyed 24-carat Gold” (Page 7, Table 6) written by C. W Corti.
Since the Zirconium atom has a misfit factor 11.11 with the Gold atom, there is a substitutional strengthening (misfit factor of more than 15) effect on the alloys. Apart from jewelry manufacture, the Gold-Zirconium alloy is also found useful in:
Moreover, different articles discuss the micro-alloyed Gold, for example, the article written by C. W. Corti:
“MICROALLOYING_CORTI_JTF2005_ENG.pdf-132-147 CORTI_eng col (page 10-11 and References) and available online and another article written by Geoffrey Gafner: “The Development of 990 Gold-Titanium: It's Production, use and properties” (page 1&9).
However, none of the compositions disclosed in the prior art literature include combinations of at least two out of these three, Zirconium, Titanium and Magnesium metals or all three together as the constituents of the gold alloy.
The disadvantages with the prior art documents are that none of the documents found during this search have exhibited all the features of the applicant's NEW Gold alloy compositions having 18 to 24 carats, which they claim to have lower grammage with same volume as in the conventional high caratages and increased hardening value and to maintain ductility, colour, tensile strength and other properties of gold essential for jewelry making and easy for refining.
Some of the objects of the present invention—satisfied by at least one embodiment of the present invention—are as follows:
An object of the present invention is to provide a gold alloy with a combination of metals zirconium, Titanium and Magnesium or all three together for jewelry manufacture which has improved mechanical properties.
Another object of the present invention is to provide a gold alloy with at least two out of zirconium, Titanium and Magnesium or all three together for jewelry manufacture which has improved mechanical properties.
Still another object of the present invention is to provide a gold alloy with at least two out of zirconium, Titanium and Magnesium or all three together for jewelry manufacture which has lower weight for the same volume of the conventional alloy.
Yet another object of the present invention is to provide a gold alloy with at least two out of zirconium, Titanium and Magnesium or all three together for jewelry manufacture which retains rich yellow colour of the gold after alloying.
A further object of the present invention is to provide a gold alloy with at least two out of zirconium, Titanium and Magnesium or all three together for jewelry manufacture which has workable malleability and ductility during jewelry making.
A still further object of the present invention is to provide a gold alloy with at least two out of zirconium, Titanium and Magnesium or all three together for jewelry manufacture which has improved hardness.
A yet further object of the present invention is to provide a gold alloy with at least two out of zirconium, Titanium and Magnesium or all three together for jewelry manufacture which has age-hardening property.
One more object of the present invention is to provide a gold alloy with at least two out of zirconium, Titanium and Magnesium or all three together for jewelry manufacture which has better/improved springiness.
A still more object of the present invention a gold alloy with at least two out of zirconium, Titanium and Magnesium or all three together for jewelry manufacture which shows higher resistance to wear. A yet more object of the present invention a gold alloy with at least two out of zirconium, Titanium and Magnesium or all three together for jewelry manufacture which shows higher luster.
These and other objects and advantages of the present invention will become more apparent from the following description, when read with the accompanying data and tables which are however not intended to limit the scope of the present invention in any way.
In accordance with the present invention, there is provided a high purity gold alloy alloyed with a combination of metals zirconium, Titanium and Magnesium for jewelry manufacture, the gold alloy comprising:
Typically, the gold alloy is an 18-carat Gold alloy comprising:
Typically, the gold alloy is a 21-carat Gold alloy comprising:
Typically, the gold alloy is a 22-carat Gold alloy comprising:
Typically, the gold alloy is a 23-carat Gold alloy comprising:
Typically, the gold alloy is a 24-carat Gold alloy comprising:
Typically, the gold alloy has a specific gravity in the range of 14 to 19.5 g/cc; preferably 14.67 g/cc, 16.502 g/cc, 17.057 g/cc, 17.88 g/cc and 18.771 g/cc for 18, 21, 22, 23 and 24-carat gold alloy respectively.
Typically, the gold alloy comprises a hardness in the range of 75 to 260 Vickers HV-0.05 ASM F 384-11; preferably 240-260, 200-225, 170-195, 125-155 and 75-100 Vickers HV-0.05 ASM F 384-11 for 18, 21, 22, 23 and 24-carat gold alloy respectively.
Typically, the gold alloy has substantially higher springiness, luster and lower wear and has rich yellow color and compatible color retention properties compared with conventional Gold alloy.
In another embodiment of the present invention, the gold alloy is alloyed with at least two metals out of zirconium, Titanium and Magnesium for jewelry manufacture and comprises:
Typically, the gold alloy is a whitish yellow 18-carat Gold alloy comprising:
Typically, the gold alloy is a greenish yellow 18-carat Gold alloy comprising:
Typically, the gold alloy is a pale yellow 18-carat Gold alloy comprising:
Typically, the gold alloy has a specific gravity in the range of 14 to 15 g/cc; preferably 14.78 g/cc., 14.75-g/cc and 14.74 g/cc for Zr—Ti, Zr—Mg and Ti—Mg of the 18-carat gold alloy respectively. Typically, the gold alloy comprises a hardness in the range of 235 to 265 Vickers HV-0.05 ASM F 384-11, preferably 245-265, 235-255 and 245-255 Vickers HV-0.05 ASM F 384-11 for Zr—Ti, Zr—Mg and Ti—Mg of the 18-carat gold alloy respectively.
Typically, the gold alloy has substantially higher springiness, luster and lower wear and has compatible color retention properties compared with conventional Gold alloy.
In yet another embodiment of the present invention, the gold alloy is a whitish yellow 21-carat Gold alloy comprising:
Typically, the gold alloy is a greenish yellow 21-carat Gold alloy comprising:
Typically, the gold alloy is a pale yellow 21-carat Gold alloy comprising:
Typically, the gold alloy has a specific gravity in the range of 16 to 17 g/cc; preferably 16.69 g/cc, 16.55 g/cc, 16.51 g/cc for Zr—Ti, Zr—Mg and Ti—Mg of the 21-carat combinations respectively. Typically, the gold alloy comprises a hardness in the range of 200 to 230 Vickers HV-0.05 ASM F 384-11, preferably 205-230, 200-210 and 200-225 Vickers HV-0.05 ASM F 384-11 for Zr—Ti, Zr—Mg and Ti—Mg of the 21-carat gold alloy respectively.
Typically, the gold is a 21-carat alloy having substantially higher springiness, luster and lower wear and has compatible color retention properties compared with conventional Gold alloy.
In a further embodiment of the present invention, the gold alloy is a whitish yellow 22-carat Gold alloy comprising:
Typically, the gold alloy is a greenish yellow 22-carat Gold alloy comprising:
Typically, the gold alloy is a pale yellow 22-carat Gold alloy comprising:
Typically, the gold alloy has a specific gravity in the range of 17 to 18 g/cc; preferably 17.40 g/cc, 17.14 g/cc and 17.08 g/cc for Zr—Ti, Zr—Mg and Ti—Mg of the 22-carat gold alloy respectively.
Typically, the gold alloy comprises a hardness in the range of 170 to 205 Vickers HV-0.05 ASM F 384-11, preferably 175-190, 190-205 and 170-195 Vickers HV-0.05 ASM F 384-11 for Zr—Ti, Zr—Mg and Ti—Mg of the 22-carat gold alloy respectively.
Typically, the gold is a 22-carat alloy having substantially higher springiness, luster and lower wear and has compatible color retention properties compared with conventional Gold alloy.
In a still further embodiment of the present invention, the gold alloy is a whitish yellow 23-carat Gold alloy comprising:
Typically, the gold alloy is a greenish yellow 23-carat Gold alloy comprising:
Typically, the gold alloy is a pale yellow 23-carat Gold alloy comprising:
Typically, the gold alloy has a specific gravity in the range of 17.5 to 18.5 g/cc; preferably 18.27 g/cc, 17.97 g/cc, 17.92 g/cc for Zr—Ti, Zr—Mg and Ti—Mg of the 23-carat gold alloy respectively.
Typically, the gold alloy comprises a hardness in the range of 125 to 155 Vickers HV-0.05 ASM F 384-11, preferably 145-155, 125-135 and 135-150 Vickers HV-0.05 ASM F 384-11 for Zr—Ti, Zr—Mg and Ti—Mg of the 23-carat gold alloy respectively.
Typically, the gold is a 23-carat (having Indian standard of 95.58 to 96% by weight of gold and Thailand standard of 96.15 to 96.55% by weight of gold) gold alloy having substantially higher springiness, luster and lower wear and has compatible color retention properties compared with conventional Gold alloy.
In a yet further embodiment of the present invention, the gold alloy is a whitish yellow 24-carat Gold alloy comprising:
Typically, the gold alloy is a greenish yellow 24-carat Gold alloy comprising:
Typically, the gold alloy is a pale yellow 24-carat Gold alloy comprising:
Typically, the gold alloy has a specific gravity in the range of 18.5 to 19.5 g/cc; preferably 19.05 g/cc, 18.73 g/cc, 18.67 g/cc for Zr—Ti, Zr—Mg and Ti—Mg of the 24-carat gold alloy respectively.
Typically, the gold alloy comprises a hardness in the range of 75 to 105 Vickers HV-0.05 ASM F 384-11, preferably 75-105, 80-95 and 75-100 Vickers HV-0.05 ASM F 384-11 for Zr—Ti, Zr—Mg and Ti—Mg of the 24-carat gold alloy respectively.
Typically, the Gold alloy is a 24-carat Gold (includes Hong Kong/China based Chuk Kam jewelry with 99.0 to 99.5% by weight of Gold) alloy having substantially higher springiness, luster and lower wear and compatible color retention properties compared to conventional Gold alloy.
Experimental Verification:
The following are the results of the test conducted for different caratage of the gold alloy made in accordance with the present invention:
Specific Gravity:
It has been tested and observed that the specific gravity of the 18-carat Gold alloy made according to the present invention is significantly reduced. While the conventional 18-carat gold has a specific gravity of 15.442 gm/cc, 18-carat gold alloy made in accordance with the present invention with the above composition has demonstrated a specific gravity of 14.67 gm/cc, which is 4.99% less than the conventional 18-carat gold alloy. This is a substantial cost-effectiveness for this high value metal used for jewelry manufacture.
Color Retention:
18-carat Gold alloy with the above composition made according to the present invention is also compatible in terms of the color retention properties thereof, when compared with conventional 18-carat Gold alloys as observed under (CIE Defined) color spectrograph.
Size of test pieces 21 mm×21 mm×0.32 mm:
Enhanced Hardness:
Springiness—Test Conducted by Compression Tester:
Accordingly, from the above table, it is evident that the springiness witnessed in the gold alloy made in accordance with the present invention is substantially higher in comparison with the conventional 18-carat Gold alloy.
Higher Resistance to Wear:
Test Conducted with media polishing set up in which ceramic is used as media for 2 Hours:
Experimental Verification:
The following are the results of the test conducted for 18 caratage of the gold alloy made in accordance with the present invention:
Specific Gravity:
It has been tested and observed that the specific gravity of the 18-carat Gold alloy made according to the present invention is significantly reduced by the gold alloy made in accordance with the present invention. While the conventional 18-carat gold has a specific gravity of 15.442 gm/cc, 18-carat gold alloy made in accordance with the present invention with the above composition has demonstrated a specific gravity of 14.75 gm/cc, which is 4.49% lesser than the conventional 18-carat gold alloy. This is a substantial cost-effectiveness for this high value metal used for jewelry manufacture.
Color Retention:
18-carat Gold alloy with the above composition made according to the present invention is also compatible in terms of the color retention properties thereof, when compared with conventional 18-carat Gold alloys as observed under (CIE Defined) color spectrograph.
Size of test pieces 21 mm×21 mm×0.32 mm:
Enhanced Hardness:
Springiness—Test Conducted by Compression Tester:
Accordingly, from the above table, it is evident that the springiness witnessed in the gold alloy made in accordance with the present invention is substantially higher in comparison with the conventional 18-carat Gold alloy.
Higher Resistance to Wear:
Test Conducted with media polishing set up in which ceramic is used as media for 2 Hours:
Specific Gravity:
It has been tested and observed that the specific gravity of the 18-carat Gold alloy made according to the present invention is significantly reduced by the gold alloy made in accordance with the present invention. While the conventional 18-carat gold has a specific gravity of 15.442 gm/cc, 18-carat gold alloy made in accordance with the present invention with the above composition has demonstrated a specific gravity of 14.74 gm/cc, which is 4.54% lesser than the conventional 18-carat gold alloy. This is a substantial cost-effectiveness for this high value metal used for jewelry manufacture.
Color Retention:
18-carat Gold alloy with the above composition made according to the present invention is also compatible in terms of the color retention properties thereof when compared with conventional 18-carat Gold alloys as observed under (CIE Defined) color spectrograph.
Size of test pieces 21 mm×21 mm×0.32 mm:
Enhanced Hardness:
Springiness—Test Conducted by Compression Tester:
Accordingly, from the above table, it is evident that the springiness witnessed in the gold alloy made in accordance with the present invention is substantially higher in comparison with the conventional 18-carat Gold alloy.
Higher Resistance to Wear:
Test Conducted with media polishing set up in which ceramic is used as media for 2 Hours:
Specific Gravity:
It has been tested and observed that the specific gravity of the 18-carat Gold alloy made according to the present invention is significantly reduced by the gold alloy made in accordance with the present invention. While the conventional 18-carat gold has a specific gravity of 15.442 gm/cc, 18-carat gold alloy made in accordance with the present invention with the above composition has demonstrated a specific gravity of 14.78 gm/cc, which is 4.24% lesser than the conventional 18-carat gold alloy. This is a substantial cost-effectiveness for this high value metal used for jewelry manufacture.
Color Retention:
18-carat Gold alloy with the above composition made according to the present invention is also compatible in terms of the color retention properties thereof when compared with conventional 18-carat Gold alloys as observed under (CIE Defined) color spectrograph.
Size of test pieces 21 mm×21 mm×0.32 mm:
Enhanced Hardness:
Springiness—Test Conducted by Compression Tester:
Accordingly, from the above table, it is evident that the springiness witnessed in the gold alloy made in accordance with the present invention is substantially higher in comparison with the conventional 18-carat Gold alloy.
Higher Resistance to Wear:
Test Conducted with media polishing set up in which ceramic is used as media for 2 Hours:
Specific Gravity:
It has been tested and observed that the specific gravity of the 21-carat Gold alloy made according to the present invention is significantly reduced. While the conventional 21-carat gold has a specific gravity of 17.006 gm/cc, 21-carat gold alloy made in accordance with the present invention with the above composition has demonstrated a specific gravity of 16.502 gm/cc, which is 2.96% less than the conventional 21-carat gold alloy. This is a substantial cost-effectiveness for this high value metal used for jewelry manufacture.
Color Retention:
21-carat Gold alloy with the above composition made according to the present invention is also compatible in terms of the color retention properties thereof when compared with conventional 21-carat Gold alloys as observed under (CIE Defined) color spectrograph.
Size of test pieces 21 mm×21 mm×0.32 mm:
Enhanced Hardness:
Springiness—Test Conducted by Compression Tester:
Accordingly, from the above table, it is evident that the springiness witnessed in the gold alloy made in accordance with the present invention is substantially higher in comparison with the conventional 21-carat Gold alloy.
Higher Resistance to Wear:
Test Conducted with media polishing set up in which ceramic is used as media for 2 Hours:
Specific Gravity:
It has been tested and observed that the specific gravity of the 21-carat Gold alloy made according to the present invention is significantly reduced. While the conventional 21-carat gold has a specific gravity of 17.006 gm/cc, 21-carat gold alloy made in accordance with the present invention with the above composition has demonstrated a specific gravity of 16.69 gm/cc, which is 1.84% lesser than the conventional 21-carat gold alloy. This is a substantial cost-effectiveness for this high value metal used for jewelry manufacture.
Color Retention:
21-carat Gold alloy with the above composition made according to the present invention is also compatible in terms of the color retention properties thereof when compared with conventional 21-carat Gold alloys as observed under (CIE Defined) color spectrograph.
Size of test pieces 21 mm×21 mm×0.32 mm:
Enhanced Hardness:
Springiness—Test Conducted by Compression Tester:
Accordingly, from the above table, it is evident that the springiness witnessed in the gold alloy made in accordance with the present invention is substantially higher in comparison with the conventional 21-carat Gold alloy.
Higher Resistance to Wear:
Test Conducted with media polishing set up in which ceramic is used as media for 2 Hours:
Specific Gravity:
It has been tested and observed that the specific gravity of 21-carat Gold alloy made according to the present invention is significantly reduced. While conventional 21-carat gold has a specific gravity of 17.006 gm/cc, 21-carat gold alloy made in accordance with the present invention with the above composition has demonstrated a specific gravity of 16.55 gm/cc, which is 2.7% lesser than the conventional 21-carat gold alloy. This is a substantial cost-effectiveness for this high value metal used for jewelry manufacture.
Color Retention:
21-carat Gold alloy with the above composition made according to the present invention is also compatible in terms of the color retention properties thereof when compared with conventional 21-carat Gold alloys as observed under (CIE Defined) color spectrograph.
Size of test pieces 21 mm×21 mm×0.32 mm:
Enhanced Hardness:
Springiness—Test Conducted by Compression Tester:
Accordingly, from the above table, it is evident that the springiness witnessed in the gold alloy made in accordance with the present invention is substantially higher in comparison with the conventional 21-carat Gold alloy.
Higher Resistance to Wear:
Test Conducted with media polishing set up in which ceramic is used as media for 2 Hours:
Specific Gravity:
It has been tested and observed that the specific gravity of the 21-carat Gold alloy made according to the present invention is significantly reduced. While the conventional 21-carat gold has a specific gravity of 17.006 gm/cc, 21-carat gold alloy made in accordance with the present invention with the above composition has demonstrated a specific gravity of 16.51 gm/cc, which is 2.87% lesser than the conventional 21-carat gold alloy. This is a substantial cost-effectiveness for this high value metal used for jewelry manufacture.
Color Retention:
21-carat Gold alloy with the above composition made according to the present invention is also compatible in terms of the color retention properties thereof, when compared with conventional 21-carat Gold alloys as observed under (CIE Defined) color spectrograph.
Size of test pieces 21 mm×21 mm×0.32 mm:
Enhanced Hardness:
Springiness—Test Conducted by Compression Tester:
Accordingly, from the above table, it is evident that the springiness witnessed in the gold alloy made in accordance with the present invention is substantially higher in comparison with the conventional 21-carat Gold alloy.
Higher Resistance to Wear:
Test Conducted with media polishing set up in which ceramic is used as media for 2 Hours:
Specific Gravity:
It has been tested and observed that the specific gravity of the 22-carat Gold alloy made according to the present invention is significantly reduced by the above composition. the conventional 22-carat gold has a specific gravity of 17.696 gm/cc, 22-carat gold alloy made in accordance with the present invention has demonstrated a specific gravity of 17.057 gm/cc, which is 3.61% lesser than the conventional 22-carat gold alloy. This is a substantial cost-effectiveness for this high value metal used for jewelry manufacture.
Color Retention:
22-carat Gold alloy according to the present invention is also compatible in terms of the color retention properties thereof when compared with conventional 22-carat Gold alloys as observed under (CIE Defined) color spectrograph.
Size of test pieces 21 mm×21 mm×0.32 mm:
Enhanced Hardness:
Springiness—Test Conducted by Compression Tester:
Accordingly, from the above table, it is evident that the springiness witnessed in the gold alloy made in accordance with the present invention is substantially higher than the conventional 22-carat Gold alloy.
Higher Resistance to Wear:
Test Conducted with media polishing set up in which ceramic is used as media for 2 Hours:
Specific Gravity:
It has been tested and observed that the specific gravity of the 22-carat Gold alloy made according to the present invention is significantly reduced by the above composition. the conventional 22-carat gold has a specific gravity of 17.696 gm/cc, 22-carat gold alloy made in accordance with the present invention has demonstrated a specific gravity of 17.14 gm/cc, which is 3.16% lesser than the conventional 22-carat gold alloy. This is a substantial cost-effectiveness for this high value metal used for jewelry manufacture.
Color Retention:
22-carat Gold alloy according to the present invention is also compatible in terms of the color retention properties thereof when compared with conventional 22-carat Gold alloys as observed under (CIE Defined) color spectrograph.
Size of test pieces 21 mm×21 mm×0.32 mm:
Enhanced Hardness:
Springiness—Test Conducted by Compression Tester:
Accordingly, from the above table, it is evident that the springiness witnessed in the gold alloy made in accordance with the present invention is substantially higher than the conventional 22-carat Gold alloy.
Higher Resistance to Wear:
Test Conducted with media polishing set up in which ceramic is used as media for 2 Hours:
Specific Gravity:
It has been tested and observed that the specific gravity of the 22-carat Gold alloy made according to the present invention is significantly reduced by the above composition. the conventional 22-carat gold has a specific gravity of 17.696 gm/cc, 22-carat gold alloy made in accordance with the present invention has demonstrated a specific gravity of 17.08 gm/cc, which is 3.45% lesser than the conventional 22-carat gold alloy. This is a substantial cost-effectiveness for this high value metal used for jewelry manufacture.
Color Retention:
22-carat Gold alloy according to the present invention is also compatible in terms of the color retention properties thereof, when compared with conventional 22-carat Gold alloys as observed under (CIE Defined) color spectrograph.
Size of test pieces 21 mm×21 mm×0.32 mm:
Enhanced Hardness:
Springiness—Test Conducted by Compression Tester:
Accordingly, from the above table, it is evident that the springiness witnessed in the gold alloy made in accordance with the present invention is substantially higher than the conventional 22-carat Gold alloy.
Higher Resistance to Wear:
Test Conducted with media polishing set up in which ceramic is used as media for 2 Hours:
Specific Gravity:
It has been tested and observed that the specific gravity of the 22-carat Gold alloy made according to the present invention is significantly reduced by the above composition. the conventional 22-carat gold has a specific gravity of 17.696 gm/cc, 22-carat gold alloy made in accordance with the present invention has demonstrated a specific gravity of 17.40 gm/cc, which is 1.67% lesser than the conventional 22-carat gold alloy. This is a substantial cost-effectiveness for this high value metal used for jewelry manufacture.
Color Retention:
22-carat Gold alloy according to the present invention is also compatible in terms of the color retention properties thereof when compared with conventional 22-carat Gold alloys as observed under (CIE Defined) color spectrograph.
Size of test pieces 21 mm×21 mm×0.32 mm:
Enhanced Hardness:
Springiness—Test Conducted by Compression Tester:
Accordingly, from the above table, it is evident that the springiness witnessed in the gold alloy made in accordance with the present invention is substantially higher than the conventional 22-carat Gold alloy.
Higher Resistance to Wear:
Test Conducted with media polishing set up in which ceramic is used as media for 2 Hours:
Specific Gravity:
It has been tested and observed that the specific gravity of the 23-carat Gold alloy made according to the present invention is significantly reduced. While the conventional 23-carat gold has a specific gravity of 18.523 gm/cc, 23 carats gold alloy made in accordance with the present invention with the above composition has demonstrated a specific gravity of 17.88 gm/cc, which is 3.459% less than the conventional 23-carat gold alloy. This is a substantial cost-effectiveness for this high value metal used for jewelry manufacture.
Color Retention:
23-carat Gold alloy made according to the present invention is also compatible in terms of the color retention properties thereof, when compared with conventional 23-carat Gold alloys as observed under (CIE Defined) color spectrograph.
Size of test pieces 21 mm×21 mm×0.32 mm:
Enhanced Hardness:
Springiness—Test Conducted by Compression Tester:
Accordingly, from the above table, it is evident that the springiness witnessed in the Gold Alloy according to the present invention is almost more than double of applied load (pressure) in comparison with the conventional Gold alloy without Zirconium.
Higher Resistance to Wear:
Test Conducted with media polishing set up in which ceramic is used as media for 2 Hours:
Specific Gravity:
It has been tested and observed that the specific gravity of the 23-carat Gold alloy made according to the present invention is significantly reduced. While the conventional 23-carat gold has a specific gravity of 18.523 gm/cc, 23 carats gold alloy made in accordance with the present invention with the above composition has demonstrated a specific gravity of 18.27 gm/cc, which is 1.37% less than the conventional 23-carat gold alloy. This is a substantial cost-effectiveness for this high value metal used for jewelry manufacture.
Color Retention:
23-carat Gold alloy made according to the present invention is also compatible in terms of the color retention properties thereof, when compared with conventional 23-carat Gold alloys as observed under (CIE Defined) color spectrograph.
Size of test pieces 21 mm×21 mm×0.32 mm:
Enhanced Hardness:
Springiness—Test Conducted By Compression Tester:
Accordingly, from the above table, it is evident that the springiness witnessed in the Gold Alloy according to the present invention is almost more than double of applied load (pressure) in comparison with the conventional Gold alloy without Zirconium.
Higher Resistance to Wear:
Test Conducted with media polishing set up in which ceramic is used as media for 2 Hours:
Specific Gravity:
It has been tested and observed that the specific gravity of the 23-carat Gold alloy made according to the present invention is significantly reduced. While the conventional 23-carat gold has a specific gravity of 18.523 gm/cc, 23 carats gold alloy made in accordance with the present invention with the above composition has demonstrated a specific gravity of 17.97 gm/cc, which is 2.94% less than the conventional 23-carat gold alloy. This is a substantial cost-effectiveness for this high value metal used for jewelry manufacture.
Color Retention:
23-carat Gold alloy made according to the present invention is also compatible in terms of the color retention properties thereof, when compared with conventional 23-carat Gold alloys as observed under (CIE Defined) color spectrograph.
Size of test pieces 21 mm×21 mm×0.32 mm:
Enhanced Hardness:
Springiness—Test Conducted By Compression Tester:
Accordingly, from the above table, it is evident that the springiness witnessed in the Gold Alloy according to the present invention is almost more than double of applied load (pressure) in comparison with the conventional Gold alloy without Zirconium.
Higher Resistance to Wear:
Test Conducted with media polishing set up in which ceramic is used as media for 2 Hours:
Specific Gravity:
It has been tested and observed that the specific gravity of the 23-carat Gold alloy made according to the present invention is significantly reduced. While the conventional 23-carat gold has a specific gravity of 18.523 gm/cc, 23 carats gold alloy made in accordance with the present invention with the above composition has demonstrated a specific gravity of 17.92 gm/cc, which is 3.24% less than the conventional 23-carat gold alloy. This is a substantial cost-effectiveness for this high value metal used for jewelry manufacture.
Color Retention:
23-carat Gold alloy made according to the present invention is also compatible in terms of the color retention properties thereof, when compared with conventional 23-carat Gold alloys as observed under (CIE Defined) color spectrograph.
Size of test pieces 21 mm×21 mm×0.32 mm:
Enhanced Hardness:
Springiness—Test Conducted By Compression Tester:
Accordingly, from the above table, it is evident that the springiness witnessed in the Gold Alloy according to the present invention is almost more than double of applied load (pressure) in comparison with the conventional Gold alloy without Zirconium.
Higher Resistance to Wear:
Test Conducted with media polishing set up in which ceramic is used as media for 2 Hours:
Specific Gravity:
It has been tested and observed that the specific gravity of the 24-carat Gold alloy made according to the present invention is reduced by the above composition. While the conventional 24-carat gold has a specific gravity of 19.219 gm/cc, 24-carat gold alloy made in accordance with the present invention with the above composition has demonstrated a specific gravity of 18.771 gm/cc, which is 2.33% lesser than the conventional 24-carat gold alloy. This is a substantial cost-effectiveness for this high value metal used for jewelry manufacture.
Color Retention:
24-carat Gold alloy made according to the present invention is also compatible in terms of the color retention properties thereof when compared with conventional 24-carat Gold alloys as observed under (CIE Defined) color spectrograph.
Size of test pieces 21 mm×21 mm×0.32 mm:
Enhanced Hardness:
Springiness—Test Conducted by Compression Tester:
Accordingly, from the above table, it is evident that the springiness witnessed in the gold alloy made in accordance with the present invention is substantially higher in comparison with the conventional 24-carat Gold alloy.
Higher Resistance to Wear:
Test Conducted with media polishing set up in which ceramic is used as media for 2 Hours:
Specific Gravity:
It has been tested and observed that the specific gravity of the 24-carat Gold alloy made according to the present invention is reduced by the above composition. While the conventional 24-carat gold has a specific gravity of 19.219 gm/cc, 24-carat gold alloy made in accordance with the present invention with the above composition has demonstrated a specific gravity of 19.05 gm/cc, which is 0.88% lesser than the conventional 24-carat gold alloy. This is a substantial cost-effectiveness for this high value metal used for jewelry manufacture.
Color Retention:
24-carat Gold alloy made according to the present invention is also compatible in terms of the color retention properties thereof, when compared with conventional 24-carat Gold alloys as observed under (CIE Defined) color spectrograph.
Size of test pieces 21 mm×21 mm×0.32 mm:
Enhanced Hardness:
Springiness—Test Conducted by Compression Tester:
Accordingly, from the above table, it is evident that the springiness witnessed in the gold alloy made in accordance with the present invention is substantially higher in comparison with the conventional 24-carat Gold alloy.
Higher Resistance to Wear:
Test Conducted with media polishing set up in which ceramic is used as media for 2 Hours:
Specific Gravity:
It has been tested and observed that the specific gravity of the 24-carat Gold alloy made according to the present invention is reduced by the above composition. While the conventional 24-carat gold has a specific gravity of 19.219 gm/cc, 24-carat gold alloy made in accordance with the present invention with the above composition has demonstrated a specific gravity of 18.73 gm/cc, which is 2.53% lesser than the conventional 24-carat gold alloy. This is a substantial cost-effectiveness for this high value metal used for jewelry manufacture.
Color Retention:
24-carat Gold alloy made according to the present invention is also compatible in terms of the color retention properties thereof, when compared with conventional 24-carat Gold alloys as observed under (CIE Defined) color spectrograph.
Size of test pieces 21 mm×21 mm×0.32 mm:
Enhanced Hardness:
Springiness—Test Conducted by Compression Tester:
Accordingly, from the above table, it is evident that the springiness witnessed in the gold alloy made in accordance with the present invention is substantially higher in comparison with the conventional 24-carat Gold alloy.
Higher Resistance to Wear:
Test Conducted with media polishing set up in which ceramic is used as media for 2 Hours:
Specific Gravity:
It has been tested and observed that the specific gravity of the 24-carat Gold alloy made according to the present invention is reduced by the above composition. While the conventional 24-carat gold has a specific gravity of 19.219 gm/cc, 24-carat gold alloy made in accordance with the present invention with the above composition has demonstrated a specific gravity of 18.67 gm/cc, which is 2.84% lesser than the conventional 24-carat gold alloy. This is a substantial cost-effectiveness for this high value metal used for jewelry manufacture.
Color Retention:
24-carat Gold alloy made according to the present invention is also compatible in terms of the color retention properties thereof, when compared with conventional 24-carat Gold alloys as observed under (CIE Defined) color spectrograph.
Size of test pieces 21 mm×21 mm×0.32 mm:
Enhanced Hardness:
Springiness—Test Conducted by Compression Tester:
Accordingly, from the above table, it is evident that the springiness witnessed in the gold alloy made in accordance with the present invention is substantially higher in comparison with the conventional 24-carat Gold alloy.
Higher Resistance to Wear:
Test Conducted with media polishing set up in which ceramic is used as media for 2 Hours:
Some of the technical advantages of the gold alloy containing at least two out of zirconium, magnesium and titanium or all three together as an alloying element made in accordance with the present invention are as under:
Throughout this specification, the word “comprise”, or variations such as “comprises” or “comprising”, shall be understood to implies including a described element, integer or method step, or group of elements, integers or method steps, however, does not imply excluding any other element, integer or step, or group of elements, integers or method steps.
The use of the expression “a”, “at least” or “at least one” shall imply using one or more elements or ingredients or quantities, as used in the embodiment of the disclosure in order to achieve one or more of the intended objects or results of the present invention.
The exemplary embodiments described in this specification are intended merely to provide an understanding of various manners in which this embodiment may be used and to further enable the skilled person in the relevant art to practice this invention. The description provided herein is purely by way of example and illustration.
Although the embodiments presented in this disclosure have been described in terms of its preferred embodiments, the skilled person in the art would readily recognize that these embodiments can be applied with modifications possible within the spirit and scope of the present invention as described in this specification by making innumerable changes, variations, modifications, alterations and/or integrations in terms of materials and method used to configure, manufacture and assemble various constituents, components, subassemblies and assemblies, in terms of their size, shapes, orientations and interrelationships without departing from the scope and spirit of the present invention.
While considerable emphasis has been placed on the specific features of the preferred embodiment described here, it will be appreciated that many additional features can be added and that many changes can be made in the preferred embodiments without departing from the principles of the invention.
These and other changes in the preferred embodiment of the invention will be apparent to those skilled in the art from the disclosure herein, whereby it is to be distinctly understood that the foregoing descriptive matter is to be interpreted merely as illustrative of the invention and not as a limitation.
| Number | Date | Country | Kind |
|---|---|---|---|
| 201721010746 | Mar 2017 | IN | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/IN2017/050266 | 6/28/2017 | WO |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2018/178998 | 10/4/2018 | WO | A |
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| MUM 2012 0263 | Apr 2013 | IN |
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| Number | Date | Country | |
|---|---|---|---|
| 20200216931 A1 | Jul 2020 | US |
