DE202014001179U1 - Precious metal alloy, in particular for use in the jewelery and watch industry - Google Patents

Abstract

Precious metal alloy containing palladium and rhodium, characterized in that the noble metal alloy palladium in a proportion of 40-60 wt .-% and rhodium in a proportion of 40-60 wt .-%, wherein the weight fraction of Rhodium and palladium, except for usual admixtures and impurities, to 100 wt .-% complete.

Description

The invention relates to a noble metal alloy containing palladium and rhodium.

In the jewelery and watch industry, a particularly white metal color of a noble metal alloy is desired, since in this way the gloss of stones, in particular of gemstones such as diamonds, which has a piece of jewelery made from this noble metal alloy, is supported in a particularly good manner. White gold is therefore very often coated with a galvanic rhodium layer to improve the less white color of white gold or a white gold alloy used to make the jewelry. Rhodium is known to be the precious metal with the best white color. Such an approach is z. B. in the DE 10 2008 050 135 described. The disadvantage of this is not only that in the production of jewelry from white gold or white gold alloy an additional operation - the galvanic Rhodinierung this piece of jewelry - must be performed. It is more important for a purchaser of such a manufactured piece of jewelry that galvanically applied rhodium layers are subjected to natural wear when using the piece of jewelry, so that after a certain period of wear, the rhodium coating of the piece of jewelry must be renewed, as by their wear the less white color of the base material of the jewel, that is, the white gold alloy, has become visible.

To make a piece of jewelry made of rhodium or a rhodium alloy as a massive alloy is impractical because rhodium is very brittle and therefore not suitable for the production of jewelry such as jewelry, jewelry, watch cases, writing instruments, etc., or at least not to a sufficient extent.

Platinum and high-alloy platinum alloys such. Example, an alloy with 95 wt .-% platinum have for most of the jewelry and watch industry applications occurring a sufficiently white color and are generally considered to be of particular value, since platinum is the precious metal with the highest metal price.

Palladium is a white precious metal with the lowest reflectance of light and therefore appears gray compared to platinum alloys. For this reason, palladium is currently used only for selected applications in the jewelery and watch industry where it does not or does not primarily arrive at an "ideal white" color of a product made from palladium or a palladium alloy. Palladium not only has the advantage over platinum that it is about 40% lighter than this precious metal. Rather, the metal price of palladium is significantly lower than that of platinum. The two aforementioned advantages can be due to the disadvantageous color described above - palladium acts gray - use only inadequate in the jewelry and watch industry.

It is an object of the present invention to provide an alloy based on palladium, which is suitable for the production of jewelry such as jewelry, watches, jewelery or writing instruments and has a "whiter" color compared to pure or high-alloyed palladium.

This object is achieved in that the noble metal alloy of the invention palladium in a proportion of 40-60 wt .-% and rhodium in a proportion 60-40 wt .-%, wherein the weight proportions of palladium and rhodium together with conventional Add impurities and admixtures to 100 wt .-%.

The measures according to the invention advantageously provide a massive precious metal alloy which has a white color which is comparable to that of rhodium or a rhodium coating or at least that of platinum or platinum alloys. The noble metal alloy according to the invention therefore acts in an advantageous manner particularly bright and is therefore particularly suitable for the production of jewelry pieces, in particular of pieces of jewelry that have gemstones such as diamonds. Since the precious metal alloy according to the invention - since it is made metallurgically and not just a coating - this color itself, it is no longer necessary for the production of jewelry their color by a further treatment step, such. As a galvanic rhodium, to improve.

Another advantage of the precious metal alloy according to the invention is that it is significantly lighter in weight than a platinum alloy of the same or comparable white color, and that it is much cheaper to produce than such a platinum alloy, since - as already stated above - the metal price of rhodium and palladium is significantly lower than that of platinum.

The noble metal alloy according to the invention has a hardness soft in the range of 180-200 HV and is therefore particularly well suited for the production of a piece of jewelry by means of a hot deformation. It has a hardness hard in the range of more than 250 HV, preferably more than 300 HV, and is therefore characterized by a good wear resistance. Draw jewelry made from the precious metal alloy according to the invention Therefore, it is characterized by the fact that their glossy surface is retained for a long time.

An advantageous development of the invention provides that the noble metal alloy palladium according to the invention contains a weight fraction of 47 to 53 wt .-% and rhodium a weight fraction of 53 to 47 wt .-%, wherein the proportions of rhodium and palladium and the aforementioned Add impurities and admixtures to 100 wt .-%. Such a measure has the advantage of an even whiter color of the noble metal alloy according to the invention.

A further advantageous development of the invention provides that the precious metal alloy according to the invention comprises 50-52% by weight of palladium and 50-48% by weight of rhodium, the abovementioned proportions of palladium and rhodium excluding the aforementioned impurities and admixtures - supplement to 100 wt .-%.

A further advantageous development of the invention provides that the precious metal alloy according to the invention comprises 50% by weight of palladium and 50% by weight of rhodium, these two proportions of palladium and rhodium, apart from the aforementioned impurities and admixtures, being 100% by weight .-% complete.

A further advantageous development of the invention provides that the noble metal alloy according to the invention has 47-50% by weight of palladium and 53-50% by weight of rhodium, the proportions of palladium and rhodium, apart from the aforementioned impurities and admixtures, to 100 wt .-% complete.

A further advantageous development of the invention provides that the alloy according to the invention contains gold, platinum, ruthenium and / or iridium in a proportion of more than zero and not more than 10% by weight, preferably 2% by weight to 5% by weight. %, more preferably 3 wt .-%, wherein the proportions of rhodium and palladium and the aforementioned secondary alloy components to 100 wt .-% complement and replace the secondary alloy components preferably the corresponding proportion of rhodium.

Further advantages and developments of the invention are the subject of the dependent claims.

Further details and advantages of the invention can be found in the exemplary embodiments which are described below.

The first embodiment of the described noble metal alloy comprises 40-60 wt .-% palladium and 60-40 wt .-% rhodium, wherein the aforementioned proportions of palladium and rhodium to 100 wt .-% complement, if one of the usual Disregards impurities and admixtures of these metals. It is not necessary for a person skilled in the art to explain that the abovementioned proportions by weight and also the proportions by weight of the following exemplary embodiments are to be understood to include the usual tolerances occurring in a metallurgical production process.

The precious metal alloy described has a yellowness index YI in the range of 9 to 10. Such a yellowness index YI of less than 10 is considered to be very low for such noble metal alloys and is generally achieved only by rhodium itself or a rhodium-platinum alloy.

The brightness value (L * value) of the described alloy lies in the range between 86 and 88, which is surprising since the L * value is significantly higher than for the pure noble metals palladium or rhodium: rhodium has an L * value of 83.8 and palladium one from 81.1 up. The precious metal alloy described therefore, in an advantageous manner, has a very bright appearance, that is to say has a very white color, which is at the level of platinum alloy with 95% by weight of platinum. The described precious metal alloy is therefore visually hardly distinguishable from rhodium, a rhodium layer applied galvanically on a base material, a rhodium-platinum alloy or at least platinum or a platinum alloy with 95% by weight platinum, but is of an advantageous type and cheaper to manufacture.

The above values were determined by measurements and by the DIN 5033 defined standard conditions. The further values of the L * a * b * color space are in the range of 0.7 <= a * <= 0.9 and 3.5 <= b * <= 4 for the exemplary embodiment described.

A second exemplary embodiment of the noble metal alloy provides that the noble metal alloy contains 53-47% by weight of palladium and 47-53% by weight of rhodium, the abovementioned proportions taking into account unavoidable impurities and admixtures as well as the corresponding metallological tolerance limits to 100 wt .-% complete. Such an alloy has an L * value in the range of 87.3 and a yellowness index YI in the range of 9.7. The color parameters a * and b * are approximately 0.8 and 3.8, respectively.

A third embodiment of the noble metal alloy provides that the precious metal alloy 52-50 wt .-% palladium and 48-50 wt .-% rhodium, wherein the proportions of Palladium and rhodium - except for usual admixtures and impurities and alloy tolerances - add to 100 wt .-%. Such an alloy has a yellowness index YI of 9.8, an L * value of 87.3. The color parameters a * and b * are 0.8 and 3.8, respectively.

A fourth exemplary embodiment of the noble metal alloy provides that it contains 50% by weight of palladium and 50% by weight of rhodium, with the proportions of palladium and rhodium, apart from customary admixtures and impurities and alloy tolerances, being 100% by weight. % complete. Such an alloy has a yellowness index YI in the range of 9.8. The brightness L * is in the range of 87.3 and the color parameters a * and b * are 0.8 and 3.8, respectively.

A fifth exemplary embodiment of the noble metal alloy provides that the noble metal alloy contains 47-50% by weight of palladium and 53-50% by weight of rhodium, with the proportions of rhodium and palladium - of customary admixtures and impurities as well as alloy tolerances apart - supplement to 100 wt .-%. Such a noble metal alloy has a yellowness index YI in the range of 9.8. The brightness L * is in the range of 87.4 and the color parameters a * and b * are 0.9 and 3.7, respectively.

A sixth embodiment of the noble metal alloy provides that the noble metal alloy 40 wt .-% palladium and 60 wt .-% rhodium, wherein the proportions of rhodium and palladium - apart from conventional admixtures and impurities and alloy tolerances - to 100 Add% by weight. Such an alloy has a yellowness index YI in the range of 9.0. The brightness L * is in the range of 87.1 and the color parameters a * and b * are 0.8 and 3.5, respectively.

Preferred among the abovementioned noble metal alloys is that of the fourth exemplary embodiment, that is to say an alloy which has a weight fraction of 50% by weight of palladium and 50% by weight of rhodium. As can be seen from the color parameters described above, this has a yellow-blue value b * of 3.8, which is close to the arithmetic mean of the corresponding b * values of rhodium (b * = 2.8) and palladium ( b * = 6.0). The green-red value a * of the alloy of the fourth embodiment is slightly higher than the arithmetic mean of the primary alloy components of this alloy; Rhodium has an a * value of a * = 0.6 and palladium has a value of a * = 0.4. The green-red value a * of the alloy of the fourth embodiment is about 0.8, but is still substantially close to zero and therefore still negligible.

Surprisingly, it has been found that the brightness value L * of the described alloys, in particular the alloy of the fourth embodiment with L * = 87.3, is significantly higher than that of the pure materials. Palladium has a brightness L * of 81.1 and a yellowness index YI of 13.6. The corresponding values of rhodium are L * = 83.8 and YI = 6.8. The L * value of the alloy of the fourth embodiment is L * = 87.3 at the level of a 95% platinum alloy, making this alloy very bright, which is also evident from the yellowness index of YI = 9.8 results. As a result, in particular, the noble metal alloy according to the fourth embodiment can hardly be visually distinguished from rhodium, a galvanic rhodium layer, a rhodium-platinum alloy or at least platinum or a high-alloy platinum alloy such as Pt 950.

It is preferred that the noble metal alloys described above gold, platinum, ruthenium and / or iridium in an amount of more than 0 wt .-% and at most 10 wt .-% is added as a secondary alloy components, wherein the proportions of rhodium and palladium and those of the secondary alloy components to 100 wt .-% complete, apart from conventional admixtures and impurities and alloying tolerances. Such a measure has the advantage that the cast structure of such a noble metal alloy has a finer microstructure.

In the preparation of the aforementioned gold, platinum, rhenium and / or rhodium-containing noble metal alloy of an alloy according to one of the first five embodiments, it is preferably provided that the corresponding proportion of rhodium is replaced by the proportion of the abovementioned secondary alloy components added to these alloys , But it is also possible that not rhodium but paladium is replaced. Likewise, a combination of the two aforementioned measures, namely that the corresponding proportions of rhodium and palladium are replaced by the abovementioned secondary alloy components, is possible.

Surprisingly, it has been shown that the precious metal alloys described are very well suited for jewelery casting by the lost wax process, whereby conventional equipment and investment materials can be used for the casting of precious metal alloys. The castings made from the described alloys have essentially no or only a low porosity. They have a hardness in the range of 180-200 HV. This large molding hardness has the advantage that for the production of jewelry finished molds can be poured and their Hardness does not have to be subsequently improved by deformation from a variety of applications.

Another advantage of the precious metal alloys described is that surface defects were virtually not observed by reactions with an investment. The unexpectedly low solidification shrinkage of the precious metal alloys described compared to other jewelry materials such as platinum 950 or white gold 750 reduces the risk of shrinkage porosity, which is a major problem in jewelry casting.

Another advantage of the described noble metal alloys is that gas and / or embedding mass reactions are almost excluded since both rhodium and palladium have a high chemical resistance. This also implies that a re-casting of residues of the described noble metal-precious metal alloys without much difficulty is feasible, since these described precious metal alloys are not affected by chemical reactions in Schmuckguß process. This thereby given reusability of remnants of the casting process leads to a good material utilization.

Another advantage of the precious metal alloys described is in connection with the jewelery casting, that castings produced by such a jewelery casting have close to the final dimensions, which in conjunction with a good Wiedervergießbarkeit brings an economical use of materials with it.

The cast hardness of the alloys described in the range of 180-200 HV, in particular 190 HV, has the advantage that these alloys can best be processed by means of a hot forming process, for which a temperature above the miscibility gap at about 845 ° C is suitable , Particularly suitable is a temperature of 1200-1300 ° C. The advantage is that at such a temperature still hammering or rolling is possible, with deformations of up to 10% per forming step is possible.

After the hot deformation and a consequent transformation of the cast structure, cold working with machines such as are commonly used in precious metal processing is also possible. The solution-annealed state (annealing at 1000 ° C and subsequent quenching) has a hardness of 130 HV to 140 HV. By cold working hardening greater than 250 HV, preferably greater than 300 HV can be achieved. The high hardness of the described precious metal alloys provides for good wear resistance and thereby provides a good preservation of a glossy surface of a jewelry made of the described alloys such as a piece of jewelry, a watch case, a writing instrument, jewelery or the like.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102008050135 [0002]

Cited non-patent literature

• DIN 5033 [0021]

Claims (8)

Precious metal alloy containing palladium and rhodium, characterized in that the noble metal alloy palladium in a proportion of 40-60 wt .-% and rhodium in a proportion of 40-60 wt .-%, wherein the weight fraction of Rhodium and palladium, except for usual admixtures and impurities, to 100 wt .-% complete. Noble metal alloy according to claim 1, characterized in that the noble metal alloy palladium in a proportion of 53-47 wt .-% and rhodium in a proportion of 47-53 wt .-%, wherein the weight fraction of palladium and rhodium Apart from usual admixtures and impurities, add to 100 wt .-%. Noble metal alloy according to one of the preceding claims, characterized in that the noble metal alloy palladium in a proportion of 52-50 wt .-% and rhodium in a proportion of 48-50 wt .-%, wherein the weight fraction of palladium and rhodium, except for usual admixtures and impurities, to 100 wt .-% complete. Noble metal alloy according to one of the preceding claims, characterized in that the noble metal alloy palladium in a proportion of 50 wt .-% and rhodium in a proportion of 50 wt .-%, wherein the weight fraction of palladium and rhodium, of usual admixtures and impurities apart, to 100 wt .-% complete. Noble metal alloy according to one of the preceding claims, characterized in that the noble metal alloy palladium in a proportion of 47-50 wt .-% and rhodium in a proportion of 53-50 wt .-%, wherein the weight fraction of palladium and rhodium and, apart from usual admixtures and impurities, add to 100 wt .-%. Noble metal alloy according to one of the preceding claims, characterized in that the noble metal alloy palladium in a proportion of 40 wt .-% and rhodium in a proportion of 60 wt .-%, wherein the weight fraction of palladium and rhodium, of usual admixtures and impurities apart, to 100 wt .-% complete. Noble metal alloy according to one of the preceding claims, characterized in that the noble metal alloy gold, platinum, ruthenium and / or iridium in a proportion between more than 0 and 10 wt .-%, preferably a proportion between 2 wt .-% and 5 wt .-%, more preferably a proportion of 3 wt .-%, wherein the proportions of rhodium and palladium and the aforementioned secondary alloy components add up to 100 wt .-% substantially. Jewelery such as jewelry, watch, watch case, jewelry or writing instrument, characterized in that the piece of jewelry is made of a solid alloy according to any one of claims 1-7.