WO2013085420A1

WO2013085420A1 - Palladium-based alloy and method for hardening palladium alloys used for the manufacture of items of jewellery

Info

Publication number: WO2013085420A1
Application number: PCT/RU2012/000910
Authority: WO
Inventors: Сергей Алексеевич КОСТИН; Александр Константинович НИКОЛАЕВ
Original assignee: Kostin Sergey Alexeevich
Priority date: 2011-12-06
Filing date: 2012-11-07
Publication date: 2013-06-13
Also published as: RU2537329C2; EA201400647A1; RU2011149542A

Abstract

The invention relates to the metallurgy of precious metals and alloys used for the manufacture of items of jewellery. What are proposed are: a palladium-based alloy and a method for hardening palladium alloys used for the manufacture of items of jewellery, which method ensures the necessary technological efficiency of the process for manufacturing items of jewellery by means of the use of the dispersion hardening effect. The alloy has been processed on the basis of a precious metal which is nevertheless cheaper and more readily available than platinum, namely palladium. The claimed alloy has increased flowability and fusibility, which advantageously distinguishes it from its platinum analogue on use. The palladium-based alloy is characterized in that hardening phases which are precipitated on decomposition of a solid solution are intermetallic compounds which do not contain base metals. The method comprises an operation in which a palladium base is alloyed with at least two components which together form a chemical compound that does not contain base metal atoms, which makes it possible to harden the alloy in the casts for the items of jewellery by means of thermal and thermomechanical processing thereof. The thermal processing makes it possible, depending on the previous operation or the initial state (casting or hot and cold deformation), to produce a selection of strength properties from soft to hard.

Description

Palladium-based alloy and method of hardening palladium alloys used for the manufacture of jewelry.

The invention relates to the metallurgy of noble metals and alloys used for the manufacture of jewelry.

Palladium - a white metal belongs to the platinum group. It has high corrosion resistance and good adaptability to cold forming, is highly polished and does not fade. The disadvantage of unalloyed palladium is the low strength properties and high, as with the entire platinum group of metals, the melting point is 1554 ° C. In the soft state, palladium has a temporary tensile strength σ _Β = 180-190 MPa, a conditional yield strength σ ₀ , ₂ = 49-50 MPa and a hardness of only 40-50 HV. Even cold deformation by 90% increases the temporary resistance by only half, which is significantly less than that of a metal such as copper in any production conditions. All of the above complex of positive properties and qualities of palladium makes the development of durable alloys based on palladium very promising. Since, at a significantly lower cost than the leader in the jewelry industry - platinum, palladium in color and properties, including interaction with other noble and base metals, is close to platinum.

Palladium-based alloys are known that can be used for the manufacture of jewelry according to RF patents Ν2 232 2395604, 2362823, 2331689, 2319758, 2405051, 2349660, 2349659, 2331683, 2331684. However, none of the known solutions fully discloses alloys of real commodity compositions.

Known alloy based on palladium according to the patent of the Russian Federation Ns 2220218 (publ. 12/27/2003), which can be used for the manufacture of jewelry. The known alloy as additives contains cobalt, copper, indium, gallium, iridium, cadmium and / or bismuth. The proposed alloy and the ratio of its components provides a lower melting point due to the inclusion of bismuth, which facilitates the work with the alloy during casting. The addition of cadmium in the specified interval supposedly leads to a decrease in the oxidizability of the alloy, which improves the surface the original cast billet and reduces the strength of the alloy during deformation. However, the alloying additives of cadmium and bismuth with low boiling points used in the known alloy are toxic, which makes its production incompatible with accepted sanitary standards.

The technical result to which the invention is directed is to increase the strength properties (at least hardness) of palladium. In addition, the claimed variants of palladium-based alloys differ from the known palladium alloy according to RF patent Ns 2220218 in that they do not contain toxic, low boiling points, and, therefore, alloying components that are not high-tech in their production, have a relatively low melting point, good technological properties in the casting process, hot and cold deformation, the ability to harden in the process of thermal or thermomechanical processing.

The claimed technical result is achieved in that the increase in the strength properties of palladium is achieved by alloying it

• nickel and silicon in an amount of 5% in total, with a ratio of nickel to silicon as 3.5-4.5 / 1, necessary for the formation of the chemical compound Ni ₂ Si,

• nickel and aluminum in total in the amount of 15% with the ratio of nickel and aluminum necessary for the formation of at least one of the chemical compounds Ni ₃ AI, NiAI and Ni ₂ AI ₃

In addition, as additional alloying components, the alloy contains at least one element from the group of copper, gold, indium, gallium, boron.

For example, a palladium-based alloy may contain palladium in an amount of 50-95%; nickel 3-5%; silicon 0.5-2%; copper 1-40%; gold 1-30%; indium 1-10%; gallium 1-10%; boron 0.01-1, 0%

or

a palladium-based alloy may contain palladium in an amount of 50-85%, nickel 11-13.5%, aluminum 1.5-4%; copper 1-40%; gold 1-30%; indium 1-10%; gallium 1-10%; boron 0.01-1, 0%.

The novelty of the claimed alloy is determined, first of all, by the fact that the hardening phases released during the decomposition of the solid solution are intermetallic compounds that do not contain a metal - solvent (base) in their composition. This fact is fundamental, since it allows alloying alloys of any base with the same high hardening effect as a result of thermal or thermomechanical treatment. The hardening effect in this case is significantly increased and remains for a longer time even when heated.

Additional alloying of palladium alloys with copper, gold, indium and gallium, both each and in any combination, provides a decrease in the melting temperature of the palladium alloy in accordance with the state diagrams of Pd-Cu, Pd-Au, Pd-ln, Pd-Ga, and an increase in casting properties , density of products, the ability to change color from white to yellow and golden pink with various shades.

In addition, these alloying elements can further strengthen the alloys of the claimed composition as a result of the action of the solid-solution mechanism, interatomic interaction and structural factors.

And, for example, the inclusion of boron, which is a deoxidizer of the alloy, reduces the effect of oxygen and reduces the loss of alloying components on waste.

Known alloy platinum-gallium-palladium for the jewelry industry according to international application WO 00/32829 (publ. 08.06.2000), to which heat treatment is applicable. However, the basis of the alloy is platinum, and palladium is included only as an additional alloying element that improves the properties of the alloy in an amount of less than 3%.

The inventive method of hardening palladium alloys used for the manufacture of jewelry based on the effect of dispersion hardening (nanophase hardening). The heat treatment of precipitation hardening alloys consists in their heating to the formation of a supersaturated solid solution, subsequent possible rapid cooling - quenching, and aging, as a result of which the solid solution decomposes with the release of nanophase particles of hardener phases.

The inventive method differs from the known method in the composition of the formed and released intermetallic compounds. The difference from hardeners of a different composition is significant, both by the method of formation and by the structure, nature of the melting points, kinetics of decomposition of the solid solution, the effect of hardening and its stability. Other in comparison with the known platinum alloy are the parameters and temperature-time regimes of the heat treatment itself. The method of hardening palladium alloys used for the manufacture of jewelry by using the dispersion hardening effect, which provides the necessary manufacturability in the process of their manufacture and operation, involves doping the palladium base with at least two components that form a chemical compound that does not contain base metal atoms , which allows to strengthen the alloy in the products through their thermal or thermomechanical processing. In this case, heat treatment includes operations

- heating and holding products from palladium alloys at a temperature that ensures the formation of a supersaturated solid solution,

- quenching from this temperature in water, in air, in a vacuum or other medium to a temperature of less than 100 ° C,

- aging at temperatures from 300 to 800 ° C for a time of 5 minutes to 24 hours with cooling in any environment and at any speed.

In this case, the hardening operation can be combined both with the casting of the product into the mold (hardening from the cast state) and can be carried out by additional heating of the molded product from a temperature of 800 ° C to the pre-melting temperature of the alloy with holding at this temperature from 0 min for hardening directly during casting up to 180 min with additional heating.

The method may also include the operation of thermomechanical processing of products made of palladium alloys, when between hardening and aging or after aging plastic deformation is carried out by any method and with any degree in the temperature range from room temperature to a temperature of 1300 ° C, depending on the composition of the alloy.

The inventive method can be carried out using vacuum arc or induction furnaces or furnaces with a protective atmosphere. Alloy castings can be obtained by the method of pre-casting into the mold or by casting the finished products in special forms, including investment casting. The deformation of the workpieces can be carried out by rolling, pressing and drawing, stamping or forging, weaving.

Claims

CLAIM

1. An alloy based on palladium containing palladium in an amount of up to 95%, nickel and silicon in total in an amount of up to 5% with a ratio of nickel to silicon as 3.5-4.5 / 1.

2. An alloy based on palladium according to claim 1, characterized in that it contains at least one element from the group copper, gold, indium, gallium, boron as additional alloying components.

3. An alloy based on palladium according to any one of p. 1 or p. 2, characterized in that it contains palladium in an amount of 50-95%; nickel 3-5%; silicon 0.5-2%; copper 1-40%; gold 1-30%; indium 1-10%; gallium 1-10%; boron 0.01-1, 0%

4. A palladium-based alloy containing palladium in an amount of up to 85%, nickel and aluminum in total in an amount of up to 15% in a stoichiometric ratio that determines the formation of intermetallic compounds Ni ₃ AI, ΝίΑΙ and Ni ₂ AI ₃ .

5. An alloy based on palladium according to claim 4, characterized in that it contains at least one element from the group copper, gold, indium, gallium, boron as additional alloying components.

6. An alloy based on palladium according to any one of p. 4 or p. 5, characterized in that it contains palladium in an amount of 50-85%, nickel 11-13.5%, aluminum in 1, 5-4%; copper 1-40%; gold 1-30%; indium 1-10%; gallium 1-10%; boron 0.01-1, 0%.

7. A method of hardening palladium alloys used for the manufacture of jewelry, including the operation of alloying a palladium base with at least two components that form a chemical compound between themselves that does not contain base metal atoms, followed by thermal or thermomechanical processing of the products.

8. The method of hardening palladium alloys according to claim 7, characterized in that the heat treatment includes heating and holding products from palladium alloys at the temperature of formation of a supersaturated solid solution, quenching from this temperature in water, in air, in a vacuum or other medium to a temperature less than 100 ° C and aging at temperatures from 300 to 800 ° C for a time of 5 minutes to 24 hours with cooling in any environment and at any speed.

9. The method of hardening palladium alloys according to claim 8, characterized in that the hardening operation is combined with casting the product into a mold with holding at this temperature from 0 min.

10. The method of hardening palladium alloys according to claim 8, characterized in that the product is heated before the hardening operation from 800 ° C to a pre-melting temperature with holding at this temperature for up to 180 minutes.

11. The method of hardening palladium alloys according to claim 7, characterized in that the thermomechanical treatment of the molded product is carried out by plastic deformation in the temperature range depending on the composition of the alloy from room temperature to a temperature of 1300 ° C, between quenching and aging or after aging.