JPH0625810A - Production of non-ferrous alloy article its component - Google Patents

Abstract

PURPOSE: To manufacture an article having a surface appearance which is novel and esthetically enjoyable by grinding the surface of the article consisting of non-ferrous alloy and successively executing the heat treatment of the article to generate a martensitic phase transformation on at least the ground surface.

CONSTITUTION: An article or its component consisting of a non-ferrous alloy having a composition to be selected so as to show a martensitic phase transformation, is formed in the condition of a base phase and its whole surface or the surface of a desired part is ground. Then, the article or the component is heat-treated to generate the martensitic phase transformation at least on the ground surface. The heat treatment is executed by heating the article or the component to a temperature in a base phase region in an equilibrium diagram and then, rapidly cooling it below a martensitic transformation starting temperature and as necessary, additionally by applying a refrigeration treatment with liquid nitrogen etc. to it. Thereafter, the final martensitic phase is preferably stabilized through the aging for a long time, the surface is etched as necessary, or the surface is treated with reaction species etc. to improve the remarkability of a surface effect.

COPYRIGHT: (C)1994,JPO

Description

Detailed Description of the Invention

[0001]

This invention relates to the surface of articles or components thereof of non-ferrous metals, and more particularly of non-ferrous metals whose components exhibit a martensitic phase transformation when subjected to a suitable heat treatment. It is about aesthetic enhancement. A number of alloys within the scope of the alloys relevant to the present invention are based on various metals, and more particularly, and more importantly, on the gold, silver and platinum group metals. Still more particularly, the present invention relates to, but is not limited to, modifying the surface appearance of jewelry, coins, ornaments, and other articles of aesthetic appeal.

[0002]

2. Description of the Related Art Articles made of non-ferrous metals, more particularly jewels,
Coins, ornaments, etc., more particularly articles made of precious metals such as gold, platinum and silver, are highly polished, frosted or physically formed by pressing, forging, casting or engraving. It has a surface with various relief patterns.

[0003]

The methods of applying decoration or aesthetic appeal to the surface of such articles are limited.
It would be highly desirable to provide an alternative to these known basic surface finishes. Therefore,
It is an object of the present invention to provide articles or parts thereof made of non-ferrous metals, in particular, but not exclusively, noble metals having a novel and aesthetically pleasing surface appearance.

[0004]

According to one aspect of the present invention, an article or component thereof comprising a non-ferrous alloy having a composition selected to exhibit a martensitic phase transformation between a parent phase and a martensitic phase. In the manufacturing method of, an article or a component thereof is manufactured, the entire surface or a surface of a desired portion thereof is polished, and then the article or a component thereof is heat treated to cause a martensite phase transformation on at least the polished surface. There is provided a method of manufacturing a part or its component made of a non-ferrous alloy, which is characterized by causing a visible surface effect.

The article may first be manufactured and polished in the parent phase and heat treated to achieve a phase transformation to the martensitic phase at least on the polished surface. Alternatively or additionally, the surface may be polished in the martensitic phase and then heat treated to transform the alloy back into the parent phase to produce the inverse surface effect.

The invention is based on the fact that the alloy is based on a metal of the copper, gold, silver or platinum group, that after heating the article or its components to a temperature in the parent phase region of the equilibrium diagram, then martensite. Achieving a heat treatment by rapid cooling below the transformation onset temperature and, if necessary, by additionally refrigerating the article or its components in liquid nitrogen and subjecting the alloy to high temperatures. In the case of oxidation, polishing or buffing the surface at a temperature between a high temperature heat treatment and a low temperature heat treatment, and if necessary to show ductility, before processing or shaping to induce a martensite phase transformation, A further feature is the heat treatment of the article or component thereof at a temperature outside the beta phase region.

According to a further feature of the invention, certain metals are thermally treated or aged to prevent martensitic transformation.

According to a further feature of the invention, the martensitic or matrix phase is achieved by aging for a long period of time.

According to a further feature of the present invention, the inherent color of certain alloys is modified, and more particularly certain gold-based alloys are produced exhibiting a range of colors. Still more particularly, the inherent color of at least 18 carat alloys based on the gold-copper-aluminum system can be modified from yellow to red, violet and white by varying the aluminum content.

The present invention includes the inclusion of ternary or higher alloy additives in a non-ferrous metal alloy to modify the mechanical properties, color, or temperature range in which martensitic transformation occurs, or a combination thereof. Prior to heat treatment to induce the martensitic phase transformation, inoculation of the melt or suitable thermomechanical treatment of the compound (thermo
-mechanical processing), the surface effect roughness of the martensitic phase transformation (coarneses
s) is refined, by chemical or electroetching of the surface, or by chemically reacting species (reactive).
reaction with the surface of, and / or diffusing into, and depositing on the surface.
on) enhances the saliency of additional color effects or surface effects.

The modified surface is the "spangle" that results from the martensitic phase transformation.
Although it may be called, by mechanical polishing and buffing,
Alternatively, it is interesting to note that the shape memory properties, if present, are removed by cooling the article or its components at a rate slow enough to reheat and diffuse.

It is also interesting to note that the spangles produced by the martensitic phase transformation on some or all surfaces are unique, and therefore each article or component thereof is characterized as a "fingerprint".

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention and some embodiments will be described in detail below with reference to the accompanying drawings. Relatively few metal alloys exhibit a phenomenon known as martensitic phase transformation. In its simplest form, the martensitic phase transformation is considered to be a substitutional solid transformation which consists of a change in crystal structure without diffusion. From the microstructure scale, the martensite phase appears as a lens-shaped plate, a flat plate, or a packed body of twins. The martensitic transformation in non-ferrous alloys can cause several related effects such as thermoelasticity, pseudoelasticity, electrical resistance anomalies, damping, rubbery behavior and one or two-way shape memory effects.

The equilibrium diagrams of alloys with copper (Cu), silver (Ag), gold (Au) and platinum group metals (PGMs), especially metals of group B of the Periodic Table, show a considerable degree of similarity. And characterize the V-shaped mother "beta" phase region. A typical phase diagram is shown in FIG. A list of some binary alloys in this family, which are expected to exhibit a martensitic phase transformation, is shown diagrammatically in the general periodic table of FIG. The elements within the bold line frame represent the base elements, in which the adjacent elements are expected to produce the required transformation properties. Various other noble metals and ternary compounds have also been identified in the literature as exhibiting martensitic phase transformations.

The properties of martensitic transformations and their associated effects in intermetallic solid solutions are well documented in the literature. Although some issues remain to be clarified, rigorous research has been done into control mechanisms and is well understood. Various compounds have been prepared, for example, by vacuum arc, or by vacuum induction melting or melting in a sealed quartz container. The composition was selected to change the martensitic transformation temperature and the compound was heat treated to exhibit the martensitic transformation. One compound is, for example, wire rod rolling (wi
It was found that it can be processed by re-rolling) or cold or hot rolling. In addition, processed products were selected and manufactured to demonstrate the application of the martensitic transformation to decoration.

Swatches of compounds based on the Cu, Ag, Au and Pt systems were prepared. Specifically, martensitic phase spangles were produced with the following composition ratios (weight ratios) using the techniques described above. Cu-27% Zn-4% Al Cu-26% Zn-4% Al Cu-23.6% Sn Pt-21% Ti Pt-19% Ti Pt-9% Al-10% Cu Pt-9.5% Al-5% Cu Au-22% Cu-31% Zn Au- (0-22% Cu)-(2-8% Al)

Further selections of compositions that are expected to exhibit the martensitic transformation are currently under investigation (in parentheses give the composition range in which the martensitic transformation is expected). Au-Al (96-98% Au; rest Al) Au-Cu-Zn (69-83% Au; 17-31% Z)
n; 0-22% Cu) Au-Mn (61-88% Au; rest Mn) Au-Ti (71-82% Au; rest Ti) Au-Cu-Mn (61-88% Au; 12-39% M
n; 0-22% Cu) Au-Cu-Ti (71-82% Au; 18-29% T
i; 0-22% Cu) Au-Mn-Ti (64-88% Au; 12-36% M
n; 0-22% Ti) Au-Zn (69-83% Au; rest Zn) Au-Mn-Zn (61-88% Au; 12-39% M
n; 17-31% Zn) Pt-Al (88-91% Pt; rest Al) Pt-Al-Cu (9-12% Al; 0-10% C
u; rest Pt) Pt-Mn (63-86% Pt; rest Mn) Pt-Mo (60-70% Pt; rest Mo)

Based on the above results, it was shown that the concept of the present invention is applicable to various alloy systems beyond the composition range.

[0019]

Accordingly, a number of different alloys having different colors and compositions can be produced to exhibit the desired martensitic phase transformation, which gives an attractive shiny finish to the polished surface of articles and their parts. Glowing effect (spangle effec
t) can be given. The surface effect occurs not only when the matrix phase transforms into the martensite phase, but also when the matrix phase undergoes the opposite phase transformation. The surface or part of it may be polished when the alloy is in the martensitic phase and heat treated to recover the parent phase. This gives a surface effect and an aesthetically pleasing appearance.

[Brief description of drawings]

FIG. 1 is a schematic periodic table showing mother elements (thick lines) showing martensitic transformation together with adjacent alloy elements. Diagram of some martensitic non-ferrous alloys. [Source: Dela
ey, L., Mukherjee, K., and Chanrasekaran, M., “ Non-Fer
" Rous Martensites ", Minutes of "Science and Technology of Shape Memory Alloys", Barcelona, January-1989, ECC-COMETT 87/2 / C-2 /
[00863] Platinum group metals Pt, Pd, Ru, R
A martensitic alloy based on h, Ir, Os is added.

FIG. 2 is a typical equilibrium diagram of an alloy exhibiting martensitic phase transformation properties. Au-Mn system showing the characteristics of the parent beta (β) phase region for the B ₂ structure. Β ₁ and β ₂ transitions corresponding to martensitic transformation. [Source: " Binary
Alloy Phase Diagrams ", Vol.1, (Author) TBMassalsk
i, ASM, Ohio, 1986]

FIG. 3 is an optical micrograph taken under polarized light showing a martensitic metallographic structure in a Cu—Zn—Al alloy.

FIG. 4 is an optical micrograph showing a martensitic metallographic structure in a Pt—Ti alloy.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Michael Bernard Courtee No. 28 François Avenue, Randburg, Bordeaux, Transvaal Republic of South Africa

Claims (12)

[Claims] 1. A method for producing an article or a component thereof made of a non-ferrous alloy having a composition selected so as to exhibit a martensitic phase transformation between a mother phase and a martensite phase, the article or a component thereof being manufactured. Polishing the entire surface or a desired portion of the surface, and subsequently subjecting the article or its component to a heat treatment to cause a martensitic phase transformation on at least the polished surface to cause a visible surface effect. A method of manufacturing a part made of a non-ferrous alloy or a component thereof. 2. Method according to claim 1, characterized in that the article is first produced in the mother phase. 3. The alloy in the matrix phase is polished on its surface or a part thereof and then heat-treated to form a martensite phase on at least the polished surface. The method described in crab. 4. The phase transformation from the mother phase to the martensite phase is performed by heating the article or its constituent parts to a temperature within the matrix phase region in the equilibrium diagram, and then rapidly cooling it to a temperature below the martensite transformation start temperature. Method according to any of claims 1 to 3, characterized in that it is achieved. 5. The method according to claim 4, wherein after the rapid cooling, the article or its components are additionally subjected to a freezing treatment. 6. An alloy having at least a surface in a martensitic phase, the surface or a part of which is polished,
The method according to any one of claims 1 to 5, wherein the article or the constituent article thereof is then heat-treated to cause a phase transformation to return the martensite phase to the matrix phase. 7. An article or its components are heated to a temperature above the martensitic transformation temperature, aged at high temperature to stabilize the parent phase, and cooled to ambient temperature.
The method according to claim 6, characterized in that a phase transformation from the martensite phase to the matrix phase is achieved. 8. A method according to any of the preceding claims, characterized in that the alloy is oxidized at high temperature and the surface or part of it is polished or buffed at a temperature between the high and low temperature heat treatments. 9. Prior to processing or forming the article or its constituent parts, the article is heated in a matrix phase at a temperature outside the matrix phase and then heat treated to achieve the martensitic phase transformation. Method according to any of the preceding claims to 10. The method according to any of the preceding claims, characterized in that the final martensite phase is stabilized by aging for a long time. 11. Significance of surface effects by chemically or electrically etching the surface, or by treating the surface with reactive species or coatings to cause reaction, diffusion, or deposition of materials on the surface. The method according to any of the preceding claims, characterized in that 12. An article or a component thereof manufactured by the method according to any one of the preceding claims.