CH686136A5 - Nickel@-free soldering alloy with grey golden colouration - Google Patents

Abstract

A grey golden coloured alloy consists of in wt.%: 58-80 Au; 2-6 Mn; 4-15 of at least one from Zn, Ga, In; 2-6 Cu; and 0-25 Ag. The temp. difference between the liquidus and solidus is max.150 deg C with the liquidus having a max. temp. of 915 deg C.

Description

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CH 686 136 A5

Description

The present invention relates to a gray gold alloy for brazing.

There exist on the market essentially so-called gray or white gold alloys for brazing in which the bleaching agent is nickel and comprising certain other metals such as zinc, in-dium and cadmium with optionally silver and / or copper as a complement depending on the proportion of gold in the alloy. Palladium is not used since it increases the melting temperature.

The presence of nickel in these alloys poses a problem of skin allergy. There are actually few cases of allergies caused by gray gold alloys. These generally come from fancy ear pendants galvanically coated with a thin layer of gold deposited on a nickel undercoat. The presence of this layer of pure nickel and the piercing of the ear promote the development of allergies. Studies have shown, even in a young population, that in more than 10% of people with pierced ears a reaction to nickel has already been observed. People thus sensitized can develop an allergy on other parts of the body put in the presence of nickel alloy. This is the reason why there would be a great interest in a gray gold alloy for nickel-free solder, all the more so as certain legislations provide for prohibiting its use for articles intended to come into contact. prolonged with the skin.

Of course, such an alloy should have adequate physical properties, comparable to those of existing solders, in addition, its color should be sufficiently close to the ideal white so as not to be distinguished from the white gold alloy forming the pieces that it is intended to be assembled by brazing.

The object of the present invention is precisely to provide a solution which makes it possible to respond to the above-mentioned problem.

To this end, the subject of this invention is a gray gold alloy for solder according to claim 1.

It is noted that the use of manganese is hardly ever mentioned for the bleaching of gold. The only document, to our knowledge, which mentions its possible use in gray gold alloys is an article by Grahame P. O'Connor: "Improvement of 18 Carat White Gold Alloys" in Gold Bulletin 1978, 11, (2) , pages 35-85, in which the author discarded it as having no bleaching effect and because of its strong tendency to form oxides.

It will be seen in the description and the examples which follow that, on the contrary, a good bleaching effect is obtained with manganese and that the alloys obtained correspond completely to the requirements demanded of the gray gold alloys for solder sold and produced with nickel as a bleaching agent.

To obtain the alloys according to the invention, elements of a purity of 999.9% deoxidized are selected.

The alloy is produced by inductively melting the elements, the proportions and the choice of which are given in the table of examples which follows, in a graphite crucible placed in a sealed oven in which a partial nitrogen pressure is established. The molten metal is then poured into a graphite ingot mold. Once solidified, it is removed from the mold, removed from the oven enclosure and quickly cooled by water quenching.

The ingot obtained is then cold rolled. The rate of work hardening between each annealing is 30 to 50%. Then the alloy is annealed at 600 ° C for 30 minutes under a reducing atmosphere 20% H2 - 80% N2, then cooled by quenching with water.

The color measurement of the examples in the table below was carried out according to the three-dimensional system CIELAB (CIE = International Lighting Commission) and LAB for the three axes of orthogonal colors L representing the white-black component where black = 0 and white = 100, has the red-green component where + a = red -a = green and b the yellow-blue component where + b = yellow -b = blue. Therefore, the absolute white corresponds to L = 100, a = 0 and b = o.

These various components were measured using a Perkin-EI-mer Lambda 16 UV-visible spectrophotometer, equipped with an RSA-PE-60 accessory with integrating sphere of 150 mm diameter coated with Spectralon® PTFE, from Labsphere. Inc .. The lighting geometry is 8 ° / diffuse reflectance.

By way of comparison, the table below gives the advantageous properties of three alloys for brazing of 83, 82 and 75% by weight of gold sold, referenced 1, 2 and 3 respectively comprising nickel and an alloy with 58 , 5% by weight of gold referenced 4. All the percentages are expressed by weight.

In addition to deformability and color, the melting range between solidus and liquidus has been indicated, which should not exceed 150 ° C. The liquidus temperature should not exceed much 900 ° C. In the examples selected, it reaches a maximum of 915 ° C.

2

o> m

Ol o

o co en

G5 O

ro en

N> o

No.

Composition (%) Ag

Pd Ni

Mn

Cu

Zn

Other

Melting interval

Distorted.

Color L *

at *

b *

No.

1

83

11

6

860-890

Average

1

2

82

12

6 In

780-855

Average

2

3

75

5.2

4.8

1.5

3.5

10 Cd

715-775

Low

3

AT

75

10

3

2

8

2 Ga

650-780

Average

88

-0.5

13

AT

B

75

10

3

2

10

750-810

Average

88.5

-1

14.5

B

VS

75

5

15

5 Ga

675-810

Average

85

1

13

VS

D

75

5

13

2

5 Ga

720-795

Average

D

E

75

2

5

11

2

5 Ga

635-785

Average

E

F

75

10

5

2

8

795-870

Good

87

0

11.5

F

G

75

8

2

5

2

8

815-880

Good

86

0.5

11.5

G

H

75

8

3

5

2

7

840-915

Good

85.5

0.5

11

H

I

75

13

5

3

4

845-910

Good

87.5

0

12

I

4

58.5

16

7

3.5

15

715-730

Low

84.8

-1.3

10.6

4

J

58.5

19.5

3

4

15

700-720

Low

80.8

1.4

9.1

J

K

58.5

22.5

5

4

10

759-802

Average

87.3

-1

13.2

K

L

58.5

24.5

5

2

10

759-809

Average

87.6

-0.9

11.9

L

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CH 686 136 A5

None of the 18 or 14 carat examples according to the invention designated A-1 respectively J-L contains nickel, this is replaced by manganese. Two of the examples contain 2 and 3% Pd, but this increases the temperature of the liquidus. The metals used to lower this temperature are mainly Zn, sometimes Ga, or a combination of the two. Although the examples in the table do not mention it, one could also use In alone, or in combination with Zn or Ga or even with both, In also serving to lower the temperature of the liquidus.

It is found that even if the proportions of Mn used 3-5% in the examples are relatively low, the colorimetric values L, a, b are good. In all cases, the L is high between 80.8 and 88.5, the value of a is close to 0 and there is a slight tendency to yellow (between 9.1 and 14.5), this tendency remaining tolerable for brazing since the upper limit is very little higher than most gray gold alloys. The deformability properties are equivalent to or greater than those of the references, the liquidus-solidus differences not exceeding 150 ° C. and for the most part less than 100 ° C.

Besides the use in jewelry, the alloy object of the invention can be used for the brazing of dental prostheses. In fact, the absence of Ni makes this alloy suitable for such use, which the gray gold solders known up to now did not allow.

Claims (4)

Claims 1. Gray gold alloy for brazing, characterized in that it comprises the following proportions expressed by weight: 58-80% Au, 2-6% Mn, 4-15% of at least one of the elements Zn, Ga , In, 2-6% Cu and 0-25% Ag, the difference between liquidus and solidus being 150 ° C maximum, the liquidus being maximum 915 ° C. 2. Gray gold alloy according to claim 1, characterized in that it comprises by weight: 67-76% Au, 3-5% Mn, 4-10% of at least one of the elements Zn, Ga with 5 maximum% of Ga, 7-15% Ag and 2-4% Cu. 3. Gray gold alloy according to claim 1, characterized in that it comprises by weight 58-67% Au, 3-5% Mn, 10-15% Zn, 19-25% Ag and 2-4% Cu . 4. Gray gold alloy according to one of claims 1 to 3, characterized in that it additionally contains at most 3% by weight of Pd. 4