US3137571A - Palladium base alloy and method of producing same - Google Patents

Palladium base alloy and method of producing same Download PDF

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Publication number
US3137571A
US3137571A US170223A US17022362A US3137571A US 3137571 A US3137571 A US 3137571A US 170223 A US170223 A US 170223A US 17022362 A US17022362 A US 17022362A US 3137571 A US3137571 A US 3137571A
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Prior art keywords
palladium
gallium
alloys
base alloy
alloy
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US170223A
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Cooper Irving
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Joseph B Cooper & Sons Inc
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Joseph B Cooper & Sons Inc
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    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C5/00Alloys based on noble metals
    • C22C5/04Alloys based on a platinum group metal

Definitions

  • Alloys of metals of the platinum group with baser metals have been employed commercially for many years in applications such as electrical and switch contacts, electrical conductors, resistance Wire, and the like, where high electrical and thermal conductivity, resistance to heat and corrosion, ductility, and tensile strength are of importance.
  • metals as platinum, palladium, rhodium and iridium have been alloyed with silver, nickel, copper and zinc.
  • a known alloy of platinum containing about 8% tungsten is extensively used for the production of electronic components, for example as a wire contact member in diodes. This alloy has disadvantages which include a Rockwell hardness of only about 22, and a fairly low resistance to flexing or bending, frequently breaking when first sharply bent. Alloys of palladium and zinc have been proposed for telephone circuitry, but the preparation of these alloys offers some difficulty in that it involves diffusion of the zinc into the palladium at high temperatures.
  • new and useful alloys have been prepared from palladium and gallium which possess outstanding properties of resilience, hardness and resistance to fatigue.
  • These novel alloys comprise palladium containing from about /2% to about 15% by weight of gallium.
  • the new alloys of the invention are useful as electrical contact elements, for example with silicon diodes.
  • An alloy containing about /z% to 2 /z% and preferably about 1% to 2% gallium has proved especially useful for diodes as a substitute forgold bonded diodes.
  • They can readily be manufactured in any form, shape or thickness, as for example, in the form of sheets or wires of any desired gauge. Their resilience renders them suitable for use for small springs for watches and scientific instruments.
  • the resistivity of the alloys makes them especially valuable in potentiometers.
  • the alloys of palladium and gallium are prepared simply and directly by heating together palladium metal in the form of strip or wire and the required quantity of gallium metal at a temperature slightly above the melting point of the palladium until the molten mass has become homogeneous. The mass is allowed to cool and can be fabricated into any desired shape.
  • the novel alloys of the invention can be heat treated.
  • the starting materials are palladium, preferably of pure grade (99.9%), having a melting point about 1554 C., and a specific gravity of 12.0, and gallium metal.
  • the gallium is a silvery-white metal, having a melting point of 29.7 C., and hence generally liquid at ordinary temperatures, and having a boiling point of 1983 C. Its specific gravity is 5.9 (solid).
  • the palladium-gallium alloys of the invention have a silvery-white appearance, and a melting point slightly below that of palladium.
  • the specific gravity is about 11.15.
  • Example 92 grams of palladium wire were heated together with 8 grams gallium in a crucible placed in an electric furnace until the palladium had completely melted, the temperature then being 2831 F., and the mass had become homogeneous.
  • the molten alloy was allowed to cool, removed from the crucible, and formed into ribbon. If desired, the alloying can be conducted under an atmosphere of an inert gas, such as nitrogen.
  • the resulting alloy was silvery-white in appearance, and had a specific gravity of 11.15. It possessed a tensile strength of about 200,000 pounds per square inch, and a hardness on the Rockwell C scale of 36.
  • the alloy had an electrical resistance of 250 ohms per circular mil foot. It is very ductile and can readily be rolled into wire or flat ribbon.
  • the electrical resistance properties of the alloys of the invention have been found to be a function of the amount of gallium present, higher percentages of gallium imparting higher resistance and vice versa.
  • a palladium base alloy consisting essentially of from about /2% to about 2 /2% by Weight of gallium, the remainder of the alloy being palladium.
  • a palladium base alloy consisting essentially of v 0 base alloy consisting essentially of 98% to 99% palladium and 2% to 1% gallium by weight.

Description

United States Patent 3,137,571 PALLABIUM BASE ALLOY AND METHGB 0F PRCDUCING SAME Irving Cooper, Brookl N.Y., assignor to Joseph E. Cooper 8; Sons Inc., New York, N.Y., a corporation of New York No Drawing. Filed Jan, 31, 1962, Ser. No. 170,223 8 Claims. (Ci. 75--1'72) This invention relates to novel alloys of palladium and gallium, and to a method for their production. More particularly, the invention concerns palladium base alloys containing from about /2% to about 15% by Weight of gallium.
Alloys of metals of the platinum group with baser metals have been employed commercially for many years in applications such as electrical and switch contacts, electrical conductors, resistance Wire, and the like, where high electrical and thermal conductivity, resistance to heat and corrosion, ductility, and tensile strength are of importance. Thus, such metals as platinum, palladium, rhodium and iridium have been alloyed with silver, nickel, copper and zinc. A known alloy of platinum containing about 8% tungsten is extensively used for the production of electronic components, for example as a wire contact member in diodes. This alloy has disadvantages which include a Rockwell hardness of only about 22, and a fairly low resistance to flexing or bending, frequently breaking when first sharply bent. Alloys of palladium and zinc have been proposed for telephone circuitry, but the preparation of these alloys offers some difficulty in that it involves diffusion of the zinc into the palladium at high temperatures.
In accordance with the present invention, new and useful alloys have been prepared from palladium and gallium which possess outstanding properties of resilience, hardness and resistance to fatigue. These novel alloys comprise palladium containing from about /2% to about 15% by weight of gallium.
The new alloys of the invention are useful as electrical contact elements, for example with silicon diodes. An alloy containing about /z% to 2 /z% and preferably about 1% to 2% gallium has proved especially useful for diodes as a substitute forgold bonded diodes. They can readily be manufactured in any form, shape or thickness, as for example, in the form of sheets or wires of any desired gauge. Their resilience renders them suitable for use for small springs for watches and scientific instruments. The resistivity of the alloys makes them especially valuable in potentiometers.
The alloys of palladium and gallium are prepared simply and directly by heating together palladium metal in the form of strip or wire and the required quantity of gallium metal at a temperature slightly above the melting point of the palladium until the molten mass has become homogeneous. The mass is allowed to cool and can be fabricated into any desired shape. The novel alloys of the invention can be heat treated.
The starting materials are palladium, preferably of pure grade (99.9%), having a melting point about 1554 C., and a specific gravity of 12.0, and gallium metal. The gallium is a silvery-white metal, having a melting point of 29.7 C., and hence generally liquid at ordinary temperatures, and having a boiling point of 1983 C. Its specific gravity is 5.9 (solid).
The palladium-gallium alloys of the invention have a silvery-white appearance, and a melting point slightly below that of palladium. The specific gravity is about 11.15.
3,137,571 Patented June 16, teen The preparation and properties of the novel palladiumgalliurn alloys of the invention as a class are illustrated by one preferred embodiment of the invention, which is a ribbon alloy of palladium containing 8% gallium by weight, and are set forth in the following example.
Example 92 grams of palladium wire were heated together with 8 grams gallium in a crucible placed in an electric furnace until the palladium had completely melted, the temperature then being 2831 F., and the mass had become homogeneous. The molten alloy was allowed to cool, removed from the crucible, and formed into ribbon. If desired, the alloying can be conducted under an atmosphere of an inert gas, such as nitrogen.
The resulting alloy was silvery-white in appearance, and had a specific gravity of 11.15. It possessed a tensile strength of about 200,000 pounds per square inch, and a hardness on the Rockwell C scale of 36.
The alloy had an electrical resistance of 250 ohms per circular mil foot. It is very ductile and can readily be rolled into wire or flat ribbon.
The electrical resistance properties of the alloys of the invention have been found to be a function of the amount of gallium present, higher percentages of gallium imparting higher resistance and vice versa. When rolled into ribbon of widths ranging from 0.015 to 0.0700 inch and thickness ranging from 0.002 to 0.0095 inch, they provide an electrical contact member which is especially effective and economical in connection with diodes.
The following is data on the various percentages of gallium alloyed with palladium.
Resistance,
Hardness ohms/c.m.f. 7
Pure Palladium 1R0ckwell B.
22-Rockwell B." 56Rockwell B. 4Rockwell O. 35Rockwel1 C. 45-Rockwell "0.
15% Gallium from about /2% to about 15% by weight of gallium, the
remainder of the alloy being palladium.
3. A palladium base alloy consisting essentially of from about /2% to about 2 /2% by Weight of gallium, the remainder of the alloy being palladium.
4. A palladium base alloy consisting essentially of v 0 base alloy consisting essentially of 98% to 99% palladium and 2% to 1% gallium by weight.
References Cited in the file of this patent Hansen: Constitution of Binary Alloys, 1958, McGraw-, Hill Book Company, Inc., New York, page 752.

Claims (1)

1. A PALLADIUM BASE ALLOY CONSISTING ESSENTIALLY OF FROM ABOUT 1/2% TO ABOUT 15% BY WEIGHT OF GALLIUM.
US170223A 1962-01-31 1962-01-31 Palladium base alloy and method of producing same Expired - Lifetime US3137571A (en)

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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4179288A (en) * 1979-01-24 1979-12-18 Neoloy Products, Inc. Palladium base dental alloy
US5174954A (en) * 1991-03-01 1992-12-29 Ivoclar N.A. Palladium alloys for dental implant restorations
US11318446B2 (en) * 2020-05-28 2022-05-03 Taizhou University Activated carbon/Pd-Ga liquid alloy composite catalyst, preparation method and use thereof
EP4074435A3 (en) * 2021-02-26 2022-12-21 C. Hafner GmbH + Co. KG Powder made of spherical particles of a noble metal alloy containing platinum or palladium, use of this powder in a powder-based production method for producing a three-dimensional object, and an additive method for producing a three-dimensional object using the aforementioned powder

Non-Patent Citations (1)

* Cited by examiner, † Cited by third party
Title
None *

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4179288A (en) * 1979-01-24 1979-12-18 Neoloy Products, Inc. Palladium base dental alloy
US5174954A (en) * 1991-03-01 1992-12-29 Ivoclar N.A. Palladium alloys for dental implant restorations
US11318446B2 (en) * 2020-05-28 2022-05-03 Taizhou University Activated carbon/Pd-Ga liquid alloy composite catalyst, preparation method and use thereof
EP4074435A3 (en) * 2021-02-26 2022-12-21 C. Hafner GmbH + Co. KG Powder made of spherical particles of a noble metal alloy containing platinum or palladium, use of this powder in a powder-based production method for producing a three-dimensional object, and an additive method for producing a three-dimensional object using the aforementioned powder

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