US2072368A - Tungsten-base alloy for points of gold nibs - Google Patents

Tungsten-base alloy for points of gold nibs Download PDF

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Publication number
US2072368A
US2072368A US105A US10535A US2072368A US 2072368 A US2072368 A US 2072368A US 105 A US105 A US 105A US 10535 A US10535 A US 10535A US 2072368 A US2072368 A US 2072368A
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United States
Prior art keywords
alloys
tungsten
points
alloy
nibs
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Expired - Lifetime
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US105A
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Jedele Alfred
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WC Heraus GmbH and Co KG
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WC Heraus GmbH and Co KG
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Priority to US102817A priority Critical patent/US2074474A/en
Priority to US102818A priority patent/US2072676A/en
Application granted granted Critical
Publication of US2072368A publication Critical patent/US2072368A/en
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Expired - Lifetime legal-status Critical Current

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    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C27/00Alloys based on rhenium or a refractory metal not mentioned in groups C22C14/00 or C22C16/00
    • C22C27/04Alloys based on tungsten or molybdenum

Definitions

  • My invention relates to alloys for the points of gold nibs.
  • I compound my novel alloy of tungsten as the base to which are added a metal of the iron group, i. e., iron, nickel, or cobalt, a soft metal of the platinum group, i. e., platinum or palladium, and a hard metal of the same 8 group, i. e., osmium, ruthenium, rhodium, or iridium.
  • a metal of the iron group i. e., iron, nickel, or cobalt
  • a soft metal of the platinum group i. e., platinum or palladium
  • a hard metal of the same 8 group i. e., osmium, ruthenium, rhodium, or iridium.
  • the percentage of the soft metal should be higher than that of the hard metal.
  • the base of the alloy is tungsten, at the rate of 65 to 80% of the alloy. However, up to of the tungsten may be replaced by molybdenum. or tantalum, or by carbides of these metals.
  • metals of the iron group i. e., iron, nickel, or cobalt, at the rate of 5 to 20%. Iron and nickel are less efficient than cobalt, so that cobalt is normally preferred.
  • the novel feature of my alloys is that their 50 content of precious metals consists for the major part, preferably at the rate of 8 to 20%, of soft metals of the platinum group, i. e., platinum or palladium, and for the minor part, preferably at the rate of 2 to 10%, of hard metals of the is same group, i. e., osmium, or other hard metals.
  • Ruthenium is particularly suitable as a constituent of my alloys, but rhodium and iridium may also be used.
  • My alloys may be prepared uniformly in any suitable manner, for instance, in electric are or 5 high-frequency-induction furnaces, preferably with inserted crucibles.
  • the tenacity of alloys is ascertained by placing a particle of the alloy whose diameter may be 1.3 millimetres, between a pair of jaws, and compressing it until it is crushed.
  • the crushing strength is determined by the tenacity, and not by the hardness, of the alloy under test. It amounts to only a few kilogrammes in brittle alloys, but may be 50 kilogrammes, and more, for tenacious alloys.
  • Table I shows the crushing strengths of five alloys according to my invention and Table II, by way of comparison, shows the crushing strengths of four commercial alloys for the same purpose. It will appear that while the crushing strengths of my novel alloys range from 48.4 to '70 kilogrammes, those of the commercial alloys only range from 5.8 to 29.3 kilogrammes.
  • %% ass contain osmium as the hard metal, as demonstrated by the maximum crushing strength of alloy No. 3.
  • My novel alloys have the further good property that they can be welded to the nibs on account their content of cobalt, while, as known, pure tungsten and many alloys oi tungsten, molybdenum, and metals of the platinum group, cannot be welded directly to gold nibs.
  • An alloy for points of gold nibs consisting of 65% of tungsten, 10% of cobalt, 20% of platinum. and 5% of osmium.
  • An alloy for points of gold nibs consisting of 80% ot tungsten, of cobalt, 8% of platinum, and 2% of iridium.
  • An alloy for points of gold nibs consistinfl of from 65% to 80% oi! tungsten, from 5% to of a metal of the iron group, from 2% to 10% 01' osmium, and from 8% to 20% 0t platinum, the amount of the platinum being greater than the amount of the osmium.
  • An alloy for points or gold nibs consisting of from to of tungsten, from 5% to 20% o! a metal of the iron group, from 2% to 10% of a hard metal or the class composed of osmium, ruthenium, rhodium and iridium from the platinum group and from 8% to 20% of a soft metal of the class composed of platinum and palladium from the platinum group, the amount of the soft metal of the platinum group being greater than the amount of the hard metal of the platinum group.

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  • Chemical & Material Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Materials Engineering (AREA)
  • Mechanical Engineering (AREA)
  • Metallurgy (AREA)
  • Organic Chemistry (AREA)
  • Contacts (AREA)

Description

Patented Mar. 2, 1937 UNITED STATES PATENT OFFICE TUNGSTEN-BASE ALLOY FOR POINTS OF GOLD NIBS No Drawing. Application January 2, 1935, Serial No. 105. In Germany June 16, 1932 4 Claims.
My invention relates to alloys for the points of gold nibs.
Many alloys for the purpose specified have already become known. There are tungsten-base alloys whose balance is made up by metals of the platinum group. There are other alloys with a base of platinum-group metals, and up to tungsten, with a. small percentage of nickel or the like. Lastly, there are alloys with iron, cop- 10 per, or nickel as the base, with a small percentage of two metals of the platinum group, and of tungsten.
The many alloys of these types which have become known, are hard and suiliciently acid-proof, 1 so that they do not wear rapidly, and are not attacked by ink. However, they are so brittle that it is diilicult to split the nibs, and this operation must be performed by means of a very thin and rapidly rotating disk of copper moistened with a paste of emery. This is obviously an undesired complication which ought to be eliminated.
It is an object of my invention to provide an alloy for the points of gold nibs which is as hard 2 and acid-proof as the aforesaid known alloys but at the same time possesses a high degree of tenacity so that nibs having points of my novel alloy, can be split simply by means of a blade or shearing device.
To this end, I compound my novel alloy of tungsten as the base to which are added a metal of the iron group, i. e., iron, nickel, or cobalt, a soft metal of the platinum group, i. e., platinum or palladium, and a hard metal of the same 8 group, i. e., osmium, ruthenium, rhodium, or iridium. The percentage of the soft metal should be higher than that of the hard metal.
I have found that the composition of an alloy which can be cut by the aforesaid cutting or 4 shearing means, must fulfill certain conditions. The base of the alloy is tungsten, at the rate of 65 to 80% of the alloy. However, up to of the tungsten may be replaced by molybdenum. or tantalum, or by carbides of these metals. To 4 this base I add metals of the iron group, i. e., iron, nickel, or cobalt, at the rate of 5 to 20%. Iron and nickel are less efficient than cobalt, so that cobalt is normally preferred.
The novel feature of my alloys is that their 50 content of precious metals consists for the major part, preferably at the rate of 8 to 20%, of soft metals of the platinum group, i. e., platinum or palladium, and for the minor part, preferably at the rate of 2 to 10%, of hard metals of the is same group, i. e., osmium, or other hard metals.
Ruthenium is particularly suitable as a constituent of my alloys, but rhodium and iridium may also be used.
My alloys may be prepared uniformly in any suitable manner, for instance, in electric are or 5 high-frequency-induction furnaces, preferably with inserted crucibles.
Heretofore, the soft metals of the platinum group, i, e., platinum and palladium, were not added at comparatively high percentages, as the alloys for the points of nibs became too soft. However,I have established the surprising fact that by adding platinum and a small percentage of osmium to a. base of tungsten with iron, nickel, or cobalt, alloys are obtained whose hardness is equal to that of alloys consisting principally of the said hard metals but whose tenacity is very much superior to that of the aforesaid alloys, and my novel alloys can therefore be cut.
The tenacity of alloys is ascertained by placing a particle of the alloy whose diameter may be 1.3 millimetres, between a pair of jaws, and compressing it until it is crushed. The crushing strength is determined by the tenacity, and not by the hardness, of the alloy under test. It amounts to only a few kilogrammes in brittle alloys, but may be 50 kilogrammes, and more, for tenacious alloys. v
Table I shows the crushing strengths of five alloys according to my invention and Table II, by way of comparison, shows the crushing strengths of four commercial alloys for the same purpose. It will appear that while the crushing strengths of my novel alloys range from 48.4 to '70 kilogrammes, those of the commercial alloys only range from 5.8 to 29.3 kilogrammes.
Table I Platinum Tungstem Hard metal Cobalt Percent Percent Ru. l0 10 48. 4 Os. l0 3 0s. 2 Ir. 2
Percent Fermi;
%% ass contain osmium as the hard metal, as demonstrated by the maximum crushing strength of alloy No. 3.
It ruthenium or rhodium are added which are hard metals similar to osmium, the alloys become less tenacious and softer but still are superior to commercial alloys with respect to their crushing strength.
1 hr crushing strengths oi commercial alloys. see
Comparing Nos. 2 and 9, it will appear that, by converting the percentages 01' soft and hard metals in an alloy of otherwise equal composition, the crushing strength becomes almost twice that of the commercial alloy.
My novel alloys have the further good property that they can be welded to the nibs on account their content of cobalt, while, as known, pure tungsten and many alloys oi tungsten, molybdenum, and metals of the platinum group, cannot be welded directly to gold nibs.
I claim:
1. An alloy for points of gold nibs consisting of 65% of tungsten, 10% of cobalt, 20% of platinum. and 5% of osmium.
2. An alloy for points of gold nibs consisting of 80% ot tungsten, of cobalt, 8% of platinum, and 2% of iridium.
3. An alloy for points of gold nibs consistinfl of from 65% to 80% oi! tungsten, from 5% to of a metal of the iron group, from 2% to 10% 01' osmium, and from 8% to 20% 0t platinum, the amount of the platinum being greater than the amount of the osmium.
4. An alloy for points or gold nibs consisting of from to of tungsten, from 5% to 20% o! a metal of the iron group, from 2% to 10% of a hard metal or the class composed of osmium, ruthenium, rhodium and iridium from the platinum group and from 8% to 20% of a soft metal of the class composed of platinum and palladium from the platinum group, the amount of the soft metal of the platinum group being greater than the amount of the hard metal of the platinum group.
HIRED JEDELE.
US105A 1932-06-16 1935-01-02 Tungsten-base alloy for points of gold nibs Expired - Lifetime US2072368A (en)

Priority Applications (2)

Application Number Priority Date Filing Date Title
US102817A US2074474A (en) 1935-01-02 1936-09-26 Tungsten base alloy for points of gold nibs
US102818A US2072676A (en) 1935-01-02 1936-09-26 Tungsten-base alloy

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DE2072368X 1932-06-16

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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2466992A (en) * 1945-08-30 1949-04-12 Kurtz Jacob Tungsten nickel alloy of high density
US2600995A (en) * 1945-10-30 1952-06-17 Sylvania Electric Prod Tungsten alloy
US3301641A (en) * 1964-01-27 1967-01-31 Mallory & Co Inc P R Tungsten-ruthenium alloy and powdermetallurgical method of making
US3957451A (en) * 1974-08-02 1976-05-18 General Motors Corporation Ruthenium powder metal alloy
US3977841A (en) * 1974-08-02 1976-08-31 General Motors Corporation Ruthenium powder metal alloy and method for making same

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2466992A (en) * 1945-08-30 1949-04-12 Kurtz Jacob Tungsten nickel alloy of high density
US2600995A (en) * 1945-10-30 1952-06-17 Sylvania Electric Prod Tungsten alloy
US3301641A (en) * 1964-01-27 1967-01-31 Mallory & Co Inc P R Tungsten-ruthenium alloy and powdermetallurgical method of making
US3957451A (en) * 1974-08-02 1976-05-18 General Motors Corporation Ruthenium powder metal alloy
US3977841A (en) * 1974-08-02 1976-08-31 General Motors Corporation Ruthenium powder metal alloy and method for making same

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