US2134423A - Alloy - Google Patents
Alloy Download PDFInfo
- Publication number
- US2134423A US2134423A US58163A US5816336A US2134423A US 2134423 A US2134423 A US 2134423A US 58163 A US58163 A US 58163A US 5816336 A US5816336 A US 5816336A US 2134423 A US2134423 A US 2134423A
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- US
- United States
- Prior art keywords
- alloy
- nickel
- chromium
- alloys
- cobalt
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Classifications
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- C—CHEMISTRY; METALLURGY
- C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
- C22C—ALLOYS
- C22C19/00—Alloys based on nickel or cobalt
- C22C19/03—Alloys based on nickel or cobalt based on nickel
- C22C19/05—Alloys based on nickel or cobalt based on nickel with chromium
- C22C19/051—Alloys based on nickel or cobalt based on nickel with chromium and Mo or W
- C22C19/053—Alloys based on nickel or cobalt based on nickel with chromium and Mo or W with the maximum Cr content being at least 30% but less than 40%
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61K—PREPARATIONS FOR MEDICAL, DENTAL OR TOILETRY PURPOSES
- A61K6/00—Preparations for dentistry
- A61K6/80—Preparations for artificial teeth, for filling teeth or for capping teeth
- A61K6/84—Preparations for artificial teeth, for filling teeth or for capping teeth comprising metals or alloys
Definitions
- My invention relates to alloys and particularly to alloys having especially high resistance to attack by various corrosive media. It also relates to alloys particularly adapted for making prosthetic articles such, for example, as dentures.
- lactic acid is formed in the mouth, and recent investigations have shown that individuals whose teeth are subject to rapid decay and who by reason of this fact must provide a themselves with artificial teeth generate lactic acid to a greater extent than do individuals whose teeth remain sound for many years. Lactic acid is also present in milk and milk products, and is encountered in fermentation processes involving other substances.
- the base alloy disclosed contains the following ingredients:
- my base alloy may contain the following ingredients Ni 20% to under 50% Cr 20% to 33% Go from 20% to 50% i
- the following examples of my composition are fllustrative of my invention.
- MnTi indicates manganesetitanium containing 30% of titanium, while CuBe is copper-beryllium containing 80% of beryllium.
- tungsten and beryllium when added alone or in combination to the base alloy exert a deleterious influence upon its resistance to the lactic acid test.
- the effect of beryllium in this respect can be overcome by incorporating molybdenum in the base alloy within the limits above-set forth but this is not true of tungsten.
- Other elements such as the copper, manganese, titanium and silicon also lower the general resistance to corrosion when molybdenum is not present. This is substantiated by lactic acid tests, as above described, on specimens 31, 3,3, 51, 5'! and "65. Specimens 31, 51 and 65 corroded in 1 hours. Specimen 33 corroded in 19 hours while specimen 57 which is the base alloy withstood: the test for 72 hours without discoloring, indicating that the base alloy itself has extremely high resistance to attack.
- specimen No. 58 was tested in a tincture of iodine solution using a "Nichrome specimen containing 80% of nickel and 2.0% of chromium as a control. The nichrome was badly attacked in two days and the iodine solution in which it was submerged had decomposed, but specimen 58 was not visibly attacked.
- Specimens 57 and 58 were immersed in phosphoric acid at a temperature of 212 F. for 8 hours without attack. In boiling" phosphoric acid both specimens were attacked, but specimen 58 showed the best resistance to this medi- A solution of ammonium poly-sulphite (NI-10x8 is recommended by the Bureau of Standards as a proper test for the inertness of nickel alloys. Specimens Nos. 25 and 33 when I subjected to the fumes of this solution were not Percent Percent Percent Percent Percent Percent Percent Percent Percent Percent Percent Percent 5 Ni Co Cr Mo MnTi Bi Be W CuBe 85. 8 29. 3 27. 9 4 2. l. 0 85. 4 29. 0 27. 6 6 2. 0 1.0 81.
- Ni 38% Co 32% Cr 26% Mo 4% in a hot 20% salt spray for 30 hours showed that the steel became appreciably coated with rust while my alloy maintained its initially bright appearance and was not visibly affected in any way.
- molybdenum is a desirable element because it lowers the melting point of the alloy, increases its fluidity at casting temperatures and improves the melting characteristics in general.
- the casting includes attenuated portions such as in dental bridgework, the addition of small quantitles of manganese-titanium as a deoxidizer and denitrifler will be found advantageous.
- manganese-titanium aids in keeping the alloy clean upon recasting.
- smallportions of calcium about 0.1%, may be added to the melt before casting to further deoxidize the metal.
- My alloy is easy to form and cast, has a tensile strength greater than the ordinary nichrome alloys, is quite ductile and yet its yield point is sufllciently high so that in use as a denture it successfully resists the normal forces tending to cause deformation. Its hardness reaches a greater degree than that of nichrome alloys of the ordinary form containing about 80% nickel. The hardness varies from about C- to C-25 on the Rockwell scale which places it intermediate in hardness between the ordinary casting gold used in making dentures and alloys of the cobaltchromium type such as are used for this purpose.
- This intermediate hardness gives it a particularly desirable position as a sort of compromise between quite soft and very hard alloys and so is most satisfactory to the majority of dentists who desire an alloy which, while having the most desirable properties, is of suiilcient ductility to allow desired adjustments upon partially finished dentures without danger of breaking by reason mas 0! too great brittleness which usually accompanies excessive hardness.
- My alloys are, generally speaking, malleable, iorgeable and otherwise workable. Where an especlally easily workable alloy is desired, it will be found advisable to keep the chromium below and the molybdenum under 6%.
- the cobalt is present in the higher portions of its range when the nickel is present in its lower portions and vice versa, and the total of the chromium, nickel and cobalt will be between and substantially of the total alloy. This allows permissible additions of molybdenum in the quantities above set forth plus small additions of other elements which do not substantially deleteriously eifect the resistance of the alloy to the corrosive attack of acids.
- the composidenum For example, with the chromium, nickel and cobalt totaling substantially 100% the composidenum, are added for the purpose of enhancing certain characteristics it will generally be found advisable to add molybdenum also in a suiilcient quantity to offset the reduction in corrosion resistance which would otherwise be occasioned by adding such elements alone.
Description
Patented Oct. 25, 1938 UNITED STATES PATENT OFFICE ALLOY Enrique a. ToucodahAlbany, N. 1., alsignor to Consolidated Careating Company, Inc., Albany, N. 1., a corporation of New York No Drawing. Application January 8 1986,
, Serial No. sales 2 Claims. (01. us-n1) My invention relates to alloys and particularly to alloys having especially high resistance to attack by various corrosive media. It also relates to alloys particularly adapted for making prosthetic articles such, for example, as dentures.
so far as I am aware there are no commercial alloys at present available which are not subject to attack by lactic acid.
Chrome-nickel steels of the so-called 18-8 type,
10 for example, while highly resistant to atmospheric corrosion and to various other media are easily corroded by lactic acid, as are also the high nickel-chromium alloys of the so-called Nichrome type, and the high cobalt-chromium alloys of the so-called "Stellite type.
It is well known that lactic acid is formed in the mouth, and recent investigations have shown that individuals whose teeth are subject to rapid decay and who by reason of this fact must provide a themselves with artificial teeth generate lactic acid to a greater extent than do individuals whose teeth remain sound for many years. Lactic acid is also present in milk and milk products, and is encountered in fermentation processes involving other substances.
Hence, it is particularly desirable that alloys to be used in the manufacture of dentures, and
in apparatus and equipment for use in the dairy-.- ing, ice cream, brewing. pasteurizing and other industries should be as resistant as possible to the corrosive influences of this acid. In many of these industries the alloy should be capable of satisfactorily withstanding attack by lactic acid at comporatively high temperatures such as those 85 encountered in pasteurizing, sterilizing, etc., as
well as at normal atmospheric temperatures.
In my copending application Serial No. 738,816 filed August 7, 1934, of which this application is a continuation in part, I have disclosed a base alloy comprising nickel, chromium and cobalt to which minor quantities of molybdenum. titanium and silicon may be added and which exhibits remarkable resistance to attack when submerged for long periods in a 12% solution of lactic acid in temperatures of the order of F, to F,
In that application the base alloy disclosed contains the following ingredients:
Ni 82% 1704070 Cr2'7% to 35% C0 24% to 30% This base alloy in and of itself, as pointed out '7 the corrosion resistant characteristics of the composition, but a molybdenum content in excess of about 7% or 8% markedly decreases the workability of the alloy and it approaches the class of alloys adapted for high speed tools. Particularly where small quantities of other elements are present such as silicon, manganese, titanium or beryllium, which may be added to enhance certain characteristics of the alloy, such as its hardness, fluidity, etc., molybdenum within the preferred ranges stated above seems to offset the I marked reduction in corrosion resistance of the alloy which follows the addition of these elements alone or in combination. Experiments have shown that slightly lower percentages of chromium, lower percentages of nickel, and both lower and higher percentages of cobaltmay be advantageously employed than are disclosed in my said copending application provided, certain preferred ratios between the nickel and the cobalt and between the total of the nickel and cobalt and the chromium are maintained. In other words, my base alloy may contain the following ingredients Ni 20% to under 50% Cr 20% to 33% Go from 20% to 50% i The following examples of my composition are fllustrative of my invention.
discolored. Nichrome, however, was discolored in two days.
In the above table MnTi indicates manganesetitanium containing 30% of titanium, while CuBe is copper-beryllium containing 80% of beryllium.
Highly polished specimens of all of these compositions were tested by immersion in a 12% lactic acid solution maintained at a temperature of from 180 F. to 190 F. In addition, stainless steel containing 18% of chromium and 8% of nickel, Nichrome containing 80% of nickel and 20% of chromium and "Stellite containing 69.3% of cobalt and 29.7% of chromium and 1% of copper-beryllium were subjected to the same test for comparative purposes.
At the end of 200 hours, specimens Nos. 21, 25, 2'7, 58, 60, 61, 62, 63 and 64 of my alloy were not discolored. The nichrome and stellite compositions were badly corroded in 1 hours, and the solution containing the stainless steel was badly discolored in '7 hours, indicating that the alloy had been attacked.
Certain elements, such as tungsten and beryllium when added alone or in combination to the base alloy exert a deleterious influence upon its resistance to the lactic acid test. The effect of beryllium in this respect can be overcome by incorporating molybdenum in the base alloy within the limits above-set forth but this is not true of tungsten. Other elements such as the copper, manganese, titanium and silicon also lower the general resistance to corrosion when molybdenum is not present. This is substantiated by lactic acid tests, as above described, on specimens 31, 3,3, 51, 5'! and "65. Specimens 31, 51 and 65 corroded in 1 hours. Specimen 33 corroded in 19 hours while specimen 57 which is the base alloy withstood: the test for 72 hours without discoloring, indicating that the base alloy itself has extremely high resistance to attack.
As an example of the corrosion resistant characteristics of my alloy when subjected to other media, specimen No. 58 was tested in a tincture of iodine solution using a "Nichrome specimen containing 80% of nickel and 2.0% of chromium as a control. The nichrome was badly attacked in two days and the iodine solution in which it was submerged had decomposed, but specimen 58 was not visibly attacked.
Specimens 57 and 58 were immersed in phosphoric acid at a temperature of 212 F. for 8 hours without attack. In boiling" phosphoric acid both specimens were attacked, but specimen 58 showed the best resistance to this medi- A solution of ammonium poly-sulphite (NI-10x8 is recommended by the Bureau of Standards as a proper test for the inertness of nickel alloys. Specimens Nos. 25 and 33 when I subjected to the fumes of this solution were not Percent Percent Percent Percent Percent Percent Percent Percent Percent 5 Ni Co Cr Mo MnTi Bi Be W CuBe 85. 8 29. 3 27. 9 4 2. l. 0 85. 4 29. 0 27. 6 6 2. 0 1.0 81. 7 26. 9 24. 7 16 2.0 l. 0 37. 2 80. 6 29.2 2. 0 1. 0 88. 0 29. 3 27. 9 6 88. l 81. 2 29. 7 38. 3i. 5 30. 0 30. 2 29. 6 28. 2 6 ll. 0 45. 8 27. 9 6 0.8 34. 8 28. 4 27. 0 9 0. 8 33. 7 27. 4 28.1 -12 0.8 88. 4 27. 2 32. 6 6 0. 8 20.0 40.6 32.6 0 0.8
Ni 38% Co 32% Cr 26% Mo 4% in a hot 20% salt spray for 30 hours showed that the steel became appreciably coated with rust while my alloy maintained its initially bright appearance and was not visibly affected in any way.
All of my alloys are characterized by extremely high resistance to lactic acid and to the corrosive action of most other media, but changes in the proportions of the ingredients or the addition of other elements may somewhat afiect the corrosion'resistance as against these other media. For example, specimen 25 is attacked by a 20% sulphuric acid solution at 212 F., and by a boiling solution of caustic soda, while specimen 33 is not. On the other hand, specimen 25 is more resistant to lactic acid than specimen 33.
For certain specific uses such as casting, molybdenum is a desirable element because it lowers the melting point of the alloy, increases its fluidity at casting temperatures and improves the melting characteristics in general. Where the casting includes attenuated portions such as in dental bridgework, the addition of small quantitles of manganese-titanium as a deoxidizer and denitrifler will be found advantageous. The
manganese-titanium aids in keeping the alloy clean upon recasting. In some cases. if desired; smallportions of calcium, about 0.1%, may be added to the melt before casting to further deoxidize the metal.
My alloy is easy to form and cast, has a tensile strength greater than the ordinary nichrome alloys, is quite ductile and yet its yield point is sufllciently high so that in use as a denture it successfully resists the normal forces tending to cause deformation. Its hardness reaches a greater degree than that of nichrome alloys of the ordinary form containing about 80% nickel. The hardness varies from about C- to C-25 on the Rockwell scale which places it intermediate in hardness between the ordinary casting gold used in making dentures and alloys of the cobaltchromium type such as are used for this purpose. This intermediate hardness gives it a particularly desirable position as a sort of compromise between quite soft and very hard alloys and so is most satisfactory to the majority of dentists who desire an alloy which, while having the most desirable properties, is of suiilcient ductility to allow desired adjustments upon partially finished dentures without danger of breaking by reason mamas 0! too great brittleness which usually accompanies excessive hardness.
My alloys are, generally speaking, malleable, iorgeable and otherwise workable. Where an especlally easily workable alloy is desired, it will be found advisable to keep the chromium below and the molybdenum under 6%.
It is to be understood that the percentages of the various elements stated above are percentages by weight of the total alloy.
In general, the cobalt is present in the higher portions of its range when the nickel is present in its lower portions and vice versa, and the total of the chromium, nickel and cobalt will be between and substantially of the total alloy. This allows permissible additions of molybdenum in the quantities above set forth plus small additions of other elements which do not substantially deleteriously eifect the resistance of the alloy to the corrosive attack of acids.
For example, with the chromium, nickel and cobalt totaling substantially 100% the composidenum, are added for the purpose of enhancing certain characteristics it will generally be found advisable to add molybdenum also in a suiilcient quantity to offset the reduction in corrosion resistance which would otherwise be occasioned by adding such elements alone.
While my invention is in no sense limited to chromium, cobalt and nickel in the following ratios as will be apparent from a consideration of the examples given above, very excellent results are obtained if the ratio of the nickel to the cobalt is between about 0.45 and 1.25 and the ratio of the sum of the nickel and the cobalt to the chromium is between about 1.85 and 2.35.
What I claim is:
1. An alloy consisting of 32% to 40% nickel; 20% to 33% of chromium; andfrom 24% to 30% of cobalt.
2. A denture formed of the alloy of claim 1.
ENRIQUE G. 'I'OUCEDA.
Priority Applications (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US58163A US2134423A (en) | 1936-01-08 | 1936-01-08 | Alloy |
US120549A US2103500A (en) | 1936-01-08 | 1937-01-14 | Alloy |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US58163A US2134423A (en) | 1936-01-08 | 1936-01-08 | Alloy |
Publications (1)
Publication Number | Publication Date |
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US2134423A true US2134423A (en) | 1938-10-25 |
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US58163A Expired - Lifetime US2134423A (en) | 1936-01-08 | 1936-01-08 | Alloy |
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3356542A (en) * | 1967-04-10 | 1967-12-05 | Du Pont | Cobalt-nickel base alloys containing chromium and molybdenum |
US3837838A (en) * | 1972-12-18 | 1974-09-24 | M Mohammed | High strength, ductile cobalt-base dental alloy |
US4088479A (en) * | 1976-01-16 | 1978-05-09 | Westinghouse Electric Corp. | Hot corrosion resistant fabricable alloy |
US4461618A (en) * | 1982-01-25 | 1984-07-24 | Johnson & Johnson Dental Products Company | Process for producing a dental restoration |
-
1936
- 1936-01-08 US US58163A patent/US2134423A/en not_active Expired - Lifetime
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3356542A (en) * | 1967-04-10 | 1967-12-05 | Du Pont | Cobalt-nickel base alloys containing chromium and molybdenum |
US3837838A (en) * | 1972-12-18 | 1974-09-24 | M Mohammed | High strength, ductile cobalt-base dental alloy |
US4088479A (en) * | 1976-01-16 | 1978-05-09 | Westinghouse Electric Corp. | Hot corrosion resistant fabricable alloy |
US4461618A (en) * | 1982-01-25 | 1984-07-24 | Johnson & Johnson Dental Products Company | Process for producing a dental restoration |
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