US2581420A - Alloys - Google Patents

Alloys Download PDF

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Publication number
US2581420A
US2581420A US117510A US11751049A US2581420A US 2581420 A US2581420 A US 2581420A US 117510 A US117510 A US 117510A US 11751049 A US11751049 A US 11751049A US 2581420 A US2581420 A US 2581420A
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percent
alloys
nickel
chromium
iron
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US117510A
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James M Lohr
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Driver Harris Co
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Driver Harris Co
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Priority to US117510A priority Critical patent/US2581420A/en
Priority to US252198A priority patent/US2687954A/en
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    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C19/00Alloys based on nickel or cobalt
    • C22C19/03Alloys based on nickel or cobalt based on nickel
    • C22C19/05Alloys based on nickel or cobalt based on nickel with chromium
    • C22C19/058Alloys based on nickel or cobalt based on nickel with chromium without Mo and W

Definitions

  • This invention relates to alloys and more particularly to alloys for electric resistance units.
  • alloy having the property of resisting oxidation at high temperature is essential.
  • the alloys forming the subject matter oi. this invention are' characterized by ability to resist oxidation and by a prolonged fire, exceeding that of other known-alloys when used under high temperature conditions. Since the introduetionoi nickehchromium-iron alloys'as electricresistance units, many developments have occurred that have improved their resistance to oxidation;- In a numberot-prior patents I have disclosed and claimed various alloying additions or calcium. zirconium and aluminum which greatly improve the liie'o! heatinz elements. It has also been proposed to addrareearth metals.”such as cerium. to'nickel chromium-iron alloys toim prove the liIe oi the heating elements. a
  • the present invention is, therefore, directed to the addition of small quantities of the rare earths with calcium and aluminum to .niclrel-chromium-iron alloys. I have found that such combination oi addition elements greatly increases the period of life 01 nickel-chromium-iron alloys when employed under conditions where they are subjected to high temperatures.
  • the alloys forming the subject matter of the present invention may also contain small amounts of either silicon or manganese or both oi these elements.
  • the rare earth metals may be added as "Misch Metal having an approximate composition of 45 percent cerium, 30 percent lanthanum, percent yttcrbium and didymium. Although it is convenient to add the rare earth metals in the form of "Misch Metal.” i do not restrict myself to the use of this material as one or more of the rare earth metals may be added singly and its efiect is of a similar nature.
  • the additions may be used to advantage with the nickel-chromium-iron alloys of which the best known examples are the alloys of 30 to 0 percent nickel, 10 to percent chromium. balance iron. However, the proportions of these l oys may be varied with the nickel forming a substantial p rt of the alloys.
  • the additions were made to the alloys consisting of substantially percent nickel, 15 percent chromium and balance iron.
  • Rare earth metals. such as Misch Metal. with calcium and alumlnum may be added to such alloys with or without silicon.
  • the proportions oi. nickel in such alloys may vary from 50 to '70 percent and the chromium mm 10 to 20 percent with the balance iron.
  • the quantities or such addition elements are subtracted from the iron content.
  • the dual alloys will contain 50 to '70 percent nickel, 10 to 25 percent chromium, the addition elements calcium, aluminum and the rare earth metals in the percentages hereinaiter stated, and the balance iron. While the proportions of calcium. aluminum and rare earth metals may vary within certain limits, I have found that the best results are obtained when these materials are present in the final alloys within the following limits:
  • alloys contain manganese, silicon, or carbon. they may be present within the following limits:
  • the alloy is produced in the form of a wire, drawn to a diameter of approximately .025" and tested at a temperature of 2050 F.
  • the "useful life" in hours for wire of prior compositions in current production containing .04 percent calcium, .10 percent zirconium and .12 percent aluminum is of the order of 200 hours.
  • the useful life of alloys oi the present invention-according to the above described test is of the order of 500 to 700 hours.
  • the useful life is increased 250 to 300 percent over that of the alloys containing the calcium, zirconium, aluminum group when the rare earth metals are added with calcium and aluminum in the proportions herein stated.
  • the alloys are prepared in the usual manner by placing the ingredients in a bath, heating until the alloying elements become molten and then pouring. In adding rare earth metals to a molten bath, it is necessary to add considerably larger quantities than will be found in the cast metal because they vaporize readily and pass out of the bath. In many instances, with additions of the rare earth metals only a spectrographic trace of one or more of the rare earth metals is found in the cast material. The presence of such traces, however, in combination with calcium and aluminum, greatly increases the oxidation resistance of the alloys.
  • the rare earth metals may be added in amounts sunlcient to leave a residue in the cast alloys up to .2 percent but inmost instances the use of such amounts is not necessary.
  • the invention may be employed in connection with the 3515 alloys in which the alloys contain 30 to 40% nickel, 10 to 25% chromium, and balance iron.
  • the addition elements are present in substantially the same proportions as heretofore stated in connection with the 60-15 alloys, which contain substantially 60% nickel, substantially 10 to chromium, balance iron.
  • a nickel chromium iron alloy consisting essentially of 50 to 70 percent nickel, 10 to percent chromium, .01 to .20 percent calcium, .01 to 1.0 percent aluminum, a trace to .50 percent of a rare earth metal, balance essentially iron.
  • cent chromium substantial .07 perc ggiit alum cent oia rare earth iron.
  • a nickel chromium iron alloy consisting essentially of substantially 00 percent nickel, substantially 15 percent chromium, .01 to .20 percent calcium, .01 to 1.0 percent aluminum, a trace to .50 percent of a rare earth metal, balance essentially iron.
  • a nickel chromium iron alloy consisting essentially of substantially 00 percent nickel. substantially 15 percent chromium, substantially .04 percent calcium, .07 to .40 percent aluminum, a trace to .20 percent of a rare earth metal, balance essentially iron.
  • a nickel chromium iron alloy consisting essentially of 50 to 70 percent nickel, 10 to 25 percent chromium, .01 to .20 percent calcium, .01 to 1.0 percent aluminum. .a trace to .50 percent of cerium and lanthanum, balance essentially iron.
  • a nickel -chromium -iron alloy consisting essentially of substantially percent nickel, substantially 15 percent chromium, .01 to .20 percent calcium, .01 to 1.0 percent aluminum, a trace to .50 percent of cerium and lanthanum, balance essentially iron.
  • a nickel chromium iron alloy consisting essentially of 50 to percent nickel, 10 to 25 percent chromium. substantially .04 percent calcium. .07 to .40 percent aluminum, a trace to .20 percent oi cerium and lanthanum, balance essentially iron.
  • a nickel chromium iron alloy consisting essentially of substantially 60 percent nickel, substantially 15 percent chromium, substantially .04 percent calcium, .O'T'to .ilfpercent aluminum, a trace to .20 percent of cerium and lanthanum, balance essentially iron.

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

Description

Patented Jan. W2
.Z SSIAZU UNITED STATES PATENT OFFICE poration of-New Jersey No Drawing.
Application September 23, 1949,
'SerialNo. 117,510
8 Claims.
This invention relates to alloys and more particularly to alloys for electric resistance units.
In the manufacture 0! electrical resistance units, and alloy having the property of resisting oxidation at high temperature is essential. The alloys forming the subject matter oi. this invention are' characterized by ability to resist oxidation and by a prolonged lire, exceeding that of other known-alloys when used under high temperature conditions. Since the introduetionoi nickehchromium-iron alloys'as electricresistance units, many developments have occurred that have improved their resistance to oxidation;- In a numberot-prior patents I have disclosed and claimed various alloying additions or calcium. zirconium and aluminum which greatly improve the liie'o! heatinz elements. It has also been proposed to addrareearth metals."such as cerium. to'nickel chromium-iron alloys toim prove the liIe oi the heating elements. a
I have found that when calcium and aluminum as well as rare earth metals are'ad'tied to nickelchromlum-iron alloys. better results are obtained than if the calcium, zirconium, aluminum group or the rare earths are used alone. The present invention is, therefore, directed to the addition of small quantities of the rare earths with calcium and aluminum to .niclrel-chromium-iron alloys. I have found that such combination oi addition elements greatly increases the period of life 01 nickel-chromium-iron alloys when employed under conditions where they are subjected to high temperatures. The alloys forming the subject matter of the present invention may also contain small amounts of either silicon or manganese or both oi these elements. The rare earth metals may be added as "Misch Metal having an approximate composition of 45 percent cerium, 30 percent lanthanum, percent yttcrbium and didymium. Although it is convenient to add the rare earth metals in the form of "Misch Metal." i do not restrict myself to the use of this material as one or more of the rare earth metals may be added singly and its efiect is of a similar nature. The additions may be used to advantage with the nickel-chromium-iron alloys of which the best known examples are the alloys of 30 to 0 percent nickel, 10 to percent chromium. balance iron. However, the proportions of these l oys may be varied with the nickel forming a substantial p rt of the alloys. The claims of this application are directed to an alloy containing 50 to '70 percent nickel. Alloys containing from to 50 percent nickel form the subject matter of a divisional application, Serial No, 252,198, filed 2 October 19, 1951. The proportions or these alloys may also be varied with the nickel, however. forming a substantial part 01' the alloys and the nickel-chromium content being such that the alloys have the characteristics of non-ferrous alloys.
In the examples hereinaiter described, the additions were made to the alloys consisting of substantially percent nickel, 15 percent chromium and balance iron. Rare earth metals. such as Misch Metal. with calcium and alumlnummay be added to such alloys with or without silicon. The proportions oi. nickel in such alloys may vary from 50 to '70 percent and the chromium mm 10 to 20 percent with the balance iron. Employing nickel-chromium-iron alloys 01 these proportions, I have added calcium, aluminum and Misch Metal in the quantities or amounts hereinatter mentioned.
In preparing alloys containing the addition 'elc' ments above mentioned. the quantities or such addition elements are subtracted from the iron content. For example, when additions are made to base alloys containing 50 to '10 percent nickel, 10 to 25 percent chromium, the dual alloys will contain 50 to '70 percent nickel, 10 to 25 percent chromium, the addition elements calcium, aluminum and the rare earth metals in the percentages hereinaiter stated, and the balance iron. While the proportions of calcium. aluminum and rare earth metals may vary within certain limits, I have found that the best results are obtained when these materials are present in the final alloys within the following limits:
Calcium Jill-20% Aluminum All-1.0% Rare Earth Metals Trace-0.50%
If the alloys contain manganese, silicon, or carbon. they may be present within the following limits:
Manganese e 02-40% Silicon r-.. 20- Carbon i 0.25% max.
While alloys having the properties desired to a very gh degree are obtained within the limits before mentioned, the preferred range of addition elements is as follows:
Alloys so prepared haye been tested for resistance to oxidation at hifitemperature by the method approyed bythe American society for Testing Materials Accelerated Life. .',l1ect.ior Metallic Materials, B76 39. In conducting such test, the alloy is produced in the form of a wire, drawn to a diameter of approximately .025" and tested at a temperature of 2050 F. The "useful life" in hours for wire of prior compositions in current production containing .04 percent calcium, .10 percent zirconium and .12 percent aluminum is of the order of 200 hours. The useful life of alloys oi the present invention-according to the above described test, is of the order of 500 to 700 hours. Thus, the useful life is increased 250 to 300 percent over that of the alloys containing the calcium, zirconium, aluminum group when the rare earth metals are added with calcium and aluminum in the proportions herein stated.
The alloys are prepared in the usual manner by placing the ingredients in a bath, heating until the alloying elements become molten and then pouring. In adding rare earth metals to a molten bath, it is necessary to add considerably larger quantities than will be found in the cast metal because they vaporize readily and pass out of the bath. In many instances, with additions of the rare earth metals only a spectrographic trace of one or more of the rare earth metals is found in the cast material. The presence of such traces, however, in combination with calcium and aluminum, greatly increases the oxidation resistance of the alloys. The rare earth metals may be added in amounts sunlcient to leave a residue in the cast alloys up to .2 percent but inmost instances the use of such amounts is not necessary.
In the test referred to above the increase of electrical resistance at temperature with time is plotted and an increase 01' percent in resistance is known as the useful life." The life of the tested specimen to burn-out is known as total life.
The invention may be employed in connection with the 3515 alloys in which the alloys contain 30 to 40% nickel, 10 to 25% chromium, and balance iron. The addition elements are present in substantially the same proportions as heretofore stated in connection with the 60-15 alloys, which contain substantially 60% nickel, substantially 10 to chromium, balance iron.
I claim:
1. A nickel chromium iron alloy consisting essentially of 50 to 70 percent nickel, 10 to percent chromium, .01 to .20 percent calcium, .01 to 1.0 percent aluminum, a trace to .50 percent of a rare earth metal, balance essentially iron.
='essentlally of 50 to 70 perceg to 4 B. A nickel chromium iron or consisting C l. 10 to 25 perrcent calcium.
cent chromium, substantial .07 perc ggiit alum cent oia rare earth iron.
3. A nickel chromium iron alloy consisting essentially of substantially 00 percent nickel, substantially 15 percent chromium, .01 to .20 percent calcium, .01 to 1.0 percent aluminum, a trace to .50 percent of a rare earth metal, balance essentially iron.
4. A nickel chromium iron alloy consisting essentially of substantially 00 percent nickel. substantially 15 percent chromium, substantially .04 percent calcium, .07 to .40 percent aluminum, a trace to .20 percent of a rare earth metal, balance essentially iron.
5. A nickel chromium iron alloy consisting essentially of 50 to 70 percent nickel, 10 to 25 percent chromium, .01 to .20 percent calcium, .01 to 1.0 percent aluminum. .a trace to .50 percent of cerium and lanthanum, balance essentially iron.
6. A nickel -chromium -iron alloy consisting essentially of substantially percent nickel, substantially 15 percent chromium, .01 to .20 percent calcium, .01 to 1.0 percent aluminum, a trace to .50 percent of cerium and lanthanum, balance essentially iron.
7. A nickel chromium iron alloy consisting essentially of 50 to percent nickel, 10 to 25 percent chromium. substantially .04 percent calcium. .07 to .40 percent aluminum, a trace to .20 percent oi cerium and lanthanum, balance essentially iron.
8. A nickel chromium iron alloy consisting essentially of substantially 60 percent nickel, substantially 15 percent chromium, substantially .04 percent calcium, .O'T'to .ilfpercent aluminum, a trace to .20 percent of cerium and lanthanum, balance essentially iron.
JAMES M. LOHR.
REFERENCES CITED The following references are of record in the file of this patent:
UNITED STATES PATENTS til?" Date

Claims (1)

1. A NICKEL - CHROMIUM - IRON ALLOY CONSISTING ESSENTIALLY OF 50 TO 70 PERCENT NICKEL, 10 TO 25 PERCENT CHROMIUM, .01 TO .20 PERCERNT CALCIUM, .01 TO 1.0 PERCENT ALUMINUM, A TRACE TO .50 PERCENT OF A RARE EARTH METAL, BALANCE ESSENTIALLY IRON.
US117510A 1949-09-23 1949-09-23 Alloys Expired - Lifetime US2581420A (en)

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Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2687956A (en) * 1951-12-28 1954-08-31 Driver Harris Co Alloy
US2687954A (en) * 1949-09-23 1954-08-31 Driver Harris Co Alloy
US2815283A (en) * 1952-07-17 1957-12-03 Interantional Nickel Company I Nickel chromium alloy and electrical resistance heating elements made thereof
DE1060149B (en) * 1952-07-17 1959-06-25 Mond Nickel Co Ltd Use of a nickel-chromium alloy to produce electrical resistance wires
US4494987A (en) * 1982-04-21 1985-01-22 The United States Of America As Represented By The United States Department Of Energy Precipitation hardening austenitic superalloys
EP0386730A1 (en) * 1989-03-09 1990-09-12 Krupp VDM GmbH Nickel-chromium-iron alloy

Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2005431A (en) * 1934-10-12 1935-06-18 Driver Harris Co Alloy
GB488926A (en) * 1936-04-11 1938-07-12 Heraeus Vacuumschmelze Ag Improvements in and relating to heat resistant alloys and articles comprising the same

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2005431A (en) * 1934-10-12 1935-06-18 Driver Harris Co Alloy
GB488926A (en) * 1936-04-11 1938-07-12 Heraeus Vacuumschmelze Ag Improvements in and relating to heat resistant alloys and articles comprising the same

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2687954A (en) * 1949-09-23 1954-08-31 Driver Harris Co Alloy
US2687956A (en) * 1951-12-28 1954-08-31 Driver Harris Co Alloy
US2815283A (en) * 1952-07-17 1957-12-03 Interantional Nickel Company I Nickel chromium alloy and electrical resistance heating elements made thereof
DE1060149B (en) * 1952-07-17 1959-06-25 Mond Nickel Co Ltd Use of a nickel-chromium alloy to produce electrical resistance wires
US4494987A (en) * 1982-04-21 1985-01-22 The United States Of America As Represented By The United States Department Of Energy Precipitation hardening austenitic superalloys
EP0386730A1 (en) * 1989-03-09 1990-09-12 Krupp VDM GmbH Nickel-chromium-iron alloy

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