US1035947A - Alloy. - Google Patents

Alloy. Download PDF

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Publication number
US1035947A
US1035947A US60791311A US1911607913A US1035947A US 1035947 A US1035947 A US 1035947A US 60791311 A US60791311 A US 60791311A US 1911607913 A US1911607913 A US 1911607913A US 1035947 A US1035947 A US 1035947A
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Prior art keywords
iron
per cent
alloy
taken
aggregate
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US60791311A
Inventor
Robert B Carnahan Jr
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INTERNATIONAL METAL PRODUCTS Co
INTERNAT METAL PRODUCTS Co
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INTERNAT METAL PRODUCTS Co
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Priority to US60791311A priority Critical patent/US1035947A/en
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    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C38/00Ferrous alloys, e.g. steel alloys
    • C22C38/04Ferrous alloys, e.g. steel alloys containing manganese

Definitions

  • the present invention comprehends an iron alloy (by which is meant an alloy containing at least 80 per cent. of iron) slagless and crystalline and deoxidized and degasified, the alloy containing not less than 99.80 per cent. of iron with its alloying metal or metals taken together, and containing not over .14 per cent. of silicon, sulfur, phosphorus, carbon and manganese when taken 1n the aggregate, and containing not over .05 per cent. of oxygen.
  • iron alloy by which is meant an alloy containing at least 80 per cent. of iron
  • the alloy containing not less than 99.80 per cent. of iron with its alloying metal or metals taken together, and containing not over .14 per cent. of silicon, sulfur, phosphorus, carbon and manganese when taken 1n the aggregate, and containing not over .05 per cent. of oxygen.
  • loying metal will of itself be of higher corrosion-resisting quality loyed iron, I am not sure that'this is true in all cases, my intention being, vhowever,
  • the alloy when produced shall have higher. corrosion-resisting qualities than the iron alone even if it should be proved that the alloying metal was of itself of lower corrosion-resistingquality than the iron alone.
  • the improved alloy is to contain not less than 80 per cent. of iron, and not less than 99.80 per cent. of iron and alloying metal or metals taken together. 'As a type of the alloyed iron I. would mention an iron-' While it may be generally true that the althan the unalnickel alloy containing 99.30 per cent. of
  • the improved 1 alloy may be made in a basic open-hearth furnace by refining iron till silicon, sulfur,. phosphorus, carbon and manganese do not exceed .14 per cent. when taken inthe ag gregate; then partially-deoxidizing the bath by the addition of, say, 5 per cent. of pigiron to the bath; then tapping the charge into.
  • a ladle or other receptacle along with a deoxidizing and degasifying agent, say aluminum at the rate of two and one-half pounds per ton; the alloying metal or metals being combined with the'iron either in the furnace orladle, it being essential however that deoxidizing action take place after I the alloying elementhas been incorporated with the iron, since the alloy itself should be subjected to the deoxidizing action in contradistinction to the deoxidizing of the iron or major component of the alloy alone.
  • the molten alloy is poured into molds to form alloy castings or to form ingots for rolling mill or bloomery 1 purposes. Such ingots may be rolled and forged with facility and the microscope has thus far failed to discover slag-lines in the ingots or'their products.
  • the proportion of the alloying metal employed with the iron will be determined largely by the quality wanted when considered in connection with the cost. In a nickeliron alloy, for instance, if the high cost will be justified by the results, an alloy can be produced which would be practically proof against corrosion.
  • the nickel in the above case not only enhances the corrosion-resist-- ing quality of the alloy but is itself of higher corrosion-resisting quality than the iron alone, and also enhances the strength of the phorus, carbon and manganese taken in the aggregate, and containing not over .05 per cent. of oxygen, and containing at least 9980 per cent. of iron and alloying metal or metals taken 1n the aggregate, and containing at least 80 per cent. of iron, substantially as set forth.

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  • Chemical & Material Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Materials Engineering (AREA)
  • Mechanical Engineering (AREA)
  • Metallurgy (AREA)
  • Organic Chemistry (AREA)
  • Treatment Of Steel In Its Molten State (AREA)

Description

UNITED STATES PATENT OFFICE.
ROBERT B. CARNAHAN, JR., F MIDDLETOWN, OHIO, ASSIGNOR TO THE INTERNA- TIONAL METAL PRODUCTS COMPANY, OF NEWARK, NEW JERSEY.
Patented Aug. 20, 1912.
ALLOY.
1,035,947 Specification of Letters Patent.
No' Drawing.
Application filed Februaryll, 1911. Serial No. 607,913.
To all whom iii-may concern;
Be it known that I, ROBERT B. CARNA- HAN, J r., a citizen of the United States, re.- siding at Middletown, Butler county, Ohio, have invented certain new and useful provements in Alloys, of which the following is a specification.
The present invention comprehends an iron alloy (by which is meant an alloy containing at least 80 per cent. of iron) slagless and crystalline and deoxidized and degasified, the alloy containing not less than 99.80 per cent. of iron with its alloying metal or metals taken together, and containing not over .14 per cent. of silicon, sulfur, phosphorus, carbon and manganese when taken 1n the aggregate, and containing not over .05 per cent. of oxygen.
Notwithstanding the teachings of author ities that pure iron is without utility in the arts owing to its extreme susceptibility to corrosion I have discovered that this is not correct. Having produced, as I believe, the purest iron yet commercially produced,
I have ascertained that the greater its purity the greaterits resistance to corrosion and the greater its capacity for all of the general useful purposes of iron.
"In my present invention I purify molten iron to such extent that its silicon, sulfur, phosphorus, carbon and manganese will not exceed .14 percent. when taken in the aggregate and I so reduce the oxygen that it will not exceed .05 per cent. in the finished product and I combine with the iron an alloying metal, or metals, of a character which, in conjunction with the iron, will produce an alloy having greater corrosionresisting qualities than the unalloyed iron.
loying metal will of itself be of higher corrosion-resisting quality loyed iron, I am not sure that'this is true in all cases, my intention being, vhowever,
that the alloy when produced shall have higher. corrosion-resisting qualities than the iron alone even if it should be proved that the alloying metal was of itself of lower corrosion-resistingquality than the iron alone.
The improved alloy is to contain not less than 80 per cent. of iron, and not less than 99.80 per cent. of iron and alloying metal or metals taken together. 'As a type of the alloyed iron I. would mention an iron-' While it may be generally true that the althan the unalnickel alloy containing 99.30 per cent. of
iron and .50 per cent. of nickel, and containing not over .14 per cent. of silicon, sulfur, phosphorus, carbon and manganese when taken in the aggregate and containing not over .05 per cent. of oxygen. The improved 1 alloy may be made in a basic open-hearth furnace by refining iron till silicon, sulfur,. phosphorus, carbon and manganese do not exceed .14 per cent. when taken inthe ag gregate; then partially-deoxidizing the bath by the addition of, say, 5 per cent. of pigiron to the bath; then tapping the charge into. a ladle or other receptacle along with a deoxidizing and degasifying agent, say aluminum at the rate of two and one-half pounds per ton; the alloying metal or metals being combined with the'iron either in the furnace orladle, it being essential however that deoxidizing action take place after I the alloying elementhas been incorporated with the iron, since the alloy itself should be subjected to the deoxidizing action in contradistinction to the deoxidizing of the iron or major component of the alloy alone. After the deoxidation the molten alloy is poured into molds to form alloy castings or to form ingots for rolling mill or bloomery 1 purposes. Such ingots may be rolled and forged with facility and the microscope has thus far failed to discover slag-lines in the ingots or'their products.
' As a standard from which the oxygen content is to be determined reference is here made to the Ledebur method of oxygen determination.
The proportion of the alloying metal employed with the iron will be determined largely by the quality wanted when considered in connection with the cost. In a nickeliron alloy, for instance, if the high cost will be justified by the results, an alloy can be produced which would be practically proof against corrosion. The nickel in the above case not only enhances the corrosion-resist-- ing quality of the alloy but is itself of higher corrosion-resisting quality than the iron alone, and also enhances the strength of the phorus, carbon and manganese taken in the aggregate, and containing not over .05 per cent. of oxygen, and containing at least 9980 per cent. of iron and alloying metal or metals taken 1n the aggregate, and containing at least 80 per cent. of iron, substantially as set forth.
2. An alloy slagless and crystalline and deoxidizecl and degasified and containing not over .14 per cent. of silicon, sulfur, phos phorus, carbon and manganese taken in the aggregate, and containing not over .05 per cent. of oxygen, and containing at least 99.80 per cent. of iron and alloying metal 'or metals taken in the aggregate, and con- 3. An alloy slagless andcrystalline and deoxidized and degasified and containing not over .14: .per cent. of silicon,'sulfu'r, phosphorus, carbon and manganese taken in the aggregate, and'containing not over .05 per cent. of oxygen, and containing at least 99.80 per cent. of iron and alloying metal or metals taken in the aggregate, and containing at least 80 per cent. of iron, the alloying metal or metals having a higher corrosion-resisting quality than the unalloyed iron, substantially as set forth.
v ROBERTI'BPGARNAHAN, JR.
l/Vitnessesz G. W. JOHNSON, M. S. BELDEN.
US60791311A 1911-02-11 1911-02-11 Alloy. Expired - Lifetime US1035947A (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US10852214B2 (en) 2017-05-19 2020-12-01 Nutech Ventures Detecting faults in wind turbines

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US10852214B2 (en) 2017-05-19 2020-12-01 Nutech Ventures Detecting faults in wind turbines

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