US1035948A - Alloy manufacture. - Google Patents
Alloy manufacture. Download PDFInfo
- Publication number
- US1035948A US1035948A US66943412A US1912669434A US1035948A US 1035948 A US1035948 A US 1035948A US 66943412 A US66943412 A US 66943412A US 1912669434 A US1912669434 A US 1912669434A US 1035948 A US1035948 A US 1035948A
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- US
- United States
- Prior art keywords
- iron
- alloy
- metals
- alloying
- alloy manufacture
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
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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
- C22C1/00—Making non-ferrous alloys
- C22C1/10—Alloys containing non-metals
- C22C1/1036—Alloys containing non-metals starting from a melt
Definitions
- the present invention comprehends the manufacture of iron'alloys, by which .is meant alloys containing at least 80 per cent. of iron.
- My present invention has to do with the process of manufacturing iron alloys, as above defined, the iron forming the base of the alloy being of extremely high purity, and the alloying metal or alloying metals being of a character to enhance the qualities of the iron as, for instance, by increasing the corrosion-resisting quality over that of-the iron, or by increasing the strength over that of the iron, or both.
- the im-- proved process may be executed with economy and certainty.
- the resultof the process thus far,is that the metal is highly super-oxidized, or burned past present utility.
- the super-oxidized iron may now be tapped out into a ladle and deoxidized and degasified by treatment with, say, aluminum, at the rate of two and onehalf pounds per ton.
- the alloying metal or metals may be introduced into the ladle along with the.iron to produce the alloy, but whatever may have been the degree of deoxidation of the iron, there must be a subsequent deoxidizing and degasifying action on the alloy.
- the general deoxidation may be facilitated and economized by charging pig-iron, say, at the rate of about one hundred pounds per ton, while the metal is in the furnace, and the alloying metal or alloying metals, instead of being combined with the iron after the iron has been withdrawn from the furnace, may be combined with the iron while inv the furnace, either before or after the purification and the deoxidizing of the charge.
- the combining of the alloying metal or metals with the charge while in the furnace is decidedly preferable, as it avoids the cooling effect of the alloying metal or metals in the ladle.
- the alloy may be poured into ingots or other molds.
- the alloying metal employed with the iron will be selected according to the special desire regarding the alloy, a nickel-iron alloy, for instance, being of particularly high value in resisting corrosion, and the alloy having greater strength than the unalloyed iron.
- the alloys resulting from the im proved process have distinct advantages in the art by reason of the high purity of the iron forming their bases.
- the deoxidation of the alloy, or the deoxidation of the iron' plus the deoxidation of the alloy can, without difficulty, be carried to such extent that the oxygen does not exceed .05 per cent. or even to half this amount, and as known methods of determining oxygen content vary in their results, reference is here made to the Ledebur method of oxygen determination as a standard.
Description
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UNITED" STATES ATENT OFFICE.
ROBERT B. GARN'AHAN, .13., 0F MIDDLETOWN, 01110, ASSIGNQR To THE TIONAL METAL PRODUCTS COMPANY, OF NEWARK, NEW JERSEY.
LOY MAN I ACTURE.
Specification dflie'tters Patent.
Patented Aug, 20,1912.
No Drawing. Application filed February 13, 1911, Serial No. 608,204. Renewed January 4, 1912. Serial To all whom it may concern:
"Be it known that I, ROBERT B. CARNAHAN, J r., a, citizen of the United States, residing at Middletown, Butler county, Ohio, have invented certain new and useful Improvements in Alloy Manufacture, of which the following is a specification.
The present invention comprehends the manufacture of iron'alloys, by which .is meant alloys containing at least 80 per cent. of iron.
Notwithstanding the teachings of some authorities that pure iron is without utility in the arts, owing to its extreme susceptibility to corrosion, I have discovered that Having produced on a large scale what I believe to be the purest iron yet commercially produced, I have ascertained that the greater its purity the greater its resistance to corrosion and the greater its capacity for all of the general useful purposes of iron.
My present invention has to do with the process of manufacturing iron alloys, as above defined, the iron forming the base of the alloy being of extremely high purity, and the alloying metal or alloying metals being of a character to enhance the qualities of the iron as, for instance, by increasing the corrosion-resisting quality over that of-the iron, or by increasing the strength over that of the iron, or both. The im-- proved process may be executed with economy and certainty. V
In executing my lmproved process I employ a basic open-hearth furnace which I charge withiron and purifying agents such,
for instance, as lime and iron ore, the charge being then subjected to the action of an oxidizing flame at such high temperature and for such long continued period that the carbon and manganese will be practically eliminated, by which I mean that the carbon and manganese taken together will not be over .10 per' cent., neither alone being, prefer ably, over .06 per cent. This process of elimination incidentally brings down the silicon, sulfur and phosphorus, and in practice the silicon, sulfur, phosphorus, carbon, and manganese need not exceed .14 per cent.
- when taken in the aggregate, and generally Will not be half such percentage. The resultof the process, thus far,is that the metal is highly super-oxidized, or burned past present utility. The super-oxidized iron may now be tapped out into a ladle and deoxidized and degasified by treatment with, say, aluminum, at the rate of two and onehalf pounds per ton. The alloying metal or metals may be introduced into the ladle along with the.iron to produce the alloy, but whatever may have been the degree of deoxidation of the iron, there must be a subsequent deoxidizing and degasifying action on the alloy. The general deoxidation may be facilitated and economized by charging pig-iron, say, at the rate of about one hundred pounds per ton, while the metal is in the furnace, and the alloying metal or alloying metals, instead of being combined with the iron after the iron has been withdrawn from the furnace, may be combined with the iron while inv the furnace, either before or after the purification and the deoxidizing of the charge. In many cases the combining of the alloying metal or metals with the charge while in the furnace is decidedly preferable, as it avoids the cooling effect of the alloying metal or metals in the ladle. The alloy may be poured into ingots or other molds.
The alloying metal employed with the iron will be selected according to the special desire regarding the alloy, a nickel-iron alloy, for instance, being of particularly high value in resisting corrosion, and the alloy having greater strength than the unalloyed iron. The alloys resulting from the im proved process have distinct advantages in the art by reason of the high purity of the iron forming their bases.
The deoxidation of the alloy, or the deoxidation of the iron' plus the deoxidation of the alloy, can, without difficulty, be carried to such extent that the oxygen does not exceed .05 per cent. or even to half this amount, and as known methods of determining oxygen content vary in their results, reference is here made to the Ledebur method of oxygen determination as a standard.
I claim The improved process for producing carbonless, manganeseless pure iron alloys,
which consists in eliminating practically all ing the alloy into molds,-t;he alloying metal of the carbon and manganese from the iron or alloying metals not to exceed 20 per cent. by the action' of purifying agents and an of the whole, substantially as set forth.
oxidizing flame under basic conditions; com- ROBERT B. OARNAHAN, JR. 5 biningtherewith an alloying metal or al- Witnesses:
loying metals; deoxidizing and degasifying LUTIE HALE,
the alloy while in molten form; and pour- GEO. JOHNSON.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US66943412A US1035948A (en) | 1912-01-04 | 1912-01-04 | Alloy manufacture. |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US66943412A US1035948A (en) | 1912-01-04 | 1912-01-04 | Alloy manufacture. |
Publications (1)
Publication Number | Publication Date |
---|---|
US1035948A true US1035948A (en) | 1912-08-20 |
Family
ID=3104227
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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US66943412A Expired - Lifetime US1035948A (en) | 1912-01-04 | 1912-01-04 | Alloy manufacture. |
Country Status (1)
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US (1) | US1035948A (en) |
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1912
- 1912-01-04 US US66943412A patent/US1035948A/en not_active Expired - Lifetime
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