US2390023A - Treating inherently aging chromium-nickel stainless steel - Google Patents
Treating inherently aging chromium-nickel stainless steel Download PDFInfo
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- US2390023A US2390023A US551256A US55125644A US2390023A US 2390023 A US2390023 A US 2390023A US 551256 A US551256 A US 551256A US 55125644 A US55125644 A US 55125644A US 2390023 A US2390023 A US 2390023A
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- This invention is concerned with treating in-.
- aging characteristics are inherently possessed by a carbon-containing chromiumnickel stainless steel of the type containing at least one of the stronger-thamchromiumcarbide formers such as titanium, columbium, zirconium, etc., when its components that are ferrite formers, other than the named carbide formers, are proportioned to those that are austenite formers to provide the steel with a structure that transforms at relatively low temperatures to stressladen ferrite.
- the stronger-thamchromiumcarbide formers such as titanium, columbium, zirconium, etc.
- the steel when such a steel is cooled from an elevated temperature, where it is predominantly austenitic, to a lower temperature producing the stress-laden ferrite, the steel may be aged, without its being previously cold worked, to a higher hardness and strength.
- the aging occurs naturally or may be artificially induced by the use of elevated temperature sufllcient to shorten the time required but insuflicient to return the steel to a predominantly austenitic condition.
- the steel has a maximum aging characteristic. If the ferrite formers overbalance the austenite formers so far that the steel practically entirely transforms to ferrite at too high a temperature to result inferrite that is stress laden, the steel is not inherently aging. Therefore, it is natural, in commercially producing the steel, to tend to produce a steel having a structure that transforms to ferrite relatively close to roomtemperature, the result being that, at times, steel is produced having a structure that incompletely transforms thestress-laden ferrite required for aging, the untransformed structure being'austenite which is not inherently aging. In such instances it is impossible 'to develop the same high hardness and strength that would have been possible had the steel been produced with a structure that was practically all stress-laden ferrite.
- the present invention is concerned with en-.
- ferrite formers overbalance the austenite formnamely, when its ferrite formers are proportioned to those that are austenite formers to provide the steel with a structure that only partly transforms, at relatively low temperatures, tov
- This invention comprises treating the steel by cold straining it to a sufficient degree to convert all or a substantial amount of the described, retamed austemte to stress-laden ferrite, the enhancement of the aging characteristic depending on the amount of cold strain placed in the steel since this, in turn, determines the amount of retained austenite transformed to stress-laden ferrite. so as to' be converted from a nonaging material to a material that is inherently aging.
- steel was produced, in sheet form, containing,.08% carbon, 18.52% chromium, 7.1% nickel, and 34% titanium, which retained austenite upon cooling from a temperature where it was austenitic to a temperature normally resulting in the production of practically all stress-laden ferrite in the case of a steel having the somewhat higher proportion of ferrite formers, respecting the austemte formers, required to produce a steel having the maximum aging characteristic.
- the same aging treatment increased its hardness from Rockwell C285 to (333.5; while 50% cold reduction resulted in the aging increasing it from Rockwell C38 to Rockwell 046.5.
- composition ranges may be narrowed to obtain a critically more vigorous response to aging as follows:
- the present invention is not concerned with those instances where the ferrite formers are proportioned sufliciently high respecting the austenite formers to produce a steel that is, practically speaking, 100% stressladen ferrite.
- the invention is applicable to those instances where the compositional balance is such that substantial amounts of austenite are retained at room temperature, the invention providing a means for converting practically all, or any portion, of this retained austenite to stressladen ferrite, depending on the amount of cold strain used, so as to, thereby, enhance the inherent aging characteristic of the steel, as required.
- the stronger-than-chromium carbide former is held to sufficiently low values to produce a steel having adequate ductility to adapt it for structural use, it being the chromium and, generally, aluminum, particularly, that are to be considered; as the ferrite formers whose proportion is increased respecting the austenite formers, although the proportioning must be carried out in conjunction with the ferrite forming efiect of the stronger-than-chromium carbide former.
- the stronger-than-chromium carbide formers such as titanium, columbium, zirconium, etc..
Description
Patented Nov. 27, 1945 TREAT ING INHERENTLY AGING CHRO- lVIIUM-NICKEL STAINLESS STEEL Ernest H. Wyohe, Niagara Falls, N. Y., assignor to Carnegie-Illinois Steel Corporation, a corporation of New Jersey No Drawing. Application August 25, 1944,
Serial No. 551,256
1 Claim.
This invention is concerned with treating in-.
herently aging chromium-nickel stainless steel for the purpose of enhancing its aging characteristic when its composition is such that the steel has a structure incompletely amenable to aging.
' As disclosed in a copending application Serial No. 414,194, filed jointly by this inventor and another, aging characteristics are inherently possessed by a carbon-containing chromiumnickel stainless steel of the type containing at least one of the stronger-thamchromiumcarbide formers such as titanium, columbium, zirconium, etc., when its components that are ferrite formers, other than the named carbide formers, are proportioned to those that are austenite formers to provide the steel with a structure that transforms at relatively low temperatures to stressladen ferrite. That is to say, when such a steel is cooled from an elevated temperature, where it is predominantly austenitic, to a lower temperature producing the stress-laden ferrite, the steel may be aged, without its being previously cold worked, to a higher hardness and strength. The aging occurs naturally or may be artificially induced by the use of elevated temperature sufllcient to shorten the time required but insuflicient to return the steel to a predominantly austenitic condition.
If the composition of the steel is such that the ers to a degree producing a structure that is approximately all stress-laden ferrite, then the steel has a maximum aging characteristic. If the ferrite formers overbalance the austenite formers so far that the steel practically entirely transforms to ferrite at too high a temperature to result inferrite that is stress laden, the steel is not inherently aging. Therefore, it is natural, in commercially producing the steel, to tend to produce a steel having a structure that transforms to ferrite relatively close to roomtemperature, the result being that, at times, steel is produced having a structure that incompletely transforms thestress-laden ferrite required for aging, the untransformed structure being'austenite which is not inherently aging. In such instances it is impossible 'to develop the same high hardness and strength that would have been possible had the steel been produced with a structure that was practically all stress-laden ferrite.
The present invention is concerned with en-.
hancing the aging characteristic of the described steel under the above discussed circumstances,
. ferrite formers overbalance the austenite formnamely, when its ferrite formers are proportioned to those that are austenite formers to provide the steel with a structure that only partly transforms, at relatively low temperatures, tov
stress-laden ferrite, so it retains an appreciable amount of austenite.
This invention comprises treating the steel by cold straining it to a sufficient degree to convert all or a substantial amount of the described, retamed austemte to stress-laden ferrite, the enhancement of the aging characteristic depending on the amount of cold strain placed in the steel since this, in turn, determines the amount of retained austenite transformed to stress-laden ferrite. so as to' be converted from a nonaging material to a material that is inherently aging. Heretofore, it has not been known that c ld working would perform the function described, it being known only that austenitic, chromiumnickel stainless steel of the stabilized type, containing titanium, columbium, etc., could be rendered aging by cold working after the steel was first given a stabilizing thermal treatment, such as normally used to fix the carbides to prevent intergranular corrosion by preventing intergranular carbide precipitation. However, the practice.
described herein works with the defined steel regardless of whether the steel is first thermally stabilized.
'As a specific example of the invention, steel was produced, in sheet form, containing,.08% carbon, 18.52% chromium, 7.1% nickel, and 34% titanium, which retained austenite upon cooling from a temperature where it was austenitic to a temperature normally resulting in the production of practically all stress-laden ferrite in the case of a steel having the somewhat higher proportion of ferrite formers, respecting the austemte formers, required to produce a steel having the maximum aging characteristic. Aging this steel at 950 F. for one-half hour, followed by air cooling, increased the hardness of the steel from Rockwell B84 to B91. When the same steel was cold strained by a 17% cold reduction in its thickness, the same aging treatment increased its hardness from Rockwell C285 to (333.5; while 50% cold reduction resulted in the aging increasing it from Rockwell C38 to Rockwell 046.5.
As the amount of austenite retained at room temperature increases towards it becomes increasingly dificult to make the steel aging in the manner described, a fully austenitic steel remaining practically nonaging regardless of the amount of cold strain induced in its structure, unless it is first given a stabilizing thermal treatment such as is usually used in the interest of intergranular corrosion prevention.
As explained in the previously mentionedcopending application, an inherently aging steel results by following the following percentage composition range:
Carbon .03 to .15 Chromium 12.0 to 20.0 Nickel 2.0 to 10.0 Manganese"; .25 to 10.0 Aluminum 0,0 to 10 Tita .40 to 2.0
or Columbium .50 to 3.0
Balance, iron.
These percentage composition ranges may be narrowed to obtain a critically more vigorous response to aging as follows:
Balance, iron.
It is to be understood that the present invention is not concerned with those instances where the ferrite formers are proportioned sufliciently high respecting the austenite formers to produce a steel that is, practically speaking, 100% stressladen ferrite. The invention is applicable to those instances where the compositional balance is such that substantial amounts of austenite are retained at room temperature, the invention providing a means for converting practically all, or any portion, of this retained austenite to stressladen ferrite, depending on the amount of cold strain used, so as to, thereby, enhance the inherent aging characteristic of the steel, as required. It is to be further understood that in all instances the stronger-than-chromium carbide former is held to sufficiently low values to produce a steel having adequate ductility to adapt it for structural use, it being the chromium and, generally, aluminum, particularly, that are to be considered; as the ferrite formers whose proportion is increased respecting the austenite formers, although the proportioning must be carried out in conjunction with the ferrite forming efiect of the stronger-than-chromium carbide former.
I claim:
A method of enhancing the inherent aging characteristic of carbon-containing chromiumnickel stainless steel of the type containing at least one of the stronger-than-chromium carbide formers such as titanium, columbium, zirconium, etc.. with its components, other than said carbide former, that are ferrite formers proportioned to those that are austenite formers to provide said steel with a structure that partly transforms at relatively low temperatures to stress-laden ferrite while retaining an appreciable amount of austenite, said method comprising cooling said steel to produce said ferrite, and cold straining the steel to an extent transforming an appreciable amount of said austenite to said ferrite.
Y ERNEST H. WYCHE.
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US551256A US2390023A (en) | 1944-08-25 | 1944-08-25 | Treating inherently aging chromium-nickel stainless steel |
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US551256A US2390023A (en) | 1944-08-25 | 1944-08-25 | Treating inherently aging chromium-nickel stainless steel |
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Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2505762A (en) * | 1946-09-06 | 1950-05-02 | Armco Steel Corp | Stainless steel and method |
US2505763A (en) * | 1946-09-06 | 1950-05-02 | Armco Steel Corp | Stainless steel and method |
US2505764A (en) * | 1946-09-06 | 1950-05-02 | Armco Steel Corp | Stainless steel and method |
US2553707A (en) * | 1947-01-31 | 1951-05-22 | Armco Steel Corp | Stainless steel spring |
US3139682A (en) * | 1960-06-24 | 1964-07-07 | Nicholas J Grant | Strength recovery of dispersion hardened alloys |
US3884731A (en) * | 1964-07-02 | 1975-05-20 | Reynolds Metals Co | Metal composite and method of producing the same |
-
1944
- 1944-08-25 US US551256A patent/US2390023A/en not_active Expired - Lifetime
Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2505762A (en) * | 1946-09-06 | 1950-05-02 | Armco Steel Corp | Stainless steel and method |
US2505763A (en) * | 1946-09-06 | 1950-05-02 | Armco Steel Corp | Stainless steel and method |
US2505764A (en) * | 1946-09-06 | 1950-05-02 | Armco Steel Corp | Stainless steel and method |
US2553707A (en) * | 1947-01-31 | 1951-05-22 | Armco Steel Corp | Stainless steel spring |
US3139682A (en) * | 1960-06-24 | 1964-07-07 | Nicholas J Grant | Strength recovery of dispersion hardened alloys |
US3884731A (en) * | 1964-07-02 | 1975-05-20 | Reynolds Metals Co | Metal composite and method of producing the same |
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