US2139538A - Chromium alloy steel tube - Google Patents

Chromium alloy steel tube Download PDF

Info

Publication number
US2139538A
US2139538A US727280A US72728034A US2139538A US 2139538 A US2139538 A US 2139538A US 727280 A US727280 A US 727280A US 72728034 A US72728034 A US 72728034A US 2139538 A US2139538 A US 2139538A
Authority
US
United States
Prior art keywords
chromium
steel
tubes
titanium
steels
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.)
Expired - Lifetime
Application number
US727280A
Inventor
Frederick M Becket
Franks Russell
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Union Carbide Corp
Original Assignee
Union Carbide and Carbon Corp
Priority date (The priority date 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 date listed.)
Filing date
Publication date
Application filed by Union Carbide and Carbon Corp filed Critical Union Carbide and Carbon Corp
Priority to US727280A priority Critical patent/US2139538A/en
Application granted granted Critical
Publication of US2139538A publication Critical patent/US2139538A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Classifications

    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C38/00Ferrous alloys, e.g. steel alloys
    • C22C38/18Ferrous alloys, e.g. steel alloys containing chromium
    • C22C38/28Ferrous alloys, e.g. steel alloys containing chromium with titanium or zirconium

Definitions

  • Chromium-steel seamless tubes have been widely used commercially to resist corrosion and oxidation at high temperatures. While it has been possible to fabricate seamless tubes from.
  • chromium steels difdculties have been encountered, because of certain inherent properties of the chromium steels'customarily used.
  • the chromium content of the steels exceedsabout 16%,-the tendency of steel to air-harden is considerably less than that of the steels lower in chromium, and when the amount of chromium is about or more there is practically no tendency for the steel to harden on cooling from elevated temperatures, provided the carbon percentage is reasonably low.
  • the steelscontaining more than about 16% chromium possess lit le ductility in the as-rolled condition, and to improve their ductility they must be heated for relatively long periods atthe proper annealing temperatures.
  • Steels containing more than about 20% chromium must be rapidly cooled from the annealing-temperatures to avoid brittleness. required after hot rolling causes the development of very large grains which weaken the article.
  • all these steels may be cooled either rapidly or slowly from elevated temperatures without producing either hardness or brittleness. Rapid cooling, that is, air-cooling or quenchingas opposed toiurnace-cooling, from the elevated temperatures used in hot-forming or annealing, does not produce marked hardening even in tubes containing the lower percentages of chromium.
  • the content of titanium or columbium, or both must be strictly controlled. If titanium alone is used, the content of this material'should be at leasttwice the carbon content, but not more than four times the carbon content plus an excess of 1.00% of the steel, preferably the excess is not over about 0.5% of the steel.
  • Columbium may be substituted for the titanium in the ratio of two parts by weight of columbium for one of titanium; but preferably the maximum content of columbium does not exceed about 5%.
  • Molybdenum in amounts up to about 2% or tungsten in amounts up to about 3% may be included in the tubes of the invention to advantage.
  • tubes of the present invention which contain about 4% to about 10% chromium, less than 0.2% carbon, and preferably up to about 1% molybdenum.
  • the tubes of the invention are not only easier and cheaper to fabricate than the chromium steel tubes heretofore known, but they are also more ductile, strong and uniform, and they may be straightened or bent, hot or cold, to a great extent without danger of breakage, behaving in this respect somewhat like carbon steel tubes.
  • Chromium alloy ferritic steel seamless tube characterized by extreme ductility and a Brinell hardness number between about and 200,
  • chromium a carbon content not over about 0.3%
  • titanium at least twice the carbon content but not exceeding four times the carbon content by more than 1% of the steel, part of the titanium being replaceable by 00- lumbium, the remainder being chiefly iron; which tube has been formed at temperatures initially above 1000 C. but below the melting point thereof, rapidly cooled from the forming temperature, and subsequently annealed for a time from a few minutes to not over two hours at a temperature above 750 C. and then rapidly cooled.
  • Chromium alloy ferritic steel seamless tube characterized by extreme ductility and a Brinell hardness number between about 100 and 170. and having substantially the composition: 3% to 16% chromium, a carbon content not over about 0.2%, titanium at least twice the carbon content but not exceeding four times the carbon content by more than 0.5% of the steel, and the remainder chiefly iron; which tube has been formed at temperatures initially above 1100 C. but below the melting point thereof, rapidly cooled from the forming temperature, and*subsequently annealed for a time from a few minutes to not over one hour at a temperature between 850 and 950 C. and then rapidly cooled.
  • Method of making soft and ductile chromium alloy ferritic steel hot-wrought articles having a Brinell hardness number between 100 and 200 which comprises hot-forming, at temperatures initially between 1000 C. and the melting point, an alloy steel having substantially the composition; 3% to 30% chromium, carbon in an amount not over 0.3%, titanium in an amount at least twice the carbon content but not exceeding four times the carbon content by more than 1% of the steel, part of the titanium being replaceable by columbium, and the remainder principally iron; rapidly cooling the article from the forming temperature; subsequently annealing the article for a time from a few minutes to not over two hours at a temperature above 750 0.; and
  • Brinell hardness number between 100 and which comprises hot-forming into a seamless tube, at a temperature initially between 1000 C.
  • an alloy steel having sub stantially the composition: 3% to 16% chroa few minutes to not over one hour at a. temperature between 850 C. and. 950 0,: and then rapidly cooling the article from the annealing temperature.

Description

Patented Dec. 6, 1938 onaoriimu aisasss srizai. roar.
Frederick M. Becket, New York, and Russell Franks, Jackson Heights, Long Island, N. 35L, assignors, by mesne assignments, to Union Garporatiori, a corporation of bide and Carbon (for New York No Drawing. Application-lusty 2%,
Serial No. teases The invention relates to chromium alloy steel seamless tubes, and to similar articles, fabricated by hot or cold forming. This application'is a continuation in part of our application Serial No. 640,'778,- md May 24, 1934.
llll
Chromium-steel seamless tubes have been widely used commercially to resist corrosion and oxidation at high temperatures. While it has been possible to fabricate seamless tubes from.
chromium steels, difdculties have been encountered, because of certain inherent properties of the chromium steels'customarily used.
When chromium is added to steel the hardenfled. This is especially true of steels containing about 3% to 16% chromium, which are known as air-hardening steels. In fabricating articles ing eiiect of any carbon present is greatly intensisuch ,as seamless tubes from these air-hardening steels, care must be exercised to prevent cracking of the metalduring cooling. Further, the addition of about 3% to'l6% chromium to steels renders sluggish the thermal changes which occur during heatingend cooling, and it is necessary to use long heat treating periods, followed by slow cooling, in order to soften the meal.
If the chromium content of the steels exceedsabout 16%,-the tendency of steel to air-harden is considerably less than that of the steels lower in chromium, and when the amount of chromium is about or more there is practically no tendency for the steel to harden on cooling from elevated temperatures, provided the carbon percentage is reasonably low. However, the steelscontaining more than about 16% chromium possess lit le ductility in the as-rolled condition, and to improve their ductility they must be heated for relatively long periods atthe proper annealing temperatures. Steels containing more than about 20% chromium must be rapidly cooled from the annealing-temperatures to avoid brittleness. required after hot rolling causes the development of very large grains which weaken the article.
to about 16% chromium can be strongly inhibited In some instances, the long heat treatment if the steel contains suitable additions of titanium I 3% to 16% chromium or 0.3% in steels containing about 16% to 30%- chromium; and suitable amounts of titanium or .columbium, or both; the remainder chiefly iron; are soft and ductile in. the hot-worked condition, instead of hard and relatively brittle; Mcreover,,the tubes, of the invention may; a readily be fully softened by heating them for a relatively short period at a temperature inexcess of about 750 C It is not necessary to keep these tubes at the annealing temperature for longer than two hours to secure sumcient softness, provided a sufllciently high temperature is used. Further, all these steels may be cooled either rapidly or slowly from elevated temperatures without producing either hardness or brittleness. Rapid cooling, that is, air-cooling or quenchingas opposed toiurnace-cooling, from the elevated temperatures used in hot-forming or annealing, does not produce marked hardening even in tubes containing the lower percentages of chromium.
In the following table are given data obtained from certain tests of chromium alloy seamless tubes. In this table are indicated the chemical analyses of the tubing, the balance in each case being substantially all iron; the heat treatment of the tubes A representing as hot formed", B representing heated at 750 C. 4 hours and air- .cooled (a suitable annealing treatment for straight chromium s eels), and C representing heated at 900 C. 10 minutes and air-cooled"; the Brinell hardness; and the results of tests in which the tubing was crushed in a press. All
tubes tested had an outside diameter oi 2.375 issued as Patent No. 1,954,344 on April 10, 1984.
These data show, first, that the ordinary 6% chromium steel tubes are relatively brittle and hard in the rolled state, and that a long annealing period is required to soften the metal and render it satisfactorily ductile; second, that 6% chromium steel tubes containing moderate amounts of titanium are soft and ductile in the as-rolled state, and that they are fully softened by annealing for only a few minutes at temperatures in the vicinity of 900 C.; and, third,
that 6% chromium steel tubes containing moderate amounts of both titanium and molybdenum have substantially the same ductility and softness as those containing the titanium alone. Similar results have been obtained in the case of chromium steels with other chromium, titanium, and carbon contents, and with steels containing columbium instead of titanium.
In order to obtain the full benefits of this invention the content of titanium or columbium, or both, must be strictly controlled. If titanium alone is used, the content of this material'should be at leasttwice the carbon content, but not more than four times the carbon content plus an excess of 1.00% of the steel, preferably the excess is not over about 0.5% of the steel. Columbium may be substituted for the titanium in the ratio of two parts by weight of columbium for one of titanium; but preferably the maximum content of columbium does not exceed about 5%.
Molybdenum in amounts up to about 2% or tungsten in amounts up to about 3% may be included in the tubes of the invention to advantage. Small amounts of metals and metalloids usually present in commercial steels as impurities, deoxidizers, scavengers, and so forth, for example, manganese, silicon, aluminum, zirconium, sulfur, and phosphorus, may also be present in the steel of the tubes without departing from the invention.
Particularly useful for oil-cracking tubes and similar articles for use at elevated temperatures are those tubes of the present invention which contain about 4% to about 10% chromium, less than 0.2% carbon, and preferably up to about 1% molybdenum.
The tubes of the invention are not only easier and cheaper to fabricate than the chromium steel tubes heretofore known, but they are also more ductile, strong and uniform, and they may be straightened or bent, hot or cold, to a great extent without danger of breakage, behaving in this respect somewhat like carbon steel tubes.
This application contains subject-matter in common with our joint applications Serial Numbers 640,778 and 640,900, both filed on Novemher 2, 1933. Our application Serial No. 640,900
1. Chromium alloy ferritic steel seamless tube characterized by extreme ductility and a Brinell hardness number between about and 200,
, and having substantially the composition: 3%
to 30% chromium, a carbon content not over about 0.3%, titanium at least twice the carbon content but not exceeding four times the carbon content by more than 1% of the steel, part of the titanium being replaceable by 00- lumbium, the remainder being chiefly iron; which tube has been formed at temperatures initially above 1000 C. but below the melting point thereof, rapidly cooled from the forming temperature, and subsequently annealed for a time from a few minutes to not over two hours at a temperature above 750 C. and then rapidly cooled.
2. Chromium alloy ferritic steel seamless tube characterized by extreme ductility and a Brinell hardness number between about 100 and 170. and having substantially the composition: 3% to 16% chromium, a carbon content not over about 0.2%, titanium at least twice the carbon content but not exceeding four times the carbon content by more than 0.5% of the steel, and the remainder chiefly iron; which tube has been formed at temperatures initially above 1100 C. but below the melting point thereof, rapidly cooled from the forming temperature, and*subsequently annealed for a time from a few minutes to not over one hour at a temperature between 850 and 950 C. and then rapidly cooled.
3. Method of making soft and ductile chromium alloy ferritic steel hot-wrought articles having a Brinell hardness number between 100 and 200 which comprises hot-forming, at temperatures initially between 1000 C. and the melting point, an alloy steel having substantially the composition; 3% to 30% chromium, carbon in an amount not over 0.3%, titanium in an amount at least twice the carbon content but not exceeding four times the carbon content by more than 1% of the steel, part of the titanium being replaceable by columbium, and the remainder principally iron; rapidly cooling the article from the forming temperature; subsequently annealing the article for a time from a few minutes to not over two hours at a temperature above 750 0.; and
a Brinell hardness number between 100 and which comprises hot-forming into a seamless tube, at a temperature initially between 1000 C.
and the melting point, an alloy steel having sub stantially the composition: 3% to 16% chroa few minutes to not over one hour at a. temperature between 850 C. and. 950 0,: and then rapidly cooling the article from the annealing temperature.
FREDERICK M. BEQKET. RUSSELL FRANKS.
US727280A 1934-05-24 1934-05-24 Chromium alloy steel tube Expired - Lifetime US2139538A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US727280A US2139538A (en) 1934-05-24 1934-05-24 Chromium alloy steel tube

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US727280A US2139538A (en) 1934-05-24 1934-05-24 Chromium alloy steel tube

Publications (1)

Publication Number Publication Date
US2139538A true US2139538A (en) 1938-12-06

Family

ID=24922035

Family Applications (1)

Application Number Title Priority Date Filing Date
US727280A Expired - Lifetime US2139538A (en) 1934-05-24 1934-05-24 Chromium alloy steel tube

Country Status (1)

Country Link
US (1) US2139538A (en)

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2476666A (en) * 1946-01-14 1949-07-19 Tech Studien Ag Tubing for heat exchangers operated at high temperatures and pressures
US3250611A (en) * 1963-04-10 1966-05-10 Allegheny Ludlum Steel Corrosion-resisting steel and method of processing
US3455681A (en) * 1965-09-27 1969-07-15 Crucible Steel Co America Stainless steel
US3926624A (en) * 1972-03-17 1975-12-16 Jones & Laughlin Steel Corp Production of ferritic stainless steels containing zirconium

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2476666A (en) * 1946-01-14 1949-07-19 Tech Studien Ag Tubing for heat exchangers operated at high temperatures and pressures
US3250611A (en) * 1963-04-10 1966-05-10 Allegheny Ludlum Steel Corrosion-resisting steel and method of processing
US3455681A (en) * 1965-09-27 1969-07-15 Crucible Steel Co America Stainless steel
US3926624A (en) * 1972-03-17 1975-12-16 Jones & Laughlin Steel Corp Production of ferritic stainless steels containing zirconium

Similar Documents

Publication Publication Date Title
US1836317A (en) Corrosion resistant alloys
US3726723A (en) Hot-rolled low alloy steels
US2562854A (en) Method of improving the high-temperature strength of austenitic steels
USRE28523E (en) High strength alloy steel compositions and process of producing high strength steel including hot-cold working
US2797162A (en) Low alloy steel for sub-zero temperature application
JPH0152462B2 (en)
US2715576A (en) Age hardening alloy steel of high hardenability and toughness
US2791500A (en) High strength aircraft landing gear steel alloy elements
US4460542A (en) Iron-bearing nickel-chromium-aluminum-yttrium alloy
US3342590A (en) Precipitation hardenable stainless steel
US2139538A (en) Chromium alloy steel tube
JPS5891123A (en) Production of seamless steel pipe for 80kg/mm2 class structure having excellent toughness of weld zone
US3347663A (en) Precipitation hardenable stainless steel
US1496980A (en) Alloy steel for metal-cutting tools
US3128175A (en) Low alloy, high hardness, temper resistant steel
US2505763A (en) Stainless steel and method
US3318690A (en) Age hardening manganese-containing maraging steel
JPS6144121A (en) Manufacture of high strength, high toughness steel for pressurized vessel
JPH02243740A (en) Martensitic stainless steel material for oil well and its manufacture
JPH062904B2 (en) High strength low alloy steel Extra thick steel manufacturing method
US3201232A (en) Use of steel involving prolonged stressing at elevated temperatures
JPS58107416A (en) Method of directly softening steel wire or rod steel useful for mechanical construction
JPS5914535B2 (en) Non-heat treated high tensile strength steel line pipe thick plate with unstable ductility and good fracture resistance
US3658514A (en) Martensitic steel
JPS5853711B2 (en) Nickel-chromium-molybdenum-based high strength, high toughness thick wall steel for pressure vessels