US2353688A - Method of improving abrasion resistance of alloys - Google Patents

Method of improving abrasion resistance of alloys Download PDF

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US2353688A
US2353688A US460775A US46077542A US2353688A US 2353688 A US2353688 A US 2353688A US 460775 A US460775 A US 460775A US 46077542 A US46077542 A US 46077542A US 2353688 A US2353688 A US 2353688A
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alloys
chromium
abrasion
iron
carbon
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US460775A
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Charles O Burgess
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ELECTRO METALLURG CO
ELECTRO-METALLURGICAL Co
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ELECTRO METALLURG CO
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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
    • C22C38/18Ferrous alloys, e.g. steel alloys containing chromium
    • C22C38/26Ferrous alloys, e.g. steel alloys containing chromium with niobium or tantalum

Definitions

  • the invention relates to a method of improving the abrasion resistance of iron-base alloys containing chromium and to articles, composed of such alloys, having superior resistance to abrasion.
  • iron-base alloy containing about 12% to 30% chromium and 1.5% to 3% carbon, the remainder principally iron.
  • this alloy is used in the cast or wrought condition,-
  • the present invention has for one of its objects a method of improving the wear resistance of iron-base alloys containing chromium and carbon.
  • Another object of the invention' is an abrasion resistant article composed of such alloys treated to impart thereto superior resistance to abrasion.
  • the invention comprises a method of improving the abrasion-resistance of high chromium-high carbon iron-base alloys, which method consists in heating such alloys at a temperature above about 1100 C. but below the melting point of the alloys, and thereafter cooling them at a rate suiilcient to permit retention in the alloys at ordinary room temperatures of a predominantly austeniti'c structure.
  • the most preferable range is 1200' C. to 1300 C.
  • the invention also includes abrasion-resistant articles composed of high chromium-high carbon ironbase alloys, which articles are in the condition resulting from the heat treatment just described.
  • the alloys to which the heat treatment of the invention is most suitably applied contain about 10% to 40% chromium and 1% to 4% carbon, the remainder principally iron, Generally, to attain the desired structure by the heat treatment, the chromium content should 'be at least about 12% if the carbon content is near the low end of the range given, and if both the chromium content and the carbon content are near the low ends of their respective ranges, the presence of one or more austenite-promoting elements may be necessary in order to achieve this result.
  • the temperature at which the iron-chromiumcarbon alloys under discussion are heated in the practice of the invention is considerably higher than the temperature at which the same alloys are heated in the usual treatment designed to develop their greatest hardness.
  • magnetic, and X-ray diffraction tests indicate that when such alloys are cooled in air or quenched in oil from the high temperatures employed in the heat treatment of the invention, they have a predominantly austenitic structure.
  • the hardness of the alloys after this treatment is less than the maximum hardness that may be developed, the wear-resisting properties of the alloys are far superior to thos of similar alloys treated to develop maximum hardness.
  • austenite although itself relatively soft, is unstable and breaks down under conditions of use to a structure that is extremely resistant to abrasion.
  • an article to be treated may be heated in any conveninet-manner. Generally, it will be most convenient-to heat the entire article in a furnace. On occasion it may be desirable that it be heated electrically by induction or resistance heatingrand if the greatest degree of wear resistance is desired only locally, the heat treatment may be locally applied, as by an oxy-fuel gas torch. In all cases, to develop the greatest degree of wear resistance, the cooling rate should be sufliciently rapid to permit retention of an austenitic structure inthe alloy of which the article is composed. Generally, for articles having sections no greater than about /2 inch in thickness, cooling instill air is sufliciently rapid for the purpose. Articles hav- Microscopic,
  • heavier sections are preferably cooled more rapidly, as by an air blast or by quenching in a suitable liquid. Ordinarily, it is unnecesary that the articles be quenched in water, and too-rapid quenching should be avoided as it may cause cracking. 1
  • the heat treatment of the invention is applicable in general to ironbase alloys containing to 40% chromium and 1% to 4% carbon, the remainder principally iron.
  • the greatest degree of abrasion resistance is obtained by the invention in alloys containing 12% to 80% chromium and 1.5% to 3% carbon, remainder iron and, as incidental impurities, up to about 3% silicon and 5% manganese.
  • the heat treatment is also effective to enhance the wear resistance of high chromium alloys of the kind described, modified by the presence of minor proportions, say between about 0.1% and 5%, of the elements nickel, copper, cobalt, molybdenum, tungsten, vanadium, boron and nitrogen sometimes added to these alloys to improve their physical properties.
  • vanadium imparts a substantial improvement in the strength of the cast and heat treated alloys, as measured by the standard transverse strength and deflection tests for cast iron.
  • the presence of any of these elements with the exception of boron and vanadium makes possible the use of slightly lower heat treating temperatures than are required for the ordinary high chromium-high carbon alloys.
  • temperatures near the lower end of the range recited may be used for the heat treatment ofalloys containing not more than about 14% chromium, but in all cases the temperature of the heat treatment is above that employed for maximum hardening and is above about 1050 C.
  • the tests were conducted by using blades cast of the several materials to be tested. Each blade was weighed before being placed in the machine, the machine was used to'produce an abrasive blast for a measured period of time, and the blades were again weighed. The loss in weight of a blade caused by the abrasive action of the steel grit in the normal operation of the machine is a measure of the wear resistance of the blade. Results obtained in some of these tests are set forth in the following tables. All of the heattreated blades were cooled in still air from the treatment temperatures indicated.
  • Second test Blades composed of ello eontalnin 8 0' 20. 10: rest Is' I test gm for nao miziitesl 69% Rockwell We sh? hardness nut treatment Grams 11a 63 M 110111 Q 1,1)0' O 01 Third test [Blades composed of alloy containing 2.00% 0; assets r: rest Fe] Hard- Blade no" Heat treatment In the third test blades '7 and 8 failed by penetration; that is, a hole was worn through these blades. Blade 6, tested in the second test, was subsequently given a life test, which continued for 12,628 minutes before the blade was penetrated.
  • a method of improving the. resistance to abrasion of iron-base alloys containing about 10% to 40% chromium and about 1% to 4% carbon, the remainder principally iron which method consists in heating said alloys at a temperature above the temperature range at which alloys of such composition are customarily heated to develop maximum hardness and between about 1100 C. and their melting point and thereafter cooling said alloys at a rate sufllciently rapid to permit the retention in said alloys at ordinary roomtemperature of a predominantly austenitic structure.
  • a method of increasing the resistance to abrasion of iron-base alloys containing about 10% to 40% chromium and 1% to 4% carbon, 0.5% to 3% vanadium, silicon up to 3%, manganese up to 5%, the remainder substantially iron which method consists in heating said alloys at a temperature above the temperature range at which alloys of such composition are customarily heated to develop maximum hardness and between about 1200 C. and 1300" C. and thereafter cooling said alloys in air.
  • An abrasion-resistant article composed of an iron-base alloy containing about to 40% chromium, 1% to 4% carbon, and the remainder principally iron, said article being in the condition resulting from heating it at a temperature above the temperature range at which alloys of such composition are customarily heated to develop maximum hardness and between about 1100 0., and the melting point of the alloy of which it is composed, and thereafter cooling it at a rate sufliciently rapid to permit the retention at ordinary room'temperatures of a predominantly austenitic structure in the alloy.
  • An abrasion-resistant article composed of an iron-base cast alloy containing about 12% to chromium, about 1.5% to 3% carbon, 0.1% to 5% molybdenum, and the remainder principally iron, said article being in the condition resulting from heating it at a temperature above the temperature range at which alloys of such composition are customarily heated to develop maximum hardness and between about 1100 C. and 1300 C. and thereafter cooling it at a rate sufficiently rapid to permit the retention at ordinary room temperatures of a predominantly austenitic structure ln the alloy of which it is composed.
  • An abrasion-resistant article composed of a cast alloy containing about 12% to 30% chromium, about 1.5% to 3% carbon, and the remainder iron and incidental impurities, said article being in the condition resulting from heating it at a temperature above the temperature range at which alloys of such composition are customarily heated to develop maximum hardness and between about 1200 C. and 1300 C. and thereafter cooling it at arate suiliciently rapid to permit the retention at ordinary room temperatures of a predominantly austenitic structure in said alloy.

Description

Patented July 18, 1944 un'rnon F mraovmo masrou aasrs'rasca or annoys Charles 0. Burgess, Niagara Falls. N. 1., assignor to Electro-Metallurgieal Company, a corporation of West Virginia No Drawing. Application 0mm 5, 1942,
Serial No. 460,775
6 Claims. or. 10- 0) The invention relates to a method of improving the abrasion resistance of iron-base alloys containing chromium and to articles, composed of such alloys, having superior resistance to abrasion.
The abrasion, or wearing away, of metal articles during service in industry causes large monetary losses, involvingslrutdowns and labor and replacement costs. To combat abrasion, many special wear-resistant" alloys have been developed. However, the importance of the problem is such that efiorts continue to be made either toldevelop new wear-resistant materials or to improve the wear resistance of already known materials.
One material that has been used to some extent in applications where resistance to abrasion is required is an iron-base alloy containing about 12% to 30% chromium and 1.5% to 3% carbon, the remainder principally iron. Generally this alloy is used in the cast or wrought condition,-
but under some conditions of use it is heat treated before use, either to develop maximum hardness (by heating it at a temperature between about 900 C. and 1000 C. and cooling it in air or by an oil quench) or to develop maximum toughness (by heating it at about 700 C. to' 800 C. and cooling it in air). The abrasion resistance of this alloy is good, but improvement is desirable.
The present inventionhas for one of its obiects a method of improving the wear resistance of iron-base alloys containing chromium and carbon. Another object of the invention'is an abrasion resistant article composed of such alloys treated to impart thereto superior resistance to abrasion.
' In accordance with the invention, these objects are achieved by a heat treatment adapted to produce in such alloys a physical structure such that the alloys are rendered extremely resistant to abrasion. Specifically, the invention comprises a method of improving the abrasion-resistance of high chromium-high carbon iron-base alloys, which method consists in heating such alloys at a temperature above about 1100 C. but below the melting point of the alloys, and thereafter cooling them at a rate suiilcient to permit retention in the alloys at ordinary room temperatures of a predominantly austeniti'c structure. The most preferable range is 1200' C. to 1300 C. The invention also includes abrasion-resistant articles composed of high chromium-high carbon ironbase alloys, which articles are in the condition resulting from the heat treatment just described.
The alloys to which the heat treatment of the invention is most suitably applied contain about 10% to 40% chromium and 1% to 4% carbon, the remainder principally iron, Generally, to attain the desired structure by the heat treatment, the chromium content should 'be at least about 12% if the carbon content is near the low end of the range given, and if both the chromium content and the carbon content are near the low ends of their respective ranges, the presence of one or more austenite-promoting elements may be necessary in order to achieve this result.
The temperature at which the iron-chromiumcarbon alloys under discussion are heated in the practice of the invention is considerably higher than the temperature at which the same alloys are heated in the usual treatment designed to develop their greatest hardness. magnetic, and X-ray diffraction tests indicate that when such alloys are cooled in air or quenched in oil from the high temperatures employed in the heat treatment of the invention, they have a predominantly austenitic structure. Although the hardness of the alloys after this treatment is less than the maximum hardness that may be developed, the wear-resisting properties of the alloys are far superior to thos of similar alloys treated to develop maximum hardness. A possible explanation for this may be that austenite, although itself relatively soft, is unstable and breaks down under conditions of use to a structure that is extremely resistant to abrasion.
In the practiceoi the invention an article to be treated may be heated in any conveninet-manner. Generally, it will be most convenient-to heat the entire article in a furnace. On occasion it may be desirable that it be heated electrically by induction or resistance heatingrand if the greatest degree of wear resistance is desired only locally, the heat treatment may be locally applied, as by an oxy-fuel gas torch. In all cases, to develop the greatest degree of wear resistance, the cooling rate should be sufliciently rapid to permit retention of an austenitic structure inthe alloy of which the article is composed. Generally, for articles having sections no greater than about /2 inch in thickness, cooling instill air is sufliciently rapid for the purpose. Articles hav- Microscopic,
ing heavier sections are preferably cooled more rapidly, as by an air blast or by quenching in a suitable liquid. Ordinarily, it is unnecesary that the articles be quenched in water, and too-rapid quenching should be avoided as it may cause cracking. 1
As already pointed out, the heat treatment of the invention is applicable in general to ironbase alloys containing to 40% chromium and 1% to 4% carbon, the remainder principally iron. The greatest degree of abrasion resistance is obtained by the invention in alloys containing 12% to 80% chromium and 1.5% to 3% carbon, remainder iron and, as incidental impurities, up to about 3% silicon and 5% manganese. The heat treatment is also effective to enhance the wear resistance of high chromium alloys of the kind described, modified by the presence of minor proportions, say between about 0.1% and 5%, of the elements nickel, copper, cobalt, molybdenum, tungsten, vanadium, boron and nitrogen sometimes added to these alloys to improve their physical properties. I have particularly observed that about 0.5% to 3% vanadium imparts a substantial improvement in the strength of the cast and heat treated alloys, as measured by the standard transverse strength and deflection tests for cast iron. The presence of any of these elements with the exception of boron and vanadium makes possible the use of slightly lower heat treating temperatures than are required for the ordinary high chromium-high carbon alloys. Similarly, temperatures near the lower end of the range recited may be used for the heat treatment ofalloys containing not more than about 14% chromium, but in all cases the temperature of the heat treatment is above that employed for maximum hardening and is above about 1050 C.
In tests of the effectiveness of the heat treatment oi' the invention the abrasion resistance of alloys subjected to different heat treatments was compared. A "Rotoblast cleaning machine provided with a revolvable wheel much like a paddle wheel, having eight blades, was used for these tests. In operation, the wheel revolves at high speed, throwing an abrasive material, such as steel grit, against a surface to be cleaned. The blades are called upon-to withstand exceptionally severe conditions of wear..
The tests were conducted by using blades cast of the several materials to be tested. Each blade was weighed before being placed in the machine, the machine was used to'produce an abrasive blast for a measured period of time, and the blades were again weighed. The loss in weight of a blade caused by the abrasive action of the steel grit in the normal operation of the machine is a measure of the wear resistance of the blade. Results obtained in some of these tests are set forth in the following tables. All of the heattreated blades were cooled in still air from the treatment temperatures indicated.
First test [Blades composed of alloy containing 1.67% C; 18.24% Cr; rest Fe:
test runjor 672 minutes] Rockwell C H hardness Blade Heat treatment uh vb ats...
assaees Second test Blades composed of ello eontalnin 8 0' 20. 10: rest Is' I test gm for nao miziitesl 69% Rockwell We sh? hardness nut treatment Grams 11a 63 M 110111 Q 1,1)0' O 01 Third test [Blades composed of alloy containing 2.00% 0; assets r: rest Fe] Hard- Blade no" Heat treatment In the third test blades '7 and 8 failed by penetration; that is, a hole was worn through these blades. Blade 6, tested in the second test, was subsequently given a life test, which continued for 12,628 minutes before the blade was penetrated.
These tests demonstrate that in alloys 01' the kind tested, mere hardness is not a reliable criterion of wear resistance. Blades heat treated to develop maximum hardness were more readily worn than blades given the heat treatment of the invention, despite the fact that'the latter blades were considerably softer. The heat treatment of the invention, which provides an important increase in the wear resistance of the alloys, is conducted at a temperature higher than that used for maximum hardening.
Although particular examples of the application of the invention to particular alloys have been given herein, the invention is not limited to such examples. It is. applicable both to cast alloys, which usually have a chromium content near the higher end of the range given, and to wrought alloy which usually have chromium contents near the lower end oi the range, generally about 12% to 14%.
Iclaim:
1. A method of improving the. resistance to abrasion of iron-base alloys containing about 10% to 40% chromium and about 1% to 4% carbon, the remainder principally iron, which method consists in heating said alloys at a temperature above the temperature range at which alloys of such composition are customarily heated to develop maximum hardness and between about 1100 C. and their melting point and thereafter cooling said alloys at a rate sufllciently rapid to permit the retention in said alloys at ordinary roomtemperature of a predominantly austenitic structure.
2. A method of improving the resistance to abrasion of iron-base alloys containing about 10% to 40% chromium and about 1% to 4% carbon, the remainder principally iron, which consists in heating said alloys at a temperature above the temperature range at which alloys of such composition are customarily heated to de- 70 velop maximum hardness and between about 1100 C. and 1300 C. and thereafter cooling said alloys at a rate sufllciently rapid to permit the retention in said alloysat ordinary room temperatures of a predominantly austenitic strucure.
We lit.
3. A method of increasing the resistance to abrasion of iron-base alloys containing about 10% to 40% chromium and 1% to 4% carbon, 0.5% to 3% vanadium, silicon up to 3%, manganese up to 5%, the remainder substantially iron, which method consists in heating said alloys at a temperature above the temperature range at which alloys of such composition are customarily heated to develop maximum hardness and between about 1200 C. and 1300" C. and thereafter cooling said alloys in air.
4. An abrasion-resistant article composed of an iron-base alloy containing about to 40% chromium, 1% to 4% carbon, and the remainder principally iron, said article being in the condition resulting from heating it at a temperature above the temperature range at which alloys of such composition are customarily heated to develop maximum hardness and between about 1100 0., and the melting point of the alloy of which it is composed, and thereafter cooling it at a rate sufliciently rapid to permit the retention at ordinary room'temperatures of a predominantly austenitic structure in the alloy.
5. An abrasion-resistant article composed of an iron-base cast alloy containing about 12% to chromium, about 1.5% to 3% carbon, 0.1% to 5% molybdenum, and the remainder principally iron, said article being in the condition resulting from heating it at a temperature above the temperature range at which alloys of such composition are customarily heated to develop maximum hardness and between about 1100 C. and 1300 C. and thereafter cooling it at a rate sufficiently rapid to permit the retention at ordinary room temperatures of a predominantly austenitic structure ln the alloy of which it is composed.
6. An abrasion-resistant article composed of a cast alloy containing about 12% to 30% chromium, about 1.5% to 3% carbon, and the remainder iron and incidental impurities, said article being in the condition resulting from heating it at a temperature above the temperature range at which alloys of such composition are customarily heated to develop maximum hardness and between about 1200 C. and 1300 C. and thereafter cooling it at arate suiliciently rapid to permit the retention at ordinary room temperatures of a predominantly austenitic structure in said alloy.
CHARLES o. BURGESS.
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Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3414442A (en) * 1965-06-17 1968-12-03 Int Nickel Co Heat treatment of alloy cast iron
US3496031A (en) * 1966-10-17 1970-02-17 United States Steel Corp Steel mandrel plug and method of treating
US4716643A (en) * 1985-04-10 1988-01-05 Berchem & Schaberg Gmbh Method of making a machine part for abrasive applications
US6165288A (en) * 1994-05-17 2000-12-26 Ksb Aktienegsellschaft Highly corrosion and wear resistant chilled casting
US20100147247A1 (en) * 2008-12-16 2010-06-17 L. E. Jones Company Superaustenitic stainless steel and method of making and use thereof
US9284631B2 (en) * 2014-05-16 2016-03-15 Roman Radon Hypereutectic white iron alloys comprising chromium and nitrogen and articles made therefrom
US9580777B1 (en) 2016-02-08 2017-02-28 Roman Radon Hypereutectic white iron alloys comprising chromium, boron and nitrogen and articles made therefrom

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3414442A (en) * 1965-06-17 1968-12-03 Int Nickel Co Heat treatment of alloy cast iron
US3496031A (en) * 1966-10-17 1970-02-17 United States Steel Corp Steel mandrel plug and method of treating
US4716643A (en) * 1985-04-10 1988-01-05 Berchem & Schaberg Gmbh Method of making a machine part for abrasive applications
US6165288A (en) * 1994-05-17 2000-12-26 Ksb Aktienegsellschaft Highly corrosion and wear resistant chilled casting
US20100147247A1 (en) * 2008-12-16 2010-06-17 L. E. Jones Company Superaustenitic stainless steel and method of making and use thereof
US8430075B2 (en) 2008-12-16 2013-04-30 L.E. Jones Company Superaustenitic stainless steel and method of making and use thereof
US9284631B2 (en) * 2014-05-16 2016-03-15 Roman Radon Hypereutectic white iron alloys comprising chromium and nitrogen and articles made therefrom
US9580777B1 (en) 2016-02-08 2017-02-28 Roman Radon Hypereutectic white iron alloys comprising chromium, boron and nitrogen and articles made therefrom

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