US1833099A - Method of making a composition of matter - Google Patents

Method of making a composition of matter Download PDF

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Publication number
US1833099A
US1833099A US413423A US41342329A US1833099A US 1833099 A US1833099 A US 1833099A US 413423 A US413423 A US 413423A US 41342329 A US41342329 A US 41342329A US 1833099 A US1833099 A US 1833099A
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United States
Prior art keywords
cobalt
cutting
particles
agent
binding
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Expired - Lifetime
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US413423A
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Elmer B Welch
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FIRTH STERLING STEEL CO
FIRTH-STERLING STEEL Co
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FIRTH STERLING STEEL CO
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Priority to US413423A priority Critical patent/US1833099A/en
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Classifications

    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C1/00Making non-ferrous alloys
    • C22C1/04Making non-ferrous alloys by powder metallurgy
    • C22C1/05Mixtures of metal powder with non-metallic powder
    • C22C1/051Making hard metals based on borides, carbides, nitrides, oxides or silicides; Preparation of the powder mixture used as the starting material therefor
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10STECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10S76/00Metal tools and implements, making
    • Y10S76/05Electric welding

Definitions

  • T his invention relates generally to a method of making a composition of matter having cutting or abrading characteristics.
  • Such compositions are suitable for making cutting a or abrading tools, such as bits, milling cutters, shapers, drills and the like. They are also suitable for makingdies, particularly dies for drawing wire.
  • compositions having cutting or abrading properties by mechanically mixing a finely divided cutting agent, such as tungsten carbide, with a finely divided binding agent, such as cobalt. These materials after being mixed are pressed into shape and are then heated, in order to sinter or fuse the binding, agent without, however, melting the cutting agent. This forms a composition in which the particles of cutting agent are embedded in a matrix of binding metal.
  • a finely divided cutting agent such as tungsten carbide
  • a cutting agent such as tungsten carbide
  • a binding agent such as cobalt
  • I coat the particles of cutting agent with a metallic binding agent, such as oobalt.
  • a metallic binding agent such as oobalt.
  • the particles of cutting agent having ametallic coating of cobalt thereon are pressed into a mass which will retain its shape and the mass is then heated in a furnace so as to sinter the binding agent without, however, melting the cutting agent.
  • I include hard materials, such as tungsten carbide, silicon carbide, chromium carbide or any material which has cutting or abrasive characteristics.
  • the binding metals which are used to coat the particles of cutting agent include cobalt, copper, nickel, iron or other suitable metal or alloy.
  • the binding agent may be composed of mixtures'or alloys of any of these metals.
  • the binding agent particles may be coated with two or more layers of the same or difi'erent binding, agents.
  • any of these cutting agents or binding agents may be used, depending upon the characteristics desired in the finished article, I have found that for most purposes I prefer to use tungsten car-' bide as the cuttin agent and cobalt as the binding agent. T e percentages of cutting agent and binding agent will vary accordin to the materials used as cutting agents an binding agents, and also according to the uses of the article.
  • the finely divided tungsten carbide particles are then coated with cobalt.
  • I have found it advantageous to coat the particles by electro-depositi'ng metallic cobalt thereon from a cobalt solution.
  • I may use a solution of cobalt sulphate, cobalt ammonium sulphate or cobalt chloride, preferably cobalt ammonium sulphate.
  • the tungsten carbide particles are placed on a nickel plate which forms the cathode, and metallic cobalt is used as the anode.
  • the cobalt plating may be carried out to such an extent that the cobalt constitutes from an effective amount up to about of the total weight of the tungsten carbide.
  • the preferred proportions are from about 3 to 13% of cobalt, and from 87% to about 96 of tungsten carbide.
  • the tungsten carbide, having each of its particles coated with cobalt is then pressed in a die and subjected to pressure while cold.
  • the pressure may be from 1000 to 300,000 pounds per square inch.
  • This compacting of the material enablesthe mass to be removed from the mold and transferred to a furnace.
  • the mass is given a first sintering at a temperature of about 1800 F.
  • the furnace is maintained under neutral or reducing conditions by the introduction of a gas, such, for example, as hydrogen, in order to prevent oxidation of thematerial.
  • a gas such, for example, as hydrogen
  • the article is allowed to cool in the furnace and after removal therefrom, it may be used for the purposes hereinbefore described.
  • the second sintering step results in an article which is very diflicult to grind or otherwise shape. For this reason", it is preferred to carry out the sintering in two steps, rather than in a single operation.
  • the loose coated particles may be placed in a mold and sintered. Pressure may be used to compress the particles either before, during, or after sintering, or it may be used both before and either during or after the sintering step. I prefer, however, to press the coated particles to shape while cold, and then sinter without applying pressure.
  • the metal which is used to coat the particles of cutting agent binds the particles OfCuttlIlg agent together when the mixture is sintered.
  • the sintering temperature is such that it fuses or melts the coating metal but does not melt the cutting agent.
  • the fused or melted binding metal itself forms the matrix in which the particles of cutting agent are embedded.
  • My process is distinguished from a process in which particles of cutting agent are first coated with a metal and then the coated particles are mixed with molten metal having point and which cannot be employed satis factorily where the article gets very hot when in use.
  • My invention contemplates the use of binding metals having relatively high melting points, so that even if the tool becomes highly heated when in use, the binding metal will not be melted but will firmly hold the particles of cutting agent.
  • a composition in' which cobalt is used as the. binding agent is suitablefor many uses where a composition containing zinc or other low melting point metal could not be used. This is true because-cobalt has a relatively high melting point, about 2690 F.
  • tungsten preferably utilize a carbide having approximately 6% of carbon combined with the tungsten. I have found that other carbides of tungsten produce compositions of materially different characteristics.
  • compositions of matter having cutting or ab-rading characteristics comprising coating finely divided particles of tungsten carbide with metallic cobalt by electrodepositing the cobalt thereon, and sintering the coated particles under non-oxiding conditionsat a temperature sut'ficient to melt the cobalt but not the tungsten carbide.
  • compositions of matter having cutting or abrading characteristics comprising coating finely divided p taeaoee particles of tungsten carbide with 8% to 18% of cobalt by electrodepositin the cobalt thereon, and sintering the coate particles at a temperature sufiicient to melt the cobalt I but not the tungsten carbide.
  • compositions of matter having cutting or abradmg characteristics comprising coatin finely divided particles of cutting agent wit cobalt by electrodepositing metallic cobalt from a cobalt solution on the particles, and sintering the coated particles at a temperature sufficient to melt the cobalt but notthe cutting agent.
  • compositions of matter having cutting'or abrading characteristics comprising coating finely divided particles of tungsten carbide .with cobalt by electrodepositing metallic cobalt from a co balt solution on the particles to provide a. .coating constituting from 3 to 13% of the weight of the coated particles, and sintering the coated particles under non-oxidizing conditions at a temperature sufiicient to melt the cobalt but not the tungsten carbide.
  • compositions of matter having cutting or abrading teristics comprising electrodepositm binding metal of the group including coba t, copper, nickel or iron, on finely divided particles of tungsten carbide to coat the particles with binding metal, compressing the coated articles, and sintering at a tem erature's cient to melt the binding metal ut not the tungsten carbide.

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  • Chemical & Material Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Materials Engineering (AREA)
  • Mechanical Engineering (AREA)
  • Metallurgy (AREA)
  • Organic Chemistry (AREA)
  • Powder Metallurgy (AREA)

Description

Patented New. 24, 1%31 ELMEB B. WELCH, OF MCKEESPORT, PENNSYLVANIA, ASSIGNOB TO FIRTH-STERLING STEEL COMPANY, OF MCKEESPORT, EENNSYLVANIA, A CORPORATION OF PENN- SYLVANIA METHOD OF MAKING A COMPOSITION OF MATTER No Drawing.
T his invention relates generally to a method of making a composition of matter having cutting or abrading characteristics. Such compositions are suitable for making cutting a or abrading tools, such as bits, milling cutters, shapers, drills and the like. They are also suitable for makingdies, particularly dies for drawing wire.
The present application is a continuation in part of my copending application Serial No. 301,692, filed August 23, 1928.
It has been proposed heretofore to make compositions having cutting or abrading properties by mechanically mixing a finely divided cutting agent, such as tungsten carbide, with a finely divided binding agent, such as cobalt. These materials after being mixed are pressed into shape and are then heated, in order to sinter or fuse the binding, agent without, however, melting the cutting agent. This forms a composition in which the particles of cutting agent are embedded in a matrix of binding metal.
It has been found that there is some dif-' ficulty in obtaining a homogeneous mixture of a finely divided cutting agent and binding agent when both the cutting agent and binding agent are in powdered form. This difficulty is increased when large percentages of cutting agent are mixed with small percentages of binding agent. For example, in cases where, say, 99.5% of cutting agent is to be used with about 0.5% of binding agent, it is very diliicult to obtain an even distribution of the binding agent throughout the mass of. cutting agent particles, by mechanically mixing the materials in powdered form. Another objection to mixing the cutting agent and binding agent while both materials are in powdered form is that a cutting agent, such as tungsten carbide, is'much heavier than a binding agent, such as cobalt, which results, after mixing, in the tungsten carbide, settling to the bottom. If a homogeneous mixture of cutting agent and binding agent is not provided, the article resulting from sintering the mixture of cutting agent and binding agent is not homogeneous and does not perform its function as efiiciently as an en-- tirely homogeneous body.
Application filed December 11, 1929. Serial No, 413,428.
In order to provide a homogeneous body of a mixture of cutting agent and binding agent, I coat the particles of cutting agent with a metallic binding agent, such as oobalt. The particles of cutting agent having ametallic coating of cobalt thereon are pressed into a mass which will retain its shape and the mass is then heated in a furnace so as to sinter the binding agent without, however, melting the cutting agent. This results in an article in which the particles of cutting agent are embedded in a matrix of binding agent, and in which the binding agent is evenly distributed throughout the mass, so as to provide a homogeneous prodnot.
As cutting agents, I include hard materials, such as tungsten carbide, silicon carbide, chromium carbide or any material which has cutting or abrasive characteristics. The binding metals which are used to coat the particles of cutting agent include cobalt, copper, nickel, iron or other suitable metal or alloy. The binding agent may be composed of mixtures'or alloys of any of these metals. The binding agent particles may be coated with two or more layers of the same or difi'erent binding, agents. Although any of these cutting agents or binding agents may be used, depending upon the characteristics desired in the finished article, I have found that for most purposes I prefer to use tungsten car-' bide as the cuttin agent and cobalt as the binding agent. T e percentages of cutting agent and binding agent will vary accordin to the materials used as cutting agents an binding agents, and also according to the uses of the article.
I will describe in detail the method which I prefer to employ when tungsten carbide is ness to which the tungsten carbide is ground will depend upon the article to be made and is not hmited to the degree of fineness above set forth. a
The finely divided tungsten carbide particles are then coated with cobalt. I have found it advantageous to coat the particles by electro-depositi'ng metallic cobalt thereon from a cobalt solution. I may use a solution of cobalt sulphate, cobalt ammonium sulphate or cobalt chloride, preferably cobalt ammonium sulphate. The tungsten carbide particles are placed on a nickel plate which forms the cathode, and metallic cobalt is used as the anode. The cobalt plating may be carried out to such an extent that the cobalt constitutes from an effective amount up to about of the total weight of the tungsten carbide. The preferred proportions are from about 3 to 13% of cobalt, and from 87% to about 96 of tungsten carbide.
After washing free from salts and drying the tungsten carbide, having each of its particles coated with cobalt, is then pressed in a die and subjected to pressure while cold. The pressure may be from 1000 to 300,000 pounds per square inch. This compacting of the material enablesthe mass to be removed from the mold and transferred to a furnace. The mass is given a first sintering at a temperature of about 1800 F. During the sintering the furnace is maintained under neutral or reducing conditions by the introduction of a gas, such, for example, as hydrogen, in order to prevent oxidation of thematerial. After the material has been allowed to cool in the furnace, it is removed conditions, at a temperature of about 2650 F. The article is allowed to cool in the furnace and after removal therefrom, it may be used for the purposes hereinbefore described. The second sintering step results in an article which is very diflicult to grind or otherwise shape. For this reason", it is preferred to carry out the sintering in two steps, rather than in a single operation.
Instead of first pressing the coated particles to shape and then sintering, the loose coated particles may be placed in a mold and sintered. Pressure may be used to compress the particles either before, during, or after sintering, or it may be used both before and either during or after the sintering step. I prefer, however, to press the coated particles to shape while cold, and then sinter without applying pressure.
I have described the use of tungsten carbide as the preferred cutting agent and cobalt as the preferred binding agent. However, other cutting agents or a mixture of cutting agents may be used with other metallic binding agents, or a mixture or alloy of other metallic binding agents.
In my process the metal which is used to coat the particles of cutting agent binds the particles OfCuttlIlg agent together when the mixture is sintered. The sintering temperature is such that it fuses or melts the coating metal but does not melt the cutting agent. The fused or melted binding metal itself forms the matrix in which the particles of cutting agent are embedded.
My process is distinguished from a process in which particles of cutting agent are first coated with a metal and then the coated particles are mixed with molten metal having point and which cannot be employed satis factorily where the article gets very hot when in use. My invention contemplates the use of binding metals having relatively high melting points, so that even if the tool becomes highly heated when in use, the binding metal will not be melted but will firmly hold the particles of cutting agent. A composition in' which cobalt is used as the. binding agent is suitablefor many uses where a composition containing zinc or other low melting point metal could not be used. This is true because-cobalt has a relatively high melting point, about 2690 F.
Throughout the foregoing description where I have referred to tungsten carbide, I-
preferably utilize a carbide having approximately 6% of carbon combined with the tungsten. I have found that other carbides of tungsten produce compositions of materially different characteristics.
I have described the present preferred manner of practicing my process. It will be understood, however, that the invention may be otherwise practiced within the scope of the following claims.
I claim as my invention:
1. The method of making compositions of matter having cutting or ab-rading characteristics, comprising coating finely divided particles of tungsten carbide with metallic cobalt by electrodepositing the cobalt thereon, and sintering the coated particles under non-oxiding conditionsat a temperature sut'ficient to melt the cobalt but not the tungsten carbide.
2. The method of making compositions of matter having cutting or abrading characteristics comprising coating finely divided p taeaoee particles of tungsten carbide with 8% to 18% of cobalt by electrodepositin the cobalt thereon, and sintering the coate particles at a temperature sufiicient to melt the cobalt I but not the tungsten carbide.
3. The method of making compositions of matter having cutting or abradmg characteristics, comprising coatin finely divided particles of cutting agent wit cobalt by electrodepositing metallic cobalt from a cobalt solution on the particles, and sintering the coated particles at a temperature sufficient to melt the cobalt but notthe cutting agent.
4. The method of making compositions of matter having cutting'or abrading characteristics, comprising coating finely divided particles of tungsten carbide .with cobalt by electrodepositing metallic cobalt from a co balt solution on the particles to provide a. .coating constituting from 3 to 13% of the weight of the coated particles, and sintering the coated particles under non-oxidizing conditions at a temperature sufiicient to melt the cobalt but not the tungsten carbide. I
5. The method of making compositions of matter having cutting or abrading teristics, comprising electrodepositm binding metal of the group including coba t, copper, nickel or iron, on finely divided particles of tungsten carbide to coat the particles with binding metal, compressing the coated articles, and sintering at a tem erature's cient to melt the binding metal ut not the tungsten carbide.
In testimonywhereof I have hereunto my hand.
ELMER B. WELCH.
cl1arac--
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Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2467596A (en) * 1946-11-08 1949-04-19 Bevil Company Manufacture of abrasive wheels
US2553714A (en) * 1947-03-05 1951-05-22 Carboloy Company Inc Process for making, and an article of, porous cemented carbide
US2578167A (en) * 1945-09-21 1951-12-11 Dentatus Ab Grinding wheel and method of producing same
US2729146A (en) * 1952-02-27 1956-01-03 Wandel Kurt Impellers for pulp disintegrating machines
US2729559A (en) * 1952-08-01 1956-01-03 Matsukawa Tatsuo Method of manufacturing electric contact material
US3071489A (en) * 1958-05-28 1963-01-01 Union Carbide Corp Process of flame spraying a tungsten carbide-chromium carbide-nickel coating, and article produced thereby
US3428543A (en) * 1964-05-09 1969-02-18 Starck Hermann C Fa Composite powders and apparatus for the production of the same
US4120758A (en) * 1975-09-09 1978-10-17 Rippere Ralph E Production of powder metallurgy alloys
US4356034A (en) * 1980-09-10 1982-10-26 Reed Rock Bit Company Method of reducing defects in powder metallurgy tungsten carbide elements
US5413016A (en) * 1993-04-05 1995-05-09 Ledermann Gmbh Method for manufacturing cutting tools and cutting tools made thereby

Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2578167A (en) * 1945-09-21 1951-12-11 Dentatus Ab Grinding wheel and method of producing same
US2467596A (en) * 1946-11-08 1949-04-19 Bevil Company Manufacture of abrasive wheels
US2553714A (en) * 1947-03-05 1951-05-22 Carboloy Company Inc Process for making, and an article of, porous cemented carbide
US2729146A (en) * 1952-02-27 1956-01-03 Wandel Kurt Impellers for pulp disintegrating machines
US2729559A (en) * 1952-08-01 1956-01-03 Matsukawa Tatsuo Method of manufacturing electric contact material
US3071489A (en) * 1958-05-28 1963-01-01 Union Carbide Corp Process of flame spraying a tungsten carbide-chromium carbide-nickel coating, and article produced thereby
US3428543A (en) * 1964-05-09 1969-02-18 Starck Hermann C Fa Composite powders and apparatus for the production of the same
US4120758A (en) * 1975-09-09 1978-10-17 Rippere Ralph E Production of powder metallurgy alloys
US4356034A (en) * 1980-09-10 1982-10-26 Reed Rock Bit Company Method of reducing defects in powder metallurgy tungsten carbide elements
US5413016A (en) * 1993-04-05 1995-05-09 Ledermann Gmbh Method for manufacturing cutting tools and cutting tools made thereby

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