US1826456A - Metal aggregate - Google Patents

Metal aggregate Download PDF

Info

Publication number
US1826456A
US1826456A US270155A US27015528A US1826456A US 1826456 A US1826456 A US 1826456A US 270155 A US270155 A US 270155A US 27015528 A US27015528 A US 27015528A US 1826456 A US1826456 A US 1826456A
Authority
US
United States
Prior art keywords
cutting
aggregate
agent
agents
metallic
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
US270155A
Inventor
Gregory J Comstock
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.)
FIRTHSTERLING STEEL Co
Original Assignee
FIRTHSTERLING STEEL Co
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 FIRTHSTERLING STEEL Co filed Critical FIRTHSTERLING STEEL Co
Priority to US270155A priority Critical patent/US1826456A/en
Application granted granted Critical
Publication of US1826456A publication Critical patent/US1826456A/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
    • C22C32/00Non-ferrous alloys containing at least 5% by weight but less than 50% by weight of oxides, carbides, borides, nitrides, silicides or other metal compounds, e.g. oxynitrides, sulfides, whether added as such or formed in situ

Definitions

  • This invention relates broadly to an improved composition of matter, and more particularly to a metal aggregate comprising the combination of a cutting agent or cutting agents of abrasive characteristics and a binding agent or binding agents.
  • an alloy which consists of a tungstic carbide with a carbon content of from 4% to 10%, in combination with an auxiliary metal of a considerably lower melting point, as, for instance, iron, cobalt or nickel, in quantities up to a maximum of 10%.
  • the tungstic metal constitutes the predominating element and constitutes at least 80% of the total content of the alloy.
  • the eifect o the auxiliary or alloying metal is to reduce the sintering point of the body to such an extent that it occurs at temperatures which liein the neighborhood of 1,000 below the melting point of the carbide.
  • the temperature at whichthe sinteringoccurs is affected by the quantity of the admixed auxiliary metal, which can be made as high as 10% of the alloy.
  • I provide a metallic aggregate consisting of a cutting agent or agents of abrasive characteristics and a bindin agent or binding agents, suitable for the ormation of tools, such as bits, shapers, drills, cutters, saws and the like, as well as dies for both drawing and extrusion purposes. It also contemplates the producmetallic grinding stones, knife sharpeners and othersimilar devices, and tools requiring high abrasive or This,
  • the product result- 1ng from the practlce of my process is a homogeneous non-porous aggregate comprising a metallic oxide embedded in a matrix of a metallic binding agent.
  • the metallic oxide and the metallicbinding agent are not chemically combined, as is the case disclosed in the Schroter patent, nor is an alloy inany sense of the word formed.
  • the amount of metallic binding agent employed has no effect whatsoever on the melting temperature of the cutting or abrading material. Whether a small or a large percentage of binding agent is employed, it in noway affects the melting pointof the agent.
  • any proportion of a metallic binding agent up to 99% by weight of the resulting aggregate may be employed, and irrespective of the amount of binding agent employed, the melting temperature of the metallic oxide emagent remains the same.
  • I abrading agent or agents a suitable metallic binding agent or agents which serve to bond together the particles of the cutting agent.
  • cutting agents I may utilize vitrified zirconium oxide, tungsten carbide, silicon carbide, or any other suitable cutting or abrading agent.
  • bindingagents I may employ ployed as a cutting In carrying out utilize a cutting or nickel, cobalt, iron or chromium. The preferred comblnat on of cutting agent or agents is vitrified zirconium oxide as the cutting agent, and metallic nickel as the binding agent.
  • the cutting agent or agents and the binding agent or agents havingbeen reduced to cutting or abrading of water are provided.
  • the desired fineness are mixed together in varying proportions, depending upon the characteristics which are desired in the final composition. Where brittleness of the product is not a limiting factor, smaller percentages of metallic .binder may be used, but where strength and resistance to shock are required, larger percentages of binder must be present.
  • the cutting or abrading value of the abrasive, and likewise the cutting or abrading value of the product is necessarily decreased due to the relatively greater dispersion of the cutting particles.
  • I may utilize as high as 99% of the cutting agent .or cutting agents with desirable results, while in the latter case, where strength, and resistance to shock are the dominating characteristics desired, I may use up to, say, 99% of the metallic binding agent, or even higher.
  • an aggregate comprising only a trace of the cutting agent will show extremely great resistance to shock and extreme strength, and will, in addition, have improved cutting characteristics over alloys in which the cutting agent is not employed.
  • composition of matter of such nature that it lends itself to shaping and deformation by hot working.
  • I utilize not less than 30%, and preferably not less than 50% of the binding agent, although varia-- tions in this amount may be made one way or the other while retaining some degree of workability.
  • the resulting product is to have for its'specific application, I may proceed in accordance with any of four different methods.
  • the first of these involves .the pressing to shape followed by fusing without any subsequent pressure; the second involves the pressing to shape followed either in sequence or simultaneously by heat and pressure; the third involves the application of heat and pressure simultaneously without any preliminary pressure; while the fourth involves the application of heat followed by the application of pressure, without any preliminary pressing.
  • the cold compacting method I preferably form a paste by using a resinous material such, for example, as gum tragacanth, in the amount of one ounce of the gum tragacanth to a pint and add this paste -to the mixture of cutting agent or cutting agents and binding agent in the ratio of about of 1% by weight.
  • This mixture is then subjected to pressure while cold, the pressure preferably being of the order of 150 tons to the square inch.
  • the preliminary steps of forming a paste-like mixture, and pressing the same are followed. Thereafter this mixture is subjected to heat to 'fuse the binding agent, and either simultaneously with the application of the heat, or subsequently thereto while the mixture is still hot, is subtions, and thereafter, while stillhot, is subjected to pressure.
  • the second, third and fourth methods have the advantage of providing pressure at such a time 'as to tend to close up any pores which may have formed under the heat treatment by reason of the volatilization of any of the ingredients. Also, these three last-mentioned processes require a materially lower pressure, pressures as low as from? 7 5 to 150 pounds per square inch producing satisfactory results with some mixtures.
  • heating in each of the methods above referred to, I prefer to employ temperatures in the neighborhood of 2800 F., although it will be obvious that this temperature depends on the particular metallic binder employed, and may vary within fairl wide limits. During the heating, suitab e precautions must be taken to prevent oxidation of the product. Thismaybe accomplished, for example, by heating in a reducing atmosphere of hydrogen.
  • a sintered aggregate comprising finely divided vitrified zirconium oxide bonded in a matrix of nickel, the aggregate being amenable to shaping while hot, the nickel constituting at least of the aggregate.
  • a sintered aggregate comprising finely divided vitrified zirconium oxide bonded in a matrix of nickel, the aggregate being amenable to shaping while hot, the nickel constituting at least of the aggregate.
  • a sintered aggregate comprising finely divided vitrified zirconium oxide bonded in a matrix of nickel, the zirconium oxide constituting from a major portion to about 95% of the aggregate.
  • a sintered aggregate comprising finely divided vitrified zirconium oxide bonded in a matrix of nickel, the zirconium oxide constituting from about the aggregate.
  • sintered aggregate comprising finely divided vitrified zirconium oxide bonded in a matrix of nickel, the zirconium oxide constituting about 94% and the nickel about 6% of the aggregate.

Description

- vided state, serving tion of dressing tools,
mesa Get. a rear NET GREGORY .l'. COMSTOCK, 01F PITTSBURGH, BENNSYLVANIA,
STERLING STEEL COMPANY, OF MCKEESPOBT, PENNSYLVANIA,
PENNSYLVANIA ASSIGNOR TO FIRTH- A CORPORATION OF METAL AGGREGATE Ho Drawing.
This invention relates broadly to an improved composition of matter, and more particularly to a metal aggregate comprising the combination of a cutting agent or cutting agents of abrasive characteristics and a binding agent or binding agents.
It has heretofore been proposed in theart to which the present invention relates to provide hard metal alloys by combining tungstic carbide having from 3% to 10% carbon with not in excess of 10% of an alloying metal or alloying metals, preferably in a finely dito reduce the sintering temperature of the resulting mass. mass is then pressed into forms and the forms are sintered at a suitable temperature.
In the patent to Karl Schroter, No. 1,549,- 615, issued is described. According to the disclosure in the above-mentioned patent, an alloy is produced which consists of a tungstic carbide with a carbon content of from 4% to 10%, in combination with an auxiliary metal of a considerably lower melting point, as, for instance, iron, cobalt or nickel, in quantities up to a maximum of 10%. The tungstic metal constitutes the predominating element and constitutes at least 80% of the total content of the alloy.
Accordin to the disclosure in the patent, the eifect o the auxiliary or alloying metal is to reduce the sintering point of the body to such an extent that it occurs at temperatures which liein the neighborhood of 1,000 below the melting point of the carbide. The temperature at whichthe sinteringoccurs is affected by the quantity of the admixed auxiliary metal, which can be made as high as 10% of the alloy.
According to my invention, I provide a metallic aggregate consisting of a cutting agent or agents of abrasive characteristics and a bindin agent or binding agents, suitable for the ormation of tools, such as bits, shapers, drills, cutters, saws and the like, as well as dies for both drawing and extrusion purposes. It also contemplates the producmetallic grinding stones, knife sharpeners and othersimilar devices, and tools requiring high abrasive or This,
August 11, 1925', such a process,
- in' combination with Application filed April 14, 1928. Serial N0. 270,155.
cutting characteristics; The product result- 1ng from the practlce of my process is a homogeneous non-porous aggregate comprising a metallic oxide embedded in a matrix of a metallic binding agent. The metallic oxide and the metallicbinding agent are not chemically combined, as is the case disclosed in the Schroter patent, nor is an alloy inany sense of the word formed.
According to my invention, the amount of metallic binding agent employed has no effect whatsoever on the melting temperature of the cutting or abrading material. Whether a small or a large percentage of binding agent is employed, it in noway affects the melting pointof the agent.
Again, according to my mvent1on, any proportion of a metallic binding agent up to 99% by weight of the resulting aggregate may be employed, and irrespective of the amount of binding agent employed, the melting temperature of the metallic oxide emagent remains the same. the present invention, I abrading agent or agents a suitable metallic binding agent or agents which serve to bond together the particles of the cutting agent. As cutting agents, I may utilize vitrified zirconium oxide, tungsten carbide, silicon carbide, or any other suitable cutting or abrading agent. As bindingagents I may employ ployed as a cutting In carrying out utilize a cutting or nickel, cobalt, iron or chromium. The preferred comblnat on of cutting agent or agents is vitrified zirconium oxide as the cutting agent, and metallic nickel as the binding agent.
' I have found that desirable results may be accomplished by taking-the desired quantity of vitrified zirconium oxide or an equivalent abrasive, reducing the same to finely divided form, preferably such that it will pass through a 200 mesh screen, and mixing the same with a desired amount of a suitable metallic binding agent of the character herein referred to, preferably metallic nickel, which has been similarly finely divided.
The cutting agent or agents and the binding agent or agents havingbeen reduced to cutting or abrading of water,
the desired fineness, are mixed together in varying proportions, depending upon the characteristics which are desired in the final composition. Where brittleness of the product is not a limiting factor, smaller percentages of metallic .binder may be used, but where strength and resistance to shock are required, larger percentages of binder must be present.
It is notable that where the binder is increased, the cutting or abrading value of the abrasive, and likewise the cutting or abrading value of the product, is necessarily decreased due to the relatively greater dispersion of the cutting particles. For example, in cases of the character first referred to, that is, where brittleness of the product is not a limiting factor, I may utilize as high as 99% of the cutting agent .or cutting agents with desirable results, while in the latter case, where strength, and resistance to shock are the dominating characteristics desired, I may use up to, say, 99% of the metallic binding agent, or even higher. In fact, an aggregate comprising only a trace of the cutting agent will show extremely great resistance to shock and extreme strength, and will, in addition, have improved cutting characteristics over alloys in which the cutting agent is not employed.
In some cases it is desired to provide a composition of matter of such nature that it lends itself to shaping and deformation by hot working. In such cases, I utilize not less than 30%, and preferably not less than 50% of the binding agent, although varia-- tions in this amount may be made one way or the other while retaining some degree of workability.
.Having determined upon the proper composition depending upon the character which.
the resulting product is to have for its'specific application, I may proceed in accordance with any of four different methods. The first of these involves .the pressing to shape followed by fusing without any subsequent pressure; the second involves the pressing to shape followed either in sequence or simultaneously by heat and pressure; the third involves the application of heat and pressure simultaneously without any preliminary pressure; while the fourth involves the application of heat followed by the application of pressure, without any preliminary pressing.
In accordance with the first method, which will hereinafter be referred to as, the cold compacting method, I preferably form a paste by using a resinous material such, for example, as gum tragacanth, in the amount of one ounce of the gum tragacanth to a pint and add this paste -to the mixture of cutting agent or cutting agents and binding agent in the ratio of about of 1% by weight. This mixtureis then subjected to pressure while cold, the pressure preferably being of the order of 150 tons to the square inch.
This produces a closely compacted mixture which is then subjected to a temperature sufi'iciently high to melt the binding agent and cause it to actually flow around the cutting agent or cutting agents, so that upon cooling, such agent or agents will be substantially uniformly dispersed or distributed throughout, the product with each particle firmly bonded in the binding material, which in this case forms a metal matrix.
In the second method the preliminary steps of forming a paste-like mixture, and pressing the same, are followed. Thereafter this mixture is subjected to heat to 'fuse the binding agent, and either simultaneously with the application of the heat, or subsequently thereto while the mixture is still hot, is subtions, and thereafter, while stillhot, is subjected to pressure.
The second, third and fourth methods have the advantage of providing pressure at such a time 'as to tend to close up any pores which may have formed under the heat treatment by reason of the volatilization of any of the ingredients. Also, these three last-mentioned processes require a materially lower pressure, pressures as low as from? 7 5 to 150 pounds per square inch producing satisfactory results with some mixtures.
heating, in each of the methods above referred to, I prefer to employ temperatures in the neighborhood of 2800 F., although it will be obvious that this temperature depends on the particular metallic binder employed, and may vary within fairl wide limits. During the heating, suitab e precautions must be taken to prevent oxidation of the product. Thismaybe accomplished, for example, by heating in a reducing atmosphere of hydrogen.
In all cases where a paste has been formed by the use of a resinous material, the application of heat volatilizes the same from the mixture.
, The hardness of the composition in accordperature, to subject the mixture to pressure in a mold of the desired configuration of the finished article. In this manner, a completed article, such as a tool, can be formed directly from the mixture.
It is to be understood that the form of the invention described is the preferred embodiment and that the invention is not limited except as required by the appended claims, it being-understood that the examples herein specified are given by way of illustration only and not by way of limitation;
I claim: v
1. A sintered aggregate comprising finely divided vitrified zirconium oxide bonded in a matrix of nickel, the aggregate being amenable to shaping while hot, the nickel constituting at least of the aggregate.
2. A sintered aggregate comprising finely divided vitrified zirconium oxide bonded in a matrix of nickel, the aggregate being amenable to shaping while hot, the nickel constituting at least of the aggregate.
3. A sintered aggregate comprising finely divided vitrified zirconium oxide bonded in a matrix of nickel, the zirconium oxide constituting from a major portion to about 95% of the aggregate.
4. A sintered aggregate comprising finely divided vitrified zirconium oxide bonded in a matrix of nickel, the zirconium oxide constituting from about the aggregate.
5. sintered aggregate comprising finely divided vitrified zirconium oxide bonded in a matrix of nickel, the zirconium oxide constituting about 94% and the nickel about 6% of the aggregate. In testimony whereof have hereunto set no hand.
y GREGORY J. common.
% to about 95% of
US270155A 1928-04-14 1928-04-14 Metal aggregate Expired - Lifetime US1826456A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US270155A US1826456A (en) 1928-04-14 1928-04-14 Metal aggregate

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US270155A US1826456A (en) 1928-04-14 1928-04-14 Metal aggregate

Publications (1)

Publication Number Publication Date
US1826456A true US1826456A (en) 1931-10-06

Family

ID=23030140

Family Applications (1)

Application Number Title Priority Date Filing Date
US270155A Expired - Lifetime US1826456A (en) 1928-04-14 1928-04-14 Metal aggregate

Country Status (1)

Country Link
US (1) US1826456A (en)

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2698990A (en) * 1950-01-25 1955-01-11 Union Carbide & Carbon Corp Chromium-alumina metal ceramics
US2785974A (en) * 1952-07-09 1957-03-19 Plessey Co Ltd Process for producing metal ceramic compositions
US2789341A (en) * 1950-10-03 1957-04-23 Csf Ceramic refractory products
US2941281A (en) * 1953-12-04 1960-06-21 Int Nickel Co Hot workable, heat resistant metal bodies

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2698990A (en) * 1950-01-25 1955-01-11 Union Carbide & Carbon Corp Chromium-alumina metal ceramics
US2789341A (en) * 1950-10-03 1957-04-23 Csf Ceramic refractory products
US2785974A (en) * 1952-07-09 1957-03-19 Plessey Co Ltd Process for producing metal ceramic compositions
US2941281A (en) * 1953-12-04 1960-06-21 Int Nickel Co Hot workable, heat resistant metal bodies

Similar Documents

Publication Publication Date Title
US1913373A (en) Material for making tools
US2238351A (en) Grinding wheel
US2244053A (en) Hard cemented carbide composite
DE1243079B (en) Method of making an abrasive
US2137201A (en) Abrasive article and its manufacture
DE2056820A1 (en) Grinding wheel
US1910884A (en) Method of making hard metal compositions
US3165822A (en) Tungsten carbide tool manufacture
JPH081521A (en) Tool for processing abrasive grains bound using new metal bond and manufacture thereof
US2210039A (en) Method of making diamond tools
US2244052A (en) Method of forming hard cemented carbide products
US1826456A (en) Metal aggregate
US1981719A (en) Hard cemented carbide material
US2044853A (en) Method of making cutting tools, dies, etc.
US1833099A (en) Method of making a composition of matter
US2712988A (en) Industrial drilling tools
US2173833A (en) Abrasive article and its manufacture
US2561709A (en) Diamond-set tool
US2778757A (en) Carburized tungsten alloy article
US1826454A (en) Composition of matter
US3000087A (en) Sintered tungsten carbide alloy product
US1826457A (en) Composition of matter
US2942971A (en) Process of making cemented carbide products
US1822426A (en) Composition of matter and method of making the same
US2285909A (en) Cutting and grinding tools