US3032427A - Sintered product consisting of an aluminum oxide lattice and a metallic component filling the interstices of the lattice - Google Patents
Sintered product consisting of an aluminum oxide lattice and a metallic component filling the interstices of the lattice Download PDFInfo
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- US3032427A US3032427A US4860A US486060A US3032427A US 3032427 A US3032427 A US 3032427A US 4860 A US4860 A US 4860A US 486060 A US486060 A US 486060A US 3032427 A US3032427 A US 3032427A
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- C—CHEMISTRY; METALLURGY
- C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
- C22C—ALLOYS
- C22C32/00—Non-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
- the present invention relates to sintered metallic products which are highly resistant to very high temperatures and mechanical stresses, and whose major portion consists of a continuous phase or lattice of aluminum oxide with a metallic component filling the interstices of the aluminum oxide lattice.
- Such ductile metals as the metals of the iron and copper group have such a large boundary angle in relation to aluminum oxide that they do not adhere thereto satisfactorily so that these metals, when admixed to aluminum oxide powder, frequently emerge from the sintered body in the form of molten globules under the high temperatures required to sinter the aluminum oxide lattice.
- a metallic component of chromium carbon alloy containing from 1% to 16%, by weight, of carbon, preferably from 1% to 9%.
- the major portion of the sintered product consists of aluminum oxide, the minimum percentage, by weight, being at least about 60% and the maximum percentage preferably not exceeding 95%.
- auxiliary metallic component in addition to the chromium carbon alloy
- the auxiliary component being selected from the iron group, i.e. iron, cobalt and nickel, and being added to the aluminum oxide in an amount smaller than the amount of the chromium carbon alloy component.
- the preferred range of the chromium carbon alloy component in the sintered aluminum oxide product is between 40%, by weight, and 3% while the preferred range of the iron group component will preferably vary between about 2% by weight, and 15%.
- Corundum (aluminum oxide) powder of the desired particle size for instance between about 0.1g and a, is mixed with a minor portion of a chromium carbon alloy powder of the indicated composition, which may or may not contain a metal powder of the iron group, the particle sizes of the last-mentioned metallic components varying, for instance, between 0.1 1. and 5;.
- Chromium-carbon alloys particularly when the carbon is present therein primarily in a carbide linkage, wet corundum very well and, therefore, adhere strongly to the corundum matrix of the product. Furthermore, they are relatively good: heat and electrical conductors, giving the refractory product great stability under varying temperatures.
- the melting point of the chromium carbon alloys lies in the range o'fabout 1500 C. and 1900- C., thus encompassing' the Sintering temperature range of aluminum oxide.
- the preferred alloysjcontaining 1% to 9% carbon have a melting point not exceeding about 1700 C. Such alloys will melt at a sintering temperature in excess of 1700" C., which causes a particularly good distributionof the chromium carbon. alloy in the corundum matrix.
- a mixture ofchromium carbon alloy, nickel and corundum powder may be ground to a fine powder, compacted to assume a desired shape and sintered in aconventional manner to obtain a sintered corundum body having a chromium carbide-nickel phase finely distributed throughout the corundum matrix;
- the nickel addition was replaced partially or completely by iron and/ or cobalt without substantial changes in the results.
- Sintering must be effected in an oxygen-free atmosphere, for instance in a high vacuum, in an atmosphere of a noble gas or other gas mixtures free of oxygen.
- composition of the products and the carbon content of the chromium carbon alloys may vary within wide limits within the indicated ranges, the following specific example will illustrate the invention without in any way limiting it thereto:
- corundum powder having a particle size of 2 was mixed with 15%, by weight, of a chromium carbon alloy powder containing 12% carbon and having a particle size of in.
- the two components were finely comminuted in a ball mill where they were mixed under benzene for hours. After evaporating the volatile mixing liquid, the pulverulent mixture was compacted and shaped in a conventional die, whereupon the shaped compact was sintered for an hour at a temperature of 1850 C. in a high vacuum.
- the sintered product consists of a corundum lattice which has chromium carbon alloy distributed between the corundum crystals. Neither the hardness nor the mechanical resistance of the corundum body was substantially influenced by the addition which imparted great Z stability to the body under varying temperature conditions.
- Corundum products of this type are useful wherever refractory bodies and instruments are needed, such products also having a high resistance to'mechanical stress so that they may be used for cutting or shearing tools. Since they have good heat and electrical conductivity, they may also be used for sintered products requiring the latter characteristics. They will also find use, for instance, as material for the manufacture of turbine vanes, jet nozzles and machine parts of all types, which are subjected to abrasion.
- a refractory and abrasion resistant sintered product consisting essentially of at least about 60%, by weight, of aluminum oxide constituting a continuous lattice and at least 3 percent of a chromium carbon alloy, said alloy containing from 1% to 16%, by weight, of carbon and filling the interstices of the lattice, essentially all the carbon being present in a carbide linkage.
- a refractory and abrasion resistant sintered product consisting essentially of at least about 60%, by weight, of aluminum oxide constituting a continuous lattice, and a metallic component filling the interstices of the lattice, said component consisting of a chromium carbon alloy containing from 1% to 16%, by weight, of carbon, essentially all the carbon being present in a carbide linkage, and of at least one metal selected from the group consisting of iron, cobalt and nickel, the chromium carbon alloy being from about 3% to 38%, by weight, of the product and the metal being from about 2% to 15%, by weight, of the product.
- a refractory and abrasion resistant sintered product containing at least three' percent by weight of a chromium carbon alloy, said alloy containing one percent to sixteen percent carbon by weight, the remainder of said product being essentially aluminum oxide, said product containing at least sixty percent of said aluminum oxide.
- a refractory and abrasion resistant sintered product containing three to thirty-eight percent by weight of a chromium carbon alloy, said alloy containing one percent to sixteen percent carbon by weight; two percent to fifteen percent by weight of at least one metal selected from the group consisting of iron, cobalt, and nickel; the remainder of said product being essentially aluminum oxide, said product containing at least sixty percent of said aluminum oxide.
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Description
United States Patent lice SINTERED PRODUCT CONSISIlNG()FAN ALUMI-v NUM QXLDE, TTIC AND- A META LIC PONENT F U INIER II ES QF THE LATTICE i i Emil Klingler, Plochingen (N eckar), and Walther Dawihl,
Illingen (Saar), Germany, assiguors to Feldmuhle Papier-, uud Zellstotfwerke A. G'., Dusseldorf-(Iberkassel, Germany, a corporation of; Germany N Drawing. Filed Jan. 27, 1 960, Ser. No. 4,860 Claims priority, application Germany Feb. 20, 19 59.
' 7 Claims. (Cl. 10 6 ,-43
The present invention relates to sintered metallic products which are highly resistant to very high temperatures and mechanical stresses, and whose major portion consists of a continuous phase or lattice of aluminum oxide with a metallic component filling the interstices of the aluminum oxide lattice.
Sintered aluminum oxide products are known but the efforts to increase. their stability under varying temperatures by adding certain metal components thereto have not met with complete success because no. metallic component has been found to adhere satisfactorily to the aluminum oxide lattice when added in relatively small amounts in powdered form. The reason seems to have been that the metals in question do, not have sufficient adhesion to aluminum oxide, their boundary or wettingangle being too large. Accordingly, a metallic component will produce a technically valuable sintered material only if the metal component is so small that the coherence of the aluminum oxide lattice, which is the basis for the heat resistance of the material, is not Substantially influenced thereby. I Y
Such ductile metals as the metals of the iron and copper group have such a large boundary angle in relation to aluminum oxide that they do not adhere thereto satisfactorily so that these metals, when admixed to aluminum oxide powder, frequently emerge from the sintered body in the form of molten globules under the high temperatures required to sinter the aluminum oxide lattice.
It is a primary object of the present invention to find a metallic filler component for a sintered aluminum oxide product, which has a low wetting angle in relation to aluminum oxide and, therefore, adheres strongly to the aluminum oxide lattice.
The above and other objects are accomplished by using a metallic component of chromium carbon alloy containing from 1% to 16%, by weight, of carbon, preferably from 1% to 9%. The major portion of the sintered product consists of aluminum oxide, the minimum percentage, by weight, being at least about 60% and the maximum percentage preferably not exceeding 95%.
I have found it particularly advantageous to use an auxiliary metallic component in addition to the chromium carbon alloy, the auxiliary component being selected from the iron group, i.e. iron, cobalt and nickel, and being added to the aluminum oxide in an amount smaller than the amount of the chromium carbon alloy component. The preferred range of the chromium carbon alloy component in the sintered aluminum oxide product is between 40%, by weight, and 3% while the preferred range of the iron group component will preferably vary between about 2% by weight, and 15%.
Corundum (aluminum oxide) powder of the desired particle size, for instance between about 0.1g and a, is mixed with a minor portion of a chromium carbon alloy powder of the indicated composition, which may or may not contain a metal powder of the iron group, the particle sizes of the last-mentioned metallic components varying, for instance, between 0.1 1. and 5;. The
3,032,427 Patented May 1, 1962' 2. mixture is then shaped and sintered in a conventional manner to obtain the desired sintered product.
Chromium-carbon alloys, particularly when the carbon is present therein primarily in a carbide linkage, wet corundum very well and, therefore, adhere strongly to the corundum matrix of the product. Furthermore, they are relatively good: heat and electrical conductors, giving the refractory product great stability under varying temperatures.
The melting point of the chromium carbon alloys lies in the range o'fabout 1500 C. and 1900- C., thus encompassing' the Sintering temperature range of aluminum oxide. The preferred alloysjcontaining 1% to 9% carbon, have a melting point not exceeding about 1700 C. Such alloys will melt at a sintering temperature in excess of 1700" C., which causes a particularly good distributionof the chromium carbon. alloy in the corundum matrix.
We have found that the advantages ofthe chromium carbon alloy addition and, more particularly, its excellent wetting ability are not impaired if a metal of theiron group is added to the. mixture'to increase the ductility of the final product, The amount of the ductile metal component must be smaller, however, than the amount of chromium carbide.
For instance, a mixture ofchromium carbon alloy, nickel and corundum powder may be ground to a fine powder, compacted to assume a desired shape and sintered in aconventional manner to obtain a sintered corundum body having a chromium carbide-nickel phase finely distributed throughout the corundum matrix;
Unexpectedly, we have found that when we mixed 10%, by weight, of a chromium carbon alloy containing 11% carbon with 5%, byweight, of nickel and 85%, by weight, of aluminum oxide, and sintered the powder mixture at a temperature of about 1850 C., a body of good electrical conductivity throughout its entire cross section was produced. This proved that, despite the relatively small amount thereof, the chromium carbidenickel phase formed a continuous lattice of its own which completely permeated the entire sintered body. In this manner, there was produced a refractory sintered material with the desired even distribution of metallic components throughout the matrix of the material to obtain desirable characteristics such as stability under temperature changes, conductivity and ductility.
The nickel addition was replaced partially or completely by iron and/ or cobalt without substantial changes in the results.
Sintering must be effected in an oxygen-free atmosphere, for instance in a high vacuum, in an atmosphere of a noble gas or other gas mixtures free of oxygen.
While the exact composition of the products and the carbon content of the chromium carbon alloys may vary within wide limits within the indicated ranges, the following specific example will illustrate the invention without in any way limiting it thereto:
85%, by weight, of corundum powder having a particle size of 2 was mixed with 15%, by weight, of a chromium carbon alloy powder containing 12% carbon and having a particle size of in. The two components were finely comminuted in a ball mill where they were mixed under benzene for hours. After evaporating the volatile mixing liquid, the pulverulent mixture was compacted and shaped in a conventional die, whereupon the shaped compact was sintered for an hour at a temperature of 1850 C. in a high vacuum.
The sintered product consists of a corundum lattice which has chromium carbon alloy distributed between the corundum crystals. Neither the hardness nor the mechanical resistance of the corundum body was substantially influenced by the addition which imparted great Z stability to the body under varying temperature conditions.
Corundum products of this type are useful wherever refractory bodies and instruments are needed, such products also having a high resistance to'mechanical stress so that they may be used for cutting or shearing tools. Since they have good heat and electrical conductivity, they may also be used for sintered products requiring the latter characteristics. They will also find use, for instance, as material for the manufacture of turbine vanes, jet nozzles and machine parts of all types, which are subjected to abrasion.
While the invention has been described in connection with certain preferred embodiments thereof, it will be understood that many variations and modifications may occur to the skilled in the art without departing from the spirit and scope thereof, as defined in the appended claims.
We claim:
1. A refractory and abrasion resistant sintered product consisting essentially of at least about 60%, by weight, of aluminum oxide constituting a continuous lattice and at least 3 percent of a chromium carbon alloy, said alloy containing from 1% to 16%, by weight, of carbon and filling the interstices of the lattice, essentially all the carbon being present in a carbide linkage.
2. The sintered product of claim 1, wherein the chromium carbon alloy contains up to 9% of carbon in a carbide linkage.
3. The sintered product of claim 1, further comprising at least one metal selected from the group consisting of iron, nickel and cobalt in the interstices of the lattice, the amount of said metal being less than the amount of the chromium carbon alloy.
4. A refractory and abrasion resistant sintered product consisting essentially of at least about 60%, by weight, of aluminum oxide constituting a continuous lattice, and a metallic component filling the interstices of the lattice, said component consisting of a chromium carbon alloy containing from 1% to 16%, by weight, of carbon, essentially all the carbon being present in a carbide linkage, and of at least one metal selected from the group consisting of iron, cobalt and nickel, the chromium carbon alloy being from about 3% to 38%, by weight, of the product and the metal being from about 2% to 15%, by weight, of the product.
5. The sintered product of claim 4, wherein the chromium carbide contains up to 9% of carbon in a carbide linkage.
6. A refractory and abrasion resistant sintered product containing at least three' percent by weight of a chromium carbon alloy, said alloy containing one percent to sixteen percent carbon by weight, the remainder of said product being essentially aluminum oxide, said product containing at least sixty percent of said aluminum oxide.
7. A refractory and abrasion resistant sintered product containing three to thirty-eight percent by weight of a chromium carbon alloy, said alloy containing one percent to sixteen percent carbon by weight; two percent to fifteen percent by weight of at least one metal selected from the group consisting of iron, cobalt, and nickel; the remainder of said product being essentially aluminum oxide, said product containing at least sixty percent of said aluminum oxide.
References Cited in the file of this patent UNITED STATES PATENTS 1,246,165 Ruzieka Nov. 13, 1917 2,406,275 Wejnarth Aug. 20, 1946 2,768,266 Marsden Oct. 23, 1946 2,849,305 Frost Aug. 26, 1958 FOREIGN PATENTS 447,641 Canada Apr. 6, 1948 553,427 Canada Feb. 18, 1958 560,070 Canada July 8, 1958
Claims (1)
1. A REFRACTORY AND ABRASION RESISTANT SINTERED PRODUCT CONSISTING ESSENTIALLY OF AT LEAST ABOUT 60%, BY WEIGHT, OF ALUMINUM OXIDE CONSTITUTING A CONTINUOUS LATTICE AND AT LEAST 3 PERCENT OF A CHROMIUM CARBON ALLOY, SAID ALLOY CONTAINING FROM 1% TO 16%, BY WEIGHT, OF CARBON AND FILLING THE INTERSTICES OF THE LATTICE, ESSENTIALLY ALL THE CARBON BEING PRESENT IN A CARBIDE LINKAGE.
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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DE3032427X | 1959-02-20 |
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US3032427A true US3032427A (en) | 1962-05-01 |
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US4860A Expired - Lifetime US3032427A (en) | 1959-02-20 | 1960-01-27 | Sintered product consisting of an aluminum oxide lattice and a metallic component filling the interstices of the lattice |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3920485A (en) * | 1973-05-21 | 1975-11-18 | Us Navy | Thin insulating film containing metallic particles |
US5206484A (en) * | 1989-11-09 | 1993-04-27 | Battelle Memorial Institute | Glow-plug having ceramic base matrix and conducting element dispersed therein |
Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US1246165A (en) * | 1914-05-16 | 1917-11-13 | Charles Ruzicka | Electrical-resistance material. |
US2406275A (en) * | 1942-04-07 | 1946-08-20 | Wejnarth Axel Richard | Electrical resistance element |
CA447641A (en) * | 1948-04-06 | Francis Weeton Sydney | Hard composition | |
US2768266A (en) * | 1951-04-09 | 1956-10-23 | Phillips Petroleum Co | Electrical noise element |
CA553427A (en) * | 1958-02-18 | A. Conant Louis | Metal ceramic product | |
CA560070A (en) * | 1958-07-08 | C. Redmond John | Corrosion-resistant hard composition of matter | |
US2849305A (en) * | 1954-08-30 | 1958-08-26 | Nat Lead Co | Electric furnace product |
-
1960
- 1960-01-27 US US4860A patent/US3032427A/en not_active Expired - Lifetime
Patent Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CA447641A (en) * | 1948-04-06 | Francis Weeton Sydney | Hard composition | |
CA553427A (en) * | 1958-02-18 | A. Conant Louis | Metal ceramic product | |
CA560070A (en) * | 1958-07-08 | C. Redmond John | Corrosion-resistant hard composition of matter | |
US1246165A (en) * | 1914-05-16 | 1917-11-13 | Charles Ruzicka | Electrical-resistance material. |
US2406275A (en) * | 1942-04-07 | 1946-08-20 | Wejnarth Axel Richard | Electrical resistance element |
US2768266A (en) * | 1951-04-09 | 1956-10-23 | Phillips Petroleum Co | Electrical noise element |
US2849305A (en) * | 1954-08-30 | 1958-08-26 | Nat Lead Co | Electric furnace product |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3920485A (en) * | 1973-05-21 | 1975-11-18 | Us Navy | Thin insulating film containing metallic particles |
US5206484A (en) * | 1989-11-09 | 1993-04-27 | Battelle Memorial Institute | Glow-plug having ceramic base matrix and conducting element dispersed therein |
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