序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
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1 | 用自生真空工艺制造大复合体的方法 | CN90104633.7 | 1990-07-16 | CN1033046C | 1996-10-16 | 罗伯特·坎贝尔·坎特; 拉特尼师·库玛·德维瓦迪 |
本发明涉及一种制造大复合体的新工艺,其中基体金属与放置在附近的合适填料或预型接触,或者与至少一种第二种材料接触,在工艺中至少某点,反应气氛和熔融基体金属和/或填料或预型和/或不渗透容器之间发生反应。熔融基体金属渗透入填料或预型,使得仍然基体金属与至少一种第二种材料的至少部分接触。将基体金属冷却至其熔点之下,形成金属基体复合体,由固结在至少一种第二种材料的至少一部分上的金属基体复合体所组成。 | ||||||
2 | 用自生真空工艺制造大复合体的方法及其产品 | CN90104633.7 | 1990-07-16 | CN1048894A | 1991-01-30 | 罗伯特·坎贝尔·坎特; 拉特尼师·库玛·德维瓦迪 |
本发明涉及一种制造大复合体的新工艺,其中基体金属与放置在附近的合适填料或预型接触,或者与至少一种第二种材料接触,在工艺中至少某点,反应气氛和熔融基体金属和/或填料或预型和/或不渗透容器之间发生反应。熔融基体金属渗透入填料或预型,使得仍然基体金属与至少一种第二种材料的至少部分接触。将基体金属冷却至其熔点之下,形成金属基体复合体,由固结在至少一种第二种材料的至少一部分上的金属基体复合体所组成。 | ||||||
3 | Ceramic filter element | US09803440 | 2001-03-09 | US06394281B2 | 2002-05-28 | Marcus A. Ritland; Dennis W. Readey; Richard N. Kleiner; Jack D. Sibold; Kyle Knudson; Steven Landin; Paul Thoen |
A process for sealing a ceramic filter by infiltrating a metal into an end of the filter is disclosed. The process includes the steps of contacting the end of a porous ceramic filter with a molten metal, whereby the metal enters into the ceramic matrix to substantially fill the void space. The ceramic filter is cooled to form a filter having a ceramic-metal composite portion. The present invention also provides a filter having an infiltrated metal seal. Methods for joining infiltrated ends are also provided. | ||||||
4 | Method of treating drying oil impregnated graphite electrode | US71627458 | 1958-02-20 | US2920004A | 1960-01-05 | CARLIN WILLIAM W |
5 | Method for sealing and/or joining an end of a ceramic filter | US09803440 | 2001-03-09 | US20010044999A1 | 2001-11-29 | Marcus A. Ritland; Dennis W. Readey; Richard N. Kleiner; Jack D. Sibold; Kyle Knudson; Steven Landin; Paul Thoen |
A process for sealing a ceramic filter by infiltrating a metal into an end of the filter. The process includes the steps of contacting the end of a porous ceramic filter with a molten metal, whereby the metal enters into the ceramic matrix to substantially fill the void space. The ceramic filter is cooled to form a filter having a ceramic-metal composite portion. The present invention also provides a filter having an infiltrated metal seal. Methods for joining infiltrated ends are also provided. | ||||||
6 | Method for sealing and/or joining an end of a ceramic filter | US08996680 | 1997-12-23 | US06247221B1 | 2001-06-19 | Marcus A. Ritland; Dennis W. Readey; Richard N. Kleiner; Jack D. Sibold; Kyle Knudson; Steven Landin; Paul Thoen |
A process for sealing a ceramic filter by infiltrating a metal into an end of the filter. The process includes the steps of contacting the end of a porous ceramic filter with a molten metal, whereby the metal enters into the ceramic matrix to substantially fill the void space. The ceramic filter is cooled to form a filter having a ceramic-metal composite portion. The present invention also provides a filter having an infiltrated metal seal. Methods for joining infiltrated ends are also provided. | ||||||
7 | Process of making insulating material | US18417527 | 1927-04-15 | US1799255A | 1931-04-07 | RUSS ARTHUR J |
8 | Electronic components incorporating ceramic-metal composites | US08820164 | 1997-03-19 | US06346317B1 | 2002-02-12 | Marcus A. Ritland; Dennis W. Readey; Jack D. Sibold; James E. Stephan |
The present invention relates to electronic components and in particular relates to ceramic-based electronic components wherein a portion of the component comprises a metal-infiltrated ceramic. In a preferred embodiment, the metal-infiltrated ceramic comprises copper metal. | ||||||
9 | Method for fluorination of diamond surfaces and associated product | US798311 | 1997-02-07 | US5840426A | 1998-11-24 | Vincent S. Smentkowski; John T. Yates, Jr. |
An improved method for the fluorination of a diamond surfaces comprises condensing a layer of perfluorinated alkyl iodides consisting of C.sub.n F.sub.2n+1 I (where n is a positive integer from 1 to 13) on the diamond surface, producing perfluorinated alkyl free radicals by photodecomposing C--I bonds of said perfluorinated alkyl iodides on the diamond surface, reacting the diamond surface with photochemically produced perfluorinated alkyl radicals thereby anchoring photochemically induced photofragments of the perfluorinated alkyl iodides to the diamond surface forming a perfluorinated alkyl layer, and decomposing the perfluorinated alkyl layer on the diamond surface to cause the fluorination of the diamond surface by atomic F. The method achieves greater than one fluorine atom per surface carbon atom chemisorbed on the diamond using C.sub.4 F.sub.9 I. A fluorinated diamond made by the above method is also disclosed wherein a fluorinating perfluoroalkyl iodide, C.sub.n F.sub.2n+1 I, is selected from the group consisting of n=1 to 5. In one case, the fluorinating perfluoroalkyl iodide is C.sub.4 F.sub.9 I. In another case, it is CF.sub.3 I. | ||||||
10 | Method for lubrication of diamond-like carbon surfaces | US764392 | 1996-12-11 | US5698272A | 1997-12-16 | Vincent S. Smentkowski; John T. Yates, Jr. |
An improved method for the lubrication of diamond-like carbon surfaces comprises condensing a layer of perflourinated alkyl halides of the formula C.sub.n F.sub.2n+1 X, wherein n is a positive integer from 1 to 13 and X is selected from I, Br and Cl, on the diamond-like carbon surface. Perflourinated alkyl free radicals are then produced by photodecomposing C--X bonds of said perflourinated alkyl halides on the surface. The diamond-like carbon surface is reacted with photochemically produced perflourinated alkyl radicals thereby anchoring photochemically induced photofragments of the perflourinated alkyl halides to the surface forming a perflourinated alkyl layer. The perfluorinated alkyl layer is preferably decomposed on the diamond-like carbon surface to cause the fluorination of the surface by atomic F. The method preferably achieves greater than one fluorine atom per surface carbon atom chemisorbed on the diamond-like carbon. The fluorination process produces lubricated diamond-like carbon surfaces that are particularly suitable for computer hard disks. | ||||||
11 | Method for fluorination of diamond surfaces | US521894 | 1995-08-31 | US5665435A | 1997-09-09 | Vincent S. Smentkowski; John T. Yates, Jr. |
An improved method for the fluorination of a diamond surfaces comprises condensing a layer of perfluorinated alkyl iodides consisting of C.sub.n F.sub.2n+1 I (where n is a positive integer from 1 to 13) on the diamond surface, producing perfluorinated alkyl free radicals by photodecomposing C--I bonds of said perfluorinated alkyl iodides on the diamond surface, reacting the diamond surface with photochemically produced perfluorinated alkyl radicals thereby anchoring photochemically induced photofragments of the perfluorinated alkyl iodides to the diamond surface forming a perfluorinated alkyl layer, and decomposing the perfluorinated alkyl layer on the diamond surface to cause the fluorination of the diamond surface by atomic F. The method achieves greater than one fluorine atom per surface carbon atom chemisorbed on the diamond using C.sub.4 F.sub.9 I. | ||||||
12 | Emissive coating | US30635263 | 1963-09-03 | US3404031A | 1968-10-01 | CLAYTON WILSON A; GUNDERSON JOSEPH M; SARGENT JOHN C |
13 | MINERAL SUBSTANCE PREVENTED FROM UNDERGOING BASIC REACTION AND METHOD OF PREVENTING SAID REACTION | EP90910949.8 | 1990-07-11 | EP0491946B1 | 1998-06-03 | TSUYUKI, Naomitsu, 20-35, Kanesugi 6-chome; OGASAWARA, Naochito, 1-33, Babahonmachi; GOTO, Kazumasa, Inax Corporation,; HIBINO, Takeshi, Inax Corporation |
A mineral substance substantially prevented from undergoing a reaction with a base, obtained by bringing a mineral substance containing silica and/or silicate and being reactive with a basic component into contact with hydrogen peroxide and/or ozone in the presence of water to thereby modify the reaction site(s) of the mineral substance. Said reactive mineral substance is exemplified by an aggregate for hydraulic cement and silicate ceramics. A similar effect can be attained by incorporating hydrogen peroxide and/or ozone in a cement concrete material composed of an aggregate reactive with a base, hydraulic cement and water. The invention is useful for the prolonged stabilization and prevention of contamination of the reactive mineral substance coexistent with a basic component. | ||||||
14 | MINERAL SUBSTANCE PREVENTED FROM UNDERGOING BASIC REACTION AND METHOD OF PREVENTING SAID REACTION | EP90910949.8 | 1990-07-11 | EP0491946A1 | 1992-07-01 | TSUYUKI, Naomitsu, 20-35, Kanesugi 6-chome; OGASAWARA, Naochito, 1-33, Babahonmachi; GOTO, Kazumasa, Inax Corporation,; HIBINO, Takeshi, Inax Corporation |
A mineral substance substantially prevented from undergoing a reaction with a base,obtained by bringing a mineral substance containing silica and/or silicate and being reactive with a basic component into contact with hydrogen peroxide and/or ozone in the presence of water to thereby modify the reaction site(s) of the mineral substance. Said reactive mineral substance is exemplified by an aggregate for hydraulic cement and silicate ceramics. A similar effect can be attained by incorporating hydrogen peroxide and/or ozone in a cement concrete material composed of an aggregate reactive with a base, hydraulic cement and water. The invention is useful for the prolonged stabilization and prevention of contamination of the reactive mineral substance coexistent with a basic component. |
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15 | SELF PROTECTING CARBON BODIES AND METHOD FOR MAKING SAME. | EP83903073 | 1983-09-09 | EP0119250A4 | 1985-02-18 | HOLZL ROBERT ALFRED |
A coated article and method of forming the same. The article is composed of a carbon body having a thermochemically deposited coating which renders the body resistant to oxidation at high temperatures. The coating is formed of a silicon alloy having a non-columnar grain distribution with substantially equiaxial grains of an average diameter of less than one micron. The amount of silicon in the coating is in excess of the alloy stoichiometry, producing infusion of silicon, with such at or above its melting temperature, into the cracked mosaic of the coating, to form an oxidative resistant glass filler. | ||||||
16 | Method of manufacturing a macro complex | JP18730790 | 1990-07-17 | JP3256219B2 | 2002-02-12 | クマール ドウィベディ ラトネシュ; キャンベル カントナー ロバート |
17 | Silicon thin film and its method of formation | JP31708491 | 1991-11-29 | JPH0562918A | 1993-03-12 | IHARA HISANORI; NOZAKI HIDETOSHI |
PURPOSE:To obtain a silicon thin film having low defect density on the interface between a supported substrate and the silicon thin film. CONSTITUTION:The title silicon thin film is characteristically formed by conducting a process, in which a supporting substrate 3 composed of silicon hydride is formed by an optical CVD method, and another process in which silicon hydride thin films 4b and 4c of 20nm or less in thickness are formed on the supporting substrate 3 by a plasma CVD method having the discharge power density of 100mW/cm<2> or higher. | ||||||
18 | Production of macro composite | JP18730790 | 1990-07-17 | JPH03138329A | 1991-06-12 | KANTNER ROBERT CAMPBELL; DWIVEDI RATNESH KUMAR |
PURPOSE: To produce a macro composite having a high adhesion property between a matrix metal and packing materials by forming a pressure difference within a sealed reaction system and penetrating the molten matrix metal into at least one kind of objects. CONSTITUTION: The packing materials or a preform 31 is arranged adjacently to the composite 29 of ceramic matrix, etc., which are a second material in an air impermeable vessel 32. The molten matrix metal 33 and a reaction atmosphere are housed into the vessel 32. The surface of the matrix metal 33 is provided with a hermetic sealing means 34 to isolate the reaction atmosphere from an ambient atmosphere. The lay-up 30 is put into a furnace kept at room temp. or process temp. and the molten matrix metal 33 is penetrated into the packing materials or the preform 31. The molten matrix metal is brought into contact with at least a part of the second material 29 by the formation of self-generated vacuum. The molten matrix metal 33 is then solidified and the formed macro composite is taken out. COPYRIGHT: (C)1991,JPO | ||||||
19 | Ceramic grinding grain coated with metal | JP31731087 | 1987-12-15 | JPS63162161A | 1988-07-05 | DEBUITSUDO AASAA KONDEITSUTO; HARII EDOUIN IITON |
Ceramic particles (18) useful as abrasives in a metal matrix layer are described. The particles are coated with an oxide monolayer (30) and a metal duplex layer. Preferably, the particles are silicon carbide; the oxide monolayer is aluminum oxide, and the metal duplex layer is a nickel-boron alloy (32) over pure nickel (31). | ||||||
20 | A method of forming macrocomposite bodies by self-generated vacuum techniques, and products produced therefrom | EP90630129.6 | 1990-07-16 | EP0409764B1 | 1995-03-08 | Kantner, Robert Campbell; Dwivedi, Ratnesh Kumar |