Producing Alloy Patents (Class 75/351)
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Patent number: 6749662Abstract: A relatively high carbon, water-atomized, steel shot is softened via annealing to render it suitable for ballistic use. The annealing preferably includes decarburization from a surface layer or throughout and preferably provides the shot with a surface Knoop hardness of less than 250.Type: GrantFiled: July 9, 2001Date of Patent: June 15, 2004Assignee: Olin CorporationInventors: Morris C Bueneman, Jack D. Dippold, Brian Mravic, Howard Muldrow, Peter W. Robinson
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Patent number: 6737017Abstract: An article of a base metal alloyed with an alloying element is prepared by mixing a chemically reducible nonmetallic base-metal precursor compound of a base metal and a chemically reducible nonmetallic alloying-element precursor compound of an alloying element to form a compound mixture. The alloying element is preferably thermophysically melt incompatible with the base metal. The method further includes chemically reducing the compound mixture to a metallic alloy, without melting the metallic alloy, and thereafter consolidating the metallic alloy to produce a consolidated metallic article, without melting the metallic alloy and without melting the consolidated metallic article.Type: GrantFiled: June 14, 2002Date of Patent: May 18, 2004Assignee: General Electric CompanyInventors: Andrew Philip Woodfield, Clifford Earl Shamblen, Eric Allen Ott
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Patent number: 6733562Abstract: A hard metal grade powder is produced from hard material, metal binder, and non-water-soluble pressing aid components, by forming a slurry containing the components and pure water as a liquid phase and then drying the slurry. Here, the hard material and metal binder components are first milled in water, to form a slurry. Then the pressing aid components are added to the slurry in the form of an emulsion produced with the aid of an emulsifier with the addition of water.Type: GrantFiled: November 22, 2002Date of Patent: May 11, 2004Assignee: Ceratizit Austria GmbHInventors: Gerhard Knünz, Helmut Beirer, Andreas Lackner, Wolfgang Glätzle, Erwin Hartlmayr
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Patent number: 6726741Abstract: Aluminum powder, neutron absorber, and third particle composed of oxide, nitride, carbide or boride are mixed, and preformed by cold isostatic pressing (CIP). Successively, by canning the preformed material, this preformed material is sintered by hot isostatic pressing (HIP). After sintering, the can outside and end face are machined by grinding, and the billet is taken out. Square pipes are formed by extruding this billet.Type: GrantFiled: February 1, 2001Date of Patent: April 27, 2004Assignee: Mitsubishi Heavy Industries, Ltd.Inventors: Kazuo Murakami, Kazumi Ogura, Toyoaki Yasui
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Patent number: 6719821Abstract: The production and selection of precursor mixtures used to produce fine powders and methods for making fine powders using the selected precursor. The precursor mixture comprises at least one metal containing precursor, the metal containing precursor has an average molecular weight of less than 2000 grams per unit mol of the metal, the metal containing precursor has a normal boiling point greater than 350K, and the viscosity of the precursor mixture is between 0.1 to 250 cP. The precursor mixture is processed under conditions that produce a fine powder from the precursor mixture. Fine powders produced are of size less than 100 microns, preferably less than 10 micron, more preferably less than 1 micron, and most preferably less than 100 nanometers.Type: GrantFiled: February 8, 2002Date of Patent: April 13, 2004Assignee: NanoProducts CorporationInventors: Tapesh Yadav, Elena Mardilovich
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Publication number: 20040055418Abstract: A method in which a metal powder is produced by ejecting a thermally decomposable metal compound powder into a reaction vessel through a nozzle together with a carrier gas under the condition V/S>600, where V is the flow rate of the carrier gas per unit time (liter/min), and S is the cross-sectional area of the nozzle opening part (cm2), and heating this metal powder at a temperature which is higher than the decomposition temperature of the metal compound powder and not lower than (Tm−200)° C., where Tm is the melting point of the metal, in a state where the metal compound powder is dispersed in the gas phase at a concentration of 10 g/liter or less. The method provides a fine, spherical, highly-crystallized metal powder which has a high purity, high density, high dispersibility and extremely uniform particle size, at low cost and using a simple process.Type: ApplicationFiled: September 8, 2003Publication date: March 25, 2004Inventors: Yuji Akimoto, Shinichi Ono, Kazuro Nagashima, Masayuki Maekawa, Hidenori Ieda
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Patent number: 6699305Abstract: Method for producing powdered metallic products by reacting aluminum subchloride vapor with a powdered oxide reactant such as Iron oxide, cobalt oxide, nickel oxide and boron oxide to form a solid metallic powder product mixed with aluminum oxide, together with aluminum trichloride vapor byproduct.Type: GrantFiled: September 7, 2001Date of Patent: March 2, 2004Inventor: James J. Myrick
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Patent number: 6699304Abstract: Provided are palladium-containing powders and a method and apparatus for manufacturing the palladium-containing particles of high quality, of a small size and narrow size distribution. An aerosol is generated from liquid feed and sent to a furnace, where liquid in droplets in the aerosol is vaporized to permit formation of the desired particles, which are then collected in a particle collector. The aerosol generation involves preparation of a high quality aerosol, with a narrow droplet size distribution, with close control over droplet size and with a high droplet loading suitable for commercial applications. Powders may have high resistance to oxidation of palladium. Multi-phase particles are provided including a palladium-containing metallic phase and a second phase that is dielectric. Electronic components are provided manufacturable using the powders.Type: GrantFiled: September 22, 2000Date of Patent: March 2, 2004Assignee: Superior Micropowders, LLCInventors: Mark J. Hampden-Smith, Toivo T. Kodas, Quint H. Powell, Daniel J. Skamser, James Caruso, Clive D. Chandler
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Publication number: 20040038067Abstract: The surface of the body of powder additive for use in powder metallurgy is coated with an organic binder, thereby obtaining powder additive to cause adhesion of the powder additive to the surface of iron-based powder by the organic binder, thereby providing a powder additive with no segregation of components and excellent flowability and compression, and an iron-based powder mixture manufactured by mixing the powder additive and the iron-based powder.Type: ApplicationFiled: May 21, 2003Publication date: February 26, 2004Applicant: JFE Steel Corporation, a corporation of JapanInventors: Yukiko Ozaki, Shigeru Unami, Satoshi Uenosono
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Publication number: 20040028922Abstract: Disclosed herein are capacitors having an anode based on niobium and a barrier layer based on niobium pentoxide, at least the barrier layer having a content of vanadium and process for their preparation and use.Type: ApplicationFiled: December 16, 2002Publication date: February 12, 2004Inventors: Karlheinz Reichert, Christoph Schnitter
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Patent number: 6689191Abstract: A method of converting metal-containing or metal alloy-containing compounds into a metal or metal alloy by rapidly heating the metal-containing or metal alloy-containing compound to an elevated temperature to instigate conversion and holding the metal-containing or metal alloy-containing compound at the elevated temperature for a time sufficient to effect formation of the metal or metal alloy is an efficient and economical method of producing metals and metal alloys.Type: GrantFiled: February 22, 2001Date of Patent: February 10, 2004Assignees: OMG Americas, Inc., The Regents of the University of ColoradoInventors: Stephen Dunmead, Kauko Johannes Karpale, Alan W. Weimer, Karen J. Buechler, Jacob A. Johnson
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Publication number: 20040016319Abstract: A metallic article is produced by furnishing one or more nonmetallic precursor compound comprising the metallic constituent element(s), and chemically reducing the nonmetallic precursor compound(s) to produce an initial metallic particle, preferably having a size of no greater than about 0.070 inch, without melting the initial metallic particle. The initial metallic particle is thereafter melted and solidified to produce the metallic article. By this approach, the incidence of chemical defects in the metal article is minimized. The melted-and-solidified metal may be used in the as-cast form, or it may be converted to billet and further worked to the final form.Type: ApplicationFiled: July 25, 2002Publication date: January 29, 2004Inventors: Andrew Philip Woodfield, Clifford Earl Shamblen, Eric Allen Ott
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Patent number: 6679937Abstract: Copper metal powders, methods for producing copper metal powders and products incorporating the powders. The copper metal powders have a small particle size, narrow size distribution and a spherical morphology. The method includes forming the metal particles in a continuous manner.Type: GrantFiled: June 2, 2000Date of Patent: January 20, 2004Assignee: Cabot CorporationInventors: Toivo T. Kodas, Mark J. Hampden-Smith, James Caruso, Daniel J. Skamser, Quint H. Powell, Clive D. Chandler
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Patent number: 6663688Abstract: The invention relates to sintered particles for use in wear applications and to a process for producing the sintered particles. The particles are of substantially spheroidal shape, have a grain size of 20 to 180 &mgr;m and have a predominantly closed porosity or are free of pores. The process for producing such particles starts from a powder material with a partially porous internal structure, which is introduced into a furnace and sintered at a temperature at which the material of the metallic binder adopts a pasty state while applying pressure to reduce the pore content of the starting material.Type: GrantFiled: June 17, 2002Date of Patent: December 16, 2003Assignee: WOKA Schweisstechnik GmbHInventors: Eberhard G. Findeisen, Richard F. Moll, Siegmund Kremmer
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Patent number: 6660058Abstract: The present invention relates to the preparation of nanoparticles of silver (Ag) and silver alloyed with other elements such as platinum (Pt), palladium (Pd), gold (Au), aluminum (Al), cadmium (Cd) and sulfur (S) in surfactant solutions. The surfactant molecules have the intrinsic property to adsorb into the interface, which are formed between two different phases. Thus, the surfactant molecules would adsorb into the surface of nuclei in solution. The adsorbed surfactant molecules from the solution prevent the coalescence of particles and control the rate of particle growth. By choosing the proper kind and/or concentration of surfactants, the size of particles formed in solution can be controlled in nm scale.Type: GrantFiled: August 22, 2000Date of Patent: December 9, 2003Assignee: Nanopros, Inc.Inventors: Seong-Geun Oh, Sung-Chul Yi, Seung-Il Shin, Dae-Wook Kim, Sung-Hoon Jeong
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Patent number: 6660431Abstract: The present invention relates to a hydrogen storage alloy electrode composed of a hydrogen storage alloy having a CaCu5 region and a Ce2Ni7 region in the crystal structure and satisfies the relational formula: p:q=1:(4+a), where p is the sum of the mole fraction of an element occupying the Ca site of the CaCu5 region and the mole fraction of an element occupying the Ce site of the Ce2Ni7 region, q is the sum of the mole fraction of an element occupying the Cu site of the CaCu5 region and the mole fraction of an element occupying the Ni site of the Ce2Ni7 region, and −0.2≦a≦0.4. Accordingly, although the hydrogen storage alloy electrode contains a little or no Co, it is possible to obtain an electrode having little deterioration due to pulverization of the alloy and a high capacity.Type: GrantFiled: August 8, 2001Date of Patent: December 9, 2003Assignee: Matsushita Electric Industrial Co., Ltd.Inventors: Sou Kuranaka, Akihiro Maeda, Yoshio Moriwaki
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Patent number: 6572672Abstract: Nanostructured non-stoichiometric materials are disclosed. Novel biomedical materials and their applications are discussed. More specifically, the specifications teach the use of nanotechnology and nanostructured materials for developing novel biomedical products.Type: GrantFiled: May 17, 2002Date of Patent: June 3, 2003Assignee: NanoProducts CorporationInventors: Tapesh Yadav, Ming Au, Bijan Miremadi, John Freim, Yuval Avniel, Roger Dirstine, John Alexander, Evan Franke
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Patent number: 6540811Abstract: This invention aims at providing a method of obtaining fine alloy powders, which are extremely small in particle size, high in purity, and uniform in composition, providing fine alloy powders obtained by this method, and providing molding materials, slurries, and electromagnetic shielding materials, which use these fine alloy powders. This invention provides a fine alloy powder production method, which is characterized in that after performing the process of mixing at least a trivalent titanium compound and a complexing agent, which binds with the trivalent titanium ion, in an aqueous solution containing two or more types of metal ion, the two or more types of metal are made to deposit simultaneously.Type: GrantFiled: January 16, 2001Date of Patent: April 1, 2003Assignees: Sumitomo Electric Industries, Ltd., Sumitomo Electric Fine Polymer, Inc.Inventors: Akihisa Hosoe, Shinji Inazawa, Masatoshi Majima, Katsuya Yamada, Hiroshi Okazaki, Souji Nishikawa, Toshio Shimotsuji
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Patent number: 6530972Abstract: A method for preparing a highly crystallized metal powder, involving the steps of: supplying at least one heat-decomposable metal compound powder into a reaction vessel using a carrier gas; and forming a metal powder by heating the metal compound powder in a state in which the metal compound powder is dispersed in a gas phase at a concentration of no more than 10 g/liter, at a temperature that is over the decomposition temperature of the metal compound powder and at least (Tm −200)° C. when the melting point of the metal contained in the metal compound powder is Tm° C. The method provides a high-purity, high-density, highly dispersible, fine, highly crystallized metal powder consisting of spherical particles of uniform size, which is suitable for use in thick film pastes, and particularly conductor pastes and the like used in the preparation of multilayer ceramic electronic parts.Type: GrantFiled: April 17, 2001Date of Patent: March 11, 2003Assignee: Shoei Chemical Inc.Inventors: Yuji Akimoto, Kazuro Nagashima, Hiroshi Yoshida, Hirotaka Takushima, Masayuki Maekawa
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Patent number: 6524366Abstract: Tungsten carbide is formed from a tungsten material which is preferably tungsten carbide scrap. If scrap material is used, this is oxidized and acid leached to remove impurities and any binder material. This is then dissolved in a solution of sodium hydroxide and spray dried to form a precursor compound. A carbon compound such as citric acid can be added to the solution prior to spray drying to provide a carbon source for the tungsten carbide. The powder formed from the spray dried solution is calcined and carburized to form tungsten carbide.Type: GrantFiled: September 22, 2000Date of Patent: February 25, 2003Assignee: N.V. Union Miniere S.A.Inventors: Purnesh Seegopaul, Lin Gao
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Patent number: 6521016Abstract: The present invention relates to a method of producing nanophase Cu—Al2O3 composite powder by means of 1) the producing precursor powders by centrifugal spray drying process using the water base solution, in which Cu-nitrate (Cu(NO3)23H2O) and Al-Nitrate (Al(NO3)39H2O) are solved to the point of final target composition (Cu-1 wt %/Al2O3),2) the heat treatment process (desaltation process) at the 850° C. for 30 min in air atmosphere to remove the volatile components such as the moisture and NO3 group in precursor powder and simultaneously to synthesize the nano CuO—Al2O3 composite powders by the oxidation of corresponded metal components and 3) the reduction heat treatment of CuO at 200° C. for 30 min in reducing atmosphere to produce the final nanophase Cu—Al2O3 composite powders with the size below 20 nm.Type: GrantFiled: April 5, 2001Date of Patent: February 18, 2003Assignee: Korea Institute of Machinery and MaterialsInventors: Byoung Kee Kim, Dong Won Lee
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Patent number: 6506228Abstract: A method for preparing a platinum alloy electrode catalyst for DMFC using anhydrous metal chlorides. The method includes reducing platinum chloride and non-aqueous second metal chloride with boron lithium hydride (LiBH4) in a water-incompatible organic solvent in a nitrogen atmosphere to form nano-sized particles of colloidal platinum alloy, and drying the platinum alloy particles without any heat treatment. The method of preparing a platinum alloy catalyst according to the present invention makes it possible to prepare platinum alloy particles having a narrow range of size distribution and an average particle size of less than 2 nm with ease, relative to the conventional methods. The platinum alloy particles thus obtained can be used as an electrode catalyst for DMFC to enhance methanol oxidation performance.Type: GrantFiled: March 23, 2001Date of Patent: January 14, 2003Assignee: Kwangju Institute of Science and TechnologyInventors: Seol Ah Lee, Kyung Won Park, Boo Kil Kwon, Yung Eun Sung
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Patent number: 6503291Abstract: Provided is a method for manufacturing a metal powder by providing a reducing solution by dispersing caustic alkali, and hydrazine and/or hydrazine hydrate into a solvent; providing a metal salt solution comprising a salt of electroconductive metal, a rare earth metal salt and a solvent; and mixing the reducing solution with the metal salt solution to form a metal powder by depositing a hydroxide derived from the rare earth metal salt and by reducing the salt of electroconductive metal. With this metal powder manufacturing method, the sintering of the metal powder is restricted at a low temperature, the sintering initiation temperature is shifted to a higher level, and rapid sintering shrinkage is restricted, while ceramic grain growth is not accelerated.Type: GrantFiled: April 24, 2001Date of Patent: January 7, 2003Assignee: Murata Manufacturing Co. Ltd.Inventors: Tadasu Hosokura, Atsuyoshi Maeda
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Publication number: 20030000340Abstract: A process is described for the preparation of powder mixtures or composite powders from at least one first type of powder from the group consisting of high-melting metals, hard materials and ceramic powders and at least one second type of powder from the group consisting of binder metals, binder-metal mixed crystals and binder-metal alloys, where the second type of powder is formed from precursor compounds in the form of water-soluble salts in an aqueous suspension of the first type of powder by precipitation as oxalate, removal of the mother liquor and reduction to the metal.Type: ApplicationFiled: June 18, 2002Publication date: January 2, 2003Inventors: Bernd Mende, Gerhard Gille, Ines Lamprecht
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Patent number: 6494932Abstract: Methods for recovery of naturally occurring nanoclusters are provided involving providing an aqueous nanocluster slurry and desorbing the nanoclusters from the surface of host substrate on which the nanoclusters are bound, followed by isolating the desorbed nanoclusters, and the isolated naturally occurring nanoclusters obtained thereby.Type: GrantFiled: June 6, 2000Date of Patent: December 17, 2002Assignee: Birch Mountain Resources, Ltd.Inventor: Hugh J. Abercrombie
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Publication number: 20020152842Abstract: An object of the present invention is to provide nitrogen-containing metallic powder at high productivity, which powder contains a metal such as niobium or tantalum containing nitrogen uniformly, and enables production of an anode electrode that has high specific capacitance and low leakage current and that exhibits excellent reliability for a prolonged period of time. There is provided nitrogen-containing metallic powder which is a solid solution containing 50-20,000 ppm nitrogen, in which the metal that constitutes the metallic powder is niobium or tantalum. The nitrogen-containing metallic powder is produced through the process in which while a metallic compound is reduced with a reducing agent, a nitrogen-containing gas is introduced into a reaction system to thereby form metal, and nitrogen is simultaneously incorporated into metal.Type: ApplicationFiled: June 20, 2002Publication date: October 24, 2002Applicant: CABOT SUPERMETALS K.K.Inventors: Yukio Oda, Tomoo Izumi, Yoshikazu Noguchi
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Patent number: 6464750Abstract: The invention relates to a method of preparing metal powder comprising: preparing a simple or mixed oxalate of one or more metals formed of particles with needle-like morphology having a mean acicularity ratio (length/diameter) of from 4 to 20, and a length of from 5 to 10 microns and converting said oxalate to metal or metal alloy powder by reducing treatment with gaseous hydrogen. The conversion of said oxalate can be carried out by decomposing said oxalate, in air, to an oxide and then reducing said oxide to metal or metal alloy. The metal is chosen from among the rare earth metals and the transition metals, preferably from among iron, cobalt, and nickel. The method is particularly suitable for making iron powder metal having a spongy and filament-like microstructure which makes it suitable for use in heating composition for thermo-piles. In addition, the invention relates to metal compacts unstoved or annealed which are obtained by applying compaction pressure to the powders according to the invention.Type: GrantFiled: June 12, 2000Date of Patent: October 15, 2002Assignees: ASB Aerospatiale Batteries, Universite Paul SabatierInventors: Philippe Tailhades, Valérie Carles, Abel Rousset
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Patent number: 6455746Abstract: The invention concerns ultrafine polymetallic particles obtained from reducing a mixture of salts dissolved in an organic solvent by an alkali or alkaline earth metal hydride, at a temperature not higher than the solvent reflux temperature, the mixture of dissolved salts comprising at least a salt of a metal having a standard oxidant potential E°Mn+/M at 25° C. higher than −1.18 V. The invention is applicable to the hydrogenation of olefins and the coupling of halogenated aromatic derivatives.Type: GrantFiled: March 21, 2000Date of Patent: September 24, 2002Assignee: Centre National de la Recherche ScientifiqueInventors: Jean-Marie Dubois, Yves Fort, Olivier Tillement
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Publication number: 20020129874Abstract: A method of making an alloy powder for an R—Fe—B-type rare earth magnet includes the steps of preparing a material alloy that is to be used for forming the R—Fe—B-type rare earth magnet and that has a chilled structure that constitutes about 2 volume percent to about 20 volume percent of the material alloy, coarsely pulverizing the material alloy for the R—Fe—B-type rare earth magnet by utilizing a hydrogen occlusion phenomenon to obtain a coarsely pulverized powder, finely pulverizing the coarsely pulverized powder and removing at least some of fine powder particles having particle sizes of about 1.0 &mgr;m or less from the finely pulverized powder, thereby reducing the volume fraction of the fine powder particles with the particle sizes of about 1.0 &mgr;m or less, and covering the surface of remaining ones of the powder particles with a lubricant after the step of removing has been performed.Type: ApplicationFiled: November 5, 2001Publication date: September 19, 2002Inventors: Yuji Kaneko, Junichiro Baba, Katsuya Taniguchi
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Publication number: 20020066338Abstract: High purity refractory metals, valve metals, refractory metal oxides, valve metal oxides, or alloys thereof suitable for a variety of electrical, optical and mill product/fabricated parts usages are produced from their respective oxides by metalothermic reduction of a solid or liquid form of such oxide using a reducing agent that establishes (after ignition) a highly exothermic reaction, the reaction preferably taking place in a continuously or step-wise moving oxide such as gravity fall with metal retrievable at the bottom and an oxide of the reducing agent being removable as a gas or in other convenient form and unreacted reducing agent derivatives being removable by leaching or like process.Type: ApplicationFiled: May 4, 2001Publication date: June 6, 2002Inventors: Leonid N. Shekhter, Terrance B. Tripp, Leonid L. Lanin, Anastasia M. Conlon, Howard V. Goldberg
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Publication number: 20020044877Abstract: A process for producing a thermoelectric material comprising mixing at least two of bismuth, tellurium, selenium, and antimony and, if desired, a dopant, melting the mixture, grinding the resulting alloy ingot, forming the powder, and sintering the green body under normal pressure, or hot pressing the powder, wherein the grinding and the normal sintering or hot pressing are carried out in the presence of a solvent represented by CnH2n+1OH or CnH2n+2CO (wherein n is 1, 2 or 3).Type: ApplicationFiled: February 23, 2001Publication date: April 18, 2002Inventors: Shinji Karino, Ryouma Tsukuda, Yuichi Anno, Isamu Yashima, Hitoshi Kajino
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Patent number: 6355087Abstract: The invention concerns a low pressure for the preparation of an iron-based, optionally alloyed powder comprising the steps of preparing a raw powder essentially consisting of iron and optionally at least one alloying element selected from the group consisting of chromium, manganese, copper, nickel, vanadium, niobium, boron, silicon, molybdenum and tungsten; charging a gas tight furnace with the powder in an essentially inert gas atmosphere and closing the furnace; increasing the furnace temperature; monitoring the increase of the formation of CO gas and evacuating gas from the furnace when a significant increase of the CO formation is observed and cooling the powder when the increase of the formation of CO gas diminishes.Type: GrantFiled: July 18, 2000Date of Patent: March 12, 2002Assignee: Höganäs ABInventors: Johan Arvidsson, Ola Eriksson
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Patent number: 6352571Abstract: One or more metal salts of at least one iron group metal containing organic groups are dissolved in at least one polar solvent and complex bound with at least one complex former comprising functional groups in the form of OH or NR3, (R═H or alkyl). In addition, at least one insoluble, reducible salt of at least one iron group metal is suspended in the solution. Hard constituent powder and, optionally, a soluble carbon source are added to the solution. The solvent is evaporated and the powder mass is heat treated in inert and/or reducing atmosphere. As a result, a powder mixture is obtained which, after addition of a pressing agent, can be compacted and sintered according to standard practice to form a body containing hard constituents in a binder phase.Type: GrantFiled: December 4, 1998Date of Patent: March 5, 2002Assignee: Sandvik ABInventors: Mats Waldenström, Rolf Svensson
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Patent number: 6350408Abstract: A process for producing finely divided 20 to 500 angstrom metal particles, metals with oxide coatings or metal oxides using an alkalide or electride in a non-reactive solvent is described. The process produces various forms of the metal depending upon the oxidizability of the metal initially produced by the process. The process is useful for producing catalysts, alloys, colloidal solutions, semi-conductors and the like.Type: GrantFiled: August 5, 1996Date of Patent: February 26, 2002Inventors: James L. Dye, Ahmed S. Ellaboudy, Kuo-Lih Tsai
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Publication number: 20020015889Abstract: A process for producing an electrode material for a rechargable lithium battery comprising the steps of mixing a metal compound (a) of a metal (a′) capable of being electrochemically alloyed with lithium, a transition metal compound (b) of a transition metal (b′) and a complexing agent (c) with a solvent (d) to obtain a mixed solution, mixing a reducing agent (e) with said mixed solution to obtain a mixture, and oxidizing said reducing agent in said mixture to reduce ion of said metal (a′) and ion of said transition metal (b′) to obtain an amorphous alloy material capable of being electrochemically alloyed with lithium as said electrode material. An electrode structural body in which said electrode material is used, and a rechargeable lithium battery in which said electrode material is used.Type: ApplicationFiled: March 13, 2001Publication date: February 7, 2002Inventors: Tomoya Yamamoto, Soichiro Kawakami, Hiroya Umeyama
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Publication number: 20010054328Abstract: The present invention relates to a method of producing nanophase Cu—Al2O3 composite powder by means of 1) the producing precursor powders by centrifugal spray drying process using the water base solution, in which Cu-nitrate (Cu(NO3)23H2O) and Al-Nitrate (Al(NO3)39H2O) are solved to the point of final target composition (Cu-1 wt %/Al2O3),2) the heat treatment process (desaltation process) at the 850° C. for 30 min in air atmosphere to remove the volatile components such as the moisture and NO3 group in precursor powder and simultaneously to synthesize the nano CuO—Al2O3 composite powders by the oxidation of corresponded metal components and 3) the reduction heat treatment of CuO at 200° C. for 30 min in reducing atmosphere to produce the final nanophase Cu—Al2O3 composite powders with the size below 20 nm.Type: ApplicationFiled: April 5, 2001Publication date: December 27, 2001Applicant: Korea Institute of Machinery and MaterialsInventors: Byoung Kee Kim, Dong Won Lee
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Publication number: 20010051102Abstract: A method for producing composite powders based on silver-tin oxide, by chemically reductive precipitation of silver onto particulate tin oxide. A solution of a silver compound and a solution of a reducing agent are simultaneously added in stoichiometrically equivalent amounts, separately and continuously with intensive mixing, to an aqueous suspension of tin oxide.Type: ApplicationFiled: April 4, 2001Publication date: December 13, 2001Inventors: Roger Wolmer, Mechthild Mueller, Frank Heringhaus, Dietrich Ruehlicke, Dan Goia
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Publication number: 20010037843Abstract: Provided is an inexpensive process for producing hydrogen absorbing alloy powder suitable for a nickel-metal hydride storage battery having a high rate discharge property, a high capacity and a long cycle life for repetition of charge and discharge. The process comprises a step of an addition of a rare earth metal oxide and/or hydroxide to a hydrogen absorbing alloy powder, a wet or dry mixing step and a thermal treatment step in an inert atmosphere or in a vacuum.Type: ApplicationFiled: June 19, 2001Publication date: November 8, 2001Applicant: Shin-Etsu Chemical Co., Ltd.Inventors: Naofumi Shinya, Hiroto Sugahara, Masatoshi Ishii
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Patent number: 6293989Abstract: The present invention relates to a method of producing nanophase WC/TiC/Co composite powder by means of a mechano-chemical process comprising a combination of mechanical and chemical methods. For this purpose, the present invention provides a method of producing nanophase WC/TiC/Co composite powder, said method comprising as follows: a process of producing an initial powder by means of spray-drying from water-soluble salts containing W, Ti, and Co; a process of heating to remove the salts and moisture contained in the initial powder after spray-drying; a process of mechanically ball-milling to grind oxide powder after removing the salts and moisture therefrom, and to homogeneously mix the powder with an addition of carbon; and a process of heating the powder after milling, for reduction and carburization, in an atmosphere of reductive gas or non-oxidative gas.Type: GrantFiled: May 31, 2000Date of Patent: September 25, 2001Assignee: Korea Institute of Machinery and MaterialsInventors: Byoung Kee Kim, Gook Hyun Ha, Dong Won Lee
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Patent number: 6277169Abstract: Provided are silver-containing powders and a method and apparatus for manufacturing the silver-containing particles of high quality, of a small size and narrow size distribution. An aerosol is generated from liquid feed and sent to a furnace, where liquid in droplets in the aerosol is vaporized to permit formation of the desired particles, which are then collected in a particle collector. The aerosol generation involves preparation of a high quality aerosol, with a narrow droplet size distribution, with close control over droplet size and with a high droplet loading suitable for commercial applications.Type: GrantFiled: February 24, 1998Date of Patent: August 21, 2001Assignee: Superior Micropowders LLCInventors: Mark J. Hampden-Smith, Toivo T. Kodas, Quint H. Powell, Daniel J. Skamser, James Caruso, Clive D. Chandler
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Patent number: 6273930Abstract: The present invention relates to a method of making a cemented carbide with submicron WC grain size with a powder metallurgical technique including milling, pressing and sintering. The method includes milling all components except WC for about three hours, then adding the WC powder and milling for about ten additional hours. In this way a cemented carbide powder with acceptable low compacting pressure is obtained.Type: GrantFiled: April 4, 2000Date of Patent: August 14, 2001Assignee: Sandvik ABInventor: Mats Waldenström
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Patent number: 6190785Abstract: This invention relates to a spray coating powder material which, when applied to gas turbines using a crude low-quality fuel oil as fuel, has sufficiently higher corrosion resistance to sulfur, vanadium, sodium and other substances that accelerate corrosion in a high-temperature service environment, than conventional materials such as Ni-50 Cr and MCrAlY materials, as well as high-temperature components coated therewith. Specifically, this invention relates to a spray coating powder material comprising, on a weight percentage basis, greater than 45% and up to 60% of chromium, 5 to 15% of aluminum, 0.5 to 10% of zirconium, and the balance comprising cobalt or iron, or both, and incidental impurities, as well as high-temperature components coated therewith. This material can yield a sprayed coating having high corrosion resistance to sulfur, vanadium, sodium and other substances that accelerate corrosion in a high-temperature service environment.Type: GrantFiled: January 29, 1999Date of Patent: February 20, 2001Assignee: Mitsubishi Heavy Industries, Ltd.Inventors: Toshio Yonezawa, Koji Fujimoto, Takashi Shige, Ikumasa Koshiro, Koji Takahashi
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Patent number: 6174345Abstract: The present invention relates to a method and apparatus of manufacturing nickel-metal-hydride alloy powder material. The furnace charge of nickel-metal-hydride alloy is melted in vacuum or argon atmosphere in this invention. After melting, the molten alloy is gas atomized to fine spherical powder or centrifugal atomized to flaky shape. Then the powders are fed into a hydrogen heat treatment chamber for hydrogen heat treatment and pulverization. This invention integrates the melting, pulverizing and hydrogen treatment of nickel-metal hydride alloy powder into a whole step. It can charge and pulverize continuously and is suitable for the large-scale industrialized production of homogeneous composition and least segregation nickel-metal hydride alloy powder.Type: GrantFiled: June 10, 1998Date of Patent: January 16, 2001Inventors: Yu Chen, Yun Cai, Dongping Yu, Xugeng Dai
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Patent number: 6165247Abstract: Platinum powders and methods for producing platinum powders. The powders preferably have a small particle size, narrow size distribution and a spherical morphology. The method includes forming the particles by a spray pyrolysis technique. The invention also includes novel devices and products formed from the platinum powders.Type: GrantFiled: February 24, 1998Date of Patent: December 26, 2000Assignee: Superior MicroPowders, LLCInventors: Toivo T. Kodas, Mark J. Hampden-Smith, James Caruso, Daniel J. Skamser, Quint H. Powell, Clive D. Chandler
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Patent number: 6159267Abstract: Provided are palladium-containing powders and a method and apparatus for manufacturing the palladium-containing particles of high quality, of a small size and narrow size distribution. An aerosol is generated from liquid feed and sent to a furnace, where liquid in droplets in the aerosol is vaporized to permit formation of the desired particles, which are then collected in a particle collector. The aerosol generation involves preparation of a high quality aerosol, with a narrow droplet size distribution, with close control over droplet size and with a high droplet loading suitable for commercial applications. Powders may have high resistance to oxidation of palladium. Multi-phase particles are provided including a palladium-containing metallic phase and a second phase that is dielectric. Electronic components are provided manufacturable using the powders.Type: GrantFiled: February 24, 1998Date of Patent: December 12, 2000Assignee: Superior Micropowders LLCInventors: Mark J. Hampden-Smith, Toivo T. Kodas, Quint H. Powell, Daniel J. Skamser, James Caruso, Clive D. Chandler
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Patent number: 6139658Abstract: The invention provides a method of making a titanium carbide metal matrix alloy, by firing a particulate reaction mixture comprising carbon, titanium and matrix material, under conditions such that the titanium and carbon react exothermically to form a dispersion of fine particles comprising titanium carbide (preferably less than 10 microns) in a predominantly metal matrix. The titanium and matrix are preferably added as a titanium alloy such as ferrotitanium, e.g. eutectic ferrotitanium. The reaction conditions are preferably selected so that during the reaction a molten zone moves through the body of the reaction mixture; the resulting hard particles are of globular form; and their average size is uniform throughout the resulting dispersion.Type: GrantFiled: September 23, 1997Date of Patent: October 31, 2000Assignee: London & Scandinavian Metallurgical Co., Ltd.Inventors: Peter Davies, James Leslie Frederick Kellie, Richard Nigel McKay, John Vivian Wood
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Patent number: 6126715Abstract: Metallurgical powder compositions are provided that contain a metal powder that is associated with a polymeric material in admixture with a solid, particulate polyether lubricant. The incorporation of the polyether lubricant enhances the green strength properties of compacted parts made from the powder compositions, and generally reduces the ejection forces required to remove the compacted part from the die cavity.Type: GrantFiled: January 5, 2000Date of Patent: October 3, 2000Assignee: Hoeganaes CorporationInventor: Sydney Luk
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Patent number: 6113668Abstract: The manufacture of powdered feed materials for hard fine grained metal body production includes the reduction of metal oxides into powdered metal and the subsequent carburization into metal carbide. Processes currently used are very cost intensive, mainly because of very long reaction times at high temperatures. According to applicant's economical process, the above reactions occur in the range of seconds and in a high-temperature cyclone as the reaction chamber. The apparatus is rather simple to construct. The stock to undergo reaction is continuously introduced into the chamber as a solid powdered phase with reaction gas and/or carrier gas, and passes through the chamber on predetermined paths for reaction, without leaving the solid state thereby.Type: GrantFiled: October 31, 1997Date of Patent: September 5, 2000Assignee: Schwarzkopf Technologies Corp.Inventors: Gunter Kneringer, Wolfgang Kock, Joachim Resch
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Patent number: 6103392Abstract: A high performance W--Cu composite powder is provided which is composed of individual particles having a tungsten phase and a copper phase wherein the tungsten phase substantially encapsulates the copper phase. The tungsten-coated copper composite powder may be pressed and sintered into W--Cu pseudoalloy articles having a homogeneous distribution of W and Cu phases without experiencing copper bleedout or it may be used in ceramic metallization for the electronics industry.Type: GrantFiled: November 17, 1995Date of Patent: August 15, 2000Assignee: Osram Sylvania Inc.Inventors: Leonid P. Dorfman, David L. Houck, Michael J. Scheithauer, Gail T. Meyers, Frank J. Venskytis
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Patent number: 6036742Abstract: Finely divided phosphorus-containing iron is prepared by reacting iron pentacarbonyl with a volatile phosphorus compound, in particular PH.sub.3, in the gas phase. The resulting phosphorus-containing iron powders and iron whiskers have a particularly low content of extraneous elements.Type: GrantFiled: February 12, 1998Date of Patent: March 14, 2000Assignee: BASF AktiengesellschaftInventors: Bernd Leutner, Gabriele Friedrich, Reinhold Schlegel