Of Titanium Patents (Class 502/350)
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Patent number: 7605108Abstract: A catalyst which suppresses aggregation of metal particles and which has superior heat resistance. In the catalyst, metal particles are supported by a surface of a carrier while being partially embedded therein.Type: GrantFiled: July 5, 2005Date of Patent: October 20, 2009Assignee: Nissan Motor Co., Ltd.Inventors: Hironori Wakamatsu, Hirofumi Yasuda, Kazuyuki Shiratori, Masanori Nakamura, Katsuo Suga, Toru Sekiba
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Patent number: 7605106Abstract: Alkadienes may be telomerized in the presence of a heterogeneous catalyst comprising an alumina or titania support which is modified with one or more ionic complexes of Pd or Pt and activated at a temperature from 450° C. to 850° C. for a time not less than two hours. The resulting telomere may be useful in a number of applications.Type: GrantFiled: November 15, 2005Date of Patent: October 20, 2009Assignee: Nova Chemicals (International) S.A.Inventors: Antonio Pietro Nicola, Andrzej Krzywicki
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Patent number: 7601670Abstract: A method of producing catalyst powder of the present invention has a step of precipitating any one of a noble metal particle (5) and a transition metal particle (10) in a reversed micelle (1); a step of precipitating, in the reversed micelle (1) in which any one of the noble metal particle (5) and the transition metal particle (10) is precipitated, a porous support material (7) which supports the noble metal particle (5) and the transition metal particle (10); and a step of precipitating the other of the noble metal particle (5) and the transition metal particle (10) in the reversed micelle (1) in which any one of the noble metal particle (5).Type: GrantFiled: February 8, 2005Date of Patent: October 13, 2009Assignee: Nissan Motor Co., Ltd.Inventors: Hirofumi Yasuda, Katsuo Suga, Masanori Nakamura, Hironori Wakamatsu, Kazuyuki Shiratori, Toru Sekiba
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Patent number: 7601671Abstract: A method for preparing an exhaust gas catalyst includes preparing a washcoat comprising a catalytically effective amount of at least one catalytically active metal disposed upon an oxide support; disposing the catalytically active metal-oxide support washcoat upon a catalyst substrate; drying the washcoated catalyst substrate using microwave energy to affix the precious metals to the oxide support; and conventionally calcining the dried washcoated catalyst substrate. The catalysts comprising a substrate having dispersed thereon an inorganic oxide washcoat, the washcoat having been affixed to the substrate by microwave drying, exhibit high exhaust gas purifying performance and long durability. The catalysts thus produced further provide a long in-service lifetime for reforming organic fuel species into hydrogen, carbon monoxide and light hydrocarbons used in the nitrogen oxides reduction process.Type: GrantFiled: October 28, 2004Date of Patent: October 13, 2009Assignee: Umicore AG & Co. KGInventor: William J. LaBarge
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Patent number: 7598203Abstract: Provided are a hydrogenation catalyst for hydrocarbon oil, having markedly improved desulfurization activity, denitrogenation activity, and dearomatization activity; a carrier for the catalyst and its production; and a method of hydrogenation of hydrocarbon oil with the catalyst.Type: GrantFiled: January 17, 2007Date of Patent: October 6, 2009Assignee: Idemitsu Kosan Co., Ltd.Inventors: Narinobu Kagami, Ryuichiro Iwamoto
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Patent number: 7598204Abstract: A reagent suitable for use as a catalyst comprises a first metal species substrate having a second reduced metal species coated thereon, the second reduced metal species being less electropositive than the first metal. Methods of manufacture are also provided.Type: GrantFiled: September 19, 2005Date of Patent: October 6, 2009Assignee: General Motors CorporationInventors: Andrew M. Mance, Tao Xie, Belabbes Merzougui
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Patent number: 7598205Abstract: In a three-way catalyst for purifying exhaust gases from internal combustion engines, scattering of bismuth components can be suppressed by employing a Bi—Ti composite oxide at a predetermined ratio. Accordingly, the effect of suppressing hydrogen sulfide emissions can be retained for a long time. This catalyst comprises a support substrate, and a catalyst layer formed on the support substrate and including a noble metal, a porous oxide, and a Bi—Ti composite oxide, and satisfies 0.3?R?1.5, where R is the molar ratio of the Bi content to the Ti content per unit volume of the support substrate.Type: GrantFiled: January 27, 2006Date of Patent: October 6, 2009Assignee: Toyota Jidosha Kabushiki KaishaInventor: Hiromasa Suzuki
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Publication number: 20090239739Abstract: A catalyst 1 has a heat-resistant support 2 selected from among Al2O3, SiO2, ZrO2, and TiO2, and a first metal 4 supported on an outer surface of the support 2, and included by an inclusion material 3 containing a component of the support 2.Type: ApplicationFiled: December 5, 2005Publication date: September 24, 2009Inventors: Hirofumi Yasuda, Katsuo Suga, Makoto Aoyama, Toshiharu Miyamura
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Publication number: 20090238733Abstract: A honeycomb structure includes at least one honeycomb member including inorganic fibers and having walls extending along a longitudinal direction to define cells. A catalyst is provided on the wall in an amount of at least about 100 g and at most about 400 g per liter of volume of the honeycomb structure. The honeycomb member has a pore distribution measured using mercury porosimetry in which a pore distribution curve has a first peak in a range from about 0.005 ?m to about 0.03 ?m of a pore diameter, a second peak in a range from about 1 ?m to about 15 ?m of the pore diameter, and a third peak in a range from about 15 ?m to about 50 ?m of the pore diameter, where the curve is drawn by plotting the pore diameter (?m) on an X-axis and a log differential pore volume (mL/g) on a Y-axis.Type: ApplicationFiled: December 30, 2008Publication date: September 24, 2009Applicant: IBIDEN CO., LTD.Inventors: Kazushige OHNO, Kazutake Ogyu, Yusuke Kondo
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Publication number: 20090239742Abstract: The present disclosure relates to nanocrystalline titanium dioxide (TiO2) photocatalysts having nanocrystallites of less than 14 nanometers in diameter, which are substantially defect-free. The TiO2 photocatalysts form porous particles having a very large mass transfer surface area, large cylindrical pores, and low mass transfer resistance. The nanocrystalline TiO2 photocatalysts provide at least 75% of the photocatalytic activity of commercially-available TiO2 crystals having diameters greater than 20 nm. The nanocrystalline TiO2 photocatalysts may be doped with a metal, metal oxide, or non-metal dopant. A process for preparing the nanocrystalline TiO2 photocatalysts is disclosed. The present disclosure also provides methods for using nanocrystalline TiO2 photocatalysts to remove contaminants.Type: ApplicationFiled: May 31, 2007Publication date: September 24, 2009Applicant: CARRIER CORPORATIONInventors: Thomas Henry Vanderspurt, Treese Hugener-Campbell, Stephen O. Hay, Timothy N. Obee
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Patent number: 7592290Abstract: The invention relates to supported catalysts and a process for the production of these catalysts. These supported catalysts may be used in various reactions such as reforming reactions (e.g. steam methane reforming (SMR) reactions and autothermal reforming (ATR) reactions). In one aspect of the invention, the supported catalyst comprises a transition metal oxide; optionally a rare-earth metal oxide; and a transition metal aluminate.Type: GrantFiled: April 7, 2005Date of Patent: September 22, 2009Assignee: Sulzer Metco(Canada) Inc.Inventors: Syed Tajammul Hussain, Eugene Stelmack
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Patent number: 7592293Abstract: The present invention relates to processes for improving or optimizing a catalyst for the preparation of phthalic anhydride by gas-phase oxidation of o-xylene and/or naphthalene, which comprises the following steps: a) provision of a starting catalyst (C) comprising at least one first catalyst zone located towards the gas inlet and a second catalyst zone located closer to the gas outlet, with the catalyst zones preferably each having an active composition comprising TiO2; b) replacement of part of the first catalyst zone by an upstream zone of a catalyst having a higher activity than the first catalyst zone in order to provide an improved catalyst. Furthermore, an improved catalyst obtainable by this process is described.Type: GrantFiled: August 29, 2007Date of Patent: September 22, 2009Assignee: Sud-Chemie AGInventors: Christian Guckel, Harald Dialer, Marvin Estenfelder, Werner Pitschi
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Patent number: 7592294Abstract: A process is described for producing a catalyst for gas-phase oxidations, in which a suspension of TiO2 and V2O5 particles is applied to a fluidized inert support, wherein at least 90% by volume of the V2O5 particles have a diameter of 20 ?m or less and at least 95% by volume of the V2O5 particles have a diameter of 30 ?m or less. The defined particle size distribution of the V2O5 allows a high coating efficiency.Type: GrantFiled: September 24, 2004Date of Patent: September 22, 2009Assignee: BASF SEInventors: Sebastian Storck, Jürgen Zühlke, Samuel Neto, Frank Rosowski, Wolfgang Rummel
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Publication number: 20090232728Abstract: A water gas shift catalyst for use at temperatures above about 450° C. up to about 900° C. or so comprising rhenium deposited on a support, preferably without a precious metal, wherein the support is prepared from a high surface area material, such as a mixed metal oxide, particularly a mixture of zirconia and ceria, to which may be added one or more of a high surface area transitional alumina, an alkali or alkaline earth metal dopant and/or an additional dopant selected from Ga, Nd, Pr, W, Ge, Fe, oxides thereof and mixtures thereof.Type: ApplicationFiled: March 14, 2008Publication date: September 17, 2009Applicant: Sud-Chemie Inc.Inventors: Jon P. Wagner, Michael W. Balakos, Chandra Ratnasamy
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Patent number: 7585811Abstract: A method of producing catalyst powder of the present invention has a step of precipitating a noble metal particle (2) and a porous carrier (1) in a reversed micelle substantially simultaneously; and a step of precipitating a transition metal particle (3) in the reversed micelle. By this method, it is possible to obtain catalyst powder which restricts an aggregation of the noble metal particles even at a high temperature and is excellent in a catalytic activity.Type: GrantFiled: February 10, 2005Date of Patent: September 8, 2009Assignee: Nissan Motor Co., Ltd.Inventors: Masanori Nakamura, Katsuo Suga, Toru Sekiba, Hironori Wakamatsu, Kazuyuki Shiratori, Hirofumi Yasuda
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Publication number: 20090217922Abstract: A catalyst for cellulose hydrolysis and/or the reduction of hydrolysis products, in which a transition metal of group 8 to 11 is supported on a solid support. A method of producing sugar alcohols comprising: hydrolyzing cellulose in the presence of the catalyst in a hydrogen-containing atmosphere with pressurization; and reducing the hydrolysis product of cellulose. Provided are a catalyst for use in the production of sugar alcohols by the hydrolysis and hydrogenation of cellulose that affords easy separation of catalyst and product, and that does not require pH adjustment, acid or alkali neutralization, or activation of the catalyst during reuse, and a method of producing sugar alcohols from cellulose employing this catalyst.Type: ApplicationFiled: March 1, 2007Publication date: September 3, 2009Inventors: Atsushi Fukuoka, Paresh Dhepe
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Publication number: 20090221421Abstract: There is provided a catalyst for producing hydrogen comprising a porous body, as a support, comprising either one of an amorphous phase oxide and a composite oxide containing titanium and zirconium in which titanium has a mol ratio of 5 to 75% and zirconium has a mol ratio of 25 to 95% to the sum of these two, the porous body having a micro-hole diameter distribution peak in the range of 3 nm to 30 nm; and catalytic active metal grains carried on the a gas contact surface of the support, and the catalytic active metal has a content of 1 to 30% by mass to the sum of the porous body and the catalytic active metal, and a method of manufacturing thereof. This suppresses sintering or coking causing activity deterioration, thereby minimizing reaction ratio variations with time. A fuel reformer having the above catalyst, and a fuel cell having the fuel reformer are also provided.Type: ApplicationFiled: October 19, 2006Publication date: September 3, 2009Applicant: KYOCERA CORPORATIONInventors: Fumiaki Sagou, Yusaku Takita, Katsutoshi Nagaoka
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Patent number: 7582276Abstract: The invention relates to nanoscale rutile or oxide powder that is obtained by producing amorphous TiO2 by mixing an alcoholic solution with a titanium alcoholate and with an aluminum alcohalate and adding water and acid. The amorphous, aluminum-containing TiO2 is isolated by removing the solvent, and is redispersed in water in the presence of a tin salt. Thermal or hydrothermal post-processing yields rutile or oxide that can be redispersed to primary particle size. The n-rutile or the obtained oxide having a primary particle size ranging between 5 and 20 nm can be incorporated into all organic matrices so that they remain transparent. Photocatalytic activity is suppressed by lattice doping with trivalent ions. If the amorphous precursor is redispersed in alcohol, or not isolated, but immediately crystallized, an anatase is obtained that can be redispersed to primary particle size.Type: GrantFiled: August 30, 2002Date of Patent: September 1, 2009Assignee: ITN Nanovation AGInventor: Ralph Nonninger
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Patent number: 7582202Abstract: A Composition comprising one or more metal hydroxy salts and a matrix, binder or carrier material, wherein the metal hydroxy salt is a compound comprising (a) as metal either (i) one or more divalent metals, at least one of them being selected from the group consisting of Ni, Co, Ca, Zn, Mg, Fe, and Mn, or (ii) one or more trivalent metal(s), (b) framework hydroxide, and (c) a replaceable anion. This composition has various catalytic applications.Type: GrantFiled: February 10, 2004Date of Patent: September 1, 2009Assignees: Akzo Nobel N.V., Albemarle Netherlands B.V.Inventors: William Jones, Paul O'Connor, Dennis Stamires
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Patent number: 7582586Abstract: There is disclosed a process for producing a catalyst. The process includes the steps of: a) combining a dendrimer polymer and metal salt in solution forming a metal ion complex; b) exposing the metal ion complex to a reducing environment forming a dendrimer metal nanocomposite; c) depositing the dendrimer metal nanocomposite onto a catalyst support material; d) removing a solvent from the dendrimer metal nanocomposite forming metal clusters; and e) removing the dendrimer polymer forming a catalyst. Additionally, there is disclosed a catalyst having a catalytic metal deposited on a substrate. The catalytic metal is formed in clusters having a size of from 2 to 150 atoms. In another aspect, the clusters may have a spacing of from 2 to 100 nanometers between adjacent metal clusters. Further, in another aspect, the metal clusters which comprise the catalyst have a size distribution in which 70% of the clusters are within 0.6 nm of the average diameter and 99% of the particles are within 1.Type: GrantFiled: August 24, 2006Date of Patent: September 1, 2009Assignees: Toyota Motor Corporation, Toyotal Motor Engineering & Manufacturing North America, Inc.Inventors: Paul T. Fanson, Hirohito Hirata, Michael D. Amiridis, Christopher T. Williams, David S. Deutsch, Attilio Siani, Shinichi Matsumoto
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Publication number: 20090209415Abstract: A composite material includes an aggregate which contains a first metal particle constituting a core and second metal oxide particulates surrounding the first metal particle and having an average primary particle diameter ranging from 1 to 100 nm.Type: ApplicationFiled: July 20, 2006Publication date: August 20, 2009Applicant: KABUSHIKI KAISHA TOYOTA CHUO KENKYUSHOInventors: Tomoyuki Kayama, Kouzi Banno, Kiyoshi Yamazaki, Koji Yokota
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Patent number: 7576032Abstract: A catalyst composition which prevents deterioration due to grain growth of Rh and/or Pt, includes a perovskite-type composite oxide represented by the following general formula (1): A1?xA?xB1?(y+z)B?yNzO3??(1) wherein A represents at least one element selected from alkaline earth metals; A? represents at least one element selected from rare earth elements; B represents at least one element selected from Ti, Zr, and Hf; B? represents at least one element selected from transition elements (excluding rare earth elements, Ti, Zr, Hf, Rh, and Pt) and Al; N represents at least one element selected from Rh and Pt; x represents an atomic ratio satisfying the following condition: 0?x?0.4; y represents an atomic ratio satisfying the following condition: 0?y<0.5; z represents an atomic ratio satisfying the following condition: 0<z?0.5; and X represents 0 when N represents Pt alone.Type: GrantFiled: December 15, 2004Date of Patent: August 18, 2009Assignee: Daihatsu Motor Co., Ltd.Inventors: Hirohisa Tanaka, Isao Tan, Mari Uenishi, Masashi Taniguchi
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Patent number: 7576035Abstract: A pillar-shaped honeycomb structure has a plurality of cells longitudinally placed in parallel with one another with a wall portion therebetween, wherein the honeycomb structure mainly includes inorganic fibers which form the honeycomb structure without lamination interfaces.Type: GrantFiled: April 7, 2008Date of Patent: August 18, 2009Assignee: Ibiden Co., Ltd.Inventors: Kazushige Ohno, Tomokazu Oya
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Patent number: 7572427Abstract: The present invention is related to single and/or multiple-wall carbon nanotubes which may contain interstitial metals obtainable by a preparation process. The process includes a catalytic step using a catalytic system which includes a catalyst and a support. The support comprises hydroxides and/or carbonates or mixtures thereof with or without metal oxides. The present invention is also related to carbon fibers obtainable by said preparation process. The present invention also pertains in particular to said catalytic system and to said preparation process. Another aspect concerns the use of the nanotubes and of the catalytic system according to the invention.Type: GrantFiled: July 3, 2002Date of Patent: August 11, 2009Assignee: Facultes Universitaires Notre-Dame De La PaixInventors: Janos B. Nagy, Narasimaiah Nagaraju, Isabelle Willems, Antonio Fonseca
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Patent number: 7572543Abstract: A supported catalyst includes an oxide carrier, catalyst particles supported on the oxide carrier, and catalyst layers which locate among the catalyst particles, with interface portions among the oxide carrier, the catalyst particles and the catalyst layers. The catalyst layers have a melting point lower than 1,500° C. and contain an oxide or a composite oxide which includes at least one element selected from the group consisting of Mo, W, Sn and Ru.Type: GrantFiled: August 30, 2006Date of Patent: August 11, 2009Assignee: Kabushiki Kaisha ToshibaInventors: Wu Mei, Jun Tamura, Yoshihiko Nakano
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Patent number: 7572486Abstract: This invention is intended to provide a photocatalytic coating material which includes: at least (a) photocatalytic oxide particles; (b) a hydrophobic-resin emulsion; and (c) water, wherein the average particle size of the photocatalytic oxide particles is smaller than that of the particles dispersed in the hydrophobic-resin emulsion. This invention is also intended to provide a self-cleaning water-base coating composition which includes: (a) water-based silicone emulsion or the like; (b) photocatalytic particles or a photocatalytic sol; and (c) water, wherein the solid matter of the ingredient (b) constitutes less than 5% by weight of the total solid matter of the coating composition. This invention is also intended to provide a self-cleaning water-base coating composition which includes: (a) water-based silicone emulsion or the like; (b) whisker or the like; (c) photocatalytic particles; (d) an inorganic coloring pigment; and (e) water.Type: GrantFiled: May 30, 2003Date of Patent: August 11, 2009Assignees: Toto Ltd., JHCC Ltd.Inventors: Kazuo Takahashi, Akira Shimai, Mitsuhide Shimohigoshi, Norio Sendoda, Tatsuhiko Kuga, Koji Okubo, Kazumasa Okita
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Patent number: 7569510Abstract: Catalysts for the conversion, or oxidation, of carbon monoxide to carbon dioxide. Cigarettes with filters containing the catalysts have acceptable resistance to draw. Additionally, the catalysts can be used to reduce the concentration of carbon monoxide from a vehicle exhaust emission, a gas used in a CO2 laser, a gas used in a fuel cell and/or ambient air undergoing air filtration.Type: GrantFiled: January 26, 2007Date of Patent: August 4, 2009Assignee: Philip Morris USA Inc.Inventors: Sarojini Deevi, Padmanabha Reddy Ettireddy
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Patent number: 7569511Abstract: An alcohol steam reforming catalyst for generating hydrogen contains palladium, yttrium, and at least one of cerium and a metal oxide. The catalyst displays both an improved alcohol conversion rate and improved carbon dioxide selectivity. Methods of making and using the alcohol steam reforming catalyst are described.Type: GrantFiled: May 5, 2006Date of Patent: August 4, 2009Assignee: BASF Catalysts LLCInventors: Christopher R. Castellano, Ye Liu, Ahmad Moini, Gerald Stephen Koermer, Robert Joseph Farrauto
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Publication number: 20090191431Abstract: To smoothly deliver a thermal energy required in an active site of a catalyst carried on a carrier. A method of manufacturing a catalyst carrier of the present invention includes the steps of: forming a mixed thin film in which at least metal and ceramics are mixed on a metal base, by spraying aerosol, with metal powders and ceramics powders mixed therein, on the metal base; and making the mixed thin film porous, by dissolving the metal of the mixed thin film into acid or alkaline solution to remove this metal.Type: ApplicationFiled: January 28, 2009Publication date: July 30, 2009Applicant: HITACHI CABLE, LTD.Inventors: Mineo Washima, Kenji Shibata, Fumihito Oka
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Patent number: 7566393Abstract: Compounds and methods for sorbing organosulfur compounds from fluids are provided. Generally, compounds according to the present invention comprise mesoporous, nanocrystalline metal oxides. Preferred metal oxide compounds either exhibit soft Lewis acid properties or are impregnated with a material exhibiting soft Lewis acid properties. Methods according to the invention comprise contacting a fluid containing organosulfur contaminants with a mesoporous, nanocrystalline metal oxide. In a preferred embodiment, nanocrystalline metal oxide particles are formed into pellets (14) and placed inside a fuel filter housing (12) for removing organosulfur contaminants from a hydrocarbon fuel stream.Type: GrantFiled: April 26, 2005Date of Patent: July 28, 2009Assignee: NanoScale CorporationInventors: Kenneth Klabunde, Bill R. Sanford, P. Jeevanandam
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Patent number: 7563745Abstract: The invention relates to a shaped catalyst or catalyst precursor containing a catalytically active component or a precursor therefore, the component selected from elements of Group VIII of the Periodic Table of the Elements, supported on a carrier, which catalyst or catalyst precursor is an elongated shaped particle having three protrusions each extending from and attached to a central position, wherein the central position is aligned along the longitudinal axis of the particle, the cross-section of the particle occupying the space encompassed by the outer edges of six circles around a central circle, each of the six circles touching two neighboring circles while three alternating circles are equidistant to the central circle and may be attached to the central circle, minus the space occupied by the three remaining outer circles and including the six interstitial regions.Type: GrantFiled: June 6, 2003Date of Patent: July 21, 2009Assignee: Shell Oil CompanyInventors: Arend Hoek, Hans Michiel Huisman, Carolus Matthias Anna Maria Mesters
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Publication number: 20090180941Abstract: The present disclosure relates to a fluid purification device that has a deactivation resistant photocatalyst having nanocrystallites of less than 14 nanometers (nm) in diameter with at least 200 m2 surface area/cm3 of skeletal volume in cylindrical pores of 5 nm in diameter or larger, with the mode of the pore size distribution 10 nm or more.Type: ApplicationFiled: May 31, 2007Publication date: July 16, 2009Applicant: CARRIER CORPORATIONInventors: Thomas Henry Vanderspurt, Treese Hugener-Campbell, Norberto O. Lemcoff, Stephen O. Hay, Wayde R. Schmidt, Joseph J. Sangiovanni, Zissis A. Dardas, Di Wei
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Patent number: 7560606Abstract: The invention relates to Group 1 metal/porous metal oxide compositions comprising porous metal oxide selected from porous titanium oxide and porous alumina and an alkali metal or an alkali metal alloy. The compositions of the inventions are described as Stage 0 and I materials. These materials differ in their preparation and chemical reactivity. Each successive stage may be prepared directly using the methods described below or from an earlier stage material. Stage 0 materials may, for example, be prepared using liquid alloys of Na and K which are rapidly absorbed by porous metal oxide under isothermal conditions, preferably at or just above room temperature, to form loose black powders that retain much of the reducing ability of the parent metals. When the low melting Group 1 metals are absorbed into the porous metal oxide at about 150° C., an exothermic reaction produces Stage I material, loose black powders that are stable in dry air. Further heating forms higher stage materials of unknown composition.Type: GrantFiled: August 16, 2007Date of Patent: July 14, 2009Assignee: Signa Chemistry, Inc.Inventors: Michael Lefenfeld, James L. Dye
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Patent number: 7560409Abstract: Photo-oxidation catalysts and methods for cleaning a metal-based catalyst are disclosed. An exemplary catalyst system implementing a photo-oxidation catalyst may comprise a metal-based catalyst, and a photo-oxidation catalyst for cleaning the metal-based catalyst in the presence of light. The exposure to light enables the photo-oxidation catalyst to substantially oxidize absorbed contaminants and reduce accumulation of the contaminants on the metal-based catalyst. Applications are also disclosed.Type: GrantFiled: August 19, 2005Date of Patent: July 14, 2009Assignee: Alliance for Sustainable Energy, LLCInventors: J. Roland Pitts, Ping Liu, R. Davis Smith
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Patent number: 7560047Abstract: The present invention relates to a structured catalyst for reforming of gasoline and a method of preparing the same, more particularly to a structured catalyst for reforming of gasoline for fuel-cell powered vehicles prepared by wash-coating the transition metal based reforming catalyst on the surface of the ceramic honeycomb support wash-coated with sub-micron sized alumina or its precursor to sufficiently increase the effective surface area and the performance of the catalyst and a method of preparing the same.Type: GrantFiled: July 28, 2008Date of Patent: July 14, 2009Assignee: Korea Institute of Science and TechnologyInventors: Dong Ju Moon, Jong Woo Ryu, Dong Min Kang, Byung Gwon Lee, Byoung Sung Ahn, Sang Deuk Lee
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Patent number: 7557062Abstract: An unsupported catalyst composition which comprises one or more Group VIb metals, one or more Group VIII metals, and a refractory oxide material which comprises 50 wt % or more titania, on oxide basis, which is prepared by precipitation techniques, finds use in the hydroprocessing of hydrocarbonaceous feedstocks.Type: GrantFiled: February 20, 2004Date of Patent: July 7, 2009Assignee: Shell Oil CompanyInventors: Laszlo Domokos, Hermanus Jongkind, Willem Hartman Jurriaan Stork, Johanna Maria Helena Van den Tol-Kershof
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Patent number: 7556793Abstract: A method of forming a shaped article includes forming a mixture which includes a titania hydrate pulp having a loss on ignition of from about 10 to 45 wt. %, a seed material comprising a titanium oxide, at least a portion of the titanium oxide being in a rutile form, and optionally a dispersion aid. The method includes forming the mixture into a shaped article and firing the shaped article. A shaped article suitable for use as a catalyst carrier is at least 90% titanium oxide, greater than 80% of the titanium oxide being in the rutile phase. The article has a surface area of at least 2.5 m2/g and a mercury pore volume of greater than 0.15 cc/g.Type: GrantFiled: June 6, 2005Date of Patent: July 7, 2009Assignee: Saint-Gobain Ceramics & Plastics, Inc.Inventor: Stephen L. Dahar
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Patent number: 7553474Abstract: It is an object to provide a method for producing stable alkaline metal oxide sols having a uniform particle size distribution. The method comprises the steps of: heating a metal compound at a temperature of 60° C. to 110° C. in an aqueous medium that contains a carbonate of quaternary ammonium; and carrying out hydrothermal processing at a temperature of 110° C. to 250° C. The carbonate of quaternary ammonium is (NR4)2CO3 or NR4HCO3 in which R represents a hydrocarbon group, or a mixture thereof. The metal compound is one, or two or more metal compounds selected from a group of compounds based on a metal having a valence that is bivalent, trivalent, or tetravalent.Type: GrantFiled: August 8, 2005Date of Patent: June 30, 2009Assignee: Nissan Chemical Industries, Ltd.Inventors: Yutaka Ohmori, Hirokazu Kato, Yoshinari Koyama, Kenji Yamaguchi
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Patent number: 7553794Abstract: A supported catalyst comprising a support having supported thereon at least one member selected from the group consisting of heteropolyacids and heteropolyacid salts, in which the heteropolyacid and/or heteropolyacid salt is substantially present in a surface layer region of the support to a depth of 30% from the support surface. The catalyst has a high performance when used for the production of compounds by various reactions.Type: GrantFiled: November 27, 2003Date of Patent: June 30, 2009Assignee: Showa Denko K.K.Inventor: Masaaki Sakai
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Patent number: 7547656Abstract: An exhaust gas cleaning catalyst comprising: a carrier substrate; a catalyst carrying layer formed on the carrier substrate; and a noble metal catalyst carried by the catalyst carrying layer; wherein said catalyst carrying layer comprises at least two layers, and of the at least two layers, lower layer on the side of the carrier substrate is a metal oxide layer with porosity of 40˜75% and upper layer on the side of the top surface is a metal oxide layer having thermal conductivity of 5 W/mK or less.Type: GrantFiled: July 13, 2004Date of Patent: June 16, 2009Assignee: Toyota Jidosha Kabushiki KaishaInventor: Masahide Miura
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Patent number: 7544631Abstract: The present invention provides for titanium oxide-based photocatalysts having a general formula of TiO2-X-?CXN? and self-cleaning materials that are prepared by substituting O of pure TiO2 with C and N. A preparation method comprising a process for forming thin films of TiO2-X-?CXN? by using gases such as Ar, N2, CO2, CO and O are used for reactive sputtering, and a process of heat treating at around 500° C., thereby crystallizing, is provided. The titanium oxide-based photocatalysts having a general formula of TiO2-X-?CXN? and self-cleaning materials according to the present invention have a smaller optical bandgap compared to pure titanium oxides, and therefore, the photocatalysts can be activated under the visible light range. In addition, they comprise only pure anatase crystallization phase, and since the crystallized particles are small in size, the efficiency and self-cleaning effect of the photocatalysts are very high.Type: GrantFiled: April 26, 2006Date of Patent: June 9, 2009Assignee: Korea Institute of Science and TechnologyInventors: Won-Kook Choi, Yeon-Sik Jung, Dong-Heon Kang, Kyung-Ju Lee
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Patent number: 7544285Abstract: A bulk metal oxide catalyst composition of the general formula (X)b(M)c(Z)d(O)e??(I) wherein X represents at least one non-noble Group VIII metal; M represents at least one non-noble Group VIb metal; Z represents one or more elements selected from aluminium, silicon, magnesium, titanium, zirconium, boron, and zinc; one of b and c is the integer 1; and d and e and the other of b and c each are a number greater than 0 such that the molar ratio of b:c is in the range of from 0.5:1 to 5:1, the molar ratio of d:c is in the range of from 0.2:1 to 50:1, and the molar ratio of e:c is in the range of from 3.7:1 to 108:1; is prepared by controlled (co)precipitation of component metal compounds, refractory oxide material, and alkali compound in protic liquid. Resulting compositions find use in hydrotreatment processes involving particularly hydrodesulphurisation and hydrodenitrification.Type: GrantFiled: February 20, 2004Date of Patent: June 9, 2009Assignee: Shell Oil CompanyInventors: Laszlo Domokos, Hermanus Jongkind, Johannes Anthonius Robert Van Veen
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Publication number: 20090143225Abstract: The present invention provides for catalysts for selective catalytic reduction of nitrogen oxides. The catalysts comprise metal oxide supporters, vanadium, an active material, and antimony, a promoter that acts as a catalyst for reduction of nitrogen oxides, and at the same time, can promote higher sulfur poisoning resistance and low temperature catalytic activity. The amount of antimony of the catalysts is preferably 0.5-7 wt %.Type: ApplicationFiled: January 10, 2006Publication date: June 4, 2009Inventors: Heon-Phil Ha, Soon-Hyo Chung, Young-Joo Oh
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Patent number: 7541311Abstract: A vermiculite supported catalyst for carbon monoxide (CO) preferential oxidation (PROX) is disclosed. The CO PROX catalyst comprises at least one catalytic agent, one optional modifier agent, one carrier material, and a vermiculite support. The process for preparing the vermiculite supported catalyst in this invention includes depositing first the carrier material on a vermiculite support followed by calcination to form the carrier-containing support, and wet impregnating the catalytic agent and the optional modifier agent on the carrier-containing support followed by drying and calcination to form the CO preferential oxidation catalyst.Type: GrantFiled: August 31, 2007Date of Patent: June 2, 2009Assignee: Institute of Nuclear Energy ResearchInventors: Chao-Yuh Chen, Ching-Tsuen Huang, Chi-Hung Liao, Ching-Tu Chang
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Patent number: 7541310Abstract: This invention relates to catalysts comprising a catalytic metal deposited on a composite support with well-dispersed chemical “anchor” species acting as nucleation centers for catalytic metal crystallites growth. The catalysts have the advantage that the average catalytic metal crystallite size can be controlled by the molar ratio of catalytic metal to chemical “anchor,” and is not limited by the porous structure of the support. A preferred embodiment comprises a cobalt-based catalyst on a silica-alumina support made by a co-gel method, wherein its average pore size can be controlled by the pH. The alumina species in the support most likely serve as chemical “anchors” to control the dispersion of cobalt species, such that the average cobalt crystallite size can be greater than the average pore size.Type: GrantFiled: October 12, 2004Date of Patent: June 2, 2009Assignee: ConocoPhillips CompanyInventors: Rafael L. Espinoza, Kandaswamy Jothimurugesan, Kevin L. Coy, James Dale Ortego, Jr., Nithya Srinivasan, Olga P. Ionkina
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Patent number: 7541012Abstract: The present invention features a catalytic material which includes a metal catalyst anchored to a nano-sized crystal containing a metal oxide. Furthermore, the present invention features a method of producing the catalytic material described herein. Finally, the present invention features using the catalytic material for removing contaminants and for getting the desired products.Type: GrantFiled: July 7, 2004Date of Patent: June 2, 2009Assignee: The Hong Kong University of Science and TechnologyInventors: King Lun Yeung, Nan Yao, Ka Yee Ho
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Patent number: 7538253Abstract: The present invention relates to a novel method for preparing a catalyst of the formula (1), WOx wherein, W represents tungsten atom, O represents oxygen atom x represents a value determined by oxidative state of W, for partial oxidation of methylbenzenes, the method comprising: (a) a step of preparing tungsten oxide slurry by wet milling; (b) a step of supporting the slurry obtained in the step (a) on fire-resistance inorganic carrier by impregnation; (c) a step of drying the catalyst obtained in the step (b); and (d) a step of calcining the dried catalyst obtained in the step (c), and can reduce the reaction temperature on the basis of equivalent yield in the preparation of corresponding aromatic aldehyde from methylbenzenes since the catalyst has increased the surface areas compared to the conventional one, and thus has high conversion rate.Type: GrantFiled: November 21, 2006Date of Patent: May 26, 2009Assignee: LG Chem Ltd.Inventors: Won Ho Lee, Dong Il Lee, Jong Hyun Chae, Hyun Kyung Yoon
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Publication number: 20090131253Abstract: A catalyst body including a catalytic material containing an alkali metal and/or an alkaline earth metal, a carrier carrying the catalytic material, and a method of manufacturing the catalyst body are provided. The carrier has a cordierite binder phase and aggregate phases dispersed in the cordierite binder phase.Type: ApplicationFiled: October 20, 2008Publication date: May 21, 2009Applicant: NGK Insulators, Ltd.Inventors: Misako FUJII, Kenji Morimoto, Shinji Kawasaki
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Patent number: 7534740Abstract: A method to produce photo-catalyst physical water molecule for medical purposes includes the following steps: mixing aqua pura and TiO2 at the ratio of 1:1 at a temperature range of 50 to 60° C. to be ground and refrigerated in flasks of a first semi-product; adding aqua pura at the ratio of 1:1 and mixing well to become a second semi-product; diluting with aqua pura and mixing well to indicate a viscosity of 800 to 10000 centipoises; storing the solution in a sealed and transparent container to undergo photosynthesis for 24 hours at a temperature range of 40 to 50° C.; ridding off 1% suspension and foreign matters and impurities of the sediments to avail solution of 20% solid containment; finally diluting with approximately 100% aqua pura to 0.3 to 0.8%.Type: GrantFiled: July 24, 2006Date of Patent: May 19, 2009Inventor: Tsai-Chuan Lu
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Publication number: 20090123353Abstract: The present invention relates to a method for preparing a vanadia-titania catalyst having a core-shell structure, which is highly active in decomposing chlorinated organic compounds such as dioxin present in the exhaust of an incinerator.Type: ApplicationFiled: November 7, 2008Publication date: May 14, 2009Applicant: KOREA INSTITUTE OF SCIENCE AND TECHNOLOGYInventors: Jong Soo Jurng, Sung Min Chin, Ju Young Jeong, Jung Eun Lee, Gwi-Nam Bae