Patents Assigned to Renaissance Energy Research Corporation
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Publication number: 20180185784Abstract: A carbon dioxide separation method including the steps of: feeding a mixed gas that contains at least carbon dioxide and water vapor to a carbon dioxide separation membrane that contains a hydrophilic resin and a carbon dioxide carrier; separating, from the mixed gas, a permeation gas that contains the carbon dioxide by use of the carbon dioxide separation membrane; adjusting temperature of gas which contacts the carbon dioxide separation membrane so that a temperature difference between the mixed gas and the permeation gas is not lower than 0° C. and not higher than 20° C.; and adjusting pressure of the permeation gas, the pressure of the permeation gas and water vapor partial pressure in the mixed gas satisfying the following formula (1): 2.5 kPaA<(pressure of permeation gas)<(water vapor partial pressure in mixed gas) . . . (1).Type: ApplicationFiled: June 17, 2016Publication date: July 5, 2018Applicants: SUMITOMO CHEMICAL COMPANY, LIMITED, RENAISSANCE ENERGY RESEARCH CORPORATIONInventors: Nobutaka KODAMA, Emi OKUBO, Osamu OKADA, Nobuaki HANAI
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Publication number: 20180186631Abstract: A shift conversion catalyst layer is divided into at least two front and back stages. A first catalyst and a second catalyst are provided on the upstream side and the downstream side, respectively. The first catalyst has a property that a carbon monoxide conversion rate decreases with an increase in carbon dioxide concentration in a supplied reaction gas at a constant carbon monoxide concentration in the supplied reaction gas and a constant reaction temperature. The first catalyst is combined with the second catalyst such that the degree of decrease in carbon monoxide conversion rate with respect to an increase in carbon dioxide concentration in the supplied reaction gas in the second catalyst is lower than that in the first catalyst. Whereby, the conversion rate of a carbon monoxide concentration of a carbon monoxide shift conversion apparatus can be improved without increasing the used amount of a shift conversion catalyst.Type: ApplicationFiled: March 2, 2018Publication date: July 5, 2018Applicant: RENAISSANCE ENERGY RESEARCH CORPORATIONInventors: OSAMU OKADA, MAIKO NAKAYAMA, KAORI MORIMOTO, CHIHIRO ITO, KATSUTOSHI NAGAOKA
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Patent number: 9975105Abstract: A system for producing an oxygenate, comprising: a desulfurization apparatus for contacting a raw material gas comprising hydrogen and carbon monoxide with a desulfurizing agent comprising copper; and a synthesis apparatus for contacting the raw material gas treated by the desulfurizing apparatus with an oxygenate-synthesis catalyst comprising rhodium.Type: GrantFiled: July 23, 2013Date of Patent: May 22, 2018Assignees: SEKISUI CHEMICAL CO., LTD., RENAISSANCE ENERGY RESEARCH CORPORATIONInventors: Toshihito Miyama, Tomoaki Nishino, Osamu Okada, Tamotsu Nonouchi
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Patent number: 9833746Abstract: Provided is a facilitated CO2 transport membrane having improved CO2 permeance and improved CO2 selective permeability. The facilitated CO2 transport membrane includes a separation-functional membrane comprising a hydrophilic polymer gel membrane which contains a CO2 carrier and a CO2 hydration catalyst, wherein the hydrophilic polymer is a copolymer including a first structural unit derived from an acrylic acid cesium salt or an acrylic acid rubidium salt and a second structural unit derived from vinyl alcohol. More preferably, the CO2 hydration catalyst has catalytic activity at a temperature of 100° C. or higher.Type: GrantFiled: March 24, 2014Date of Patent: December 5, 2017Assignees: Renaissance Energy Research Corporation, Sumitomo Chemical Company, LimitedInventors: Osamu Okada, Nobuaki Hanai, Peng Yan, Junya Miyata, Takehiro Nakasuji, Hayato Sugiyama
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Patent number: 9827535Abstract: A steam permselective membrane containing a crosslinked hydrophilic polymer is provided. The steam permselective membrane may further contain at least one alkali metal compound selected from the group consisting of a cesium compound, a potassium compound and a rubidium compound.Type: GrantFiled: July 26, 2011Date of Patent: November 28, 2017Assignee: Renaissance Energy Research CorporationInventors: Osamu Okada, Eiji Kamio, Nobuaki Hanai, Miwako Obama
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Publication number: 20170333833Abstract: Provided are a CO2 gas separation membrane, a method for manufacturing the same, and a carbon dioxide gas separation membrane module including the same, the CO2 gas separation membrane including: a first layer (A) containing at least one alkali metal compound selected from the group consisting of an alkali metal carbonate, an alkali metal bicarbonate and an alkali metal hydroxide, and a first resin in which a polymer having a carboxyl group has been crosslinked; a second layer (B) containing at least one of the alkali metal compounds, and a second resin having a structural unit derived from a vinyl ester of a fatty acid; and a hydrophobic porous membrane (C).Type: ApplicationFiled: November 17, 2015Publication date: November 23, 2017Applicants: SUMITOMO CHEMICAL COMPANY, LIMITED, RENAISSANCE ENERGY RESEARCH CORPORATIONInventors: Yudai OTA, Yoshihito OKUBO, Osamu OKADA, Nobuaki HANAI, Peng YAN, Yasato KIYOHARA
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Patent number: 9744522Abstract: Provided is a production method for a porous alumina material, comprising the steps of: mixing an alkoxysilane solution that comprises an alkoxysilane, a mixed solvent comprising water and an alcohol, and an inorganic acid, with an aluminum solution comprising an aluminum compound and water, to prepare a mixed solution in which the aluminum compound and the alkoxysilane are dissolved in the mixed solvent; co-precipitating aluminum hydroxide with a silicon compound in the mixed solution, to form a precipitate; and baking the precipitate to form a porous alumina material comprising aluminum oxide and silicon oxide.Type: GrantFiled: July 30, 2015Date of Patent: August 29, 2017Assignees: Renaissance Energy Research Corporation, Institute of National Colleges of Technology, JapanInventors: Akira Hasegawa, Osamu Okada, Chihiro Ito
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Publication number: 20170232398Abstract: The present invention provides a composition for a CO2 gas separation membrane containing: at least one compound selected from the group consisting of an alkali metal carbonate, an alkali metal bicarbonate, and an alkali metal hydroxide; a crosslinked polymer in which a polymer having a carboxyl group has been crosslinked; and a non-crosslinked polymer obtained by polymerization of one or more monomers selected from the group consisting of vinyl acetate, acrylic acid, methacrylic acid, and a derivative thereof.Type: ApplicationFiled: August 6, 2015Publication date: August 17, 2017Applicants: SUMITOMO CHEMICAL COMPANY, LIMITED, RENAISSANCE ENERGY RESEARCH CORPORATIONInventors: Yudai OTA, Yoshihito OKUBO, Osamu OKADA, Nobuaki HANAI, Peng YAN, Yasato KIYOHARA, Atsushi YAMAMOTO
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Patent number: 9597632Abstract: Disclosed is a CO2 permselective membrane 1 having an amino acid ionic liquid and a porous membrane impregnated with the amino acid ionic liquid, wherein the amino acid ionic liquid contains a certain range of water.Type: GrantFiled: February 6, 2013Date of Patent: March 21, 2017Assignees: Renaissance Energy Research Corporation, National University Corporation Kobe UniversityInventors: Osamu Okada, Nobuaki Hanai, Eiji Kamio, Shohei Kasahara, Hideto Matsuyama
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Publication number: 20170066649Abstract: The present invention provides a CO shift conversion device and a CO shift conversion method which improves CO conversion rate without increasing usage of a shift conversion catalyst. A CO shift conversion device includes: a CO shift converter 10 having a catalyst layer 5 composed of a CO shift conversion catalyst and performing CO shift conversion process on a gas flowing inside; and a CO2 remover 51 removing CO2 contained in a gas introduced. The catalyst layer 5 is composed of a CO shift conversion catalyst having a property that a CO conversion rate decreases with an increase of the concentration of CO2 contained in a gas flowing inside. The concentration of CO2 contained in a gas G0 to be processed is lowered by the CO2 remover 51 and, after that, the resultant gas is supplied to the CO shift converter 10 where it is subjected to the CO shift conversion process.Type: ApplicationFiled: November 18, 2016Publication date: March 9, 2017Applicant: Renaissance Energy Research CorporationInventors: Osamu Okada, Kaori Morimoto, Chihiro Ito
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Publication number: 20160272494Abstract: Provided is a facilitated CO2 transport membrane having an improved CO2 permeance and an improved CO2/H2 selectivity. The facilitated CO2 transport membrane includes a separation-functional membrane that includes a hydrophilic polymer gel membrane containing a CO2 carrier and a CO2 hydration catalyst. Further preferably, the CO2 hydration catalyst at least has catalytic activity at a temperature of 100° C. or higher, has a melting point of 200° C. or higher, or is soluble in water.Type: ApplicationFiled: June 1, 2016Publication date: September 22, 2016Applicant: Renaissance Energy Research CorporationInventors: Osamu OKADA, Nobuaki HANAI, Peng YAN, Junya MIYATA, Yasato KIYOHARA, Sayaka ISHII, Megumi NAGANO
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Patent number: 9440222Abstract: Provided is a production method for a porous alumina material, comprising the steps of: mixing an alkoxysilane solution that comprises an alkoxysilane, a mixed solvent comprising water and an alcohol, and an inorganic acid, with an aluminum solution comprising an aluminum compound and water, to prepare a mixed solution in which the aluminum compound and the alkoxysilane are dissolved in the mixed solvent; co-precipitating aluminum hydroxide with a silicon compound in the mixed solution, to form a precipitate; and baking the precipitate to form a porous alumina material comprising aluminum oxide and silicon oxide.Type: GrantFiled: January 13, 2012Date of Patent: September 13, 2016Assignees: Renaissance Energy Research Corporation, Institute of National Colleges of Technology, JapanInventors: Akira Hasegawa, Osamu Okada, Chihiro Ito
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Patent number: 9381464Abstract: Provided is a facilitated CO2 transport membrane having an improved CO2 permeance and an improved CO2/H2 selectivity. The facilitated CO2 transport membrane includes a separation-functional membrane that includes a hydrophilic polymer gel membrane containing a CO2 carrier and a CO2 hydration catalyst. Further preferably, the CO2 hydration catalyst at least has catalytic activity at a temperature of 100° C. or higher, has a melting point of 200° C. or higher, or is soluble in water.Type: GrantFiled: October 1, 2013Date of Patent: July 5, 2016Assignee: RENAISSANCE ENERGY RESEARCH CORPORATIONInventors: Osamu Okada, Nobuaki Hanai, Peng Yan, Junya Miyata, Yasato Kiyohara, Sayaka Ishii, Megumi Nagano
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Publication number: 20160051938Abstract: Provided is a facilitated CO2 transport membrane having improved CO2 permeance and improved CO2 selective permeability. The facilitated CO2 transport membrane includes a separation-functional membrane comprising a hydrophilic polymer gel membrane which contains a CO2 carrier and a CO2 hydration catalyst, wherein the hydrophilic polymer is a copolymer including a first structural unit derived from an acrylic acid cesium salt or an acrylic acid rubidium salt and a second structural unit derived from vinyl alcohol. More preferably, the CO2 hydration catalyst has catalytic activity at a temperature of 100° C. or higher.Type: ApplicationFiled: March 24, 2014Publication date: February 25, 2016Applicants: Sumimoto Chemical Company, Limited, Renaissance Energy Research CorporationInventors: Osamu Okada, Nobuaki Hanai, Peng Yan, Junya Miyata, Takehiro Nakasuji, Hayato Sugiyama
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Patent number: 9242206Abstract: In a gas separation apparatus that separates carbon dioxide and water vapor from a first mixture gas containing at least carbon dioxide, nitrogen and water vapor, the energy utilization efficiency thereof is improved. The gas separation apparatus is constructed to include a first separation membrane 33 and a second separation membrane 34 that are made of different materials. When the first mixture gas is supplied, the first separation membrane 33 separates a second mixture gas containing carbon dioxide and water vapor that permeate through the first separation membrane by allowing carbon dioxide and water vapor to permeate selectively. When the second mixture gas is supplied, the second separation membrane 34 separates water vapor that permeates through the second separation membrane 34 by allowing water vapor to permeate selectively.Type: GrantFiled: June 11, 2014Date of Patent: January 26, 2016Assignee: RENAISSANCE ENERGY RESEARCH CORPORATIONInventors: Osamu Okada, Masaaki Teramoto, Eiji Kamio, Nobuaki Hanai, Yasato Kiyohara
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Publication number: 20150336083Abstract: Provided is a production method for a porous alumina material, comprising the steps of: mixing an alkoxysilane solution that comprises an alkoxysilane, a mixed solvent comprising water and an alcohol, and an inorganic acid, with an aluminum solution comprising an aluminum compound and water, to prepare a mixed solution in which the aluminum compound and the alkoxysilane are dissolved in the mixed solvent; co-precipitating aluminum hydroxide with a silicon compound in the mixed solution, to form a precipitate; and baking the precipitate to form a porous alumina material comprising aluminum oxide and silicon oxide.Type: ApplicationFiled: July 30, 2015Publication date: November 26, 2015Applicants: Renaissance Energy Research Corporation, Institute of National Colleges of Technology, JapanInventors: Akira Hasegawa, Osamu Okada, Chihiro Ito
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Publication number: 20150151243Abstract: Provided is a facilitated CO2 transport membrane having an improved CO2 permeance and an improved CO2/H2 selectivity. The facilitated CO2 transport membrane includes a separation-functional membrane that includes a hydrophilic polymer gel membrane containing a CO2 carrier and a CO2 hydration catalyst. Further preferably, the CO2 hydration catalyst at least has catalytic activity at a temperature of 100° C. or higher, has a melting point of 200° C. or higher, or is soluble in water.Type: ApplicationFiled: October 1, 2013Publication date: June 4, 2015Applicant: Renaissance Energy Research CorporationInventors: Osamu Okada, Nobuaki Hanai, Peng Yan, Junya Miyata, Yasato Kiyohara, Sayaka Ishii, Megumi Nagano
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Publication number: 20150001447Abstract: The present invention provides a CO shift conversion device and a CO shift conversion method which improves CO conversion rate without increasing usage of a shift conversion catalyst. A CO shift conversion device includes: a CO shift converter 10 having a catalyst layer 5 composed of a CO shift conversion catalyst and performing CO shift conversion process on a gas flowing inside; and a CO2 remover 51 removing CO2 contained in a gas introduced. The catalyst layer 5 is composed of a CO shift conversion catalyst having a property that a CO conversion rate decreases with an increase of the concentration of CO2 contained in a gas flowing inside. The concentration of CO2 contained in a gas G0 to be processed is lowered by the CO2 remover 51 and, after that, the resultant gas is supplied to the CO shift converter 10 where it is subjected to the CO shift conversion process.Type: ApplicationFiled: December 13, 2012Publication date: January 1, 2015Applicant: RENAISSANCE ENERGY RESEARCH CORPORATIONInventors: Osamu Okada, Kaori Morimoto, Chihiro Ito
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Publication number: 20140377156Abstract: Disclosed is a CO2 permselective membrane 1 having an amino acid ionic liquid and a porous membrane impregnated with the amino acid ionic liquid, wherein the amino acid ionic liquid contains a certain range of water.Type: ApplicationFiled: February 6, 2013Publication date: December 25, 2014Applicants: NATIONAL UNIVERSITY CORPORATION KOBE UNIVERSITY, RENAISSANCE ENERGY RESEARCH CORPORATIONInventors: Osamu Okada, Nobuaki Hanai, Eiji Kamio, Shohei Kasahara, Hideto Matsuyama
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Publication number: 20140352540Abstract: CO2-facilitated transport membrane that can be applied to a CO2-permeable membrane reactor is stably provided. The CO2-facilitated transport membrane is provided such that a gel layer 1 composed of a hydrogel membrane is deposited onto a porous membrane 2. More preferably, the gel layer 1 deposited onto a hydrophilic porous membrane 2 is coated with and supported by hydrophobic porous membranes 3 and 4. The gel layer contains a deprotonating agent including an alkali metal element together with glycine. The deprotonating agent is preferably a carbonate or a hydroxide of an alkali metal element, and more preferably, the alkali metal element is potassium, cesium, or rubidium.Type: ApplicationFiled: July 26, 2012Publication date: December 4, 2014Applicant: RENAISSANCE ENERGY RESEARCH CORPORATIONInventors: Osamu Okada, Eiji Kamio, Masaaki Teramoto, Nobuaki Hanai, Hideto Matsuyama