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    • 6. 发明申请
    • IRON OXIDE-ZIRCONIA COMPOSITE OXIDE AND METHOD FOR PRODUCING SAME, AND EXHAUST GAS PURIFICATION CATALYST
    • 氧化铁 - 氧化锆氧化物及其制造方法和排气净化催化剂
    • US20150080211A1
    • 2015-03-19
    • US14384283
    • 2013-04-26
    • Masahide MiuraAtsushi TanakaTakahiro SuzukiTadashi SuzukiToshitaka TanabeNaoki Takahashi
    • Masahide MiuraAtsushi TanakaTakahiro SuzukiTadashi SuzukiToshitaka TanabeNaoki Takahashi
    • B01J23/89B01J23/83B01J23/745
    • B01J23/894B01J21/066B01J23/10B01J23/745B01J23/83B01J35/0006B01J35/002B01J37/0248B01J37/03C01G25/00C01G49/0018C01G49/0054C01P2002/72C01P2004/03C01P2004/32C01P2004/45C01P2004/61C01P2006/12
    • A composite oxide with a high oxygen storage capacity is provided without using cerium. The composite oxide is an iron oxide-zirconia composite oxide containing iron, zirconium, and a rare-earth element. The total content of Fe2O3, ZrO2, and an oxide of the rare-earth element is not less than 90 mass %, the content of an iron oxide in terms of Fe2O3 is 10 to 90 mass %, and the absolute value of the covariance COV(Fe, Zr+X) of the composite oxide, which has been baked in the atmosphere at a temperature of greater than or equal to 900° C. for 5 hours or more, determined by the following Formulae (1) to (3), is not greater than 20:  [ Math .  1 ]  R i  ( Fe ) = I i  ( Fe ) × 100 I i  ( Fe ) + I i  ( Zr ) + I i  ( X ) ( 1 )  R i  ( Zr + X ) = { I i  ( Zr ) + I i  ( X ) } × 100 I i  ( Fe ) + I i  ( Zr ) + I i  ( X ) ( 2 ) COV  ( Fe , Zr + X ) = 1 n  ∑ i = 1 n   [ { R i  ( Fe ) - R av  ( Fe ) } × { R i  ( Zr + X ) - R av  ( Zr + X ) } ] ( 3 ) (in the formula, Ii(Fe), Ii(Zr), and Ii(X) respectively represent the ratios of the X-ray intensities of iron, zirconium, and the rare-earth element measured at a measurement point i (where i=1 to n) to the 100% intensities of the respective elements as measured by subjecting the composite oxide to a ray analysis through EPMA (WDX: wavelength dispersive X-ray spectrometry), where Rav(Fe) and Rav(Zr+X) represent the mean values of Ri(Fe) and Ri(Zr+X), respectively, at all measurement points n).
    • 提供具有高储氧能力的复合氧化物,而不使用铈。 复合氧化物是含有铁,锆和稀土元素的氧化铁 - 氧化锆复合氧化物。 Fe2O3,ZrO2和稀土类元素的氧化物的总含量为90质量%以上,Fe 2 O 3的氧化铁含量为10〜90质量%,协方差COV的绝对值 (1)〜(3)确定的复合氧化物的(Fe,Zr + X),其在大气中在大于或等于900℃的温度下烘烤5小时以上, ,不大于20: (Fe)= I(Fe)×100 I i(Fe)+ I(Zr)+ I(X)(1)R i(Zr + X )(I)(X)(X)(2)COV(Fe,Zr + X) )= 1 nΣi = 1 n[{R i(Fe)-R av(Fe)}×{R i(Zr + X)-R av(Zr + X)}] 3)(式中,Ii(Fe),Ii(Zr)和Ii(X)分别表示在测量点i测量的铁,锆和稀土元素的X射线强度的比例 其中i = 1至n)相对于通过EPMA(WDX:波长色散X射线光谱法)对复合氧化物进行射线分析测量的各元素的100%强度,其中Rav(Fe)和Rav(Zr + X)分别表示在所有测量点n处的Ri(Fe)和Ri(Zr + X)的平均值。
    • 7. 发明授权
    • Pressure detection unit
    • 压力检测单元
    • US08857276B2
    • 2014-10-14
    • US13392621
    • 2010-08-26
    • Takahiro SuzukiYuko EndoYoshihiro KaiYuichiro Takai
    • Takahiro SuzukiYuko EndoYoshihiro KaiYuichiro Takai
    • G01L1/18G01L1/20G06F3/041
    • G01L1/20G06F3/041
    • A pressure detection unit includes a first substrate and a second substrate which are disposed in opposition to each other and subject to load from the outside, a pressure detection portion having a pair of electrodes provided between the first substrate and the second substrate and in the first substrate and the second substrate, and electrically conductive pressure-sensitive ink disposed between the pair of electrodes and having electrical characteristics which varies according to the load, and a load transmission member disposed between the first substrate and the pressure detection portion and/or between the second substrate and the pressure detection portion, the load transmission member transmitting the load to the pressure detection portion in a concentrated manner.
    • 压力检测单元包括第一基板和第二基板,所述第一基板和第二基板彼此相对设置并受到来自外部的负载;压力检测部分,具有设置在第一基板和第二基板之间的第一对电极, 基板和第二基板,以及设置在所述一对电极之间并具有根据负载而变化的电特性的导电压敏墨,以及设置在所述第一基板和所述压力检测部之间和/ 第二基板和压力检测部,负载传递部件以集中的方式将负载传递到压力检测部。
    • 9. 发明授权
    • Hydrogen generation device
    • 氢气发生装置
    • US08734625B2
    • 2014-05-27
    • US13522855
    • 2011-01-19
    • Takahiro SuzukiTakaiki NomuraKazuhito HatohNoboru TaniguchiTomohiro KurohaKenichi Tokuhiro
    • Takahiro SuzukiTakaiki NomuraKazuhito HatohNoboru TaniguchiTomohiro KurohaKenichi Tokuhiro
    • C25B9/00C25B11/00C25B9/04C25B9/06C25B9/16C25B11/04
    • C25B1/003C01B3/042C01B2203/066Y02E60/364Y02E60/368
    • A hydrogen generation device (100) of the present invention includes: a transparent substrate (1); a photocatalytic electrode (4) formed of a transparent conductive layer (2) and a photocatalytic layer (3) disposed on the transparent substrate (1); a counter electrode (8) connected electrically to the transparent conductive layer (2); a water-containing electrolyte solution layer provided between the photocatalytic electrode (3) and the counter electrode (8); a separator (6) that separates the electrolyte solution layer into a first electrolyte solution layer (5) in contact with the photocatalytic electrode (4) and a second electrolyte solution layer (7) in contact with the counter electrode (8); a first gas outlet (14) for discharging a gas generated in the first electrolyte solution layer (5); and a second gas outlet (15) for discharging a gas generated in the second electrolyte solution layer (7). The photocatalytic electrode (4) and the counter electrode (8) are arranged so that a surface of the photocatalytic layer (3) and a surface of the counter electrode (8) face each other. The separator (6) allows an electrolyte in the electrolyte solution layer to pass therethrough and prevents hydrogen gas and oxygen gas in the electrolyte solution layer from passing therethrough.
    • 本发明的氢产生装置(100)包括:透明基板(1); 由透明导电层(2)和设置在透明基板(1)上的光催化层(3)形成的光催化电极(4); 与所述透明导电层(2)电连接的对电极(8); 设置在光催化剂电极(3)和对电极(8)之间的含水电解液层; 将电解质溶液层分离成与光催化剂电极(4)接触的第一电解质溶液层(5)和与反电极(8)接触的第二电解液层(7)的分离器(6)。 用于排出在第一电解质溶液层(5)中产生的气体的第一气体出口(14); 和用于排出在第二电解质溶液层(7)中产生的气体的第二气体出口(15)。 光催化剂电极(4)和对电极(8)的配置使得光催化剂层(3)的表面和对置电极(8)的表面彼此面对。 分离器(6)允许电解质溶液层中的电解质通过,防止电解质溶液层中的氢气和氧气通过。