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    • 1. 发明申请
    • Conductive member and manufacturing method thereof, and electric device and manufacturing method thereof
    • 导电构件及其制造方法以及电气装置及其制造方法
    • US20060091992A1
    • 2006-05-04
    • US10541733
    • 2004-01-16
    • Yukie MoriNobuo KobayashiKenryo Namba
    • Yukie MoriNobuo KobayashiKenryo Namba
    • H01C7/13H01C7/10
    • H01C17/06586H01B1/24H01C7/028
    • An electric device 1 is an organic positive thermistor in which, between two plate electrodes 2a and 2b constituting an electrode couple 2, a conductive member 41 is disposed in a state being in a close contact with the plate electrodes 2a and 2b. The conductive member 41 is formed of many piled up resin particles each having its surface formed with a conductive layer of a residual material (fullerene residual), which is the soot including fullerenes generated via, for example, an arc discharging method, from which at least a part of fullerenes is removed. Such conductive layers are joined to each other to structure the conductive path and the conduction of the electric device 1 is ensured in a normal state. When an inrush current flows, the conductive path is readily shut off by a small inflation of the resin particles due to the temperature rise.
    • 电气装置1是有机正热敏电阻,其中,在构成电极对2的两个平板电极2a和2b之间,导电构件41设置在与板电极2a和2b紧密接触的状态 。 导电构件41由许多堆积的树脂颗粒形成,每个树脂颗粒的表面形成有残留材料(富勒烯残留物)的导电层,其是包含通过例如电弧放电法产生的富勒烯的烟炱, 至少部分富勒烯被去除。 这样的导电层彼此接合以构成导电路径,并且在正常状态下确保电气设备1的导通。 当浪涌电流流动时,由于温度升高,导电路径容易被树脂颗粒的小的膨胀所切断。
    • 2. 发明授权
    • Conductive member and manufacturing method thereof, and electric device and manufacturing method thereof
    • 导电构件及其制造方法以及电气装置及其制造方法
    • US07663468B2
    • 2010-02-16
    • US10541733
    • 2004-01-16
    • Yukie MoriNobuo KobayashiKenryo Namba
    • Yukie MoriNobuo KobayashiKenryo Namba
    • H01C7/13
    • H01C17/06586H01B1/24H01C7/028
    • An electric device 1 is an organic positive thermistor in which, between two plate electrodes 2a and 2b constituting an electrode couple 2, a conductive member 41 is disposed in a state being in a close contact with the plate electrodes 2a and 2b. The conductive member 41 is formed of many piled up resin particles each having its surface formed with a conductive layer of a residual material (fullerene residual), which is the soot including fullerenes generated via, for example, an arc discharging method, from which at least a part of fullerenes is removed. Such conductive layers are joined to each other to structure the conductive path and the conduction of the electric device 1 is ensured in a normal state. When an inrush current flows, the conductive path is readily shut off by a small inflation of the resin particles due to the temperature rise.
    • 电气装置1是有机正热敏电阻,其中,在构成电极对2的两个平板电极2a和2b之间,以与电极2a和2b紧密接触的状态配置导电构件41。 导电构件41由许多堆积的树脂颗粒形成,每个树脂颗粒的表面形成有残留材料(富勒烯残留物)的导电层,其是包含通过例如电弧放电法产生的富勒烯的烟炱, 至少部分富勒烯被去除。 这样的导电层彼此接合以构成导电路径,并且在正常状态下确保电气设备1的导通。 当浪涌电流流动时,由于温度升高,导电路径容易被树脂颗粒的小的膨胀所切断。
    • 7. 发明申请
    • Organic positive temperature coefficient thermistor
    • 有机正温度系数热敏电阻
    • US20070024413A1
    • 2007-02-01
    • US11493600
    • 2006-07-27
    • Kenryo Namba
    • Kenryo Namba
    • H01C7/13
    • H01C7/027
    • An organic positive temperature coefficient thermistor provided with a pair of opposing electrodes and a thermistor body situated between the pair of electrodes, wherein the thermistor body is composed of a cured resin composition comprising: a thermosetting resin; conductive particles; and a nucleating agent. Also, an organic positive temperature coefficient thermistor, wherein the thermistor body is composed of a cured resin composition comprising: a thermosetting resin which contains a crosslinkable compound with a mesogen group; and conductive particles.
    • 一种有机正温度系数热敏电阻,其设置有一对相对电极和位于该对电极之间的热敏电阻体,其中,所述热敏电阻体由固化树脂组合物构成,所述固化树脂组合物包含:热固性树脂; 导电颗粒; 和成核剂。 此外,有机正温度系数热敏电阻,其中所述热敏电阻体由固化树脂组合物构成,所述固化树脂组合物包含:含有具有介晶基团的可交联化合物的热固性树脂; 和导电颗粒。
    • 9. 发明授权
    • Fine magnetic particles containing useful proteins bound thereto,
process for producing the same, and use thereof
    • 包含与其结合的有用蛋白质的细磁性颗粒,其制备方法及其用途
    • US5958706A
    • 1999-09-28
    • US973275
    • 1998-02-09
    • Tadashi MatsunagaShinji KamiyaKenryo Namba
    • Tadashi MatsunagaShinji KamiyaKenryo Namba
    • A61K48/00C07K14/195C12N11/02C12N11/14C12N15/00C12N15/31G01N33/543C12N15/74G01N33/53
    • G01N33/54326C07K14/195C12N11/02C12N11/14C12N15/00A61K48/00C07K2319/00Y10S435/82Y10S530/811
    • This invention provides a useful protein-bound magnetic particle which includes a magnetic particle produced in the cell of a magnetic bacterium, and a hybrid protein bound to an organic membrane covering the magnetic particle, and of which the hybrid protein comprises a membrane protein which is originally produced in a state of being bound to the organic membrane, and one or more useful proteins bound biologically through fusion or other binding means to the membrane protein. The protein biologically immobilized does not suffer reduced activity. It is possible to obtain a useful protein such as an enzyme, antibody, etc. immobilized on a magnetic particle, only by cultivating a transformed bacterium, and separating a magnetic particle produced in the cell of the bacterium. When a functional protein is immobilized in this way, it is possible to guide the functional protein magnetically, and to move it to a desired location effectively. As the expression site of a protein can be controlled genetically, a magnetic particle on which a binding protein such as protein A and a labeling protein such as luminescence-related protein are allowed to express themselves close to each other enables a highly sensitive detection process.
    • PCT No.PCT / JP97 / 01043 Sec。 371日期:1998年2月9日 102(e)日期1998年2月9日PCT 1997年3月27日PCT公布。 公开号WO97 / 35964 日期1997年10月2日本发明提供了一种有用的蛋白质结合磁性颗粒,其包括在磁性细菌的细胞中产生的磁性颗粒,以及与覆盖磁性颗粒的有机膜结合的杂合蛋白质,其杂合蛋白质包含 最初以与有机膜结合的状态产生的膜蛋白和通过融合或其它结合手段生物地结合到膜蛋白的一种或多种有用的蛋白质。 生物固定的蛋白质不会降低活性。 通过培养转化细菌,分离固定在磁性粒子上的酶,抗体等有用的蛋白质,可以分离细菌的细胞中产生的磁性粒子。 当以这种方式固定功能性蛋白质时,有可能磁性地引导功能性蛋白质,并且有效地将其移动到期望的位置。 由于蛋白质的表达位点可以在遗传上进行控制,因此允许结合蛋白如蛋白质A和标记蛋白质如发光相关蛋白质的磁性颗粒彼此表面接近,可以实现高灵敏度的检测过程。