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    • 3. 发明申请
    • STREPTAVIDIN-COUPLED MAGNETIC PARTICLES AND MANUFACTURING METHOD FOR SAME
    • STREPTAVIDIN-偶联磁性颗粒及其制造方法
    • US20140051070A1
    • 2014-02-20
    • US13985521
    • 2012-02-15
    • Nobuyuki AraiYasuhiro MatsuokaKazuki Morita
    • Nobuyuki AraiYasuhiro MatsuokaKazuki Morita
    • G01N33/566
    • G01N33/566G01N33/531G01N33/54326G01N33/5434
    • The present invention provides a streptavidin-coupled magnetic particle with high biotin-binding capacity, and a manufacturing method thereof. The streptavidin-coupled magnetic particle has a structure in which streptavidins are cross-linked with each other on a magnetic particle. A method for manufacturing the streptavidin-coupled magnetic particle includes the steps of:(1) preparing a suspension containing magnetic particles having amino groups on their surface; and (2) reacting the magnetic particles with streptavidin and glutaraldehyde by adding glutaraldehyde in the presence of streptavidin to the suspension prepared in step (1). The streptavidin-coupled magnetic particle of the present invention, and the streptavidin-coupled magnetic particle manufactured by the manufacturing method of the present invention are useful in clinical diagnosis.
    • 本发明提供具有高生物素结合能力的链霉抗生物素蛋白偶联磁性颗粒及其制造方法。 链霉抗生物素蛋白偶联磁性颗粒具有链霉亲和素在磁性颗粒上彼此交联的结构。 制备链霉抗生物素蛋白偶联磁性颗粒的方法包括以下步骤:(1)制备含有表面具有氨基的磁性颗粒的悬浮液; 和(2)通过在链霉亲和素存在下将戊二醛加入到步骤(1)中制备的悬浮液中使磁性颗粒与链霉亲和素和戊二醛反应。 本发明的链霉抗生物素蛋白偶联磁性颗粒和通过本发明的制造方法制造的链霉抗生物素蛋白偶联的磁性颗粒可用于临床诊断。
    • 4. 发明申请
    • ELECTRIC POWER SUPPLY DEVICE
    • 电力设备
    • US20120025613A1
    • 2012-02-02
    • US13262723
    • 2010-06-25
    • Kazuki MoritaMasahiro Saito
    • Kazuki MoritaMasahiro Saito
    • H02J9/00
    • H01M10/44B60L3/00B60L3/0092B60L11/005B60L11/1857G01R31/3662G01R31/3679H01M10/443H01M10/46H01M10/48H01M10/486H02J7/345Y02T10/7005Y02T10/7022Y02T10/705Y10T307/615
    • A power supply device includes an electric storage unit connected to a main power supply and a load via a charging circuit; and a control circuit connected to the main power supply, the charging circuit, a voltage detection circuit, and a current detection circuit. When the electric storage unit is charged up to a steady-state voltage Vcs of the electric storage unit, the control circuit controls the electric storage unit to be charged until the voltage Vc of the electric storage unit reaches a voltage for determining the property deterioration of the electric storage unit. During the charge process, the control circuit calculates at least one of the internal resistances and the capacitance of the electric storage unit from the variation width ΔVcr of the voltage Vc, the current Ic of the electric storage unit, the variation width ΔVct per unit time of the voltage Vc, and the current-time product ∫(Ic)dt of the electric storage unit. One of these values is used to determine the property deterioration of the electric storage unit.
    • 电源装置包括通过充电电路连接到主电源和负载的蓄电单元; 以及连接到主电源,充电电路,电压检测电路和电流检测电路的控制电路。 当蓄电单元被充电到蓄电单元的稳定电压Vcs时,控制电路控制蓄电单元被充电,直到蓄电单元的电压Vc达到用于确定蓄电单元的性能劣化的电压 蓄电单元。 在充电过程中,控制电路根据电压Vc的变化宽度& V rg,蓄电单元的电流Ic,变化宽度& Dgr,计算存储单元的内部电阻和电容中的至少一个。 电压Vc的单位时间的Vct以及蓄电部的电流 - 时间乘积∫(Ic)dt。 这些值之一用于确定蓄电单元的特性劣化。
    • 6. 发明申请
    • ELECTRICITY STORAGE DEVICE
    • 电力存储设备
    • US20090261782A1
    • 2009-10-22
    • US12307169
    • 2007-07-25
    • Kazuki Morita
    • Kazuki Morita
    • H02J7/00
    • H02J7/0016H02J7/345Y02T10/7055
    • An electric storage device is disclosed, this device can balance voltages across each one of energy storage devices with each other in a short time even if the voltages disperse in a wide range, and also it can reduce needless power consumption. This device includes the energy storage devices and an equalizing voltage circuit coupled in parallel with the energy storage devices. The equalizing voltage circuit includes a balancing resistor, a balancing switch coupled between respective energy storage devices and respective balancing resistors, a discharging resistor coupled in parallel with the respective energy storage devices and having a smaller resistance value than the balancing resistor, and a discharging switch coupled between the respective energy storage devices and the respective discharging resistors. All the balancing switches and all the discharging switches are turned on during the charge to the energy storage devices, and after the voltages across the respective energy storage devices can be balanced with each other, all the discharging switches alone are turned off.
    • 公开了一种蓄电装置,即使电压分散在宽范围内,该装置也可以在短时间内平衡每个能量存储装置之间的电压,并且还可以减少不必要的功率消耗。 该装置包括能量存储装置和与能量存储装置并联耦合的均衡电压电路。 均衡电压电路包括平衡电阻器,耦合在相应的能量存储器件和相应的平衡电阻器之间的平衡开关,与各个能量存储器件并联耦合并且具有比平衡电阻器更小的电阻值的放电电阻器,以及放电开关 耦合在各个储能装置和相应的放电电阻之间。 所有的平衡开关和所有的放电开关在​​对蓄电装置的充电期间被接通,并且在相应的能量存储装置之间的电压彼此平衡之后,所有的放电开关都被关闭。
    • 7. 发明申请
    • Analog-To-Digital Converting Apparatus And Vehicle Power Supply Apparatus Using The Same
    • 模数转换装置及其使用的车辆电源装置
    • US20090167575A1
    • 2009-07-02
    • US12097340
    • 2006-12-19
    • Yohsuke MitaniKazuki MoritaYoshimitu Odajima
    • Yohsuke MitaniKazuki MoritaYoshimitu Odajima
    • H03M1/06F02P3/02
    • H03M1/1038H03M1/12
    • The A/D conversion apparatus and the vehicle power-supply device using the apparatus calculate errors at a plurality of reference voltages and reference errors prior to error correction. Each reference error is applied to a digital-output range that is divided by digital output corresponding to the reference voltages. In the calculation, when the errors obtained at adjacent reference voltages have same signs, the reference error is determined as an average of the errors obtained at adjacent reference voltages; on the other hand, when the errors obtained at adjacent reference voltages have different signs, the reference error is determined to be zero. The apparatus provides a corrected digital output by subtracting the reference error—which is applied to the digital-output range including the digital output—from the digital output corresponding to analog input voltage.
    • 使用该装置的A / D转换装置和车辆供电装置在纠错之前计算多个参考电压的误差和参考误差。 每个参考误差被应用于数字输出范围,该数字输出范围除以与参考电压相对应的数字输出。 在计算中,当相邻参考电压获得的误差具有相同的符号时,将参考误差确定为在相邻参考电压下获得的误差的平均值; 另一方面,当相邻参考电压获得的误差具有不同的符号时,基准误差被确定为零。 该装置通过从对应于模拟输入电压的数字输出中减去应用于包括数字输出的数字输出范围的参考误差来提供校正的数字输出。
    • 9. 发明授权
    • Energy storage device
    • 储能装置
    • US08305035B2
    • 2012-11-06
    • US12860957
    • 2010-08-23
    • Kazuki MoritaYohsuke Mitani
    • Kazuki MoritaYohsuke Mitani
    • H02J7/00
    • H02J7/34G01R19/16542
    • In an energy storage device, a charging circuit is electrically coupled to the energy storage section. A first comparator is electrically coupled to an energy storage section, and its output is inverted when voltage Vc of the energy storage section reaches first predetermined voltage Vc1. A second comparator is electrically coupled to the energy storage section, and its output is inverted when voltage Vc of the energy storage section reaches second predetermined voltage Vc2. A control circuit is electrically coupled to the first comparator and the second comparator. The control circuit obtains period tm from inversion of the output of the first comparator to the output of the second comparator. Capacitance C of the energy storage section is calculated based on this period tm and voltage change width ΔVc between the first predetermined voltage Vc1 and the second predetermined voltage Vc2.
    • 在能量存储装置中,充电电路电耦合到能量存储部分。 第一比较器电耦合到能量存储部分,并且当能量存储部分的电压Vc达到第一预定电压Vc1时,其输出反相。 第二比较器电耦合到能量存储部分,并且当能量存储部分的电压Vc达到第二预定电压Vc2时,其输出反相。 控制电路电耦合到第一比较器和第二比较器。 控制电路从第一比较器的输出的反相到第二比较器的输出获得周期tm。 基于该时间段tm和第一预定电压Vc1与第二预定电压Vc2之间的电压变化宽度&Dgr; Vc计算能量存储部分的电容C.