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    • 41. 发明授权
    • Gas sensor
    • 气体传感器
    • US08127594B2
    • 2012-03-06
    • US12496702
    • 2009-07-02
    • Takeshi KawaiKentaro MoriRyohei Aoki
    • Takeshi KawaiKentaro MoriRyohei Aoki
    • G01N7/00
    • G01N27/4071
    • A gas sensor including: a gas sensing element including first and second ceramic layers. The first ceramic layer has a first through hole and a first through hole conductor covering an inner surface thereof. The first ceramic layer includes a first conductor which includes: a first peripheral conductive portion electrically connected to the first through hole conductor; a first lead portion that is narrower than the first peripheral conductive portion; and a first contact conductive portion that is wider than the first lead portion. The first peripheral conductive portion, the first lead portion and the first contact conductive portion are integrally formed and arranged in this order in a longitudinal direction. The second ceramic layer includes a second conductor electrically connected to at least the first contact conductive portion.
    • 一种气体传感器,包括:气体感测元件,包括第一和第二陶瓷层。 第一陶瓷层具有覆盖其内表面的第一通孔和第一通孔导体。 第一陶瓷层包括:第一导体,其包括:电连接到第一通孔导体的第一外围导电部分; 第一引线部分,其比第一外围导电部分窄; 以及比第一引线部分宽的第一接触导电部分。 第一周边导电部分,第一引线部分和第一接触导电部分沿纵向依次整体形成并布置。 第二陶瓷层包括电连接到至少第一接触导电部分的第二导体。
    • 42. 发明授权
    • Gas sensor and method for manufacturing the same
    • 气体传感器及其制造方法
    • US07951277B2
    • 2011-05-31
    • US11349177
    • 2006-02-08
    • Yukinobu NagaoMasaki NakagawaTakeshi KawaiRyohei AokiSatoshi Teramoto
    • Yukinobu NagaoMasaki NakagawaTakeshi KawaiRyohei AokiSatoshi Teramoto
    • G01N27/407
    • G01N27/4071
    • A prismatic multilayer gas sensor element and method of making the same, the prismatic multilayer gas sensor element (1) having a substantially rectangular cross section, and including a gas-sensing cell portion (2) formed at a distal end portion of the prismatic gas sensor element (1); and a posterior lead portion (3) adjoining the gas-sensing cell portion (2). The longitudinal lateral surfaces of the posterior lead portion (3) are coated with a non-porous alumina layer (11), the non-porous alumina layer (11) having a multilayered structure including at least a joining layer (11a) and a surface layer (11b). The longitudinal lateral surface of the gas-sensing portion (2) is not coated with a non-porous alumina layer.
    • 一种棱柱形多层气体传感器元件及其制造方法,所述棱柱形多层气体传感器元件(1)具有基本上矩形的横截面,并且包括形成在棱柱形气体的远端部分处的气体感测单元部分(2) 传感器元件(1); 和邻接气体感测单元部分(2)的后引线部分(3)。 后引线部分(3)的纵向侧表面涂覆有无孔氧化铝层(11),所述无孔氧化铝层(11)具有多层结构,所述多层氧化铝层至少包括接合层(11a)和表面 层(11b)。 气体感测部分(2)的纵向侧表面没有涂覆无孔氧化铝层。
    • 45. 发明申请
    • Control apparatus for gas sensor
    • 气体传感器控制装置
    • US20050205550A1
    • 2005-09-22
    • US11082902
    • 2005-03-18
    • Takuya SaitoTakeshi KawaiSatoshi Teramoto
    • Takuya SaitoTakeshi KawaiSatoshi Teramoto
    • F02D41/14F02D45/00G01N27/00G01N27/12G01N27/407G01N27/409G01N33/00H05B1/02
    • F02D41/1494G01N33/007
    • A control apparatus for a gas sensor, wherein a microcomputer 44, which is connected to an oxygen sensor 30 including a detection element 12 and a heater 14, detects the cooling water temperature Tw of the engine. The control apparatus determines that condensation water within the exhaust pipe is being generated when the cooling water temperature Tw is equal to or lower than 0° C. When equal to or lower than 0° C., the microcomputer 44 supplies to the heater 14 electrical power for maintaining the temperature of the detection element 12 within the range of 100° C. to a splash-water-cracking generation temperature (e.g., about 300° C.) at or above which cracking can occur in a laminated-type oxygen sensor element 10 due to splash of condensation water. Electrical power is supplied to the heater 14 such that a pulse signal Sh is output from the microcomputer 44, and the heater 14 is pulse-driven by use of a heater electrification control circuit 34.
    • 一种用于气体传感器的控制装置,其中连接到包括检测元件12和加热器14的氧传感器30的微型计算机44检测发动机的冷却水温度Tw。 当冷却水温度Tw等于或低于0℃时,控制装置确定排气管内的冷凝水正在产生。当等于或低于0℃时,微计算机44向加热器14供应电 用于将检测元件12的温度保持在100℃的范围内的功率达到或高于其中的飞溅水裂解发生温度(例如,约300℃),其中层压型氧传感器 元素10由于冷凝水溅出。 向加热器14提供电力,使得从微计算机44输出脉冲信号Sh,并且通过使用加热器通电控制电路34对加热器14进行脉冲驱动。
    • 47. 发明授权
    • Temperature control for all range oxygen sensor
    • 所有范围氧传感器的温度控制
    • US6120677A
    • 2000-09-19
    • US903940
    • 1997-07-31
    • Tessho YamadaTakeshi KawaiYuji OiShigeki MoriSatoshi TeramotoToshiya Matsuoka
    • Tessho YamadaTakeshi KawaiYuji OiShigeki MoriSatoshi TeramotoToshiya Matsuoka
    • F02D41/14G01N27/406G01N27/407
    • G01N27/4065F02D41/1494
    • A constant current Iconst is applied to an electromotive force cell which is interposed between a gap (measurement chamber) of a fixed atmosphere and an oxygen reference chamber of a constant oxygen content, for measurement of a resistance value of the electromotive force cell, whereby the resistance value can be measured accurately irrespective of an oxygen content in an atmosphere to be measured by an oxygen sensor element or cell unit. The resistance value of the electromotive force cell is measured at a predetermined timing T2 after application of a current is started, so that a measure resistance value is free of a variation of a resistance value due to deterioration of porous electrodes of an electromotive force cell, such a variation being included in the measured resistance value in case the measurement is done by using an AC current, and therefore accurate measurement can be attained. A temperature control methods and a temperature control apparatus for an oxygen sensor, capable of detecting the temperature accurately without suspending measurement of an oxygen content for a long period of time are also provided. Further, a temperature control method and a temperature control apparatus for an oxygen sensor, capable of detecting not only the temperature of the electromotive force cell but the temperature of the pump cell by applying a current or voltage to the electromotive force cell are provided.
    • 将恒定电流Iconst应用于介于固定气氛的间隙(测量室)和恒定氧含量的氧气参考室之间的电动势单元,用于测量电动势单元的电阻值,由此 可以精确地测量电阻值,而不管氧传感器元件或电池单元测量的气氛中的氧含量如何。 在施加电流开始之后,在预定定时T2测量电动势电池的电阻值,使得测量电阻值不会由于电动势电池的多孔电极的劣化而导致的电阻值的变化, 在通过使用AC电流进行测量的情况下,这种变化被包括在测量的电阻值中,因此可以获得精确的测量。 还提供了一种用于氧传感器的温度控制方法和温度控制装置,其能够准确地检测温度而不长时间地测量氧气含量。 此外,提供了一种用于氧传感器的温度控制方法和温度控制装置,其不仅可以通过向电动势单元施加电流或电压来检测电动势单元的温度,而且可以检测泵室的温度。
    • 48. 发明授权
    • Method and apparatus for controlling the energizing of a heater in an
oxygen sensor
    • 用于控制氧传感器中的加热器通电的方法和装置
    • US5700367A
    • 1997-12-23
    • US636401
    • 1996-04-23
    • Tessho YamadaKatsuhisa YabutaTakeshi KawaiHideki Toyoda
    • Tessho YamadaKatsuhisa YabutaTakeshi KawaiHideki Toyoda
    • F02D41/14G01N27/406G01N27/419G01N27/409
    • G01N27/419F02D41/1494G01N27/4065
    • An oxygen sensor according to the present invention has battery element and a pump element in each of which porous electrodes are disposed on both faces of a solid electrolyte substrate. A minute current is supplied to the battery element after the start of energizing a heater and the activation of the sensor elements are judged on the basis of an interelectrode voltage generated at this energizing. A heater voltage is set to be 12V at the start of energizing. When the time period necessary for the interelectrode voltage to reach a predetermined voltage is short, the applied voltage is lowered to 11V. As a result, the time period necessary for judging the sensor elements to be activated can be made substantially constant irrespective of variations in sensor characteristics. After the activation judgment, the variation of the temperature of the sensor element is monitored on the basis of the interelectrode voltage. When the element temperature is varied, the heater voltage is raised or lowered so that the element temperature is stabilized.
    • 根据本发明的氧传感器具有电池元件和泵元件,其中每个多孔电极设置在固体电解质基板的两个面上。 在开始加热加热器之后,向电池元件供给微小的电流,并且基于在该通电时产生的电极间电压来判断传感器元件的启动。 在通电开始时,加热器电压设定为12V。 当电极间电压达到预定电压所需的时间段短时,施加的电压降低到11V。 结果,无论传感器特性的变化如何,可以使用于判断要激活的传感器元件所需的时间段基本上是恒定的。 在激活判断之后,基于电极间电压来监测传感器元件的温度变化。 当元件温度变化时,加热器电压升高或降低,使元件温度稳定。
    • 49. 发明授权
    • Method of activating zirconia oxygen sensor
    • 激活氧化锆氧传感器的方法
    • US5433830A
    • 1995-07-18
    • US186650
    • 1994-01-26
    • Takeshi KawaiNobuhiro HayakawaTessho Yamada
    • Takeshi KawaiNobuhiro HayakawaTessho Yamada
    • G01N27/419G01N27/26
    • G01N27/419
    • Activation treatment for a zirconia oxygen sensor is performed by applying alternately a treating voltage, which can make an oxygen partial pressure at the electrode-zirconia interface of a sensor equal to or higher than a critical oxygen partial pressure value (10.sup.-34 atm) not to cause blackening, between a pair of electrodes of the sensor at temperatures of 500.degree. to 800.degree. C. As a result, the treatment current flowing through the sensor can always be held below the critical level, whereby the sensor can be activated without causing blackening and other physical structural changes to occur in the zirconia sensing element. If the sensor is to be used in an A/F ratio control or the like on an internal combustion engine, it can be rendered active at all times by the activation treatment during or before or after the control.
    • 氧化锆氧传感器的激活处理通过交替施加处理电压来进行,该处理电压可以使传感器的电极 - 氧化锆界面处的氧分压等于或高于临界氧分压值(10-34atm)而不是 在500〜800℃的温度下在传感器的一对电极之间引起黑化。结果,流过传感器的处理电流总是能够保持在临界水平以下,从而可以激活传感器而不引起 氧化锆感应元件中发生黑化和其他物理结构变化。 如果将传感器用于内燃机上的A / F比控制等,则可以通过在控制期间或控制之后或之后的激活处理始终使其变为活动状态。
    • 50. 发明授权
    • Amorphous photo-detecting element with spatial filter
    • 具有空间滤光片的非晶光电检测元件
    • US5130775A
    • 1992-07-14
    • US539830
    • 1990-06-18
    • Shosaku MaedaTakeshi KawaiFumio Koike
    • Shosaku MaedaTakeshi KawaiFumio Koike
    • H01L27/142H01L31/0224H01L31/0392
    • H01L31/035281H01L31/022433H01L31/03921H01L31/046H01L31/075Y02E10/548
    • In this sensitive, relatively inexpensive to manufacture, photo-detector, one surface of an amorphous silicon photovoltaic element is bonded to a thin transparent conductive layer formed on an insulating base. A conductive pattern is formed on the opposite surface of the element. The conductive layer may be formed of indium-tin oxide (ITO) and the photovoltaic element may be an element with an intrinsic semiconducting layer between p and n doped layers. The photovoltaic element generates component currents in response to photons passing through the transparent base and conducting layer. Those current components flowing predominantly in a direction at right angles to the photovoltaic element surfaces are summed by the conductive pattern which acts as a spatial filter, responsive to desired ones of these components and relatively unresponsive to other current components. The spatial filter conductive pattern and the transparent conducting layer may be coupled as the input to a suitable high impedance current detector.
    • 在这种敏感的,相对便宜的制造中,光电检测器,非晶硅光电元件的一个表面被结合到形成在绝缘基底上的薄的透明导电层。 在元件的相对表面上形成导电图案。 导电层可以由氧化铟锡(ITO)形成,并且光电元件可以是在p和n掺杂层之间具有本征半导体层的元件。 光电元件响应于穿过透明基底和导电层的光子而产生分量电流。 主要以与光电元件表面成直角的方向流动的那些电流分量由作为空间滤波器的导电图形相加,响应于这些组分中的所需元件,并且对其它电流分量相对不响应。 空间滤波器导电图案和透明导电层可以作为输入耦合到合适的高阻抗电流检测器。