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    • 1. 发明授权
    • Image forming device, image forming process, and pattern forming process, and photosensitive material used therein
    • 图像形成装置,图像形成处理和图案形成处理以及其中使用的感光材料
    • US06195156B1
    • 2001-02-27
    • US09042079
    • 1998-03-13
    • Hirohisa MiyamotoShuzo HiraharaYasushi ShinjoKoichi TsunemiMitsunaga SaitoMasahiro Hosoya
    • Hirohisa MiyamotoShuzo HiraharaYasushi ShinjoKoichi TsunemiMitsunaga SaitoMasahiro Hosoya
    • G03B2704
    • G03G13/22
    • The present invention provides an image forming process, an image forming device, and a pattern forming process intended to obtain an image by developing a latent image which has been formed by exposing to light a photosensitive material including a photocatalytic layer which includes a photocatalyst and a hydrophobic layer applied on top of said photocatalytic layer, or a photosensitive material including a hydrophobic photosensitive layer which includes a photocatalyst and an organic compound, wherein the photocatalyst, when exposed to light, changes the angle of contact with water in the area on the surface of the photosensitive material which is exposed to light, thereby differentiating from the angle of contact with water in the area which is not exposed to light. The present invention also provides an image forming device and an image forming process which enable on-demand printing and reduce effects on health and environment, as well as a pattern forming process which is simple and reduces the effects on health and the environment.
    • 本发明提供一种图像形成处理,图像形成装置和图案形成处理,其旨在通过将通过曝光光形成的潜像显影而获得图像,所述感光材料包括光催化剂层,所述光敏材料包括光催化剂和 施加在所述光催化层顶部的疏水层,或包含光催化剂和有机化合物的疏水性感光层的感光材料,其中光催化剂在曝光时改变与表面上的区域中的水的接触角度 感光材料暴露于光,从而与不暴露于光的区域中的与水接触的角度区分开来。 本发明还提供一种图像形成装置和图像形成方法,其能够进行按需打印并减少对健康和环境的影响,以及简单的图案形成处理,并且减少对健康和环境的影响。
    • 3. 发明授权
    • Ink jet recording apparatus
    • 喷墨记录装置
    • US06123415A
    • 2000-09-26
    • US774072
    • 1996-12-23
    • Hitoshi NagatoTeruo MurakamiShuzo HiraharaHideyuki NakaoKoichi IshiiYasuo Hosaka
    • Hitoshi NagatoTeruo MurakamiShuzo HiraharaHideyuki NakaoKoichi IshiiYasuo Hosaka
    • B41J2/06
    • B82Y15/00B41J2/06B41J2002/061
    • In the ink jet recording apparatus for recording an image by supplying ink obtained by dispersing color material components in a solvent to a head substrate and by jetting ink drops containing at least the color material components to a recording medium on the basis of electrostatic force applied to the color material components, the recording apparatus comprises a driving circuit (107) for applying voltages to electrodes of an electrode array (102) arranged on a head substrate (101), in such a way that a first potential difference whose potential level relationship is reversed at a predetermined period between the two adjacent electrodes can be applied when the color material components are cohered and/or stirred on the head substrate, and a second potential difference different from the first potential difference between the two adjacent electrodes can be applied when the ink drops are jetted toward a recording medium. In this ink jet recording apparatus, a stable recording can be made by uniformalizing the density of the ink color material components on the head substrate and further by preventing the color material components from adhering onto the electrode.
    • 在用于记录图像的喷墨记录装置中,通过将通过将颜料成分分散在溶剂中而获得的油墨提供给头基板,并且通过将至少含有着色材料成分的墨滴基于施加到 彩色材料成分,记录装置包括:驱动电路(107),用于向布置在头基板(101)上的电极阵列(102)的电极施加电压,使得其电位关系为 当在两个相邻电极之间的颜色材料成分被粘合和/或搅拌时,可以在两个相邻电极之间的预定周期处反转,并且可以应用与两个相邻电极之间的第一电位差不同的第二电位差 墨水朝向记录介质喷射。 在该喷墨记录装置中,可以通过使头基板上的油墨着色材料成分的密度均匀化,并进一步防止着色材料成分附着在电极上,进行稳定的记录。
    • 7. 发明授权
    • Microfluidic device and analyzing device using the same
    • 微流体装置及分析装置采用相同的方法
    • US08313626B2
    • 2012-11-20
    • US13067005
    • 2011-05-02
    • Shuzo HiraharaTomoyuki TsurutaHaruyuki Minamitani
    • Shuzo HiraharaTomoyuki TsurutaHaruyuki Minamitani
    • G01N27/26B81B1/00
    • B01F13/0076B01L3/5027B01L2300/088B01L2300/0887F04B19/006
    • The conventional micropump and the conventional micromixer have the following problems. In a mechanical or hydrodynamic method, the structure of the inside of a flow path is complex so as to easily cause clogging, and manufacturing cost is high, and dead volume is large. Additionally, in an electrical method, the conventional micropump or the conventional micromixer was incapable of operating with a liquid having the concentration of a physiological saline that is important in the medical or biological field although the structure of the flow path is simple. These problems are solved by applying an AC voltage to a pair of electrodes in which an electrode-to-electrode gap between the pair of electrodes is vertically arranged and by generating the flow of a fluid in the direction opposite to gravity along the electrode-to-electrode gap. A micropump (43, 44) can be realized especially by forming a micro-sized flow path (11) in the vertical direction along the electrode-to-electrode gap, and a micromixer (41) can be realized by forming a micro-sized flow path (11) in the horizontal direction to cross at right angle to the electrode-to-electrode gap.
    • 传统的微型泵和传统的微混合器具有以下问题。 在机械或流体动力学方法中,流路内部的结构复杂,容易引起堵塞,制造成本高,死体积大。 此外,在电气方法中,传统的微型泵或常规微混合器不能用具有在医学或生物领域中重要的生理盐水浓度的液体进行操作,尽管流动路径的结构简单。 通过对一对电极施加AC电压来解决这些问题,在该对电极中,一对电极之间的电极间电极垂直排列,并且沿与电极相反的方向产生与重力相反的方向的流体 - 电极间隙。 特别是通过在电极间电极间沿垂直方向形成微小流路(11),能够实现微型泵(43,44),通过形成微型混合器(41) 流动路径(11)在水平方向上与电极间电极交叉成直角。
    • 8. 发明申请
    • Microfluidic device, measuring apparatus, and microfluid stirring method
    • 微流体装置,测量装置和微流体搅拌方法
    • US20080047833A1
    • 2008-02-28
    • US11802419
    • 2007-05-22
    • Shuzo HiraharaKentaro TaniHaruyuki Minamitani
    • Shuzo HiraharaKentaro TaniHaruyuki Minamitani
    • G01N27/26
    • G01N33/49B01L3/502715B01L2300/1833
    • Conventionally, it has been difficult to effectively and promptly stir and mix fluids together by use of a microfluidic device having a simple flow path structure. Additionally, there has been no means for keeping a particulate sample floating in a fluid in a flow path for a long time without precipitating the particulate sample. Additionally, there has been no method for measuring the true size of a flowing and floating particulate sample by use of a microscope. The present invention solves these problems by using a microfluidic device in which an electrode pair having a wide electrode-to-electrode gap is formed in a flow path or in a chamber, and by applying an AC voltage to this electrode pair, and by generating an eddy by which a fluid is swirled in a torus manner. The accurate size of the particulate sample that crosses the in-focus plane can be measured especially by setting an in-focus plane (53) of an objective lens (52) of a microscope at a position through which a swirling flow (41) vertically passes.
    • 通常,通过使用具有简单流路结构的微流体装置,难以有效地并且迅速地将流体混合在一起。 此外,没有使颗粒样品在流动路径中长时间漂浮在流体中而不使颗粒样品沉淀的方法。 另外,没有使用显微镜测量流动和浮动的颗粒样品的真实尺寸的方法。 本发明通过使用微流体装置来解决这些问题,其中在流路或室内形成具有宽的电极间电极间隙的电极对,并且通过向该电极对施加AC电压,并且通过产生 流体以环形方式旋转的涡流。 可以通过将显微镜的物镜(52)的聚焦平面(53)设置在垂直于旋转流(41)的位置上来测量穿过对焦平面的颗粒样品的精确尺寸 通过