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    • 3. 发明申请
    • Field Emission Type Planar Lamp And Method For The Same
    • 场发射型平面灯及其方法
    • US20080079348A1
    • 2008-04-03
    • US11538132
    • 2006-10-03
    • Kuei-Wen ChengShie-Heng LeeChun-Yen Hsiao
    • Kuei-Wen ChengShie-Heng LeeChun-Yen Hsiao
    • H01J1/02H01J9/24H01J1/16
    • H01J63/06H01J2329/00
    • A field emission type planar lamp with stacked structure and method for the same are proposed. The field emission type planar lamp includes an anode plate, a cathode plate and a panel. The anode plate includes a anode substrate. The cathode plate is stacked with the anode plate and includes an isolation mesh with a plurality of apertures and a cathode mesh with a plurality of through holes. The through holes are corresponding to the apertures. The panel is sealed with t he anode substrate to form a vacuum cavity to enclose the anode unit and the cathode plate. Electron beams generated by the cathode plate bombard the anode plate to illuminate. The illumination will exit from one side of the panel through passage defined by the aperture and the through, besides exit from one side of the anode substrate. Therefore, the field emission type planar lamp has two-side illumination.
    • 提出一种堆叠结构的场致发射型平面灯及其制造方法。 场发射型平面灯包括阳极板,阴极板和面板。 阳极板包括阳极基板。 阴极板与阳极板堆叠并且包括具有多个孔的隔离网和具有多个通孔的阴极网。 通孔对应于孔。 面板用阳极基板密封以形成真空腔,以包围阳极单元和阴极板。 由阴极板产生的电子束轰击阳极板照亮。 除了从阳极基板的一侧离开之外,照明将通过由孔径和通孔限定的通道从面板的一侧离开。 因此,场发射型平面灯具有双面照明。
    • 4. 发明申请
    • Method of manufacturing carbon nanotube electron field emitters by dot-matrix sequential electrophoretic deposition
    • 通过点阵顺序电泳沉积制造碳纳米管电子场发射体的方法
    • US20070187246A1
    • 2007-08-16
    • US11354846
    • 2006-02-16
    • Kuei-Wen ChengJin-Lung TsaiShie-Heng LeeYu-An LiChun-Yen Hsiao
    • Kuei-Wen ChengJin-Lung TsaiShie-Heng LeeYu-An LiChun-Yen Hsiao
    • C25B7/00
    • C25B7/00
    • A method of manufacturing carbon nanotube electron field emitters by do-matrix sequential electrophoretic deposition forms an electric field for only one pixel in the electrophoretic deposition, so that only the electrophoretic area has the electrophoretic effect. Longitudinally aligned cathode electrodes of a cathode plate include a plurality of electron field transmitters at the depositing positions, and anode electrodes of an anode plate perpendicular to the cathode electrodes are preinstalled, and a switch unit provides a potential difference for each cathode or anode electrode by a sequential change, and only one alternating pixel having an electric field between the cathode and anode plates per unit time of the electrophoresis produces a deposition effect in the area for manufacturing a carbon nanotube electron field transmitter, and the sequential voltage change of each cathode or anode electrode is used to achieve the electrophoretic deposition effect for all pixels of the cathode plate.
    • 通过在线电泳沉积制作碳纳米管电子场发射体的方法仅在电泳沉积中仅形成一个像素,从而只有电泳区具有电泳效应。 阴极板的纵向排列的阴极包括在沉积位置处的多个电子场发射器,并且预先垂直于阴极电极的阳极板的阳极电极,并且开关单元通过以下方式为每个阴极或阳极电极提供电位差 顺序变化,并且在电泳的每单位时间仅具有在阴极和阳极板之间具有电场的一个交替像素在用于制造碳纳米管电子场发射器的区域中产生沉积效应,并且每个阴极的顺序电压变化或 阳极用于实现阴极板所有像素的电泳沉积效应。
    • 6. 发明申请
    • Method for enhancing homogeneity and effeciency of carbon nanotube electron emission source of field emission display
    • 提高场致发射显示碳纳米管电子发射源均匀性和有效性的方法
    • US20060213774A1
    • 2006-09-28
    • US11090269
    • 2005-03-28
    • Chun-Yen HsiaoShie-Heng LeeYu-An LiJin-Lung TsaiKuei-Wen Cheng
    • Chun-Yen HsiaoShie-Heng LeeYu-An LiJin-Lung TsaiKuei-Wen Cheng
    • C25B7/00
    • C25D13/02B82Y10/00C25D13/22H01J9/025H01J2201/30469
    • A method for enhancing the homogeneity and efficiency of carbon nanotube electron emission source. The method includes the following steps. First, a semi-manufactured cathode structure is prepared. Then, the cathode structure and the metallic plate are connected to the electrophoresis electrodes. After that, the side of the cathode structure to be electrophoresis deposited is kept a fixed distance in parallel with the metallic plate. Then, the electrophoresis deposition is performed to the semi-manufactured cathode structure by placing the combination into the solution of the electrophoresis tank. Later, an electric field is formed from a direct current voltage of a power supply. In this manner, the carbon nanotubes are deposited on the cathode electrode to form the electron emission source. After the deposition process of the cathode structure is completed, the combination is baked with a low temperature so as to remove the residual water solution on the cathode structure. Meanwhile, the indium chloride charger and the electrolyte hydroxide ions react to form indium hydroxide. Next, a sintering process is performed for re-oxidating the indium hydroxide on the cathode electrode layer back to indium oxide. Consequently, the electron conductivity of the carbon nanotubes and the cathode electron layer is enhanced.
    • 一种提高碳纳米管电子发射源的均匀性和效率的方法。 该方法包括以下步骤。 首先,制备半制成的阴极结构。 然后,将阴极结构和金属板连接到电泳电极。 之后,将要电泳沉积的阴极结构的一侧与金属板平行地保持固定的距离。 然后,通过将组合放入电泳槽的溶液中,对半制成的阴极结构进行电泳沉积。 之后,由电源的直流电压形成电场。 以这种方式,将碳纳米管沉积在阴极上形成电子发射源。 在阴极结构的沉积工艺完成之后,将该组合以低温烘烤,以除去阴极结构上的残余水溶液。 同时,氯化铟填充剂和电解质氢氧化物离子反应形成氢氧化铟。 接下来,进行烧结工序,将阴极电极层上的氢氧化铟再氧化成氧化铟。 因此,提高了碳纳米管和阴极电子层的电子传导性。
    • 8. 发明申请
    • Method for batch fabricating electron emission source of electrophoresis deposited carbon nanotubes
    • 批量制作电泳沉积碳纳米管的电子发射源的方法
    • US20070000782A1
    • 2007-01-04
    • US11168487
    • 2005-06-29
    • Kuei-Wen ChengJin-Lung TsaiShie-Heng LeeYu-An LiChun-Yen Hsiao
    • Kuei-Wen ChengJin-Lung TsaiShie-Heng LeeYu-An LiChun-Yen Hsiao
    • C25B7/00
    • C25D13/02C25D13/12
    • A method for batch fabricating electron emission source of electrophoresis deposited carbon nanotubes includes preparing a semi-manufactured cathode structure and a metallic plate connected with electrophoresis electrodes. The cathode structure and the metallic plate that are parallel to each other are separated with a fixed distance and are rinsed in an electrophoresis solution. A processe is performed to remove the bubbles formed in the cathode structure, and to electrophoresis deposit the carbon nanotubes onto the cathode structure. After each deposition process is completed, the cathode structure is baked under a low temperature so as to remove the residual solution remained on the cathode structure. After a homogeneous carbon nanotubes layer is deposited to form the electron emission source, a sintering process is performed so as to transfer the chargers into conductive metallic oxide salts. Thereby, the electron conduction of the carbon nanotubes and the cathode electrode layer is enhanced.
    • 批量制造电泳沉积碳纳米管的电子发射源的方法包括制备半制成的阴极结构和与电泳电极连接的金属板。 将彼此平行的阴极结构体和金属板以一定距离分离,并在电泳液中进行冲洗。 执行处理以去除阴极结构中形成的气泡,并将碳纳米管电泳电沉积到阴极结构上。 在每个沉积工艺完成后,在低温下烘烤阴极结构,以除去留在阴极结构上的残余溶液。 在沉积均匀的碳纳米管层以形成电子发射源之后,进行烧结工艺以将充电器转移到导电金属氧化物盐中。 由此,能够提高碳纳米管和阴极电极层的电子传导。
    • 9. 发明申请
    • Method for enhancing homogeneity of carbon nanotube electron emission source made by electrophoresis deposition
    • 通过电泳沉积法提高碳纳米管电子发射源均匀性的方法
    • US20060217025A1
    • 2006-09-28
    • US11090221
    • 2005-03-28
    • Chun-Yen HsiaoShie-Heng LeeYu-An LiJin-Lung TsaiKuei-Wen Cheng
    • Chun-Yen HsiaoShie-Heng LeeYu-An LiJin-Lung TsaiKuei-Wen Cheng
    • H01J9/00H01J9/20
    • H01J9/025
    • A method for enhancing the homogeneity of carbon nanotube electron emission source which is manufactured using electrophoresis deposition. The method includes the following steps. First, a semi-manufactured cathode structure is prepared. Then, the cathode structure and the metallic plate are connected to the electrophoresis electrodes. After that, the side of the cathode structure to be electrophoresis deposited is kept a fixed distance in parallel with the metallic plate. Then, the electrophoresis deposition is performed to the semi-manufactured cathode structure by placing the combination into the solution of the electrophoresis tank. Later, an electric field is formed from a direct current pulse voltage of a power supply. In this manner, the carbon nanotubes are deposited on the cathode electrode to form the electron emission source. After the deposition process of the cathode structure is completed, the combination is baked with a low temperature so as to remove the residual water solution on the cathode structure. Meanwhile, the indium chloride charger and the electrolyte hydroxide ions react to form indium hydroxide. Next, a sintering process is performed for re-oxidating the indium hydroxide on the cathode electrode layer back to indium oxide. Consequently, the electron conductivity of the carbon nanotubes and the cathode electron layer is enhanced.
    • 一种增强碳纳米管电子发射源的均匀性的方法,该方法是使用电泳沉积制造的。 该方法包括以下步骤。 首先,制备半制成的阴极结构。 然后,将阴极结构和金属板连接到电泳电极。 之后,将要电泳沉积的阴极结构的一侧与金属板平行地保持固定的距离。 然后,通过将组合放入电泳槽的溶液中,对半制成的阴极结构进行电泳沉积。 之后,由电源的直流脉冲电压形成电场。 以这种方式,将碳纳米管沉积在阴极上形成电子发射源。 在阴极结构的沉积工艺完成之后,将该组合以低温烘烤,以除去阴极结构上的残余水溶液。 同时,氯化铟填充剂和电解质氢氧化物离子反应形成氢氧化铟。 接下来,进行烧结工序,将阴极电极层上的氢氧化铟再氧化成氧化铟。 因此,提高了碳纳米管和阴极电子层的电子传导性。