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    • 14. 发明申请
    • Inorganic/organic complex nano-beads and method for manufacturing the same
    • 无机/有机复合纳米珠及其制造方法
    • US20040151907A1
    • 2004-08-05
    • US10469531
    • 2004-03-29
    • Katsuhiko NaoiShunzo Suematsu
    • B32B005/16
    • H01G9/155H01L51/0034H01L51/0035Y02E60/13Y10S977/773Y10T428/2982Y10T428/2991
    • An inorganic/organic composite material which is advantageous in physical characteristics (mechanical strength), chemical characteristics (thermal stability) and electric characteristics (electric conductivity), as compared with a sole system, as being compounded in nano order. An improved energy storage device using the inorganic/organic composite nano-beads, and especially an improved electrochemical capacitor for covering the range of a power energy density which cannot be achieved with devices of the prior art. A method of producing the inorganic/organic composite nano-beads. The inorganic/organic composite nano-beads have a three-dimensional structure in which nuclei are made of an inorganic material having a particle diameter of nano order and a high electronic conductivity, and are covered with thin films of an organic conductive material.
    • 无机/有机复合材料与单体系相比,以纳米级复合物的特性(机械强度),化学特性(热稳定性)和电特性(电导率)有利。 使用无机/有机复合纳米珠的改进的能量存储装置,特别是用于覆盖现有技术的装置无法实现的功率能量密度范围的改进的电化学电容器。 制备无机/有机复合纳米珠的方法。 无机/有机复合纳米珠具有三维结构,其中核由具有纳米级粒径和高电子导电性的无机材料制成,并被有机导电材料的薄膜覆盖。
    • 15. 发明申请
    • Transparent electroconductive laminate
    • 透明导电层压板
    • US20040151895A1
    • 2004-08-05
    • US10474638
    • 2003-10-10
    • Haruhiko ItohHitoshi MikoshibaYuji Tamura
    • B32B005/16
    • G02B1/116B32B7/02B32B27/06B32B27/18G02B5/286G02B5/287G06F3/045Y10T428/25Y10T428/254Y10T428/258Y10T428/259
    • A transparent electroconductive laminate comprising an organic polymer film having stacked on at least one surface thereof an optical interference layer and a transparent electroconductive layer in this order, the optical interference layer comprising a high refractive-index layer and a low refractive-index layer, with the low refractive-index layer being in contact with the transparent electroconductive layer, and the optical interference layer being composed of a crosslinked polymer, wherein the optical interference layer contains ultrafine particles A comprising a metal oxide and/or a metal fluoride and having a primary diameter of 100 nm or less, and/or at least one of the high refractive-index layer and the low refractive-index layer contains fine particles B having an average primary diameter as large as 1.1 times or more the thickness of the optical interference layer and an average primary diameter of 1.2 nullm or less in an amount of 0.5 wt % or less of the crosslinked polymer component. This transparent electroconductive laminate is used as a transparent electrode substrate of a transparent touch panel.
    • 一种透明导电性层叠体,其包含依次层叠有至少一个表面的光学干涉层和透明导电性层的有机聚合物膜,所述光学干涉层包括高折射率层和低折射率层, 所述低折射率层与所述透明导电层接触,并且所述光学干涉层由交联聚合物构成,其中所述光学干涉层含有包含金属氧化物和/或金属氟化物的超细颗粒A,并且具有主要 直径为100nm以下,和/或高折射率层和低折射率层中的至少一个包含平均初级直径大至光学干涉层的厚度的1.1倍以上的微粒B 平均一次直径为1.2μm以下的交联聚合物c的0.5重量%以下 组件 该透明导电性层叠体用作透明触摸面板的透明电极基板。
    • 17. 发明申请
    • Particulate reinforced aluminum composites, their components and the near net shape forming process of the components
    • 颗粒增强铝复合材料,其组分和组分的近净形状成型过程
    • US20040137218A1
    • 2004-07-15
    • US10628528
    • 2003-07-28
    • ASM Automation Assembly LtdGeneral Research Institute for Non-Ferrous Metals
    • Deming LiuChou Kee Peter LiuJian Zhong FanJun XuTao ZuoZhao Zu Gao
    • B32B005/16
    • C22F1/047B22D17/007B22F2009/041B22F2998/10C22C2001/1073C22F1/04Y10T428/256B22F9/04B22F3/04C22C1/1036
    • This invention concerns particulate reinforced Al-based composites, and the near net shape forming process of their components. The average size of the reinforced particle in the invented composites is 0.1null3.5 nullm and the volume percentage is 10null40%, and a good interfacial bonding between the reinforced particulate and the matrix is formed with the reinforced particles uniformly distributed. The production method of its billet is to have the reinforced particles and Al-base alloy powder receive variable-speed high-energy ball-milling in the balling drum. Then, with addition of a liquid surfactant, the ball-mill proceeds to carry on ball-milling. After the ball-milling, the produced composite powder undergoes cold isostatic pressing and the subsequent vacuum sintering or vacuum hot-pressing to be shaped into a hot compressed billet, which in turn undergoes semisolid thixotropic forming and may be shaped into complex-shaped components. These components can be used in various fields. This product is featured with excellent property, good machinability, stable quality, component near net shape forming and cost effective and higher performance.
    • 本发明涉及颗粒增强的基于Al的复合材料及其组分的近净形状形成过程。 本发明复合材料中增强颗粒的平均尺寸为0.1〜3.5μm,体积百分比为10〜40%,增强颗粒与基质之间形成良好的界面结合,均匀分布。 钢坯的生产方法是将球磨机中的增强颗粒和Al基合金粉末接受可变速高能球磨。 然后,加入液体表面活性剂,使球磨机进行球磨。 在球磨后,所生产的复合粉末进行冷等静压,随后进行真空烧结或真空热压成型为热压缩坯料,其又进行半固体触变形成并且可以成形为复杂形状的组分。 这些组件可用于各种领域。 本产品具有优良的性能,良好的机械加工性,质量稳定性,近净成型成分,成本效益高,性能更高。