Filter Cartridge Endplate with Integrated Flow Structure
    2.
    发明申请
    Filter Cartridge Endplate with Integrated Flow Structure 有权
    带集成流量结构的滤芯式端板

    公开(公告)号:US20150096932A1

    公开(公告)日:2015-04-09

    申请号:US14372834

    申请日:2012-02-23

    IPC分类号: B01D35/30 B01D29/23

    摘要: A filter cartridge endplate (12) is described herein that has an integrated flow structure. For example, the integrated flow structure has concentric flow portions disposed at a center of the endplate (12), where a separator (10) is built into the endplate (12) that separates fluid flow. The endplate (12) includes a plate with a major surface, a separator (10) that protrudes axially away from the major surface. The separator (10) includes a first flow portion (14) and a second flow portion (16), where the first flow portion (14) is disposed radially inward relative to the second flow portion (16). The first flow portion (14) includes a channel (22) and the second flow portion includes a channel (24). The respective channels (22,24) are configured to allow axial fluid flow relative to the plate, and configured to allow fluid flow that is localized toward the center of the plate (12).

    摘要翻译: 本文描述了具有集成流动结构的过滤器滤芯端板(12)。 例如,集成流动结构具有设置在端板(12)的中心处的同心流动部分,其中分离器(10)内置在分离流体流动的端板(12)中。 端板(12)包括具有主表面的板,从主表面轴向突出的隔板(10)。 分离器(10)包括第一流动部分(14)和第二流动部分(16),其中第一流动部分(14)相对于第二流动部分(16)径向向内设置。 第一流动部分(14)包括通道(22),第二流动部分包括通道(24)。 相应的通道(22,24)构造成允许相对于板的轴向流体流动,并且构造成允许朝向板(12)的中心定位的流体流动。

    GAN-BASED VERTICAL STRUCTURE LED APPLYING GRAPHENE FILM CURRENT EXPANSION LAYER
    3.
    发明申请
    GAN-BASED VERTICAL STRUCTURE LED APPLYING GRAPHENE FILM CURRENT EXPANSION LAYER 审中-公开
    基于GAN的垂直结构LED应用石墨膜电流扩展层

    公开(公告)号:US20140151632A1

    公开(公告)日:2014-06-05

    申请号:US14123439

    申请日:2012-03-13

    IPC分类号: H01L33/06 H01L33/32

    摘要: The present invention discloses A graphene film electrical current spreading layer applied GaN-based LED in vertical. structure, comprising: a p-type metal electrode including a metal support substrate and a metal reflective mirror formed on the metal support substrate; a hole injecting layer formed on the metal reflective mirror of the p-type metal electrode; an electron blocking layer formed on the hole injecting layer; a lighting layer formed on the electron blocking layer; an electron limiting layer formed on the lighting layer; an electron injecting layer formed on the electron limiting layer; an electrical current spreading layer formed on the electron injecting layer; two n-type metal electrodes formed on the electrical spreading layer and covering a part of the electrical current spreading layer.

    摘要翻译: 本发明公开了一种石墨烯膜电流扩散层,其在垂直方向上施加GaN基LED。 结构,包括:p型金属电极,其包括形成在所述金属支撑基板上的金属支撑基板和金属反射镜; 形成在p型金属电极的金属反射镜上的空穴注入层; 形成在空穴注入层上的电子阻挡层; 形成在电子阻挡层上的照明层; 形成在照明层上的电子限制层; 形成在电子限制层上的电子注入层; 形成在电子注入层上的电流扩散层; 两个n型金属电极形成在电扩散层上并覆盖电流扩展层的一部分。

    STIMULI-RESPONSIVE LOW SOLUBILITY HYDROGEL COPOLYMERS OF N-ISOPROPYL ACRYLAMIDE AND SYNTHESIS METHOD
    4.
    发明申请
    STIMULI-RESPONSIVE LOW SOLUBILITY HYDROGEL COPOLYMERS OF N-ISOPROPYL ACRYLAMIDE AND SYNTHESIS METHOD 审中-公开
    硝基丙烯酰胺的合成低分子量水凝胶共聚物及合成方法

    公开(公告)号:US20100203141A1

    公开(公告)日:2010-08-12

    申请号:US12703266

    申请日:2010-02-10

    摘要: Preferred embodiment stimuli-responsive low solubility copolymer hydrogel compositions of the invention include polymerized N-isopropylacrylamide and water insoluble monomer or oligomer repeating units. The repeating units are arranged within the polymer backbone of the copolymer hydrogel. In a preferred fabrication method, precursors of N-isopropylacrylamide and precursors of the water insoluble monomer of oligomer are solved in a liquid solvent to form a solution in a container. An initiator is added to the solution. Gas is bubbled through the solution, and the container is sealed. The solution is stirred while heating to a polymerization temperature and polymerization is permitted to complete to form the copolymer hydrogel composition.

    摘要翻译: 本发明的优选实施方案的刺激响应性低溶解度共聚物水凝胶组合物包括聚合的N-异丙基丙烯酰胺和水不溶性单体或低聚物重复单元。 重复单元布置在共聚物水凝胶的聚合物主链内。 在优选的制造方法中,将N-异丙基丙烯酰胺的前体和低聚物的水不溶性单体的前体溶解在液体溶剂中以在容器中形成溶液。 将一个启动器添加到该解决方案中。 将气体鼓泡通过溶液,并将容器密封。 在加热至聚合温度的同时搅拌该溶液,并允许聚合完成以形成共聚物水凝胶组合物。

    NANOFIBER COVERED MICRO COMPONENTS AND METHODS FOR MICRO COMPONENT COOLING
    6.
    发明申请
    NANOFIBER COVERED MICRO COMPONENTS AND METHODS FOR MICRO COMPONENT COOLING 审中-公开
    NANOFIBER覆盖的微型组件和微型组件冷却方法

    公开(公告)号:US20120090825A1

    公开(公告)日:2012-04-19

    申请号:US13273719

    申请日:2011-10-14

    CPC分类号: C25D5/56 C25D7/00

    摘要: A device including a micro component having an external surface and a permeable nanofiber covering on at least a portion of the external surface of the micro component. A cooled micro component system further includes a droplet spray system for spraying liquid droplets onto the nanofiber covering to cool the micro component. In an example method for cooling a micro component, droplet spray is directed onto a nanofiber covering that covers at least a portion of the micro component. The directing is controlled to permit efficient spreading and evaporation of liquid permeating the nanofiber covering. In example embodiments nanofibers of the permeable nanofiber covering are metalized to provide a rougher surface (e.g., a nano-textured metal layer).

    摘要翻译: 一种包括具有外表面的微组件和覆盖在微组件的外表面的至少一部分上的可渗透纳米纤维的装置。 冷却的微组件系统还包括用于将液滴喷射到纳米纤维覆盖物上以冷却微组件的液滴喷射系统。 在用于冷却微组件的示例性方法中,液滴喷射被引导到覆盖微组件的至少一部分的纳米纤维覆盖物上。 控制引导以允许渗透纳米纤维覆盖层的液体的有效扩散和蒸发。 在示例实施例中,可渗透纳米纤维覆盖物的纳米纤维被金属化以提供更粗糙的表面(例如,纳米纹理金属层)。