公开(公告)号：US06986955B2

公开(公告)日：2006-01-17

申请号：US10019082

申请日：2001-08-02

Applicant: Jerome Schmitt ,  George Guang-Ji Cui ,  Henry A. Luten, III ,  Fang Yang ,  Fe Alma Gladden ,  Scott Flanagan ,  Yongdong Jiang ,  Andrew Tye Hunt

Inventor： Jerome Schmitt ,  George Guang-Ji Cui ,  Henry A. Luten, III ,  Fang Yang ,  Fe Alma Gladden ,  Scott Flanagan ,  Yongdong Jiang ,  Andrew Tye Hunt

IPC: B32B9/04 ,  B32B3/00 ,  C30B29/32 ,  C01G23/047

CPC classification number: C23C16/404 ,  C23C16/405 ,  C23C16/406 ,  C30B25/02 ,  C30B29/32 ,  Y10T428/24917

Abstract: Epitaxial and reduced grain boundary materials are deposited on substrates for use in electronic and optical applications. A specific material disclosed is epitaxial barium strontium titanate (14) deposited on the C-plane of sapphire (12).

Abstract translation: 外延和还原的晶界材料沉积在用于电子和光学应用的基板上。 公开的具体材料是沉积在蓝宝石（12）的C平面上的外延钛酸钡锶（14）。

公开(公告)号：US09040120B2

公开(公告)日：2015-05-26

申请号：US13204483

申请日：2011-08-05

Applicant: Andrew Hunt ,  Yongdong Jiang ,  Kenneth Scott Laverdure ,  Anthony Robert Knoerzer

Inventor： Andrew Hunt ,  Yongdong Jiang ,  Kenneth Scott Laverdure ,  Anthony Robert Knoerzer

IPC: C23C16/00 ,  C23C16/40 ,  C23C16/02 ,  C23C16/50 ,  C23C14/02 ,  C23C16/453

CPC classification number: C23C16/40 ,  C23C14/02 ,  C23C16/02 ,  C23C16/0272 ,  C23C16/401 ,  C23C16/402 ,  C23C16/453 ,  C23C16/50

Abstract: An inorganic nanolayer surface coated polymer film product is disclosed with enhancements such as improved metallization capability, low cost, low polymer additives and modifiers, improved recyclability, and good web properties. Also method for priming a flexible film substrate to enhance the reactivity or wettability of the substrate for metallization is disclosed. A substrate film is coated with one or more nanolayers of a metal or metal oxide applied by CCVD and/or PECVD at open atmosphere. The deposited coating acts to enhance the surface energy of the film substrate and to and reduce the surface gauge variation of the substrate or supporting film, thereby enhancing the wettability of the film substrate for metallization and/or to improve the anti-block characteristics of the film. The deposited coatings may also act as a barrier layer for lowering the permeability of light, gas and vapor transmission through the substrate.

Abstract translation: 公开了无机纳米层表面涂覆的聚合物膜产品，其具有改进的金属化能力，低成本，低聚合物添加剂和改性剂，改善的可循环性和良好的网性能。 公开了一种用于引发柔性膜基底以提高用于金属化的基底的反应性或润湿性的方法。 在敞开的气氛下，用一个或多个通过CCVD和/或PECVD施加的金属或金属氧化物的纳米层涂覆基底膜。 沉积的涂层用于增强膜基材的表面能，并降低基材或支撑膜的表面规格变化，从而提高用于金属化的膜基材的润湿性和/或改善薄膜基材的抗块特性 电影。 沉积的涂层还可以用作阻挡层，用于降低通过基底的光，气体和蒸气透过率的渗透性。

公开(公告)号：US07282238B2

公开(公告)日：2007-10-16

申请号：US10111684

申请日：2001-06-27

Applicant: Subramaniam Shanmugham ,  Andrew Tye Hunt ,  Girish Deshpande ,  Tzyy-Jiuan Jan Hwang ,  Erika Moore ,  Yongdong Jiang

Inventor： Subramaniam Shanmugham ,  Andrew Tye Hunt ,  Girish Deshpande ,  Tzyy-Jiuan Jan Hwang ,  Erika Moore ,  Yongdong Jiang

IPC: B05D3/08

CPC classification number: C03C17/001 ,  B05D1/08 ,  B05D1/34 ,  B05D3/0254 ,  B05D3/08 ,  B05D2518/10 ,  C03C17/007 ,  C03C17/009 ,  C03C17/32 ,  C03C17/42 ,  C03C2217/425 ,  C03C2217/445 ,  C03C2217/475 ,  C08K3/22 ,  C08K3/346 ,  C09D7/61 ,  C09D183/04 ,  C23C4/12 ,  C23C4/123 ,  C23C26/00 ,  Y10T428/12583 ,  Y10T428/31522

Abstract: A coherent material is formed on a substrate (10) by providing a precursor suspension (14) in which particulates are suspended in a carrier fluid, and directing the precursor suspension (14) at the substrate (10) from a first source (12). Generally contemporaneously with application of the deposited precursor suspension (14) to the surface, hot gases, e.g. hot gases produced by a flame (16), are directed at the substrate (10) from a remote second source (18) to fuse the particulates into the coherent material.

Abstract translation: 通过提供一种前体悬浮液（14），其中颗粒悬浮在载体流体中，并且将前体悬浮液（14）从第一源（12）引导到基底（10）处，在基底（10）上形成相干材料， 。 通常同时将沉积的前体悬浮液（14）施加到表面，热气体，例如， 由火焰（16）产生的热气体从远程第二源（18）引导到衬底（10），以将微粒熔合成粘结材料。

公开(公告)号：US20130066477A1

公开(公告)日：2013-03-14

申请号：US13582767

申请日：2010-09-07

Applicant: Yongdong Jiang

Inventor： Yongdong Jiang

IPC: G06F1/32

CPC classification number: H04L12/2823 ,  G01D4/002 ,  G05B2219/25387 ,  H04L41/0813 ,  H04L41/0833 ,  Y02B90/241 ,  Y02B90/244 ,  Y02P80/114 ,  Y04S20/32 ,  Y04S20/327

Abstract: An energy source management control system based on cloud computing includes: a field controller (11), for field controlling each energy consumption device (10) according to user defined parameters and sending the user defined parameters to a cloud computing management control platform (13); an energy consumption parameter collector (12) for collecting parameters related to energy consumption of each energy consumption device (10) and sending the collected parameters to the cloud computing management control platform (13); the cloud computing management control platform (13), for adjusting a field control mode of the field controller (11) according to the collected parameters related to energy consumption of each energy consumption device (10) and the user defined parameters. A method for energy management control based on cloud computing is also provided.

Abstract translation: 一种基于云计算的能源管理控制系统包括：一个现场控制器（11），用于根据用户定义的参数实时控制每个能量消耗装置（10），并将用户定义的参数发送给云计算管理控制平台（13） ; 能量消耗参数收集器（12），用于收集与每个能量消耗装置（10）的能量消耗相关的参数，并将收集的参数发送到云计算管理控制平台（13）; 云计算管理控制平台（13），用于根据与每个能量消耗装置（10）的能量消耗相关的所收集的参数和用户定义的参数来调整现场控制器（11）的现场控制模式。 还提供了一种基于云计算的能量管理控制方法。

公开(公告)号：US20130034689A1

公开(公告)日：2013-02-07

申请号：US13204523

申请日：2011-08-05

Applicant: Andrew Tye Hunt ,  Yongdong Jiang

Inventor： Andrew Tye Hunt ,  Yongdong Jiang

IPC: B32B3/00 ,  B32B9/04 ,  B32B7/02 ,  B32B27/36 ,  B32B27/00

CPC classification number: B32B27/08 ,  B32B27/281 ,  B32B27/302 ,  B32B27/32 ,  B32B27/36 ,  B32B2250/24 ,  B32B2255/10 ,  B32B2255/20 ,  B32B2307/716 ,  B32B2307/7242 ,  B32B2439/00 ,  C23C14/02 ,  C23C14/024 ,  C23C14/20 ,  C23C14/562 ,  C23C16/0209 ,  C23C16/402 ,  C23C16/453 ,  C23C16/545 ,  C23C16/56 ,  C23C28/322 ,  C23C28/345 ,  Y10T428/24355 ,  Y10T428/2495 ,  Y10T428/265 ,  Y10T428/31721 ,  Y10T428/31786 ,  Y10T428/31855

Abstract: An inorganic nanolayer surface coated polymer film product is disclosed with enhancements such as improved metallization capability, low cost, low polymer additives and modifiers, improved recyclability, and good web properties. Also method for priming a flexible film substrate to enhance the reactivity or wettability of the substrate for metallization is disclosed. A substrate film is coated with one or more nanolayers of a metal or metal oxide applied by CCVD and/or PECVD at open atmosphere. The deposited coating acts to enhance the surface energy of the film substrate and to and reduce the surface gauge variation of the substrate or supporting film, thereby enhancing the wettability of the film substrate for metallization and/or to improve the anti-block characteristics of the film. The deposited coatings may also act as a barrier layer for lowering the permeability of light, gas and vapor transmission through the substrate.

Abstract translation: 公开了无机纳米层表面涂覆的聚合物膜产品，其具有改进的金属化能力，低成本，低聚合物添加剂和改性剂，改善的可循环性和良好的网性能。 公开了一种用于引发柔性膜基底以提高用于金属化的基底的反应性或润湿性的方法。 在敞开的气氛下，用一个或多个通过CCVD和/或PECVD施加的金属或金属氧化物的纳米层涂覆基底膜。 沉积的涂层用于增强膜基材的表面能，并降低基材或支撑膜的表面规格变化，从而提高用于金属化的膜基材的润湿性和/或改善薄膜基材的抗块特性 电影。 沉积的涂层还可以用作阻挡层，用于降低通过基底的光，气体和蒸气透过率的渗透性。

公开(公告)号：US20100246009A1

公开(公告)日：2010-09-30

申请号：US12438374

申请日：2007-08-21

Applicant: Todd A. Polley ,  Andrew Tye Hunt ,  Yongdong Jiang ,  Eric Stepowany ,  Scott Flanagan

Inventor： Todd A. Polley ,  Andrew Tye Hunt ,  Yongdong Jiang ,  Eric Stepowany ,  Scott Flanagan

IPC: G02B5/28 ,  H01B1/00 ,  G02B5/00 ,  B32B5/16 ,  G02B1/10

CPC classification number: C23C16/30 ,  C08K3/08 ,  C09D7/61 ,  C09D7/67 ,  C09D7/70 ,  C23C16/006 ,  Y10T428/25 ,  Y10T428/265

Abstract: Optical coating materials comprise a transparent matrix material having dispersed nanoparticles comprising between 1 and 20 volume percent of the optical coating material. The coating materials are used to form optical coatings on substrates, such as glass/ceramic, polymer or metal, to alter the color or other optical properties. The nanoparticles are semiconductive material or elemental metals or elemental metal alloys that exhibit surface plasmon resonance.

Abstract translation: 光学涂层材料包括具有分散的纳米颗粒的透明基质材料，其包含1至20体积％的光学涂层材料。 涂层材料用于在基底上形成光学涂层，例如玻璃/陶瓷，聚合物或金属，以改变颜色或其它光学性质。 纳米颗粒是表现出等离子体共振的半导体材料或元素金属或元素金属合金。

公开(公告)号：US09350562B2

公开(公告)日：2016-05-24

申请号：US13582767

申请日：2010-09-07

Applicant: Yongdong Jiang

Inventor： Yongdong Jiang

IPC: G06F1/32 ,  H04L12/28 ,  G01D4/00

CPC classification number: H04L12/2823 ,  G01D4/002 ,  G05B2219/25387 ,  H04L41/0813 ,  H04L41/0833 ,  Y02B90/241 ,  Y02B90/244 ,  Y02P80/114 ,  Y04S20/32 ,  Y04S20/327

Abstract: An energy source management control system based on cloud computing may include a field controller, an energy consumption parameter collector and a cloud computing management control platform. The field controller may control each energy consumption device according to user defined parameters and send the user defined parameters to the cloud computing management control platform. The energy consumption parameter collector may collect parameters related to energy consumption of each energy consumption device and send the collected parameters to the cloud computing management control platform. The cloud computing management control platform may adjust a field control mode of the field controller according to the collected parameters related to energy consumption of each energy consumption device and the user defined parameters.

Abstract translation: 基于云计算的能源管理控制系统可以包括现场控制器，能量消耗参数采集器和云计算管理控制平台。 现场控制器可以根据用户定义的参数控制每个能量消耗装置，并将用户定义的参数发送到云计算管理控制平台。 能量消耗参数采集器可以收集与每个能量消耗装置的能量消耗相关的参数，并将收集的参数发送到云计算管理控制平台。 云计算管理控制平台可以根据与每个能量消耗设备的能耗相关的收集参数和用户定义的参数来调整现场控制器的现场控制模式。

公开(公告)号：US08834964B2

公开(公告)日：2014-09-16

申请号：US12765703

申请日：2010-04-22

Applicant: Masayoshi Kitada ,  Todd Fitz ,  Andrew Tye Hunt ,  Yongdong Jiang ,  Jeanne Yadlyne Smalley ,  Marvis White

Inventor： Masayoshi Kitada ,  Todd Fitz ,  Andrew Tye Hunt ,  Yongdong Jiang ,  Jeanne Yadlyne Smalley ,  Marvis White

IPC: B05D1/12 ,  C23C4/12 ,  C23C24/04 ,  B32B33/00

CPC classification number: B32B33/00 ,  B32B2307/554 ,  B32B2307/728 ,  B32B2307/73 ,  C23C4/129 ,  C23C24/04 ,  Y10T428/24372

Abstract: The process of the present invention significantly increases the durability of superhydrophobic surfaces, while retaining similar optical properties to those of the original surface. The process uses velocity and heat to take freshly formed nano- and ultrafine particles and can partially embed and chemically bond them to the substrate, creating a strongly bonded nano-to-submicron textured surface. This nanotextured surface can then be modified to have desirable surface properties; for example, it can be hydrophobic, oliophobic, or hydrophilic. The high points of the coating made with this process protect the remainder of the surface from abrasion, thus greatly increasing product life in many uses. In preferred embodiments, the process is used to coat transportation vehicle windshields.

Abstract translation: 本发明的方法显着提高超疏水表面的耐久性，同时保持与原始表面相似的光学性质。 该方法使用速度和热量来取代新形成的纳米和超细颗粒，并且可以部分地嵌入和化学地将它们结合到基底上，产生强粘合的纳米到亚微米的纹理表面。 然后可以将该纳米纹理表面改性成具有期望的表面性质; 例如，它可以是疏水性的，唾液酸的或亲水的。 用这种方法制成的涂层的高点保护了表面的其余部分免受磨损，从而大大提高了许多用途中的产品寿命。 在优选实施例中，该方法用于涂覆运输车辆挡风玻璃。

公开(公告)号：US20110143094A1

公开(公告)日：2011-06-16

申请号：US12765703

申请日：2010-04-22

Applicant: Masayoshi Kitada ,  Todd Fitz ,  Andrew Tye Hunt ,  Yongdong Jiang ,  Jeanne Yadlyne Smalley ,  Marvis White

Inventor： Masayoshi Kitada ,  Todd Fitz ,  Andrew Tye Hunt ,  Yongdong Jiang ,  Jeanne Yadlyne Smalley ,  Marvis White

IPC: B32B5/16 ,  B05D1/12 ,  B05D1/10 ,  B05D3/02 ,  B05C19/00 ,  B32B33/00

CPC classification number: B32B33/00 ,  B32B2307/554 ,  B32B2307/728 ,  B32B2307/73 ,  C23C4/129 ,  C23C24/04 ,  Y10T428/24372

Abstract: The process of the present invention significantly increases the durability of superhydrophobic surfaces, while retaining similar optical properties to those of the original surface. The process uses velocity and heat to take freshly formed nano- and ultrafine particles and can partially embed and chemically bond them to the substrate, creating a strongly bonded nano-to-submicron textured surface. This nanotextured surface can then be modified to have desirable surface properties; for example, it can be hydrophobic, oliophobic, or hydrophilic. The high points of the coating made with this process protect the remainder of the surface from abrasion, thus greatly increasing product life in many uses. In preferred embodiments, the process is used to coat transportation vehicle windshields.

Abstract translation: 本发明的方法显着提高超疏水表面的耐久性，同时保持与原始表面相似的光学性质。 该方法使用速度和热量来取代新形成的纳米和超细颗粒，并且可以部分地嵌入和化学地将它们结合到基底上，产生强粘合的纳米到亚微米的织构表面。 然后可以将该纳米纹理表面改性成具有期望的表面性质; 例如，它可以是疏水性的，唾液酸的或亲水的。 用这种方法制成的涂层的高点保护了表面的其余部分免受磨损，从而大大提高了许多用途中的产品寿命。 在优选实施例中，该方法用于涂覆运输车辆挡风玻璃。

公开(公告)号：US20090134953A1

公开(公告)日：2009-05-28

申请号：US12300464

申请日：2007-05-17

Applicant: Andrew Tye Hunt ,  Zhiyong Zhao ,  Yongdong Jiang ,  Xiaoyan Wang ,  Kwang Choi

Inventor： Andrew Tye Hunt ,  Zhiyong Zhao ,  Yongdong Jiang ,  Xiaoyan Wang ,  Kwang Choi

IPC: H03H7/01

CPC classification number: H01P1/184 ,  H01P1/203

Abstract: Tunable radio frequency (RF) devices, such as phase shifters and filters, are formed by depositing thin film layers on a substrate and patterning the thin film layers by various lithography techniques. A thin film metal layer is patterned to form a plurality of capacitors and inductors, leaving at least two grounding regions that lie closely adjacent the capacitors and inductors. As patterned portions of the grounding regions are electrically isolated from each other. Performance of the devices are improved by electrically bridging the differential potential grounding regions.

Abstract translation: 通过在衬底上沉积薄膜层并通过各种光刻技术对薄膜层进行图案化来形成可调谐射频（RF）器件，例如移相器和滤波器。 图案化薄膜金属层以形成多个电容器和电感器，留下紧邻电容器和电感器的至少两个接地区域。 由于接地区域的图案部分彼此电隔离。 通过电气桥接差分电位接地区来改善器件的性能。