公开(公告)号：US20140349536A1

公开(公告)日：2014-11-27

申请号：US14357004

申请日：2012-02-23

Applicant: TOP NANOSYS, INC

Inventor： Yong Sung Jo ,  Sang Keun Oh

IPC: D06M11/74 ,  B05D3/14 ,  C08K3/04 ,  C08K5/13 ,  C08K5/41 ,  C09K5/14 ,  C09D175/04

CPC classification number: D06M11/74 ,  B05D3/145 ,  B82Y30/00 ,  C08K5/13 ,  C08K5/41 ,  C09D175/04 ,  C09K5/14 ,  D06M11/47 ,  Y10S977/752 ,  Y10T428/249921 ,  Y10T442/2631 ,  C08K3/041

Abstract: A heat storage textile. In one embodiment the textile is prepared by applying a coating containing carbon nanotubes to a side of a textile. The coating solution comprises, by weight, at least 0.1% carbon nanotubes, 0.01% dispersant, 9.89% resin binder, and 10 solvent. The carbon nanotube surface may be modified to improve the adhesive properties. The carbon nanotubes can be single wall nanotubes, multi-wall carbon nanotubes such as a double wall nanotube (DWNT), or thin multi-wall nanotubes. The coating may cure while transferring the coated heat storage textile with a constant velocity at a room temperature or in a heated chamber.

Abstract translation: 储热纺织品。 在一个实施方案中，通过将包含碳纳米管的涂层施加到纺织品的侧面来制备纺织品。 该涂层溶液包含至少0.1％的碳纳米管，0.01％的分散剂，9.89％的树脂粘合剂和10种溶剂。 可以改变碳纳米管表面以改善粘合性能。 碳纳米管可以是单壁纳米管，双壁碳纳米管（DWNT）等多壁碳纳米管，或者是多壁纳米管。 在室温下或加热室中以等速转移涂覆的储热织物时，涂层可以固化。

公开(公告)号：US20140141255A1

公开(公告)日：2014-05-22

申请号：US14164867

申请日：2014-01-27

Applicant: TOPPAN PRINTING CO., LTD.

Inventor： Mitsuru KANO ,  JIN SATO ,  TOSHIAKI YOSHIHARA ,  MASATO KON

IPC: C23C16/40 ,  C23C16/02

CPC classification number: C23C16/403 ,  B05D3/007 ,  B05D3/107 ,  B05D3/141 ,  B05D3/145 ,  B05D3/148 ,  B32B7/04 ,  C08K3/01 ,  C08K3/013 ,  C09J201/02 ,  C09J201/025 ,  C09J201/06 ,  C09J201/08 ,  C09J2400/10 ,  C09J2400/22 ,  C23C16/02 ,  C23C16/0227 ,  C23C16/0245 ,  C23C16/0272 ,  C23C16/04 ,  C23C16/405 ,  C23C16/44 ,  C23C16/455 ,  C23C16/45525 ,  C23C16/45555 ,  C23C28/00 ,  C23C28/042 ,  Y10T428/25 ,  Y10T428/251 ,  Y10T428/258 ,  Y10T428/259 ,  Y10T428/31562 ,  Y10T428/31721 ,  Y10T428/31757

Abstract: A laminate body includes a base material, a film-like or a membrane-like undercoat layer that is formed in at least a portion of the outer surface of the base material, and an atomic layer deposition film that is formed on a surface opposite to a surface coming into contact with the base material among both surfaces of the undercoat layer in the thickness direction thereof. At least a portion of precursors of the atomic layer deposition film bind to the undercoat layer, and the atomic layer deposition film is formed into a membrane shape covering the undercoat layer.

Abstract translation: 层压体包括形成在基材的外表面的至少一部分中的基材，膜状或膜状底涂层，以及形成在与基材的相反侧的表面上的原子层沉积膜 在底涂层的厚度方向的两面中与基材接触的表面。 原子层沉积膜的前体的至少一部分与底涂层结合，原子层沉积膜形成为覆盖底涂层的膜状。

公开(公告)号：US20140106151A1

公开(公告)日：2014-04-17

申请号：US14125166

申请日：2012-06-13

Applicant: KONICA MINOLTA , INC.

Inventor： Takahiro Mori

IPC: H01L31/0203 ,  H01L51/52

CPC classification number: H01L31/0203 ,  B05D3/067 ,  B05D3/145 ,  B05D7/04 ,  B05D7/546 ,  B05D7/586 ,  B05D2252/10 ,  B32B27/08 ,  B32B27/16 ,  B32B27/281 ,  B32B27/283 ,  B32B27/285 ,  B32B27/286 ,  B32B27/302 ,  B32B27/304 ,  B32B27/32 ,  B32B27/34 ,  B32B27/36 ,  B32B27/365 ,  B32B2307/306 ,  B32B2307/412 ,  B32B2307/7242 ,  B32B2457/00 ,  C23C16/0272 ,  C23C16/308 ,  C23C16/345 ,  C23C18/14 ,  H01L31/049 ,  H01L51/5253 ,  H01L2251/558 ,  Y02E10/50 ,  Y10T428/24975

Abstract: Provided are a gas barrier film which has extremely excellent gas barrier performance and high durability, a manufacturing method thereof, and an electronic device using the same. The gas barrier film having at least two gas barrier layers which contain at least Si, O and N and are laminated on a substrate, in which the total thicknesswise composition distribution of the gas barrier layers includes both a thicknesswise continuous region which has a thickness of 20 nm or more and satisfies the following composition range (A) and a thicknesswise continuous region which has a thickness of 50 nm or more and satisfies the following composition range (B) in this order from the substrate side. (A): when the composition of the gas barrier layer is represented by SiOwNx, w≧0.8, x≧0.3, and 2w+3x≦4, and (B): when the composition of the gas barrier layer is represented by SiOyNz, 0

Abstract translation: 本发明提供阻气性优异，耐久性高的阻气膜及其制造方法以及使用该阻气膜的电子装置。 所述阻气膜具有至少两个至少含有Si，O和N并且层压在基板上的气体阻隔层，其中阻气层的总厚度组成分布包括厚度方向连续区域 20nm以上，满足以下组成范围（A）和厚度为50nm以上的厚度连续区域，从基板侧依次满足以下组成范围（B）。 （A）：当阻气层的组成由SiO wNx，w≥0.8，x≥0.3，以及2w + 3x＆nlE; 4和（B）表示时：当阻气层的组成由SiO y N z表示时， 0

公开(公告)号：US08628829B2

公开(公告)日：2014-01-14

申请号：US12893936

申请日：2010-09-29

Applicant: Hiroki Uchiyama

Inventor： Hiroki Uchiyama

IPC: B05D1/32

CPC classification number: B41J2/161 ,  B05D1/62 ,  B05D3/104 ,  B05D3/142 ,  B05D3/145 ,  B41J2/1606 ,  B41J2/1626 ,  B41J2/1631 ,  B41J2/1642 ,  B41J2/1646 ,  B41J2002/14459 ,  B41J2202/20

Abstract: The method of forming an organic film, includes: a pre-processing step including a plasma treatment step of carrying out plasma treatment to a surface of a base member, and an exposure processing step of exposing the surface of the base member that has undergone the plasma treatment, in an atmosphere containing at least water; and an organic film formation step of thereafter forming an organic film on the surface of the base member using a silane coupling agent.

Abstract translation: 形成有机膜的方法包括：预处理步骤，包括对基材的表面进行等离子体处理的等离子体处理步骤;以及曝光处理步骤，使已经经历过的 在至少含水的气氛中进行等离子体处理; 以及有机膜形成工序，然后使用硅烷偶联剂在基材的表面上形成有机膜。

公开(公告)号：US08541065B2

公开(公告)日：2013-09-24

申请号：US12602331

申请日：2008-05-31

Applicant: Gerold Lukowski ,  Karsten Schroeder ,  Wolf-Dieter Juelich ,  Ruediger Foest ,  Klaus-Dieter Weltmann ,  Joerg Ehlbeck

Inventor： Gerold Lukowski ,  Karsten Schroeder ,  Wolf-Dieter Juelich ,  Ruediger Foest ,  Klaus-Dieter Weltmann ,  Joerg Ehlbeck

IPC: H05H1/00 ,  B05D3/00 ,  B05D1/12

CPC classification number: B05D3/141 ,  A61K9/5123 ,  A61L2/14 ,  A61L27/34 ,  A61L27/50 ,  A61L27/54 ,  A61L2300/22 ,  A61L2300/404 ,  A61L2300/602 ,  A61L2300/606 ,  A61L2400/12 ,  B05D3/142 ,  B05D3/145 ,  B05D7/02 ,  B05D2201/00 ,  B05D2401/32 ,  Y10T428/25

Abstract: The invention relates to a method for coating surfaces with micro- and nanoparticles, the micro- and nanoparticles being chemically bonded to the surface, comprising the steps of pre-treatment of the surface with a plasma method, simultaneous or subsequent application of the micro- and nanoparticles to the surface, and subsequent fixation of the micro and nanoparticles on the surface using a plasma method, characterized in that the fixation of the micro- and nanoparticles takes place with the aid of anisothermal plasmas, the median electrical energy of which lies in the range of the bond dissociation energy of the micro- and nanoparticles, thus allowing the strength of the chemical bond between the surface and the micro- and nanoparticles to be variably set.

Abstract translation: 本发明涉及一种用微孔和纳米颗粒涂覆表面的方法，微米和纳米颗粒化学键合到表面，包括以等离子体方法预处理表面的步骤， 和纳米颗粒到表面，以及随后使用等离子体方法将微粒和纳米颗粒固定在表面上，其特征在于，借助于等温等离子体，其中的中等电能位于 微米和纳米颗粒的键解离能的范围，从而允许表面和微米级和纳米颗粒之间的化学键的强度可变地设定。

公开(公告)号：US08124207B2

公开(公告)日：2012-02-28

申请号：US12195222

申请日：2008-08-20

Applicant: Vinay G. Sakhrani ,  Charles Tomasino

Inventor： Vinay G. Sakhrani ,  Charles Tomasino

IPC: A61M5/178 ,  B32B1/08 ,  B32B15/04 ,  B32B33/00

CPC classification number: B05D5/08 ,  A61M2005/3131 ,  B05D3/0254 ,  B05D3/068 ,  B05D3/144 ,  B05D3/145 ,  B05D5/083 ,  B05D7/02 ,  B05D7/22 ,  B05D2203/35 ,  C08J7/047 ,  C08J7/18 ,  C10M107/38 ,  C10M107/50 ,  C10M177/00 ,  C10M2213/023 ,  C10M2213/0606 ,  C10M2229/0415 ,  C10N2230/06 ,  C10N2240/66 ,  C10N2250/18 ,  C10N2270/00 ,  C10N2280/00 ,  F16N15/00 ,  Y10T428/1393 ,  Y10T428/31544 ,  Y10T428/31663 ,  Y10T428/31678

Abstract: Articles having reduced sliding frictional force comprising a lubricant applied to one or more surfaces of the article, and the lubricant-coated surface treated by exposing the surface to an energy source, wherein the energy source is an ionizing gas plasma at about atmospheric pressure. The ionizing gas plasma may be a flame plasma. One or more of the surfaces may be exposed to the ionizing gas plasma at about atmospheric pressure prior to application of the lubricant.

Abstract translation: 具有降低的滑动摩擦力的制品包括施加到制品的一个或多个表面上的润滑剂，以及通过将表面暴露于能量来处理的润滑剂涂覆的表面，其中能量源是在大气压下的电离气体等离子体。 电离气体等离子体可以是火焰等离子体。 在施加润滑剂之前，一个或多个表面可能在大气压下暴露于电离气体等离子体。

公开(公告)号：US20110159273A1

公开(公告)日：2011-06-30

申请号：US12602331

申请日：2008-05-31

Applicant: Gerold Lukowski ,  Karsten Schroeder ,  Wolf-Dieter Juelich ,  Ruediger Foest ,  Klaus-Dieter Weltmann ,  Joerg Ehlbeck

Inventor： Gerold Lukowski ,  Karsten Schroeder ,  Wolf-Dieter Juelich ,  Ruediger Foest ,  Klaus-Dieter Weltmann ,  Joerg Ehlbeck

IPC: B32B5/16 ,  B05D3/10 ,  B05D1/12 ,  B05D1/18 ,  B05D1/00 ,  B05D5/00 ,  B82Y40/00 ,  B82Y5/00 ,  B82Y99/00

CPC classification number: B05D3/141 ,  A61K9/5123 ,  A61L2/14 ,  A61L27/34 ,  A61L27/50 ,  A61L27/54 ,  A61L2300/22 ,  A61L2300/404 ,  A61L2300/602 ,  A61L2300/606 ,  A61L2400/12 ,  B05D3/142 ,  B05D3/145 ,  B05D7/02 ,  B05D2201/00 ,  B05D2401/32 ,  Y10T428/25

Abstract: The invention relates to a method for coating surfaces with micro- and nanoparticles, the micro- and nanoparticles being chemically bonded to the surface, comprising the steps of pre-treatment of the surface with a plasma method, simultaneous or subsequent application of the micro- and nanoparticles to the surface, and subsequent fixation of the micro and nanoparticles on the surface using a plasma method, characterized in that the fixation of the micro- and nanoparticles takes place with the aid of anisothermal plasmas, the median electrical energy of which lies in the range of the bond dissociation energy of the micro- and nanoparticles, thus allowing the strength of the chemical bond between the surface and the micro- and nanoparticles to be variably set.

Abstract translation: 本发明涉及一种用微孔和纳米颗粒涂覆表面的方法，微米和纳米颗粒化学键合到表面，包括以等离子体方法预处理表面的步骤， 和纳米颗粒到表面，以及随后使用等离子体方法将微粒和纳米颗粒固定在表面上，其特征在于，借助于等温等离子体，其中的中等电能位于 微米和纳米颗粒的键解离能的范围，从而允许表面和微米级和纳米颗粒之间的化学键的强度可变地设定。

公开(公告)号：US07935565B2

公开(公告)日：2011-05-03

申请号：US10538857

申请日：2003-12-12

Applicant: Thomas Meredith Brown ,  Henning Sirringhaus ,  John Devin Mackenzie

Inventor： Thomas Meredith Brown ,  Henning Sirringhaus ,  John Devin Mackenzie

IPC: H01L51/40

CPC classification number: B05D5/12 ,  B05D1/322 ,  B05D3/145 ,  B82Y10/00 ,  B82Y30/00 ,  H01L51/0016 ,  H01L51/0017 ,  H01L51/0021 ,  H01L51/0022 ,  H01L51/0023 ,  H01L51/0036 ,  H01L51/0037 ,  H01L51/0039 ,  H01L51/0043 ,  H01L51/052 ,  H01L51/0525 ,  H01L51/0541 ,  H01L51/0545 ,  H01L51/057 ,  H01L51/105 ,  H01L2251/105 ,  Y10S977/887

Abstract: A method for forming an electronic device having a multilayer structure, comprising: embossing a surface of a substrate so as to depress first and second regions of the substrate relative to at least a third region of the substrate; depositing conductive or semiconductive material from solution onto the first and second regions of the substrate so as to form a first electrode on the first region and a second electrode on the second region, wherein the electrodes are electrically insulated from each other by the third region.

Abstract translation: 一种形成具有多层结构的电子器件的方法，包括：对衬底的表面进行压花，以相对于衬底的至少第三区域压下衬底的第一和第二区域; 将溶液中的导电或半导体材料沉积到衬底的第一和第二区域上，以在第一区域上形成第一电极，在第二区域上形成第二电极，其中电极通过第三区域彼此电绝缘。

公开(公告)号：US07776396B2

公开(公告)日：2010-08-17

申请号：US11112664

申请日：2005-04-21

Applicant: Boris Kobrin ,  Jeffrey D. Chinn ,  Romuald Nowak ,  Richard C. Yi

Inventor： Boris Kobrin ,  Jeffrey D. Chinn ,  Romuald Nowak ,  Richard C. Yi

IPC: C23C16/40

CPC classification number: C23C16/0227 ,  B05D1/185 ,  B05D1/60 ,  B05D3/142 ,  B05D3/145 ,  B05D7/52 ,  B05D7/56 ,  B82Y30/00 ,  B82Y40/00 ,  C03C17/42 ,  C03C23/006 ,  C23C16/0245 ,  C23C16/0272 ,  C23C16/401 ,  C23C16/402 ,  C23C16/448 ,  C23C16/4485 ,  C23C16/455 ,  C23C16/45557 ,  C23C16/56 ,  Y10T428/12618 ,  Y10T428/12632 ,  Y10T428/24 ,  Y10T428/24355 ,  Y10T428/24967 ,  Y10T428/24975 ,  Y10T428/261 ,  Y10T428/265 ,  Y10T428/31663 ,  Y10T428/31667

Abstract: An improved vapor-phase deposition method and apparatus for the application of multilayered films/coatings on substrates is described. The method is used to deposit multilayered coatings where the thickness of an oxide-based layer in direct contact with a substrate is controlled as a function of the chemical composition of the substrate, whereby a subsequently deposited layer bonds better to the oxide-based layer. The improved method is used to deposit multilayered coatings where an oxide-based layer is deposited directly over a substrate and an organic-based layer is directly deposited over the oxide-based layer. Typically, a series of alternating layers of oxide-based layer and organic-based layer are applied.

公开(公告)号：US07431989B2

公开(公告)日：2008-10-07

申请号：US10791542

申请日：2004-03-02

Applicant: Vinay G. Sakhrani ,  Joel L. Williams ,  Charles Tomasino ,  Paul M. Vernon, Jr.

Inventor： Vinay G. Sakhrani ,  Joel L. Williams ,  Charles Tomasino ,  Paul M. Vernon, Jr.

IPC: A61M5/178 ,  B32B17/06 ,  B32B27/16 ,  B32B27/32 ,  B32B33/00

CPC classification number: C08J7/047 ,  A61M2005/3131 ,  A61M2205/0222 ,  A61M2205/0238 ,  B05D3/144 ,  B05D3/145 ,  B05D5/08 ,  B05D5/083 ,  B05D7/02 ,  B05D7/22 ,  B29C59/14 ,  B29C59/142 ,  B29C59/16 ,  B29C59/165 ,  B29C2035/085 ,  B29C2035/0877 ,  B29C2059/145 ,  B29L2009/005 ,  B29L2031/7544 ,  C08J7/18 ,  C10M107/38 ,  C10M107/50 ,  C10M2213/043 ,  C10M2213/0606 ,  C10M2229/0415 ,  C10N2250/00 ,  C10N2270/00 ,  F16N15/00 ,  Y10T428/1393 ,  Y10T428/31504 ,  Y10T428/31544 ,  Y10T428/31612 ,  Y10T428/31663 ,  Y10T428/31667 ,  Y10T428/31938

Abstract: A method for preparing one or more lubricated surfaces of an article to reduce the break-out force and sliding frictional force. A lubricant is applied to one or more surfaces, and the lubricant-coated surface is treated by exposing the surface to an energy source, wherein the energy source is an ionizing gas plasma at about atmospheric pressure, gamma radiation, or electron beam radiation. One or more of the surfaces may be exposed to the ionizing gas plasma at about atmospheric pressure prior to application of the lubricant. Another aspect of the invention is articles produced using one or more methods of the invention.

Abstract translation: 一种用于制备物品的一个或多个润滑表面以减少断裂力和滑动摩擦力的方法。 将润滑剂施加到一个或多个表面，并且通过将表面暴露于能量源来处理润滑剂涂覆的表面，其中能量源是在大气压，伽马辐射或电子束辐射下的电离气体等离子体。 在施加润滑剂之前，一个或多个表面可能在大气压下暴露于电离气体等离子体。 本发明的另一方面是使用本发明的一种或多种方法制备的制品。