| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 141 | SILICONE RESIN, RESIN COMPOSITION, RESIN FILM, SEMICONDUCTOR DEVICE, AND MAKING METHOD | US14918080 | 2015-10-20 | US20160122586A1 | 2016-05-05 | Kazunori KONDO; Yoichiro ICHIOKA; Hideto KATO |
| A silicone resin comprising constitutional units represented by formula (1) and having a Mw of 3,000-500,000 contains 10-50 wt % of (A-1) a first silicone resin having a silicone content of 10-40 wt % and (A-2) a second silicone resin having a silicone content of 50-80 wt %. A resin composition comprising the silicone resin can be formed in film form, and it possesses satisfactory covering or encapsulating performance to large size/thin wafers. The resin composition or resin film ensures satisfactory adhesion, low warpage, and wafer protection. The resin film is useful in wafer-level packages. | ||||||
| 142 | FUNCTIONAL SINGLE-LAYER FILM AND DISPLAY DEVICE HAVING THE SAME | US14856170 | 2015-09-16 | US20160117004A1 | 2016-04-28 | DongChin LEE; Chul-Hong KIM; Sunghee CHO; Keunyoung KIM; Yongbin JEONG; Kelly Sooyeun SONG |
| Disclosed are a functional single-layer film and a display device including the same. The functional single-layer film is positioned on a cover window of the display device. The functional single-layer film includes a matrix material and carbon-containing flakes contained in the matrix material. The content of the carbon-containing flakes ranges from 0.01% to 0.1% by weight. | ||||||
| 143 | COMPOSITE SHEET, METHOD FOR MANUFACTURING SAME, AND DISPLAY DEVICE INCLUDING SAME | US14893921 | 2014-05-09 | US20160114555A1 | 2016-04-28 | Eun Hwan JEONG; Woo Jin LEE; Sung Kook KIM; Jae Cheol CHO |
| Provided are: a composite sheet comprising a silicone matrix and a first sheet including a reinforcement material impregnated into the silicone matrix, wherein the first sheet has a compression elongation of about 30% or more; a method for manufacturing the same; and a display device including the same. | ||||||
| 144 | Pad of labels and labels for use on store shelves in a retail environment | US14081703 | 2013-11-15 | US09259891B2 | 2016-02-16 | Jeffrey Weidauer; Michael Wilkinson; Jeffrey Blackwell; Gene Bethards; Scott Aten; David Adler |
| A pad of labels and labels for use on store shelves in a retail environment. The pad of labels include labels with adhesive strips applied to a bottom surface of each label and a top laminate layer with a release coating applied to the top surface of each label. The labels in the pad are sequenced according to a store's planogram. | ||||||
| 145 | Integrated molded product | US13823711 | 2011-08-17 | US09249296B2 | 2016-02-02 | Kouichi Sakata |
| To provide a technique in which a phosphorus compound does not inhibit curing of an addition reaction type silicone-based composition even though the addition reaction type silicone-based composition is in contact with a resin molded product containing the phosphorus compound. An integrated molded product including a thermoplastic resin molded product containing a phosphorus compound, an addition reaction type silicone-based composition, and a member, in which: the thermoplastic resin molded product is in contact with the addition reaction type silicone-based composition; and a pentavalent phosphorus compound is used as the phosphorus compound. The thermoplastic resin molded product preferably contains a polybutylene terephthalate resin in light of heat resistance. | ||||||
| 146 | Blanket materials for indirect printing methods | US13903517 | 2013-05-28 | US09200120B2 | 2015-12-01 | Brynn Mary Dooley; Carolyn P. Moorlag; Anthony James Wigglesworth; Adrien Pierre Cote; Yu Qi; Barkev Keoshkerian |
| An intermediate transfer member containing a layer of a siloxyfluorocarbon networked polymer. A method of preparing an intermediate transfer member including mixing a coating solution containing siloxyfluorocarbon precursor materials; applying the coating solution as a sol on a substrate; curing the coating solution on the substrate to form an intermediate transfer member containing a layer of a siloxyfluorocarbon networked polymer. The surface free energy of the intermediate transfer member may be from about 10 mN/m to about 40 mN/m. A method of printing an image to a substrate includes applying an inkjet ink to an intermediate transfer member containing a layer of a siloxyflurocarbon networked polymer; spreading the ink onto the intermediate transfer member; inducing a property change of the ink; and transferring the ink to a substrate. | ||||||
| 147 | Microfluidic chips with optically transparent glue coating and a method of manufacturing microfluidic chips with optically transparent glue coating for a microfluidic device | US14028320 | 2013-09-16 | US09180652B2 | 2015-11-10 | Tej Patel; Ryan Revilla; Matthew D'Ooge |
| A microfluidic chip for a microfluidic system includes a PDMS substrate having a first thickness, at least one microfluidic pathway in the substrate, a coating along the microfluidic pathway, and a glass layer having a second thickness on the substrate and above the microfluidic pathway, wherein the coating contains an optically transparent material, and the first thickness is greater than the second thickness. The coating includes cyanoacrylates, an UV curable epoxy adhesive, a gel epoxy or epoxy under trade name of EPO-TEK OG175, MasterBond EP30LV-1 or Locite 0151. | ||||||
| 148 | Method for transferring nanostructures | US14251768 | 2014-04-14 | US09168725B2 | 2015-10-27 | Yu-Jun He; Dong-Qi Li; Tian-Yi Li; Yang Wei; Kai-Li Jiang; Shou-Shan Fan |
| A method for transferring nanostructures includes providing a growth substrate and a number of nanostructures located on the growth substrate. The nanostructures are transferred by an adhesive layer from the growth substrate to a target substrate. The nanostructures are between the target substrate and the adhesive layer, and at least partial of nanostructures is in contact with a surface of the target substrate. The adhesive layer is covered by a metal layer. The adhesive layer together with the metal layer is separated from the plurality of nanostructures and the target substrate in an organic solvent, wherein the organic solvent permeates into an interface between the adhesive layer and the nanostructures. | ||||||
| 149 | ANTI-REFLECTIVE FILM, COMPRISING HARD COATING LAYER, HAVING SUPERB OPTICAL CHARACTERISTICS | US14443645 | 2013-10-14 | US20150301231A1 | 2015-10-22 | Ji-Yeon YANG; Hong-Kwan CHO; Jin-Ki HONG; Won-Kook KIM |
| Provided is an anti-reflective film having a stacked structure comprising a transparent substrate, a hard coating layer, a high refraction layer and a low refraction layer, and more specifically, the low refraction layer may comprise, as a binder, a siloxane compound synthesized by reacting alkoxysilane and organosilane having a fluoroalkyl group. | ||||||
| 150 | MicroAdhesive Systems and Methods of Making and Using the Same | US14525022 | 2014-10-27 | US20150284613A1 | 2015-10-08 | Brian MAYERS; Sandip Agarwal; Jeffrey Carbeck; David Ledoux; Kevin Randall Stewart; George M. Whitesides; Adam Winkleman |
| The present invention is directed to adhesive systems and methods of making and using such systems. Exemplary adhesive systems comprise protrusions and/or grooves that can interleave to form a reversible adhesive interaction. | ||||||
| 151 | METHOD AND SYSTEM FOR MANUFACTURING INTEGRATED FLUIDIC CHIPS | US13813625 | 2009-07-23 | US20150273735A1 | 2015-10-01 | David S. Cohen |
| An integrated fluidic chip includes a substrate defined by a lateral surface area greater than 28 square inches. The integrated fluidic chip also includes a first elastomeric layer having a mold surface and a top surface. The mold surface of the first elastomeric layer is joined to a portion of the substrate. The first elastomeric layer includes a plurality of first channels extending normally from the substrate to a first dimension inside the first elastomeric layer. The integrated fluidic chip further includes a second elastomeric layer having a mold surface and a top surface. The mold surface of the second elastomeric layer is joined to at least a portion of the top surface of the first elastomeric layer. | ||||||
| 152 | Preventing conductive anodic filament (CAF) formation by sealing discontinuities in glass fiber bundles | US13221268 | 2011-08-30 | US08974888B2 | 2015-03-10 | Gregory E. Balcome; Brett P. Krull; Joseph Kuczynski; Terry G. Ryks; Timothy J. Tofil |
| An enhanced substrate for making a printed circuit board (PCB) includes a silane applied to the ends of glass fibers in via holes. In one embodiment, during a plated through-hole (PTH) via fabrication process, glass fiber bundles exposed in a drilled through-hole are selectively sealed. For example, after the through-hole is drilled in a substrate, the substrate may be subjected to an aqueous silane bath (e.g., an organo trialkoxysilane in an aqueous solution of an acid that acts as a catalyst) to deposit a layer of silane on the exposed glass fiber bundle ends. For example, trialkoxy groups of the silane may react with exposed silanols on the glass to form a siloxane, which is further polymerized to form a silane polymer barrier layer on the exposed glass fiber ends. The barrier layer effectively seals the glass fiber bundles and eliminates the conductive anodic filament (CAF) pathway between PTH vias. | ||||||
| 153 | LIGHT-WEIGHT, HIGH STIFFNESS GLASS LAMINATE STRUCTURE | US14471830 | 2014-08-28 | US20150064374A1 | 2015-03-05 | Anurag Jain; Michael M. Laurin; Christianus Johannes Jacobus Maas; Michael John Moore; Charlie W. Wood |
| A laminate structure having a first chemically strengthened glass layer, a second chemically strengthened glass layer, and a polymer interlayer structure intermediate the first and second glass layers. The polymer interlayer structure can include a first polymeric layer adjacent to the first glass layer, a second polymeric layer adjacent to the second glass layer, and a polymeric rigid core intermediate the first and second polymeric layers. | ||||||
| 154 | Method Of Making A Pad Of Labels And Labels For Use On Store Shelves In A Retail Environment | US14084733 | 2013-11-20 | US20140367017A1 | 2014-12-18 | JEFFREY BLACKWELL; GENE BETHARDS; SCOTT ATEN |
| A method of making a pad of labels and labels for use on store shelves in a retail environment. The pad of labels include labels with adhesive strips applied to a bottom surface of each label and a top laminate layer with a release coating applied to the top surface of each label. The labels in the pad are sequenced according to a store's planogram. | ||||||
| 155 | STRUCTURAL GLAZING SPACER | US14455643 | 2014-08-08 | US20140345782A1 | 2014-11-27 | Thomas A. Veilleux; James N. Gordon; Stewart B. Dittmeier |
| A method of preparing a window module includes providing a metal frame having a first major surface, applying a structural glazing tape to the first major surface of the metal frame, and positioning a glass panel overtop the structural glazing tape. The structural glazing tape includes a polymer foam tape having first and second major surfaces, an adhesive layer overlying the first major surface for bonding the structural glazing tape to the structural frame, and a release layer overlying the second major surface. The method further includes filling a channel defined by the glass panel, the metal frame, and the structural glazing tape with a curable sealant, and curing the sealant to bond the glass panel and the metal frame together. | ||||||
| 156 | INTEGRATED MOLDED PRODUCT | US13823711 | 2011-08-17 | US20130274390A1 | 2013-10-17 | Kouichi Sakata |
| To provide a technique in which a phosphorus compound does not inhibit curing of an addition reaction type silicone-based composition even though the addition reaction type silicone-based composition is in contact with a resin molded product containing the phosphorus compound. An integrated molded product including a thermoplastic resin molded product containing a phosphorus compound, an addition reaction type silicone-based composition, and a member, in which: the thermoplastic resin molded product is in contact with the addition reaction type silicone-based composition; and a pentavalent phosphorus compound is used as the phosphorus compound. The thermoplastic resin molded product preferably contains a polybutylene terephthalate resin in light of heat resistance. | ||||||
| 157 | FLUORINE-BASED SURFACE TREATING AGENT FOR VAPOR DEPOSITION AND ARTICLE FINISHED WITH THE SURFACE TREATING AGENT BY VAPOR DEPOSITION | US13684289 | 2012-11-23 | US20130136928A1 | 2013-05-30 | Yuji Yamane; Noriyuki Koike |
| There is disclosed a fluorine-based surface treating agent for vapor deposition comprising (A) a hydrolyzable group-containing silane modified with a polymer containing a fluorooxyalkylene group and/or a partial hydrolytic condensate, and (B) a polymer containing a fluorooxyalkylene group having a higher weight average molecular weight than component (A), wherein components (A) and (B) are mixed in a weight ratio of from 6:4 to 9:1. | ||||||
| 158 | Structural Glazing Spacer | US13337048 | 2011-12-23 | US20120159880A1 | 2012-06-28 | Thomas A. Veilleux; James N. Gordon; Stewart B. Dittmeier |
| A method of preparing a window module includes providing a metal frame having a first major surface, applying a structural glazing tape to the first major surface of the metal frame, and positioning a glass panel overtop the structural glazing tape. The structural glazing tape includes a polymer foam tape having first and second major surfaces, an adhesive layer overlying the first major surface for bonding the structural glazing tape to the structural frame, and a release layer overlying the second major surface. The method further includes filling a channel defined by the glass panel, the metal frame, and the structural glazing tape with a curable sealant, and curing the sealant to bond the glass panel and the metal frame together. | ||||||
| 159 | METHOD OF INCREASING THE SCRATCH HARDNESS OF A BODY | US13380549 | 2010-06-23 | US20120100771A1 | 2012-04-26 | Johann Kappacher; Manfred Oberkofler; Christian Loos; Marco Grugger |
| A method for increasing the scratch hardness of a body, which has at least in some regions a surface (4a) consisting of an extrudated or co-extrudated plastic (4), wherein an organic, fluoro-organic or silico-organic compound (18) that increases the scratch hardness is applied to the surface (4a) of the extrudated or co-extrudated plastic (4), wherein the organic, fluoro-organic or silico-organic compound (11a, 18) is applied to the surface (4a) of the extrudated or co-extrudated plastic (4) by means of a sheet-like transfer medium (6, 11), on which the organic, fluoro-organic or silico-organic compound (11a, 18) is disposed. | ||||||
| 160 | MICROADHESIVE SYSTEMS AND METHODS OF MAKING AND USING THE SAME | US13014182 | 2011-01-26 | US20110171430A1 | 2011-07-14 | Brian MAYERS; Sandip Agarwal; Jeffrey Carbeck; David Ledoux; Kevin Randall Stewart; George M. Whitesides; Adam Winkleman |
| The present invention is directed to adhesive systems and methods of making and using such systems. Exemplary adhesive systems comprise protrusions and/or grooves that can interleave to form a reversible adhesive interaction. | ||||||
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