| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 181 | Dielectric materials, methods of forming subassemblies therefrom, and the subassemblies formed therewith | US12813556 | 2010-08-23 | US08632874B2 | 2014-01-21 | Sankar Paul; Scott D. Kennedy; Dirk M. Baars |
| A circuit subassembly, comprising a dielectric layer formed from a dielectric composition comprising, based on the total volume of the composition: about 15 to about 65 volume percent of a dielectric filler; and about 35 to about 85 volume percent of a thermosetting composition comprising: a poly(arylene ether), and a carboxy-functionalized polybutadiene or polyisoprene polymer. | ||||||
| 182 | Process For Joining Carbide And Non Carbide Materials And The Method Thereof | US13889831 | 2013-05-08 | US20130337283A1 | 2013-12-19 | Raghavan Rengarajan; Ramesh S. Rao; Jagannath Vaishali; Kuttan P. Pramodh; Bhaskar Alok; Gopalrao Rao Shivaram; Shenoy K. Chandrashekar |
| In one embodiment, a process for joining carbide and non-carbide materials is disclosed, the process comprising providing an interface binder material, positioning the interface binder material between the carbide material and non-carbide material to provide an assembly and heating the assembly to join the carbide material and non-carbide material through the interface binder material, wherein the interface binder material comprises a powder metal or powder alloy or a sheet of metal or alloy. | ||||||
| 183 | Biocompatible substrates and uses thereof | US11784332 | 2007-04-05 | US08470453B2 | 2013-06-25 | Mattias Ohrlander; Billy Sodervall |
| A new substrate makes it possible to modify surface properties relating to biocompatibility. Said substrate has an electron donating surface, characterized in having metal particles on said surface, said metal particles comprising palladium and at least one metal chosen from gold, ruthenium, rhodium, osmium, iridium, and platinum, wherein the amount of said metal particles is from about 0.001 to about 8 μg/cm2. The substrate is suggested for different uses, such as for modifying the hydrophobicity, protein adsorption; tissue ingrowth, complement activation, inflammatory response, thrombogenicity, friction coefficient, and surface hardness. | ||||||
| 184 | Suction sheet | US13121328 | 2009-09-25 | US08414999B2 | 2013-04-09 | Toshimitsu Tachibana |
| A suction sheet (1) to be attached onto a suction surface (4a) of a suction apparatus (4) that holds an object by vacuum suction is provided with a substrate (2) and a porous body (3). The substrate (2) has one surface (2a) and the other surface (2b), and the one surface (2a) is brought into contact with the suction surface (4a). Further, a plurality of through holes (21) are provided in the substrate (2). The porous body (3) has a thickness of 1.4 mm or less, and is adhered onto the other surface (2b) of the substrate (2) so as to cover the through holes (21). | ||||||
| 185 | Antimicrobial substrates and uses thereof | US13155334 | 2011-06-07 | US08394494B2 | 2013-03-12 | Mattias Ohrlander; Billy Sodervall |
| A new substrate makes it possible to modify surface properties relating to antimicrobial properties. Said substrate has an electron donating surface, characterized in having metal particles on said surface, said metal particles comprising palladium and at least one metal chosen from gold, ruthenium, rhodium, osmium, iridium, and platinum, wherein the amount of said metal particles is from about 0.001 to about 8 μg/cm2. The substrate is suggested for different uses, such as for modifying the hydrophobicity, protein adsorption, adhesion of bacteria, as well as preventing bacterial transmission and in particular preventing nosocomial infections. | ||||||
| 186 | Metal-coated polymer article of high durability and vacuum and/or pressure integrity | US13529308 | 2012-06-21 | US08394473B2 | 2013-03-12 | Jonathan McCrea; Francisco Gonzalez; Gino Palumbo; Klaus Tomantschger; Rich Emrich; Konstantinos Panagiotopoulos; Mary Pasquantonio; John Kratochwil; Herath Katugaha |
| Metal-coated polymer articles containing structural substantially porosity-free, fine-grained and/or amorphous metallic coatings/layers optionally containing solid particulates dispersed therein on polymer substrates, are disclosed. The substantially porosity-free metallic coatings/layers/patches are applied to polymer or polymer composite substrates to provide, enhance or restore vacuum/pressure integrity and fluid sealing functions. Due to the excellent adhesion between the metallic coating and the polymer article satisfactory thermal cycling performance is achieved. The invention can also be employed as a repair/refurbishment technique. The fine-grained and/or amorphous metallic coatings are particularly suited for strong and lightweight articles, precision molds, sporting goods, aerospace and automotive parts and other components exposed to thermal cycling and stress created by erosion and impact damage. | ||||||
| 187 | LOW-FRICTION SURFACE COATINGS AND METHODS FOR PRODUCING SAME | US12833507 | 2010-07-09 | US20120009432A1 | 2012-01-12 | Carl V. Cox; Matthew C. Shaw; Yakov Epshteyn |
| A coated article system includes a substrate and a surface coating on the substrate. The surface coating is formed by depositing individual particles of a composite metal powder with sufficient energy to cause the composite metal powder to bond with the substrate and form the surface coating. The composite metal powder includes a substantially homogeneous dispersion of molybdenum and molybdenum disulfide sub-particles that are fused together to form the individual particles of the composite metal powder. | ||||||
| 188 | METHOD OF FORMING THE STRUCTURE OF THERMAL RESISTIVE LAYER | US13213892 | 2011-08-19 | US20110297550A1 | 2011-12-08 | Jung-Fang Chang; Te-Chi Wong; Chien-Te Hsieh; Chin-Jen Huang; Yu-Hung Chen |
| The prevent disclosure discloses a structure of thermal resistive layer and the method of forming the same. The thermal resistive structures, formed on a plastic substrate, comprises a porous layer, formed on said plastic substrate, including a plurality of oxides of hollow structure, and a buffer layer, formed on said porous layer, wherein said porous layer can protect said plastic substrate from damage caused by the heat generated during manufacturing process. With the structure and method disclosed above, making a thin film transistor and forming electronic devices on the plastic substrate in the technology of Low Temperature PolySilicon, i.e. LTPS, without changing any parameters is possible. | ||||||
| 189 | SUCTION SHEET | US13121328 | 2009-09-25 | US20110183108A1 | 2011-07-28 | Toshimitsu Tachibana |
| A suction sheet (1) to be attached onto a suction surface (4a) of a suction apparatus (4) that holds an object by vacuum suction is provided with a substrate (2) and a porous body (3). The substrate (2) has one surface (2a) and the other surface (2b), and the one surface (2a) is brought into contact with the suction surface (4a). Further, a plurality of through holes (21) are provided in the substrate (2). The porous body (3) has a thickness of 1.4 mm or less, and is adhered onto the other surface (2b) of the substrate (2) so as to cover the through holes (21). | ||||||
| 190 | DIELECTRIC MATERIALS, METHODS OF FORMING SUBASSEMBLIES THEREFROM, AND THE SUBASSEMBLIES FORMED THEREWITH | US12813556 | 2010-08-23 | US20100307803A1 | 2010-12-09 | Sankar Paul; Scott D. Kennedy; Dirk M. Baars |
| A circuit subassembly, comprising a dielectric layer formed from a dielectric composition comprising, based on the total volume of the composition: about 15 to about 65 volume percent of a dielectric filler; and about 35 to about 85 volume percent of a thermosetting composition comprising: a poly(arylene ether), and a carboxy-functionalized polybutadiene or polyisoprene polymer. | ||||||
| 191 | FLUORORESIN THIN FILM, FLUORORESIN COMPOSITE, POROUS FLUORORESIN COMPOSITE, MANUFACTURING METHODS THEREOF, AND SEPERATION MEMBRANE ELEMENT | US12376545 | 2007-08-06 | US20100203310A1 | 2010-08-12 | Fumihiro Hayashi; Itsumu Furumoto; Shinichi Kanazawa; Kazuaki Ikeda; Tooru Morita; Hajime Funatsu |
| There are provided a fluororesin thin film which is composed of a fluororesin, which has a thickness of 20 μm or less and a Gurley's number of 300 seconds or more, and which includes no defects, such as voids and/or cracks; a method for manufacturing the fluororesin thin film in which after a fluororesin dispersion including a dispersing medium and a fluororesin powder dispersed therein is applied on a flat and smooth foil, the dispersing medium is dried, and the fluororesin powder is sintered; the fluororesin dispersion; a fluororesin composite including a porous base material and the fluororesin thin film; a manufacturing method thereof a porous fluororesin composite formed by stretching the fluororesin composite; and a separation membrane element using the porous fluororesin composite. | ||||||
| 192 | METAL-CERAMIC COMPOSITE WITH GOOD ADHESION AND METHOD FOR ITS PRODUCTION | US12519092 | 2007-12-11 | US20100028699A1 | 2010-02-04 | Reinhard Lenk; Tassilo Moritz; Andreas Baumann |
| The invention relates to the field of material sciences and relates to a metal-ceramic composite with good adhesive strength, such as can be used, for example, for forming tools or cutting tools. The object of the present invention lies in the disclosure of a metal-ceramic composite with good adhesive strength which has a strong and durable bond between ceramic and metal. The object is attained with a metal-ceramic composite with good adhesive strength, comprising a metal component and a ceramic component and which are connected to one another by adhesive force or by adhesive force and in a non-positive manner, wherein silicon, beryllium, titanium, chromium, nickel, manganese, hafnium, vanadium, zirconium, aluminum and/or the organic compounds thereof is present in the area of the connection surfaces and wherein the components have been processed as a greenbody to form a composite and jointly sintered. The object is further attained through a method in which at least respectively one metal component and ceramic component are connected as a total greenbody and jointly subjected to a temperature treatment, at least for sintering the ceramic components. | ||||||
| 193 | HUMIDITY-CONDITIONING SHEET | US12517370 | 2007-12-10 | US20100005968A1 | 2010-01-14 | Takahiro Endo; Masaru Shimoyama; Yuko Tsuruta; Yutaka Mori |
| A humidity-conditioning sheet 10 excellent in reversibility and responsiveness of a moisture adsorbing/desorbing ability of rapidly adsorbing moisture at high ambient humidity and conversely rapidly desorbing adsorbed moisture at low ambient humidity includes a sheet-shaped humidity-conditioning layer 7 formed by bonding together, with a thermoplastic resin powder 4, humidity-conditioning particles 3 which reversibly adsorb and desorb water vapor. The void ratio of the humidity-conditioning layer 7 is 5% or more. Since a ratio of voids 8 formed between the humidity-conditioning particles 3 is high, the voids 8 between the humidity-conditioning particles 3 can be used as water retention spaces for moisture adsorption and desorption, thereby achieving the high reversible moisture adsorbing/desorbing ability and excellent moisture adsorption/desorption responsiveness with the aid of not only the moisture adsorbing/desorbing ability inherent in the humidity-conditioning particles but also the moisture adsorbing/desorbing ability of the voids between the humidity-conditioning particles. | ||||||
| 194 | Radiant Panel | US12432408 | 2009-04-29 | US20090314463A1 | 2009-12-24 | Raymond C. Frobosilo; Sam Borgia |
| A radiant panel which can be used for heating or cooling and in floors, walls and ceilings, has a honeycomb layer of vertical metal webs or fins and rigid upper and lower cover boards rigidly adhered to upper and lower surfaces of the honeycomb layer. The upper cover board has router-cut channel there through, the channel having a width and being elongated in the shape of a selected pattern for at least one heat transfer tube that extends along the channel in the selected pattern. The tube is pressed into the honeycomb layer past the upper surface of the honeycomb layer for at least partly crushing the metal webs or fins of honeycomb layer in the areas of the channel for establishing a heat transfer engagement between the tube and the honeycomb layer. Dragon Board Brand construction board is preferred as the cover boards, the honeycomb layer as preferably aluminum and a heat reflecting layer is preferably adhered to the lower surface of the lower cover board. | ||||||
| 195 | METAL MATRIX COMPOSITE MATERIAL | US12428244 | 2009-04-22 | US20090220814A1 | 2009-09-03 | Toshimasa Nishiyama; Takutoshi Kondou; Hideki Ishii; Kazuto Sanada; Toshiaki Yamazaki |
| A metal matrix composite material comprising a pair of metal plates having a powder mixture disposed therebetween forming an intermediate layer is disclosed. The powder mixture includes a metal powder and a ceramic powder. The ceramic powder has a neutron absorbing function and includes a B4C powder. The intermediate layer has a theoretical density ratio at least 98%, and a percentage of a total thickness of the metal plates to an overall thickness of the intermediate layer is in a range of 15 to 25% and the ceramic powder has a neutron absorption rate of at least 90%. | ||||||
| 196 | Flame retardant adhesive composition, and adhesive sheet, coverlay film and flexible copper-clad laminate using same | US11401854 | 2006-04-12 | US07524394B2 | 2009-04-28 | Toru Nakanishi; Kazunori Kondo; Shigehiro Hoshida; Tadashi Amano |
| Provided is a flame retardant adhesive composition including (A) a halogen-free epoxy resin, (B) a thermoplastic resin and/or a synthetic rubber, (C) a curing agent, (D) a nitrogen-containing polyphosphate compound, and (E) a curing accelerator. Also provided are an adhesive sheet having a layer including the above composition, and a protective layer for covering the layer including the composition; a coverlay film having an electrically insulating film, and a layer including the above composition provided on top of the film; a flexible copper-clad laminate having an electrically insulating film, a layer including the above composition provided on top of the film, and copper foil; and a method of bonding two substrates, including the steps of sandwiching the above adhesive sheet between two substrates, and curing the adhesive sheet. Further provided are a process for producing the adhesive sheet, a process for producing the coverlay film, and a process for producing the flexible copper-clad laminate. The halogen-free adhesive composition yields a cured product, on curing, that exhibits excellent flame retardancy and anti-migration properties. The composition can be used for producing an adhesive sheet, a coverlay film, and a flexible copper-clad laminate. The adhesive sheet can be used for a method of bonding two substrates. | ||||||
| 197 | Electrostatically fiber planted steel sheet and production process therefor | US10446379 | 2003-05-29 | US07211298B2 | 2007-05-01 | Teruyuki Tatsumi |
| A fiber planted steel sheet obtained by forming only a fiber planting layer having excellent adhesion to a substrate made from a composition having special composition on the surface of a surface treated steel sheet as a substrate without forming a primer of a polyester synthetic resin containing an anticorrosive pigment and the like and electrostatically planting short fibers in the planting layer. Therefore, the electrostatically fiber planted steel sheet is produced by coating an aqueous adhesive composition for planting fibers comprising an emulsion resin having a glass transition temperature of −40 to 40° C., aqueous coloring pigment dispersion, defoamer and pH modifier on the surface of the surface treated steel sheet to form a fiber planting layer having excellent adhesion to the steel sheet on the surface of the steel sheet and electrostatically planting short fibers while the surface of the planting layer retains adhesion. | ||||||
| 198 | Assembly for protection against an explosion | US10573781 | 2004-09-28 | US20070069847A1 | 2007-03-29 | Erik Lauritzen |
| An assembly for protection against explosion in form of a substantially plate-shaped multi-ply element includes two or outer walls (1,2) and at least one intermediate layer of a ceramic material presenting a density in the range of approximately 0.3 to 1.5 g/cm3, a pore diameter in the range of approximately 20 to 120 μand a physical extent in the range of approximately 0.5 to 10mm. | ||||||
| 199 | Weldable metal composites and methods | US11017411 | 2004-12-20 | US20060134395A1 | 2006-06-22 | David Sigler; Xiaohong Gayden; Yen-Lung Chen |
| The present invention is directed to improved weldable metal composites and methods. A metal composite structure (10) features two metal members (12) (14) sandwiching a viscoelastic layer (26) where the viscoelastic layer entrains electrically conductive particles (28) and a carbon extracting attractant layers (32) (34) to inhibit and/or prevent carbon migration and carbide formation during welding. | ||||||
| 200 | Battery sheath having radiation layer formed thereon and lithium polymer battery using the same | US11253053 | 2005-10-17 | US20060083984A1 | 2006-04-20 | Jeong Oh; Young Sohn |
| A battery sheath having a radiation layer on its surface and a lithium polymer battery using the sheath are provided. The radiation layer improves radiation performance and mechanical strength of the battery, and also improves the response of a PTC device. The battery sheath comprises a metal layer having first and second surfaces, a radiation layer on the first surface of the metal layer, and a cast polypropylene (CPP) layer on the second surface of the metal layer. The lithium polymer battery has a PTC device electrically connected to a protective circuit module. The PTC device directly contacts the radiation layer of the battery sheath, thereby improving the response of the PTC device. | ||||||
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