子分类:
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 101 | Cable | US46233221 | 1921-04-18 | US1760409A | 1930-05-27 | FORREST HOWE JAMES |
| 102 | CONNECTING MATERIAL AND CONNECTION STRUCTURE | US15767804 | 2016-11-18 | US20180297153A1 | 2018-10-18 | Mai YAMAGAMI; Satoshi HANEDA; Takeshi WAKIYA; Yasuyuki YAMADA; Saori UEDA; Masao SASADAIRA |
| A connecting material that can suppress the occurrence of cracking during a stress load in a connection part that connects two members to be connected, further can suppress the variation in thickness in the connection part to ensure the heat dissipation performance, and can increase the connection strength is provided. The connecting material according to the present invention is a connecting material used for forming the connection part that connects two members to be connected, the connecting material contains particles and metal atom-containing particles, the particles are used for forming the connection part such that thickness of the connection part after connection is twice or less the average particle diameter of the particles before connection, or the particles have an average particle diameter of 1 μm or more and 300 μm or less, the particles have a 10% K value of exceeding 3000 N/mm2 and 20000 N/mm2 or less, and the particles have a particle diameter CV value of 10% or less. | ||||||
| 103 | CONDUCTOR ASSEMBLY, ELECTRONIC COMPONENT USING SAME, AND MANUFACTURING METHOD THEREOF | US15564442 | 2016-12-15 | US20180082764A1 | 2018-03-22 | IKUYA WAKAMORI; KENGO NAKAMURA; MUTSUYASU OHTSUBO |
| A conductor assembly includes a first conductor made of metal and a second conductor bonded to the first conductor. The second conductor is made of a metal plate having first and second surfaces opposite to each other. The second conductor has a projection locally projecting from the first surface. A recess is provided in the second surface of the second conductor opposite to the projection. The projection of the second conductor has a portion contacting and entering into the first conductor. The projection of the second conductor is resistance-welded to the first conductor. The portion of the projection of the second conductor has two tips locally projecting from the portion of the projection of the second conductor and entering the first conductor. | ||||||
| 104 | ELECTROCONDUCTIVE FILM AND METHOD FOR PRODUCING SAME | US15552282 | 2015-12-16 | US20180077798A1 | 2018-03-15 | Hidefumi FUJITA; Shuji KANEDA; Daisuke ITOH |
| To provide a copper electroconductive film formed on a paper substrate, the copper electroconductive film being considerably improved in weather resistance and electroconductivity. The problem can be achieved by an electroconductive film formed by pressing a sintered electroconductive film formed by sintering copper particles in a coating film containing copper powder on a paper substrate along with the substrate, the electroconductive film having an area ratio of copper occupying on a cross section of the electroconductive film in parallel to a thickness direction thereof of 82.0% or more. The electroconductive film can be produced by pressing, for example, by roll press to from 90 to 190° C., after light sintering. | ||||||
| 105 | COPPER POWDER AND COPPER PASTE, CONDUCTIVE COATING MATERIAL, AND CONDUCTIVE SHEET USING SAME | US15560750 | 2015-03-26 | US20180051176A1 | 2018-02-22 | Hiroshi Okada; Yu Yamashita |
| Provided is a copper powder that has an increased number of points of contact between copper powder particles, that ensures excellent conductivity, and that can be suitably used in a conductive paste, an electromagnetic wave shield, or the like. The copper powder is configured from flat plate-shaped copper particles that form a dendritic shape having a linearly grown main trunk and a plurality of branches branching from the main trunk. The main trunk and the branches have an average cross-sectional thickness of more than 1.0 μm but no more than 5.0 μm. The copper powder has a flat plate shape that is configured from a layered structure of one layer or a plurality of stacked layers. The average particle size (D50) is 1.0-100 μm. | ||||||
| 106 | COPPER-CONTAINING PARTICLES, CONDUCTOR-FORMING COMPOSITION, METHOD OF PRODUCING CONDUCTIOR, CONDUCTOR, AND APPARATUS | US15552981 | 2016-02-23 | US20180029121A1 | 2018-02-01 | Kohsuke URASHIMA; Motoki YONEKURA; Yasushi KUMASHIRO |
| Copper-containing particles each include: a core particle containing copper; and an organic substance on at least a part of the surface of the core particle, in which a proportion of copper-containing particles having a major-axis length of 50 nm or less is 55% by number or less with respect to the total number of the copper-containing particles. | ||||||
| 107 | METALLIC COPPER PARTICLES, AND PRODUCTION METHOD THEREFOR | US15506574 | 2015-08-26 | US20170252801A1 | 2017-09-07 | Kiyonobu IDA; Mitsuru WATANABE; Masanori TOMONARI |
| Provided are: metallic copper particles exhibiting excellent low-temperature sintering properties at temperatures equal to or lower than 300° C.; and a production method therefor. In these metallic copper particles, metallic copper fine particles are adhered to the surfaces of large-diameter metallic copper particles. With regard to the metallic copper particles to be produced, copper oxide and hypophosphoric acid and/or a salt thereof are mixed and reduced, preferably in the presence of 1-500 mass % of gelatin and/or collagen peptide. The reduction reaction temperature is preferably in the range of 20-100° C. The produced metallic copper particles have a volume resistivity value when heated to a temperature of 300° C. under a nitrogen atmosphere of 1×10-2 Ω·cm or less. | ||||||
| 108 | MESH PATTERNS FOR TOUCH SENSOR ELECTRODES | US15460853 | 2017-03-16 | US20170185189A1 | 2017-06-29 | Roger W. Barton; Billy L. Weaver; Bernard O. Geaghan; Brock A. Hable |
| An electrode for a touch sensitive device includes micro-wire conductors arranged to define an electrically continuous area and to include interior regions that are electrically discontinuous. The electrically continuous area may be patterned according to a one pattern, and the interior pattern may be patterned according to another pattern. | ||||||
| 109 | COPPER POWDER, AND COPPER PASTE, ELECTRICALLY CONDUCTIVE COATING MATERIAL AND ELECTRICALLY CONDUCTIVE SHEET EACH PRODUCED USING SAID COPPER POWDER | US15320333 | 2015-03-26 | US20170152386A1 | 2017-06-01 | Hiroshi Okada; Yu Yamashita |
| Provided is a copper powder in which the number of contact points between copper powder particles is increased to allow excellent electric conductivity to be achieved, and which can be used suitably in use applications including an electrically conductive paste and an electromagnetic wave shield. The copper powder according to the present invention has a dendritic shape composed of a main stem that is grown linearly and multiple branches that are branched from the main stem, wherein the main stem and the branches are composed of a flat-plate-like cupper particle having a cross section with an average thickness of 0.2 to 1.0 μm, and the average particle diameter (D50) of the copper powder is 5.0 to 30 μm. A copper paste having excellent electric conductivity can be produced by mixing the dendritic copper powder with a resin. | ||||||
| 110 | SILVER PARTICLE SYNTHESIZING METHOD, SILVER PARTICLES, CONDUCTIVE PASTE PRODUCING METHOD, AND CONDUCTIVE PASTE | US15318903 | 2015-06-16 | US20170144220A1 | 2017-05-25 | Katsuaki SUGANUMA; Jinting JIU |
| A silver particle synthesizing method includes reducing a dispersant from first silver particles each covered with the dispersant to obtain second silver particles. The method further includes synthesizing third silver particles each having a larger particle diameter than the second silver particles by causing a reaction between a silver compound and a reductant in a liquid phase containing the second silver particles. | ||||||
| 111 | TOUCH SENSOR ELECTRODE WITH PATTERNED ELECTRICALLY ISOLATED REGIONS | US15350297 | 2016-11-14 | US20170060306A1 | 2017-03-02 | Roger W. Barton; Billy L. Weaver; Matthew W. Gorrell; Brock A. Hable |
| An electrode layer has a plurality of substantially parallel electrodes disposed along a first direction. At least one electrode has a length along the first direction and a width from a first edge to a second edge along a second direction transverse to the first direction. At least one electrode comprises across its width at least one edge section, at least one intermediate section, and at least one central section, wherein an intermediate section is disposed along the electrode width between an edge section and the central section. At least one electrode edge section and intermediate section includes a plurality of electrically isolated regions arranged in a pattern along the electrode length. An electrode conductive area of the edge section is less than an electrode conductive area of the intermediate section. | ||||||
| 112 | Transfer method for manufacturing conductor structures by means of nano-inks | US13642006 | 2011-04-19 | US09403211B2 | 2016-08-02 | Ando Welling |
| A method for equipping a film material with at least one electrically conductive conductor structure, wherein a dispersion containing metallic nanoparticles in the form of a conductor structure is applied to a thermostable transfer material and the metallic nanoparticles are sintered to form an electrically conductive conductor structure. The electrically conductive conductor structure of sintered metallic nanoparticles is then transferred from the thermostable transfer material to the non-thermostable film material. A method for producing a laminate material using the film material using at least one electrically conductive conductor structure, and to the corresponding film material and laminate material are described. | ||||||
| 113 | ELECTROCONDUCTIVE SHEET AND TOUCH PANEL | US15074540 | 2016-03-18 | US20160202805A1 | 2016-07-14 | Akira ICHIKI |
| An electroconductive sheet and a touch panel having a first electroconductive section and a second electroconductive section, the second electroconductive section being disposed on the display-panel side. The first electroconductive section has a plurality of first electroconductive patterns arranged in the x-direction, a plurality of first large grids being respectively connected to the first electroconductive patterns. The second electroconductive section has a plurality of second electroconductive patterns arranged in the y-direction, a plurality of second large grids being respectively connected to the second electroconductive patterns. The area occupied by thin metal wires in the second electroconductive patterns is larger than the area occupied by thin metal wires in the first electroconductive patterns. The area occupied by thin metal wires in the second large grids is larger than the area occupied by thin metal wires in the first large grids. | ||||||
| 114 | SILVER POWDER | US14650161 | 2013-10-02 | US20150314370A1 | 2015-11-05 | Yuji KAWAKAMI; Akihiro MURAKAMI; Toshiaki TERAO; Isao KANEKO |
| The present invention provides a silver powder that has an appropriate viscosity range at the time of paste production, can be easily kneaded, and prevents flake occurrence. The silver powder has a dibutyl phthalate absorption amount, measured by a method of JIS-K6217-4, of 7.0 to 9.5 ml/100 g, and has an oil absorption profile at the time of measurement of the absorption amount, having two peaks, or one peak having a half width of not more than 1.5 ml/100 g. | ||||||
| 115 | TRANSFER METHOD FOR MANUFACTURING CONDUCTOR STRUCTURES BY MEANS OF NANO-INKS | US14706640 | 2015-05-07 | US20150239047A1 | 2015-08-27 | Ando WELLING |
| A method for equipping a film material with at least one electrically conductive conductor structure, wherein a dispersion containing metallic nanoparticles in the form of a conductor structure is applied to a thermostable transfer material and the metallic nanoparticles are sintered to form an electrically conductive conductor structure. The electrically conductive conductor structure of sintered metallic nanoparticles is then transferred from the thermostable transfer material to the non-thermostable film material. A method for producing a laminate material using the film material using at least one electrically conductive conductor structure, and to the corresponding film material and laminate material are described. | ||||||
| 116 | TRANSFER METHOD FOR MANUFACTURING CONDUCTOR STRUCTURES BY MEANS OF NANO-INKS | US14706613 | 2015-05-07 | US20150239044A1 | 2015-08-27 | Ando WELLING |
| A method for equipping a film material with at least one electrically conductive conductor structure, wherein a dispersion containing metallic nanoparticles in the form of a conductor structure is applied to a thermostable transfer material and the metallic nanoparticles are sintered to form an electrically conductive conductor structure. The electrically conductive conductor structure of sintered metallic nanoparticles is then transferred from the thermostable transfer material to the non-thermostable film material. A method for producing a laminate material using the film material using at least one electrically conductive conductor structure, and to the corresponding film material and laminate material are described. | ||||||
| 117 | Self-lubricating coating and method for producing a self-lubricating coating | US13388949 | 2010-07-30 | US09057142B2 | 2015-06-16 | Dominique Freckmann; Helge Schmidt |
| The invention relates to a coating (7) made up of a metal layer (8), in which a lubricant (1) which can be released by wear is embedded. In order to provide a wear-resistant coating (7) which is simply structured and economical to produce, the invention provides for the lubricant (1) to consist of an at least singly branched organic compound (2). The present invention further relates to a self-lubricating component (11) with a coating (7) according to the invention applied at least in certain portions, to a method for producing a coating (7), and also to a coating electrolyte (10) comprising at least one type of metal ions and at least one lubricant (1) consisting of an at least singly branched organic compound (2). | ||||||
| 118 | METHOD FOR CONNECTING THE CONDUCTORS OF A FLEXIBLE BONDED (EQUIPOTENTIAL) CONNECTION LAYER, AS WELL AS CRIMPING TOOL, CONNECTORS AND WIRING LOOM FITTED WITH SUCH CONNECTORS | US14396592 | 2013-04-18 | US20150107893A1 | 2015-04-23 | Jean-Luc Biesse; Arnaud Camille Ayme; Florian Barraud; David Boutot |
| A connection which is reproducible, uniform and reliable both for intermediate and terminal connections of a conductor layer wiring loom, by making provision for simultaneous crimping of the conductors in connectors by applying continuous and uniform pressure in a crimping zone. The crimping is carried out by a tool including two shells, each shell including a main wall that forms an inner face including transverse ribs and end edges folded over perpendicularly relative to the walls to define an inner space. In the inner space, a connector of non-insulated conductors arranged perpendicularly relative to the ribs is introduced to form transverse grooves by compression of the ribs on the walls of the connector. The tool can find use in current return networks of aircraft passenger cabins having composite skin. | ||||||
| 119 | Circuit assembly | US13539553 | 2012-07-02 | US08884169B2 | 2014-11-11 | Andrew J. Jozwiak |
| A circuit assembly that includes a planar lead frame formed of electrically conductive material having a first thickness. The lead frame is configured to define a routing plane and a plurality of coplanar sections in the routing plane. The circuit assembly also includes a top-side terminal formed of electrically conductive material having a second thickness independent of the first thickness. The top-side terminal is configured to be inserted into a hole defined in a section and form an electrical connection to the section, wherein the top-side terminal protrudes from the routing plane. | ||||||
| 120 | Carbon nanotube enhanced conductors for communications cables and related communications cables and methods | US13446728 | 2012-04-13 | US08853540B2 | 2014-10-07 | Luc Walter Adriaenssens |
| A conductor for a communications cable includes an elongated metal wire and a metal sheet that includes a plurality of carbon nanotubes that at least partially surrounds the elongated metal wire. The metal wire may include copper, and the metal sheet may likewise include copper and may be welded to an outside surface of the metal wire to surround the metal wire. This conductor may be used in a variety of communications cables that carry high frequency signals. | ||||||
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