81 |
COPPER POWDER AND ELECTRICALLY CONDUCTIVE PASTE, ELECTRICALLY CONDUCTIVE COATING, ELECTRICALLY CONDUCTIVE SHEET, AND ANTISTATIC COATING USING SAME |
US15323162 |
2015-03-26 |
US20170145225A1 |
2017-05-25 |
Hiroshi Okada; Yu Yamashita |
To provide a copper powder exhibiting a high electric conductivity suitable for a metallic filler used in an electrically conductive paste, a resin for electromagnetic shielding, an antistatic coating, etc., and having excellent uniform dispersibility required for forming a paste so as to inhibit an increase in viscosity due to flocculation. This copper powder 1 forms a branch shape having a plurality of branches through the conglomeration of copper particles 2. The copper particles 2 have a spheroidal shape, with diameters ranging from 0.2 μm-0.5 μm, inclusive, and lengths ranging from 0.5 μm-2.0 μm, inclusive. The average particle diameter (D50) of the copper powder 1 in which the spheroidal copper particles 2 have conglomerated is 5.0 μm-20 μm. By mixing this tree-branch-shaped copper powder 1 into a resin, it is possible to produce an electrically conductive paste, etc., exhibiting excellent electric conductivity, for example. |
82 |
Low resistance insert |
US13964721 |
2013-08-12 |
US09653194B2 |
2017-05-16 |
Kimberly Debock; David James Fabian; Brian Todd Klinger |
A conductive insert which provides a low resistance bond between low conductive materials. The insert includes a first surface and an oppositely facing second surface. A plurality of openings extends between the first surface and the second surface. At least one first projection extends from the first surface proximate respective first openings, the at least one first projections extend from the first surface in a direction away from the second surface. At least one second projection extends from the second surface proximate respective second openings, the at least one second projections extend from the second surface in a direction away from the first surface. |
83 |
Mesh patterns for touch sensor electrodes |
US15138418 |
2016-04-26 |
US09639228B2 |
2017-05-02 |
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. |
84 |
Transfer method for manufacturing conductor structures by means of nano-inks |
US14706640 |
2015-05-07 |
US09550234B2 |
2017-01-24 |
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. |
85 |
Cable structure for preventing tangling |
US14148074 |
2014-01-06 |
US09524810B2 |
2016-12-20 |
Jonathan S. Aase; Cameron P. Frazier; Matthew D. Rohrbach; Peter N. Russell-Clarke; Dale N. Memering |
This is directed to a cable structure for use with an electronic device. The cable structure can include one or more conductors around which a sheath is provided. To prevent the cable structure from tangling, the cable structure can include a core placed between the conductors and the sheath, where a stiffness of the core can be varied along different segments of the cable structure to facilitate or hinder bending of the cable structure in different areas. The size and distribution of the stiffer portions can be selected to prevent the cable from forming loops. The resistance of the core to bending can be varied using different approaches including, for example, by varying the materials used in the core, varying a cross-section of portions of the core, or combinations of these. |
86 |
ELECTRIC WIRE AND CABLE |
US14936113 |
2015-11-09 |
US20160141072A1 |
2016-05-19 |
Tamotsu KIBE; Hisao FURUICHI; Hiroshi OKIKAWA; Ryutaro KIKUCHI |
An electric wire includes a conductor having a cross-sectional area of not less than 225 mm2 and not more than 275 mm2, an insulation provided so as to cover the outer periphery of the conductor, and a wire sheath provided so as to cover the outer periphery of the insulation. The amount of deflection is not less than 130 mm when, at 23° C., one end of the electric wire is fixed to a fixture table so that another end horizontally protrudes 400 mm from the fixture table and a weight of 2 kg is attached to the other end, and cracks and breaks do not occur when wound with a bending diameter of three times the diameter at −40° C. |
87 |
Electroconductive sheet and touch panel |
US13966898 |
2013-08-14 |
US09312048B2 |
2016-04-12 |
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. |
88 |
Collective conductor and method for producing collective conductor |
US14018797 |
2013-09-05 |
US09251926B2 |
2016-02-02 |
Ichiro Okada; Hiroaki Urano |
A collective conductor includes a plurality of conductive wires that is arranged collectively; and a copper foil that is wound around the collectively-arranged conductive wires and fusion-bonded to the conductive wires, and the copper foil has a tin plating on the side in contact with the conductive wires. |
89 |
CONNECTOR FRAME AND SEMICONDUCTOR DEVICE |
US14456722 |
2014-08-11 |
US20150221582A1 |
2015-08-06 |
Takeshi Miyakawa |
According to one embodiment, a connector frame includes a frame part, a first connector projected from the frame part and integrated with the frame part, and a second connector projected from the frame part and integrated with the frame part. The first connector includes a first portion and a second portion provided between the first portion and the frame part. The second portion is thinner than the first portion. The second connector is as thick as the second portion of the first connector. |
90 |
Metallic Material For Electronic Components And Method For Producing Same, And Connector Terminals, Connectors And Electronic Components Using Same |
US14411779 |
2013-06-27 |
US20150147924A1 |
2015-05-28 |
Yoshitaka Shibuya; Kazuhiko Fukamachi; Atsushi Kodama |
The present invention provides metallic materials for electronic components, having low degree of whisker formation, low adhesive wear property and high durability, and connector terminals, connectors and electronic components using such metallic materials. The metallic material for electronic components includes: a base material; a lower layer formed on the base material, the lower layer being constituted with one or two or more selected from a constituent element group A, namely, the group consisting of Ni, Cr, Mn, Fe, Co and Cu; an intermediate layer formed on the lower layer, the intermediate layer including an alloy constituted with one or two or more selected from a constituent element group B, namely, the group consisting of Ag, Au, Pt, Pd, Ru, Rh, Os and Ir, and one or two selected from a constituent element group C, namely, the group consisting of Sn and In; and an upper layer formed on the intermediate layer, the upper layer being constituted with one or two selected from a constituent element group C, namely, the group consisting of Sn and In; wherein the thickness of the lower layer is 0.05 μm or more and less than 5.00 μm; the thickness of the intermediate layer is 0.02 μm or more and less than 0.80 μm; and the thickness of the upper layer is 0.005 μm or more and less than 0.30 μm. |
91 |
MOISTURE-RETAINING AND ELECTRICALLY CONDUCTIVE STRUCTURE |
US13774044 |
2013-02-22 |
US20140243639A1 |
2014-08-28 |
HONG-HSU HUANG; SHUN-TUNG YANG; JUNG-HSIANG PENG; I-CHEN SU |
An improved moisture-retaining and electrically conductive structure includes a plurality of moisture-retaining and electrically conductive yarns that is woven to form a planar structure, wherein each of the moisture-retaining and electrically conductive yarns is formed by blending a plurality of electrically conductive fibers and a plurality of moisture-retaining fibers. With such a structure, fabric of the same layer can provide both functions of moisture retention and electrical conduction and may improve the lifespan and electrical conductivity. |
92 |
MULTI-LAYER COMPOSITE WITH METAL-ORGANIC LAYER |
US14081177 |
2013-11-15 |
US20140134454A1 |
2014-05-15 |
Herbert FUCHS; Hyung Seok HA; Kerstin TIMTER; Jeongno LEE; Bumjoo LEE; Chul Jong HAN; Seunghyun LEE |
A multi-layer composite precursor is provided comprising a substrate, wherein the substrate comprises a light emitting organic compound, a first surface, and a second surface, wherein the second surface is superimposed by a transparent electrically conducting layer, a liquid phase superimposing at least a part of the first surface comprising a metal-organic compound, wherein the metal-organic compound comprises an organic moiety, wherein the organic moiety comprises a C═O group; and wherein the liquid phase further comprises a first silicon compound, wherein the first silicon compound comprises at least one carbon atom and at least one nitrogen atom. |
93 |
Cable structure for preventing tangling |
US12942531 |
2010-11-09 |
US08625836B2 |
2014-01-07 |
Jonathan Aase; Cameron Frazier; Matthew Rohrbach; Peter Russell-Clark; Dale Memering |
This is directed to a cable structure for use with an electronic device. The cable structure can include one or more conductors around which a sheath is provided. To prevent the cable structure from tangling, the cable structure can include a core placed between the conductors and the sheath, where a stiffness of the core can be varied along different segments of the cable structure to facilitate or hinder bending of the cable structure in different areas. The size and distribution of the stiffer portions can be selected to prevent the cable from forming loops. The resistance of the core to bending can be varied using different approaches including, for example, by varying the materials used in the core, varying a cross-section of portions of the core, or combinations of these. |
94 |
ELECTRODE FOR MEDICAL APPLICATIONS, SYSTEM HAVING SUCH AN ELECTRODE, AND METHOD FOR PRODUCING SUCH AN ELECTRODE |
US13818662 |
2011-08-26 |
US20130206454A1 |
2013-08-15 |
Giorgio Cattaneo; Alfred Stett; A. Gharabaghi |
An electrode for intravascular medical applications for neuromodulation and/or nerve stimulation and/or neurological signal detection, wherein the electrode can be compressed and expanded in order to insert same into a hollow organ of a body and is or can be coupled to a current supply. A compressible and expandable lattice structure is provided, which has cells formed from lattice webs and is or can be coupled to the current supply, the lattice structure being obtained at least partially by physical vapor deposition. |
95 |
Electric contact member |
US12895050 |
2010-09-30 |
US08410367B2 |
2013-04-02 |
Takayuki Hirano; Akashi Yamaguchi; Takashi Miyamoto |
Provided is an electric contact member which reduces, to the utmost, peel-off of a carbon film that is caused at the time of use of the electric contact member having at least an edge to keep stable electric contact over a long period of time. Disclosed is an electric contact member which repeatedly contacts with a device under test at a tip part of the electric contact member in which the tip part has an edge, the electric contact member comprising: a base material; an underlying layer comprising Au, Au alloy, Pd or Pd alloy, which is formed on a surface of the base material of the tip part; an intermediate layer which is formed on a surface of the underlying layer; and a carbon film comprising at least one of a metal and a carbide thereof which is formed on a surface of the intermediate layer, wherein the intermediate layer has a lamination structure comprising: an inner layer comprising Ni or Ni alloy; and an outer layer comprising at least one of Cr, Cr alloy, W and W alloy. |
96 |
Occupant sensing and heating textile |
US13637517 |
2011-03-28 |
US20130075381A1 |
2013-03-28 |
Thomas Wittkowski |
A textile electrode material comprises an electrically conductive textile sheet material having a first sheet resistance. According to the invention the electrical properties of at least one specific region of said textile sheet material are modified with respect to the other regions so that in said specific region the textile electrode has a second sheet resistance, which is substantially lower than said first sheet resistance. |
97 |
SELF-LUBRICATING COATING AND METHOD FOR PRODUCING A SELF-LUBRICATING COATING |
US13388949 |
2010-07-30 |
US20120129740A1 |
2012-05-24 |
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). |
98 |
Multi-core conductive wire and a method of manufacturing the same |
US09485157 |
2000-02-04 |
US06452101B1 |
2002-09-17 |
Takashi Haramaki; Izumi Sakurai; Yoshitaka Kojima |
An object of the invention is to provide a multi-core conductive wire having the small number of manufacturing processes and a terminal with high strength, and a method of manufacturing the multi-core conductive wire. The multi-core conductive wire is provided with a terminal, at the end portion thereof, where individual strands of the multi-core conductive wire are entangled with each other and the terminal is molded by subjecting to pressure-molding. A method of manufacturing a multi-core conductive wire comprises a step of processing the multi-core conductive wire into a state where individual strands of the multi-core conductive wire are partially entangled with each other; a step of temporarily molding the processed portion; and a step of further applying pressure to the temporarily molded portion for pressure-molding or plastic working. |
99 |
Power cable conductor for reducing windage |
US42097764 |
1964-12-24 |
US3286018A |
1966-11-15 |
MCLOUGHLIN JOSEPH R |
|
100 |
Overhead electric lines and conductors therefor |
US24082851 |
1951-08-08 |
US2731510A |
1956-01-17 |
GIDDENS BRAZIER LESLIE; GEORGE HAWLEY WILLIAM |
|