141 |
Power transmission cable |
US35897064 |
1964-03-26 |
US3264404A |
1966-08-02 |
TREBBY CLAUDINE J; ROEHMANN LUDWIG F; SHEALY ALEXANDER N |
|
142 |
Copper wrapped cable |
US27940763 |
1963-05-10 |
US3206543A |
1965-09-14 |
GILMORE WILLIAM J |
|
143 |
METHOD FOR PRODUCING CARBON NANOFIBER COMPOSITE AND CARBON NANOFIBER COMPOSITE |
US15753138 |
2016-07-15 |
US20180347073A1 |
2018-12-06 |
Toru Arai; Hitoshi Kaneko |
An object of the present invention is to provide a method for a carbon nanofiber composite, which can obtain a carbon nanofiber composite with high productivity and high activity, and which does not require removal of fluidizing materials or dispersing materials. The present invention also provides a carbon nanofiber composite having improved dispersibility. The method for producing the carbon nanofiber composite includes bringing at least one catalyst and at least one particulate carbon material into contact with at least one gas containing at least one gaseous carbon-containing compound while mechanically stirring the catalyst and the particulate carbon material in a reactor. The carbon nanofiber composite includes carbon nanofibers and at least one particulate carbon material, wherein the particulate carbon material has 70% by volume or more of particles with a particle diameter of 1 μm or less, and/or a median diameter D50 by volume of 1 μm or less. |
144 |
PARTICLES, CONNECTING MATERIAL AND CONNECTION STRUCTURE |
US15767820 |
2016-11-18 |
US20180318970A1 |
2018-11-08 |
Mai YAMAGAMI; Satoshi HANEDA; Takeshi WAKIYA; Yasuyuki YAMADA; Saori UEDA; Masao SASADAIRA |
Particles that can suppress the occurrence of cracking during a stress load in a connection part that connects two members to be connected are provided. The particles according to the present invention are particles used to obtain a connecting material for forming the connection part that connects two members to be connected, and the particles are used for forming the connection part such that thickness of the connection part after connection exceeds twice the average particle diameter of the particles before connection, or the particles have an average particle diameter of 0.1 μor more and 15 μm or loss, the particles have a 10% K value of exceeding 3000 N/mm2 and 20000 K/mm2 or less, and the particles have a particle diameter CV value of 50% or less. |
145 |
PARTICLES, CONNECTING MATERIAL AND CONNECTION STRUCTURE |
US15767803 |
2016-11-18 |
US20180297154A1 |
2018-10-18 |
Mai YAMAGAMI; Satoshi HANEDA; Takeshi WAKIYA; Yasuyuki YAMADA; Saori UEDA; Masao SASADAIRA |
Particles that can suppress the occurrence of cracking or peeling during a thermal cycle in a connection part, that connects two members to be connected are provided. The particles according to the present invention are particles used to obtain a connecting material for forming a connection part that connects two members to be connected, and the particles are used for forming the connection part such that thickness of the connection part, after connection exceeds twice the average particle diameter of the particles before connection, or the particles have an average particle diameter of 0.1 nm or more and 15 μm or less, the particles have a 10% K value of 30 N/mm2 or more and 3000 N/mm2 or less, and the particles have a particle diameter CV value of 50% or less. |
146 |
Electric wire and cable |
US14936113 |
2015-11-09 |
US09991027B2 |
2018-06-05 |
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. |
147 |
Heating Layer For Film Removal |
US15716700 |
2017-09-27 |
US20180016028A1 |
2018-01-18 |
Daniel J. Kovach; Gary E. Georgeson; Robert J. Miller; Jeffrey D. Morgan; Diane Rawlings |
Embodiments of the presently disclosed system include a thin thermoplastic or thermosetting polymer film loaded with non-polymeric inclusions that are susceptible to heating under a time-varying magnetic field. Insertion of this additional heating layer into a structural or semi-structural heterogeneous laminate provides an “on-demand” de-bonding site for laminate deconstruction. For example, in some embodiments when the heating layer is inserted between a cured Carbon-Fiber Reinforced Plastic (CFRP) layer and a Polymeric/Metallic film stackup layer, the heating layer can be selectively heated above its softening point (e.g., by using energy absorbed from a locally-applied time-varying magnetic field) to allow for ease of applique separation from the CFRP layer. |
148 |
METAL POWDER, INK, SINTERED BODY, SUBSTRATE FOR PRINTED CIRCUIT BOARD, AND METHOD FOR MANUFACTURING METAL POWDER |
US15546093 |
2016-01-26 |
US20180015547A1 |
2018-01-18 |
Issei OKADA; Yoshio OKA; Takashi KASUGA; Yasuhiro OKUDA; Jinjoo PARK; Kousuke MIURA; Hiroshi UEDA |
An object of the present invention is to provide a metal powder and an ink with which a sintered body having good flexibility can be formed, and a sintered body having good flexibility. A metal powder according to an embodiment of the present invention has a mean particle size D50BET of 1 nm or more and 200 nm or less as calculated by a BET method, a mean crystallite size DCryst of 20 nm or less as determined by an X-ray analysis, and a ratio (DCryst/D50BET) of the mean crystallite size DCryst to the mean particle size D50BET of less than 0.4. |
149 |
CONDUCTIVE PARTICLES, CONDUCTIVE POWDER, CONDUCTIVE POLYMER COMPOSITION AND ANISOTROPIC CONDUCTIVE SHEET |
US15520855 |
2015-09-29 |
US20170333989A1 |
2017-11-23 |
Hidehito MORI; Tsutomu NOZAKA |
A conductive particle including a conductive powder, a conductive polymer composition, and an anisotropic conductive sheet, each of which has a particularly smaller volume resistivity and better conductivity than those of the related art, and is desirably inexpensive. A conductive particle includes a first plating layer (pure Ni plating layer or Ni plating layer containing 4.0 mass % or less of P) covering the surface of a spherical Ni core containing 5 mass % to 15 mass % or less of P. The conductive particle may further include a Au plating layer having a thickness of from 5 nm to 200 nm and covering the surface of the first plating layer. |
150 |
Virus film as template for porous inorganic scaffolds |
US13934964 |
2013-07-03 |
US09805841B2 |
2017-10-31 |
Noemie-Manuelle Dorval Courchesne; Angela M. Belcher; Paula T. Hammond; Matthew T. Klug |
Virus multilayers can be used as templates for growth of inorganic nanomaterials. For example, layer-by-layer construction of virus multilayers on functionalized surfaces form nanoporous structures onto which metal particles or metal oxide nanoparticles can be nucleated to result in an interconnected network of nanowires. |
151 |
Transparent conductive film, heater, touch panel, solar battery, organic EL device, liquid crystal device, and electronic paper |
US14005976 |
2012-03-21 |
US09786410B2 |
2017-10-10 |
Keisuke Shimizu; Toshiyuki Kobayashi; Nozomi Kimura; Kyoko Izuha |
There are provided a transparent conductive film, as well as a heater, a touch panel, a solar battery, an organic EL device, a liquid crystal device, and an electronic paper that are provided with the transparent conductive film, the transparent conductive film being capable of easing a decline in optical transmittance when graphene is laminated, and of achieving optical transmittance higher than an upper limit of optical transmittance of a single layer of graphene. The transparent conductive film includes a single-layered conductive graphene sheet. The single-layered conductive graphene sheet includes a first region and a second region, the first region being configured of graphene, and the second region being surrounded by the first region and having optical transmittance that is higher than optical transmittance of the first region. |
152 |
Method for producing silver nano-particles and silver nano-particles |
US14419613 |
2013-07-31 |
US09776250B2 |
2017-10-03 |
Yuki Iguchi; Kazuki Okamoto |
The present invention provides a silver nano-particle production method which is safe and simple also in terms of scaled-up industrial-level production, in a so-called thermal decomposition method in which a silver-amine complex compound is thermally decomposed to form silver nano-particles. A method for producing silver nano-particles comprising: mixing an aliphatic hydrocarbon amine and a silver compound in the presence of an alcohol solvent having 3 or more carbon atoms to form a complex compound comprising the silver compound and the amine; and thermally decomposing the complex compound by heating to form silver nano-particles. |
153 |
SILVER-COATED COPPER POWDER, AND CONDUCTIVE PASTE, CONDUCTIVE COATING MATERIAL AND CONDUCTIVE SHEET EACH OF WHICH USES SAME |
US15504109 |
2015-03-26 |
US20170274453A1 |
2017-09-28 |
Hiroshi Okada; Hideyuki Yamashita |
Provided is a dendritic silver-coated copper powder which is capable of effectively ensuring a contact, while having excellent electrical conductivity by having the surface coated with silver. A silver-coated copper powder according to the present invention is obtained by coating the surface of a copper powder 1, which is an assembly of copper particles 2 and has a dendritic form having a plurality of branches, with silver. Each copper particle 2, the surface of which is coated with silver, is an ellipsoid that has a breadth within the range of from 0.2 μm to 0.5 μm and a length within the range of from 0.5 μm to 2.0 μm. The average particle diameter (D50) of the copper powder 1, which is obtained by coating the surface of the assembly of the ellipsoidal copper particles 2 with silver, is from 5.0 μm to 20 μm. |
154 |
Manufacturing and applications of metal powders and alloys |
US14078871 |
2013-11-13 |
US09679675B2 |
2017-06-13 |
Andrew Matheson |
Disclosed is a process to reduce mixtures of at least one metal halide by molten metal reduction of the liquid phase metal halide in an alkali or alkaline earth metal to form a reaction product comprising at least one metal mixture and a halide salt coating, in which the at least one metal halide is in stoichiometric excess to the molten metal reductant and wherein the reductant is consumed in the reaction and does not need to be removed at the end of the reaction. |
155 |
STRETCHABLE ELECTRICALLY-CONDUCTIVE CIRCUIT AND MANUFACTURING METHOD THEREFOR |
US15311659 |
2015-05-14 |
US20170153152A1 |
2017-06-01 |
Manabu Yoshida; Sei Uemura; Taiki Nobeshima |
A stretchable electrically-conductive sheet according to the present invention includes an elastomer sheet 1 having an adhesive layer corresponding to a wiring region with a predetermined pattern formed on a front surface of the elastomer sheet, and also includes electrically-conductive fiber materials 2 each having a predetermined diameter and a predetermined length. When the elastomer sheet 1 is stretched or bended, the electrically-conductive fiber materials relatively move maintaining mutual electrical continuity so as to maintain the electrical continuity in the wiring region. Accordingly, it is possible to achieve a low-cost stretchable electrically-conductive circuit having excellent stretchability, bendability, and durability. |
156 |
Highly conducting material |
US14900124 |
2014-06-18 |
US09634222B2 |
2017-04-25 |
Jorma Virtanen; Veijo Kangas |
The present invention concerns electrically conductive nanocomposites. More specifically the electrical conductance of graphitic material can be improved significantly by a molecular coating that has well defined repeating structure. Even superconductivity of these materials may be possible at technologically meaningful temperatures. |
157 |
CONDUCTIVE BALL |
US15306059 |
2016-02-12 |
US20170047145A1 |
2017-02-16 |
Akimichi TAKIZAWA |
The present invention provides a conductive ball, which can be used as a connector by intervening between electrodes to apply a current between the electrodes with relatively high conductivity, and which is prevented from decreasing the conductivity due to the following thermal history. The conductive ball of the present invention comprises a sphere formed of an elastic body; a thermal expansion-resistant resin shell applied so as to coat the surface of the sphere; and a conductive metal shell applied so as to coat the outer surface of the thermal expansion-resistant resin shell. For example, the sphere is formed of a silicone rubber, the thermal expansion-resistant resin shell is formed of a polyimide, and the conductive metal shell is formed of copper, gold, silver, or palladium, or an alloy containing it. |
158 |
Touch sensor electrode with patterned electrically isolated regions |
US14368473 |
2013-02-11 |
US09529481B2 |
2016-12-27 |
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. |
159 |
MESH PATTERNS FOR TOUCH SENSOR ELECTRODES |
US15138418 |
2016-04-26 |
US20160253003A1 |
2016-09-01 |
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. |
160 |
Mesh patterns for touch sensor electrodes |
US13689935 |
2012-11-30 |
US09360971B2 |
2016-06-07 |
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. |