| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 21 | A CURRENT TRANSPORT MECHANISM, IN PARTICULAR AN ELECTRICAL OR ELECTROMECHANICAL CURRENT BAR | EP17207212.6 | 2017-12-14 | EP3339104A1 | 2018-06-27 | ULRICH, Harald; SCHMIDT, Christian |
The invention relates to a vehicle current transport mechanism (1), in particular for a motor vehicle, with an elongated, electromechanical base conductor (10), wherein the base conductor (10) comprises at least one electrically-rigidly mechanical plug-in connection device (100, 202) which is connected thereto in an electrically-rigidly mechanical manner, and which in turn can be electrically contacted by an electrically-rigidly mechanical mating plug-in connection device (9). Furthermore, the invention relates to a current transport mechanism (1), in particular a current bar (1), a backbone (1) or a bus bar (1) for the automotive industry, wherein the current transport mechanism (1) has an elongated, electromechanical base conductor (10) with an electrical insulation (30) surrounding it in the circumferential direction, and the electrical insulation (30) has at least one through-recess (310) and the base conductor (10) is electrically contacted by a plug-in connection device (100) in a region (11) of the through-recess (310).
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| 22 | PROCÉDÉ DE RACCORDEMENT, RACCORD DE DÉRIVATION ÉQUIPOTENTIEL ET RÉSEAU DE RETOUR COURANT À LIAISON ÉQUIPOTENTIELLE DANS UNE ARCHITECTURE NON CONDUCTRICE | EP13704169.5 | 2013-01-17 | EP2805392A2 | 2014-11-26 | BIESSE, Jean-Luc; ALBERO, Franck; ANDRAUD, Samuel; BOUTOT, David |
| The aim of the invention is to produce electrically efficient equipotential connections in terms of resistivity between portions of a current return network of a non-conductive architecture, such as an airplane fuselage. The approach adopted according to the invention is to impart an equipotential bonding function to an aluminum cable having a large cross-section, said bond being electrically connected, via direct contact, to as many pieces of equipment as is physically possible. According to one embodiment, an electrical connection assembly of an aircraft fuselage (100) having a composite skin comprises on-line shunt connections (2) for electrically interconnecting an aluminum alloy cable (1), having a large cross-section and serving as an equipotential bond, to brackets (113, 141) for primary current return networks and to brackets (111) for electrical devices via connections (202). Each on-line shunt connection (2) comprises a central sleeve (2m) for directly electrically contacting the cable (1), end portions for being assembled to the cable (1) by crimping, and an attachment means (2p) for attaching to the bracket (111) of the equipment. Each of the ends of the sleeve (2m) have seal accommodated therein. Each interconnection has two sealed areas, which surround a central contact area formed by means of window-stripping. | ||||||
| 23 | INTELLIGENT PATCHING SYSTEM | EP09793634.8 | 2009-11-12 | EP2347600B1 | 2013-08-21 | CAVENEY, Jack, E.; NORDIN, Ronald A.; ALLEN, Shahriar, B. |
| 24 | METHOD FOR PRODUCING CABLE WITH TERMINAL, AND CABLE WITH TERMINAL | EP11828610.3 | 2011-07-28 | EP2624379A1 | 2013-08-07 | ITOU Akira; GOTO Kouichirou |
It is aimed to enable a heat shrinkable tube to be mounted on a connected part of a core exposed portion of a wire and a terminal with high positioning accuracy. A terminal-fitted wire manufacturing method is for mounting a heat shrinkable tube on a connected part of a core exposed portion of a wire and a terminal. After the wire is inserted into the heat shrinkable tube, the terminal is connected to the core exposed portion. Thereafter, the heat shrinkable tube is moved to a position for covering the connected part of the core exposed portion and the terminal, and a part of the heat shrinkable tube is temporarily fixed to at least parts of the wire and the terminal. Thereafter, the heat shrinkable tube is mounted by being heated and thermally shrunk. |
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| 25 | CONDUCTIVE PATH STRUCTURE AND WIRE HARNESS | EP11770186.2 | 2011-09-16 | EP2617041A1 | 2013-07-24 | ADACHI, Hideomi; KUBOSHIMA, Hidehiko |
| A conductive path structure includes a conductor (28) that includes a first conductive portion and a second conductive portion which are connected to each other through a cut-off facilitating portion ( 30 ), and a semi -solid state insulation member ( 31 ) that is in a semi -solid state and covers the cut-off facilitating portion ( 30 ). When the cut-off facilitating portion ( 30 ) is cut off so as to separate the first conductive portion and the second conductive portion to each other due to an impact applied to the cut-off facilitating portion ( 30 ), the semi -solid state insulation member ( 31 ) covers end portions of the separated first conductive portion and the separated second conductive portion which are close to the cut-out facilitating portion ( 30 ). | ||||||
| 26 | ELECTRICAL CONNECTORS FOR SOLID STATE LIGHT | EP17173207.6 | 2013-03-14 | EP3252373A1 | 2017-12-06 | DEVORE, Charles N.; MCGRATH, Kayla A.; RAIDER, Wesley A.; SCHLEIF, Larry A.; FELDMAN, Steven; NEU, Steven A. |
The present invention relates to a light with integrated light and thermal guides and separable electrical connectors, comprising: |
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| 27 | ELECTRICAL CONNECTORS FOR SOLID STATE LIGHT | EP13769434 | 2013-03-14 | EP2831498A4 | 2016-01-13 | DEVORE CHARLES N; MCGRATH KAYLA A; RAIDER WESLEY A; SCHLEIF LARRY A; FELDMAN STEVEN; NEU STEVEN A |
| 28 | METHOD FOR PRODUCING CABLE WITH TERMINAL, AND CABLE WITH TERMINAL | EP11828610 | 2011-07-28 | EP2624379A4 | 2014-12-03 | ITOU AKIRA; GOTO KOUICHIROU |
| 29 | INTELLIGENT PATCHING SYSTEM | EP09793634.8 | 2009-11-12 | EP2347600A1 | 2011-07-27 | CAVENEY, Jack, E.; NORDIN, Ronald A.; ALLEN, Shahriar, B. |
| An intelligent network patch field management system is provided that includes active electronic hardware, firmware, mechanical assemblies, cables, and software that guide, monitor, and report on the process of connecting and disconnecting patch cords plugs in an interconnect or cross-connect patching environment. The system is also capable of monitoring patch cord connections to detect insertions or removals of patch cords or plugs. In addition, the system can map embodiments of patch fields. | ||||||
| 30 | Kelvin contact assembly in a testing apparatus for integrated circuits | US15422690 | 2017-02-02 | US10018653B2 | 2018-07-10 | Wei Kuong Foong; Kok Sing Goh; Shamal Mundiyath; Eng Kiat Lee |
| An electrical Kelvin contact assembly for testing IC testing apparatus that uses an assembly design that reduces the tolerance to a near negligible range. The assembly does not use any screws, dowel pins, adhesives or welding to fasten the electrical contacts to the housing. The design of the assembly uses rows of contacts with specially designed protrusions that sit snugly in openings located on three plate-like layers. These layers contain the contacts in the horizontal plane by securing the protrusions in the opening, as well as in the vertical plane by means of a sandwich between three separate layers. A second contact is slid into back slits formed by the three layers. | ||||||
| 31 | Electrical connector | US29564149 | 2016-05-11 | USD792347S1 | 2017-07-18 | Daron Callahan; Peter M. Schneider; David Singer; Kenneth J. Buras |
| 32 | POLYKETONE RESIN COMPOSITION HAVING OUTSTANDING WATER RESISTANCE | US15327213 | 2015-07-20 | US20170158851A1 | 2017-06-08 | Jong In CHOI; Kyung Tae CHO; Sung Kyoun YOON; Seong Hwan KIM; Jong LEE; Ka Young KIM; Seung Jo BAEK |
| The present invention relates to a polyketone resin composition and to a production method therefor; and relates to a polyketone copolymer having outstanding water resistance, moisture-absorption rate and shock resistance, characterised in that the polyketone copolymer comprises repeat units represented by general formulae (1) and (2) and has an intrinsic viscosity of between 1.0 and 2.0 dl/g. Because of the outstanding moisture-absorption rate and shock resistance, the present invention can be used in, inter alia, marine bolts, clips and holders, connectors, switches, bobbins, sludge-treatment chains, cable ties, automotive fuel injection ports, green juicer screws, office partition frames and box frames. —[—CH2CH2-CO]x- (1) —[—CH2-CH(CH3)-CO]y- (2) | ||||||
| 33 | System incorporating current path between conductive members | US13877766 | 2011-10-06 | US09627780B2 | 2017-04-18 | Rainer Meinke |
| An electrical system having a current path formed in a region between first and second electrodes. When a low pressure is sustained in the region, and a plasma is generated in a portion of a gap between the electrodes, current flows across the gap from the first electrode to the second electrode. In one embodiment the system is operable as a motor or a generator, having a first electrode and a member including a second electrode which is rotatable with respect to the first electrode. In another embodiment a first conductor is positioned to carry current toward or away from a first terminal at a high temperature, and a second conductor is spaced apart from the first terminal to carry current toward or away from a second terminal when the second conductor is at a low temperature relative to the temperature of the first region. | ||||||
| 34 | INTELLIGENT PATCHING SYSTEM | US15235229 | 2016-08-12 | US20160373839A1 | 2016-12-22 | Jack E. Caveney; Ronald A. Nordin; Shahriar B. Allen |
| An intelligent network patch field management system is provided that includes active electronic hardware, firmware, mechanical assemblies, cables, and software that guide, monitor, and report on the process of connecting and disconnecting patch cords plugs in an interconnect or cross-connect patching environment. The system is also capable of monitoring patch cord connections to detect insertions or removals of patch cords or plugs. In addition, the system can map embodiments of patch fields. | ||||||
| 35 | Cable connector assembly with improved luminous effect | US14920058 | 2015-10-22 | US09450350B2 | 2016-09-20 | Chi-Ming Chen; De-Gang Zhang; Zhi-Yang Li |
| A cable connector assembly (100) comprises: a first connector (10) having a main body (120), a number of contacts (121) retained in the main body, a first circuit board (130) electrically connected to the contacts, and a metal shell (110) enclosing the first circuit board; a cable (30) electrically connected between the first circuit board and a power source to provide a power to the first circuit board; a second circuit board (150) vertically fixed on the metal shell; a cover enclosing the first and the second circuit board; a luminous element (152) disposed on a front side of the second circuit board and electrically connected to the first circuit board; and a translucent portion (1610) defined on a front end of the cover to pass light emitted by the luminous element. | ||||||
| 36 | Intelligent patching system | US14797635 | 2015-07-13 | US09426032B2 | 2016-08-23 | Jack E. Caveney; Ronald A. Nordin; Shahriar B. Allen |
| An intelligent network patch field management system is provided that includes active electronic hardware, firmware, mechanical assemblies, cables, and software that guide, monitor, and report on the process of connecting and disconnecting patch cords plugs in an interconnect or cross-connect patching environment. The system is also capable of monitoring patch cord connections to detect insertions or removals of patch cords or plugs. In addition, the system can map embodiments of patch fields. | ||||||
| 37 | Terminal-fitted wire manufacturing method | US13813724 | 2011-07-28 | US09331399B2 | 2016-05-03 | Akira Itou; Kouichirou Goto |
| It is aimed to enable a heat shrinkable tube to be mounted on a connected part of a core exposed portion of a wire and a terminal with high positioning accuracy. A terminal-fitted wire manufacturing method is for mounting a heat shrinkable tube on a connected part of a core exposed portion of a wire and a terminal. After the wire is inserted into the heat shrinkable tube, the terminal is connected to the core exposed portion. Thereafter, the heat shrinkable tube is moved to a position for covering the connected part of the core exposed portion and the terminal, and a part of the heat shrinkable tube is temporarily fixed to at least parts of the wire and the terminal. Thereafter, the heat shrinkable tube is mounted by being heated and thermally shrunk. | ||||||
| 38 | Intelligent patching system | US14081443 | 2013-11-15 | US09083088B2 | 2015-07-14 | Jack E. Caveney; Ronald A. Nordin; Shahriar B. Allen |
| An intelligent network patch field management system is provided that includes active electronic hardware, firmware, mechanical assemblies, cables, and software that guide, monitor, and report on the process of connecting and disconnecting patch cords plugs in an interconnect or cross-connect patching environment. The system is also capable of monitoring patch cord connections to detect insertions or removals of patch cords or plugs. In addition, the system can map embodiments of patch fields. | ||||||
| 39 | Integrated device architectures for electrochromic devices | US13758468 | 2013-02-04 | US09013777B2 | 2015-04-21 | Jonathan Mack Frey; Brian Spencer Berland |
| This disclosure describes systems and methods for creating monolithically integrated electrochromic devices which may be a flexible electrochromic device. Monolithic integration of thin film electrochromic devices may involve the electrical interconnection of multiple individual electrochromic devices through the creation of specific structures such as conductive pathway or insulating isolation trenches. | ||||||
| 40 | WALL GROMMET FOR POWER CONNECTION | US14447217 | 2014-07-30 | US20140361231A1 | 2014-12-11 | Daron Callahan; Peter M. Schneider; David Singer; Kenneth J. Buras |
| Provided is a wall grommet, which can be installed through the surfaces of walls to route wiring in the walls' interior spaces. In particular, the wall grommet is configured for running power cords inside walls and presenting the electrical connectors of a power cord in a manner such that power cords are hidden from view. The grommet may comprise a housing, which defines an interior space that is adapted to hold either the female connector or male connector of a power cord. The housing may be configured to enclose and secure the electrical connector of the power cord in the housing. | ||||||
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