201 |
benjamin |
US302883D |
|
US302883A |
1884-08-05 |
|
|
202 |
Making joint-connections in electric cables |
US294546D |
|
US294546A |
1884-03-04 |
|
|
203 |
teask |
US293688D |
|
US293688A |
1884-02-19 |
|
|
204 |
goebel |
US290415D |
|
US290415A |
1883-12-18 |
|
|
205 |
Island |
US266171D |
|
US266171A |
1882-10-17 |
|
|
206 |
Edwaed a |
US235883D |
|
US235883A |
1880-12-28 |
|
|
207 |
Improvement in protection for underground telegraph-wires |
US144135D |
|
US144135A |
1873-10-28 |
|
|
208 |
Stretchable printed battery and methods of making |
US14563885 |
2014-12-08 |
US10003087B1 |
2018-06-19 |
Weifeng Liu; Dick Tak Shing Pang; Anwar Mohammed; Murad Kurwa |
A stretchable battery and the method of manufacturing the same. The stretchable battery can be manufactured by using a printing process. The construction of the stretchable battery can comprise a first layer of an elastomer film, a first current collector layer, a layer of cathode, a separating layer, a layer of anode, and a second current collector layer. Metal traces can be used to couple with the first and/or the second current collector layers. |
209 |
Systems, apparatus, and related methods for weather-proofed wire splicings |
US13966742 |
2013-08-14 |
US09559435B2 |
2017-01-31 |
Michael Joye |
Disclosed are systems, apparatus and related methods for making weather, fire, or water-proofed wire-to-wire electrical connections. |
210 |
WIRE HARNESS |
US14431889 |
2013-08-21 |
US20150287497A1 |
2015-10-08 |
Koki Shiga |
A wire harness prevents corrosion from occurring in a connection section at which a metal pipe and a metal braided section are connected to each other. The wire harness includes a metal pipe into which an electrical wire is inserted, a metal braided section that covers the electrical wire drawn out from the metal pipe and is formed by braiding metal bare wires that are made of a different type of metal from that of the metal pipe, and a joint pipe to one end of which the metal pipe is connected and to the other end of which the metal braided section is connected. The joint pipe is made of the same type of metal as the metal braided section or of an insulating material. |
211 |
WATERPROOF STRUCTURE FOR STOPPING WATER BETWEEN BARE WIRES OF MULTIPLE CIRCUITS |
US14661587 |
2015-03-18 |
US20150279516A1 |
2015-10-01 |
Masataka WAKABAYASHI; Kazuto HASEGAWA |
A waterproof structure for stopping water between bare wires of multiple circuits stopping water between bare wires all together for plural covered wires is provided. It is provided with plural covered wires each of which has a stripped wire exposed part formed by removing a cover material in an intermediate portion thereof, and is folded over at the stripped wire exposed part; a non-electrically conductive wire support supporting plural covered wires so as to prevent short-circuits between the stripped wire exposed parts of plural covered wires; a container accommodating portions of plural covered wires supported by the wire support and the stripped wire exposed part; and a thermosetting waterproofing agent 40 filled into the container to immerse at least the stripped wire exposed parts of plural covered wires and cured to immerse the stripped wire exposed part and clearance between plural covered wires. |
212 |
Wire connecting device for connecting fiber-core conductor |
US13820827 |
2011-09-15 |
US09048549B2 |
2015-06-02 |
Hisashi Hanazaki |
A wire connecting device for connecting a fiber-core conductor configured by stranding a plurality of fiber-core conductive wires. The wire connecting device includes a vis having a rod-shape pin and a head extending outwardly from the pin. A plate-shape terminal connects with the vis by inserting the pin in an opening. The head matches up with an overlap portion of the terminal so that the fiber-core conductor is clamped between the head and the overlap portion of the terminal connect electrically the fiber-core conductor and the terminal. The conductor passes over and contacts an end portion of the pin. The pin and the inner surface of the opening are curved surfaces to eliminate sharp corners. |
213 |
SYSTEMS, APPARATUS, AND RELATED METHODS FOR WEATHER-PROOFED WIRE SPLICINGS |
US13966742 |
2013-08-14 |
US20150047871A1 |
2015-02-19 |
Michael Joye |
Disclosed are systems, apparatus and related methods for making weather, fire, or water-proofed wire-to-wire electrical connections. |
214 |
Medical cable connector for a medical lead providing an electrical receptacle that is movable relative to an outer body |
US13069077 |
2011-03-22 |
US08954163B2 |
2015-02-10 |
Daniel J. Stetson; Carole A. Tronnes; David W. Lee |
A medical cable connector of a medical cable receives a medical lead while an electrical receptacle within the medical cable connector is placed into a distal position relative to an outer body of the medical cable connector. The electrical receptacle is retracted to a proximal position once insertion of the medical lead into the medical cable connector is completed. The electrical receptacle may be mounted to an inner body which moves relative to the outer body. A biasing member may be present to bias the inner body to a particular position. A slider may be present to provide a clinician with a surface to touch when applying force to position the electrical receptacle in the distal position for insertion of the medical lead. Various other features may be present to facilitate insertion of the medical lead and/or to maintain the position of the electrical receptacle relative to the outer body. |
215 |
ELECTRICALLY CONDUCTIVE PIN CONNECTION |
US14297079 |
2014-06-05 |
US20140345131A1 |
2014-11-27 |
Guenther STOECKMANN; Wilfried BAUCH; Axel KRANICH; Juergen OTTEN |
The present disclosure relates to an electrically conductive pin connection, including a first electrically conductive contact component which has a first hole, a second electrically conductive contact component which is in contact with the first electrically conductive contact component and which has a second hole, a connecting pin which has a pin head and which is guided through the first and second holes for connecting the first electrically conductive contact component and the second electrically conductive contact component, and a plurality of electrically conductive wires which are arranged in the holes between the edges of the holes and the connecting pin, wherein the electrically conductive wires are bent in such a way that they are clamped between the pin head of the connecting pin and the first electrically conductive contact component. |
216 |
METHODS AND APPARATUS FOR OPTIMIZING ELECTRICALLY INOPERATIVE ZONES ON LAMINATED COMPOSITE ASSEMBLIES |
US13804575 |
2013-03-14 |
US20140262499A1 |
2014-09-18 |
James S. Smith; James D. Duford; Stephane Eisen; James D. Jore; Brian Sullivan |
In some embodiments, a system includes a first portion, a second portion, and a third portion of an electrical conductor. Each portion is electrically coupled to the other two portions. The first, second, and third portions are configured such that substantially no current induced in and/or supplied to the first portion is conducted to the third portion of the electrical conductor. The third portion of the electrical conductor is also thermally coupled to the first and second portions of the electrical conductor. The third portion of the electrical conductor is configured to transfer thermal energy from the first portion of the electrical conductor to an edge portion of the laminated composite assembly. |
217 |
TERMINAL STRUCTURE OF BRAIDED WIRE AND TERMINAL PROCESSING METHOD FOR BRAIDED WIRE |
US14141826 |
2013-12-27 |
US20140110165A1 |
2014-04-24 |
Kohki Ishikawa; Takamitsu Noguchi; Shigeru Ishikawa |
In a terminal structure of a braided wire, in which a terminal of the braided wire (42) is interposed between an inner ferrule (26) and an outer ferrule (25) and the outer ferrule (25) is caulked inwardly, the inner ferrule (26) includes at least one first groove (264) along an axial direction of the inner ferrule (26) and the outer ferrule (25) is recessed along the first groove (264) of the inner ferrule (26). |
218 |
SERIALLY CONNECTED MICRO-INVERTER SYSTEM WITH TRUNK AND DROP CABLING |
US14031763 |
2013-09-19 |
US20140077609A1 |
2014-03-20 |
Martin Fornage |
A system and apparatus for serially coupling a plurality of inverters. In one embodiment, the apparatus comprises a cable assembly for (i) coupling the plurality of inverters in series to form a string, and (ii) coupling AC power generated by the plurality of inverters to the AC grid, wherein the cable assembly comprises (A) a trunk cable comprising at least one phase conductor and a neutral conductor, wherein the neutral conductor is conductively continuous throughout the trunk cable; and (B) a plurality of junction boxes, positioned at locations along the trunk cable, for coupling the plurality of inverters to the trunk cable, wherein at each junction box of the plurality of junction boxes the at least one phase conductor is discontinuous for being coupled to a corresponding inverter of the plurality of inverters. |
219 |
MULTI-CORE CABLE ASSEMBLY |
US13937496 |
2013-07-09 |
US20140014410A1 |
2014-01-16 |
Masato TANAKA |
A multi-core cable assembly is formed by arranging a plurality of cables side by side and connecting the cables to a substrate 30 which is a connection member. The plurality of cables configure flat cable units 10, 20 for each diameter of cables, and ground bars 16, 27 are fixed thereto so as to be electrically connected with a shield member included in the cable. Each of ground bars 16, 27 are electrically connected to a ground pad 31 of the substrate 30. The ground bars 16, 27 adjacent to each other are disposed to be shifted in a longitudinal direction of the cable. In addition, two ground bars 16, 27 interposing the other one ground bar and positioned at both sides thereof are disposed in a position overlapped in the longitudinal direction of the cables. |
220 |
Cable lug with shell-shaped part and fastening device |
US13520276 |
2010-10-26 |
US08540535B2 |
2013-09-24 |
Sebastian Martens; Martin Schloms; Franz-Josef Lietz |
The invention relates to a method and a system for fastening a round conductor 200 to a connection element 100, 100′, 100″, comprising a connection element 100, 100′, 100″ that comprises at one end an at least partially shell-shaped part 110, and a round conductor 200 closed with a contact element 210, the contact element 210 being adapted to contact the connection element 100, 100′, 100″, and a fastening device 400, 510, 520, 610, 620, 660, 710, 810, which is adapted to fasten in a frictional manner (force-fit) an end region 210 of the round conductor 200 lying in front of the contact element 210 in the region of the shell-shaped part 110 of the connection element 100, 100′, 100″, to the connection element 100, 100′, 100″. |