Patent application number | Description | Published |
20110067903 | BUNDLED FLEXIBLE FLAT CIRCUIT CABLE - A bundled flexible flat circuit cable includes a flexible substrate that forms at least one cluster section having an end forming at least one first connection section and an opposite end forming at least one second connection section. Both the first and second connection sections or one of the first and second connection sections form a stack structure. The flexible substrate can be of a structure of single-sided or double-sided substrate and may additionally include an electromagnetic shielding layer. A bundling structure is provided to bundle the cluster section at a predetermined location to form a bundled structure. The bundling structure can be made of a shielding material, an insulation material, or a combination of shielding material and insulation material. | 03-24-2011 |
20110094775 | DOUBLE-SIDE-CONDUCTING FLEXIBLE-CIRCUIT FLAT CABLE WITH CLUSTER SECTION - Disclosed is a double-side-conducting flexible-circuit flat cable with cluster section, which includes a flexible circuit substrate, a first electrical conduction path, a second electrical conduction path, a plurality of first and second conductive contact zones. The flexible circuit substrate has a first surface and a second surface and includes, in an extension direction, a first connection section, a cluster section, and at least one second connection section. The cluster section is composed of a plurality of clustered flat cable components formed by slitting in the extension direction. The first and second electrical conduction paths are respectively formed on the first and second surfaces of the flexible circuit substrate and each extends along one of the clustered flat cable components of the cluster section. The plurality of first and second conductive contact zones are respectively arranged on the first and second surfaces of the flexible circuit substrate at the first connection section. Each of the first and second conductive contact zones extends along one of the electrical conduction paths of the cluster section toward the second connection section. | 04-28-2011 |
20110094790 | FLEXIBLE FLAT CIRCUIT CABLE WITH GAPPED SECTION - A flexible flat circuit cable includes first and second flexible circuit substrates extending in an extension direction. The first flexible circuit substrate has a first surface forming a first conductor layer and an insulation layer, and the second flexible circuit substrate has a first surface forming a second conductor layer and an insulation layer. A bonding material layer is applied at a predetermined section between the first flexible circuit substrate and the second flexible circuit substrate to bond the first and second flexible circuit substrates together in such a way to maintain a predetermined spacing distance between the first and second flexible circuit substrate and forming a gapped segment at sections where no bonding material is applied. The first and second flexible circuit substrates form a cluster section within the gapped segment, which has opposite ends respectively forming first and second connected sections each of which forms a connection plug or is provided with a connector. | 04-28-2011 |
20110159724 | WIRE INSERTION AND CONNECTION STRUCTURE - A wire insertion and connection structure includes a plurality of wires that extends in a substantially parallel manner. Each wire includes a conductor and an insulation layer enclosing the conductor. Each wire has an end forming an insertion end, and each conductor has a portion exposed outside the respective insertion end to form a conductive engagement section. The insertion ends of the wires are coupled to an insertion assisting unit. The insertion assisting unit forms a plurality of positioning slots, which is distributed in a surface of the insertion assisting unit in a substantially parallel manner and spaced from each other by insulation sections. The conductive engagement sections of the conductors are respectively positionable in the positioning slots, whereby when the insertion ends of the wires and the insertion assisting unit are inserted into a receiving compartment defined in a connector, the conductive engagement sections of the conductors of the wires are respectively positioned on and engaging metal conductive elements received and set inside the receiving compartment of the connector. | 06-30-2011 |
20110197553 | CABLE BUNDLING DEVICE - A cable bundling device includes a cable positioning and a wrapping mechanism. The cable positioning mechanism includes a first clamping member and a second clamping member, which are set in a working zone. The first and second clamping members function to respectively clamp ends of a cable. One of the wrapping mechanism and the cable positioning mechanism is selectively rotatable to have the bundling material loaded in the wrapping mechanism wrapped around the cable. | 08-18-2011 |
20110266050 | CABLE BUNDLING STRUCTURE IN SLIDABLE ENGAGEMENT WITH CABLE - A cable bundling structure is provided for being set in slidable engagement with a target cable. The cable bundling structure includes a helical wrap member, which wraps around a wrapped section of the target cable. The helical wrap member is selectively composed of one or more sections of wrapping turns and each section is made in a one-piece form having a predetermined wrap width, a predetermined helix angle, and a predetermined wrap diameter and extending a predetermined length in a wrapping direction. The helical wrap member helically wraps around the target cable in such a way that the helical wrap member is in slidable engagement with the target cable and serves as an external protection for the cable. The helical wrap member can be made of an insulation material or an electromagnetic shielding material, whereby besides structural protection of the cable for improving resistance against bending, the external protection formed by the helical wrap member also provides protection against electromagnetic interference (EMI). | 11-03-2011 |
20120142218 | STRUCTURE OF ELECTROMAGNETIC WAVE RESISTANT CONNECTOR FOR FLEXIBLE CIRCUIT CABLE - Disclosed is a structure of electromagnetic wave resistant connector for flexible flat cable. A flexible flat cable defines an insertion device mounting section to which an insertion device is mounted. The insertion device includes a metal member that is at least partly formed of a metal material. The flexible flat cable forms thereon conductive traces on which an insulation layer is provided. The insulation layer has a surface, which forms, in at least a portion thereof, a conductive shielding layer. The conductive shielding layer extends to the insertion device mounting section, so that when the insertion device is mounted to the insertion device mounting section, electrical connection is formed between the metal member of the insertion device and the conductive shielding layer. | 06-07-2012 |
20120247811 | COMPOSITE CIRCUIT BOARD WITH FRACTURABLE STRUCTURE - A composite circuit board with fracturable structure includes a first flat cable and first signal transmission lines formed on the first flat cable. A second flat cable is stacked on and bonded to the first circuit flat cable. The second flat cable includes second signal transmission lines and forms an overlapping segment and a selective breakable segment between which a fracturable structure is formed. The selective breakable segment covers the connection segment of the first flat cable or may be broken off for separation of the flat cables. Some of the second signal transmission lines of the second flat cable are connected through a hole in the first circuit flat cable to the first signal transmission lines of the first flat cable or connected through the hole to the conductive terminals of the connection segment of the first flat cable. | 10-04-2012 |
20120267156 | MULTILAYER STACKED CIRCUIT ARRANGEMENT WITH LOCALIZED SEPARATION SECTION - A multilayer stacked circuit arrangement with localized separation section, has a first flat cable and first signal transmission lines arranged on the first flat cable. A second flat cable is stacked on and bonded to the first flat cable. The second flat cable further has signal transmission lines arranged on it. A bonding substance layer is formed between a first non-separation section of the first flat cable and a second non-separation section of the second flat cable for properly stacking the first and second flat cables where the separation sections are spaced apart from each other. A conductive via extends between the first non-separation section and the second non-separation section. At least some of the second signal transmission lines of the second flat cable are connected through the conductive via to the first signal transmission lines of the first flat cable. | 10-25-2012 |
20120325526 | BUNDLED FLEXIBLE FLAT CIRCUIT CABLE - A bundled flexible flat circuit cable includes a flexible substrate that forms at least one cluster section having an end forming at least one first connection section and an opposite end forming at least one second connection section. Both the first and second connection sections or one of the first and second connection sections form a stack structure. The flexible substrate can be of a structure of single-sided or double-sided substrate and may additionally include an electromagnetic shielding layer. A bundling structure is provided to bundle the cluster section at a predetermined location to form a bundled structure. The bundling structure can be made of a shielding material, an insulation material, or a combination of shielding material and insulation material. | 12-27-2012 |
20120325527 | BUNDLED FLEXIBLE FLAT CIRCUIT CABLE - A bundled flexible flat circuit cable includes a flexible substrate that forms at least one cluster section having an end forming at least one first connection section and an opposite end forming at least one second connection section. Both the first and second connection sections or one of the first and second connection sections form a stack structure. The flexible substrate can be of a structure of single-sided or double-sided substrate and may additionally include an electromagnetic shielding layer. A bundling structure is provided to bundle the cluster section at a predetermined location to form a bundled structure. The bundling structure can be made of a shielding material, an insulation material, or a combination of shielding material and insulation material. | 12-27-2012 |
20130020122 | CABLE BUNDLING STRUCTURE IN SLIDABLE ENGAGEMENT WITH CABLE - A cable bundling structure is provided for being set in slidable engagement with a target cable. The cable bundling structure includes a helical wrap member, which wraps around a wrapped section of the target cable. The helical wrap member is selectively composed of one or more sections of wrapping turns and each section is made in a one-piece form having a predetermined wrap width, a predetermined helix angle, and a predetermined wrap diameter and extending a predetermined length in a wrapping direction. The helical wrap member helically wraps around the target cable in such a way that the helical wrap member is in slidable engagement with the target cable and serves as an external protection for the cable. The helical wrap member can be made of an insulation material or an electromagnetic shielding material, whereby besides structural protection of the cable for improving resistance against bending, the external protection formed by the helical wrap member also provides protection against electromagnetic interference (EMI). | 01-24-2013 |
20130277095 | DOUBLE-SIDE-CONDUCTING FLEXIBLE-CIRCUIT FLAT CABLE WITH CLUSTER SECTION - Disclosed is a double-side-conducting flexible-circuit flat cable with cluster section, which includes a flexible circuit substrate, a first electrical conduction path, a second electrical conduction path, a plurality of first and second conductive contact zones. The flexible circuit substrate has a first surface and a second surface and includes, in an extension direction, a first connection section, a cluster section, and at least one second connection section. The cluster section is composed of a plurality of clustered flat cable components formed by slitting in the extension direction. The first and second electrical conduction paths are respectively formed on the first and second surfaces of the flexible circuit substrate and each extends along one of the clustered flat cable components of the cluster section. The plurality of first and second conductive contact zones are respectively arranged on the first and second surfaces of the flexible circuit substrate at the first connection section. Each of the first and second conductive contact zones extends along one of the electrical conduction paths of the cluster section toward the second connection section. | 10-24-2013 |
20140057482 | CONNECTION STRUCTURE FOR FLEXIBLE CIRCUIT CABLE - A connection structure for a flexible circuit cable includes a flexible circuit cable that has a flexible circuit substrate having a first end bonded to a soldering stage of the connector housing with first finger pad conductive contacts of conductive lines of the flexible circuit cable respectively corresponding to cable soldering sections of metal conductive terminals of the connector. A soldering layer is formed between a metal coating layer of the first finger pad conductive contact of each of the conductive lines and the cable soldering section of the corresponding metal conductive terminals to set the conductive lines of the flexible circuit cable in electrical connection with the metal conductive terminals of the connector. | 02-27-2014 |
20140285280 | GROUNDING PATTERN STRUCTURE FOR HIGH-FREQUENCY CONNECTION PAD OF CIRCUIT BOARD - Disclosed is a grounding pattern structure for high-frequency connection pads of a circuit board. A substrate of the circuit board includes a component surface on which at least a pair of high-frequency connection pads. At least a pair of differential mode signal lines are formed on the substrate and connected to the high-frequency connection pads. The grounding surface of the substrate includes a grounding layer formed at a location corresponding to the differential mode signal lines. The grounding surface of the substrate includes a grounding pattern structure formed thereon to correspond to a location adjacent to the high-frequency connection pads. The grounding pattern structure is electrically connected to the grounding layer. The component surface of the substrate can be provided with a connector mounted thereto with signal terminals of the connector soldered to the high-frequency connection pads. | 09-25-2014 |
20140318833 | ATTENUATION REDUCTION GROUNDING PATTERN STRUCTURE FOR CONNECTION PADS OF FLEXIBLE CIRCUIT BOARD - An attenuation reduction grounding pattern structure for connection pads of a flexible circuit board includes a plurality of high frequency connection pads formed on a component surface of a substrate and a plurality of differential mode signal lines arranged on the substrate and connected to the high frequency connection pads. The substrate has a grounding surface forming a grounding layer. The grounding layer includes an attenuation reduction grounding pattern structure formed at a location corresponding to the transition zone and including a hollowed area and a protruded portion. The protruded portion extends a predetermined length in a direction from the grounding layer toward the high frequency connection pads and along the adjacent high frequency connection pads to reach the transition zone. The protruded portion and the high frequency connection pads form a polarization-direction-varying electric field in the transition zone. | 10-30-2014 |
20140375394 | ATTENUATION REDUCTION CONTROL STRUCTURE FOR HIGH-FREQUENCY SIGNAL TRANSMISSION LINES OF FLEXIBLE CIRCUIT BOARD - An attenuation reduction control structure for high-frequency signal transmission lines of a flexible circuit board includes an impedance control layer formed on a surface of a substrate. The impedance control layer includes an attenuation reduction pattern that is arranged in an extension direction of the high-frequency signal transmission lines of the substrate and corresponds to bottom angle structures of the high-frequency signal transmission lines in order to improve attenuation of a high-frequency signal transmitted through the high-frequency signal transmission lines. An opposite surface of the substrate includes a conductive shielding layer formed thereon. The conductive shielding layer is formed with an attenuation reduction pattern corresponding to top angle structures of the high-frequency signal transmission lines. | 12-25-2014 |
20150017818 | METHOD AND STRUCTURE OF PENETRATION AND COMBINATION FOR FLEXIBLE CIRCUIT BOARD WITH HINGE ASSEMBLY - Disclosed are a method and a structure of penetration and combination for a flexible circuit board with a hinge assembly. A pre-formed flexible circuit board is processed by taking a pre-folding line as a center line to fold a connection section of the flexible circuit board toward the terminal distribution section. Then, the connection section is rolled in a direction toward the terminal distribution section so as to make the connection section forming a rolled body. The rolled body is then put through the bore of the hinge assembly to have the rolled body completely extend through the bore of the hinge assembly so that the extension section of the flexible circuit board is positioned in the bore of the hinge assembly and the first end and the second end are respectively located at opposite sides of the bore of the hinge assembly. | 01-15-2015 |
20150029685 | PENETRATION AND ASSEMBLY STRUCTURE FOR FLEXIBLE CIRCUIT BOARD WITH HINGE ASSEMBLY - Disclosed is a penetration and assembly structure for a flexible circuit board with a hinge assembly. With a pre-folding line formed on a pre-prepared flexible circuit board serving as a center line, a connection section of the flexible circuit board is folded to a terminal distribution section, and then, the connection section and an extended sheet are wound up in a direction towards the terminal distribution section to form the connection section into a rolled body with the extended sheet wrapped around the rolled body to provide an effect of protection. The rolled body is then inserted through a bore of a hinge assembly so that after the rolled body completely passes through the bore of the hinge assembly, the extension section of the flexible circuit board is located in the bore of the hinge assembly and the first end and the second end are respectively set at opposite ends of the bore of the hinge assembly. In other applications, a reinforcement plate is included to reinforce the terminal distribution section of the flexible circuit board. | 01-29-2015 |
Patent application number | Description | Published |
20100273348 | Flat signal transmission cable with bundling structure - Disclosed is a flat signal transmission cable with bundling structure, including at least one flexible circuit. The flexible circuit includes a plurality of clustered flat cable components that are formed by slitting in a direction parallel to extension direction of the flexible circuit to impose free and independent flexibility for bending to each clustered flat cable component. At least one bundling structure is formed on a lateral side edge of a predetermined clustered flat cable component of the cluster section of the flexible circuit. The bundling structure forms a fastening section. When the clustered flat cable components of the cluster section of the flexible circuit are stacked to form a bundled structure, the bundling structure bundles the plurality of clustered flat cable components and is secured by being fastened by the fastening section. | 10-28-2010 |
20100294556 | Flexible-circuit flat cable with cluster section - Disclosed is a flexible-circuit flat cable with cluster section, including at least one cluster section, at least one slip section, a first connection section, and a second connection section. The first connection section is set at a first end of the cluster section. The slip section has a first end connected to a second end of the cluster section and a second end at which the second connection section is set. The four sections are all provided with a plurality of signal transmission lines corresponding to and connecting each other. The first connection section and the second connection section are selectively provided with a connector or a plugging end. Further, the cluster section includes a cluster structure composed of a plurality of clustered flat cable components that are formed by slitting in a direction parallel to extension direction of a flexible circuit board to impose free and independent flexibility for bending to each clustered flat cable component. | 11-25-2010 |
20100326705 | Flexible-circuit-board cable with positioning structure for insertion - Provided is a flexible-circuit-board cable having a positioning structure. A connection zone is defined in a free end of the flexible-circuit-board cable and is provided with a plurality of conductive contacts. The connection zone has a first surface on which at least one projection section is formed and a second surface. A shielding layer overlaps the projection section and a portion of the first surface. The second surface of the connection zone is also bonded to a shielding layer. When the connection zone of the flexible-circuit-board cable is inserted into an insertion space defined in a connector, the first and second local zones of the connection zone formed by the shielding layers and the projection section are put into engagement with and thus positioned and retained by walls on opposite sides of the insertion space of the connector to thereby fix within the connector. | 12-30-2010 |
20110014811 | Shielded insertion and connection structure of flat cable connector - A shielded insertion and connection structure is provided for a flat cable connector, including a receiving housing and a hold-down member. The receiving housing forms a receiving compartment and two side walls formed at opposite ends of the receiving compartment. The hold-down member has opposite ends that respectively form pivot structures for pivotally coupling the hold-down member to the side walls and rotating between an open position and a holding position. The hold-down member is made of metal and the receiving housing is at least partly made of metal to form a conduction section, which is connected to a grounding terminal. When the hold-down member is at the open position and a circuit flat cable is inserted into the receiving compartment, the hold-down member is operated to depress down and hold the circuit flat cable and the hold-down member is put in electrical connection with the grounding terminal through the conduction section. | 01-20-2011 |
20110028017 | Circuit board based connector with raised projection section - Provided is a circuit board based connector with raised projection section, which is formed by applying substrate bonding and formation techniques to make a connector that features a raised projection section. The circuit substrate has an end that is provided with conductive terminals and an opposite end that is provided with flat cable connection terminals for connection with a flat cable. The circuit substrate has a first surface on which the projection section is formed. A shielding layer covers the projection section and a portion of the first surface. The circuit substrate has a second surface on which a second shielding layer is selectively formed. When the circuit substrate is inserted into an insertion space defined in a connection socket with the conductive terminals thereof, the shielding layer and the projection section of the circuit substrate are put into engagement with and thus retained by the insertion space of the connection socket to thereby fix within the connection socket. | 02-03-2011 |