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 |
20120018196 | FLEXIBLE PRINTED CIRCUIT BOARD WITH WATERPROOF STRUCTURE - Disclosed is a flexible printed circuit board with waterproof structure, including a flexible substrate that has a first surface on which a first metal layer is bonded. The first metal layer has an upper surface forming a covered area and at least one mounting zone and the metal layer forms on a surface thereof within the mounting zone a bonding improved waterproof structure. A first insulation layer is formed on the covered area of the upper surface of the first metal layer in such a way not to cover the mounting zone of the first metal so as to expose the mounting zone. A water resistant member is securely mounted to the mounting zone of the first metal layer. The flexible substrate also has a second surface to which a second metal layer and a second insulation layer are mounted. The second metal layer also forms a mounting zone, which is not covered by the second insulation layer so as to expose for mounting the water resistant member. The metal surface inside the mounting zone also forms bonding improved waterproof structure. The waterproof structure improves the bonding strength between the flexible printed circuit board and the water resistant member through proper arrangement and selection of shape, size, and distribution density of holes that are defined in the exposed metal surface. Alternatively, the holes can be made completely through the metal layer in order to also feature control of impedance for high frequency signals. | 01-26-2012 |
20120139655 | ELECTRICAL IMPEDANCE PRECISION CONTROL OF SIGNAL TRANSMISSION LINE FOR CIRCUIT BOARD - Disclosed is a structure for precision control of electrical impedance of signal transmission circuit board. A substrate forms thereon a plurality of first signal transmission lines, and a first covering insulation layer is formed on a first surface of the substrate to cover a surface of each first signal transmission lines and each spacing section formed between adjacent first signal transmission lines. Each first signal transmission lines can transmit a differential mode signal or a common mode signal. At least one first flattening insulation layer is formed between a surface of the first covering insulation layer and a first conductive shielding layer so that the first flattening insulation layer fills up the height difference between the surface of each first signal transmission line and the spacing section associated with each first signal transmission line to thereby ensure a consistent distance between the signal transmission lines and the conductive shielding layer for realizing precision control of electrical impedance of the signal transmission circuit board. | 06-07-2012 |
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 |
20120149235 | DETACHMENT AND DISPLACEMENT PROTECTION STRUCTURE FOR INSERTION OF FLEXIBLE CIRCUIT FLAT CABLE - Disclosed is a detachment and displacement protection structure for insertion of flexible circuit flat cable. An inserter positioning section is formed on a flexible circuit flat cable and coupled with an inserter, which includes a metal member and a plastic member. In assembling, the plastic member is first positioned on a first surface of the inserter positioning section of the flexible circuit flat cable, and then the metal member is fit over the plastic member. A detachment and displacement protection structure is provided on the inserter positioning section to constrain the inserter from displacing and detaching in a flat cable extension direction due to being acted upon by an external force when the inserter is positioned on the inserter positioning section. | 06-14-2012 |
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 |
20130269996 | STRUCTURE OF VIA HOLE OF ELECTRICAL CIRCUIT BOARD - A structure of via hole of electrical circuit board includes an adhesive layer and a conductor layer that are formed after wiring is formed on a carrier board. At least one through hole extends in a vertical direction through the carrier board, the wiring, the adhesive layer, and the conductor layer and forms a hole wall surface. The conductor layer shows a height difference with respect to an exposed zone of the circuit trace in the vertical direction. A conductive cover section covers the conductor layer and the hole wall surface of the through hole. The carrier board is a single-sided board, a double-sided board, a multi-layered board, or a combination thereof, and the single-sided board, the double-sided board, and multi-layered board can be flexible boards, rigid boards, or composite boards combining flexible and rigid boards. | 10-17-2013 |
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 |
20130312999 | FLEXIBLE CIRCUIT CABLE WITH AT LEAST TWO BUNDLED WIRE GROUPS - Disclosed is a flexible circuit cable with at least two bundled wire groups. The circuit cable has first and second ends respectively connected to first and second connection sections. The circuit cable includes a cluster section, which is formed of a plurality of cluster wires formed by slitting the circuit cable, in an extension direction of the cable, at a predetermined cut width. The cluster section includes at least two independent bundles, which are formed by dividing the cluster wires of the circuit cable into different signal groups according to electrical signals transmitted therethrough. Bundling members are used to the cluster wires of the independent bundles according to predetermined bundling modes. Further, the circuit cable has a surface forming a shielding conductive layer for electromagnetic interference protection and impedance control for internal signals of the circuit cable. | 11-28-2013 |
20130341072 | COMPOSITE FLEXIBLE CIRCUIT PLANAR CABLE - A composite flexible circuit planar cable includes a flat cable, a first section, and a second section. The flat cable includes a plurality of straight line like parallel and non-jumping conductor lines. At least one jumping line is formed on the first section to interchangeably connect a selected conductive line of the first section to an another selected conductive line. The second section may also form at least one jumping line to interchangeably connect a selected conductive line of the second section to an another selected conductive line. Through such a jumping line, electrical connection can be formed between signal terminals and corresponding and interchanged signal terminals. The plurality of conductor lines of the flat cable includes at least a pair of differential signal conductor lines, a grounding line, and a power line. | 12-26-2013 |
20140014409 | DIFFERENTIAL MODE SIGNAL TRANSMISSION MODULE - A differential mode signal transmission module includes a first section having an external connection end on which at least a pair of differential mode signal transmission terminals are formed and includes a grounding terminal, a first differential mode signal terminal, and a second differential mode signal terminal. The extension connection end of the first section forms a counterpart signal terminals corresponding to those of the external connection end. At least one first conductive connection line is formed on the first section. The conductive connection line connects the grounding terminal of the external connection end of the first section to a collective grounding point. The extension connection end of the first section is connected to an extension section. The extension section is further connected to a second section opposite to the first section. The extension section includes at least one slit line in order to form a bundled section. The first section, the second section, and the extension section include at least one fold line. | 01-16-2014 |
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 |
20140102763 | RIGID FLEXIBLE CIRCUIT BOARD WITH IMPEDANCE CONTROL - A rigid-flexible circuit board includes at least one flexible circuit board and at least one rigid circuit board. The flexible circuit board includes a flexible-board substrate, a plurality of flexible circuit board differential mode signal lines, at least one flexible circuit board grounding line, a flexible circuit board insulation layer formed on the upper surface of the flexible-board substrate and covering the flexible circuit board differential mode signal lines and the flexible circuit board grounding line. The rigid circuit board is stacked on the stacking section of the flexible circuit board. A shielding layer is formed on the flexible circuit board insulation layer of the flexible circuit board and corresponds to the extension section of the flexible circuit board. The shielding layer further extends from the extension section to the stacking section. An impedance control structure is formed on the shielding layer to control the impedance of the flexible circuit board differential mode signal lines. | 04-17-2014 |
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 |
20140290989 | STRUCTURE OF VIA HOLE OF ELECTRICAL CIRCUIT BOARD AND MANUFACTURING METHOD THEREOF - A structure of via hole of electrical circuit board includes an adhesive layer and a conductor layer that are formed after wiring is formed on a carrier board. At least one through hole extends in a vertical direction through the carrier board, the wiring, the adhesive layer, and the conductor layer and forms a hole wall surface. The conductor layer shows a height difference with respect to an exposed zone of the circuit trace in the vertical direction. A conductive cover section covers the conductor layer and the hole wall surface of the through hole. The carrier board is a single-sided board, a double-sided board, a multi-layered board, or a combination thereof, and the single-sided board, the double-sided board, and multi-layered board can be flexible boards, rigid boards, or composite boards combining flexible and rigid boards. | 10-02-2014 |
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 |
20140374148 | CONDUCTIVE CONNECTION STRUCTURE FOR CONDUCTIVE WIRING LAYER OF FLEXIBLE CIRCUIT BOARD - A conductive connection structure for a conductive wiring layer of a flexible circuit board includes a first through hole and a second through hole formed in a lamination structure including a conductive wiring layer, a first covering layer, and a second covering layer. The first through hole extends through the first covering layer and the conductive wiring layer. The second through hole extends through the second covering layer. The second through hole is formed at a location corresponding to an exposed zone on a second surface of the conductive wiring layer and communicates with the first through hole. A first conductive paste layer is formed on a surface of the first covering layer and fills in the first through hole to form a pillar portion in the first through hole. The pillar portion has a bottom end forming a curved cap. The exposed zone of the second surface of the conductive wiring layer is at least partially covered by the curved cap. | 12-25-2014 |
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 |
20150027751 | FLEXIBLE CIRCUIT BOARD WITH PLANARIZED COVER LAYER STRUCTURE - A planarized cover layer structure of a flexible circuit board includes an insulation layer bonded through a first adhesive layer to a surface of each one of conductive signal lines laid on a substrate of a flexible circuit board. Separation areas respectively formed between adjacent ones of the conductive signal lines are each formed with a filling layer, so that the filling layer provides the first adhesive layer with a planarization height in the separation areas and the planarization height is substantially equal to the height of the conductive signal lines. The filling layer can alternatively be of a height that is higher than the surface of the conductor layer by a covering height so that the first adhesive layer has a planarization height in the separation areas and the planarization height is substantially equal to the sum of the height of the conductive signal lines and the covering height. | 01-29-2015 |
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 |