Provided is a flexible flat cable with no secondary processing adhesives. The flexible flat cable with no secondary processing adhesives includes a plurality of parallel arranged conductors, two insulation layers and two shielding layers. The two insulation layers have respective inner surfaces oppositely positioned to be adhered to sandwich the parallel arranged conductors. The two shielding layers are respectively adhered on respective outer surfaces of the two insulation layers. At least one of the inner surfaces or at least one of the outer surfaces of the two insulation layers is modified to have a modified surface layer possessing adhesibility.

The present disclosure relates to a flat electric wire and a method for manufacturing a flat electric wire. The flat electric wire includes a plurality of conductors arranged in parallel in a width direction and having substantially a same cross-sectional area with each other, resin films provided on one side and the other side of the plurality of conductors in a thickness direction orthogonal to the width direction, and an insulator covering the plurality of conductors together with the resin films. Each of the resin films have a Young's modulus of 2 GPa or more and a film thickness of 200 m or more.

A ribbon cable is described, including a first insulative layer extending along a length and a width of the cable, and a plurality of spaced apart substantially parallel conductors extending along the length of the cable. The insulative layer has opposing top and bottom major surfaces and defines a plurality of spaced apart cavities extending between the top and bottom major surfaces of the first insulative layer. The top major surface of the first insulative layer is deformed in a plurality of spaced apart substantially parallel regions extending along the length, and arranged along the width, of the cable. Each deformed region has a shape of a groove and includes a deformed portion of at least one cavity in the plurality of cavities. Each conductor is disposed within a corresponding deformed region of the insulative layer.

A shielded flat cable includes conductors arranged parallel to each other and respectively having a first surface and a second surface opposite to the first surface, a first insulator provided on the first surface of each of the conductors, and a second insulator provided on the second surface of each of the conductors. The first surface of each of the conductors includes an exposed surface at an end part along a longitudinal direction. The shielded flat cable further includes a shield member that includes a metal layer and is configured to cover the first insulator and a portion of the exposed surface of the first surface, via a resin layer.

The present invention discloses a flat cable, which comprises signal unit sets and the insulating layer which wraps and fixes the signal unit set. The signal unit set is formed by at least two signals units arranged substantially on the same plane at an interval or side by side. The left and right sides of the signal unit set are directly wrapped by insulating layers. The insulating layer is formed by splicing and bonding at least one insulating film, and the splicing points at two ends of the insulating film are located on the upper side or the lower side of the signal unit set. In the flat cable of the present invention, the length of the overlapping portion can be set as required, effectively preventing the phenomenon such as insulating film tear and short circuit caused by insulating film tear.

A flat electrical cable is described. The cable includes a plurality of equally spaced substantially parallel electrical conductors lying in a same plane and extending along the length of the cable. Each conductor has a same diameter D. The cable further includes a common unitary electrically insulating layer encapsulating the plurality of conductors. The insulating layer includes a plurality of cover portions where each cover portion is concentric with a corresponding conductor and has a radial thickness t. t/D is in a range from about 0.50 to about 1.25.

A long straight high-frequency transmission cable includes a plurality of transmission wires, at least one ground wire, first and second insulating laminates, and first and second shielding layers. The transmission wires and the ground wire are parallel to each other. The first insulating laminate and the second insulating laminate are laminated with each other to cover the transmission wires and the ground wire. The first shielding layer and the second shielding layer are respectively laminated on the first insulating laminate and the second insulating laminate. The first insulating laminate has a plurality of first conductive plugs separately arranged along a length direction of the ground wire, and each two adjacent ones of the first conductive plugs have a spacing therebetween that is at least greater than 50 mm.

A transmission line includes first and second conductor patterns that serve as signal transmission paths, first and second insulating layers that hold the first and second conductor patterns therebetween, and a third conductor pattern that is arranged between the first and second conductor patterns. No signal is transmitted through the third conductor pattern. A relation 0.5wS11.5w and a relation 0.5wS21.5w are satisfied in a range of a relation S2w, wherein S expresses a distance between the first conductor pattern and the second conductor pattern, w expresses a width of each of the first conductor pattern and the second conductor pattern, S1 expresses a distance between the first conductor pattern and the third conductor pattern, and S2 expresses a distance between the second conductor pattern and the third conductor pattern.

A circuit module includes an interposer, and the interposer includes an element body including a first surface, a first interposer terminal provided on the first surface of the element body, and connected to a first external element, a second interposer terminal provided on the first surface of the element body, and connected to a second external element, a first wiring provided in the element body, and electrically connecting the first interposer terminal and the circuit board with each other, a second wiring provided in the element body, and electrically connecting the second interposer terminal and the circuit board with each other, and a bypass wiring provided in the element body and/or on a surface of the element body, and electrically connecting the first interposer terminal and the second interposer terminal with each other.

A composite cable assembly includes flat cables, a cable unit and fastening units. Each flat cable includes conductor assemblies and a shielding layer covering the conductor assemblies. The cable unit includes transmission lines. The transmission lines are arranged horizontally and in contact with the shielding layer of the flat cable closest to the transmission lines. The cable unit contacts the flat cable closest to the cable unit, the cable unit and each flat cable are together bent to form bent portions and extension sections connected to the bent portions. Each two fastening units are arranged spaced apart at two sides of a corresponding bent portion. Each extension section has the same length when the cable unit and each flat cable are moved in a movement direction to extend or collapse.