The present invention relates to an improved insulated conductor with a low dielectric constant and reduced materials costs. The conductor (12) extends along a longitudinal axis and an insulation (14, 14<1>) surrounds the conductor (12). At least on channel (16, 16<1>) in the insulation (14, 14<1>) extends generally along the longitudinal axis to form an insulated conductor. Apparatuses and methods of manufacturing the improved insulated conductors are also disclosed.

The present invention relates to an improved insulated conductor with a low dielectric constant and reduced materials costs. The conductor (12) extends along a longitudinal axis and an insulation (14, 14<1>) surrounds the conductor (12). At least on channel (16, 16<1>) in the insulation (14, 14<1>) extends generally along the longitudinal axis to form an insulated conductor. Apparatuses and methods of manufacturing the improved insulated conductors are also disclosed.

A cable device has a first connector, a connecting cable and at least one electrical component. The connecting cable has at least one signaling yarn and a first textile. The at least one signaling yarn is arranged within the first textile and has a supporting material having a strength of 26 through 40 strands. One end of the at least one signaling yarn is electrically connected to the first connector, and one end of the first textile is connected to the first connector. The electric signals are propagated between the at least one electrical component and the first connector, and the at least one electrical component is electrically connected to the other end of the at least one signaling yarn and connected to the other end of the first textile.

Twisted pair data communication cables with modified delay skew values to improve electrical performance are disclosed. Methods of making and using the cables are also disclosed.

Twisted pair data communication cables with modified delay skew values to improve electrical performance are disclosed. Methods of making and using the cables are also disclosed.

The present disclosure relates to a high-pressure feedthrough for feeding through a coaxial cable from a low-pressure zone into a high-pressure zone, wherein the high-pressure feedthrough has a support structure having at least one elongate bore that extends from a low-pressure side of the support structure up to a high-pressure side of the support structure; wherein the elongate bore is suitable for receiving at least the inner conductor of a coaxial cable that can be continuously fed through the elongate bore from the low-pressure side to the high-pressure side; and wherein the high-pressure feedthrough has one or more components that serve in the axial direction of the elongate bore as an outer conductor and/or dielectric of the inner conductor of the coaxial cable fed through the elongate bore.

The present disclosure relates to a high-pressure feedthrough for feeding through a coaxial cable from a low-pressure zone into a high-pressure zone, wherein the high-pressure feedthrough has a support structure having at least one elongate bore that extends from a low-pressure side of the support structure up to a high-pressure side of the support structure; wherein the elongate bore is suitable for receiving at least the inner conductor of a coaxial cable that can be continuously fed through the elongate bore from the low-pressure side to the high-pressure side; and wherein the high-pressure feedthrough has one or more components that serve in the axial direction of the elongate bore as an outer conductor and/or dielectric of the inner conductor of the coaxial cable fed through the elongate bore.

A differential transmission cable module used for transmitting a differential signal between electronic devices. The module includes a cable including one inner conductor, a dielectric covering the inner conductor, and an outer conductor covering the dielectric, a sending-end substrate provided at one end of the cable, and a receiving-end substrate provided at an other end of the cable. The sending-end substrate includes two sending-end signal conductors, a sending-end ground conductor, and a sending-end signal converter for converting a differential signal transmitted through the sending-end conductors into a differential signal transmitted through the inner and outer conductors. The receiving-end substrate includes two receiving-end signal conductors, a receiving-end ground conductor, and a receiving-end signal converter for converting the differential signal transmitted through the inner and outer conductors into a differential signal transmitted through the receiving-end conductors. The cable transmits a differential signal by the inner and outer conductors.

A differential transmission cable module used for transmitting a differential signal between electronic devices. The module includes a cable including one inner conductor, a dielectric covering the inner conductor, and an outer conductor covering the dielectric, a sending-end substrate provided at one end of the cable, and a receiving-end substrate provided at an other end of the cable. The sending-end substrate includes two sending-end signal conductors, a sending-end ground conductor, and a sending-end signal converter for converting a differential signal transmitted through the sending-end conductors into a differential signal transmitted through the inner and outer conductors. The receiving-end substrate includes two receiving-end signal conductors, a receiving-end ground conductor, and a receiving-end signal converter for converting the differential signal transmitted through the inner and outer conductors into a differential signal transmitted through the receiving-end conductors. The cable transmits a differential signal by the inner and outer conductors.

A power cable having a central ground conductor. Phase interweave power conductors are positioned about the central ground conductor. Individual phase interweave power conductors have the same diameter. The individual phase interweave power conductors have a cross sectional area which is optimized. Each of the individual phase interweave power conductors is configured to support 100% cross sectional usage to maximize power carrying capability. The power cable reduces the skin effect of the power cable and the proximity effect of the power cable.