A cable is provided, configured for tandem communication and power transmission. The cable has a plurality of twisted pair conductors and a jacket surrounding said twisted pair conductors. The jacket includes a plurality of either ridges, valleys or both, disposed substantially perpendicular to the longitudinal axis of the cable, the ridges and/or valleys are dimensioned and spaced apart in a manner sufficient to create an air passage when the cable is arranged adjacent to and abutting other cables.

A cable includes insulated conductors arranged in a spaced apart generally coplanar configuration. A jacket encapsulates the insulated conductors. The jacket has a generally rounded rectangular cross-section, at least one spline along a minor edge of the jacket, and at least one channel along a major edge. An armor layer is applied about the jacket.

A cable with a tactile twist indicator, wherein the cable has at least one core for signal transmission and a cable sheath surrounding the at least one core, wherein the cable has precisely one tactile twist indicator, which extends along a longitudinal direction of the cable over essentially the entire length of the cable sheath and which has a predetermined orientation relative to the at least one core over essentially the entire length of the cable sheath.

A photoelectric composite cable and a communication system. The photoelectric composite cable includes an optical unit, an electrical unit, and an outer jacket. The optical unit includes an optical fiber and a ferrule, and the ferrule is sleeved on the optical fiber. The electrical unit includes a wire and a wire jacket, and the wire jacket is sleeved on the wire. The outer jacket wraps outside the optical unit and the electrical unit, and the optical unit and the electrical unit are disposed closely adjacent to each other. An extension direction of the optical unit is consistent with an extension direction of the electrical unit, and at least one convex structure is disposed on an outer wall of the outer jacket.

A purpose of the present invention is to make a wiring member easy to bend in a suspension wiring module connecting a vehicle body-side device and a vehicle wheel-side device. This suspension wiring module comprises a suspension wiring member, which includes a transmission line main body and one or more covering layers covering the transmission line main body. At least one section of the suspension wiring member is a cabin-external section that is positioned outside of the cabin of the vehicle. In the cabin-external section, an arc-shaped groove is formed in an outer covering, which is the covering layer that is located furthest to the outside among the one or more covering layers.

Provided is an electric cable for a wind turbine, wherein the electric cable includes at least one cooling element) to cool the electric cable, wherein the cooling element protrudes from the surface of the electric cable.

A hybrid cable is provided that transmits both electrical power and optical signals. The hybrid cable has a transverse cross-sectional shape with multiple lobes and a generally circular outer boundary. At least some of the lobes surround and insulate the electrical conductors. The lobes surrounding the electrical conductors can be torn away from the remainder of the cable while continuing to insulate the electrical conductors.

A cable set includes a line run having a multiplicity of lines. A protective sheath surrounds the line run. A taping is disposed between the line run and the protective sheath. The taping surrounds the line run and has nubs projecting outward to the protective sheath. At least some of the nubs pass through the protective sheath. A winding tape for winding around a line run for producing a cable set and a method for producing a cable set are also provided.

Described are cables for connecting components of computing systems. The cables improve automation and resulting performance of high frequency and/or high speed signal transmissions by providing reliable transmission paths between hardware components. An example cable includes parallel conductors and a dielectric core that secures the parallel conductors along the length using parallel channels in opposite sides of the dielectric core. An alignment structure is also formed in the dielectric core, which has a shape along the length of the cable. A cable jacket surrounds the parallel conductors and the dielectric core. The cable jacket is contoured to follow the shape of the alignment structure. The dielectric core can be formed to maintain consistent separation between the parallel channels along the length of the cable to match impedance of the parallel conductors along the length of the cable, whether the cable lays flat or bends around corners.

A cable core including a body, a recess in the body, and a protrusion extending radially outwardly from the body and along the recess. A cladding disposed radially outwardly of the core is used to create a cable.