A cable includes a cable core including a linear filler, and a plurality of core wires for signal transmission, a shield layer covering around the cable core, and a sheath covering around the shield layer. The filler includes a first filler provided at a cable center, and a plurality of second fillers provided around the first filler to form a cross-shape with the first filler in a cross-section perpendicular to a cable longitudinal direction. The cable core is configured in such a manner that the plurality of core wires and the plurality of second fillers are spirally twisted around the first filler to be alternately arranged in a circumferential direction.

Disclosed is a non-steel strength membered high strength cable easily monitored for heat and elongation comprising a length of a core-cable (10), the length of core-cable (10) including at least two fiber-optic conductors (2) that are: (i) disposed in a helical shape; and (ii) completely encased in a solid, flexible material.
One fiber-optic conductor capable of transmitting at least Raman backscattering and the other fiber-optic conductor capable of transmitting at least Brillouin scattering.

A combination of the cable (10): (i) with an interrogator that can read and interpret Raman backscattering coupled to and communicating with the fiber optic conductor that is capable of transmitting at least Raman backscattering; and (ii) another interrogator that can read and interpret Brillouin scattering coupled to and communicating with the fiber optic conductor that is capable of transmitting at least Brillouin scattering;
permits ascertaining the elongation of the cable, without using loose tube fiber-opticplacement.

The present invention provides a movable cable, which has strength that is at least equal to conventional movable cables while having excellent flexural fatigue resistance and flexibility as well as being lightweight. This movable cable 10 has an electric conductor therein. The conductor comprises a first conductor 2 made of a specific aluminum alloy material wherein: the alloy composition contains, in mass %, 0.05-1.8% Mg, 0.01-2.0% Si, 0.01-1.5% Fe, and at least a total of 0.00-2.00% of one element selected from the group consisting of Cu, Ag, Zn, Ni, Co, Au, Mn, Cr, V, Zr, Ti and Sn, the balance being Al and unavoidable impurities; the crystal grains have a fiber-like metal structure in which the crystal grains all extend in one direction; and in a cross-section parallel to the one direction, the average crystal grain dimension perpendicular to the longitudinal direction is 400 nm or less. The ratio X of the area of the first conductor 2 in the whole conductor of the movable cable 10 is in the range of 10-100%.

This disclosure describes electric vehicle supply equipment (EVSE) assemblies for use when charging plug-in electrified vehicles. An exemplary EVSE assembly may include a charger coupler and a cable connected to the charger coupler. The cable may include a plurality of conductor wires and a gap extrusion positioned within a gap between the plurality of conductor wires. The gap extrusion may include a non-symmetrical cross-sectional shape and may be made of a thermoplastic elastomer (TPE) material. The cable may be manufactured in a staggered extrusion process in which the gap extrusion is fed into a gap of a wound conductor wire bunch of the cable.

An assembly for supporting and retracting machine cables, thereby protecting operational components attached to machine cables. A cable organization system includes at least one modular cable management module fixed to a mounting plate that allows mounting of the cable organization system to a machine or other surface. The system has clamps which secure machine cables. The clamps are supported on top of pivoting guide tubes. The cable management modules contain retraction systems which retract the machine cable clamps from an extended position. By utilizing retracting cable clamps on pivoting guide tubes, the system allows the use of operational components attached to secured machine cables, and organizes the machine cables, so that the machine cables do not extend out into the floor around the machine. The system redirects pulling force on the machine cables, so that operational components do not get pulled onto the floor if a passerby catches on a machine cable.

A cable is composed of a cable core including one or more electric wires, a braided shield covering a periphery of the cable core and including braided metal wires, a sheath covering a periphery of the braided shield, and a cushion layer provided between the cable core and the braided shield. The cushion layer is composed of a braid including braided linear shape fiber yarns.

An FFC coupling a sensor substrate and an AFE substrate includes a configuration in which a ground line is sandwiched between a first lead wire and a second lead wire that are signal lines that transmit a read signal from the sensor substrate to the AFE substrate, and includes a configuration in which a third lead wire having a smaller voltage change than the signal line is sandwiched between two signal lines that are at least one set other than a set of the first lead wire and the second lead wire, wherein each of the signal lines is coupled to a ground pattern of the sensor substrate and is coupled to a ground pattern of the AFE substrate, and the third lead wire is coupled to a ground pattern of the sensor substrate and is coupled to a ground pattern of the AFE substrate.

A cable includes a cable core including one or more electric wires, a shield layer covering around the cable core, and a sheath covering around the shield layer. The shield layer is composed of a braided shield including a plurality of first metal wires composed of aluminum or aluminum alloy and a plurality of second metal wires composed of copper or copper alloy. The plurality of first metal wires and the plurality of second metal wires are cross-braided.

A cable includes a cable core including a linear filler, and a plurality of core wires for signal transmission, a shield layer covering around the cable core, and a sheath covering around the shield layer. The filler includes a first filler provided at a cable center, and a plurality of second fillers provided around the first filler to form a cross-shape with the first filler in a cross-section perpendicular to a cable longitudinal direction. The cable corethe cable core is configured in such a manner that the plurality of core wires and the plurality of second fillers are spirally twisted around the first filler to be alternately arranged in a circumferential direction.

This disclosure describes electric vehicle supply equipment (EVSE) assemblies for use when charging plug-in electrified vehicles. An exemplary EVSE assembly may include a charger coupler and a cable connected to the charger coupler. The cable may include a plurality of conductor wires and a gap extrusion positioned within a gap between the plurality of conductor wires. The gap extrusion may include a non-symmetrical cross-sectional shape and may be made of a thermoplastic elastomer (TPE) material. The cable may be manufactured in a staggered extrusion process in which the gap extrusion is fed into a gap of a wound conductor wire bunch of the cable.