The present disclosure describes a connection line for high currents and voltages, the connection line having an electrically conductive strand bundle enclosed by an electrically insulating cable sheath, and at least one compensation region for compensating angle tolerances, position tolerances and relative movements between two portions of the connection line. The cable sheath may be interrupted in the compensation region. The strand bundle may be widened in a spindle-like manner to form at least three arcuate strands.

A wire harness including: an electrical wire; and an exterior pipe through which the electrical wire is inserted, wherein the exterior pipe is provided with a plurality of discharge holes configured to outwardly discharge foreign matter that has entered between the exterior pipe and the electrical wire. An exterior pipe through which an electrical wire is to be inserted, the exterior pipe including: a body with a plurality of discharge holes configured to outwardly discharge foreign matter that has entered between the body and the electrical wire, wherein the plurality of discharge holes are provided in an aligned arrangement.

A fabric wrapped cable is formed by positioning adhesive on opposed layers of fabric. A cable is positioned between those layers and the layers are attached by attaching the adhesive of one layer to the adhesive of the other layer. In forming the wrapped cable in such a manner, the cable is provided with at least one wing.

The present disclosure includes a cable for a patient monitoring system. The cable can have a flexible and durable overall construction that enables the cable to withstand repeated winding and unwinding and prevent kinks from developing. The cable may include multiple bundles encased in inner jackets that reduce the amount of friction against other cable elements and allows the bundle to move more freely inside an outer jacket of the cable. The multiple bundles may include multiple wires or cords. The cable can include a flexible core that runs through the middle of the cable. The multiple bundles can be twisted, weaved, or untwisted around the core.

Aspects of the technology relate to rotational electromechanical systems, in which data and or power are supplied to components while one part of the system is rotating relative to another part of the system. Repeated rotation may create strain on or otherwise cause the cables to intermittently or permanently fail. A helical cable management system is provided that enables full rotation to the extent permitted. One or more cables are wound in a helical shape around the axis of rotation, which distributes the deformation of the cable along the helical length. Rotation in one direction causes the helix diameter to increase, while rotation in the other direction causes the helix diameter to decrease. A structure is used to maintain the distance between helical turns, while permitting the increase and decrease of the helix diameter. This reduces the overall strain on the cables, which can significantly extend their useful lifetime.

A cable that may withstand an increased pulling load may include a plurality of twisted pairs of individually insulated conductors and a metallic pulling element positioned within an outer jacket layer. The metallic pulling element may longitudinally extend parallel to the twisted pairs, and the pulling element may have an elastic modulus greater than that of the twisted pair conductors. As a result of incorporating the metallic pulling element, the cable can withstand a pulling force of 330N with an elongation of less than 0.20 percent.

Aspects of the technology relate to rotational electromechanical systems, in which data and or power are supplied to components while one part of the system is rotating relative to another part of the system. Repeated rotation may create strain on or otherwise cause the cables to intermittently or permanently fail. A helical cable management system is provided that enables full rotation to the extent permitted. One or more cables are wound in a helical shape around the axis of rotation, which distributes the deformation of the cable along the helical length. Rotation in one direction causes the helix diameter to increase, while rotation in the other direction causes the helix diameter to decrease. A structure is used to maintain the distance between helical turns, while permitting the increase and decrease of the helix diameter. This reduces the overall strain on the cables, which can significantly extend their useful lifetime.

A non-metallic cable includes at least two circuit conductors each disposed within a first insulator, a grounding conductor, and a first jacket in which the at least two circuit conductors and the grounding conductor extend. The non-metallic cable further includes two control conductors, each control conductor disposed within a second insulator, and a second jacket made from a thermoplastic material in which the two control conductors extend. The first jacket is connected to the second jacket.

Cables, cable connectors, and support structures for cantilever package and/or cable attachment may be fabricated using additive processes, such as a coldspray technique, for integrated circuit assemblies. In one embodiment, cable connectors may be additively fabricated directly on an electronic substrate. In another embodiment, seam lines of cables and/or between cables and cable connectors may be additively fused. In a further embodiment, integrated circuit assembly attachment and/or cable attachment support structures may be additively formed on an integrated circuit assembly.

A flat cable includes: a plurality of conductors arranged in parallel; an insulating layer formed, on first surfaces of the plurality of conductors and on second surfaces that are opposite surfaces of the first surfaces, along the plurality of conductors; an exposed portion where the first surfaces at end portions of the conductors are exposed to outside; and a reinforcement plate formed on the second surfaces opposite to the exposed portion. On the second surfaces opposite to the exposed portion, the reinforcement plate is directly formed on the conductors, and on the second surfaces opposite to the first surfaces that are in continuous with the exposed portion, the reinforcement plate is formed between the conductors and the insulating layer on the second surfaces.