A method for installing an elastomeric cover sleeve on an electrical connection including a connector and a cable having a cable axis includes: providing an installation tool including a slide portion; premounting the installation tool on the cable such that the slide portion extends along the cable axis and covers a portion of the cable; thereafter, sliding the cover sleeve onto the cable and onto the slide portion of the premounted installation tool to a parked position wherein the slide portion is interposed between the cover sleeve and the cable; installing the connector onto the cable; and thereafter, sliding the cover sleeve along the cable axis and the slide portion onto the connector.

A stimulation system includes an implantable pulse generator having a sealed chamber and an electronic subassembly disposed in the sealed chamber. Feed through pins are coupled to the electronic subassembly and extend out of the sealed chamber. Feed through interconnects are coupled to the electronic subassembly via the feed through pins. At least one tab is disposed on at least one feed through interconnect. The tab(s) are configured and arranged to flex away from the feed through interconnect and against a side of the feed through pin. A feed through interconnect assembly includes an assembly frame; feed through interconnects extending from the assembly frame; a first contact pad and a second contact pad disposed on at least one of the feed through interconnects; and a tab formed on a first contact pad of at least one of the feed through interconnects.

A termination for electrical cables may include: an outer insulation tubular body having a longitudinal axis; a conductive rod within the body; an elastomeric sleeve within the body and extending about an end portion of the rod; a connecting device within the sleeve, wherein the device is mechanically and electrically connected to the rod and is configured to mechanically and electrically connect to an electrical cable; a conductive tubular element within the body, configured to electrically connect to ground; a semi-conductive element within the tubular element and partially extending inside the sleeve on an opposite side to the rod with respect to the device; and at least one elastic conductive element radially interposed between, and in contact with, the tubular element and semi-conductive element, the at least one elastic conductive element configured to exert elastic force onto the semi-conductive element along at least one radial direction toward the axis.

The invention is characterized in that a HF coaxial cable is designed as a conventional corrugated sheath cable comprising a cable outer conductor, in the form of a metal corrugated tube, having a line impedance Z.sub.k and a minimum bending radius r.sub.k,min specified by the manufacturer as a characteristic feature of the coaxial cable; in corrugated sheath cable, directly or indirectly following the straight plug connector, is bent to have a bending radius r.sub.α, where 0.2 r.sub.k,min≦r.sub.α≦0.9 r.sub.k,min, which alters the line impedance Z.sub.k by a maximum of 1 ohm. The bend with the bending radius r.sub.α is produced by cold forming corrugated sheath cable with the introduction of bending forces and tensile forces directed along said corrugated sheath cable.

A power supply includes a housing, a power module, a top cover, a sealing sheet, and a filling member. The power module is disposed in the housing. The top cover is disposed above the housing. The sealing sheet is at least partially disposed between the housing and the top cover. The filling member is disposed between the housing and the sealing sheet.

A vehicle includes a traction battery having a plurality of battery cells positioned in an array with a non-conductive bus bar housing having a plurality of compartments insulated from one another and containing one or more bus bars each having an integrally formed voltage sense connector. Each compartment may accommodate terminals of a pair of adjacent battery cells to be coupled by the associated bus bar. The voltage sense connector may include fingers for crimping and securing a voltage sense wire or a welding pad for welding, soldering, or similar connection. The voltage sense wires connect to a battery control module.

A medical cable connector of a medical cable receives a medical lead while an electrical receptacle within the medical cable connector is placed into a distal position relative to an outer body of the medical cable connector. The electrical receptacle is retracted to a proximal position once insertion of the medical lead into the medical cable connector is completed. The electrical receptacle may be mounted to an inner body which moves relative to the outer body. A biasing member may be present to bias the inner body to a particular position. A slider may be present to provide a clinician with a surface to touch when applying force to position the electrical receptacle in the distal position for insertion of the medical lead. Various other features may be present to facilitate insertion of the medical lead and/or to maintain the position of the electrical receptacle relative to the outer body.

Examples disclosed herein generally relate to methods and apparatus for the insertion of one or more wires into a cavity of a fixture of a structure or component. The wire insertion apparatus includes a grommet, a gripper adapted to interface with the grommet, and at least a first vibrating element. The first vibrating element is connected to and vibrates one or more of the apparatus, the grommet, the gripper, the wire, and/or a component of the apparatus. Vibration, induced in any direction, enables the cavities to shift position during insertion relative to the contact, thus increasing the tolerance of the cavity, reducing the failure rate of wire insertion, and reducing total production time. The vibration breaks the static friction of the contact in the grommet or dielectric opening, creates the positive locating required to insert the contact in the grommet and/or dielectric, and/or pivots the contact.

An apparatus and method for crosstalk compensation in a jack of a modular communications connector includes a flexible printed circuit board connected to jack contacts and to connections to a network cable. The flexible printed circuit board includes conductive traces arranged as one or more couplings to provide crosstalk compensation.

Provided is a cable assembly backshell capable of three angular configurations: straight, 45°, and 90°. The backshell is designed to rotate at two joints that allow it to assume these three angular configurations. A locking mechanism is associated with the backshell which prevents unintended reconfigurations.