An implantable medical device comprising a sealed flat housing enclosing an electronic circuitry; a plurality of feedthrough conductors, each feedthrough conductor comprising a proximal end part connected to the enclosed electronic circuitry and a distal end part extending from a side surface of the housing and cumulated on said side surface; a tubing that houses a plurality of wires connected to said feedthrough conductors and that is arranged on the housing; and a longitudinal slit through the wall of the tubing through which the wires extend out of the tubing.

Provided is a connector assembly for use in an implantable medical device. The connector assembly for use in an implantable medical device includes an insulating sealed housing and at least one conductive element. The sealed housing defines at least one connecting hole along an axial direction of the sealed housing, a hole wall of each of the at least one connecting hole defines at least one circumferential mounting groove, and the at least one circumferential mounting groove is arranged along an axial direction of the at least one connecting hole. The at least one conductive element is disposed in a corresponding one of the at least one circumferential mounting groove and is drawn out to an outside of the sealed housing through a respective electrical contact element.

An electrical connector for an electrical cable having a contact element for connection to an electrical conductor of the electrical cable. The electrical connector has an integrated cleaning tool for the electrical conductor. The cleaning tool is arranged along a feed direction for the electrical cable on the cable side upstream of the contact element. It is provided that the cleaning tool is designed to remove or at least retain particles, residues of a sheathing and/or contaminants adhering to the electrical conductor before the electrical conductor contacts the contact element of the electrical connector arranged downstream in the feed direction within the scope of a connector assembly process.

An electrical harness assembly for an agricultural implement includes multiple harness segments coupled to one another. Each harness segment includes a first connector, a second connector, and a third connector. In addition, the second connector of each harness segment is configured to directly couple to the first connector of a subsequent harness segment, the third connector of each harness segment is configured to couple to a respective row unit component, and each harness segment does not include a harness controller.

Provided are an electrical junction box for which the time required for production is short, and a method for manufacturing the electrical junction box. An electrical junction box houses an electric device. A plurality of external devices are connected to each other via the electric device housed in the electrical junction box. The electrical junction box includes a housing box and a connector. The housing box is provided with an insertion port 40 into which the connector is inserted, and an opposite opening that is opposite to the insertion port. The insertion port and the opposite opening have the same axial direction. Inside the housing box, a component can be attached to the connector.

Provided are an electrical junction box for which the time required for production is short, and a method for manufacturing the electrical junction box. An electrical junction box houses an electric device. A plurality of external devices are connected to each other via the electric device housed in the electrical junction box. The electrical junction box includes a housing box and a connector. The housing box is provided with an insertion port 40 into which the connector is inserted, and an opposite opening that is opposite to the insertion port. The insertion port and the opposite opening have the same axial direction. Inside the housing box, a component can be attached to the connector.

A turbogenerator includes a stator core defining a first end and a second end, a plurality of stator bars disposed within the stator core, each stator bar including a coolant flow path, and a parallel ring having a first segment and a second segment separate from the first segment. The parallel ring is coupled to the first end of the stator core and is arranged to electrically connect the plurality of stator bars and to fluidly connect the coolant flow paths of the plurality of stator bars. A tang includes a main chamber, a first coolant opening, a second coolant opening, and a distribution channel that fluidly interconnects the main chamber, the first coolant opening, and the second coolant opening. A first lead tube has a first lead end connected to the first coolant opening and a second lead end connected to the first segment, and a second lead tube separate from the first lead tube has a first lead end connected to the second coolant opening and a second lead end connected to the second segment. The plurality of stator bars, the parallel ring, the tang, the first lead tube, and the second lead tube cooperate to define a portion of a circuit and a portion of a cooling path.

A system includes a pair of terminal leads joined together. An insulative sleeve is wrapped around the pair of terminal leads. Lacing binds around the insulative sleeve. Cured epoxy can encase the insulative sleeve and lacing. The insulative sleeve can include fiberglass. The insulative sleeve can be wrapped more than 360° around the pair of terminal leads so that a first edge of the insulative sleeve is tucked under a second edge of the insulative sleeve.

An electrical power system including an electrical power connector, a contact configured to electrically connect a power supply to a load, a first sensor configured to sense a first characteristic of the electrical power connector, a second sensor configured to sense a second characteristic of the electrical power connector, and an electronic controller. The electronic controller configured to receive a first signal indicative of the first characteristic, receive a second signal indicative of the second characteristic, compare the first signal to a first threshold, compare the second signal to a second threshold, and dynamically adjust at least one selected from a group consisting of the first threshold and the second threshold. Wherein the dynamic adjustment is based on at least one selected from a group consisting of a measured or calculated parameter, an installation condition, an operational limit, a known operational behavior, and parameter threshold information.

An injection-molded support has a contact chamber adapted to receive a contact partner, a fixed seal part, a movable seal part shiftable relative to the fixed seal between an open position spaced therefrom and a closed position closely juxtaposed therewith, and a break point holding the movable seal part in the open position and frangible for movement of the movable seal part into the closed position. A cable end fitted between the seal parts into the chamber is clamped when the movable seal part is then moved from the open into the closed position with rupturing of the break element and is held in form-fitting clamping engagement of the cable end between the seal parts. Finally the cable end is overmolded with molding compound to the contact body outside the contact chamber while blocking entry of the compound by the seal parts into the contact chamber.