The present disclosure relates to an integrated multipole connector, and more particularly, an integrated multipole connector that can be used as a multipole connector integrating a plurality of connectors to which different current capacities and shielding structures are applied.

To allow an electronic control unit to be replaced with good work efficiency and prevent foreign matter from entering a casing during maintenance work, the connector connection structure includes an internal connector positioned inside a casing, an external connector positioned outside the casing and an electronic control unit electrically connected between the external connector and the electronic control unit wherein the electronic control unit includes a main part that opposes an opening formed in the casing when the internal connector is connected thereto, and a first conductive connection portion and a second conductive connection portion provided on either end of the main part and configured to be connected to the internal connector and the external connector respectively, and a first seal member is provided on an outer periphery of the main part, the first seal member closing the opening when the external connector is not connected to the electronic control unit and the internal connector is connected to the electronic control unit.

An arrangement for producing an electrically conductive connection between a first machine element and a second machine element, comprising an electrically conductive disk which is secured to a supporting body, wherein the disk is provided with a bore for receiving a second machine element, wherein slots are introduced into the disk starting from the peripheral edge of the bore.

Devices and methods for a sealed electrical connector are described herein. Some embodiments include a spring connecting a first PCB to a second PCB, wherein the spring includes a first end portion in contact with the first PCB, a second end portion in contact with the second PCB, and a middle portion extending between the first end portion and the second end portion, a spacer surrounding the middle portion of the spring, a first seal seated in a first groove of the spacer and in contact with the first PCB, and a second seal seated in a second groove of the spacer and in contact with the second PCB.

A connector is provided with a sealing member to be sandwiched between a first housing and a second housing. The sealing member includes a sealing hole penetrating through a sealing body portion in a front-rear direction and a positioning recess formed in a front surface of the sealing body portion. The second housing includes a pre-fitting member and a post-fitting member separate from the pre-fitting member. The pre-fitting member includes a pre-fitting body portion to be arranged in front of the sealing body portion and a positioning projection projecting from a rear surface of the pre-fitting body portion and to be fit into the positioning recess. The post-fitting member includes a peripheral wall portion to be held in contact with an outer peripheral surface of the sealing member.

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.

An electrical pin and sleeve device is disclosed. The pin and sleeve device incorporating one or more features to facilitate easier assembly. For example, the pin and sleeve device may include an interrupted thread or a multi-start thread for coupling a first or main housing portion to a second or front housing portion of the device. In this manner, the outer housing can be assembled together with minimal number of turns to facilitate easier and faster assembly. Additionally, and/or alternatively, the front housing portion and the main housing portion may include a key such as, for example, a releasable lock (e.g., a spring plunger assembly) for indexing/indicating the proper rotational position of the front housing relative to the main housing to limit or prevent over-rotation. Additionally, and/or alternatively, a hollow O-ring may be positioned between the first and second housing portions.

Provided is a connector module that is highly durable and that also allows easy position alignment with a connection target instrument while maintaining high shielding performance. The connector module includes a connector case and a connector inserted in the connector case. The connector includes a contact, a holder, a conductive tubular shell, a housing and a conductive shield case. The shield case includes a first member having an elastic portion and a second member in the form of a bottomed tube. The first member forms an elastic piece contactable with the second member. Fixing of the connector case to a main body case via a fastener member causes, in the connector, elastic deformation of the elastic piece, resulting in decrease in a gap between the first member and the second member, consequently in establishment of electrical connection between the first member and the second member.

The disclosure relates to an electrical plug connector, comprising two housing parts, which are connected in a sealing manner on flat contact surfaces. A first housing part is, on its contact surface, equipped with an annular sealing edge directed at the opposite housing part. A second housing part is, on its contact surface, equipped with an annular seal corresponding to the sealing edge. The housing parts may be unreleasably connected to one another at multiple locations radially outside the seal and the sealing edge.

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.