A grommet for use in a cable fitting includes a body having a bore substantially therethrough and a resilient membrane located within the bore. The resilient membrane is elastically deformable from a receiving position before the cable is inserted into the bore, to an inserted position, after the cable is fully inserted into the bore. In the receiving position, the resilient membrane is substantially conically shaped having an apex substantially coincident with an insertion opening of the body, and, the resilient membrane is axially displaced during the insertion of the cable to an inverted position with respect to the receiving position where the apex is oriented away from the insertion opening. The resilient membrane has a thinner membrane portion extending from the apex towards the bore to provide a controlled tear during cable insertion. The body has an exit opening which comprises resilient gripping teeth projecting axially from the body with an axially extending resilient foldable membrane located between at least two adjacent resilient teeth and foldable therebetween when they are radially compressed. Once force is applied by the axial movement of the fitting assembly onto a tapered surface of the grommet, the flexible gripping members radially collapse towards an inserted cable. The combination of the resilient membrane and the axially extending teeth separated by a foldable membrane allow for an increased friction fit and sealing interface on the cable. The grommet may be assembled in a strain relief connector having a nut, a connector body and optionally an insert. The insert has a removed section longitudinally coincident with a gripping surface facilitating movement of the gripping surface towards the cable.

A water resistant connector assembly includes first and second connectors. Each connector has a housing and a water resistant seal. Each connector is formed in a two-shot operation with the housing being formed of polypropylene and the seal being formed of a thermoplastic elastomer. The seal of one of the connectors has a portion that is provided on an outer surface thereof and has ribs which fold over in a direction opposite a water ingression direction when the second connector is connected to the first convector, thereby creating a seal between the connectors when they are connected. The seals of each of the connectors are also provided at terminal/wire insertion areas, and these seals ensure proper insertion of the terminal/wires. These seals may further include strain relief portions to provide resistance to angularity of the wire.

A contact point for establishing a connection to a conductor element according to the present disclosure comprises a flat conductor having first and second ends, and a contact element connected to the flat conductor in a terminal area of the flat conductor, wherein the contact element is also configured to connect to the conductor element. The contact point comprises a multi-shell housing attached to the flat conductor and configured to cover the contact element and the terminal area. The housing comprises at least three openings, wherein first and second openings enable passage of first and second ends of the flat conductor, and a third opening enables passage of the conductor element. A gasket is attached to at least one of the openings for sealing the housing.

A terminal assembly comprises a conductor and an electrical terminal having a connection area connected to the conductor. A seal of the terminal assembly seals the connection area in a fluid-tight manner. The seal is composed of a foamable sealing material which includes an activatable blowing agent.

A shield connector structure is provided that can increase the precision in the size of a connection portion of a shield electric wire and can improve the water-stop performance of the connection portion without being affected by the tolerance of the external diameter of a shield unit and an external insulating covering of the shield electric wire. A shield connector includes a connection member fixed to an outer surface of a metal case and a shield member connecting the connection member and a shield unit of a shield electric wire, and a shield pipe configured to fix an exposed portion of the shield unit to the shield member. A first tubular unit of the shield member is inserted between the exposed portion of the shield unit and an internal insulating covering.

A novel busbar, suitable for low-power applications, features a u-shaped extension having a male terminal that fits into and establishes electrical connection with a standard female terminal. The housing of an electrical box including the busbar is modified to receive the female terminal in such a way that Ingress Protection ratings of IP67 and IP69K are maintained within the electrical box. The busbar is not riveted to a thicker busbar terminating with a stud and lug nut, as in legacy configurations, thus being simpler and cheaper to manufacture. The female terminal, once connected to the busbar, is removable by inserting a tool into a dedicated opening within the housing.

The invention relates to a fuse holder comprising two housing elements which, once assembled, together form a tube in which a fuse is accommodated. The first housing element includes a base extending longitudinally along the direction of assembly of the two housing elements with each other. A seal is placed on the base mainly in a plane perpendicular to the direction of assembly. During assembly, the second housing element is brought to at least partially cover the base to sandwich the seal between the two housing elements. A rim extends around the base in the direction of assembly in order to protect the seal until the two housing elements are assembled together.

A connector (F) includes an inner housing (11) configured to accommodate terminal fittings (72). An outer housing (37) is separate from the inner housing (11) and is configured to surround the inner housing (11). A lock arm (17) is formed on an outer surface of the inner housing (11) and is configured to lock the inner housing (11) and a mating housing (80) in a connected state by being locked to the mating housing (80). Protecting portions (45, 46) are formed on the outer housing (37) and are arranged near a lock releasing portion (22) of the lock arm (17).

The present teachings provide for an electrical connector including a first housing, power terminals, and first and second shunts. The terminals and shunts are located within a cavity of defined by the first housing. The first housing is configured to mate with a second housing to transfer power between a power storage device and components of an electric or hybrid electric vehicle. The first shunt is configured to complete an interlock circuit. The second shunt is configured to complete a service disconnect circuit. The interlock circuit prevents the transfer of power between the first and second housings when the circuit is broken and allows it when complete. The service disconnect circuit causes the power storage device to be substantially electrically isolated from the rest of the vehicle when the circuit is broken.

A system (10) and method that facilitates the delivery of power and fiber communications together is provided. The system and method enables quick and easy connection of a hybrid cable (12) to telecommunication equipment. The system provides a sealed robust connection for both conductors (78, 80) and fibers (50) at a single location (56). It can be used to avoid the need for local powering of fiber based communication devices and networks.