An electrical connector is disclosed which is particularly adapted to electrically and mechanically connect a main conductor to a bail or tap conductor. The connector includes a C-shaped frame having a curved top wall adapted to fit over a main conductor and a curved bottom wall adapted to receive a bail or tap conductor. A fastener-operated wedge assembly is carried within the frame between a conductor receiving position and a conductor clamping position. The wedge assembly has a wedge body with a primary contact surface adapted to contact the main conductor and a secondary contact surface adapted to contact the bail or tap conductor when the wedge body is moved from the conductor receiving position to the conductor clamping position. The fastener positively moves the wedge body between the positions so that the clamping action of the connector can be tightened or loosened as desired. A head portion of the fastener may include a breakaway feature to help prevent over tightening of the fastener.

A wedge connector system for connecting first and second elongate electrical conductors includes a C-shaped sleeve member, a wedge member, and an insert member. The sleeve member defines a sleeve cavity and opposed first and second sleeve channels on either side of the sleeve cavity. The wedge member includes a wedge body having first and second opposed wedge side walls. The insert member is configured to be selectively mounted in the first sleeve channel and defines an insert member channel to receive the first conductor when the insert member is mounted in the first sleeve channel. The sleeve member and the wedge member are configured to capture the first and second conductors such that: the first conductor is received in the insert member channel and captured between the sleeve member and the first wedge side wall; and the second conductor is captured between the sleeve member and the second wedge side wall.

An electrical connector is disclosed which is particularly adapted to electrically and mechanically connect a conductor to a terminal. The connector includes a C-shaped frame having a curved top wall adapted to fit over a conductor. A mounting surface with through holes for mechanical fastening to pad type equipment or fixture. A fastener-operated wedge assembly is carried within the frame between a conductor receiving position and a conductor clamping position. The wedge assembly has a wedge body with a contact surface adapted to contact the conductor when the wedge body is moved from the conductor receiving position to the conductor clamping position. The fastener positively moves the wedge body between the positions so that the clamping action of the connector can be tightened or loosened as desired. A head portion of the fastener may include a breakaway feature to help prevent overtightening of the fastener.

A cable assembly includes a cable, a connector-body, a cable-seal, and a retainer. The connector-body is attached to the cable. The cable-seal is disposed within the connector-body and surrounds the cable. The cable-seal is configured to inhibit entry of a contaminant into the connector-body. The retainer is in direct contact with the cable, the connector-body and the cable-seal. The retainer is configured to retain the cable-seal within the connector-body. The retainer is configured to be installed onto the cable and is attached to the connector-body. The retainer contains cable-clamps mounted to a pair of opposed inclined-surfaces located on an inner-surface of the retainer. The cable-clamps include inclined-ramps configured to engage the inclined-surfaces. The inclined-ramps move along the inclined-surfaces, thereby causing the cable-clamps to impart a radial-force normal to the cable when the retainer is attached to the connector-body.

Disclosed are a connector and a battery module. A connector according to an aspect of the present disclosure is a connector configured to electrically interconnect electrode leads of neighboring battery cells. The connector includes: a main body having a conductive material and having contact portions provided to face each other such that the leads of the neighboring battery cells are brought into contact with the contact portions, respectively; two or more push members disposed to be movable and to be spaced apart from each other between the contact portions so as to bring each of the electrode leads into contact with a corresponding contact portion among the contact portions; a core member disposed to be movable between the push members so as to bring the push members into close contact with corresponding contact portions, respectively; and a movement mechanism configured to move the core member in a second direction crossing a first direction in order to cause the push members in the first direction for close contact.

Various implementations of grounding cross connectors are disclosed. The grounding cross connectors may be used to clamp together two or more, often perpendicular, conductors. In some implementations, a grounding cross connector includes an upper clamping pad and a lower clamping pad held together by a pair of threaded fasteners. A pair of perpendicular conductors may be placed in between the clamping pads and secured together by torqueing nuts on the threaded fasteners. The upper clamping pad may include a hook through which one of the threaded fasteners may pass, thereby allowing the upper clamping to rotate relative to the lower clamping pad.

Various implementations of grounding cross connectors are disclosed. The grounding cross connectors may be used to clamp together two or more, often perpendicular, conductors. In some implementations, a grounding cross connector includes an upper clamping pad and a lower clamping pad held together by a pair of threaded fasteners. A pair of perpendicular conductors may be placed in between the clamping pads and secured together by torquing nuts on the threaded fasteners. The upper clamping pad may include a hook through which one of the threaded fasteners may pass, thereby allowing the upper clamping to rotate relative to the lower clamping pad.

A connector assembly includes a first-housing, a second-housing, and a seal. The second-housing is configured to mate with the first-housing. The second-housing has a seal-support surface having a first-surface and a second-surface perpendicular to the first-surface and generally forming an L-shape. The seal-support surface includes a plurality of seal-hangers projecting laterally from the first-surface. The seal is in direct contact with the seal-support surface. The seal defines a wall and a lip extending laterally from the wall. The wall defines an inner-surface that engages the first-surface and an outer-surface that engages the first-housing. The wall further defines a plurality of apertures configured to receive the plurality of seal-hangers. The lip defines a base that engages the second-surface and a top that engages a leading-edge of the first-housing. The plurality of seal-hangers are configured to inhibit bunching or rolling of the wall when the first-housing is mated with the second-housing.

An electrical connector includes two pads having the same shape. Each pad has a connector body with a first groove, a second groove, and a hole. The hole extends through the connector body between the first groove and the second groove. A fastener extends through the hole of both of the two pads so that the two pads having the same shape are connected to one another and are pivotable around the fastener relative to one another with the two first grooves contacting a first conductor when the first conductor is in an installed position and the two second grooves contacting a second conductor when the second conductor is in an installed position. A spring is between a first end of the fastener and one of the two pads having the same shape so that the spring biases the two pads having the same shape towards each other.