A cable splice includes a casing, a jaw assembly, a biasing member, a guide, and a bullet cup. The casing has an opening and an interior cavity. The jaw assembly is positioned in the interior cavity and moveable between a loading position and a terminated position. The biasing member biases the jaw assembly towards the terminated position. The guide includes a receiving end and a shaft extending at least partially into the interior cavity.

An arc-resistant electrical terminal includes a mount portion and a wire receiving portion formed of an electrically conductive material. The wire receiving portion is configured to be crimped onto a wire. The mount portion includes a solid tongue having opposing face surfaces. An aperture is formed between the opposing face surfaces for connecting the terminal to a connection point. A layer of insulation material is formed on at least a portion of the tongue for preventing arcing at a connection point. A raised boss is formed to surround the aperture on at least one of the opposing face surfaces of the tongue, the raised boss providing an electrically conductive surface of the terminal free from the layer of insulation material for connection to a connection point.

Bend radius adapters can be used to form connections between low-gauge electrical wires or cables, and can provide greater flexibility in the manner in which low-gauge electrical wiring or structures with equivalent load capacity can be routed through and within electrical systems and associated structures. For example, when electrical systems are being upgraded or repaired, it may be difficult or impossible to route lower-gauge or additional wiring through existing structures such as conduits and junction boxes without violating safety standards regarding the minimum bend radius of such wiring. The use of bend radius adapters can provide additional flexibility in utilizing existing electrical system structures, and can simplify installation of other electrical components.

Disclosed is an antenna device having a contact structure, and the antenna device includes: a radiator formed on a carrier; a printed circuit board having a power supply module configured to supply a power supply signal to the radiator; and a first contact structure configured to electrically connect the radiator and the printed circuit board, wherein the first contact structure includes: a conductive gasket formed with a through hole therein, installed on the radiator to be fixed onto the radiator; a torsion suppression member inserted into the conductive gasket through the through hole to suppress the torsion of the conductive gasket; and a separation suppression member extending from the radiator along an outer wall of one side of the conductive gasket in a height direction of the conductive gasket to suppress the separation of the conductive gasket.

A bus bar assembly includes a nonconductive terminal cap configured to at least partially surround an electrically conductive terminal. The terminal cap has a perimeter wall configured to circumscribe at least a portion of the terminal to provide a gap configured to expose the terminal. The terminal cap includes a first attachment feature. The bus bar assembly also includes a bus bar having an end configured to mechanically and electrically engage the terminal in an assembled condition and a nonconductive shroud enclosing the bus bar. The shroud includes a second attachment feature configured to removably engage the first attachment feature in the assembled condition to secure the shroud to the terminal cap. A method of electrically connecting cells of a battery is also provided.

A bus bar assembly includes a nonconductive terminal cap configured to at least partially surround an electrically conductive terminal. The terminal cap has a perimeter wall configured to circumscribe at least a portion of the terminal to provide a gap configured to expose the terminal. The terminal cap includes a first attachment feature. The bus bar assembly also includes a bus bar having an end configured to mechanically and electrically engage the terminal in an assembled condition and a nonconductive shroud enclosing the bus bar. The shroud includes a second attachment feature configured to removably engage the first attachment feature in the assembled condition to secure the shroud to the terminal cap. A method of electrically connecting cells of a battery is also provided.

A tail poking cover connector with a cage-type conducting mechanism comprises a front housing and a rear housing; a front open chamber is arranged in the rear housing; the front housing is used for closing the front open chamber; the cage-type conducting mechanism is arranged in the front open chamber, and the cage-type conducting mechanism comprises a conducting frame and a conducting component; the conducting frame comprises an inclined vertical part, an upper transverse part and a lower transverse part; and ports are formed in the inclined vertical part, the upper transverse part is provided with conducting heads extending backwards to the position above the lower transverse part, and clamping grooves are formed at the top of the lower transverse part.

A battery distribution unit (BDU) for holding a first electronic device having a first blade terminal extending therefrom and a second electronic device having a second blade terminal extending therefrom includes a BDU housing, a strip busbar received in the BDU housing, and first and second cross terminals received in the BDU housing. The first cross terminal receives the strip busbar at a first end thereof and is configured to receive the first blade terminal at a second end thereof. The second cross terminal receives the strip busbar at a first end thereof and is configured to receive the second blade terminal at a second end thereof.

A battery distribution unit (BDU) for holding a first electronic device having a first blade terminal extending therefrom and a second electronic device having a second blade terminal extending therefrom includes a BDU housing, a strip busbar received in the BDU housing, and first and second cross terminals received in the BDU housing. The first cross terminal receives the strip busbar at a first end thereof and is configured to receive the first blade terminal at a second end thereof. The second cross terminal receives the strip busbar at a first end thereof and is configured to receive the second blade terminal at a second end thereof.

A connector, a light source module including the connector, and a light source module array including the light source module array are provided. The connector includes a first connection part configured to connect to a first wire inserted thereto; a second connection part configured to connect to a second wire inserted thereto, the first and second connection parts being disposed to face in opposite directions; a housing covering the first and second connection parts; and a push button configured to be actuated by an external force applied thereto to release a connection of the first connection part to the first wire and a connection of the second connection part to the second wire.