A bus bar assembly for electrically connecting a plurality of battery cells having electrode leads is provided. The bus bar assembly includes a bus bar support frame having an opening; an insertion bus bar, the insertion bus bar being displaceable relative to the bus bar support frame in the opening; side-adhering bus bars positioned with the insertion bus bar being interposed therebetween to form fitting spaces respectively besides opposite sides of the insertion bus bar so that at least one electrode lead is insertable into each of the fitting spaces; and a support member configured to support the insertion bus bar at a location protruding further from the bus bar support frame than the side-adhering bus bars protrude from the bus bar support frame, the support member being elastically deformable by the insertion bus bar when the insertion bus bar is pressed.

A connection device for the connection of a conductor end includes a housing having a slotted link, a busbar section having a slotted link aligned with the housing slotted link, an d clamping spring assembly rotatably connected with the housing and operable between an open position and a contact position with the conductor end. A rotary lever assembly including a rotary lever element is operably connected with the clamping spring assembly. The rotary lever element has a cam section and a control curve section on which the clamping spring assembly slides during movement into the contact position. A clamping device is arranged on the cam section and is retained by the housing and busbar slotted links.

A connection device for the connection of a conductor end includes a housing, a busbar section arranged in the housing, and a clamping spring assembly rotatably connected with the housing and operable between an open position and a contact position in contact with the conductor end. A rotary lever assembly is operably connected with the clamping spring assembly. The clamping spring assembly includes at least one clamping spring having clamping and actuating limbs arranged at an acute angle and connected by a bending region bearing against a spring carrier. The clamping spring assembly is preferably preassembled on the spring carrier for insertion in the housing.

An electrical element holder includes a printed circuit board having a receiver. A resilient holder is electrically engaged with the receiver. The resilient holder includes a holding portion that is defined within an outward surface of the resilient holder and between opposing resilient arms. An electrical element is secured within the holding portion between the opposing resilient arms.

A novel connection terminal includes a housing, a contact assembly and a support member. The conductive clip is integrally bent and formed by spring steel plate, and two ends of a tongue forming section of the conductive clip are respectively connected to a supporting section and an approximately C-shaped cavity section by a pre-deformed elastic arch structure. Thus, the conductive clip and the bus bar form a clamping space in which the conducting wire can be more elastically crimped, ensuring that the conducting wire is firmly connected to the connection terminal assembly, allowing stable electrical connection between multiple conducting wires. The interior of the approximately C-shaped cavity section communicating with the wire passage enlarges the accommodating space for the conducting wire accordingly, facilitates the quick insertion of the conducting wire and provides more elastic and effective pressing force.

An electrical power tap connector for a model vehicle is provided including a first power tap housing. The first power tap housing may contain a power tap terminal configured to electrically couple with a connector terminal of an electrical connector. The power tap connector may also include a second power tap housing releasably securable to the first power tap housing and a releasable locking mechanism configured to physically secure the power tap connector to the electrical connector. Wherein the power tap terminal may be configured to electrically couple with the connector terminal via a non-mating end of the electrical connector.

A connection device for connecting a shield conductor of an electrical cable to a grounding section includes: a housing surrounding a receiving space into which an electrical cable is insertable with a shield conductor along a longitudinal axis, the housing being attachable to the grounding section such that the grounding section extends at least partly in the receiving space; and a spring element which is adjustably disposed on the housing and which has a clamping leg and is movable from an open position to a clamped position relative to the housing such that when in the clamped position, the spring element acts with the clamping leg on the shield conductor of the electrical cable inserted in the receiving space, the clamping leg having an engagement portion for acting on the shield conductor, the engagement portion having an at least partially curved or angled engagement contour.

A terminal block includes a housing having insulation properties, the housing having a holding portion provided in the housing and a terminal connection surface, a first opening portion through which a conductor portion of an electric wire can be inserted and pulled out and a second opening portion that is adjacent to the first opening portion and through which a jig can be inserted and pulled out being arranged in series in an array direction on the terminal connection surface and each communicating with the holding portion, and an opening surface being provided on a side of the holding portion in a width direction intersecting the array direction and a direction intersecting the terminal connection surface, and a terminal electrode portion and a leaf spring portion arranged in the holding portion. The housing is provided with a first movement restriction portion that restricts the movement of the moveable portion of the leaf spring portion in the width direction.

A contact insert for a connecting terminal, wherein the contact insert has a busbar piece and a clamping spring for clamping an electrical conductor in a conductor insertion direction, wherein the busbar piece and the clamping spring form a clamping point for the electrical conductor to be clamped, and wherein the contact insert has a bushing contact for receiving a contact pin. The longitudinal extension direction of the bushing contact runs essentially perpendicular to the conductor insertion direction from the busbar piece. The bushing contact is designed to receive the contact pin perpendicular to the longitudinal extension direction of the bushing contact and to receive the contact pin in the longitudinal extension direction of the bushing contact.

An electrical connector includes wiring with multiple wires. Each wire has a conductor covered in insulation. Each wire has a stripped portion that exposes the conductors. The stripped portions are stacked on top of one another. A housing has first and second housing portions that provide a cavity. The first housing portion receives the stripped portions. The second housing portion includes a spring that has a closed portion that extends into the cavity and is configured to urge the stripped portions into engagement with one another when the first and second housing portions are secured to another in an assembled connector condition.