A connector assembly comprises a first connector and a second connector. The first connector consists of a first monolithically formed conductive terminal adapted to be soldered onto a first circuit board. The second connector consists of a second monolithically formed conductive terminal adapted to be soldered onto a second circuit board. The first connector mates with the second connector to electrically connect the first circuit board to the second circuit board.

An electrical contact for use in connecting electrical wires is disclosed. The electrical contact includes a cage-like structure, a wire connecting portion, and a flexing contact portion. The cage-like structure includes a plurality of sidewalls and is configured to receive a wire. The wire connecting contact portion includes at least two contact tines that are configured to conductively couple with a corresponding wire. The flexing contact portion includes an end wall, an elastic portion, an extension portion, and a nose portion. The flexing contact portion can store elastic energy and apply a force to a corresponding electrical component.

A single element electrical connector includes a single conductive contact element formed into a cage structure having a wire insert end and a wire contact end along a longitudinal centerline axis of the connector. The cage structure defines an upper pick-up surface having a surface area suitable for placement of a suction nozzle of a vacuum transfer device, as well as a pair of contact tines biased towards the centerline axis to define a contact pinch point for an exposed core of a wire inserted into the connector. A contact surface is defined by a member of the cage structure for electrical mating contact with a respective contact element on a component on which the connector is mounted.

A terminal-thermistor assembly may include a thermistor and a terminal. The thermistor may include a body encasing a temperature-sensing element. The terminal may include a shaft and a housing disposed on an end of the shaft. The housing may include a cavity, a protrusion extending into the cavity and a cantilevered spring element. The spring element may be resiliently flexible between a first position in which a space between the spring element and the protrusion is less than a thickness of the body of the thermistor and a second position in which the space between the spring element and the protrusion is equal to the thickness of the body. A first surface of the thermistor body may contact the spring element and a second surface of the thermistor body opposite the first surface may contact the protrusion when the body is received within the cavity.

Embodiments herein are directed to a wire spring terminal including a main contact body having a base and a set of sidewalls defining a central cavity, a first spring contact extending from the base into the central cavity, and a second spring contact extending from one of the sidewalls into the central cavity, wherein the first and second spring contacts are configured to engage a wire inserted into the main contact body. In some embodiments, the wire spring terminal includes a third spring contact extending from the base into the central cavity, and a fourth spring contact extending from another one of the set of sidewalls into the central cavity, the third and fourth spring contacts configured to engage a wire. The first and third spring contacts may be arranged side-by-side, separated by a slot. The second and fourth spring contacts are also arranged side-by-side, separated by another slot.

An inter-battery connection device for connecting electrode terminals of a plurality of batteries comprises a housing, a bus bar attached to the housing, and a movable member attached to the housing. The bus bar electrically connects two electrode terminals of a pair of batteries adjacent to each other. The bus bar includes a pair of clips each contacting one electrode terminal and a coupling portion connecting the pair of clips. The movable member is movable between a temporary catching position attached to the housing and a final catching position attached to the housing. The movable member has a clip contact avoiding portion preventing contact between one of the clips and the electrode terminal in the temporary catching position and permitting contact between the clip and the electrode terminal during movement from the temporary catching position to the final catching position.

A conductor terminal with an insulating material housing and a spring-force terminal connection. The spring-force terminal connection has a contact body which is shaped out of a sheet element and has a base portion, lateral wall portions that protrude from the base portion and are mutually spaced, and solder connection contact tongues. The base portion together with the lateral wall portions forms a conductor receiving channel for receiving an electric conductor, and leaf spring tongues protrude from the lateral wall portions so as to face one another, each leaf spring tongue has a clamping edge for clamping an electric conductor received in the conductor receiving channel. The insulating material housing has a conductor insertion opening which leads to the conductor receiving channel on the front face.

The present description discloses a battery pack capable of being detachably attached to an apparatus including an apparatus terminal having a flat plate-like shape by sliding the battery pack in a sliding direction along the apparatus terminal. The battery pack includes a battery terminal capable of engaging with the apparatus terminal so as to be electrically connected therewith. The battery terminal includes a pair of elastic clamping pieces configured to receive the apparatus terminal when the battery pack is attached to the apparatus and to clamp the apparatus terminal from both sides of the apparatus terminal. In the battery pack, the pair of the elastic clamping pieces extends in a direction perpendicular to the sliding direction.

The present invention provides an electrical connector, comprising a shuttle member for receiving a stripped multi-core cable (such as a twin and earth conductor cable), the shuttle member including a core guide means and a resilient clip member for each of the stripped cores to be received. A body portion is configured to support at least one shuttle member in sliding engagement and includes an array of terminal connections, each connection having a shaped contact to receive a respective clip member of the shuttle member. Each shaped contact defines a jaw member operable to compress a respective clip member when the shuttle member is fully engaged with the body portion to thereby grip the stripped cores of the multi-core cable. The electrical connector has particular application as an electrical junction box for lighting circuits.

The invention relates to an electrical contact for a conductor terminal that has an insulating material housing, wherein the contact has a terminal section for connection to an electrical conductor, wherein the terminal section has a spring force clamping connection with at least one clamping spring for connection of the electrical conductor under spring force. The invention also relates to a conductor terminal having at least one such electrical contact.