An electrical connection terminal includes a metal part having a contact leg and a fastening leg which is connected to the contact leg by a web, the fastening leg having a spring receiving portion which has an inner side, an outer side, and an opening arranged in the spring receiving portion, and the contact leg having a contact portion which has an inner side and an outer side. A clamping spring can be mounted on the metal part, the clamping spring having a spring leg which has an end portion, a ridge connected to the spring leg on a side of the spring leg which faces away from the end portion, and a holding leg connected to the ridge. The ridge has a first recess and the holding leg has a second recess. The holding leg includes two side clips arranged in parallel with one another.

A conductor connection terminal for connecting electrical conductors to each other, having an insulating material housing, which has a first housing section with a first spring-loaded clamping connection arranged in the first housing section, and a second housing section with a second spring-loaded clamping connection arranged in the second housing section. The first housing section can be swiveled relative to the second housing section and the conductor connection terminal has a busbar structure or the electrically conductive connection of the first spring-loaded clamping connection to the second spring-loaded clamping connection. The busbar structure has a first connection section assigned to the first spring-loaded clamping connection and a second connection section assigned to the second spring-loaded clamping connection. A hinged section connects the first connection section with the second connection section.

An electrical terminal is disclosed. The electrical terminal has a contact made of a first kind of metal and a coupling member made of a second kind of metal fixed to the contact. The coupling member has a crimping portion crimped to press the first contact against an electrical wire made of the first kind of metal.

A terminal connection structure has a housing, a base housed in the housing, and a terminal unit having a pair of tab terminals disposed on the base, a pair of terminal portions disposed in the tab terminals in parallel, each of which is exposed from the housing and configured to be connected to an external terminal, and a terminal plate sandwiched between the pair of tab terminals.

A multiple cable disconnect includes a housing having a separable mating end and a wire terminating end configured to receive wires of power cables. The housing has a plurality of terminal chambers with terminals therein. The terminals each have a base, a mating contact extending from the base and a wire contact extending from the base. The mating contact has a mating pad defining a separable mating interface for the terminal for mating with a corresponding mating terminal of the mating connector. The wire contact has plural wire interfaces for mating with plural wires such that plural wires are configured to be terminated to and commoned with each terminal. Wire retention springs are received in the housing each having at least one spring arm defining a wire trap with the corresponding wire contact. The spring arms are releasable to release the wires from the housing.

A connector is connectable with a conductive core of a cable which is inserted from a front of the connector along a front-rear direction. The connector comprises a shell and a spring member. The shell is made of a metal. The shell has an operation portion and a contact portion. The spring member is made of another metal which is harder than the metal of the shell. The spring member has an operated portion and a press portion. When the operation portion moves the operated portion, the press portion is moved away from the contact portion. The press portion presses the conductive core against the contact portion under a connection state where the conductive core is connected with the connector.

A multiple cable disconnect includes a housing having a separable mating end and a wire terminating end configured to receive wires of power cables. The housing has a plurality of terminal chambers with terminals therein. The terminals each have a base, a mating contact extending from the base and a wire contact extending from the base. The mating contact has a mating pad defining a separable mating interface for the terminal for mating with a corresponding mating terminal of the mating connector. The wire contact has plural wire interfaces for mating with plural wires such that plural wires are configured to be terminated to and commoned with each terminal. Wire retention springs are received in the housing each having at least one spring arm defining a wire trap with the corresponding wire contact. The spring arms are releasable to release the wires from the housing.

A conductor terminal includes a rubber shell, control pieces, and clamping springs. A connecting section is formed in a height direction of each of the clamping springs. Each connecting section is connected between a highest position and a lowest position of each of the clamping springs. A total length of each connecting section is greater than a distance between the highest position and the lowest position of each of the clamping springs, making each connecting section more extended and disposed within the entire clamping spring. Moreover, the conductor terminal is flattened, which increases the size in the plug-in direction and significantly reduces the overall height, making the wiring connection more efficient and tighter. In this way, the conductor terminal is narrowed, and the conductor terminal product is made lighter and thinner.

A conductor connection terminal with a spring-force clamping connection, which has a busbar and a clamping spring for connecting an electrical conductor to the busbar by the clamping spring. An actuator acts on an actuation section of the clamping spring for displacing a clamping leg of the clamping spring from a clamping position to an open position. The actuator has a first pusher section with a first actuation contour and a second pusher section with a second actuation contour. The actuator displaces the clamping leg by a first displacement distance through interaction of the first actuation contour with the first effective contour when the actuator is displaced by a first actuation distance, and displace the clamping leg of the clamping spring by a second displacement distance through interaction of the second actuation contour with the second effective contour when the actuator is displaced by a second actuation distance.

A protective earthing contact for connecting a protective earth line with an electrically conductive carrier element in an the electrically conducting manner, wherein the protective earthing contact has a base portion, wherein two side elements project from the base portion and a respective side element has an upper region, wherein the upper regions have a latching region for clamping the protective earthing contact onto the carrier element and wherein at least one side element has a protective earth contact element for making contact to the carrier element in an electrically conducting manner. Each of the upper regions has a contact-making region, wherein the latching region and the protective earth contact element are substantially arranged at the same height in relation to the base portion.