This application discloses a coil spring type wire-locking terminal block, including a plurality of insulating seats arranged in sequence. A mounting groove is formed in each insulating seat. A wire inlet hole is formed in one side wall of the mounting groove. A connecting terminal is mounted at the bottom of the mounting groove, one end of the connecting terminal penetrates through the bottom of the mounting groove, and a first through hole is formed at one side of the connecting terminal. A wire locking frame is slidably connected in the mounting groove. A compression elastic member is arranged in the wire locking frame, and a second through hole is formed in the side wall of the wire locking frame. The wire inlet hole, the first through hole and the second through hole are arranged corresponding to each other.

A shielded in-line connector includes conductive first and second body portions, each with a securement feature, as well as conductive first and second clips. The first and second body portions are secured to one another to define an unshielded connector-receiving cavity as well as first and second shielded cable openings; each of the first and second shielded cable openings being proximate the respective clip securement feature. Each of the clip securement features includes a channel supportive of a respective shielded cable extending from each of the first and second shielded cable openings; each of the shielded cables having an exposed shield. The first and second clips are adjustably secured to a respective one of the first and second securement features to position the respective clip in direct contact with the exposed shield of the respective shielded cable.

A terminal connecting mechanism for a molded case circuit breaker that does not need a tool for connection or release between a wire and a terminal is disclosed. The terminal connecting mechanism of a molded case circuit breaker comprises a supporter having a through hole portion for allowing passing through of a terminal of the molded case circuit breaker and a terminal seat portion where the terminal, which has passed through the through hole portion, is mounted; a spring of which one end is supported by the supporter; and a lever member being in contact with the other end of the spring, rotataby moving to a position for allowing insertion of a wire to contact the terminal, and pressurizing the wire by means of an elastic force of the spring to maintain a contact state between the wire and the terminal.

This application discloses a coil spring type wire-locking terminal block, including a plurality of insulating seats arranged in sequence. A mounting groove is formed in each insulating seat. A wire inlet hole is formed in one side wall of the mounting groove. A connecting terminal is mounted at the bottom of the mounting groove, one end of the connecting terminal penetrates through the bottom of the mounting groove, and a first through hole is formed at one side of the connecting terminal. A wire locking frame is slidably connected in the mounting groove. A compression elastic member is arranged in the wire locking frame, and a second through hole is formed in the side wall of the wire locking frame. The wire inlet hole, the first through hole and the second through hole are arranged corresponding to each other.

The invention relates to a device (1) for aligning a solar panel (20) with respect to an installation rail which is attached to a base, in particular a roof, prior to installation. The invention also relates to an assembly comprising at least one solar panel (20) and at least one such device (1) which is coupled to a frame (21) of the solar panel (20). The invention furthermore relates to a method for aligning a solar panel (20), with respect to an installation rail attached to a base, in particular a roof, prior to installation by using at least one such device (1), optionally followed by the installation of the at least one solar panel (20) to the support rail.

A cable splice includes a casing, a guide, and a pilot cup. The casing has a first opening and an interior cavity. The guide includes a receiving end and a shaft extending at least partially into the interior cavity. The pilot cup is integrally formed with the guide and frangibly connected to the shaft. The cable splice may also include a clamp positioned in the interior cavity and moveable between a loading position and a terminated position. A biasing member urges the clamp into the terminated position. During movement of the clamp from the loading position to the terminated position, the clamp contacts the guide causing at least a portion of the shaft to exit the interior cavity. The guide may also include a rib and a slot allowing the guide to fit in casings having different sized interior cavities.

A method for forming a connection between a wire and a pin includes placing a fixturing element over the pin, capturing the wire between an upper surface and a lower surface of the fixturing element, compressing the fixturing element to hold the wire around the pin and forming a fixed connection between the wire and the pin. A system for forming an electrical connection includes a pin, a fixturing element disposed around the pin, and a wire placed around pin and sandwiched between an upper surface and a lower surface of the fixturing element.

The invention relates to a device (1) for aligning a solar panel (20) with respect to an installation rail which is attached to a base, in particular a roof, prior to installation. The invention also relates to an assembly comprising at least one solar panel (20) and at least one such device (1) which is coupled to a frame (21) of the solar panel (20). The invention furthermore relates to a method for aligning a solar panel (20), with respect to an installation rail attached to a base, in particular a roof, prior to installation by using at least one such device (1), optionally followed by the installation of the at least one solar panel (20) to the support rail.

A cable splice includes a casing, a guide, and a pilot cup. The casing has a first opening and an interior cavity. The guide includes a receiving end and a shaft extending at least partially into the interior cavity. The pilot cup is integrally formed with the guide and frangibly connected to the shaft. The cable splice may also include a clamp positioned in the interior cavity and moveable between a loading position and a terminated position. A biasing member urges the clamp into the terminated position. During movement of the clamp from the loading position to the terminated position, the clamp contacts the guide causing at least a portion of the shaft to exit the interior cavity. The guide may also include a rib and a slot allowing the guide to fit in casings having different sized interior cavities.

A contacting device has a housing in which a first contact element is arranged. The first contact element has a receiving chamber for a second contact element, which is open with respect to at least one opening of the housing. The first contact element is displaceable relative to the housing in a direction transverse to a central longitudinal axis of the receiving chamber against a spring element, so that the second contact element is insertable into the receiving chamber and capable of being clamped in the receiving chamber by the spring element. The first contact element is firmly connected to at least one plug-in contact element. By this device, a transmission of electrical energy from a power supply line to a circuit board can be achieved in simple and reliable manner.