Abstract: The present invention is to provide a card insert/eject mechanism, which includes an insulating seat formed with a receiving space and a track groove; a metal housing covering the receiving space and track groove and having a position-limiting resilient plate at a bottom surface thereof; a sliding block slidable along the track groove and laterally provided with a pushing portion that extends into the receiving space thereby, when an electronic card pushes the pushing portion, the sliding block is moved against rear end of the insulating seat; a resilient element provided in the track groove for applying a force to rear end of the sliding block; and a release bar disposed in the track groove for releasing the position-limiting resilient plate and enabling the sliding block to push the electronic card out of the receiving space, so as to effectively solve the insecure card engagement problem in conventional push-push connectors.
Abstract: The present invention is to provide a card insert/eject mechanism, which includes an insulating seat formed with a receiving space and a track groove; a metal housing covering the receiving space and track groove and having a position-limiting resilient plate at a bottom surface thereof; a sliding block slidable along the track groove and laterally provided with a pushing portion that extends into the receiving space thereby, when an electronic card pushes the pushing portion, the sliding block is moved against rear end of the insulating seat; a resilient element provided in the track groove for applying a force to rear end of the sliding block; and a release bar disposed in the track groove for releasing the position-limiting resilient plate and enabling the sliding block to push the electronic card out of the receiving space, so as to effectively solve the insecure card engagement problem in conventional push-push connectors.
Abstract: The present invention is to provide a high-power connector having a heat dissipation structure, which includes a cover, a plurality of resilient metal terminals and a plurality of auxiliary metal plates. The cover is made of an insulating material and defines a plurality of receiving spaces therein. The resilient metal terminals are fitted in the receiving spaces respectively. The front section of each resilient metal terminal has an arcuate shape, passes through a lateral side of the cover, and is exposed from the cover. The front section of each auxiliary metal plate is electrically connected to the corresponding resilient metal terminal, and the rear section of each auxiliary metal plate is electrically connected to a circuit board. Since the auxiliary metal plates have relatively low impedance capable of rapidly releasing the heat generated by the connector, the components of the connector are prevented from premature aging attributable to high temperature.
Abstract: The present invention is to provide a high-power connector having a heat dissipation structure, which includes a cover, a plurality of resilient metal terminals and a plurality of auxiliary metal plates. The cover is made of an insulating material and defines a plurality of receiving spaces therein. The resilient metal terminals are fitted in the receiving spaces respectively. The front section of each resilient metal terminal has an arcuate shape, passes through a lateral side of the cover, and is exposed from the cover. The front section of each auxiliary metal plate is electrically connected to the corresponding resilient metal terminal, and the rear section of each auxiliary metal plate is electrically connected to a circuit board. Since the auxiliary metal plates have relatively low impedance capable of rapidly releasing the heat generated by the connector, the components of the connector are prevented from premature aging attributable to high temperature.