An electrical connector used for bearing a chip module includes an insulating body, terminals arranged in the insulating body, a carrying member, for carrying the chip module to the insulating body, disposed at one side of the insulating body and contacting with the terminals, a pressing plate for pressing the carrying member or the chip module, and an elastic member having at least two limiting portions. The pressing plate and the carrying member are separately disposed at two adjacent sides on the periphery of the insulating body. The two limiting portions define a pivoting space, and the carrying member is pivotally connected to the pivoting space. The elastic member and the carrying member are disposed at the same side of the insulating body, the elastic member has a buffer portion, and the buffer portion abuts against the carrying member and is disposed between the insulating body and the carrying member.

A lever-type connector includes a housing configured to rotate about a first shaft, a second lever configured to rotate about a second shaft and a cam groove linked with rotation of the second lever. The first lever includes a guide portion extending from an operating portion toward the first shaft, and the second lever includes a coupling portion coupled to the first lever relatively displaceably along the guide portion. The both levers are linked and rotated between an initial position where connection of the housing and a mating housing is started and a connection position where the connection of the housing and the mating housing is completed. When a virtual line passing through the second shaft and the coupling portion with the second lever located at the initial position is set, the first shaft is located closer to the connection position than the virtual line.

An electrical connector used for bearing a chip module includes an insulating body, terminals arranged in the insulating body, a carrying member, for carrying the chip module to the insulating body, disposed at one side of the insulating body and contacting with the terminals, a pressing plate for pressing the carrying member or the chip module, and an elastic member having at least two limiting portions. The pressing plate and the carrying member are separately disposed at two adjacent sides on the periphery of the insulating body. The two limiting portions define a pivoting space, and the carrying member is pivotally connected to the pivoting space. The elastic member and the carrying member are disposed at the same side of the insulating body, the elastic member has a buffer portion, and the buffer portion abuts against the carrying member and is disposed between the insulating body and the carrying member.

An electrical connector used for carrying a chip module includes an insulating body with multiple terminals arranged in the insulating body, a carrying member pivoted to the insulating body and used for carrying the chip module to the insulating body, and a pressing plate located on one side of the insulating body and used for pressing the carrying member or the chip module. The chip module contacts with the multiple terminals. The carrying member is directly pivoted to the insulating body. Each of two ends of a pivoting side of the carrying member is provided with a pivot shaft. Fixing holes are formed on the outer side of the insulating body. The pivoting shafts are pivoted into the fixing holes, so that the carrying member is rotatingly pivoted to the insulating body without the assistance of a pivoting device for pivoting the carrying member.

An input device may include a wire element and a moveable substrate coupled to the wire element. The moveable substrate may include various wire alignment features. The input device may further include an input surface disposed above the moveable substrate. The input device may further include various sensor electrodes coupled to the input surface. The input device may further include a haptic actuator coupled to the moveable substrate. The haptic actuator may displace the moveable substrate in a direction substantially parallel to a plane of the input surface. The wire element may return the moveable substrate to an original position. The wire alignment features may allow, in response to an applied force by the haptic actuator and to the moveable substrate, a displacement of the moveable substrate in the direction that is substantially parallel to the plane of the input surface.

This lever-type connector comprises a first part forming a base and a second part mobile in relation to the base, the first and second parts inwardly receiving first and second contact assemblies facing one another, male and female respectfully, each provided at one end with conductors to be connected, and a cam mechanism able to move the mobile part between contact disconnection and connection positions. The cam mechanism includes a lever shaped so as to be circumscribed inside the main cross-section of the connector.

In an open position, a power-supply terminal and a detection terminal are not connected to a mating power-supply terminal and a mating detection terminal, respectively. In a predetermined position, the power-supply terminal is connected to the mating power-supply terminal while the detection terminal is not connected to the mating detection terminal. In a closed position, the power-supply terminal and the detection terminal are connected to the mating power-supply terminal and the mating detection terminal, respectively. When the connector is turned toward the predetermined position from the closed position, a first regulating portion regulates a first regulated portion to prevent the connector from reaching the predetermined position. When the connector is turned toward the predetermined position after the regulation is released, a second regulating portion regulates a second regulated portion to prevent the connector from being turned toward the open position beyond the predetermined position.

An electrical connector used for carrying a chip module includes an insulating body having terminals arranged in the insulating body and used for contacting the chip module, a carrying member used for carrying the chip module to the insulating body, a pressing plate used for pressing the carrying member or the chip module, and a positioning member pivoted to the carrying member through a pivoting device. The pivoting device includes a pivoting shaft and at least one elastic portion. The elastic portion includes a first elastic section and at least two limiting portions being elastic and enclosing a pivoting space. The pivoting shaft is pivoted to the pivoting space. When the electrical connector is opened, the first elastic section springs back to remove the chip module from the insulating body without damaging the terminals, so as to align and contact the chip module with the terminals without tool.

The general field of the invention is that of the locking and extraction devices for an electrical connector in an electronic casing, said electronic casing comprising the electrical socket corresponding to said electrical connector, the connection and the extraction of the electrical connector being performed in a determined direction, parallel to the electrical contacts of the electrical connector. The connector according to the invention is mounted in a mechanical assembly comprising at least one shoulder. The electronic casing comprises a mechanical structure comprising at least one mobile gripping jaw arranged so as to grasp the shoulder of the connector and to impart thereon a translational movement in said determined direction, thus facilitating the connection or the extraction of said electrical connector in its electrical socket.

A connector includes a housing and a lock arm that extends from the housing and is engageable with a counterpart connector. The lock arm includes a first arm a has a shape of a cantilever beam and has a locking hole for being engaged with the counterpart connector at a free end side of the first arm, and a second arm that extends from an end portion on the free end side of the first arm and is capable of releasing the engagement by bending the first arm around a fixing end of the first arm. The locking hole has a hole of which the size in a width direction orthogonal to an extending direction of the first arm becomes larger as a measurement position of the size of the hole gets closer to the free end from the fixing end.