The present disclosure provides a charging assembly for charging an electronic device and an electronic device system including the charging assembly. The charging assembly includes a charging transmission line, a fixing member and a telescopic member. A first end of the telescopic member is fixedly arranged on the fixing member, an input part of the charging transmission line is fixed at a second end of the telescopic member, and the telescopic member is retractable and extendable so that the input part is moved toward or away from the fixing member to be disconnected or connected to a power source.

The present disclosure provides a charging assembly for charging an electronic device and an electronic device system including the charging assembly. The charging assembly includes a charging transmission line, a fixing member and a telescopic member. A first end of the telescopic member is fixedly arranged on the fixing member, an input part of the charging transmission line is fixed at a second end of the telescopic member, and the telescopic member is retractable and extendable so that the input part is moved toward or away from the fixing member to be disconnected or connected to a power source.

A slider for an actuator, the slider comprises a driving plate that moves under a driving force of a driving unit of the actuator, and a linkage lever channel arranged in the driving plate. A sliding track channel is disposed inside the driving plate, and the slider is sleeved on a sliding track of the actuator through the sliding track channel. When the slider moves along the sliding track of the actuator, a component to be driven is driven to move together. The slider for the actuator of the application has simple assembly process, convenient and quick assembly method, and can be applied to connecting different kinds of components to be driven to meet different user's requirements.

A slider for an actuator, the slider comprises a driving plate that moves under a driving force of a driving unit of the actuator, and a linkage lever channel arranged in the driving plate. A sliding track channel is disposed inside the driving plate, and the slider is sleeved on a sliding track of the actuator through the sliding track channel. When the slider moves along the sliding track of the actuator, a component to be driven is driven to move together. The slider for the actuator of the application has simple assembly process, convenient and quick assembly method, and can be applied to connecting different kinds of components to be driven to meet different user's requirements.

A vane phaser with an unlocking and relocking mechanism attached to the lock pin, which through the use of a solenoid, distinct from the solenoid used for the oil control valve, which can lock and unlock the vane phaser. When the solenoid is energized and during rotation of the camshaft, the solenoid makes contact with a lever or gear wheel attached to the lock pin, causing the lock pin to rotate. A helical feature on the lock pin itself or on the lever causes the lock pin to move axially, unlocking the vane phaser.

A vane phaser with an unlocking and relocking mechanism attached to the lock pin, which through the use of a solenoid, distinct from the solenoid used for the oil control valve, which can lock and unlock the vane phaser. When the solenoid is energized and during rotation of the camshaft, the solenoid makes contact with a lever or gear wheel attached to the lock pin, causing the lock pin to rotate. A helical feature on the lock pin itself or on the lever causes the lock pin to move axially, unlocking the vane phaser.

This invention is related to a mechanical torque generator (MTG) (11), the cost, the maintenance costs and the energy consumption of which have been minimized, as much as possible, since the reaction forces, the reaction moments and the frictional forces at the joints that connect the mechanism to the ground have been minimized as much as possible; which does not possess any actuators; and which can generate any desired torque variation. MTG (11) may be obtained by using 3 novel kinematic chains. By using these kinematic chains, it is also possible to obtain general purpose mechanisms, which have advantages similar to the MTG (11); which may include an actuator; which may generate relative rotational motion at a joint as any desired function of relative translational motion at another joint; which may be used in many different fields such as hydraulic and pneumatic machines, internal combustion engines and compressors.

An enhanced method and precision nanopositioning apparatus for implementing enhanced nanopositioning performance is provided. The nanopositioning apparatus includes a vertical linear nanopositioning flexure stage and a horizontal linear nanopositioning flexure stage. The vertical linear nanopositioning flexure stage includes a stage base, a symmetrically configured flexure linear guiding mechanism with precision motion enhancement structure, and a stage carriage. The horizontal linear nanopositioning flexure stage is mounted on the stage carriage of the vertical linear nanopositioning flexure stage, and includes a middle-bar relative position control mechanism to enhance the stiffness of a flexure linear guiding mechanism.

An enhanced method and precision nanopositioning apparatus for implementing enhanced nanopositioning performance is provided. The nanopositioning apparatus includes a vertical linear nanopositioning flexure stage and a horizontal linear nanopositioning flexure stage. The vertical linear nanopositioning flexure stage includes a stage base, a symmetrically configured flexure linear guiding mechanism with precision motion enhancement structure, and a stage carriage. The horizontal linear nanopositioning flexure stage is mounted on the stage carriage of the vertical linear nanopositioning flexure stage, and includes a middle-bar relative position control mechanism to enhance the stiffness of a flexure linear guiding mechanism.

A rotary machine includes a cam shaft; and a plurality of linkage shafts coupled to the cam shaft, each of the linkage shafts including a pair of identically-shaped first linkage members adapted for cam contact with the cam shaft, a pair of identically-shaped second linkage members pivotally coupled to the first linkage members, and a pair of identically-shaped third linkage members pivotally coupled to the second linkage members, wherein each of the linkage shafts is progressively and continuously changing between a shortest linkage state and a longest linkage state due to the cam contact between the cam shaft and the linkage shafts, upon rotation of the linkage shafts about the cam shaft.