A lifter with damping is disclosed. It comprises: an outer casing, having an opening on a top end thereof, a gear rack formed on an inside of one side thereof, a guiding groove formed on an opposite side of the gear rack, and two accommodating bins extend downwards on the bottom of the outer casing; a moving body, movably installed inside the outer casing, wherein a round hole is formed in a middle portion of the moving body, a limiting hook is formed corresponding to the guiding groove so as to slide along the guiding groove, bottoms of the moving body corresponding to the two accommodating bins form a hollow slider, respectively, a grab bar is formed horizontally between the hollow sliders, and each hollow slider houses a spring; a damping gear, inserted into the round hole and rotatably connected to the gear rack; and a circulating hooking assembly.

A key structure including a baseplate, a key cap, a first lever, a second lever, a first magnetic member, a second magnetic member and a first buffer material is provided. The first magnetic member is disposed on the baseplate and located between the first lever and the second lever. The second magnetic member is disposed on the first lever and corresponding to the first magnetic member. The first magnetic member has a first portion. The second lever has a second central end. The first portion is adjacent to the second central end. When the key cap moves to a higher position, the first and second magnetic members move towards each other. The second magnetic member has a second portion and a third portion. The first buffer material is provided between the first and second portions and between the second central end and the third portion, respectively.

A key structure including a baseplate, a key cap, a first lever, a second lever, a first magnetic member, a second magnetic member and a first buffer material is provided. The first magnetic member is disposed on the baseplate and located between the first lever and the second lever. The second magnetic member is disposed on the first lever and corresponding to the first magnetic member. The first magnetic member has a first portion. The second lever has a second central end. The first portion is adjacent to the second central end. When the key cap moves to a higher position, the first and second magnetic members move towards each other. The second magnetic member has a second portion and a third portion. The first buffer material is provided between the first and second portions and between the second central end and the third portion, respectively.

A device is for guiding a spring belonging to a control mechanism. The device includes two elements capable of sliding relative to one another and being linked in an articulated manner respectively to two axes of which at least one is linked mechanically to an operating shaft, and a compression spring mounted around these two elements and bearing by its two opposing ends respectively on the abovementioned two axes via, respectively, two bases, each of its bases being mounted in an articulated manner relative to one of the abovementioned axes. This device includes two rods, each rod being fixed by one of its ends onto one of the abovementioned bases, and being mounted to slide by its opposite end, relative to the other of the abovementioned bases.

A device is for guiding a spring belonging to a control mechanism. The device includes two elements capable of sliding relative to one another and being linked in an articulated manner respectively to two axes of which at least one is linked mechanically to an operating shaft, and a compression spring mounted around these two elements and bearing by its two opposing ends respectively on the abovementioned two axes via, respectively, two bases, each of its bases being mounted in an articulated manner relative to one of the abovementioned axes. This device includes two rods, each rod being fixed by one of its ends onto one of the abovementioned bases, and being mounted to slide by its opposite end, relative to the other of the abovementioned bases.

A switching device for an electric circuit, the switching device comprising: at least one phase having a movable contact which can be coupled to/separated from a corresponding fixed contact; a kinematic chain operatively associated to the movable contact; driving means adapted to move the kinematic chain between a first position and a second position for actuating the movable contact; and control means adapted to control the driving means. The kinematic chain is adapted to reach the second position from the first position before reaching a dead-point position, and the control means are adapted to: detect a loss condition of a power supply associable to and suitable for operating the switching device, while the kinematic chain is in the second position; and control the driving means to move the kinematic chain away from the second position when the loss condition is detected, in such a way that the kinematic chain passes through the dead-point position and reaches a third position between the dead-point position and corresponding blocking means of the switching device.

A switching device for an electric circuit, the switching device comprising: at least one phase having a movable contact which can be coupled to/separated from a corresponding fixed contact; a kinematic chain operatively associated to the movable contact; driving means adapted to move the kinematic chain between a first position and a second position for actuating the movable contact; and control means adapted to control the driving means. The kinematic chain is adapted to reach the second position from the first position before reaching a dead-point position, and the control means are adapted to: detect a loss condition of a power supply associable to and suitable for operating the switching device, while the kinematic chain is in the second position; and control the driving means to move the kinematic chain away from the second position when the loss condition is detected, in such a way that the kinematic chain passes through the dead-point position and reaches a third position between the dead-point position and corresponding blocking means of the switching device.

A device for switching medium and/or high voltages has a spring-loaded drive for driving a kinematic chain. At least one energy storage spring and at least one damping element for generating a drive movement with specific drive characteristics are included. The at least one damping element is an active damping element. The damping is actively determined during switching or it is predetermined, in particular depending on environmental variables and/or the type of switching situation, by changing the settings of the at least one damping element.

Caging structures are disclosed for caging or otherwise reducing the mechanical shock pulse experienced by MEMS device beam structures during events that may cause mechanical shock to the MEMS device. The caging structures at least partially surround the beam such that they limit the motion of the beam in a direction perpendicular to the beam's longitudinal axis, thereby reducing stress on the beam during a mechanical shock event. The caging structures may be used in combination with mechanical shock-resistant beams.

Actuator and electric switching apparatus including a spring to provide movement of the apparatus and a rotary air damper. The damper is arranged to decelerate the spring during at least an end portion of movement. The damper has a toroidal working chamber formed by two circumferential housing parts rotatable relative to each other. Each housing part has internal walls which together define the working chamber. The first housing part has a rotatable displacement wall, sealingly rotatable in the working chamber. The second housing part has a stationary end wall of the working chamber. The second housing part has one recess in its internal walls. The recess is located less than 90 ahead the end wall as seen is the rotational direction of the displacement wall at an actuating movement. The recess has an extension in the circumferential direction that is larger than the effective thickness of the displacement wall. Alternatively the recess is on the first housing part.