A switch structure includes a lever operable by a user, a body coupled to the lever, a support formed in the lever, a pusher supported by the support, a detent surface formed in the body to produce a click when the lever is operated, and a spring that pushes the pusher against the detent surface. The pusher includes two slide surfaces, which slide on the lever and the body, and a groove, which draws grease from one of the two slide surfaces where the grease is applied to another one of the two slide surfaces.

A high load switch for a vehicle includes a case having an opening formed at an upper side of the case; a first contact unit disposed at a lower side in the case; a second contact unit disposed at a lower side in the case and disposed directly above the first contact unit; and a contactor having one end fixed to one side in the case, and the other end disposed between the first contact unit and the second contact unit, in which a portion of the contactor between the one end and the other end is continuously formed, and the contactor includes a pusher unit formed by being bent upward so that an intermediate portion thereof penetrates the opening and protrudes, and a reinforcement bead formed on a surface of the contactor, thereby preventing deformation in the contactor and enhancing durability.

A device for controlling multiple functions includes a switch panel. The switch panel includes control panels extending along a longitudinal extension of the switch panel. The switch panel is pivotably mounted about an axis of rotation parallel with the longitudinal extension to pivot about the axis of rotation in response to manual actuation of the switch panel by manual actuation of the control panels. The switch panel is movable with respect to the longitudinal extension of the switch panel and is fixed with respect to a transverse extension of the switch panel perpendicular to the longitudinal extension. Force sensors respectively associated with the control panels are distributed along the longitudinal extension of the switch panel. Actuation of the switch panel by actuating one of the control panels triggers a function depending on which one control panel is actuated and the force sensors detect which control panel is actuated.

An input device includes a base, an operation panel, and a shaft portion. The input device includes a first operation knob having a first operation part to swing the panel in a first swing direction and a second operation part to swing the panel in a second swing direction, the second operation knob having a third operation part to swing the panel in the second swing direction and a fourth operation part to swing the operation panel in the first swing direction. The input device includes a control unit to discriminate between a pressing operation and a pulling-up operation based on based on output of each of a swing detector, a first capacitance detection electrode, and a second capacitance detection electrode.

An input device includes housing; operation nob; cam member swingable in a direction intersecting with pivoting direction of operation knob, and performing swinging as first movement in response to operation knob pivoting in first angular range and performing swinging as second movement succeeding first movement in response to operation knob pivoting in second angular range; substrate; first switch on substrate, switched on in conjunction with first movement of cam member; and second switch on substrate, switched on in conjunction with second movement of cam member. When operation force is ceased, operation knob is automatically restored by restoring forces from first and second switches. Input device includes: first actuator to be slid in conjunction with first movement of cam member to push first switch perpendicularly to substrate; and second actuator to be slid in conjunction with second movement of cam member to push second switch perpendicularly to substrate.

The present disclosure relates to a vehicle door switch actuating apparatus (100). The apparatus includes an actuating element (104) having an actuating surface (110), a mechanical switch (112), and a mechanism for transferring a compressive force applied by a user to the actuating surface (110) onto the mechanical switch (112) in order to flip the mechanical switch (112). The mechanism includes: a first component (102) on which the mechanical switch (112) is fixed at least in the switching direction; and a lever (120) pivotally supported about a pivot axis (124) relative to the first component (102) or the first component group and connected to the actuating element (104) via a first bearing on a first side (111) of the actuating surface (110). The actuating element (104) is supported on the first component (102) or the first component group via a second bearing on a second side (113) of the actuating surface (110). The actuating element (104) is flexibly configured such that, when manual pressure is applied to the actuating surface (110), it flexibly bends, thereby causing a change in the distance between the first bearing and the second bearing, in particular a shortening or lengthening of the distance, and thus causes the lever to pivot about the pivot axis (124). The mechanical switch (112) is arranged such that, by pivoting the lever, the mechanical switch (112) is flipped. The lever (120) extends substantially parallel to the first side (111) of the actuating surface (110).