A switch may include: a movable member comprising a movable piece extending from a swing shaft and being swingable around the swing shaft; and a pressing member configured to press the movable piece while moving in response to a pushing operation, the movable piece swinging in response to pressing from the pressing member. The pressing member comprises a first contact portion configured to slide along an extending direction of the movable piece in a state of being in contact with the movable piece due to movement by the pushing operation, and a second contact portion configured to be in contact with the movable piece at a position different from a position where the first contact portion is in contact, due to the movement by the pushing operation, and the pressing member presses the movable piece by the first contact portion and the second contact portion in a contact state.

Embodiments of the present invention relate to a controller (1) for use with a mechanical switch (2). The controller (1) comprises at least one sensor (9), an actuator and at least one attachment member (5) suitable for attaching the controller (1) to the mechanical switch (2) such that the actuator is brought into contact with the mechanical switch (2). The actuator is arranged to operate the mechanical switch (2) in response to a signal from the at least one sensor (9), in use.

A protective cover assembly for an electrical wall switch disposed on a wall in which the electrical wall switch has an actuator physically contactable and actuatable by a user for controlling electrical power to a load from an electrical power source. The protective cover assembly may include an enclosure and a connector for connecting the enclosure over the electrical wall switch to inhibit a user from physically contacting and actuating the actuator. A first magnetic material member is attached to or disposed in the actuator. A tool includes a second magnetic material member. When the tool is moved relative to the outer surface of the enclosure, a magnetic force acting through the enclosure is operable to move the actuator from a first position to a second position thereby moving the actuator for controlling electrical power to the electrical load.

A seat belt fastened/unfastened state detection switch includes: a printed substrate that includes a circuit for detecting a fastened/unfastened state of a seat belt; a rotor that is rotatably attached to the printed substrate, includes a contact portion, the contact portion coming into contact with a tongue of the seat belt, and rotates in a forward direction in accordance with pushing of the tongue into a buckle; a spring that makes the rotor, the rotor being in a rotated state in the forward direction, rotate in a reverse direction in accordance with pulling of the tongue from the buckle; and an electric brush that is attached to a surface of the rotor, the surface facing the printed substrate, and includes a leg portion whose contact/non-contact state with respect to a conductive part of the circuit changes depending on a rotation state of the rotor.

A switch may include: a movable member comprising a movable piece extending from a swing shaft and being swingable around the swing shaft; and a pressing member configured to press the movable piece while moving in response to a pushing operation, the movable piece swinging in response to pressing from the pressing member. The pressing member comprises a first contact portion configured to slide along an extending direction of the movable piece in a state of being in contact with the movable piece due to movement by the pushing operation, and a second contact portion configured to be in contact with the movable piece at a position different from a position where the first contact portion is in contact, due to the movement by the pushing operation, and the pressing member presses the movable piece by the first contact portion and the second contact portion in a contact state.

A remote drive with a support element for a top-hat-rail mounting. Opposing actuators disposed on the support element alternatingly act on a displaceably mounted slider by rod-shaped anchors. A slider passage receives a first lever arm of a rocker lever pivotable about a rotational axis parallel to the top hat rail length and nearly passes through a rotational point of a shift lever of a switching device. A carrier rail on a second lever arm is parallel to the top hat rail length, the shift lever engaging the carrier rail to the side of the second lever arm. When the slider is displaced, the rocker lever flips simultaneously activate the shift lever. In a remote drive assembly, two remote drives are disposed adjacent to one another on a top hat rail with a locking mechanism. Alternatively, individually controlled actuators act on first and second legs of a T-shaped rocker switch.

A seat belt fastened/unfastened state detection switch includes: a printed substrate that includes a circuit for detecting a fastened/unfastened state of a seat belt; a rotor that is rotatably attached to the printed substrate, includes a contact portion, the contact portion coming into contact with a tongue of the seat belt, and rotates in a forward direction in accordance with pushing of the tongue into a buckle; a spring that makes the rotor, the rotor being in a rotated state in the forward direction, rotate in a reverse direction in accordance with pulling of the tongue from the buckle; and an electric brush that is attached to a surface of the rotor, the surface facing the printed substrate, and includes a leg portion whose contact/non-contact state with respect to a conductive part of the circuit changes depending on a rotation state of the rotor.

A remote drive with a support element for a top-hat-rail mounting. Opposing actuators disposed on the support element alternatingly act on a displaceably mounted slider by rod-shaped anchors. A slider passage receives a first lever arm of a rocker lever pivotable about a rotational axis parallel to the top hat rail length and nearly passes through a rotational point of a shift lever of a switching device. A carrier rail on a second lever arm is parallel to the top hat rail length, the shift lever engaging the carrier rail to the side of the second lever arm. When the slider is displaced, the rocker lever flips simultaneously activate the shift lever. In a remote drive assembly, two remote drives are disposed adjacent to one another on a top hat rail with a locking mechanism. Alternatively, individually controlled actuators act on first and second legs of a T-shaped rocker switch.

This application relates to securing and positioning internal components within a housing of a portable computing device. In one embodiment, a number of insert molded retaining members are utilized to inhibit outward deformation of a sidewall of the housing during a drop event. In another embodiment, a cowling is utilized to retain a number of board-to-board connectors within communication slots on a printed circuit board (PCB). In another embodiment, a C-shaped washer having diametrically opposed protrusions is utilized to adjust an alignment of an internal component.

A protective cover assembly for an electrical wall switch disposed on a wall in which the electrical wall switch has an actuator physically contactable and actuatable by a user for controlling electrical power to a load from an electrical power source. The protective cover assembly may include an enclosure and a connector for connecting the enclosure over the electrical wall switch to inhibit a user from physically contacting and actuating the actuator. A first magnetic material member is attached to or disposed in the actuator. A tool includes a second magnetic material member. When the tool is moved relative to the outer surface of the enclosure, a magnetic force acting through the enclosure is operable to move the actuator from a first position to a second position thereby moving the actuator for controlling electrical power to the electrical load.