A wireless switch includes a switch body, a push button connected to the switch body in a state of being movable along an approaching/separating direction between a non-operating position and an operating position, a signal output device accommodated in the switch body and configured to output a switch signal in response to a movement of the push button from the non-operating position to the operating position, and a restriction member that restricts the movement of the push button from the non-operating position to the operation position when the push button is located at the non-operating position.

A self-powered wireless keyboard by modifying the structure of a traditional membrane keyboard having a volcanic crater structure. Not damaging the original membrane keyboard structure, a micro magnet core is installed inside a cylindrical protrusion block under the key cap as a mover of the induction power generation device, and an induction coil is wound in a key slot of the keyboard base as the stator of the induction power generation device. In this way, when each key is pressed, it will produce induction current. A layer of flexible solar cell can be laid on the upper surface of the key, which can generate electricity by collecting the light energy in the surrounding environment during the time of daily illumination.

A passive rebound switch includes an actuation button, an energy collecting module, a detection control, a housing, a power generation module, and a signal transmission circuit. The actuation button is detachably and pivotally connected to the housing. The power generation device, the signal transmission circuit, and the detection control are accommodated in an receiving chamber formed between the actuation button and the housing. When the actuation button is actuated to move in reciprocated rebounding movement, the energy collecting module is actuated to trigger the power generation module for converting mechanical energy into electrical energy to power the signal transmission circuit for transmitting a control signal. The energy collecting module is disposed between the actuation button and the power generation module. The detection switch pre-activates an I/O interface of an encoder device of the signal transmission circuit prior to the power generation module for generating the electrical power.

The invention relates to an operating device for a motor vehicle, comprising an operating element, which can be lowered by application of force; a snap dome arranged below the operating element for applying haptic feedback to the operating element when the snap dome is deformed by means of the operating element lowering; a blocking body made of an electroactive polymer arranged below the operating element and next to the snap dome, the shape of which blocking body can be altered depending on an electrical voltage applied thereto such that lowering of the operating element is blocked or lowering of the operating element for deforming the snap dome is enabled; a detection apparatus for detecting a contact position of a finger on the operating element; a control apparatus which is set up to adjust a voltage at the blocking body depending on the detected contact position of the finger. The invention further relates to a method for operating an operating device and to a motor vehicle comprising an operating device of this kind.

Self-powered switches include a switch housing having an externally accessible user input member, a coil assembly, and a magnet arranged therein such that at least one of the coil assembly and the magnet move relative to each other responsive to movement of the user input member between first and second switch positions, and a control circuit held in the switch housing and coupled to first and second terminals of the coil assembly. The control circuit is configured to detect respective electrical characteristics of the first and second terminals of the coil assembly responsive to the movement of the user input member, and selectively transmit first and second wireless control signals to a remote receiver based on the respective electrical characteristics of the first and second terminals of the coil assembly, respectively. Related circuits and methods of operation are also discussed.

A wireless transmitter including a rotating actuator, a plate connected to the rotating actuator, and a wireless switch. The wireless switch may include at least one actuating panel and at least one transducer element. The at least one transducer element may be configured to convert mechanical energy to electrical energy. The at least one actuating panel may be configured to transmit mechanical energy to the at least one transducer element. The plate may be configured to contact the wireless switch at a rotational end point of the rotating actuator.

A self-powered wireless switch includes at least one micro generator and a control panel for transmitting wireless control signals, the micro generator including a magnet assembly and a coil assembly being moved relatively to one another to generate an induced current within the coil assembly; the coil assembly including an iron core and a wire winding around the outside of the iron core to form a magnetic coil; the magnet assembly including a permanent magnet and magnet conductive plates arranged at two sides of the opposite magnetic poles of the permanent magnet. The self-powered wireless switch enables the magnetic assembly and the coil assembly to move relatively to one another and converts the mechanical energy to electricity, thereby achieving self-power generation and providing electricity to the control panel for transmission of wireless control signals.

A switch device includes an actuation unit, a movable unit, a first base, and a second spring, which is a torsion coil spring that acts between the actuation unit and the movable unit. The movable unit is movable with respect to the base. The second spring applies a force to the actuation unit when the actuation unit is at a third position in a direction that is not parallel to a direction in which the torsion coil spring applies a force to the actuation unit when the actuation unit is at a fourth position.

Self-powered switches include a switch housing having an externally accessible user input member, a coil assembly, and a magnet arranged therein such that at least one of the coil assembly and the magnet move relative to each other responsive to movement of the user input member between first and second switch positions, and a control circuit held in the switch housing and coupled to first and second terminals of the coil assembly. The control circuit is configured to detect respective electrical characteristics of the first and second terminals of the coil assembly responsive to the movement of the user input member, and selectively transmit first and second wireless control signals to a remote receiver based on the respective electrical characteristics of the first and second terminals of the coil assembly, respectively. Related circuits and methods of operation are also discussed.

A gate is pivotally mounted on an upstanding post located adjacent a juncture of intersecting travel paths. To prevent collisions of persons and/or vehicles moving along the intersecting travel paths at the travel path juncture, a kinetic energy harvesting switch is carried by the upstanding post and has a spring-projected push button or plunger-type operator that is depressed relative to a housing of the switch when the gate begins to open to admit a person and/or a vehicle to the travel path juncture. Energy harvested by the switch is utilized to transmit a radio frequency signal that can be received by a device that displays a visual warning and/or emits an audible warning, advising that collision avoidance measures are likely to be needed to prevent a collision at the travel path juncture.