A wireless switch includes a cover member, a button member, a first plunger, a second plunger, a trigger spring, a return spring, a shaft, a housing, and a power generation module. An intermediate member constituted of the first plunger, the second plunger, the trigger spring, the return spring, and the shaft is connected between the button member and the power generation module. The intermediate member prevents a position of the shaft making contact with the power generating shaft of the power generation module from changing, and causes stress to build up in the trigger spring, until a movement distance of the button member reaches a predetermined distance. The intermediate member releases the stress built up in the trigger spring and pushes the power generation shaft with the shaft using the released stress upon the movement distance of the button member reaching the predetermined distance.

A wireless switch includes a button member, a power generation module, an RF module, and a notification unit. The button member is mounted in a housing, and is configured to move. The power generation module is configured to generate power using energy produced by the movement of the button member. The RF module is connected to the power generation module, and is configured to transmit a switch signal using power generated by the power generation module. The notification unit is configured to operate using power generated by the power generation module. The RF module controls the notification unit in one or more notification states according to a strength or details of a reception state signal corresponding to the transmitted switch signal.

A button structure comprises a keycap, an elastic body, a scissor mechanism, and a piezoresistive film sensor arranged on a support plate. The scissor mechanism and the elastic body are arranged between the keycap and the piezoresistive film sensor. The piezoresistive film sensor comprises a first pressure sensing area and a second pressure sensing area. The elastic body corresponds to the first pressure sensing area and the scissor mechanism corresponds to the second pressure sensing area, such that, when a pressure is applied to the keycap, a first pressure acts on the elastic body to generate pressure on the first pressure sensing area and a second pressure acts on the scissor mechanism to generate pressure on the second pressure sensing area.

The current embodiments provide a switch device for a wireless pushbutton, wherein the switch device comprising an energy conversion mechanism, a signal output mechanism, an actuation device, and a plurality of encoding contacts. The actuation device may be configured to establish contact with at least one of the plurality of encoding contacts when a first quantity of an actuation force is applied for generating an encoded signal. The actuation device may be configured to activate the energy conversion mechanism to generate energy when a second quantity of an actuation force greater than the first quantity is applied to the activation device. The signal output mechanism may be configured to transmit a wireless output signal using the encoded signal when the energy conversion mechanism is activated.

Provided are a piezoelectric energy harvester and a wireless switch including the piezoelectric energy harvester. The wireless switch uses energy generated in a piezoelectric energy harvester as a source of driving power, thereby transmitting communications signals to an external electronic device without requiring a battery. In addition, the piezoelectric energy harvester generates displacement in a piezoelectric element through a magnetic force generated in a magnet, thereby generating a constant level of energy when generating the driving power.

A self-powered switching device is provided. In embodiments, the device uses a prestressed flextensional electroactive member to generate a signal for activation of a latching relay. The electroactive member has a piezoelectric element with a convex face and a concave face that may be compressed to generate an electrical pulse. The flextensional electroactive member and associated signal generation circuitry can be hardwired directly to the latching relay or may be coupled to a transmitter for sending an RF signal to a receiver which actuates the latching relay.

A power generation switch comprising: a case; a core, a coil being wound around the core; a magnet magnetically connected with the core; a yoke in which the magnet is disposed; an elastic element that supports the yoke and elastically deforms so as to deviate a position of the magnet from the core; a switch element that is operated to be moved; and a yoke driving mechanism that moves the yoke so that upon an engagement of the switch element and the yoke being released, the yoke moves between a first position and a second position due to elastic force of the elastic element, wherein first magnetic flux is generated by the core and the magnet when the yoke is at the first position and second magnetic flux different from the first magnetic flux is generated by the core and the magnet when the yoke is at the second position.

Provision is made for a switching device for a wireless switch. The switching device comprises actuating means for receiving a mechanical energy, which can be introduced during a switching operation into the switching device. Furthermore, the switching device with the actuating means and with an energy conversion device comprises mechanically connectible switching means for transmitting the mechanical energy from the actuating means to the energy conversion device, in order to convert the mechanical energy to an electrical energy for transmitting a switching signal. At the same time, the switching means are designed to be actuated during a switching operation by means of the actuating means, in order to transfer, when connected with the energy conversion device, the energy conversion device at least from a first stable condition to a second stable condition, which is different from the first stable condition, in order to produce at least one electrical energy impulse.

An electro-mechanical energy harvesting switch configured to provide at least two different control signals comprises: a generator activating member (9) configured to move between a rest position and a maximum loaded position; at least one spring (11, 13) configured to force the generator activating member towards the rest position; and a unidirectionally rotating protrusion member (17) comprising at least one protrusion (21) configured to move through a protrusion's path during rotation of the protrusion member (17), through a first position of the protrusion (21), in which first position the protrusion (21) is engaged with the generator activating member (9) in the rest position, and through a second position, the protrusion (21) thereby carrying the generator activating member (9) from the rest position to the maximum loaded position against the force of the at least one spring (11, 13).

A power generation switch apparatus including multiple switch keys, a power generation apparatus that is driven to perform power generation by an operation force applied to the multiple switch keys, multiple switches being supplied with an electric power generated by the power generation apparatus and performing a switching movement by an operation of the multiple switch keys, and a switch signal transmission circuit being driven by the electric power from the power generation apparatus and outputting multiple switch signals that are different from each other in correspondence with the switching movement of the multiple switches.