In a switch unit which is equipped with a seesaw switch and a rotary switch, the seesaw switch and the rotary switch are arranged in a manner so that an axis of a swing fulcrum, i.e., swing shaft, of a knob, and an axis of a rotary shaft of a wheel intersect one another.

The present disclosure provides lighting control system multi-switch apparatuses and methods. The apparatus includes a lighting control module including at least three electrical terminals. The lighting control module configured to cause a transmission of a quantity of electrical energy to a lighting circuit of a light fixture electrically connected to the lighting control module. The apparatus includes a detector circuit positioned in the lighting control module. The apparatus includes a controller in electrical communication with the detector circuit, the controller specially programmed to cause a call signal to be transmitted to a switch connected to the traveler terminal, the call signal configured to request the switch connected to the traveler terminal transmit a response signal to the controller to identify the switch connected to the traveler terminal.

An operation device driven by an internal battery includes: a casing; an operation element; a mechanical switch; a pressing part; and a support part. The operation element is located on a plane continuing from a front surface of the casing. The mechanical switch is disposed in the casing such that a distance between the mechanical switch and the operation element is fixed. The mechanical switch has a flexible region located to oppose to a rear surface of the casing. The pressing part is located between the mechanical switch and an attachment surface, and presses the flexible region from a side opposite from the operation element. The support part supports the casing such that a distance between the operation element and the attachment surface is changeable.

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.

A switch device includes a push switch including first and second push portions that are parallel arranged, and an operating switch arranged between the first and second push portions and including a switch operation direction different from a switch operation direction of the first and second push portions. The operating switch protrudes from an operation surface of the first and second push portions so as to allow the first and second push portions to be individually recognized when operating the push switch.

A locking assembly for locking a switch is provided. According to a preferred embodiment, a locking member is connected to a support member having a plurality of first grooves, a lower receiving element, a retaining tab, a resilient member and a fastening element. Preferably, the lower receiving element includes a securing socket element having at least a second groove and a third groove. According to a preferred embodiment, the fastening element preferably secures the locking member, the lower receiving element, and the resilient member with a panel to form a locking assembly that automatically locks the switch when the switch is in a selected 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.

A switch device includes a push switch including first and second push portions that are parallel arranged, and an operating switch arranged between the first and second push portions and including a switch operation direction different from a switch operation direction of the first and second push portions. The operating switch protrudes from an operation surface of the first and second push portions so as to allow the first and second push portions to be individually recognized when operating the push switch.

An operation device driven by an internal battery includes: a casing; an operation element; a mechanical switch; a pressing part; and a support part. The operation element is located on a plane continuing from a front surface of the casing. The mechanical switch is disposed in the casing such that a distance between the mechanical switch and the operation element is fixed. The mechanical switch has a flexible region located to oppose to a rear surface of the casing. The pressing part is located between the mechanical switch and an attachment surface, and presses the flexible region from a side opposite from the operation element. The support part supports the casing such that a distance between the operation element and the attachment surface is changeable.

A non-mechanical-interfacing electronic switch or a mechanical-interfacing electronic switch are controlled to modulate between an active state and an inactive state based on electronic action. The switch includes an aperture defining an opening in a housing, and the opening defines an insertion path. A transmitter transmits a signal to a receiver along a signal path. To control the non-mechanical-interfacing electronic switch, a mechanical lockout device having a protrusion is inserted through the opening of the aperture along the insertion path. To control the mechanical-interfacing electronic switch, a mechanical control part have a protrusion is moveable to interrupt the signal. Methods of locking the non-mechanical-interfacing electronic switch with the mechanical lockout device as well as methods of locking the mechanical control part of the mechanical interfacing electronic switch with the mechanical lockout device are also provided.