A switch device includes an operating knob on which a tilting operation is performed, a detected portion that tilts with the tilting operation of the operating knob, a detection portion that detects movement of the detected portion, and a substrate on which the detection portion is arranged. The detection portion is aligned in an in-plane direction of the substrate and performs a switching operation upon detection of movement of the detected portion in the in-plane direction.

A power seat operating device for a vehicle has a switch module for operating a power seat of the vehicle. In particular, the switch module includes a plurality of seesaw type switches to control operation directions of the power seat, and the operation directions of the power seat according to the operation of each switch is displayed with arrows on a display, thereby improving the switch operating convenience of the user such as accurately controlling the operation direction of the power seat according to the switch operation by the user, and accurately recognizing a selection state and an operation direction of the switch desired by the user.

An intelligent hybrid touch display device, including: a touch display unit; a rotary mechanical switch, being integrated with the touch display unit in a body; and a control unit, located in the body and including: a first interface for driving the touch display unit; a second interface coupled with the rotary mechanical switch; a touch and switch detection unit coupled with the first interface and the second interface; a transmission interface for communicating with at least one external device; and a processor and an operating system stored in a memory, the processor being coupled with the touch and switch detection unit and the transmission interface, and being used for executing a control program with a support of the operating system, so that the touch display unit and the rotary mechanical switch can cooperate to provide a hybrid operation for selecting, changing or activating function options.

An electrical load control device such as, for example, an electrical switch is disclosed. In use, the electrical device includes a manual switch or mechanical actuator positioned with an opening or aperture of a front cover of the device, the manual switch or actuator being arranged and configured to manipulate a connected load. The electrical device includes one or more geometries, surface features, or spacers arranged and configured within the aperture of the front cover. During use, the geometries, surfaces features, or spacers are arranged and configured to interact with the manual switch or actuator to reposition and/or align the switch or actuator within the aperture so that a consistent and uniform gap or spacing is maintained between the outer perimeter of the switch or actuator and the inner surface of the aperture. In one embodiment, the geometries, surfaces features, or spacers may be positioned within one or more of the corners of the aperture.

A hybrid touch button, including: a touch display unit having a touch display area; a mechanical switch having a plurality of conductive contacts; and a control unit, having a power interface for coupling with a power source, a first interface coupled with the touch display area, a second interface coupled with the plurality of conductive contacts, and an output interface, wherein the control unit derives first input information from the first interface and second input information from the second interface, and determines an output configuration of the output interface according to the first input information and the second input information.

A power seat operating device for a vehicle has a switch module for operating a power seat of the vehicle. In particular, the switch module includes a plurality of seesaw type switches to control operation directions of the power seat, and the operation directions of the power seat according to the operation of each switch is displayed with arrows on a display, thereby improving the switch operating convenience of the user such as accurately controlling the operation direction of the power seat according to the switch operation by the user, and accurately recognizing a selection state and an operation direction of the switch desired by the user.

A button assembly includes a pedestal, a pressure sensor module and a key cap. The pedestal has an accommodating groove penetrating upward through a top surface of the pedestal. Two opposite sides of the pedestal protrude oppositely outward to form a lower active portion and a lower pivot portion. The pressure sensor module is mounted in the accommodating groove. The key cap is covered on the pressure sensor module. A bottom surface of the key cap has a contact portion contacting with the pressure sensor module. Two opposite sides of the key cap protrude oppositely outward to form an upper active portion and an upper pivot portion. The upper pivot portion rotate pivoting the lower pivot portion, the upper active portion moves downward and upward with respect to the lower active portion.

A switch device includes an operating knob on which a tilting operation is performed, a detected portion that tilts with the tilting operation of the operating knob, a detection portion that detects movement of the detected portion, and a substrate on which the detection portion is arranged. The detection portion is aligned in an in-plane direction of the substrate and performs a switching operation upon detection of movement of the detected portion in the in-plane direction.

A button assembly is disposed in a rocker. The button assembly including a base, a pressure sensor and a keycap. The base has two lower pivoting portions with each of the two lower pivoting portions protruding outwardly from respective sides of the base. The pressure sensor is mounted on the base. The keycap overlies the pressure sensor. The keycap has two upper pivoting portions with each of the two upper pivoting portions protruding outwardly from respective sides of the keycap. The two lower pivoting portions are pivoted with the two upper pivoting portions to allow the two upper pivoting portions to be rotatable relative to the two lower pivoting portions. As described above, a push-button structure is thus formed by the two lower pivoting portions and the two upper pivoting portions configured among the base, the pressure sensor and the keycap to achieve the modularization of the button assembly.

A button assembly is disposed in a rocker. The button assembly including a base, a pressure sensor and a keycap. The base has two lower pivoting portions with each of the two lower pivoting portions protruding outwardly from respective sides of the base. The pressure sensor is mounted on the base. The keycap overlies the pressure sensor. The keycap has two upper pivoting portions with each of the two upper pivoting portions protruding outwardly from respective sides of the keycap. The two lower pivoting portions are pivoted with the two upper pivoting portions to allow the two upper pivoting portions to be rotatable relative to the two lower pivoting portions. As described above, a push-button structure is thus formed by the two lower pivoting portions and the two upper pivoting portions configured among the base, the pressure sensor and the keycap to achieve the modularization of the button assembly.