A key switch includes a baseplate, a circuit layer, a keycap and a support rod. The baseplate has a hook and a first through hole neighboring to the hook. The circuit layer includes a first sublayer disposed above the baseplate and having a second through hole, and a second sublayer disposed above the first sublayer and having a third through hole; a portion of the second sublayer extends over the second through hole and forms a first resilient portion; the first resilient portion has four sides, two of which connect to the second sublayer; and the first resilient portion is neighboring to the hook. The keycap is disposed above the baseplate and can move upward and downward in respect to the baseplate. The support rod has a first portion and a second portion; the first portion movably connects to the keycap and the second portion engages the hook.

A long keyboard key device includes a base plate, a keycap, and a support unit disposed between the base plate and the keycap and including outer and inner frame members that are pivotally connected together. The outer frame member has a frame body, two first engaging parts engaging rotatably first pivotal mounting brackets of the base plate, and a first balance rod embedded in the frame body and having a plurality of engaging sections that engage rotatably first clips of the keycap. The inner frame member has a frame plate, a plurality of second engaging parts engaging rotatably second pivotal mounting brackets of the base plate, and a plurality of third engaging parts engaging rotatably second clips of the keycap.

An electronic device can include a first electronic component, a second electronic component, and an energy dampener positioned between and in contact with the first electronic component and the second electronic component. The energy dampener in this example includes a carbon nanotube-aerogel matrix including carbon nanotubes embedded in an aerogel with a rubber composited therewith.

A key module includes a base plate, a circuit layer and a lifting mechanism. The circuit layer is disposed on the base plate. The lifting mechanism is pivotally connected with the base plate relative to the circuit layer, and the lifting mechanism has an abutment element. The abutment element could interfere with the circuit layer to reduce the noise generated by the key module during operation.

A key structure includes a bottom plate, a keycap, a lifting mechanism, a thin-film switch layer and a backlight module. The bottom plate has a through hole. The lifting mechanism is pivotally connected to the bottom plate and the keycap. The thin-film switch layer has a reflective structure corresponding to the through hole. The backlight module includes a light source and a reflective layer. The light source is configured to emit light towards the reflective structure. The reflective layer is disposed surrounding the light source to reflect a reflected light from the reflective structure to the thin-film switch layer.

A key structure including a keycap, a bottom plate, a supporting element disposed on the bottom plate a backlight module, and a thin film circuit board is provided. The bottom plate includes a body and a plurality of protrusions, wherein the body has a plurality of openings, and the protrusions protrude from a first surface of the body and are disposed around the openings. At least two of the protrusions have different heights. The backlight module is disposed on a second surface of the body, wherein the first surface and the second surface are opposite surfaces. The thin film circuit board and the keycap are disposed on the first surface of the body, and the thin film circuit board is located between the keycap and the bottom plate, and the protrusions are located within an orthographic projection range of the keycap and do not contact the supporting element.

Disclosed are a control panel provided on an apparatus to control the apparatus and a clothes treating apparatus having the same. The clothes treating apparatus includes a includes a cabinet; a drum provided within the cabinet and configured to receive clothes; a driving unit that rotates the drum; a power supply unit that supplies power to the driving unit; and a control panel located on the cabinet. The control panel includes a panel body that defines the external appearance of the control panel; a printed circuit board (PCB) located adjacent to the panel body; input units; and an anti-separation unit located on at least one of the panel body and the PCB and configured to restrict the connection damper from being separated from the bar.

Systems and methods for forming button assemblies for electronic devices are disclosed. According to some embodiments, the button assemblies include one or more sound improvement features to improve the sound that the button assemblies make when pressed by users of the electronic devices. According to some embodiments, the button assemblies include shims that provide proper alignment of the various components of the button assemblies and to accommodate any tolerance stack up of the various components of the button assemblies. The shims can include alignment features to prevent the shims from shifting within the button assemblies. According to some embodiments, thicknesses of the shims are customized to accommodate varying tolerance stack ups of the components of the button assemblies. In some embodiments, the button assemblies include a combination of sound improvement features and shims.

A keyboard device with an upper housing and an under housing is disclosed, which includes a stopping piece integrally formed on the upper housing and having an upper surface and a lower surface, a key top having a side portion and an operating piece having an operating portion, and a first silencing pad disposed between the operating portion and the lower surface.

Embodiments of the present invention provide switch cells that use a non-electrical tactile feedback pad to adjust the tactile feel of the included switches. As a non-limiting advantage, separating the tactile feedback pad from the electrical switching operation allows the electrical contacts to be configured for high-current applications while relying on the tactile feedback pad to define or “tune” the tactile feel of the switch cell. Moreover, the same switch cell design may be used to meet a variety of tactile feel requirements, simply by installing different tactile feedback pads. That is, the same switch cell can be reconfigured to have a different tactile response curve simply by changing out the tactile feedback pad(s) used in the switch cell, without affecting the electrical characteristics of the switch cell.