A backlight keyswitch includes a cap with a symbol, and a backlight module under the cap and having first and second light modifying layers, a light guide plate, a light-blocking sheet having a transparent region corresponding to the cap, and first, third, and second lighting units arranged sequentially along a longitudinal direction for emitting first, third, and second color lights. The first and second light modifying layers might be ink layers formed on the light-blocking sheet and located outside the first and second lighting units, with colors of the first and second ink layers at least corresponding to colors of the second and first color lights respectively to achieve a mixed color. Alternatively, the first and second light modifying layers might be adhesive layers arrange parallel to the light guide plate, the first and second adhesive layers scattering a respective one of the first and second color light.

A waterproof electronic device includes a keyboard module, a first case and a first waterproof layer. The keyboard module has a plurality of key caps. The first case is disposed over the keyboard module and the first case has a top surface. The top surface of the first case has a plurality of first opening exposing the key caps. The first waterproof layer covers the top surface of the first case and the key caps, and the first waterproof layer includes a fabric layer and a waterproof adhesive layer.

A keyboard device has a base sheet, a membrane sheet disposed on the upper surface of the base sheet, a cover sheet disposed on the upper surface of the membrane sheet and supporting the membrane sheet between the cover sheet and the base sheet in a state of being movable in the in-plane direction, connection members connecting the base sheet and the cover sheet, a plurality of key tops vertically movably supported by a guide mechanism provided on the upper surface side of the cover sheet and bringing a movable contact and a fixed contact which are contacts of the membrane sheet into contact with each other or separating the contacts from each other by being depressed, and a frame member partitioning the key tops adjacent to each other by being depressed and having a lower surface to which the upper surface of the cover sheet is bonded and fixed.

A novel conducting structure and conducting method for an upper sheet and a lower sheet of a film button circuit. A first upper sheet conducting layer and a second upper sheet conducting layer are coated in sequence on an upper sheet conducting contact point. A first lower sheet conducting layer and a second lower sheet conducting layer are coated in sequence on a lower sheet conducting contact point. The first upper sheet conducting layer, the second upper sheet conducting layer, the second lower sheet conducting layer and the first lower sheet conducting layer are overlapped in sequence, thereby forming a composite conducting layer that is slightly greater than a back glue layer in thickness. The present invention can simplify assembly processes and can improve the production efficiency.

A keyboard device has a base sheet, a membrane sheet disposed on the upper surface of the base sheet, a cover sheet disposed on the upper surface of the membrane sheet and supporting the membrane sheet between the cover sheet and the base sheet in a state of being movable in the in-plane direction, connection members connecting the base sheet and the cover sheet, a plurality of key tops vertically movably supported by a guide mechanism provided on the upper surface side of the cover sheet and bringing a movable contact and a fixed contact which are contacts of the membrane sheet into contact with each other or separating the contacts from each other by being depressed, and a frame member partitioning the key tops adjacent to each other by being depressed and having a lower surface to which the upper surface of the cover sheet is bonded and fixed.

Embodiments are directed to a keyboard or other input structure having a continuous fiber material. In one aspect, the continuous fiber material is disposed in a layered fiber pattern under tension. The continuous fiber material is continuous in that it is not broken or severed within the webbing. Heat and pressure are then applied to form a structural web. The resulting structural web may be stronger than a webbing of conventional materials yet with reduced relative weight.

The invention relates to a remote control (1, 48) comprising: a first data read-in device (24, 78) and a second data read-in device (24, 78) which are each designed to read in data in a pressure direction (20, 61) on the basis of a pressure exerted by a user, a first pressure take-up element (30) assigned to the first data read-in device (24, 78) and a second pressure take-up element (30, 85) assigned to the second data read-in device (24, 78), which elements each have a pressure take-up side (35, 89) for taking up the pressure applied by the user, and a pressure output side for outputting the pressure, which was taken up, to the respective data read-in device (24, 78); and a flexible printed circuit board (31, 86, 97) which connects the pressure take-up sides (35, 89) of the pressure take-up elements (30, 85) to each other and on which at least one capacitive measurement transducer (38, 39, 93, 94) is formed whose capacitance is dependent on the position of a finger of the user on the flexible printed circuit board (31, 86, 97).

A dome switch includes a first release membrane, a dome, a shim, and a second release membrane, the dome is mounted at an underside of the first release membrane, the second release membrane seals one end of a through opening of the shim, when the dome switch is mounted on a circuit board, a sealed space can be formed, ensuring that in the manufacture process of a smart card, the glue will not flow into the dome and hence the second release membrane will not be connected and adhered to the glue within the card, which may otherwise result in poor hand-tactile impression of the switch. The dome switch and the smart card with the dome switch presents good hand-tactile impression; the production rate is high and the rejection rate and the production cost are low.

A keyboard device includes a base plate, a key and a membrane circuit board. The key is connected with the base plate. The membrane circuit board is arranged between the key and the base plate. The base plate includes a connecting structure. The connecting structure is protruded upwardly and penetrated through the membrane circuit board. The key includes a keycap and a stabilizer bar. The stabilizer bar is pivotally coupled to the keycap. A hook part of the stabilizer bar is penetrated through a corresponding locking hole of the connecting structure. A film layer of the membrane circuit board includes an extension part. A gel layer is formed on the extension part. While the keycap is moved upwardly or downwardly relative to the base plate, the hook part of the stabilizer bar is moved on the gel layer.

A membrane switch and a method of manufacturing the same, includes upper and lower membranes printed with upper and lower conductive dots and an isolation layer between them, holes being opened in the isolation layer corresponding to the dots, the isolation layer is bonded with the upper and lower membranes respectively via the glue coated on the upper surface and the lower surface thereof; and the glue may employ hot melt glue. This method of manufacturing the membrane switch includes a coating the upper surface and/or lower surface of the isolation layer exclusive of the positions of the holes with glue; bonding and adhering the sides of the upper membrane and the lower membrane printed with the conductive dots and respectively to the upper surface and the lower surface of the isolation layer via glue, making the positions of the conductive dots and the holes corresponding to each other.