The present invention relates to a keyswitch structure and a keyboard, and more particularly to a keyswitch structure with protective outer layer and a keyboard with the keyswitch structure.
Common keyboards have a plurality of keycaps for users to press for input. The keycap usually has some characters (including text, symbols, and so on) thereon, for users to recognize and press the keycap quickly and correctly. The Characters can be formed by printing, engraving, hollowed-out layered structures, etc., and have a spatial structure. When a finger touches and presses the keycap, the finger may rub the characters. After long-term rubbing, the characters may be damaged or even disappear. Some keyboards have a protective outer layer that covers all keycaps. However, when the finger touches and presses the protective outer layer corresponding to the keycap to be pressed, the portion of the protective outer layer may still rub the characters on the keycap. Similarly, after long-term rubbing, the characters will still be damaged or even disappear.
An objective of the invention is to provide a keyswitch structure, which uses a rigid light-transmissive cover sheet to cover a character structure to protect the character structure.
A keyswitch structure according to the invention includes a switch and a multilayer structure disposed above the switch. The multilayer structure includes an inner flexible layer, a rigid light-transmissive cover sheet, and a flexible light-transmissive layer. The inner flexible layer has a keycap portion and a connection portion extending outward from the keycap portion. The keycap portion is located above the switch and forms a spatial character structure. The rigid light-transmissive cover sheet is disposed on the keycap portion and covers the spatial character structure. The flexible light-transmissive layer covers the inner flexible layer and the rigid light-transmissive cover sheet. Thereby, the rigid light-transmissive cover sheet can protect spatial character structure from structural damage caused by rubbing when the flexible light-transmissive layer is pressed by a finger of a user.
An objective of the invention is to provide a keyboard, which includes the above keyswitch structure and therefore can use the rigid light-transmissive cover sheet to protect the character structure.
A keyboard according to the invention includes a keyswitch structure and a device casing carrying the keyswitch structure. The keyswitch structure includes a switch and a multilayer structure disposed above the switch. The multilayer structure is fixed to the device casing and includes an inner flexible layer, a rigid light-transmissive cover sheet, and a flexible light-transmissive layer. The inner flexible layer has a keycap portion and a connection portion extending outward from the keycap portion. The keycap portion is located above the switch and forms a spatial character structure. The rigid light-transmissive cover sheet is disposed on the keycap portion and covers the spatial character structure. The flexible light-transmissive layer covers the inner flexible layer and the rigid light-transmissive cover sheet. Similarly, the rigid light-transmissive cover sheet can protect spatial character structure from structural damage caused by rubbing when the flexible light-transmissive layer is pressed by a finger of a user.
These and other objectives of the present invention will no doubt become obvious to those of ordinary skill in the art after reading the following detailed description of the preferred embodiment that is illustrated in the various figures and drawings.
Please refer to
The keyboard body 12 includes a device casing 122, and a bottom plate 124, a plurality of keycaps (including a first keycap 126a and a second keycap 126b), a plurality of lift mechanisms (including a first lift mechanism 128a and a second lift mechanism 128b), a switch circuit board 130, and a plurality of resilient restoration parts (including a first resilient restoration part 132a and a second resilient restoration part 132b) which are carried by the device casing 122. The device casing 122 includes an upper casing 1222 and a lower casing 1224. The upper casing 1222 and the lower casing 1224 are connected to form an accommodating space 122a. The bottom plate 124 is placed on the lower casing 1224 in the accommodating space 122a. The plurality of keycaps are disposed above the bottom plate 124 and exposed from the upper casing 1222. The plurality of lift mechanisms are connected to and between the keycaps and the bottom plate 124, so that the plurality of keycaps can move up and down relative to the bottom plate 124 in a vertical direction Dv (indicated by a double-headed arrow). Each keycap corresponds to one lift mechanism, e.g., scissors supports, butterfly supports, or other mechanisms capable of moving the corresponding keycap up and down. In practice, the lift mechanism of the longer keycaps (such as the space bar, the enter key, the backspace key, the shift key) can be achieved by a plurality of scissors supports, butterfly supports, or a combination thereof. The switch circuit board 130 is placed on the bottom plate 124 in the accommodating space 122a and has a plurality of switches (including a first switch 130a and a second switch 130b). Each switch corresponds to one keycap. In practice, the longer keycap can correspond to multiple switches. The plurality of resilient restoration parts are disposed between the plurality of keycaps and the bottom plate 124 in the accommodating space 122a. Each resilient restoration part corresponds to one keycap. In practice, the longer keycap can correspond to multiple resilient restoration parts. The resilient restoration part can be squeezed (e.g. by the corresponding downwardly moving keycap) to elastically deform. The resilience of the squeezed resilient restoration part can drive the corresponding keycap to move upward and return to its original position.
Therein, the upper casing 1222 is a structural frame. The first keycap 126a is located above the first switch 130a and exposed from a first window 1222a of the upper casing 1222 (which communicates with the accommodating space 122a). The first lift mechanism 128a is connected to and between the first keycap 126a and the bottom plate 124. The first resilient restoration part 132a is located between the first keycap 126a and the first switch 130a. When the first keycap 126a moves toward the first switch 130a in the vertical direction Dv (e.g., by a user pressing the first keycap 126a through the multilayer structure 14), the first keycap 126a squeezes the first resilient restoration part 132a to trigger the first switch 130a. When the first keycap 126a is no longer pressed, the first resilient restoration part 132a will rebound to drive the first keycap 126a to move upward and return to its original position. Similarly, the second keycap 126b is located above the second switch 130b and exposed from a second window 1222b of the upper casing 1222 (which communicates with the accommodating space 122a). The second lift mechanism 128b is connected to and between the second keycap 126b and the bottom plate 124. The second resilient restoration part 132b is located between the second keycap 126b and the second switch 130b. When the second keycap 126b moves toward the second switch 130b in the vertical direction Dv, the second keycap 126b squeezes the second resilient restoration part 132b to trigger the second switch 130b. When the second keycap 126b is no longer pressed, the second resilient restoration part 132b will rebound to drive the second keycap 126b to move upward and return to its original position. Furthermore, in the first embodiment, the projection of the first keycap portion 1422 of the multilayer structure 14 (in which the first keycap portion 1422 is the portion of the inner flexible layer 142 corresponding to the first keycap 126a) on the upper casing 1222 in the vertical direction Dv is within the first window 1222a. The projection of the second keycap portion 1424 of the multilayer structure 14 (in which the second keycap portion 1424 is the portion of the inner flexible layer 142 corresponding to the second keycap 126b) on the upper casing 1222 in the vertical direction Dv is within the second window 1222b.
Furthermore, in the first embodiment, the switch circuit board 130 is achieved by a membrane circuit board which includes an upper circuit substrate, a lower circuit substrate, and an intermediate insulation sheet disposed between the upper circuit substrate and the lower circuit substrate. The switch is achieved by contacts oppositely disposed on the upper circuit substrate and the lower circuit substrate; for simplification of drawing, the switch is shown by a single block in the figures. In practice, the switch circuit board 130 may also be achieved by other structures, e.g., disposing a tactile switch on a printed circuit board or flexible circuit board. For another example, opposite contacts are formed on a circuit board as a switch. The resilient restoration part has a conductive portion, so that when the resilient restoration part is squeezed downward, the conductive portion can conduct the contacts. In addition, in practice, the switch may be triggered by other structures. For example, in the view point of
As shown by
Thereby, when the user presses the first keycap 126a, the user's finger actually touches the portion of the multilayer structure 14 (or the flexible light-transmissive layer 144) corresponding to the first keycap 126a. Even during the pressing process, the finger may rub the multilayer structure 14. Under the protection of the first rigid light-transmitting cover sheet 146, the first spatial character structure 1422a will not be affected by the rubbing of the finger, at least reducing structural damage to the first spatial character structure 1422a (including structural deformation of the first spatial character structure 1422a) caused by rubbing of the finger. Similarly, the second rigid light-transmissive cover sheet 148 also has the same protective effect on the second spatial character structure 1424a, which will not be repeated. In addition, for simplification of drawing and description, the first embodiment is based on that the first keycap 126a and the second keycap 126b have the first spatial character structure 1422a and the second spatial character structure 1424a respectively; however, it is not limited thereto in practice. For example, the multilayer structure 14 may has a spatial character structure and a corresponding rigid light-transmissive cover sheet for each keycap, which will not described in addition.
Furthermore, as shown by
Furthermore, as shown by
Furthermore, in the first embodiment, the inner flexible layer 142 is made of an opaque material, for example but not limited to woven fabrics, thermoplastic polyurethanes (TPU), polyurethane (PU) and so on. The first spatial character structure 1422a is a holed structure. The first keycap 126a is light-transmissive; for example, the entire first keycap 126a may be made of a light-transmissive material, or only the portion of the first keycap 126a corresponding to the holed structure is light-transmissive. The keyboard body 12 includes a light source 134a (or referred to as a first light source 134a), disposed under the first keycap 126a corresponding to the first spatial character structure 1422a. Light emitted by the light source 134a can travel upward to pass through the first keycap 126a, the first spatial character structure 1422a, the first rigid light-transmissive cover sheet 146, and the flexible light-transmissive layer 144 to be emitted from the multilayer structure 14, which can provide the user with a visual effect. Similarly, the second spatial character structure 1424a may also be a holed structure. The second keycap 126b may light-transmissive. The keyboard body 12 includes another light source 134b (or referred to as a second light source 134b), disposed under the second keycap 126b corresponding to the second spatial character structure 1424a. Light emitted by the light source 134b can travel upward to pass through the second keycap 126b, the second spatial character structure 1424a, the second rigid light-transmissive cover sheet 148, and the flexible light-transmissive layer 144 to be emitted from the multilayer structure 14, which can provide the user with visual effects. The first and second light sources 134a and 134b (for example but not limited to light-emitting diodes) are disposed on a printed circuit board or flexible circuit board under the bottom plate 124. Therein, in order to enable the light emitted by the first and second light sources 134a and 134b to travel upward, the bottom plate 124 forms holes corresponding to the light sources 134a and 134b. In practice, the light sources 134a and 134b may also be integrated onto the switch circuit board 130. In addition, if the first and second resilient restoration parts 132a and 132b covers the first and second light sources 134a and 134b, the first and second resilient restoration parts 132a and 132b may be made of a light-transmissive material, for example but not limited to light-transmissive rubber domes.
Furthermore, in practice, the profile of the first spatial character structure 1422a may be text, symbols, numbers, graphics, etc. The second spatial character structure 1424a may also be the same, which will not be repeated. In addition, in practice, the first spatial character structure 1422a is not limited to provide the user with a visual effect through light transmission. For example, the first spatial character structure 1422a is achieved by a recess in which a light reflective material is disposed. For this instance, the first keycap 126a does not need to be light transmissive; therein, the recess may be formed by the first keycap portion 1422 alone (e.g. by embossing the first keycap portion 1422), or may be formed jointly by the first keycap 126a (or the horizontal keycap surface 1262a thereof) and the opening formed by the first keycap portion 1422. In addition, the inner flexible layer 142 is opaque and therefore can be used as a light-blocking layer which blocks light (from the light sources 134a and 134b) escaping from the periphery of the first keycap 126a and the second keycap 126b.
In the first embodiment, the first keycap portion 1422 is fixed on the horizontal keycap surface 1262a by means of glue (for example but not limited to an adhesive layer 143). The connection portion 1426 is also fixed on the rigid frame sheet 150 by means of glue (i.e., by the adhesive layer 151a). The first rigid light-transmissive cover sheet 146 is also fixed on the first keycap portion 1422 by means of glue (for example but not limited to an adhesive layer 147). Therein, the above adhesive layers 143, 147, 151a and 151b are shown only in
In addition, in the first embodiment, the keyboard 1 includes a plurality of keycaps, and thus the structure of the keyboard 1 is multiple keyswitch structures. In logic, one keycap and the corresponding structure can be regarded as a single-key keyswitch structure, e.g. the single-key keyswitch structures 10a and 10b indicated by dashed frames in
Furthermore, in the first embodiment, the multilayer structure 14 covers the upper casing 1222; however, it is not limited thereto in practice. For example, as shown by
Furthermore, in the first embodiment, the keycap (e.g. the first keycap 126a) is supported by a lift mechanism (e.g. the first lift mechanism 128a) and a resilient restoration part (e.g. the first resilient restoration part 132a); however, it is not limited thereto in practice. For example, the first keycap 126a is supported only by the first resilient restoration part 132a. For another example, if the multilayer structure 14 itself can maintain the shape of the keycap (for example, the first rigid light-transmissive cover sheet 146 can increase the structural rigidity), the can be further omitted so that the first resilient restoration part 132a directly abuts the first keycap portion 1422, as shown by
In addition, in the keyboard 1, the multilayer structure 14 may be formed by, but not limited to, laminating sheet materials and shaping in practice. For example, as shown by
As shown by
As shown by
As described above, when the user presses the keycap, the user's finger actually touches the portion of the multilayer structure (or the flexible light-transmissive layer) corresponding to the keycap. Even during the pressing process, the finger may rub the multilayer structure. Under the protection of the rigid light-transmitting cover sheet, the spatial character structure will not be affected by the rubbing of the finger, at least greatly reducing structural damage to the spatial character structure (including structural deformation of the first spatial character structure) caused by rubbing of the finger.
Those skilled in the art will readily observe that numerous modifications and alterations of the device and method may be made while retaining the teachings of the invention. Accordingly, the above disclosure should be construed as limited only by the metes and bounds of the appended claims.
Number | Date | Country | Kind |
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109136369 | Oct 2020 | TW | national |