The invention relates to a key structure, and particularly, to a key structure that reduces noise when in use.
Keyboards are commonly used as an input device of an electronic device. To allow users to use a keyboard flexibly, a balance bar is usually disposed in a longer key structure to improve the structural strength and stability of keycaps. However, when the keycap moves up and down, usually the collision between the balance bar and the bottom plate generates noise. The noise problem caused by pressing the key structure needs to be further improved.
The invention provides a key structure with reduced noise when the key structure is pressed.
The key structure of the invention includes a bottom plate, a keycap, an elastic element, a first bracket, and a second bracket. The keycap is disposed on the bottom plate and has multiple first pivoting portions. The elastic element is disposed under the keycap. The first bracket is disposed between the keycap and the bottom plate, and the first bracket is pivotally connected to the first pivoting portions. The second bracket is disposed between the keycap and the bottom plate, and the second bracket is rotatably pivoted to the first bracket. The number of the first pivoting portions is greater than two.
In summary, in the key structure of the invention, multiple first pivoting portions are disposed on the keycap and connected to the first bracket, and the number of the first pivoting portions is greater than two, so the keycap may move up and down steadily relative to the bottom plate. Accordingly, the disposition of the original balance bar may be omitted or reduced, so as to eliminate or reduce the noise caused by the balance bar hitting elements, such as the bottom plate and the like when the key structure is pressed. Thereby, the effect of noise reduction is achieved, and the keycap may move up and down steadily relative to the bottom plate as well.
In order to make the features and advantages of the invention comprehensible, embodiments accompanied with drawings are described in detail below.
Reference will now be made in detail to the exemplary embodiments of the invention, examples of which are illustrated in the accompanying drawings. Whenever possible, the same reference numerals are used to represent the same or similar parts in the accompanying drawings and description.
In the embodiment, the thin film circuit board 160 is disposed on the bottom plate 110 and is located under the elastic element 130. The key structure 100A is movably connected to the bottom plate 110 through the bottom end of the first bracket 140 and the bottom end of the second bracket 150, respectively, and the top end of the first bracket 140 and the top end of the second bracket 150 are respectively movably connected to the keycap 120 so that the keycap 120 moves up and down smoothly relative to the bottom plate 110. For example, when the keycap 120 is pressed, the elastic element 130 is correspondingly squeezed and deformed and then presses down on the thin film circuit board 160 to trigger a switch to generate a pressing signal; and once the force pressing the keycap 120 is removed, the elastic restoring force of the elastic element 130 drives the keycap 120 to return upward to the original position.
In the embodiment, the key structure 100A is a multiple-width key (long key structure), such as a corresponding Enter key in the keyboard. However, in other embodiments, the key structure may also be a large-sized key corresponding to space key, Shift key, and backspace key in the keyboard.
Specifically, in the embodiment, the number of connections between the first bracket 140 and the keycap 120 is greater than two, and the number of connections between the second bracket 150 and the keycap 120 is greater than two. The number of connections between the first bracket 140 and the bottom plate 110 is greater than two, and the number of connections between the second bracket 150 and the bottom plate 110 is greater than two. Accordingly, manufacturers do not need to configure additional balance bars or may appropriately reduce the number of balance bars, so that the keycap 120 may move up and down steadily relative to the bottom plate 110.
In the key structure 100A of the embodiment, the disposition of the balance bar is omitted, so when the user presses the key structure 100A, there may be no noise caused by the balance bar hitting elements, such as the bottom plate 110 or the like, the noise reduction effect is achieved, and the keycap 120 may move up and down steadily relative to the bottom plate 110 as well.
Referring to
In the embodiment, the first pivoting portion 124 is pivotally connected to the top end of the first bracket 140, and the second pivoting portion 122 is pivotally connected to the top end of the second bracket 150. Specifically, the top end of the first bracket 140 includes a first top shaft portion 144 (four first top shaft portions are shown schematically) for being connected to the first pivoting portion 124. The second bracket 150 includes two rods 158 on two opposite sides of the second bracket 150 and a second top shaft portion 152 connected between the two rods 158. The second top shaft portion 152 is used for being pivotally connected to the second pivoting portion 122. In the embodiment, the two rods 158 have two recesses 156 facing each other for being pivotally connected to the two protrusions 146 of the first bracket 140.
Referring to
In the embodiment, the second pivoting portion 122 includes two engaging portions 1221 on two opposite sides of the keycap 120 and a middle engaging portion 1222, and the middle engaging portion 1222 is disposed between the two engaging portions 1221. The width of the middle engaging portion 1222 of the embodiment is greater than the width of the engaging portion 1221, and the middle engaging portion 1222 may be more firmly connected to the second top shaft portion 152 of the second bracket 150. In other embodiments, the number or the width of the middle engaging portion 1222 may be appropriately increased or adjusted to well match with the second top shaft portion 152 of the second bracket 150, so that the keycap 120 may move up and down steadily relative to the bottom plate 110.
Referring to
In the embodiment, the first hooking portion 112 is pivotally connected to the bottom end of the first bracket 140, and the second hooking portion 114 is pivotally connected to the bottom end of the second bracket 150. Specifically, the bottom end of the first bracket 140 includes multiple first bottom shaft portions 142 (four first bottom shaft portions are shown schematically) for being pivotally connected to the first hooking portion 112, and the bottom end of the second bracket 150 includes multiple second bottom shaft portions 154 (four second bottom shaft portions are shown schematically) for being pivotally connected to the second hooking portion 114. Meanwhile, the shapes of the first hooking portion 112 and the second hooking portion 114 are hook-shaped, for example. However, in other embodiments, the shapes of the first hooking portion 112 and the second hooking portion 114 may also be C-shaped or U-shaped. As long as the first hooking portion 112 and the second hooking portion 114 may be matched with the bottom end of the first bracket 140 and the bottom end of the second bracket 150 respectively, the shape design of the first hooking portion 112 and the second hooking portion 114 is not limited thereto.
Other embodiments are listed in the subsequent paragraphs for illustration. Note that the reference numerals and part of the content of the foregoing embodiment are used in the following embodiments, the same reference numerals are used to represent the same or similar elements, and the illustration of the same technical content is omitted. For the omitted illustration, refer to the foregoing embodiment, which is not iterated herein.
For example, a first pivoting portion 124B (six first pivoting portions are shown schematically) on a keycap 120B is connected to a first top shaft portion 144B (six first top shaft portions are shown schematically) of a first bracket 140B, and a second pivoting portion 122B is connected to a second top shaft portion 152B of a second bracket 150B. A first hooking portion 112B (six first hooking portions are shown schematically) on a bottom plate 110B is connected to a first bottom shaft portion 142B (six first bottom shaft portions are shown schematically) of the first bracket 140B, and a second hooking portion 114B (six second hooking portions are shown schematically) is connected to a second bottom shaft portion 154B (six second bottom shaft portions are shown schematically) of the second bracket 150B.
In the embodiment, the number of the pivoting portions on the keycap 120B and the number of the hooking portions on the bottom plate 110B are increased, and the number of connections between the top end and bottom end of a support element 10B and the keycap 120B and the bottom plate 110B, respectively, is increased, so that the keycap 120B moves up and down steadily relative to the bottom plate 110B. Accordingly, manufacturers do not need to configure additional balance bars or may appropriately reduce the number of balance bars, so as to eliminate or reduce the noise caused by the balance bar hitting elements, such as the bottom plate and the like, when the key structure is pressed. Thereby, the effect of noise reduction is achieved, and the keycap 120B may move up and down steadily relative to the bottom plate 110B as well.
In the embodiment, the first bracket 140C includes a first portion 1401 and a second portion 1402, and the material of the first portion 1401 is different from the material of the second portion 1402. The second bracket 150C includes a third portion 1501 and a fourth portion 1502, and the material of the third portion 1501 is different from the material of the fourth portion 1502. For example, the material of the first portion 1401 and the third portion 1501 is plastic, and the material of the second portion 1402 and the fourth portion 1502 is metal. When the key structure 100C of
Referring to
In the embodiment, the two opposite sides of the fourth portion 1502 include multiple second connecting portions C5 and C6, and the third portion 1501 covers the fourth portion 1502 and exposes the second connecting portions C5 and C6. In other words, the side of the fourth portion 1502 is not completely enclosed by the third portion 1501. Therefore, the second connecting portions C5 and C6 are respectively used to be connected to an external structure (not shown). Meanwhile, the external structure is a support part and a clamping part, for example. For example, the support part and the clamping part are structures used for positioning and fixing the structure of the inner scissor metal element and the structure of the outer scissor metal element (i.e., the second portion 1402 and the fourth portion 1502) in the mold.
Generally speaking, in the injection molding process, when metal elements are in contact with the mold, burrs may be generated. In the embodiment, the structure of the inner scissor metal element and the structure of the outer scissor metal element (i.e., the second portion 1402 and the fourth portion 1502) are connected to the external support part or clamping part through multiple first connecting portions and multiple second connecting portions. After the injection molding is completed, the first bracket 140C and the second bracket 150C may be taken out from the support part or the clamping part. Accordingly, the second portion 1402 of the first bracket 140C and the fourth portion 1502 of the second bracket 150C may be prevented from being in contact with the mold, so as to prevent burrs. Since the contact between the metal element and the plastic mold is prevented, the stability of the mold and the product may be improved, and the life of the mold may be improved.
Moreover, the external structures of the first bracket 140D and the second bracket 150D shown in
For example, the number of first hooking portions 112E of the bottom plate 110E is four, and the number of bottom shaft portions 142E of a first bracket 140E of the support element 10E is four. The first hooking portion 112E is pivotally connected to the bottom shaft portion 142E. For other portions of the key structure 100E, such as the keycap 120E, an elastic element 130E, a thin film circuit board 160E, and the like, refer to the foregoing description, which is not illustrated in detail in the embodiment.
As shown in
For example, in the embodiment, the number of first hooking portions 112F of the bottom plate 110F is six, the number of second hooking portions 114F is four, and the number of bottom shaft portions 142F of a first bracket 140F of the support element 10F is six. The bottom shaft portion 142F is pivotally connected to the first hooking portion 112F. The number of bottom shaft portions 154F of a second bracket 150F of the support element 10F is four, and the bottom shaft portion 154F is pivotally connected to the second hooking portions 114F. The number of first pivoting portions 124F on an inner surface S22 of the keycap 120F is six, the number of second pivoting portions 122F is six, and the number of top shaft portions 144F of the first bracket 140F of the support element 10F is six. The top shaft portion 144F is pivotally connected to the first pivoting portion 124F. The number of top shaft portions 152F of the second bracket 150F of the support element 10F is six, and the top shaft portion 152F is pivotally connected to the second pivoting portion 122F. For other portions of the key structure 100F, such as an elastic element 130F, a thin film circuit board 160F, and the like, refer to the foregoing description, which is not illustrated in detail in the embodiment.
In summary, the key structure of the invention is a multiple-width key, for example. The key structure includes the first bracket and the second bracket. The keycap moves up and down relative to the bottom plate through the first bracket and the second bracket. Multiple first pivoting portions are disposed on the keycap and connected to the first bracket, and the number of the first pivoting portions is greater than two, so the keycap may move up and down steadily relative to the bottom plate. Accordingly, the disposition of the original balance bar may be omitted or reduced, so as to eliminate or reduce the noise caused by the balance bar hitting elements, such as the bottom plate and the like when the key structure is pressed. Thereby, the effect of noise reduction is achieved, and the keycap may move up and down steadily relative to the bottom plate as well. On the other hand, the first bracket and the second bracket of the invention may be formed by a metal insert molding process to enhance the overall strength of the scissor-type support element.
It will be apparent to those skilled in the art that various modifications and variations can be made to the structure of the present invention without departing from the scope or spirit of the invention. In view of the foregoing, it is intended that the present invention cover modifications and variations of this invention provided they fall within the scope of the following claims and their equivalents.
Number | Date | Country | Kind |
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202121575608.9 | Jul 2021 | CN | national |
This application claims the priority benefit of U.S. provisional application Ser. No. 63/125,957, filed on Dec. 15, 2020 and China application serial no. 202121575608.9, filed on Jul. 12, 2021. The entirety of the above-mentioned patent applications is hereby incorporated by reference herein and made a part of this specification.
Number | Date | Country | |
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63125957 | Dec 2020 | US |