JP2021096894A - Keyboard device - Google Patents

Abstract

To achieve noise reduction by suppress an increase in a clearance between a second shaft part and inside upper surface of a hole in a bracket by wear to a membrane sheet caused by repetitive sliding of the second shaft part of a balance bar as well as noise generation by collision of a second shaft part with a bracket for maintenance of noise reduction.SOLUTION: A second shaft part 16b of a balance bar 16 retained to be rotatable and slidable by a bracket 19 is supported on a shaft support part 17 provided at a sheet 14a of a membrane sheet 14. Thus, the membrane sheet 14 can suppress wear caused by sliding of the second shaft part 16b, thereby maintaining suppression of collision noise between the second shaft part 16b and the bracket 19.SELECTED DRAWING: Figure 1

Description

The present invention relates to a keyboard device.

A keyboard device is generally used as an input device for a computer. The keyboard device has a configuration in which a plurality of keys are arranged according to a predetermined arrangement. Each key generally has a key top and a scissors portion and a rubber dome that support the key top so as to be able to move up and down, and the scissors portion and the rubber dome are the key tops in the membrane sheet supported by the support sheet metal. It is provided directly below.

Keyboard devices also have a balance bar on keys that have a wider key top than other keys, such as the space bar, shift key, and click buttons used in laptop computers. .. This balance bar is arranged between the key top and the support sheet metal, and raises and lowers the key top while maintaining a posture parallel to the support surface of the support sheet metal.

The balance bar has a first shaft portion that extends along the longitudinal direction of the key top and is rotatably supported by the back surface of the key top, and a rotation shaft that is distant from both sides of the first shaft portion. It has a configuration in which a second shaft portion arranged parallel to and coaxially with the rotation axis of the one shaft portion is integrally formed. The second shaft portion is rotatably held by a bracket formed on the support sheet metal and constituting the bearing portion, and is movably held in a direction parallel to the support surface of the support sheet metal. As a result, in the balance bar, the second shaft portion swings around the rotation axis of the first shaft portion pivotally supported on the back surface of the key top as the balance bar moves up and down by pressing the key top. , The second shaft portion reciprocates in the horizontal direction in the bearing portion formed on the bracket. Since this horizontal operation is performed simultaneously on both sides of the key top in the longitudinal direction, the key top always moves up and down in parallel with the support surface of the support sheet metal. As a result, the rigidity of the key top is increased, twisting is suppressed, and the key top acts to complement the link mechanism of the scissors portion. Therefore, in a wide key top, the key touch is stable regardless of the pressed position. , The membrane sheet can reliably detect the pressing operation.

Here, the key top, the scissors portion, and the support sheet metal can be formed with high accuracy. Further, a bearing structure in which the first shaft portion of the balance bar is pivotally supported on the back surface of the key top can also be formed with high accuracy. However, the bearing portion of the bracket holding the second shaft portion of the balance bar cannot be formed with the same accuracy as other structures due to tolerance. Therefore, the bearing portion of the bracket is provided with a gap between the bearing portion and the second shaft portion so as not to interfere with the assembly work.

However, since the second shaft portion of the balance bar is held by the bearing portion with a gap, a phenomenon occurs in which the second shaft portion collides with the bearing portion each time the key top is pressed. Since the balance bar and the bracket are made of metal, the collision sound between the second shaft portion and the bearing portion is a metallic sound, which is one of the unpleasant striking sound attributes.

Since such a collision sound is caused by a gap between the second shaft portion of the balance bar and the bearing portion, it is desirable to narrow the gap as much as possible in order to suppress the collision noise. However, if the gap is narrowed and there is no play, it becomes difficult to insert the second shaft portion of the balance bar into the bearing portion, so that the assembling property deteriorates.

There is known a technique for suppressing the generation of the above-mentioned collision sound and at the same time improving the assembling property (see, for example, Patent Document 1). According to the technique described in Patent Document 1, the membrane sheet is provided with a notch-shaped portion that forms a space portion in at least one layer of the plurality of layers of the sheet corresponding to the position of the second shaft portion of the balance bar. As a result, when the second shaft portion of the balance bar is inserted into the bearing portion, when the second shaft portion is pressed against the membrane sheet at the position where the notch shape portion is located, the membrane sheet moves to the side of the support sheet metal. It will be elastically deformed. At this time, as the membrane sheet is elastically deformed toward the support sheet metal, a gap is created between the second shaft portion and the inner upper surface of the bearing portion, and the second shaft portion can move to the support sheet metal side. The gap created here is a sufficient clearance for inserting the second shaft portion of the balance bar into the bearing portion. Moreover, after the second shaft portion is inserted into the bearing portion, the elastically deformed portion of the membrane sheet returns to its original shape, so that the second shaft portion is directed toward the inner upper surface of the bearing portion by the restoring force of the membrane sheet. Pushed up. As a result, the gap between the second shaft portion and the inner upper surface of the bearing portion can be reduced, so that an abnormal noise generated by the collision between the second shaft portion and the bearing portion when the key top is pressed can be reduced. Can be suppressed.

Japanese Unexamined Patent Publication No. 2019-185086

In the technique described in Patent Document 1, the second shaft portion of the balance bar is placed on the membrane sheet in a state of being sandwiched between the membrane sheet and the inner upper surface of the bearing portion of the bracket when the key top is pressed. It will slide. The bearing portion and the balance bar are made of metal, and the membrane sheet is generally made of PET (polyethylene terephthalate) resin. Therefore, when the second shaft portion of the balance bar repeatedly slides on the membrane sheet, the surface of the membrane sheet is worn, and the gap between the second shaft portion and the inner upper surface of the bearing portion is widened to widen the second shaft portion. And the bearing part collide with each other, and an abnormal noise is gradually generated.

The present invention has been made in view of such a point, and an object of the present invention is to provide a keyboard device having both assembleability and noise reduction.

In the present invention, in order to solve the above problems, one proposal includes a key top, a scissors portion that supports the key top so as to be able to move up and down, and a membrane sheet in which a plurality of layers of sheets are laminated to have a switch function. It has a support sheet metal that supports the scissors portion and the membrane sheet, and a balance bar that is arranged between the key top and the support sheet metal and raises and lowers the key top while maintaining a posture parallel to the support surface of the support sheet metal. A keyboard device with keys is provided. In the keys of this keyboard device, the balance bar extends along the longitudinal direction of the key top and is rotatably supported on the back surface of the key top. The rotating shaft is arranged parallel to and coaxially with the rotating shaft of the first shaft portion at a position separated in the direction orthogonal to the one shaft portion, and is rotatable by the bearing portion formed on the support sheet metal. It has a second shaft portion that is movably held in a direction parallel to the support surface. Further, the membrane sheet has a notch-shaped portion on the second sheet laminated on the support sheet metal side adjacent to the first sheet on the key top side at a position corresponding to the bearing portion, and also on the surface of the first sheet. A shaft support portion that supports the second shaft portion held by the bearing portion is installed.

In the keyboard device having the above configuration, by installing the shaft support portion that supports the second shaft portion on the membrane sheet, the surface of the membrane sheet is not worn, and therefore the second shaft portion and the bearing portion collide with each other. This has the advantage of suppressing the generation of abnormal noise.

It is a cross-sectional view at the time of a normal time which shows typically the structure of the key of the keyboard device which concerns on embodiment of this invention, (A) shows the case where the wide key top is cut along the longitudinal direction, (B). ) Indicates when a wide key top is cut along the lateral direction. It is sectional drawing at the time of pressing operation which shows typically the structure of the key of the keyboard device which concerns on embodiment of this invention, (A) shows the case where the wide key top was cut along the longitudinal direction, and (A) B) shows the case where the wide key top is cut along the lateral direction. It is a figure which shows the assembly procedure of the balance bar, (A) shows the state at the start of assembly, (B) shows the 1st stage of assembly, (C) shows the 2nd stage of assembly. (D) shows the state at the end of assembly.

Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the accompanying drawings.
FIG. 1 is a cross-sectional view in a normal state schematically showing a key structure of a keyboard device according to an embodiment of the present invention, and FIG. 1A shows a case where a wide key top is cut along the longitudinal direction. , (B) show the case where the wide key top is cut along the lateral direction. FIG. 2 is a cross-sectional view during a pressing operation schematically showing a key structure of a keyboard device according to an embodiment of the present invention, and FIG. 2A is a cross-sectional view when a wide key top is cut along the longitudinal direction. (B) shows the case where the wide key top is cut along the lateral direction. 1 (A) is a cross-sectional view taken along the line II in FIG. 1 (B), and FIG. 1 (B) is a cross-sectional view taken along the line II-II in FIG. 1 (A). 2 (A) is a cross-sectional view taken along the line III-III in FIG. 2 (B), and FIG. 2 (B) is a cross-sectional view taken along the line IV-IV in FIG. 2 (A).

The keys 10 of the keyboard device of the present embodiment include the key top 11 and the scissors portion 12 as shown in FIGS. 1 (A), 1 (B), 2 (A) and 2 (B). , A rubber dome 13, a membrane sheet 14, a support sheet metal 15, a balance bar 16, and a shaft support portion 17.

The key top 11 has a wide shape, and for example, in a keyboard device of a notebook personal computer, it can be a key such as a click button, a space key, a shift key, or an enter key arranged side by side on a touch pad. The key top 11 is locked to the table 12a of the scissors portion 12 provided on the membrane sheet 14, and is supported so as to be vertically movable by the pantograph operation of the scissors portion 12.

The membrane sheet 14 is supported by a support sheet metal 15, is configured by laminating a plurality of sheets 14a, 14b, 14c, and has a switch function. Here, the sheets 14a and the sheet 14c have electrodes formed on their facing surfaces, and the sheet 14b arranged in the middle functions as a spacer for holding the electrodes of the sheet 14a and the sheet 14c in a separated state. A rubber dome 13 is arranged at a position where an electrode of the membrane sheet 14 is formed, and the rubber dome 13 is adhered to the membrane sheet 14 by a rubber dome glue 13a. The rubber dome glue 13a can be, for example, an ultraviolet curable adhesive resin.

The rubber dome 13 supports the key top 11 while maintaining the dome shape in the normal state shown in FIGS. 1 (A) and 1 (B). The shape of the rubber dome 13 is deformed by the key top 11 during the pressing operation shown in FIGS. 2 (A) and 2 (B). At this time, the protrusions built into the rubber dome 13 push the membrane sheet 14 at the electrode position to electrically connect the electrodes. When the pressing operation of the key top 11 is stopped, the key top 11 is pushed up by the restoring force of the rubber dome 13 and returned to the state shown in FIGS. 1 (A) and 1 (B). At this time, the key top 11 is guided by the scissors portion 12 so that the ascending and descending can be performed stably.

The balance bar 16 is arranged between the key top 11 and the support sheet metal 15, and has a function of raising and lowering the key top 11 while maintaining a state parallel to the support surface of the support sheet metal 15. The balance bar 16 has a rotation axis of the first axis at a position separated from the first axis 16a extending along the longitudinal direction of the wide key top in a direction orthogonal to the first axis 16a. A second shaft portion 16b arranged parallel to and coaxially with the rotation axis of the portion 16a, and a connecting portion 16c connecting the first shaft portion 16a and the second shaft portion 16b at both ends of the first shaft portion 16a. Have. The balance bar 16 is integrally formed by bending the first shaft portion 16a, the second shaft portion 16b, and the connecting portion 16c into a predetermined shape, for example.

The first shaft portion 16a of the balance bar 16 is rotatably supported by a bearing portion 18 formed on the back surface of the key top 11. The second shaft portion 16b of the balance bar 16 is held rotatably by the bracket 19 functioning as a bearing portion and movably in a direction parallel to the support surface of the support sheet metal 15. The bracket 19 is formed by cutting and raising the support sheet metal 15, and as shown in FIGS. 1 (B) and 2 (B), has an elongated hole which is a long bearing portion in a direction parallel to the support surface of the support sheet metal 15. The second shaft portion 16b of the balance bar 16 is passed through the elongated hole and is placed on the shaft support portion 17.

The shaft support portions 17 are respectively installed on the membrane sheet 14 on the outside of the bracket 19. At the position of the membrane sheet 14 on which the shaft support portion 17 is installed, a notch-shaped portion 14d is provided on the sheet 14c functioning as a spacer. As a result, a space portion is formed by the notched shape portion 14d in the seat 14b directly below the shaft support portion 17 installed on the seat 14a. The cutout shape portion 14d can give elasticity to the corresponding portion of the sheet 14a. When stress is applied to the shaft support portion 17 by the second shaft portion 16b of the balance bar 16, the seat 14a is deformed, and the distance between the upper surface of the shaft support portion 17 and the inner upper surface 19a of the elongated hole of the bracket 19 is increased. , When the second shaft portion 16b of the balance bar 16 is inserted into the elongated hole of the bracket 19, the assembleability becomes easy.

The shaft support portion 17 can be formed of glue. This glue can be the same as the rubber dome glue 13a for fixing the rubber dome 13 to the membrane sheet 14, and is preferably applied in the same process as the application of the rubber dome glue 13a to the membrane sheet 14. Ru.

On the surface of the shaft support portion 17 provided on the membrane sheet 14, as shown in FIGS. 1 (B) and 2 (B), the second shaft portion 16b of the balance bar 16 is moved as the key top 11 moves up and down. It slides in the left-right direction in the figure. Therefore, the shaft support portion 17 can be made of another resin sheet instead of the glue as long as it is flexible, has higher wear resistance than the membrane sheet 14, and has a small surface friction coefficient. ..

Next, the procedure for assembling the balance bar 16 will be described for the key 10 having the above configuration.
FIG. 3 is a diagram showing an assembly procedure of the balance bar, (A) shows the state at the start of assembly, (B) shows the first stage of assembly, and (C) shows the second stage of assembly. (D) shows the state at the end of assembly.

When assembling the balance bar 16, first, as shown in FIG. 3A, the tip of the second shaft portion 16b on one side (right side in the illustrated example) is located on the outside of the bracket 19 (right side in the illustrated example). To do.

Next, as shown in FIG. 3B, one second shaft portion 16b of the balance bar 16 is placed on the shaft support portion 17 and pushed down. As a result, the upper sheet 14a of the membrane sheet 14 is elastically deformed, and the distance between the upper surface of the shaft support portion 17 and the inner upper surface 19a of the elongated hole of the bracket 19 is increased.

When the balance bar 16 is moved to the left in the figure with the second shaft portion 16b pushing down the shaft support portion 17, the second shaft portion 16b is a long hole of the bracket 19 as shown in FIG. 3 (C). Will be inserted into. When the balance bar 16 continues to move until the connecting portion 16c of the balance bar 16 abuts on the bracket 19, the tip of the second shaft portion 16b on the other side of the balance bar 16 (left side in the figure) is outside the bracket 19 (example in the figure). Then it will be located on the left side). At this time, when the other second shaft portion 16b of the balance bar 16 is placed on the shaft support portion 17 and pushed down, the upper sheet 14a of the membrane sheet 14 is elastically deformed, and the upper surface of the shaft support portion 17 and the elongated hole of the bracket 19 are elongated. The distance between the inner upper surface 19a and the inner upper surface 19a is increased.

In this state, when the balance bar 16 is moved to the right in the figure, the second shaft portion 16b is inserted into the elongated hole of the bracket 19, and then the push-down of the second shaft portion 16b is released. As shown, both second shaft portions 16b are pushed up by the restoring force of the sheet 14a of the membrane sheet 14. At this time, the gap between the upper end of the second shaft portion 16b and the inner upper surface 19a of the elongated hole of the bracket 19 is minimized. The minimum gap includes the case where the second shaft portion 16b is in contact with the inner upper surface 19a of the elongated hole of the bracket 19.

According to the keyboard device according to the embodiment, in the key 10 having the balance bar 16, the second shaft portion 16b of the balance bar 16 held by the bracket 19 constituting the bearing portion is provided on the membrane sheet 14. It is supported by the shaft support portion 17. As a result, the second shaft portion 16b that moves horizontally in the bracket 19 due to the raising and lowering operation of the key top 11 slides on the shaft support portion 17, so that the surface of the membrane sheet 14 may be worn. It disappears. Since the gap between the second shaft portion 16b and the inner upper surface 19a of the elongated hole of the bracket 19 does not widen, the gap can be kept to a minimum, and the collision sound between the second shaft portion 16b and the bracket 19 can be maintained. Can be maintained.

The shaft support portion 17 is provided on the sheet 14a of the membrane sheet 14 on the side where the second shaft portion 16b of the balance bar 16 is inserted into the bracket 19. When the second shaft portion 16b is inserted into the bracket 19, the sheet 14a of the membrane sheet 14 can be pushed down to increase the distance between the shaft support portion 17 and the inner upper surface 19a of the elongated hole of the bracket 19, so that the assembly can be performed. At this time, the insertion of the second shaft portion 16b can be facilitated.

Since glue is used for the shaft support portion 17, it is easy to select a resin in consideration of flexibility when pressed down by the second shaft portion 16b, wear resistance higher than that of the membrane sheet 14, and the like. Further, if the glue is made of the same material as the rubber dome glue 13a for fixing the rubber dome 13 to the membrane sheet 14, the application to the membrane sheet 14 is performed in the same process as the application of the rubber dome glue 13a. Can be done. Further, the glue is an ultraviolet curable resin, and depending on the type of resin, the curing by ultraviolet rays can be adjusted, so that the flexibility can be easily set.

In the above embodiment, the key 10 including one balance bar 16 has been described, but the key 10 can be configured to include two balance bars 16 as needed.

10 Keys 11 Key Tops 12 Scissors 12a Table 13 Rubber Dome 13a Rubber Dome Glue 14 Membrane Sheets 14a, 14b, 14c Sheets 14d Notched Shapes 15 Support Sheet Metal 16 Balance Bar 16a 1st Shaft 16b 2nd Shaft 16c Connection 17 Shaft support 18 Bearing 19 Bracket 19a Inner upper surface

Claims (5)

A key top, a scissors portion that supports the key top so as to be able to move up and down, a membrane sheet in which a plurality of layers of sheets are laminated to have a switch function, a support sheet metal that supports the scissors portion and the membrane sheet, and the key top. In a keyboard device provided with a key provided between the support sheet metal and a balance bar that raises and lowers the key top while maintaining a posture parallel to the support surface of the support sheet metal.
The balance bar extends along the longitudinal direction of the key top and is rotatably supported by the back surface of the key top, and the first shaft portion from both sides of the first shaft portion. The rotating shaft is arranged parallel to and coaxially with the rotating shaft of the first shaft portion at a position separated from the portion in the direction orthogonal to the portion, and is rotatable by the bearing portion formed on the support sheet metal. Has a second shaft portion that is movably held in a direction parallel to the support surface of the
The membrane sheet has a notch-shaped portion in a second sheet laminated on the side of the support sheet metal adjacent to the first sheet on the side of the key top at a position corresponding to the bearing portion, and the first sheet. A keyboard device in which a shaft support portion for supporting the second shaft portion held by the bearing portion is installed on the surface of the keyboard device. The keyboard device according to claim 1, wherein the shaft support portion is provided on the first seat adjacent to the bearing portion on the side where the second shaft portion is inserted into the bearing portion. The keyboard device according to claim 1, wherein the shaft support portion is a glue. The keyboard device according to claim 3, wherein the glue is the same material as the glue for the rubber dome that fixes the rubber dome arranged between the key top and the membrane sheet to the membrane sheet. The keyboard device according to claim 3 or 4, wherein the glue is an adhesive resin that is cured by ultraviolet rays after being applied to the surface of the first sheet.

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