WO2024147207A1

WO2024147207A1 - Push-button switch member

Info

Publication number: WO2024147207A1
Application number: PCT/JP2023/015722
Authority: WO
Inventors: 正幸伊藤
Original assignee: 信越ポリマー株式会社
Priority date: 2023-01-06
Filing date: 2023-04-20
Publication date: 2024-07-11

Abstract

A push-button switch member (1) comprises a first push-button structure (2) that generates a sense of a first stage click and second push-button structures (3) that generate a sense of a second stage click, wherein: the first push-button structure (2) comprises a base portion (11), a first dome portion (12) that is formed above the base portion (11) and becomes deformed by being pressed to generate the sense of the first stage click, and a pressing first key top (13) that is formed above the first dome portion (12); at least two second push-button structures (3) are disposed inside the first dome portion (12); the at least two second push-button structures (3) each comprise a second dome portion (17) that becomes deformed by being continuously pressed to generate the sense of the second stage click; and the at least two second push-button structures (3) share, or each comprise, a pusher portion (18), which is formed below the second dome portion (17) and by which a ground resistance is established.

Description

Push button switch parts

Cross References

This application claims priority to Japanese Patent Application No. 2023-001230, filed in Japan on January 6, 2023, the entire contents of which are incorporated herein by reference in their entirety.

The present invention relates to a component for a push button switch.

Conventionally, multi-stage switches, including two-stage switches, have been widely used in portable communication devices, digital cameras, car audio devices, car navigation devices, and the like. Performing multiple switch operations in multiple stages is useful for providing multiple functions with a minimum number of switches in devices with limited space for mounting switches (see Patent Document 1).

JP 2006-236694 A

Fig. 3 shows a plan view, a cross-sectional view along line A-A, and a cross-sectional view along line B-B of a push button switch member that has been used by the applicant in the past. Fig. 4 shows the load-stroke curve (FS curve) of the push button switch member of Fig. 3.

The push button switch member 100 in Figure 3 has the configuration of a so-called two-stage switch. The push button switch member 100 comprises a base portion 111 having a rectangular outer shape with a circular or oval hole in the center in a plan view, a first dome portion 112 formed above the base portion 111 and deforming when pressed to generate a first stage click feeling, and a first key top 113 for pressing formed above the first dome portion 112. The first key top 113 has a recess 114 recessed downward from the top surface, approximately in the center in a plan view. A structure for generating a second stage click feeling is formed below the recess 114. This configuration includes a pusher portion 118 located at the bottom of the recess 114 and above the bottom surface of the base portion 111, a second dome portion 117 located at the bottom surface of the first key top 113 and connecting the outer periphery of the recess 114 to the pusher portion 118, and a second key top 115 protruding upward from below the recess 114 from the top surface of the pusher portion 118 through the inside of the second dome portion 117.

An internal space 116 is formed radially inward of the base portion 111 and the first dome portion 112. The pusher portion 118 floats above the surface on which the push button switch member 100 is set (e.g., the upper surface of a circuit board), and is suspended from the underside of the first key top 113 by the second dome portion 117 in the internal space 116. The top surface of the second key top 115 is located below the top surface of the first key top 113. The first dome portion 112 has an inverted funnel shape that gradually expands in diameter from the outer periphery of the underside of the first key top 113 toward the base portion 111. The second dome portion 117 has a funnel shape that gradually reduces in diameter from the periphery of the recess 114 on the underside of the first key top 113 toward the pusher portion 118.

Next, the operation of the push button switch member 100 when pressed will be described with reference to Figures 3 and 4. When a finger presses from the top surface of the first key top 113 to the bottom surface, the first dome portion 112 withstands the pressure, and the resistance force on the finger increases. After that, when a predetermined pressure is reached (pressing force at point a in Figure 4), the first dome portion 112 cannot withstand the pressure and is suddenly buckled and deformed. As a result, the resistance force on the finger decreases and the first key top 113 descends. Next, when the first key top 113 and the second key top 115 reach the same height, the second key top 115 is pressed, the pusher portion 118 descends, and finally it is grounded. Grounding means, for example, contacting a switch on the top surface of a circuit board. As a result, the second dome portion 117 withstands the pressure, and the resistance force on the finger increases again. After that, when a certain pressure is reached (pressure at point c in FIG. 4), the second dome portion 117 cannot withstand the pressure and suddenly buckles and deforms. As a result, the resistance force on the finger decreases again, and the first keytop 113 descends further, eventually touching the ground. From then on, there is no part that will deform significantly even when pressed, so the resistance force on the finger increases rapidly.

Here, the pressure drop between points a and b in FIG. 4 provides the operator with a first-stage clicking sensation. Also, the pressure drop between points c and d in FIG. 4 provides the operator with a second-stage clicking sensation. In this way, the push button switch member 100 functions as a two-stage switch.

However, there is a demand for further functional improvements in the push button switch member 100 described above. That is, to increase the load at point c while maintaining the clicking sensation. It is easy to increase the load at point c by increasing the thickness of the second dome portion 117. However, in that case, the difference in pressure between points c and d becomes smaller, and the clicking sensation at the second stage becomes weaker. Therefore, increasing the thickness of the second dome portion 117 would sacrifice the clicking sensation, and so such measures cannot be taken.

The present invention was made in consideration of the above problems, and aims to provide a push button switch component that can achieve both a clear clicking sensation and a higher maximum load at the second stage.

(1) In order to achieve the above object, a member for a push button switch according to one embodiment is a member for a push button switch capable of generating a click feeling in two stages,
a first push button structure that generates a first-stage click sensation when the member for a push button switch is pressed from above;
a second push button structure that generates a second stage click feeling by continuing the pressing after the generation of the first stage click feeling;
Equipped with
The first push button structure includes a base portion, a first dome portion formed above the base portion and deformed by the pressing to generate the first-stage click feeling, and a first key top for pressing formed above the first dome portion.
Equipped with
Two or more second push button structures are arranged inside the first dome portion,
Each of the two or more second push button structures is provided with a second dome portion that deforms as the pressure continues to be applied, generating the second stage of clicking sensation, and each of the two or more second push button structures or each of the two or more second push button structures in common is provided with a pusher portion that is formed below the second dome portion and provides a ground resistance.
(2) In the member for a push button switch according to another embodiment, the second push button structure may preferably include a second key top having a top surface lower than a top surface of the first key top.
(3) In another embodiment of a push button switch member, the first key top preferably has a recess recessed inward from its top surface, the number of the recesses being equal to or greater than the number of the second push button structures, and the second key top may be arranged to protrude into the recesses.
(4) In the member for a push button switch according to another embodiment, the first dome portion may preferably be a dome portion whose diameter increases from the first key top toward the base portion.
(5) In the member for a push button switch according to another embodiment, the second dome portion may preferably be a dome portion whose diameter decreases from the first key top toward the pusher portion.

The present invention provides a push button switch component that provides both a clear clicking sensation and a higher maximum load at the second stage.

FIG. 1 shows a plan view, a cross-sectional view taken along line AA, and a cross-sectional view taken along line BB of a member for a push button switch according to one embodiment. FIG. 2 shows a load-stroke curve (FS curve) of the push button switch member of FIG. 1 in comparison with the FS curve of FIG. FIG. 3 shows a plan view, a sectional view taken along line AA, and a sectional view taken along line BB of a push button switch member that has been conventionally used by the applicant. FIG. 4 shows a load-stroke curve (FS curve) of the push button switch member of FIG.

1: push button switch member, 2: first push button structure, 3: second push button structure, 11: base portion, 12: first dome portion, 13: first key top, 14: recess, 15: second key top, 17: second dome portion, 18: pusher portion.

Below, an embodiment of the present invention will be described with reference to the drawings. Note that the embodiment described below does not limit the inventions related to each claim in the claims. Furthermore, not all of the elements and combinations thereof described in the embodiment are necessarily essential to the solution of the present invention.

FIG. 1 shows a plan view, a cross-sectional view along line A-A, and a cross-sectional view along line B-B of a push button switch member according to one embodiment.

The push button switch member 1 according to this embodiment is capable of generating a two-stage click sensation. The push button switch member 1 comprises a first push button structure 2 that generates a first stage click sensation by pressing the push button switch member 1 from above, and a second push button structure 3 that generates a second stage click sensation by continuing to press after the first stage click sensation has been generated. In FIG. 1, the reference symbols for the first push button structure 2 and the second push button structure 3 are shown in parentheses.

The first push button structure 2 comprises a base portion 11, a first dome portion 12 formed above the base portion 11 and deforming when pressed to generate a first stage click sensation, and a first key top 13 for pressing formed above the first dome portion 12. The base portion 11 is a member having an outer shape of a rectangular parallelepiped. The base portion 11 has a space inside thereof into which a part of the second push button structure 2 can descend. In this embodiment, the space has a cylindrical or elliptical cylindrical shape. However, the outer shape of the base portion 11 and the above-mentioned space are not limited to the shapes described above. The first key top 13 is a member having an outer shape of a cylindrical or elliptical cylindrical shape. However, the outer shape of the first key top 13 is not limited to a cylindrical or elliptical cylindrical shape.

The first dome portion 12 is a member with a small thickness that connects the underside or side of the first key top 13 to the base portion 11, and is an inverted funnel-shaped member that expands in diameter from the first key top 13 toward the base portion 11. The first dome portion 12 is a member that has a circular or elliptical shape in a plan view. However, the shape of the first dome portion 12 is not limited to a circular or elliptical shape. In this embodiment, the outer surface of the first dome portion 12 is a substantially linearly inclined surface, but it may be a curved surface that protrudes upward or downward in a slight arc. The first key top 13 is a member that is located on the upper part of the first dome portion 12 and presses the push button switch member 1 toward the internal space 16 of the base portion 11. The first key top 13 preferably has a recess 14 that is recessed inward from its top surface. In addition, the recesses 14 are preferably provided in the number of the second push button structures 2, which is preferably two or more. In this embodiment, the recess 14 has a circular or elliptical shape in a plan view. However, the shape is not limited to a circular or elliptical shape.

Two parts of the second push button structure 3 (pusher portion 18, second dome portion 17, and part of the second key top 15) are arranged in the internal space 16 inside the first dome portion 12. However, the number of second push button structures 3 is not limited to two, and may be three or more. Each of the two second push button structures 3 includes a second dome portion 17 that deforms with continued pressure after the first click to generate a second click feeling, and a pusher portion 18 formed below the second dome portion 17 and providing a ground resistance. Here, "ground resistance" refers to a large resistance that occurs against the downward movement of the second push button structure 3 when it comes into contact with the surface on which the push button switch member 1 is arranged, for example, the upper surface of a circuit board or a member fixed to that surface. The second dome portion 17 is a thin member that connects the underside of the first key top 13 and the pusher portion 18, and is a funnel-shaped member whose diameter decreases from the first key top 13 toward the pusher portion 18. In this embodiment, the outer surface of the second dome portion 17 is a nearly linearly inclined surface, but it may also be a curved surface that protrudes upward or downward in a slight arc.

The second dome portion 17 is a member having a circular or elliptical shape in a plan view. However, the shape of the second dome portion 17 is not limited to a circular or elliptical shape. The pusher portion 18 is a member having an outer shape of a cylinder or an elliptical cylinder. However, the outer shape of the pusher portion 18 is not limited to a cylinder or an elliptical cylinder.

In this embodiment, the second push button structure 3 preferably includes a second key top 15 having a top surface lower than the top surface of the first key top 13. The second key top 15 is formed to protrude upward within a recess 14 formed in the first key top 13. The second key top 15 is a member having an outer shape of a cylinder or an elliptical cylinder. However, the outer shape of the second key top 15 is not limited to a cylinder or an elliptical cylinder.

Before the second push button structure 3 is formed, the recess 14 is a through passage that penetrates the first key top 13 in the pressing direction. The second push button structure 3 is connected to the first key top 13 in a manner that blocks the lower opening of the through passage. The second key top 15 and the pusher part 18 are suspended from the first key top 13 via the second dome part 17. Since the top surface of the second key top 15 is formed lower than the top surface of the first key top 13, the pressure on the second key top 15 starts after the first dome part 12 buckles and deforms due to the pressure from the first key top 13. However, the top surface of the second key top 15 may be formed at the same height as the top surface of the first key top 13. The recess 14 and the second key top 15 are not essential components and may not be formed. In that case, the second push button structure 3 is a structure that includes a second dome portion 17 and a pusher portion 18, but does not include a second key top 15.

In this embodiment, a pusher portion 18 is provided for each of the two second push button structures 3. However, one pusher portion 18 may be provided below two or more second dome portions 17 in common to two or more second push button structures 3.

The push button switch member 1 is preferably made entirely of synthetic or natural rubber. Synthetic rubber includes, for example, thermosetting elastomers such as silicone rubber, urethane rubber, isoprene rubber, ethylene propylene rubber, natural rubber, ethylene propylene diene rubber, nitrile rubber (NBR), or styrene butadiene rubber (SBR); thermoplastic elastomers such as ester-based, styrene-based, olefin-based, butadiene-based, and fluorine-based elastomers; or composites thereof. Of these candidate materials, silicone rubber is particularly preferred. However, the push button switch member 1 may be made of at least the first dome portion 12 and the second dome portion 17 of the above-mentioned rubber, particularly silicone rubber, with the other components being made of materials such as resin, metal, or ceramics.

Figure 2 shows the load-stroke curve (FS curve) of the push button switch component in Figure 1 in comparison with the FS curve in Figure 4.

Below, with reference to FIG. 2, the operation of the push button switch member 1 according to this embodiment when pressed will be described. When the first key top 13 is pressed from the top surface to the bottom surface with a finger, the first dome portion 12 withstands the pressure, so the resistance force applied to the finger increases. After that, when a predetermined pressure is reached (pressing force at point a in FIG. 2), the first dome portion 12 cannot withstand the pressure and is suddenly buckled. As a result, the resistance force applied to the finger decreases, and the first key top 13 descends. Next, when the first key top 13 and the second key top 15 reach the same height, the second key top 15 is pressed, and the pusher portion 18 descends and finally touches the ground. At this point, the load is at a minimum value (point b in FIG. 2). After that, the second dome portion 17 withstands the pressure, so the resistance force applied to the finger increases again. After that, when a predetermined pressure is reached, the second dome portion 17 cannot withstand the pressure and is suddenly buckled. Just before this buckling deformation, the load again reaches a maximum value (point c1 in Figure 2). As a result, the resistance force on the finger decreases again, and the first keytop 13 further descends and finally touches the ground. At this point, the load again reaches a minimum value (point d1 in Figure 2). After that, there is no part that will deform significantly even when pressed, so the resistance force on the finger rises sharply.

The first pressing structure 2 is also present in the conventional member for a push button switch 100 shown in FIG. 3. Therefore, the curves up to point b of the FS curve are almost overlapping between the member for a push button switch 1 and the member for a push button switch 100. On the other hand, the member for a push button switch 1 has two second push button structures 3, and has one more second push button structure than the member for a push button switch 100. Therefore, the maximum value of the load just before the second stage click feeling is generated in the member for a push button switch 1 (point c1 in FIG. 2) is larger than the similar maximum value in the member for a push button switch 100 (point c in FIG. 2). Here, the minimum value of the load when the second stage click feeling is generated in the member for a push button switch 1 (point d1 in FIG. 2) is larger than the similar minimum value in the member for a push button switch 100 (point d in FIG. 2). However, the load difference between point c1 and point c is greater than the load difference between point d1 and point d. As a result, the second stage click feeling of member 1 for a push button switch is more distinct than the second stage click feeling of member 100 for a push button switch.

In this way, by increasing the number of second push button structures 3 and increasing the number of second dome portions 17, it is possible to improve the click feeling without sacrificing the click feeling, and to increase the load (resistance applied to the finger) just before the second stage click feeling is generated. In this way, with the push button switch member 1 according to this embodiment, it is possible to achieve both a clear click feeling and a higher maximum value of the second stage load.

The above describes a preferred embodiment of the present invention, but the present invention is not limited to the above embodiment and can be modified in various ways.

For example, the first dome portion 12 may be a dome portion whose diameter decreases from the first key top 13 toward the base portion 11. Also, the second dome portion 17 may be a dome portion whose diameter increases from the first key top 13 toward the pusher portion 18.

This invention can be used in devices equipped with push button switch components.

Claims

A push button switch member capable of generating a click feeling in two stages,
a first push button structure that generates a first-stage click sensation when the member for a push button switch is pressed from above;
a second push button structure that generates a second stage click feeling by continuing the pressing after the generation of the first stage click feeling;
Equipped with
The first push button structure includes a base portion, a first dome portion formed above the base portion and deformed by the pressing to generate the first-stage click feeling, and a first key top for pressing formed above the first dome portion.
Equipped with
Two or more second push button structures are arranged inside the first dome portion,
A member for a push button switch, characterized in that each of the two or more second push button structures is provided with a second dome portion that deforms as the pressure continues to be applied to generate the second stage of clicking sensation, and each of the two or more second push button structures or each of them in common is provided with a pusher portion that is formed below the second dome portion and provides a ground resistance.
The push button switch member according to claim 1, characterized in that the second push button structure includes a second key top having a top surface lower than the top surface of the first key top.
The first keytop has a recess recessed inward from its top surface,
The recesses are provided in a number equal to or greater than the number of the second push button structures,
3. The push button switch member according to claim 2, wherein the second key top is provided so as to protrude into the recess.
The push button switch member according to any one of claims 1 to 3, characterized in that the first dome portion is a dome portion that expands in diameter from the first key top toward the base portion.
The push button switch member according to any one of claims 1 to 3, characterized in that the second dome portion is a dome portion whose diameter decreases from the first key top toward the pusher portion.