JP2000113765A - Switch structure for operation panel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a switch structure allowing arbitrary selection of the operation modes of a switch button and to adapt the switch structure to keep a gap around the switch button small in an opening of an operation panel. SOLUTION: Two guide projections 21, 22 are formed on a switch button 10, and switch-button support parts 20 in an operation panel 30 are provided with guide grooves 21, 22 for guiding the two guide projections 11, 12, respectively. By forming the two guide grooves 21, 22 into the shape of a circular arc centering around a point C near a surface of the operation panel 30, the switch button 10 makes rotating motion having the point C as a center of rotation.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a switch structure of an operation panel provided in a vehicle interior or the like.

[0002]

2. Description of the Related Art Conventionally, the following is known as a switch structure provided on the surface of an operation panel.

A) Slide operation type switch structure (FIG. 5) In this figure, an opening 31 penetrating through the front and back of the operation panel 30 is provided in a part of the operation panel 30, and protrudes from the periphery to the back (the right side in FIG. 5). The surrounding wall 35 is formed over the entire circumference of the opening 31, and the switch button 10 is fitted inside the surrounding wall 35 from the back side. The switch button 10 can be slid backward by the guidance of the surrounding wall 35. On the other hand, a circuit board 40 is provided on the back side of the operation panel 30, and a switch body 50 having an operated portion 51 is provided on the surface of the circuit board 40.

When the switch button 10 is pressed from the front side, the switch button 10 slides to the back side, and the operation unit 15 provided on the back surface near the lower end of the switch button 10 causes the switch body 50 to be operated. The portion 51 is pressed.

B) Rotating operation type switch structure (FIG. 6) In this structure, an opening 31 provided in an operation panel 30
A switch button support portion 36 is provided which protrudes from the upper part of the periphery to the rear side (the right side in the figure), and a pin hole 37 is formed in the switch button support portion 36. on the other hand,
The switch button 10 is provided with a flange 19 having a pin 18 formed at the upper end thereof.
Is rotatably inserted into the pin hole 37, so that the switch button 10 can rotate around the pin hole 37 and the pin 18.

[0006] When the switch button 10 is pressed from the front side, the switch button pivots toward the back side, and the operation section 15 provided on the back surface near the lower end portion of the switch body 50 is pressed. Is pressed.

[0007]

In the slide type structure A), the switch button 10 is slid and guided by using the inner surface of the surrounding wall 35 as a guide surface. Δ ₁ ,
δ ₂ can be made sufficiently small. However, if the position where the switch button 10 is pressed with a finger deviates from the center of the button, the switch button 10 is tilted and a so-called stiffness occurs between the switch button 10 and the surrounding wall 35, which is disadvantageous in that the operation is likely to malfunction. For this reason, in such a slide type switch structure, usually, the depth dimension of the surrounding wall 35 is set to be sufficiently large so that the switch button 10 does not tilt inside the surrounding wall 35, and the entire switch structure is formed. , And could not be made compact in the depth direction. Further, as means for preventing such malfunction due to stiffening, it is conceivable to provide an auxiliary spring or to dispose the switch body 50 at a plurality of positions. However, if such means is taken, the number of parts is reduced. This causes another problem that the cost increases.

On the other hand, according to the rotary operation type structure B),
Although the occurrence of the stiffness as described above can be prevented, the operation of the switch button 10 is limited to the rotation operation about the pin hole 37 formed in the switch button support portion 36. In addition, the switch button support portion 36 provided with the pin hole 37 serving as the center of the pivoting operation is strong enough to support the switch button 10 that is located inside the operation panel 30 and is further pressed. It can be provided only in a very limited position that does not interfere with various members arranged in the panel 30.

Therefore, in such a conventional rotary operation type switch structure, the setting of the operation mode of the switch button 10 is greatly restricted, and various problems may occur depending on the operation mode of the switch button 10. Even so, a fundamental solution could not be achieved by changing the operation mode of the switch button 10 itself.

For example, the switch structure shown in FIG. 6 in which the switch button 10 rotates about a pin hole 37 disposed at a position a predetermined distance behind the switch panel 30 will be described below. There's a problem.

That is, according to this switch structure, when the switch button 10 that has been pressed is rotated, the switch button 10 moves downward as a whole (two-dot chain line in FIG. 6). In order to secure a sufficient operating margin, the lower gap dimension δ ₂ between the switch button 10 and the opening 31 of the operation panel 30 before the pressing operation must be set large. the gap is conspicuous by increasing the size [delta] _2, also, there is a case where dust or the like will be penetrated by cause operation failure in the operation panel 30 through the gap. At the same time, the switch button 10 and the opening 3 are
Since the upper gap dimension δ 1 between the first button 1 and the second button ₁ increases (two-dot chain line in FIG. 6), when a sufficient operating margin is secured, the upper gap dimension δ ₁ ′ between the switch button 10 and the opening 31 during the pressing operation. Becomes large, and the lower clearance dimension δ
The same disadvantages as those described above caused by increasing ₂ occur.

However, such a switch button 10
In order to solve the problem that a large gap is generated between the switch button 10 and the opening 31 which has a factor in the operation mode of the above, changing the position to the center point of the rotation operation is
Usually, it is difficult to achieve a fundamental solution because it is difficult due to mounting strength required for the switch button support portion 36 and restrictions on mounting positions with respect to other members in the operation panel 30. .

The present invention has been made in view of the above circumstances, and provides a switch structure of an operation panel in which the operation mode of the switch button can be set with a high degree of freedom while preventing the occurrence of operation failure due to the button button. Aim.

[0014]

In order to solve the above-mentioned problems, a switch structure of an operation panel according to the present invention includes an operation panel having an opening, a switch button fitted in the opening, and the operation panel. A first switch button supporting portion for supporting the switch button in the panel; a first guided portion; and a first guide portion for guiding the first guided portion along a first guide route. A first guide mechanism comprising: a guide mechanism; a second guided section; and a second guide mechanism including a second guide section for guiding the second guided section along a second guide path. And one of the first guided portion is provided on the switch button, the other is provided on the switch button support portion, and one of the second guide portion and the second guided portion is provided on the switch button. And the other is the switch The first guide route and the second guide route are provided on a button support portion, and the switch button performs an operation having a rotation component. ).

An object (rigid body) that moves in a predetermined plane and is not deformed is regarded as performing a rotational movement about a predetermined point in the plane at each moment.
The center of this rotational movement is called the instantaneous center at that time. This instant center can be determined by the instantaneous motion at any two points in the object.

Conversely, for an object in a predetermined plane,
If the instantaneous center could be located at any point in this plane, the object would be able to perform any motion in that plane, and furthermore, the instantaneous center would be at any two points in the object. In consideration of the fact that the object is determined by the above operation, if two points in the object can be operated along an arbitrary path, the object can perform an arbitrary operation in the plane.

Therefore, according to the switch structure having the above-described structure, the switch button is provided at the predetermined two points where the guide portions or the guided portions of the first and second guide mechanisms are formed, respectively, with the first and second guides. Because the mechanism operates on the first and second guide routes, these first and second guide routes are used.
By configuring the second guide route in an arbitrary shape, the switch button can perform any operation on the plane formed by the first and second guide routes.

That is, according to such a configuration, the switch button has a very large degree of freedom as an operation mode, and the center of rotation of the operation of the switch button (the moment center if captured at each moment). Can be arranged at a position where the guide portion and the guided portion of the first and second guide mechanisms do not actually exist. For example, as needed, the rotation center of the operation of the switch button ( (The moment center) can be located outside the operation panel. Therefore, by appropriately selecting and adopting the operation mode of the switch button from this large degree of freedom, even if various problems having a factor in the operation mode of the switch button occur, a fundamental solution can be achieved. Can be planned.

However, in the switch structure having the above structure, the first guide route and the second guide route are configured such that the switch button performs an operation having a rotation component, and the switch button is configured to rotate the rotation component. There is no complete slide operation without any. Therefore, the occurrence of operation failure of the switch button due to undulation, such as when the switch button performs a complete slide operation, is reduced, and it is not necessary to increase the depth of the switch unlike the conventional slide operation type switch structure. In addition, the thickness of the switch can be reduced.

Further, the fact that the switch button does not perform a complete sliding operation means that the first and second guide mechanisms do not guide the guided parts in the same direction at each moment by the guide portions of the respective guide mechanisms. , The first and second at each moment
Is not parallel, one of the guide routes always regulates the play in the other guide route direction. Therefore, the operation of the switch button based on the guidance of such two guide mechanisms is It will be stable.

As described above, the first guide route and the second guide route may be formed in any shape including a linear shape in accordance with the required operation mode of the switch button. It is desirable that both the guide route and the second guide route are formed in an arc shape centered on the same point.

According to this structure, the instantaneous center of the operation of the switch button is always located at the center point of the arc shape of the first and second guide paths, and the switch button is always at the center of the arc shape. Since the turning operation is performed around the point as the center of rotation, the operation of the switch button becomes very stable. Even in the case where the switch button is rotated about a specific point, the first and second guide routes are formed in an arbitrary arc shape, and thus the switch button is formed. The position of the rotation center can be arranged at an arbitrary point.

Further, in accordance with the operation of the switch button which is pressed, both of the gaps formed in the gap between the opening and the switch button in the direction in which the switch button is displaced in accordance with the operation of the switch button. But,
It is desirable to configure the first guide route and the second guide route such that both decrease or increase (claim 3).

A gap is formed between the opening and the switch button on both sides in the switch button operation direction and on both sides in a direction orthogonal to the switch button operation direction. In the former of these gaps, the dimension of the gap can change with the operation of the switch button that is pressed.

Therefore, if the gaps on both sides in the operation direction of the switch button are configured to decrease or increase together according to the operation of the switch button to be pressed, the gaps before and after the switch button are pressed, respectively. In this case, it is possible to reduce the tendency of the gap to be deviated to one of these two sides and to prevent the formation of a large gap.

As a specific configuration for reducing or increasing both of the gaps on both sides of the switch button, the first guide route and the second guide route are configured as follows.
In both cases, there can be cited means for forming an arc shape centered on one point near the operation panel surface (claim 4).

With this configuration, the rotation center of the operation of the switch button is located near the operation panel surface, so that the pressed switch button moves as a whole in a direction parallel to the operation panel surface. Is reduced,
The pressed switch button rotates in the opening while moving (pressing down) as a whole in a direction perpendicular to the operation panel surface. Therefore,
According to such a configuration, the gaps on both sides of the switch button are both reduced or increased, and the above-described effects are obtained.

Further, if both the first guide route and the second guide route are formed in an arc shape centered on a point outside the pressing surface of the switch button (claim 5), The rotation center of the above operation is located outside the pressing surface.

Therefore, with such a configuration, by pressing an arbitrary portion of the pressing surface of the switch button, the switch button can be rotated as a whole in a pressing direction substantially perpendicular to the operation panel surface. Therefore, a reliable switch operation can be realized as a push button switch.

The first guide route and the second guide route
If both of the guide routes are formed in an arc shape centered on one point inside the pressing surface of the switch button (claim 6), the rotation center of the operation of the switch button is located inside the pressing surface. Becomes

Therefore, with such a configuration, on the pressing surface of the switch button, on both sides in the switch button operation direction parallel to the operation panel surface with respect to the position of the rotation center of the operation of the switch button as a boundary. The direction of the rotation operation of the switch button with respect to the pressing operation is reversed, so that a so-called seesaw switch can be configured.

[0032]

FIG. 1 shows a first embodiment of the present invention.
A description will be given based on FIG.

In each of the above figures, an operation panel 30 is disposed in front of the circuit board 40 (the left side in FIG. 1 and the upper side in FIG. 2) with a switch button support member (switch button support) 20 interposed therebetween. , Switch button support member 2
The switch button 10 is provided inside 0.

On the front side of the circuit board 40, a switch body 50 and a spring 60 for applying a restoring force to the switch button 10 are mounted. The switch body 50 has an operated portion 51 that receives a pressing operation, and ON / OFF switching is performed by pressing the operated portion 51.

The switch button support member 20 is configured as a substantially rectangular parallelepiped frame having a hollow portion penetrating substantially in the front-rear direction (vertical direction in FIG. 2). Switch button insertion portions 23 are provided on the left and right sides of the hollow portion so as to increase the width of the hollow portion. Left and right switch button loading section 2
Above (in the lower right direction in FIG. 2) upper portions 3, 23, arc-shaped first guide grooves (first guide portions) 21, 21 are formed substantially vertically. The switch button support member 20
On the left and right sides of the lower portion (the upper left portion in FIG. 2), arc-shaped second guide grooves (second guide portions) 2 from the front side to a predetermined depth.
2, 22 are formed in a substantially horizontal direction. The first guide grooves 21 and 21 and the second guide grooves 22 and 22 are formed in an arc shape centered on the same point C when viewed in the cross-sectional direction.

The operation panel 30 has an opening 31 formed therethrough. A pressing wall surface 32 for covering the front end of the second guide grooves 22 formed in the switch button support member 20 is formed on the lower side of the peripheral portion of the opening 31 (see FIG. 2). (See FIG. 1).

The switch button 10 is formed in a hollow shape opened on the back side.
Is slightly smaller than the inner peripheral shape on the front side of the panel. Therefore, when the switch button 10 is fitted into the opening 31 of the operation panel 30 from the back side,
When viewed from the panel surface side, a substantially uniform gap is secured over the entire circumference between the outer peripheral surface of the switch button 10 and the inner peripheral surface of the opening 31.

On the back side of the switch button 10, flange portions 13 and 14 having a predetermined width are formed on the upper and lower portions thereof. On the left and right sides of the upper end of the flange portion 13 above the switch button 10, first guide projections (first guide projections) which are fitted into the first guide grooves of the switch button support member 20 and guided by the first guide grooves 21 are provided. Guided part) 1
1 and 11 are provided. The switch button 10
On the left and right sides near the lower end of the lower flange portion 14, the second guide grooves 22, 22 of the switch button support member 20 are provided.
And second guide protrusions (second guided portions) 12, 12 which are fitted into the second guide grooves 22 and guided by the second guide grooves 22, 22.

On the back side of the flange portion 14 below the switch button 10, there is provided an operation section 15 for pressing the operated section 51 of the switch body 50 in accordance with the operation of the switch button 10. I have.

In the switch button 10 thus configured, the first guide projections 11 provided at the upper end of the switch button support member 20 are connected to the switch button support member 20 by the switch button mounting member. Parts 23, 2
3, the first guide projections 11, 11 are inserted into the first guide grooves 21, 21 in the state where the first guide projections 11, 11 are inserted into the first guide grooves 21, 21, respectively. 2 The guide projections 12, 12 are
Are assembled into the second guide grooves 22, 22 from the front side. Switch button 1 in this way
When the operation panel 30 is put on the switch button support member 20 in which the switch button support member 20 is incorporated from the front side, the second guide grooves 22,
The front end is covered by the pressing wall surface 31 protruding from the back side of the operation panel 30, and the switch button 1
0 is prevented from dropping to the front side.

The switches in the operation panel 30 assembled in this manner include first guide projections 11, 11 of the switch button 10, and first guide grooves 21, 21 formed in an arc shape of the switch button support member 20. Along with the second guide projections 12,
12 is guided along the second guide grooves 22, 22 of the switch button support member 20 formed in an arc shape centered on the same point as viewed from the cross section with the first guide grooves 21, 21. Become.

That is, the first guide projections 11, 11 are
, The first guide grooves 21 and 21 are the first guide portions,
The shape of the first guide grooves 21 and 21 constitutes a first guide path, and the first guide projections 11 and 11 and the first guide grooves 21 and 21 constitute a first guide mechanism. The two guide projections 12 and 12 serve as the second guided portion and the second guide groove 2.
Reference numerals 2 and 22 denote second guide portions, and the second guide grooves 22 and 2
2 has a second guide path and a second guide projection 1
The second guide groove 22 and the second guide groove 22 constitute a second guide mechanism.

The first and second guide mechanisms allow the switch button 10 to rotate about an arc-shaped center point C formed by the guide paths of the first and second guide mechanisms. It is supposed to.

As described above, when the switch button 10 is pressed by the pressing surface on the front surface thereof, the switch button 10 is rotated about the point C as a rotation center. The operation unit 15 on the side presses the operated portion 51 of the switch body 50, and the ON / OFF state of the switch body 50 is switched (see the two-dot chain line in FIG. 1). If the pressing force on the front surface of the switch button 10 is released, the switch button 10 is pushed back to the front side by the restoring force of the spring 60 that pushes the flange portion 14 at the lower end on the back side of the switch button 10 back to the front side. (Solid line state in FIG. 1).

As described above, since the switch button 10 is rotated by the pressing operation, a malfunction due to stiffness unlike the slide operation type switch structure (FIG. 5) is unlikely to occur. Since it is not necessary to increase the depth of the switch, the thickness of the switch can be reduced.

The rotation center C of the switch button 10
In the first embodiment, the switch button 1 is located near the surface of the operation panel 30.
0 indicates that the operation in the vertical direction is small as the whole switch button 10 depending on the rotation operation.
Therefore, the switch button 10 that has been pressed performs a rotating operation at that position while being pressed down in the pressing direction. Therefore, the upper and lower gaps formed between the opening 31 of the operation panel 30 and the switch button 10 are different from the gap sizes δ ₁ and δ ₂ before the pressing operation to the gap size δ ₁ ′ after the pressing operation. , Δ ₂ ′.

As described above, in this embodiment, since the rotation center C of the switch button 10 is located near the surface of the operation panel 30, the switch button 10
Both the state before pressing operation and the state after pressing operation
The gap formed between the switch button 10 and the opening 31 can be substantially evenly distributed between the upper gap and the lower gap.
The gap between 0 and the opening 31 can be reduced.

In this embodiment, the center of rotation C of the switch button 10 is located at the periphery of the pressing surface of the switch button 10 but slightly outside. Therefore, by pressing an arbitrary position on the pressing surface of the switch button 10, the rotation center C is applied to the switch button 10.
Since the rotating operation can be performed, the operation of the push button switch is stable.

Further, since the rotation center C of the switch button 10 is arranged at the peripheral portion of the switch button 10, the first guide path and the second guide groove 22 formed by the first guide groove 21 are formed. Since the second guide routes are substantially orthogonal to each other, one guide route prevents play in the direction of the other guide route. More specifically, the first guide protrusion 11 of the switch button 10 can cause a play in a substantially vertical direction along the first guide groove (first guide path) 21, but the first guide protrusion 11 in which the second guide protrusion 12 is inserted is provided. Since the two guide grooves (second guide paths) 22 are formed in a substantially horizontal direction, such play is restricted. In addition, the second guide protrusion 12 may cause a play in the substantially horizontal direction along the second guide groove (second guide path) 22, but the first guide groove (first guide path) 21 may be substantially vertical. Since it is formed, such play is also regulated. Thus, switch button 1
The switch structure according to the present embodiment also provides a stable switch operation from the viewpoint of suppressing play at zero.

FIG. 3 shows a sectional view of a second embodiment of the present invention.

This embodiment differs from the first embodiment in that
The arc shapes of the first and second guide grooves 24 and 25 formed in the switch button support member 20 are changed, and the position of the center point C of these arc shapes is disposed a predetermined distance above the pressing surface of the switch button 10. Things. For this reason, the first guide groove 24 is in a state where the front surface is open, and the upper edge portion 33 of the opening 31 of the operation panel 30 covers the opened portion. Therefore, during assembly,
First and second guide projections 11 and 12 of switch button 10
Are inserted from the opening portions of the first and second guide grooves of the switch button support member 20 on the front side.

As described above, the first and second guide grooves 24, 25
If the position of the center point C of the arc shape is arranged above the pressing surface of the switch button 10 by a predetermined distance, the operation of the pressed switch button 10 has a more pressing component (pressing component) in the pressing direction. Since it becomes large, a sufficient operation stroke can be secured at any point on the pressing surface of the switch button 10, and the operability is further improved.

However, the rotation center C of the switch button 10
Is arranged at a position distant from the pressing surface of the switch button 10, the operation of the switch button 10 approaches the sliding operation of the sliding switch structure (see FIG. 5), and the gap δ between the switch button 10 and the opening 31. ₁ , δ ₁ ', δ ₂ , δ
_Although both ₂ ′ can be set small, it is not desirable that the switch button 10 is disposed too far from the pressing surface of the switch button 10 because the operation error due to so-called tangling is likely to occur. Therefore, operation stability and
It is desirable to set the position of the rotation center C of the switch button 10 at an appropriate position according to design requirements while taking into account the allowable amount of the gap and the like.

FIG. 4 is a sectional view of a third embodiment of the present invention.

In this embodiment, the first and second guide grooves 26 and 27 of the switch button support member 20 are
This is an example in which a so-called seesaw switch is formed by forming an arc shape having a center C on the inner side of the pressing surface of the switch button 110 within 30 planes and on the back side.

For this reason, the switch button 11 is formed in a substantially symmetrical shape in the upper and lower directions, and operation parts 115 and 116 are provided on the upper and lower parts thereof, respectively.
, Switch bodies 52 and 54 having operated parts 53 and 55 pressed by operation parts 115 and 116 provided above and below the switch button 10 are arranged. In addition, on the operation panel 130 provided with the opening 131, holding wall portions 132, 132 that cover the front sides of the first and second guide grooves 26, 27, respectively, are formed.

In this configuration, similarly to the first and second embodiments, the switch button 10 is connected to the first guide projection 111 on the upper portion thereof via the switch button mounting portion 23 of the switch button support portion 20 by the first button. In the state of being inserted in the guide groove 21,
The second guide projection 112 is connected to the front opening 2 of the second guide groove 27.
By mounting from 8, the switch button support member 20 is attached.

According to such a configuration, of the pressing surface of the switch button 10, the upper and lower portions of the switch button 10 for the pressing operation are separated by the position of the rotation center C of the operation of the switch button 10 as a boundary. The so-called seesaw switch is configured because the directions of the rotation operations of 10 are opposite.

As described above, according to the switch structure of the present invention having two guide mechanisms, by appropriately selecting the shapes and combinations of the two guide paths, for example, the two guide paths as in the above three embodiments are provided. Even when both paths are arc-shaped, by appropriately setting the position of the center point of the arc-shaped, a one-way push switch having various characteristics (first and second embodiments),
A seesaw switch (third embodiment) can be configured.

Although the present invention has been described with reference to the embodiment, the switch structure of the operation panel according to the present invention is not limited to the above embodiment, and may be configured as follows.

(1) In the above embodiment, the guide portions (first and second guide grooves 21, 22, 24, 25, 26, 27) are provided with the switch button for both the first guide mechanism and the second guide mechanism. Although provided on the support member 20 side and guided portions (first and second guide projections 11, 12, 111, 112) are provided on the switch buttons 10 and 110 side, these may be reversed. One of the guide mechanisms may be provided on the switch button 10 side, and the other guide section may be provided on the switch button support member 20 side.

(2) In the above-described embodiment, the guide portion and the guided portion are constituted by the combination of the guide groove and the guide projection. However, the guide portion for guiding the guided portion along a predetermined guide route, and the guide portion and the guided portion. Any known guide mechanism may be adopted as long as it is a combination of guide portions. For example, the guide portion may be constituted by a guide protrusion forming a guide path of a predetermined length, and the guided portion may be constituted by a guide recess engaged with the guide protrusion so as to be guided along the guide protrusion. it can.

(3) In the above-described embodiment, the first and second guide paths formed by the first and second guide grooves are formed in an arc shape centered on the same point C, so that the switch button 1
Although the case where the rotation operation is performed with 0 as the rotation center about the point C has been described, the first and second guide routes are not limited to the arc shape, and may be constituted by a straight line or an arbitrary curve as necessary. Good.

(4) In the above embodiment, the switch button support 20 is formed as a member different from the operation panel 30 and the circuit board 40. However, if the switch button can be assembled, the switch button support 2
0 may be integrally formed with either or both of these.

(5) In the above embodiment (FIGS. 1 and 2), the spring 60 for applying a restoring force to the switch button 10 is provided. However, the switch body 50 also has a constant restoring force. If the restoring force is used, such a spring 60 need not always be provided.

[0066]

As described above, according to the present invention, the switch button is configured to perform an operation having a rotation component by the two guide paths of the first and second guide mechanisms. By setting the guide route of the mechanism as necessary, the instantaneous center (center of rotation) of the operation of the switch button can be arranged at any position including the outside of the operation panel without the switch button support. , Any operation mode can be given to the switch button.

Further, since the switch button performs an operation including a rotation component, an operation failure due to stiffness unlike a slide operation type switch structure is unlikely to occur. To prevent the operation failure due to the stiffness, the depth of the switch is increased. Since there is no need to take the switch, the thickness of the switch can be reduced.

The guide paths of the first and second guide mechanisms are arranged such that the gap formed between the opening and the opening on both sides of the operation direction of the switch button decreases or increases together with the operation of the switch button. According to this structure, before and after the pressing operation of the switch button, it is possible to reduce a gap that is shifted to one of these two sides, and to prevent a large gap from being formed.

[Brief description of the drawings]

FIG. 1 is a sectional view showing a first embodiment of a switch structure of an operation panel according to the present invention.

FIG. 2 is an exploded explanatory view of the switch structure.

FIG. 3 is a sectional view showing a second embodiment of the switch structure of the operation panel according to the present invention.

FIG. 4 is a sectional view showing a third embodiment of the switch structure of the operation panel according to the present invention.

FIG. 5 is a sectional view showing a conventional slide operation type switch structure.

FIG. 6 is a sectional view showing a conventional rotary operation type switch structure.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Switch button 11 1st guide pin 12 2nd guide pin 13 Upper flange 14 Lower flange 15 Switch pressing piece 20 Guide 21 1st guide groove (1st guide part) 22 2nd guide groove (2nd guide part) 30 Operation panel 31 opening 40 circuit board 50 switch body 51 operating piece

 ────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Kiyotaka Naito 1-7-10 Kikuzumi, Minami-ku, Nagoya-shi, Aichi F-term in Harness Research Institute, Inc. (reference) 5G006 AZ01 BA01 BB01 BC03 CB01 DD05 LA09 5G025 AA02 AA13 BA04 BA05 CA04 EA02 EB04 FA01 FA02 5G035 AA24 CA03 CB01 DA03

Claims (6)

[Claims] An operation panel provided with an opening; a switch button fitted into the opening; a switch button support for supporting the switch button in the operation panel; a first guided portion; A first guide mechanism comprising a first guide portion for guiding the first guided portion along a first guide route; a second guided portion and a second guided portion; A second guide mechanism comprising a second guide section for guiding along a guide route, wherein one of the first guide section and the first guided section is provided on the switch button, and the other is provided on the switch button. One of the second guide portion and the second guided portion is provided on the switch button, the other is provided on the switch button support portion, and the first guide path and The second guide route is Switch of a control panel switch button is characterized in that it is configured to perform the operations having a rotational component. 2. The switch structure for an operation panel according to claim 1, wherein said first guide route and said second guide route are both formed in an arc shape centered on the same point. 3. A gap formed between the opening and the switch button in a direction in which the switch button is displaced in accordance with the operation of the switch button, according to an operation of the switch button that is pressed. The switch structure of the operation panel according to claim 1, wherein the first guide route and the second guide route are configured such that both decrease or increase. 4. The switch structure for an operation panel according to claim 3, wherein both the first guide route and the second guide route are formed in an arc shape centered on a point near the operation panel surface. 5. The operation panel according to claim 4, wherein both the first guide route and the second guide route are formed in an arc shape centered on a point outside a pressing surface of the switch button. Switch structure. 6. The operation panel according to claim 4, wherein the first guide route and the second guide route are each formed in an arc shape centered on a point inside a pressing surface of the switch button. Switch structure.