KR100807613B1 - Multidirectional input device - Google Patents

Abstract

An object of this invention is to provide the multidirectional input device by which the deviation of the operation force in an operation direction can be reduced and a favorable operation feeling can be obtained.

As a solution for this, the multidirectional input device 1 of the present invention is formed in an annular shape with a plurality of circumferential edge fixed contacts 3 arranged in an annular shape and having a predetermined width, and the inner side of the circumference thereof. Or a flat plate-like peripheral edge movable electrode 4 formed with a convex to-be-held portion 4a extending toward the outside and generating a reaction force against the pressing force generated on the periphery, and for an annularly arranged peripheral edge. It is disposed above the casing 2 for holding the fixed contact 3 for the peripheral edge and the movable electrode 4 for the peripheral edge with a predetermined gap while facing the fixed contact 3, and the movable electrode for the peripheral edge. And an operation member 9 having a peripheral edge pressing portion 12a for pressing the movable electrode 4 for peripheral edge.

And the above-mentioned movable electrode for peripheral edges 4 has the reaction force adjustment part which makes reaction force which arises in the vicinity 4e of the to-be-held part 4a to the same degree as reaction force produced in the part 4f other than the vicinity of the to-be-held part 4a. It is formed to have (4c, 4d).

Description

Multi-directional input device {MULTIDIRECTIONAL INPUT DEVICE}

1 is an exploded perspective view illustrating a multidirectional input device according to a first embodiment.

Fig. 2 is a plan view showing a casing disposed in the multidirectional input device of the first embodiment.

Fig. 3 is a plan view of a casing in which movable electrodes for peripheral edges are arranged in the multidirectional input device according to the first embodiment.

4 is a plan view showing another example of the movable electrode for the peripheral edge;

5 is a cross-sectional view taken along the line A-A of FIG.

FIG. 6 is a plan view showing another example of a movable electrode for a peripheral edge different from that shown in FIG. 4. FIG.

FIG. 7 is a sectional view taken along the line B-B in FIG. 6; FIG.

8 is a perspective view of a multidirectional input device of a first embodiment;

FIG. 9 is a cross-sectional view taken along the line C-C in FIG. 8; FIG.

FIG. 10 is a sectional view taken along the line D-D in FIG. 8; FIG.

Fig. 11 is a sectional view taken along the line C-C in Fig. 8 at the time of input operation in the circumferential direction of the multidirectional input device of the first embodiment.

FIG. 12 is a sectional view taken along the line D-D in FIG. 8 at the time of input operation in the circumferential direction of the multidirectional input device of the first embodiment. FIG.

The top view of the casing in which the movable electrode for peripheral edges is arrange | positioned in the multidirectional input device of 2nd Embodiment.

FIG. 14 is a sectional view taken along the line D-D in FIG. 8 in the multidirectional input device according to the third embodiment; FIG.

15 is a plan view of a casing disposed in the multidirectional input device of a third embodiment;

The top view of the casing in which the circumferential edge movable electrode and the 2nd circumferential edge movable electrode are arrange | positioned in the multidirectional input device of 3rd Embodiment.

FIG. 17 is a cross-sectional view taken along the line C-C in FIG. 8 in the multidirectional input device according to the fourth embodiment. FIG.

18 is an exploded perspective view of a multidirectional input device of a fifth embodiment;

19 is a plan view of a casing in the multidirectional input device of a fifth embodiment;

20 is a cross-sectional view of the multidirectional input device according to a fifth embodiment in a cross section taken along the line E-E in FIG. 19;

FIG. 21 is a cross-sectional view of a multidirectional input device according to a fifth embodiment in a cross section taken along the line F-F in FIG. 19; FIG.

Fig. 22 is an exploded perspective view showing a unitized lid member of the multidirectional input device according to the fifth embodiment.

Fig. 23 is a perspective view showing the arrangement relationship of unitized lid members of a multidirectional input device according to a fifth embodiment.

24 is an exploded perspective view showing an example of a conventional multidirectional input device;

25 is a plan view showing a casing disposed in a conventional multidirectional input device;

Fig. 26 is a schematic diagram showing input operation in a circumferential direction in a conventional multidirectional input device.

* Description of the symbols for the main parts of the drawings *

1: multi-directional input device

2: casing

2a: cavity part

2b: guide wall

2c: bottom surface outside the guide wall

2d: bottom surface inside the guide wall

2e: holding part

2f: holding surface

2g: support

2h: support surface

2i: catch

3: fixed contact for the perimeter edge

3a: withdrawal terminal

3b: tip of the lead-out terminal

4: movable electrode for peripheral edge

4a: Maintenance part

4b: Supported part

4c, 4d: reaction force adjustment unit

4e: part near the maintained part

4f: Parts other than the part to be held

5: common electrode for peripheral edge

5a: withdrawal terminal

5b: tip of lead-out terminal

6: fixed contact center

6a: withdrawal terminal

6b: tip of the lead-out terminal

7: center movable electrode

7a: bend

7b: pedestal

8: common electrode for center

8a: withdrawal terminal

8b: tip of lead-out terminal

9: operation member

10: operating body

10a: control panel

10b: convex

11: center pressure member

11a: Insertion mount

11b: interference

11c: recessed portion

11d: central pressurization

12: pressure member for the peripheral edge

12a: Pressing portion for the peripheral edge

12b: center hole

12c: convex wall

13: cover body

13a: center hole

13b: insertion through hole

13c: lower part of the center hole

14: return member

14a: elastic diaphragm portion

14b: center hole

14c: protrusion

15: restraint member

15a: Arm part

15b: center hole

16: movable electrode for second peripheral edge

16a: bend

16b: pedestal

17: common electrode for the second peripheral edge

17a: withdrawal terminal

17b: distal end of the lead terminal

Patent Document 1: Japanese Patent No. 3183776

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multidirectional input device, and more particularly, to a multidirectional input device used for azimuth input operation of various electronic devices as direction keys used in a mobile phone, a portable music player, a controller for a game machine, and the like.

In general, a multidirectional input device is capable of performing key input in multiple directions such as up, down, left, and right by pressing a direction key or a stick-like input key by pressing or hardness.

One example of a conventional multidirectional input device is formed as shown in Figs. This conventional multidirectional input device 100 arranges each component part inside the casing 101 formed into a rectangular box, and covers the opening of the uppermost part of the casing 101 with the lid 112.

In order from the lower side to the upper and lower parts, that is, the casing 101, the center fixed contact 102, the fixed contact 103 for the circumferential edge, the movable electrode plate 105, the inversion member 106, the operation member 107 Explain in order.

In the substantially rectangular concave portion of the casing 101, an annular guide wall 101b formed by partially divided into four in the circumferential direction is formed.

The circular center fixed contact 102 is formed integrally with the casing 101 at the circular bottom center position inside the guide wall 101b of the casing 101 so as to expose the surface. Further, four rectangular peripheral edge fixed contacts 103 are formed integrally with the casing 101 so as to expose the surface from the guide wall 101b of the casing 101 to the bottom of the outer recess. As shown in FIG. 19, these peripheral edge fixed contacts 103 are arranged at substantially equal intervals in the circumferential direction along the four sides of the inner bottom surface of the casing 101, respectively.

As shown in FIG. 24, the movable electrode plate 105 is a flat plate-shaped electrode which is arranged to face the center fixed contact 102 and the circumferential edge fixed contact 103, using a metal plate such as spring phosphor bronze or the like. Formed. The shape of the movable electrode plate 105 is a circular center movable electrode portion 105a in the center of the center facing the center fixed contact 102 and the outermost annular circumference facing the fixed contact 103 for the circumferential edge. An annular portion 105c continuous through the edge movable electrode portion 105b, the inner and outer center movable electrode portion 105a, the peripheral edge movable electrode portion 105b, and the connecting portion 105d, and a guide wall ( It is formed to have two circular openings 105e through which 101b) is inserted. And this movable electrode plate 105 is inserted through the predetermined gap with the circumferential fixed contact 103 and the center fixed contact 102, while inserting the opening 105e through the guide wall 101b. do. Each connecting portion 105d that partially connects the circumferential edge movable electrode portion 105b and the annular portion 105c is formed to pass through the slit portion 101a formed in the annular guide wall 102b.

As shown in FIG. 24, although the inversion member 106 is formed in the dome shape, such as a metal dome, on the upper side of the torus part 105c, it may be abbreviate | omitted.

The operation member 107 presses the movable electrode plate 105, and is disposed above the movable electrode portion 105 as shown in FIG. 24. This operation member 107 has an operation unit 108 for carrying out an input operation, a collar portion 109, a central pressing portion 110, and a peripheral edge pressing portion 111. The collar portion 109 is formed in a wheel shape at a position facing the movable electrode portion 105b for the circumferential edge. The center press part 110 protrudes in the direction opposite to the center movable electrode part 105a near the center inside the collar part 109. The circumferential edge pressing portion 111 protrudes from the outer circumferential side of the collar portion 109 in a direction opposite to the circumferential edge movable electrode portion 105b. The collar portion 109 is formed with an arc-shaped opening 109c that can be inserted into the guide wall 101b.

The lid 112 covering the casing 101 is formed in the shape of a rectangular flat plate with a rectangular central hole 112a through which a rectangular stick-like operation portion 108 of the operation member 107 passes. In addition, this cover body 112 is formed so that the one part 109a of the operation member 107 may contact | abut, and the rotation support point of the said hardness operation, when longitudinally operating the operation member 107.

In the conventional multidirectional input device 100 configured as described above, as shown in FIG. 26, the operation member 107 can be input radially outward by hardness of the radially outward direction. Specifically, the collar portion 109 of the operation member 107 whose hardness is manipulated pressurizes the movable electrode portion 105b for the peripheral edge of the movable electrode plate 105, whereby the movable electrode portion 105b for the peripheral edge is surrounded. It contacts with the edge fixed contact 103, and is electrically conducting. In addition, since the movable electrode plate 105 is formed using a metal plate having an elastic force, an appropriate reaction force is generated on the operation member 107 at the time of the hardness operation of the operation member 107. Therefore, it is possible to obtain a suitable feeling of operation when making contact with the circumferential edge movable electrode part 105b and the circumferential edge fixed contact 103 (refer patent document 1).

However, the circumferential edge movable electrode portion 105b formed in the movable electrode plate 105 is used for the circumferential edge formed in the vicinity of the connecting portion 105d, compared to the movable electrode portion 105b for the circumferential edge formed in the vicinity of the connecting portion 105d. The reaction force of the movable electrode part 105b became large, and there existed a problem that the dispersion | variation generate | occur | produced in the circumferential direction in the input operation feeling to radial direction outer side.

Moreover, since the casing 101 has the guide wall 101b which penetrates the movable electrode plate 105 and the operation member 107, and restrains the arrangement | positioning position, the direction which stands up and forms the guide wall 101b is formed. There was a problem that it was difficult to reduce the thickness.

In addition, since the movable electrode plate 105 has the central movable electrode portion 105a, the annular portion 105c, the connecting portion 105d and the movable electrode portion 105b for the circumferential edge, the structure is likely to be complicated and multidirectional. There was a problem that it was difficult to lower the manufacturing cost of the input device 100.

Accordingly, the present invention has been made in view of such a point, and it is an object of the present invention to provide a multidirectional input device which makes it possible to reduce the deviation of the operation force in the radially outward direction in the circumferential direction and obtain a good operating feel. Doing.

Further, another object of the present invention is to provide a multidirectional input device which is capable of miniaturizing the multidirectional input device and reducing the manufacturing cost thereof.

In order to achieve the above object, the multidirectional input device of the present invention annularly arranges a plurality of peripheral edge fixed contacts in a casing, and has an annular flat plate facing the peripheral edge fixed contacts arranged annularly. The formed peripheral edge movable electrode is held in the casing through a predetermined gap on the upper side of the fixed edge fixed contact, and a portion of the peripheral direction of the peripheral edge movable electrode is pressed against the reaction force against the reaction force, The circumferential edge movable electrode is disposed by arranging an operation member having a circumferential edge pressing portion connected to the fixed contact for circumferential edge in the casing, and the circumferential edge pressing portion presses a portion of the circumferential direction of the circumferential edge movable electrode. And fixed contact for the peripheral edge Conduction is formed by the art to detect an input operation by pressing.

The multidirectional input device according to the present invention further provides a reaction force generated near the holding portion of the movable electrode for circumferential edge, in which the movable electrode for circumferential edge is held in the casing, other than the vicinity of the held portion of the movable electrode for circumferential edge. It has a reaction force adjustment part which is made to the same extent as reaction force which arises in a part, It is characterized by the above-mentioned.

Thereby, reaction force in the circumferential direction of the circumferential edge movable electrode becomes constant in any part, and it becomes possible to reduce the variation of the operating force in the radial direction outward direction in the circumferential direction.

Moreover, the multidirectional input device of this invention is formed by making reaction force adjustment part smaller the width dimension of the radial direction of the to-be-held part of the movable electrode for circumferential edges than the width dimension of the part other than the to-be-held part, It is characterized by the above-mentioned. have.

This makes it possible to change the operating force in the radially outward direction in the circumferential direction only by simple processing such as press working.

Further, the multidirectional input device of the present invention is characterized in that the reaction force adjusting portion is formed by making the thickness of the vicinity of the held portion of the movable electrode for the peripheral edge thinner than the thickness of the portion other than the vicinity of the held portion.

Thereby, it becomes possible to change the operation force to the radial direction outward direction in a circumferential direction, without changing the length of a width direction.

The multidirectional input device according to the present invention is characterized in that the reaction force adjusting portion is formed concave or convex along the circumferential direction with respect to a portion other than the vicinity of the held portion in the movable electrode for the circumferential edge. .

Thereby, the operation force of the radial direction outward direction in a circumferential direction can be changed only by simple processes, such as press work.

The multidirectional input device of the present invention is further characterized in that the circumferential edge movable electrode has a supported portion supported by the supporting portion of the casing, and the reaction force adjusting portion is formed integrally with the supported portion.

Thereby, it becomes possible to stably support the circumferential edge movable electrode, without changing the operation force of the radial direction outward in the circumferential direction. Moreover, by forming the said supported part integrally with the reaction force adjustment part, it becomes possible to reduce the formation process of the reaction force adjustment part.

Moreover, the multidirectional input device of this invention is characterized by the movable electrode for peripheral edges being formed using the metal plate material.

This makes it possible to reduce the thickness of the movable electrode for the peripheral edge while exerting a high repulsion force on the movable electrode for the peripheral edge.

In addition, the multidirectional input device of the present invention has a casing formed in a box shape whose outer circumference becomes a polygonal shape, and movable for the circumferential edge from a position where the fixed contact for the circumferential edge is disposed inside the corner portion of the outer circumference. In order to arrange | position an electrode with a predetermined gap, it is characterized by having the holding part of the required height holding a to-be-holded part.

Thereby, it becomes possible to use the edge part of the casing which becomes easy to become a dead space suitably.

In addition, the multidirectional input device of the present invention has a central fixed contact, a predetermined gap, and a central fixed contact in the inner peripheral side portions of the plurality of peripheral edge fixed contacts and the peripheral edge movable electrodes arranged in an annular shape in the casing. It is characterized by including the operation member which has the center movable electrode arrange | positioned opposingly and the center press part which presses a center movable electrode on the upper side of the center movable electrode.

As a result, not only the input operation in the radially outward direction but also the input operation in the center pressing direction can be performed.

Moreover, the multidirectional input device of this invention is characterized in that the center movable electrode is formed integrally with the circumferential edge movable electrode through the support part.

This makes it possible to reduce the part score of the multidirectional input device.

Moreover, the multidirectional input device of this invention is characterized in that the center movable electrode is formed in the dome shape which protrudes in the axial direction of a center press part.

Thereby, it becomes possible to prevent erroneous input. In addition, it is possible to obtain a good click feeling when operating in the center pressing direction.

The multidirectional input device of the present invention is characterized in that the holding portion has a common electrode at a portion where the holding portion is always in contact with the held portion.

Thereby, it becomes possible to form the space and the holding | maintenance part which were formed only in order to contact a common electrode with the movable electrode for peripheral edges.

The multidirectional input device of the present invention is characterized in that at least one of the fixed contact for the peripheral edge, the common electrode or the center movable electrode is insert molded into the casing.

This makes it possible to reduce the part score. In addition, it becomes possible to reduce the assembling process.

In addition, the multidirectional input device of the present invention has an outgoing terminal through which at least one of a fixed contact for a peripheral edge, a common electrode, or a center movable electrode is drawn out of the casing, and the outgoing terminal drawn out of the casing corresponds to the type of each member. It is characterized by being formed in a different shape accordingly.

This makes it possible to prevent wrong assembly when the multidirectional input device is attached to another device.

In addition, the multidirectional input device of the present invention includes a movable electrode for peripheral edge and a movable electrode for second peripheral edge which is arranged while being insulated from the movable electrode for peripheral edge and the fixed contact for peripheral edge between the movable electrode for peripheral edge and the fixed contact for peripheral edge. It is characterized by having.

Thereby, two steps of input are possible in a pressurization direction in the input operation to radial direction outward direction.

The multidirectional input device of the present invention is characterized in that the second peripheral edge movable electrode is formed in a dome shape protruding in the axial direction of the peripheral electrode movable electrode while covering the fixed contact for the peripheral edge.

This makes it possible to prevent a malfunction in response to the two-stage input in the radially outward direction. Moreover, when performing the 2nd stage of input operation to radial direction outward direction, it becomes possible to obtain a favorable click feeling.

In addition, the multidirectional input device of the present invention has a circumferential edge pressing member having a circumferential edge pressing portion, a central pressing member having a central pressing portion, and an operating body directly inputted from the operating main body, The pressing member for circumferential edge is arrange | positioned through insertion of the center pressing member in the center hole formed near the center, and the front side of the pressing member for a center is larger than the outer shape of the center hole of the pressing member for circumferential edge, and pressurizing It is characterized in that the outer shape is formed in a shape different from the pressing direction in which the rear of the direction is equal to the outer shape of the center hole of the pressing member for peripheral edges or smaller than the outer shape of the center hole.

Thereby, when the center pressurizing member presses the center movable electrode, it becomes possible to prevent the circumferential edge pressurizing member from contacting the casing and limiting the movement of the center pressurizing member.

Further, the multidirectional input device of the present invention has a return member for generating a restoring force in the direction of restoring the operation member to the initial position of the operation member when the operation member presses the movable electrode for the peripheral edge or the center movable electrode. It is characterized by that.

Thereby, when performing an input operation, it becomes possible to always perform an input operation from an initial position.

In addition, the multidirectional input device of the present invention is characterized in that the return member is formed in a cover shape so as to cover an opening formed in the casing.

Thereby, it becomes possible to prevent the entry of malfunction factors, such as dust and moisture, into a casing.

In addition, the multi-directional input device of the present invention, the casing is a lid body for restraining the sliding movement amount in the radially outward direction of the pressing member for the circumferential direction, and the guide for sliding freely supporting the pressing portion for the circumferential edge from the opposite direction of the lid body It has a wall, The circumferential edge pressurizing member is formed so as to pressurize the circumferential edge movable electrode, sliding the part which the center pressurizing part and the center movable electrode contact.

Thereby, it becomes possible to input-operate in the radial direction outward while sliding an operation member.

Moreover, the multi-directional input device of this invention has the cover body which the casing restrains the sliding movement amount to the outer peripheral direction of the pressurizing member for a peripheral edge, and the pressurizing member for a peripheral edge has a center press part and a center movable electrode. It is characterized in that it is formed so as to pressurize the movable electrode for peripheral edges by making a contact point of a rotation support point.

Thereby, it becomes possible to input-operate in radial direction outward direction, making hardness of an operation member.

Implement the invention  Best form for

Hereinafter, first to fourth embodiments of the multidirectional input device of the present invention will be described with reference to FIGS. 1 to 17.

Here, FIG. 1 has shown the exploded perspective view of the multidirectional input device of 1st Embodiment. 2 shows a plan view of the casing in the multidirectional input device of the first embodiment. FIG. 3: shows the top view of the casing in which the circumferential edge movable electrode was arrange | positioned in the multidirectional input device of 1st Embodiment. 4 shows another example of the movable electrode for the circumferential edge. 5 is a cross-sectional view taken along the line A-A of FIG. FIG. 6: shows another example of the movable electrode for peripheral edges different from what was shown in FIG. FIG. 7 is a sectional view taken along line B-B in FIG. 8 is a perspective view of the multidirectional input device according to the first embodiment. 9 is a cross-sectional view taken along the line C-C in FIG. FIG. 10 is a sectional view taken along the line D-D in FIG. 8. FIG. 11 is a cross-sectional view taken along the line C-C in FIG. 8 at the time of input operation in the circumferential direction of the multidirectional input device of the first embodiment. FIG. 12 is a sectional view taken along the line D-D in FIG. 8 at the time of input operation in the circumferential direction of the multidirectional input device of the first embodiment.

13 has shown the top view of the casing in which the circumferential edge movable electrode was arrange | positioned in the multidirectional input device of 2nd Embodiment.

14 has shown D-D sectional drawing of FIG. 8 in the multidirectional input device of 3rd Embodiment. 15 is a plan view of the casing in the multidirectional input device according to the third embodiment. FIG. 16: shows the top view of the casing in which the circumferential edge movable electrode and the 2nd circumferential edge movable electrode are arrange | positioned in the multidirectional input device of 3rd Embodiment.

17 is a sectional view taken along the line C-C in FIG. 8 in the multidirectional input device according to the fourth embodiment.

18 has shown the exploded perspective view of the multidirectional input device of 5th Embodiment. 19 is a plan view of a casing in the multidirectional input device of a fifth embodiment. 20 is a cross-sectional view of the multidirectional input device according to a fifth embodiment in the cross section taken along the line E-E in FIG. 19. FIG. 21 is a cross-sectional view of the multidirectional input device according to a fifth embodiment in the F-F cross section of FIG. 19. 22 is an exploded perspective view showing a unitized lid member of the multidirectional input device according to the fifth embodiment. It is a perspective view which shows the arrangement relationship of the cover member unitized of the multi-directional input device in 5th Embodiment.

(1) First embodiment

The multidirectional input device 1 according to the first embodiment of the present invention is formed by assembling the respective disassembled components as shown in Fig. 1 as shown in Figs. The components of the multidirectional input device 1 according to the present embodiment are casing 2, a fixed contact 3 for a peripheral edge, a movable electrode 4 for a peripheral edge, and a common electrode for a peripheral edge in order from the bottom side to the upper side. 5) Used for input in the pressing direction at the center of each member used for input in the circumferential direction of the back, the center fixed contact 6 and the center movable electrode 7 and the center common electrode 8, etc. Each member, the operation member 9, the cover body 13, the return member 14, and the restraining member 15 which are used are demonstrated in order.

As shown in FIG. 2, the casing 2 of the multidirectional input device 1 is formed in the substantially rectangular thin box shape using insulating synthetic resin. In addition, a substantially circumferential cavity 2a is formed in the central portion of the casing 2. At a position about 2/3 of the inner circumferential diameter of the cavity portion 2a, an annular guide wall 2b is formed from the bottom. Further, at a diagonal position of the casing 2 of the cavity portion 2a, a holding portion 2e is formed integrally with radially holding the movable electrodes 4 for peripheral edges on the concave grooves so as not to move in the circumferential direction. have. The movable electrode for the circumferential edge in the position above the bottom face (hereinafter referred to as "guide wall outer bottom face") 2c that is inside the cavity 2a of the casing 2 and is outside the guide wall 2b. The holding portion 2e holding the portion 4 and the supporting portion projecting from the position at which the holding portion 2e is in the middle of the holding portion 2e as the outer circumference of the guide wall 2b to support the movable electrode 4 for the circumferential edge ( 2g) is formed. And the holding surface 2f of the holding | maintenance part 2e and the supporting surface 2h of the supporting part 2g are the same on each surface 2f, 2h in order to hold the movable electrode 4 for a peripheral edge horizontally. It is formed to be flat.

The fixed contact 3 for the peripheral edge is integrally molded to the casing 2 by insert molding. In addition, this circumferential edge fixed contact 3 is exposed in the bottom face 2c of the outer side of the guide wall of the casing 2, and has a constant space | interval in 4 directions of up, down, left, and right when viewed from a plane. It is arranged in a ring. And the fixed contact 3 for each circumferential edge has the extraction terminal 3a for drawing out to the exterior of the casing 2. A portion (hereinafter referred to as a "tip of a lead terminal") 3b drawn out of the casing 2 of the lead terminal 3a is the common electrode 5 for the peripheral edge, the fixed contact 6 for the center, and the center for The lead terminals 3a, 5a, 6a, 8a are formed in different shapes so as to distinguish them from the tips 5b, 6b, 8b of the lead terminals 5a, 6a, 8a of the common electrode 8, respectively. have. For example, the lengths and widths of the lead terminals 3a, 5a, 6a, 8a, and the like are respectively different, or the tip portions 3b, 5b, 6b, 8b of the lead terminals 3a, 5a, 6a, 8a are different. ), Each lead terminal 3a, 5a, 6a, 8a is formed so that each may have a different shape or shape, respectively.

As shown in FIG. 1 and FIG. 3, the movable electrode 4 for peripheral edges is formed in flat form using metal flat materials, such as spring phosphor bronze which generate | occur | produces a large reaction force, and the outer side of the guide wall of the casing 2 is carried out. As an annular shape overlapping with the bottom face 2c, it is formed with the width | variety of a predetermined radial direction so that it may become the size equivalent to the ring formed by the four circumferential edge fixed contacts 3. In the circumferential edge movable electrode 4, a held portion 4a extending radially outward from the outer circumference thereof is formed in four directions of the outer circumference corresponding to the holding portion 2e. The convex to-be-supported part 4b extended inward from the inner periphery is formed in the circumferential direction intermediate position of each to-be-held part 4a. The protruding length of the held portion 4a is such that the holding portion 2e does not pass outward while one side is held by the holding surface 2f. Further, the protruding length of the supported portion 4b is such that it is supported by the supporting surface 2h and does not come into contact with the guide wall 2b inside thereof.

In addition, the movable electrode 4 for the peripheral edge has a reaction force adjusting portion 4c which makes the reaction force generated in the vicinity of the held portion 4a 4e and the reaction force generated in the portion 4f other than the vicinity of the held portion 4a to the same degree. , 4d). Specifically, as shown in FIG. 3, the reaction force adjusting portions 4c and 4d have a width dimension in the radial direction of the vicinity of the held portion 4a of the portion 4f except for the vicinity of the held portion 4a. It is formed by press working so as to be smaller than the width dimension in the radial direction. In addition, since the reaction force adjusting portions 4c and 4d are easily formed in the circumferential edge movable electrode 4, the reaction force adjusting portions 4c and 4d are preferably formed integrally with the supported portion 4b.

Of course, reaction force adjustment part 4c, 4d is not limited to the shape formed according to the change of the width dimension mentioned above. For example, as shown in FIGS. 4 and 5, the reaction force adjusting portions 4c and 4d have a thickness of the vicinity of the held portion 4a and the thickness of the portion 4f except the vicinity of the held portion 4a. It may be formed by making it thinner than thickness, and as shown to FIG. 6 and FIG. 7, in the thickness direction along the annulus in the part 4f other than the to-be-held part vicinity in the movable electrode 4 for peripheral edges along the annulus. Alternatively, the convex shape may be formed. In addition, the formation position and number of reaction force adjustment parts 4c and 4d are not limited to what was mentioned above, A plurality of reaction force adjustment parts 4c and 4d of various shapes are provided in various positions on the ring of the movable electrode 4 for peripheral edges. It is more preferable to form such that the reaction force of the movable electrode 4 for the peripheral edge changes steplessly between the respective held portions 4a.

As shown in FIG. 2, the peripheral electrode common electrode 5 is integrally formed with some of the holding parts 2e holding the movable electrode 4 for the peripheral edges of the four corners of the casing 2 by insert molding. While being molded, only the convex portion 5c formed in the common electrode 5 for the peripheral edge is exposed from the holding surface 2f of the several holding portions 2e. In addition, each common electrode 5 for peripheral edges has a lead terminal 5a for leading out of the casing 2. As described above, the tip portion 5b of the lead terminal 5a is each lead terminal 3a, 6a of the fixed electrode 3 for the peripheral edge, the fixed electrode 6 for the center, and the common electrode 8 for the center. , 8a, the lead terminals 3a, 5a, 6a, and 8a are formed in different shapes to distinguish them from the tip portions 3b, 6b and 8b, respectively.

As shown in FIG. 2, the center fixed contact 6 has a bottom face inside the cavity 2a of the casing 2 and inside the guide wall 2b by insert molding (hereinafter, `` bottom face inside the guide wall ''). It is molded integrally with (2d). Moreover, the center fixed contact 6 is arrange | positioned so that only the convex part 6c formed in the center fixed contact 6 may protrude from the said bottom face 2d, and be exposed. And this center fixed contact 6 has the lead-out terminal 6a for drawing out to the exterior of the casing 2, and as mentioned above, the front-end | tip part 6b has each said lead-out terminal 3a. , 5a, 8a are formed in a shape different from the tip portions 3b, 5b, 8b.

As shown in FIG. 2, the center common electrode 8 is in planar U-shape which encloses the outer periphery of the center fixed contact 6 on the bottom face 2d of guide side inside by insert molding, without contacting it. Formed. In addition, this center common electrode 8 is arrange | positioned so that only the convex part 8c formed in the U-shaped center common electrode 8 may protrude from the said bottom face 2d, and may be exposed. And this center common electrode 8 has the lead-out terminal 8a for drawing out to the exterior of the casing 2, and this lead-out terminal 8a has the front-end | tip part 8b as mentioned above. Is formed in the shape different from the front-end | tip part 3b, 5b, 6b of each said drawing terminal 3a, 5a, 6a.

1, 9 and 10, the center movable electrode 7 is in contact with a curved portion 7a formed in a dome shape protruding upward and the convex portion 8c of the central common electrode 8. It has a pedestal 7b. This center movable electrode 7 has a predetermined gap and is arranged to face the center fixed contact 6. In addition, the diameter of the pedestal part 7b becomes equal to the distance between each convex part 8c which opposes the center common electrode 8. As shown in FIG. And this center movable electrode 7 is fixed by the fixing resin sheet 7c which covers the center movable electrode 8 from the upper side, as shown to FIG. 9 and FIG.

As shown in FIG. 1, FIG. 8, FIG. 9, and FIG. 10, the operation member 9 has the operation body 10, the center press member 11, and the circumferential edge press member 12. As shown in FIG.

As shown in FIG. 1, FIG. 9, and FIG. 10, the operating body 10 has the columnar convex part 10b which engages with the central press member 11 in the lower side of the disk-shaped operation part 10a. Formed.

The circumferential edge pressing member 12 has a diameter about the same as the inner diameter of the movable electrode 4 for circumferential edges, and is formed in a circular collar shape. The circumferential edge pressing member 12 has a circumferential edge pressing portion 12a that presses the circumferential edge movable electrode 4 on its outer circumferential side, and has a central hole 12b at its center portion. have. Moreover, the circular convex convex wall 12c is formed in the outer upper surface part from the center hole 12b.

The center pressurizing member 11 is a diameter which fits comfortably in the center hole 12b of the circumferential edge pressurizing member 12 in the order from upper side to the lower side (order toward the pressing direction PD of the operating member 9). The insertion mounting portion 11a formed in a circumferential shape, and the inhibiting portion 11b formed in a circular shape with a diameter larger than the diameter of the central hole 12b of the insertion mounting portion 11a and the pressing member 12 for the peripheral edge. Have Moreover, the insertion mounting part 11a has the recessed part 11c fitted with the circumferential convex part 10b of the operating body 10, The restraint part 11b has the center movable electrode 7 in the lower surface. 11d of convex center press parts which pressurize). And the center press member 11 inserts the insertion mounting part 11a into the center hole 12b of the circumferential edge press member 12, and presses the convex part 10b of the operating body 10, and the center pressurization. The recessed part 11c of a member is fitted and it is arrange | positioned in the casing 2.

The cover body 13 is formed in the rectangular shape which has the magnitude | size similar to the outer periphery of the casing 2 using a metal plate. In addition, a circular central hole 13a having a diameter larger than the diameter of the convex wall 12c is formed near the center of the lid 13, and is inserted through four corners of the lid 13; Holes 13b are formed in perforations, respectively. The lid 13 is disposed above the circumferential edge pressing member 12. When the operating body 10 is slid in an arbitrary circumferential direction, the circumferential edge pressing member 12 causes the casing ( It slides to the upper surface 2j of the guide wall 2a of 2), and it is hold | maintained so that it may slide freely, sliding the upper surface to the lower part 13c of the center hole 13a of the cover body 13. As shown in FIG. Moreover, when the circumferential edge pressurizing member 12 slides large, the outer peripheral part of the convex wall 12c will contact with the inner peripheral surface of the center hole 13c of the cover body 13, and will function as a stopper.

The return member 14 consists of elastic members, such as rubber | gum and an elastomer, and is arrange | positioned above the lid | cover 13 as shown in FIG. The return member 14 is formed to have an outer shape of the same size as the outer shape of the lid 13, and the placement of the operating body 10 with respect to the slide operation direction of the operating body 10. It has the annular elastic diaphragm part 14a which has a zigzag cross section which produces the restoring force to a position (center position). The center hole 14b of the magnitude | size which covers the outer periphery of the recessed part 11c of the center press member 11 is formed in the center part of this elastic diaphragm part 14a, and the insertion hole of the lid | cover body 13 is provided in the lower surface. The four holding parts 4a of the movable electrode 4 for peripheral edges are pressed and held to the holding surface 2f of the holding | maintenance part 2e, and the common electrode 5 for peripheral edges, while passing through 13b. The protrusion part 14c is formed. In addition, except for the central hole 14b, the return member 14 is not provided with a hole in which moisture, dust, or the like may enter the casing 2 from the outside, and is formed in the casing 2. It is formed in the shape of a cover which seals and closes an opening part.

The restraining member 15 is formed in an annular plate shape which is covered on the outer upper surface of the elastic diaphragm portion 14a of the returning member 14, and the locking portion 2i is formed on the outer surface of each side of the casing 2. The four arm parts 15a which engage with each other are protrudingly contacted downward, and the center hole 15b is formed by raising the inner circumferential part as usual so as not to disturb the movement of the elastic diaphragm portion 14a. The restraining member 15 is assembled by engaging each arm portion 15a with the respective engaging portions 2i from above thereof so as to restrain the lid 13 and the return member 14.

Next, the operation of the multidirectional input device 1 of the first embodiment will be described.

When the operation body 10 of the operation member 9 of the multidirectional input device 1 is moved by moving in an arbitrary radial direction outward and input operation, as shown in FIG. 11 or FIG. 12 moves in the slide-operated direction while sliding with the upper surface 2j of the guide wall 2b of the casing 2 and the lower portion 13c of the central hole 13a of the lid 13, and for the circumferential edge. The circumferential edge pressing portion 12a of the pressing member 12 is in contact with the circumferential edge movable electrode 4. When the operating body 10 is further slide-moved, the peripheral edge pressurizing portion 12a deforms the peripheral electrode movable electrode 4 to fix the peripheral electrode movable electrode 4 and the peripheral edge fixed below it. The contact 3 contacts and conducts. As a result, the multidirectional input device 1 can detect that the operation body 10 has been input operation in an arbitrary radial direction outside.

This radially outward input operation deforms the circumferential edge movable electrode 4 in the thickness direction, thereby producing a high repulsive force on the circumferential edge movable electrode 4. Here, since the circumferential edge movable electrode 4 of the multidirectional input device 1 of 1st Embodiment has reaction force adjustment parts 4c and 4d, reaction force in the circumferential direction of the circumferential edge movable electrode 4 is here. It becomes constant in any part, and it becomes possible to reduce the dispersion | variation in the operation force of a radial direction outer side. The reaction force adjusting portions 4c and 4d form the width dimension of the portion 4a in the vicinity of the held portion 4a smaller than the width dimension of the portion 4f other than the portion held in the vicinity of the held portion 4a. In the vicinity 4e, the reaction force can be reduced, and in the portion 4f other than the vicinity of the held portion 4a, the reaction force can be increased. Thereby, since it becomes possible to reduce the deviation of the operation force to radial direction outer side, the operation feeling of the multidirectional input device 1 becomes favorable.

As described above, the reaction force adjusting portions 4c and 4d have the thickness of the portion 4a near the held portion 4a as shown in FIGS. 4 and 5 except for the portion 4a near the held portion 4a. It is formed by making it thinner than the thickness of 4f), or as shown to FIG. 6 and 7, along the periphery to the part 4f other than the holding part 4a vicinity of the movable electrode 4 for a peripheral edge. As formed in the concave or convex shape, similarly to the case where the width dimension is changed, in the vicinity of the held portion 4a, the reaction force is reduced, and portions other than the vicinity of the held portion 4a 4f. ), It is possible to increase the reaction force.

Moreover, since this circumferential edge movable electrode 4 has the support part 4b supported without being restrained at all by the support part 2g of the casing 2, the reaction force which arises in the vicinity of the support part 4b raises much. It becomes possible to stably support the circumferential edge movable electrode 4, without making it possible. In addition, by forming the supported portion 4b integrally with the reaction force adjusting portion 4d, it is possible to reduce the formation process of the reaction force adjusting portion 4d and to lower the manufacturing cost of the movable electrode 4 for the circumferential edge. have.

Moreover, the holding | maintenance part 2e of the casing 2 holding the to-be-held part 4a of this circumferential edge movable electrode 4 is formed in four corners of the casing 2, as shown in FIG. . Thereby, it is possible to preferably use the corner portion of the casing 2 which is not likely to increase the appearance of the casing 2 and to become a dead space in the casing 2, thereby miniaturizing the multidirectional input device 1. It becomes possible to plan. In addition, since the common electrode 5 for peripheral edges which is connected to the movable electrode 4 for peripheral edges is formed in the holding surface 2f of this holding | maintenance part 2e, the common electrode 5 for peripheral edges is used as a peripheral edge. The space formed only in contact with the movable movable electrode 4 and the holding portion 2e can be formed integrally, and the size of the multidirectional input device 1 can be further reduced.

In addition, the multidirectional input device 1 of the first embodiment has a center movable electrode in contact with the center fixed contact 6 and the center common electrode 8 with respect to the pressing direction PD of the operation member 9. (7) is provided. Thereby, by pressing down the operating body 10 of the operation member 9, the center pressurizing portion 11d of the center pressurizing member 11 deforms while pressing the center movable electrode 7 and moves to the center. It is possible to detect the input operation in the pressing direction PD by the contact between the electrode 7 and the center fixed contact 6. At that time, the circumferential edge pressing member 12 disposed on the operation member 9 is limited by the upper surface 2j of the guide wall 2b in the direction toward the front of the pressing direction PD, but is centered. Since the insertion passage 11a of the pressing member 11 is inserted into the center hole 12b of the pressing member 12 for the circumferential edge, the pressure passing member 11a slides the center hole 12b in the pressing direction PD. It is possible to move forward (lower side of drawing). Thereby, even if the upper surface 2j of the guide wall 2b and the circumferential edge pressing member 12 contact, the operation member 9 becomes movable in the pushing direction. Therefore, not only the input operation to radial direction outer side but also the input operation to the pushing direction PD are possible.

In the input operation in the pressing direction PD, the center movable electrode 7 is formed in a dome shape, so that a reaction force can be generated in the direction opposite to the pressing direction PD, thereby preventing a wrong input. In addition, it is also possible to obtain a good click feeling when intentionally operated in the pressing direction PD.

And when the above-mentioned input operation to the circumferential direction and the reduction direction PD is complete | finished, in order to make it easier to perform an input operation next, to the initial position which the operation body 10 of the operation member 9 was arrange | positioned. Need to get back. At this time, since the multidirectional input device 1 has a return member 14 for generating a restoring force for restoring the operation member 9 to the initial position, the multidirectional input device 1 automatically inputs from the initial position when the input operation is performed. It becomes possible to perform an operation. Moreover, since this return member 14 is formed in the cover shape which seals the inside of the casing 2, it is possible to prevent the entry of malfunction factors, such as dust and moisture, into the casing 2.

Moreover, the fixed contact 3 for peripheral edges, the common electrode 5 for peripheral edges, and the center fixed which are arrange | positioned inside the casing 2 and which need to electrically connect with the outer member of the casing 2 are also required. Since both the contact 6 and the central common electrode 8 are formed by insert molding, the number of parts of the multidirectional input device 1 can be reduced, and the assembly process can be reduced. . In addition, since the tip portions 3b, 5b, 6b, and 8b of each of the lead terminals 3a, 5a, 6a, and 8a are formed to have different shapes, there are fewer cases of incorrect assembly at the time of assembly. It is possible to improve the yield of (1).

That is, the multidirectional input device 1 of the first embodiment makes it possible to obtain a comfortable operation feeling at the time of the input operation in the radially outward direction and the pressing direction PD, while reducing the cost, reliability and yield. Improvement is possible.

(2) 2nd Embodiment

In the multidirectional input device 1a of the second embodiment, as shown in FIG. 13, the guide wall 2b of the casing 2, the movable electrode 4 for the circumferential edge, the movable electrode 7 for the center, and the central use Each member disposed in the multidirectional input device 1a other than the common electrode 8 is the same as that used for the multidirectional input device 1 of the first embodiment. Here, the circumferential edge movable electrode 4 and the center movable electrode 7 used in the second embodiment communicate with each other through the supporting portion 4g and are integrally formed as shown in FIG. 13. As a result, in the second embodiment, the central common electrode 8 is not disposed and is excluded. Moreover, the slit 2k which passes the support part 4g which connects and supports the circumferential edge movable electrode 4 and the center movable electrode 7 is formed in a part of annular guide wall 2b.

Next, the operation of the multidirectional input device 1a of the second embodiment will be described.

The multidirectional input device 1a of the second embodiment, like the multidirectional input device 1 of the first embodiment, can perform input operations in the radially outward direction and the pressing direction PD. . However, since the circumferential edge movable electrode 4 and the center movable electrode 7 are integrally formed in the multidirectional input device 1a of the second embodiment, the circumferential edge movable electrode 4 and the center movable By conducting the center fixed contact 6 and the circumferential edge common electrode 5 via the electrode 7, it is possible to detect the contact between the center fixed contact 6 and the center movable electrode 7. As a result, it is not necessary to arrange the central common electrode 8, and it is possible to reduce the component scores from the components of the multidirectional input device 1 of the first embodiment, and thus the multidirectional input device 1a. Of the multidirectional input device 1a can be prevented. In addition, it is possible to reduce the cost of the multidirectional input device 1a.

(3) Third Embodiment

As shown in FIG. 14, since the multidirectional input device 1b of 3rd Embodiment gives input of two steps to the input operation to a circumferential direction, the multidirectional input device 1 of 1st Embodiment is as follows. The same member is provided and formed. That is, the multidirectional input device 1b of the third embodiment, as shown in FIG. 14, has the fixed contact 3 for the peripheral edge and the movable electrode 4 for the peripheral edge in the casing 2 similarly to the first embodiment. And at the center of each member used for input to the radially outer side such as the common electrode 5 for the peripheral edge, the center fixed contact 6 and the center movable electrode 7 and the center common electrode 8 and the like. Each member, the operation member 9, the cover body 13, the return member 14, and the restraint member 15, which are used for the input in the pressing direction of the substrate, are provided, and the two-stage input to the radially outer side is provided. In order to perform an operation, the 2nd peripheral edge movable electrode 16 and the 2nd peripheral edge common electrode 17 are provided in the vicinity of the fixed contact 3 for peripheral edges. Specifically, the movable electrode 16 for the second peripheral edge and the common electrode 17 for the second peripheral edge are formed as follows. In addition, the specific description is abbreviate | omitted that the same member as the multidirectional input device 1 of 1st Embodiment is used.

As shown in FIG. 15, the second peripheral edge common electrode 17 is integrally formed with the casing 2 by insert molding, and is exposed from the bottom face 2c outside the guide wall of the casing 2. The part to be insulated from the fixed contact 3 for each peripheral edge in 4 directions, and is formed in the substantially C shape which covers the fixed contact 3 for each peripheral edge. The common electrode 17 for the second circumferential edge is drawn out to the outside of the casing 2 in the same manner as the other contacts or electrodes 3, 5, 6, 8 which are insert-molded inside the casing 2. It has a terminal 17a, and the leading end portion 17b of the lead-out terminal is formed to have a special shape that can be distinguished from other lead-out terminals 3a, 5a, 6a, and 8a.

As shown in FIGS. 14-16, the 2nd circumferential edge movable electrode 16 is the curved part 16a on the elliptical dome which protrudes in the thickness direction of the circumferential edge movable electrode 4, and the circumference | surroundings of the curved part 16a. The fixed contact part 3 for a peripheral edge is provided with the base part 16b which contacts the common electrode 17 for 2nd peripheral edges formed in the edge, and is in an initial state (state which does not perform input operation to a radially outer side). And the fixed contact 3 for each peripheral edge in 4 directions while being insulated from the movable electrode 4 for the peripheral edge. Moreover, the pedestal part 16b of the 2nd circumferential edge movable electrode 16 is arrange | positioned so that it may contact with the 2nd circumferential edge common electrode 17. As shown in FIG.

Next, the operation of the multidirectional input device 1b of the third embodiment will be described.

The multidirectional input device 1b of the third embodiment enables two-stage input to the radially outer side in addition to the input performed by the multidirectional input device 1 of the first embodiment. For example, when the operating body 10 of the operating member 9 shown in FIG. 14 is slidably moved outside in any radial direction, the pressing member 12 for the peripheral edge presses the movable electrode 4 for the peripheral edge. To deform. Then, the 2nd circumference which contacts the movable electrode 16 for 2nd peripheral edges in contact with the one of the 2nd peripheral edge movable electrodes 16 arrange | positioned in 4 directions, The edge common electrode 17 and the circumferential edge common electrode 5 are conductive. As a result, the multidirectional input device 1b can appropriately detect an input operation to any outside in the radial direction. This is the input operation in the circumferential direction of the first step.

And in the state which the circumferential edge movable electrode 4 contacted with the 2nd circumferential edge movable electrode 16, the operation body 10 of the operation member 9 is further slid to the said arbitrary radial direction outer side. When it moves, the circumferential edge pressurizing member 12 pressurizes the circumferential edge movable electrode 4 and the 2nd circumferential edge movable electrode 16 which contacted the circumferential edge movable electrode 4 further. Then, the pressurized second peripheral edge movable electrode 16 is in contact with the peripheral edge fixed contact 3 disposed below. Thereby, since the circumferential edge common electrode 5 connected to the circumferential edge movable electrode 4 is conductive with the 2nd circumferential edge common electrode 17 and the circumferential edge fixed contact 3, a multi-directional input device It becomes possible to detect that (1b) was pressed further from the input operation to the circumferential direction of a 1st step, and was input operation to the radial direction outer side. This becomes an input operation to the radial direction outer side of a 2nd step. The input operation to the radially outer side in the second step is different from the input operation to the radially outer side in the first step, and provides a feeling of click by pressing the movable electrode for second circumferential edge 16 formed in a dome shape. Therefore, malfunction can be prevented with respect to the two-stage input to the radially outer side. Moreover, when performing the 2nd stage input operation to radial direction outer side, it is possible to operate with favorable and light feeling of clicking.

That is, the multidirectional input device 1b of the third embodiment has the effect of being able to input two stages in the pressing direction in the input operation to the radially outer side, thereby improving the convenience of the multidirectional input device 1b. Indicates.

(4) Fourth Embodiment

As shown in FIG. 17, the multidirectional input device 1c according to the fourth embodiment includes a fixed contact 3 for a peripheral edge, a movable electrode 4 for a peripheral edge, and a casing 2, as in the first embodiment. Reduction in the center of each member used for input in the circumferential direction, such as the circumferential edge common electrode 5, the center fixed contact 6, the center movable electrode 7, and the center common electrode 8, etc. Each part used for the input to a direction, the operation member 9, the cover body 13, the return member 14, and the restraining member 15 are provided. Here, the difference from the multidirectional input device 1 of the first embodiment is that the guide wall 2b of the casing 2 is formed to have a height such that it does not contact the pressing member 12 for the circumferential edge. At the same time, the central movable electrode 7 is formed with the recessed portion 7c at the portion in contact with the central pressurized portion 11d.

The multidirectional input device 1c of the fourth embodiment having the above-described guide wall 2b and the center movable electrode 7 is different from the multidirectional input device 1 of the first embodiment in the circumferential direction. In the input operation, the input operation can be performed by the longitudinal movement, not by the slide movement. Specifically, when the operation member 9 is longitudinally operated radially outward, the operation member 9 uses the contact point between the center pressurizing portion 11d and the recess 7c of the center movable electrode 7 as the rotation support point. In addition, since the lid 13 is freely restrained in the circumferential direction by sliding the circumferential edge of the pressing member 12 for the circumferential edge as in the first embodiment, the circumferential edge pressing member 12 is a movable electrode for the circumferential edge ( 4) It becomes possible to harden while pressing. Thereby, the multidirectional input device 1c of the fourth embodiment is not only an input operation in the circumferential direction by sliding movement of the operating body 10 such as the multidirectional input device 1 of the first embodiment but also a fourth The input operation to the radial direction outer side by the hardness of the operating body 10 like the multidirectional input device 1c of embodiment is attained.

(5) Fifth Embodiment

The multidirectional input device of the fifth embodiment is similar to the first embodiment in the casing 2 such as the fixed contact 3 for the peripheral edge and the movable electrode 4 for the peripheral edge and the common electrode 5 for the peripheral edge. Each member used for input in the pressing direction at the center of each member used for the input in the circumferential direction, the center fixed contact 6 and the center movable electrode 7 and the center common electrode 8, etc. Equipped. Here, the difference from the multidirectional input device 1 of the first embodiment is that the lid 113 as the lower member, the return member 114, and the restraining member 115 as the upper member are previously integrated to form one lid member. It is united.

The return member 114 is formed to have an outer shape of the same size as the outer shape of the restraining member 115, and positioning projections as positioning portions for fitting the positioning edges of the restraining member 115 to four corner portions. 114e is formed toward the upper surface, and the positioning projection 114f as the positioning portion to be fitted into the insertion passage hole 113b of the lid 113 toward the lower surface is formed. And in this embodiment, when the said positioning projection 114f attaches the unitized cover member to the casing 2, of the said circumferential edge movable electrode 4 accommodated in the said holding | maintenance part 2e, It acts to press the to-be-held part 4a to the holding surface 2f and the common electrode 5 for a peripheral edge (refer FIG. 20).

The lid 113 as the lower member is a plate-shaped member which is disposed on the lower surface side of the return member 114 and supports the return member 114, and has a size that is about the same as the outer circumference of the casing 2. It is formed in the shape of an external rectangle having a shape. Moreover, in the vicinity of the center of this lid | cover 113, the center hole 113a which fits the operation member 9 so that a slide operation is possible is formed, and the upper side of the outer edge part of the press member 12 for peripheral edges is formed. The cover body 113c arranged to cover at all times, and the flange part 113d which is arrange | positioned on the outer periphery of the said cover body 113c, and formed in substantially the same planar shape as the flange part 114d of the said return member 114, Equipped.

On the side of the flange portion 113d, a temporary fixing protrusion 113e constituting the temporary fixing locking means is formed to protrude outward from the flange portion 113d.

Further, the insertion through-holes 113b are drilled in the four corner portions of the lid 113 as the positioning portions corresponding to the positioning projections 114f formed at the four corner portions of the bottom face of the return member 114, respectively. Formed.

And the lid | cover body 113 is arrange | positioned on the upper side of the pressurizing member 12 for peripheral edges, when the unitary cover member is attached to the casing 2, and slides the operation member 9 to arbitrary radial directions. In this case, the slide movement is freely held while the pressing member 12 for the peripheral edge slides on the upper surface of the convex wall 2b and the lower portion of the central hole 113a of the lid 113.

The restraining member 115 as the upper member is a plate-shaped member made of a metal disposed on the upper surface side of the return member 114 and holding the outer peripheral portion of the return member 114, and is of the same degree as the outer circumference of the casing 2. It is formed in the shape of a rectangular shape having a size of.

The restraining member 115 has a central hole 115a for arranging the elastic diaphragm portion 114a at the center thereof, and has an upper plate portion 115b formed in the substantially same planar shape as the flange portion 114d of the return member 114. And a side plate portion 115c which is in continuous contact with the side edge of the upper plate portion 115b and extends below the upper plate portion 115b. The space portion surrounded by the upper plate portion 115a and the side plate portion 115c restricts the lateral positions of the return member 114 and the lid member 113, and includes a space portion for fitting and accommodating at least a portion of the upper side of the casing 2. do.

Moreover, the temporary fixing hole 115e which engages the temporary fixing protrusion 113e of the said lid member 113 formed as a temporary fixing locking means is formed in the width direction center part in each said side plate part 115c. .

The thickness direction dimension, that is, the height dimension of the return member 114 of the temporary fixing hole 115e is larger than the thickness direction dimension of the return member of the temporary fixing protrusion 113e.

Further, a mounting tongue 115f as a mounting means to the casing 2 is formed on the central virtual line of the temporary fixing hole 115e at the lower edge portion of the side plate portion 115c. To fix the united lid member to the casing 2 by caulking the distal end of the mounting tongue 115f at a predetermined dimensional position and fitting it to the mounting recess 2k of the casing 2. It is.

In addition, the four corner portions of the restraining member 115 are chamfered, and the end side portion thereof is a positioning portion (end position for positioning) 115g corresponding to the positioning projection 114e of the return member 114. Formed.

In the multidirectional input device 1d of the present embodiment, the lid member is unitized and assembled in the following order.

That is, the cover is inserted into the lid 113 arranged below and the restraining member 115 arranged above, and the lid is placed in the temporary fixing hole 115e formed in the restraining member 115. The temporary fixing protrusion 113e formed in the sieve 113 is engaged and temporarily fixed, and each member 114, 115, 116 is integrated, and it is set as the cover member unitized.

Subsequently, the lid member temporarily fixed and united is fitted to the casing 2 from above, presses the restraining member 115 to the casing 2 side, and compresses the mounting member 115f while compressing the return member 114. ) Is folded into a mounting recess 2k formed at the bottom of the casing 2, and the multidirectional input device 1d is assembled.

At this time, the mounting height of the lid member is regulated and adjusted by the length dimension of the mounting tongue 115f, and is mounted in a state in which the flange portion 114d of the return member 114 is compressed in the thickness direction, and then compressed. When the state is released, the return member 114 acts to bring the lid 113 close to the casing 2 side by the elastic restoring force within the range of the mounting height. At that time, the temporary fixing protrusion 113e is in the temporary fixing hole 115e in the compressed state of the return member 114 sandwiched between the restraining member 115 and the lid 113. In the temporary fixing hole 115e, as the lid 113 is pressed toward the casing 2 side by the elastic restoring force of the return member 114 after the compression is released. Will move downward.

Moreover, in this embodiment, by forming the mounting tongue 115f as a mounting means to the said casing 2 on the center virtual line of the said temporary fixing hole 115e, it is the elastic restoring force of the compressed return member. When the lid member is brought into close contact with the casing 2, compression of the return member and release of compression can be performed most efficiently.

As described above, in the multidirectional input device 1d according to the fifth embodiment, the temporary fixing projection protruding outwardly formed on the side of the flange portion of the return member fixing plate, and the casing mounting plate 16 By using the temporary fixing hole formed on the side wall of the side wall and engaging the temporary fixing projection, the temporary fixing locking means can be formed simply and inexpensively. Moreover, it can be temporarily fixed in the state which interposed the said return member by simple operation, and assembly can be performed easily.

That is, the multidirectional input device (1, 1a, 1b, 1c, 1d) of the above-described first to fifth embodiments makes it possible to reduce the deviation of the operating force in the radially outward direction. The operation feeling of 1, 1a, 1b, 1c, 1d) becomes favorable. In addition, since the reaction force adjusting portions 4c and 4d can be easily formed, or the guide wall 2b inside the casing 2 can be formed lower than before, the multidirectional input devices 1, 1a, 1b, The effect of compacting the shape of 1c, 1d) is shown. In addition, the manufacturing cost of the multidirectional input devices 1, 1a, 1b, 1c, 1d becomes low because the shapes of the movable electrodes 4 for peripheral edges and the pressing member 12 for peripheral edges are relatively simple. Has an effect. Then, by changing the shape of the guide wall 2b or the like, it is possible to enable two-stage input to the radially outer side, or to select the input operation by the slide movement and the hardness.

In addition, this invention is not limited to embodiment mentioned above, A various change is possible as needed.

By the multidirectional input device of the present invention, it becomes possible to reduce the deviation of the operation force in the radially outward direction in the circumferential direction of the movable electrode for the circumferential edge, thereby exhibiting the effect that the operation feeling of the multidirectional input device becomes good. In addition, since the reaction force adjusting portion is easily formed or the number of parts mounted on the multidirectional input device is reduced, the manufacturing cost of the multidirectional input device is reduced.

Claims (20)

A plurality of peripheral edge fixed contacts are disposed in a casing in an annular shape, and a peripheral edge movable electrode formed of an annular flat plate facing the peripheral edge fixed contacts arranged in an annular shape is located above the fixed edge fixed contact. An operation member having a circumferential edge pressing portion which is held in the casing through a predetermined gap between the circumferential edges and presses a portion of the circumferential direction of the movable electrode for circumferential edges from above to resist a reaction force and connects to the fixed contact for the circumferential edge. It arrange | positions in the said casing, The said circumferential edge pressurization part presses a part of the circumferential direction of the said circumferential edge movable electrode, and the said circumferential edge movable electrode and the said circumferential edge fixed contact are made to conduct input operation by the said pressurization. Multi-directional input cabinet detecting As, The circumferential edge movable electrode has a reaction force such that the reaction force generated near the holding portion of the circumferential edge movable electrode held in the casing is equal to the reaction force generated in a portion other than the vicinity of the held portion of the circumferential edge movable electrode. Has an adjustment section, And the reaction force adjusting unit is formed integrally with the movable electrode for the circumferential edge. The method of claim 1, And the reaction force adjusting portion is configured to form a width dimension in the radial direction near the held portion of the movable electrode for the circumferential edge smaller than a width dimension of a portion other than the portion held near the held portion. The method of claim 1, And the reaction force adjusting portion is formed to have a thickness near the holding portion of the movable electrode for the circumferential edge smaller than a thickness of a portion other than the holding portion vicinity. The method of claim 1, The said reaction force adjustment part is formed in concave shape or convex shape along the circumferential direction with respect to parts other than the said to-be-held part vicinity in the said movable electrode for peripheral edges. The method according to any one of claims 1 to 4, The circumferential edge movable electrode has a supported portion supported by the supporting portion of the casing, And the reaction force adjusting portion is formed integrally with the supported portion. The method of claim 1, The circumferential edge movable electrode is formed using a metal sheet material. The method of claim 1, The casing is formed in a box shape whose outer circumference is a polygonal shape, and the movable electrode for the circumferential edge has a predetermined gap from a position where the circumferential edge fixed contact is disposed inside the corner portion of the outer circumference. And a holding portion having a necessary height for holding the held portion for placement. The method of claim 1, A center fixed contact and a center having a predetermined gap in the inner peripheral side portions of the plurality of the circumferential edge fixed contacts and the circumferential edge movable electrodes arranged in the casing, the center being disposed facing the center fixed contact; And the said operation member which has a movable electrode and a center press part which presses the said center movable electrode on the upper side of the said center movable electrode. The method of claim 8, And the center movable electrode is integrally formed with the circumferential edge movable electrode through a supporting portion. The method of claim 8, And the center movable electrode is formed on a dome protruding in the axial direction of the center pressurizing portion. The method of claim 7, wherein And the holding portion has a common electrode at a portion always in contact with the held portion. The method according to any one of claims 1 to 8 or 11, The at least one of the fixed contact for the peripheral edge, the common electrode or the center movable electrode is insert molded into the casing. The method according to any one of claims 1 to 8 or 11, At least one of the circumferential edge fixed contact, the common electrode, or the center movable electrode has a lead terminal drawn out of the casing, and the lead terminal drawn out of the casing has a different shape according to the type of each member. A multidirectional input device, characterized in that formed. The method of claim 1, And a second circumferential edge movable electrode disposed between the circumferential edge movable electrode and the circumferential edge fixed contact and disposed while being insulated from the circumferential edge movable electrode and the circumferential edge fixed contact. Multidirectional input device. The method of claim 14, The second circumferential edge movable electrode is formed in a dome shape protruding in the axial direction of the circumferential edge movable electrode while covering the circumferential edge fixed contact. The method of claim 8, The operating member has a peripheral edge pressing member having the peripheral edge pressing portion, a central pressing member having the central pressing portion, and an operating body directly inputted from the operating main body. The center pressurizing member is inserted through the center hole formed near the center thereof, and is disposed. The center pressurizing member has a front in the pressing direction larger than an outer shape of the center hole of the pressing member for the circumferential edge, and the rear of the pressing direction. A multidirectional input device, wherein the external shape is formed in a shape different from a pressing direction equal to or smaller than the external shape of the center hole of the pressing member for peripheral edges. The method of claim 16, And a return member for generating a restoring force in a direction for restoring the operation member to an initial position of the operation member when the operation member presses the circumferential edge movable electrode or the center movable electrode. Input device. The method of claim 17, The return member is formed in a cover shape so as to cover the opening formed in the casing. The method of claim 16, The casing has a lid which restrains the sliding movement amount in the radially outer side of the pressing member for the circumferential edge, and a guide wall for slidingly supporting the pressing portion for the circumferential edge from an opposite direction of the lid, The edge pressing member is formed so as to press the movable electrode for the circumferential edge while sliding the portion where the center pressing portion and the center movable electrode are in contact with each other. The method of claim 16, The casing has a lid which restrains the sliding movement amount in the radially outward direction of the circumferential edge pressing member, and the circumferential edge pressing member makes the contact point between the center pressing portion and the center movable electrode a rotational support point. And pressurize the movable electrode for the circumferential edge of the multidirectional input device.

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