KR100413264B1 - Input device - Google Patents

Abstract

An object of the present invention is to provide a compact, good assembly and low cost.

To this end, the input device of the present invention is to position the rotation axis (G2) of the operation member (12, 80) in front of the rotation axis (G1) of the rotating body (10, 54), to the connecting member (15, 40) By connecting the operating members 12 and 80 and the rotating bodies 10 and 54, the rotary electric parts R1 were operated through the connecting members 15 and 40 by the rotation operation of the operating members 12 and 80. .

Description

Input device {INPUT DEVICE}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an input device which is suitably used for an operation unit for operating various electric devices such as a radio, a CD recorder, a car navigation system, and can transmit various input signals.

A conventional input device is disclosed in Japanese Patent Laid-Open No. 10-312728, and as shown in Figs. 19 and 20, which are main cross-sectional views, the bottom wall 101 of the U-shaped box body 100 made of a molded article made of synthetic resin is formed on three bottoms. First, second, and third push switches S4, S5, and S6 are installed in parallel with each other, and at one side wall 102, a rotary electric component such as an encoder having a rotating body 110. (R2) is installed.

The drive body 120 formed of a molded product made of synthetic resin has a box shape, and has a plurality of protrusions 122 on the bottom wall 121 thereof. The drive body 120 has a pair of protrusions on the opposing side wall 124. The projection 123 is inserted into the pair of elongated grooves 105 provided with the side wall 124 of the box body 100 opposite to the box body 100, thereby being provided to the box body 100 to have a hardness. The operation and the seesaw operation are possible, and when the driving body 120 is provided, each of the plurality of protrusions 122 is connected to the first, second, and third push switches S4, S5, and S6. It is in an opposing state.

In addition, the spring plate 130 made of a metal plate is installed on the bottom wall 121 of the drive body 120 to always elastically press the drive body 120 upwards.

The cylindrical operation member 140 penetrates in the direction of the rotation axis G4 at the center portion, and is provided with a conical through hole 141 that gradually increases from the center portion toward the outside, and the operation member 140 has a through hole ( The non-circular shaft portion 150 inserted in 141 is provided in the box body 100 so as to enable rotation operation, hardness operation and seesaw operation.

In addition, the shaft portion 150 has a non-circular portion 151 provided at one end thereof is engaged with the insertion hole 111 of the rotating body 110, and the other end thereof is inserted into the insertion hole 104 of the side wall 103 to rotate the rotating body. It is hypothesized long between 110 and side wall 103. As a result, the rotation axis G4 of the operation member 140 and the rotation axis of the rotation body 110 are in a state of coincidence.

Next, the operation of the conventional input device will be described. First, when the operation member 140 is rotated, the shaft part 150 rotates according to the rotation.

In this case, the rotating body 110 rotates via the shaft part 150, and as a result, the contact etc. are switched and the rotating electrical component R2 is operated.

Next, when the central portion of the operating member 140 is pressed in a direction perpendicular to the rotation axis G4, that is, in the direction of the arrow Y1 in FIG. 19, the operating member 140 protrudes in a direction opposite to each other. 123 is guided by a pair of elongate grooves 105 formed on the side wall (not shown) of the longitudinal direction of the box body 100 to linearly move downward along this drive body 120. As a result, the first push switch S4 is operated by the protrusion 122 to switch the contact point.

When the pressurization of the operating member 140 in the direction of the arrow Y1 is released, the driving member 120 and the operating member 140 are pushed back to their original state before pressurization by the spring plate 130 and at the same time, the protrusions ( The operation of the first push switch S4 by 122 is also released.

In addition, when the operation member 140 moves in the direction of the arrow Y1, the shaft portion 150 is pressurized at the center portion, and the shaft portion 150 is supported by the hardness of the non-circular portion 151 engaged with the rotating body 110 as a supporting point. And the other end moves in the insertion hole 104 of the side wall 103.

At this time, the non-circular portion 151 rotates in the insertion hole 111 of the rotating body 110.

Next, when the end of the operation member 140 is pressed in the seesaw operation, that is, the direction perpendicular to the rotation axis G4, that is, the direction of the arrow Y2 or the arrow Y3 of FIG. 19, the operation member 140 The longitudinal movement is performed along the drive body 120 with the central portion of the operation member 140 as a support point. As a result, the second push switch S5 or the third push switch S6 is operated by the protrusion 122. The contact is switched.

When the pressing of the operating member 140 in the direction of the arrow Y2 or the direction of the arrow Y3 is released, the spring 120 130 causes the driving body 120 and the operating member 140 to be in their original states before pressing. At the same time, the operation of the second push switch S5 or the third push switch S6 by the protrusion 122 is also released.

When the second and third push switches S5 and S6 are operated, the shaft portion 150 is not pressed by the operation member 140 by the conical through hole 141 provided in the operation member 140. It is.

In this way, by rotating the operation member 140, the rotary electric component R2 is operated, and the operation member 140 is moved up and down with respect to the rotation axis G4, so that the first, second, and third The push switches S4, S5 and S6 are operated.

In the conventional input device, since the rotational axis G4 of the operation member 140 and the rotational axis of the rotational body 110 coincide with each other and are at the same height from the bottom wall 101 of the box body 100, the rotational electrical component ( There is a problem in that it becomes necessary to raise the installation position of R2) to the position of the rotation axis G4 of the operation member 140, which becomes large.

Moreover, since the shaft part 150 is a structure which penetrates the through-hole 141 of the operation member 140, and hangs both ends to the rotating body 110 and the side wall 103, respectively, its assembly property is bad, Not only is it expensive, but there is a problem that the space in the transverse direction is increased.

In addition, in the conventional input device, when the operation member 140 is pressed in the direction of the arrow Y1 to operate the push switch S4, the driving body 120 is guided by the long groove 105 to move up and down. . However, there is a problem that rattling occurs because a gap exists between the side wall 124 of the driving body 120 and the side wall 100a of the box body 100.

In particular, when the operation member 140 is rotated, there is a problem that the drive body 120 is difficult to operate because the drive body 120 rotates after moving by the amount of rattling. In the state where the projection 123 is located halfway in the elongated groove 105, the driving body 120 is hardly guided, and since the position changes easily in any direction during operation, the behavior becomes unstable and difficult to operate. There was a problem.

In addition, this problem is solved by making the gap between the sidewall 124 and the sidewall 100a very small or increasing the spring load of the spring plate 130. However, when the operation member 140 is pressed and the line connecting the protrusions 123 to the driving body 120 is weighted in the direction inclined in the vertical direction, the side wall 124 and the side wall 100a or the spring plate There is a problem that a jam occurs between the 130 and does not press or return smoothly, and at the same time there was a problem that the push switch is inadvertently pressed to cause an incorrect operation.

This invention is made | formed in view of such a problem, and a 1st objective is to provide the input device which is compact, good assembly, and low cost. Moreover, a 2nd object is to provide the input device which has a favorable feeling of operation, and is low in fear of wrong operation.

1 is a plan view of an input device according to a first embodiment of the present invention;

2 is a cross-sectional view taken along line 2-2 of FIG. 1;

FIG. 3 relates to the input device of FIG. 1, which is a plan view in which a part of the arrangement of the push switches is notched;

4 is an exploded perspective view of the input device of FIG. 1, FIG.

5 is an explanatory diagram showing an operation of the input apparatus of FIG. 1;

6 is a plan view of an input device according to a second embodiment of the present invention;

7 is a cross-sectional view taken along the line A-A of FIG. 6;

8 is a cross-sectional view taken along line B-B of FIG. 6;

9 is a plan view in which part of the notch showing the arrangement of the push switches in the input device of FIG. 6 is notched;

10 is a plan view for showing the internal structure of the operation member in the input device of FIG.

11 is a right side view of the operation member in the input device of FIG. 6;

12 is a plan view of a drive body in the input device of FIG. 6;

13 is a plan view of the box body in the input device of FIG. 6;

14 is a cross-sectional view taken along the line C-C in FIG. 13;

15 is an explanatory diagram showing an operation in the input device of FIG. 6;

16 is an explanatory diagram showing the operation of the input apparatus of FIG. 6;

17 is an explanatory diagram showing an operation of the input apparatus of FIG. 6;

18 is an explanatory diagram showing an operation of the input apparatus of FIG. 6;

19 is a sectional view of main parts of a conventional input device;

20 is an exploded perspective view of a conventional input device.

※ Explanation of symbols for main parts of drawing

1: printed board 2: case

3: push button 4: box body

4a: side wall 4b: first storage part

4c: 2nd accommodating part 4d: insertion part

4e: recess 4f: support

4g: notch 5: spring member

6: mounting plate 7: fixed contact

8: insulated gas 9: movable contact

10: rotating body 10a: recess

11 driver 11a arc portion

11b: convex portion 11c: convex portion

11d: protrusion 12: operating member

13 holding part 13a: tube part

13b: hole 14: delivery unit

14a: recess 14b: hole

15: connecting member 15a: shaft portion

15b: engagement portion G1, G2: rotation axis

R1: Rotating electrical part S1: First push switch

S2: second push switch S3: third push switch

A1: side front side A2: side rear side

20: driving body 21: semi-circular arc

22: protrusion 23: first shaft portion

24: 2nd shaft part 25: 1st protrusion

As a first solution for solving the above problems, there is provided a rotating electrical component having a rotating body, an operating member for operating the rotating electrical component, and a connecting member for transmitting the rotating operation of the operating member to the rotating body. And the operation member is provided so as to perform a rotation operation from the side front side in the direction perpendicular to the rotation axis thereof, and the operation member is positioned so that the rotation axis of the operation member is located ahead of the rotation axis of the rotation body. And connecting the operating member and the rotating body with the connecting member so as to manipulate the rotating electrical component via the connecting member by a rotation operation of the operating member.

In addition, as a second solution means, one end side of the connection member is engaged with one end side of the operation member, and the other end side of the connection member is engaged with the rotating body so that the connection member is connected to the rotor and the rotor. It was set as the structure arrange | positioned in inclined state between the rotation axis of an operation member.

Further, as a third solution means, a first push switch is provided at a position facing the rear side of the side of the operating member, and the first push switch is pressed by a pressing operation of the operating member in a direction perpendicular to a rotation axis of the operating member. It was set as the structure which operated a push switch.

In addition, as a fourth solution, a drive body for rotatably supporting the operation member is provided, and the first push switch is operated through the drive body by the pressing operation of the operation member.

Moreover, as a 5th solution means, it was set as the structure which had the box body which installs the said drive body, the said drive body snapped to the said box body, and the said drive body was provided in the said box body.

Further, as a sixth solution, the drive body has a semi-circular arc-shaped portion and a protrusion located at the center of the semi-circular arc-shaped portion, and the protrusion is fitted into a hole provided on the other end side of the operating member. While supporting the operation member rotatably, the side rear side of the operation member was covered with the semi-circular arc portion, and the first push switch was operated by the semi-circular arc portion.

In addition, as a seventh solution, when the second and third push switches are provided on both sides of the first push switch, and the pressure is applied to both end portions of the front side of the side of the operation member, the operation member becomes hard. It operated so that the said 2nd, 3rd push switch could be operated via the said drive body, respectively.

As an eighth solution, a non-circular engaging portion having an outer surface with an arc shape is provided at both ends of the connecting member, and the engaging portion is a non-circular shape provided on the rotating body and the operation member. It was configured such that the rotational operation of the operation member is transmitted to the rotating body by engaging with the concave portion of the.

As a ninth solution, the concave portion of the rotating body and / or the operation member is provided with a flat surface extending in the rotational axis direction, and the engaging portion is slidable in the rotational axis direction. It was made.

In addition, as a tenth means for solving the above problems, the input device of the present invention is connected to a rotary electrical component by a connecting member, the operation member for operating the rotary electrical component via the connecting member by a rotation operation, and A drive body for rotatably holding the operation member, a box body for holding the drive body, and at least first, second, and third push switches disposed below the drive body; With the center of gravity in the direction of the rotational axis of the operating member as the center of hardness, both ends can be seesawed in a direction orthogonal to the direction of the rotational axis, and the longitudinal motion is performed using the position perpendicular to the center of the direction of the rotational axis as a support point. The first and second push switches are operated by the seesaw operation of the driving body, respectively, and are held by the box body as much as possible. It characterized in that the third push-switch operated by the inclining operation.

In addition, as an eleventh solution, the first and second push switches in the input device of the present invention are arranged in parallel with the rotation axis direction of the operation member, and the third push switch is the first and second push. The rotary shaft is inserted in the middle of the switch, characterized in that disposed on the opposite side to the hardness point of the drive body.

As a twelfth solution, the drive member of the input device of the present invention includes a first shaft portion and a second shaft portion sandwiching the rotational axis, the first shaft portion being a support point for the longitudinal motion, and the first shaft portion being the box body. The second shaft portion is movable up and down in a guide groove formed in the box body, and the seesaw operation of the drive body is supported by the support point. And at the same time, the longitudinal movement of the drive body is characterized in that the second shaft portion is moved by moving the guide groove with the first shaft portion as a support point.

As a thirteenth solution, a torsion coil spring for contacting the drive member in the input device of the present invention and adding the drive member is disposed, and the torsion coil spring drives the drive during the seesaw operation and hardness operation. The sieve is returned to the state before operation.

As a fourteenth solution, the torsion coil spring in the input device of the present invention is held by a protrusion provided in the box body.

Further, as a fifteenth solution, the torsion coil spring in the input device of the present invention is arranged on the side opposite to the hardness point of the drive body while sandwiching the rotational axis, and the winding portion of the torsion coil spring is the projection. The projection is characterized in that located in the center portion of the rotation axis direction of the operation member.

Further, as a sixteenth solution means, the torsion coil spring in the input device of the present invention has a pair of arm portions which sandwich the winding portion and extend in opposite directions to each other and in the rotation axis direction, and the arm portion is free. It is characterized in that the end side is made to be able to stop by the locking part provided in the said box body.

1 is a plan view of an input device of the present invention, FIG. 2 is a cross-sectional view taken along line 2-2 of FIG. 1, and FIG. Fig. 4 is an exploded perspective view of the input device of the present invention, and Fig. 5 is an explanatory view showing the operation of the input device of the present invention.

Next, the structure of the input device according to the present invention will be described with reference to Figs. 1 to 5, wherein the flat printed circuit board 1 has the first push switch S1 as the center, and the second and second sides are provided on both sides thereof. Three push switches S2 and S3 are provided in parallel with each other in a straight line.

The first, second, and third push switches S1, S2, and S3 are provided with a movable contact (not shown) in the case 2 and a push switch 3 for operating the movable contact. Is attached to the case 2, and is in the state located on the upper surface.

The box-shaped box body 4 made of a molded article made of synthetic resin and having an open front and a rear part is surrounded by a first accommodating portion 4b and a first accommodating column 4b surrounded by sidewalls 4a arranged on all sides. Insertion part 4d which consists of the 2nd accommodating part 4c provided adjacently, the notch provided in the side wall 4a located between 1st and 2nd accommodating part 4b, 4c, and this insertion part 4d. Concave portions 4e provided opposite to the central portions of the two side walls 4a perpendicular to the side walls 4a provided with the recesses, and circular arcs provided on the two side walls 4a in a state located behind the concave portions 4e. It has a pair of support part 4f which has a shape surface, and a pair of notch part 4g provided in the rear part of a pair of side wall 4a which opposes in the longitudinal direction of the 1st accommodating part 4b.

The box body 4 is a means suitable for the printed circuit board 1 with the first, second and third push switches S1, S2, and S3 positioned on the rear side of the first housing 4b. It is installed by.

Two strip-shaped spring members 5 made of a spring-like metal plate or the like are positioned at the rear side of the first housing portion 4b of the box 4, and both ends thereof are notched to the notch portion 4g. At the same time, the center part is mounted on the upper surface of the supporting part 4f and provided in the box body 4.

And these two spring members 5 are arrange | positioned in the 1st accommodating part 4b in the bow state centering on the support part 4f.

In addition, this spring member 5 may use a linear spring.

The rotary electrical component R1 made of an encoder or the like is supported by the mounting plate 6 and is rotatably held on the insulated gas 8 provided with the fixed contact point 7 and the insulated gas 8. It is comprised by the rotating body 10 which has the non-circular recessed part 10a which consists of a hexagonal hole etc. provided in the center part while providing the movable contact 9 in the circumferential surface.

The rotary electric component R1 is accommodated in the second housing portion 4c of the box body 4 and is installed in the box body 4, and at the same time, the fixed contact of the rotary electric component R1 ( 7) is soldered to the printed board 1 and connected to a wiring pattern (not shown).

Moreover, when the rotary electric component R1 is provided in the box 4, the recessed part 10a of the rotating body 10 will become the position which opposes the insertion part 4d, and the rotating body 10 Rotates about the rotation axis G1 as an axis, and the movable contact 9 comes out of contact with the fixed contact 7 by this rotation to generate a pulse.

Moreover, the inner surface of the non-circular recess 10a of the rotating body 10 is comprised by the flat surface extended along the rotation axis G1 direction.

The drive body 11 made of a molded product made of synthetic resin has a semicircular arc portion 11a having a cylindrical shape approximately half and a pair of convex portions 11b provided to face the outer periphery of the semicircular arc portion 11a. And a spherical convex portion 11c provided at the center of the lower surface (rear side) of the arc shape portion 11a, and a circumference which is located at the center portion of the arc shape portion 11a and whose one end is connected to the arc shape portion 11a. It has the protrusion 11d of shape.

The drive body 11 is positioned on the first housing portion 4b of the box body 4 and snaps the convex portion 11b to the recessed portion 4e of the box body 4 so as to snap the box body ( It is installed in 4).

And when this drive body 11 is installed in the box body 4, the convex part covers the upper part of the 1st, 2nd, 3rd push switches S1, S2, S3 with the arc-shaped part 11a. 11c is positioned above the first push switch S1, and the lower surface of the arc-shaped portion 11a is in elastic contact with the spring member 5, and the driving body 11 is made of a shanghai copper, Hardness operation | movement which made the convex part 11c the support point is attained.

The operation member 12 made of a molded product of synthetic resin is composed of two parts, a holding part 13 which is rotatably held, and a transmission part 14 which transmits the rotational motion to the rotary electric component R1.

This holding | maintenance part 13 has a cylindrical shape, and has the small diameter cylinder part 13a provided in the outer peripheral part of one end, and the hole 13b provided in the center part with the other end side open, and a transmission part 14 has a non-circular (hexagonal) recessed part 14a provided in the center part in the state which opened one end side, and the hole 14b provided in the center part in the state which opened the other end part.

The holding portion 13 and the transmission portion 14 press-in the tubular portion 13a of the holding portion 13 to the hole 14b of the transmission portion 14, or the like, so that both are integrated to form a drum shape. The operation member 12 which comprised this is comprised.

In this embodiment, the operation member 12 is formed by combining two parts, but may be formed by one part.

The operation member 12 is installed by fitting the protrusion 11d of the drive body 11 to the hole 13b of the holding part 13, and the operation member 12 is rotated about the axis of rotation G2. Is rotatably supported by the protrusion 11d so that the side front side A1 of the operation member 12 is exposed from the box body 4, and at the same time, the side rear side A2 of the operation member 12 is formed in an arc shape. It is in the state covered with 11a.

And this operation member 12 can be rotated from the side front side A1 of the orthogonal direction with respect to the rotation axis G2, and when the rotation operation is performed, it will be centered on the projection part 11d with the rotation axis G2 as the axis. As shown in FIG. 2, when the central portion of the side front side A1 of the operation member 12 is pressed in the direction of the arrow Y1, the operation member 12 is driven against the spring member 5. The first push switch S1 is operated by linearly moving along the sieve 11 toward the side rear side A2.

As shown in FIG. 2, when both ends of the side front side A1 of the operation member 12 are pressed in the direction of the arrow Y2 or the arrow Y3, the operation member 12 is a spring member 5. ), The second push switch S2 or the third push switch S3 is operated by longitudinally operating the convex portion 11b along the driving body 11 as a support point.

When the operation member 12 is installed in the drive body 11, as shown in Fig. 2, the rotation axis G2 of the operation member 12 becomes stepped with the rotation axis G1 of the rotation body 10. At the same time, the rotation axis G2 of the operation member 12 is located on the side front side A1 than the rotation axis G1 of the rotation body 10.

As a result, the rotation axis G1 of the rotating body 10 is close to the side rear side A2, that is, the printed board 1 side, whereby the rotary electric component R1 can be miniaturized in the height direction. will be.

Moreover, the inner surface of the non-circular recessed part 14a of the transmission part 14 is comprised by the flat surface extended along the rotation axis G2 direction.

The connecting member 15 made of a metal material or the like is provided at both ends of the shaft portion 15a and the shaft portion 15a, and the outer surface in the forming direction of the shaft portion 15a forms an arc shape, and a cross section perpendicular to this has a hexagonal cross section. It has a non-circular engagement part 15b, and this connection member 15 has one engagement part 15b recessed in the rotating body 10, with the shaft part 15a inserted in the insertion part 4d. While engaging the part 10a, the other engaging part 15b is engaged with the recessed part 14a of the operation member 12. As shown in FIG.

As a result, the connecting member 15 is arranged in an inclined state between the rotational axes G1 and G2.

Next, the operation of the input device having the above configuration will be described. First, in the state shown in FIG. 2, when the operation member 12 is rotated from the side front side A1 in the right angle direction with respect to the rotation axis G2. , The operation member 12 rotates around the protrusion 11d.

Then, the connecting member 15 is rotated via the engaging portion 15b by the non-circular recess 14a of the operating member 12, and the rotation of the connecting member 15 is the non-circular recess. It is transmitted to the rotating body 10 via 10a, and as a result, the rotating body 100 rotates to generate a pulse signal, and the rotating electrical component R1 is operated.

Next, as shown in FIG. 2, the center part of the operation member 12 is pressurized by the perpendicular | vertical direction with respect to the rotation axis G2, ie, the center part of the side front side A1 of the operation member 12 in the direction of an arrow Y1. In the pressing operation, the operation member 12 moves linearly along the driving body 11 to the rear side A2 along the driving member 11 by the convex portion 11c of the arc-shaped portion 11a. The first push switch S1 is operated.

After the operation, when the pressing operation of the operation member 12 is released, the driving member 11 and the operation member 12 are pushed back to their original state by the spring member 5 and at the same time, the first push switch S1. ) Operation is released.

Moreover, in the shanghai-dong of this operation member 12, the connection member 15 changes the inclination angle by making the engagement part 15b of the rotating body 10 side into a support point, but the engagement part 15b is this time. Slides along the flat surface of the recess 10a or / and the recess 14a in the direction of the rotation axis G1, and / or in the direction of the rotation axis G2.

In addition, as shown in FIG. 2, the end side of the operation member 12 is pressurized in the direction orthogonal to the rotation axis G2, ie, the end side of the side front part A1 of the operation member 12 is arrow Y2. In the direction of pressurization, as shown in FIG. 5, the operation member 12 resists the spring member 5 and is longitudinally moved along the drive body 11 with the convex portion 11b as a supporting point. The second push switch S2 is operated by the arc-shaped portion 11a.

After the operation, when the pressing operation of the operation member 12 is released, the driving member 11 and the operation member 12 are pushed back to their original state by the spring member 5 and at the same time, the second push switch S2. ) Operation is released.

Moreover, in the shanghai-dong of this operation member 12, the connection member 15 changes the inclination angle by making the engagement part 15b of the rotating body 10 side into a support point, but the engagement part 15b is this time. Is slid along the flat surface of the recess 10a or / and the recess 14a in the direction of the rotation axis G1, or in the direction of the rotation axis G2.

As shown in Fig. 2, the end side of the operation member 12 is pressurized in the direction perpendicular to the rotation axis G2, that is, the end side of the side front portion A1 of the operation member 12 is arrowed (Y3). When the pressure operation is carried out in the direction of), the operation member 12 resists the spring member 5 and is longitudinally moved along the driving body 11 with the convex portion 11b as a supporting point by the same operation principle as the above. The third push switch S3 is operated by the arc-shaped portion 11a.

After the operation, when the pressing operation of the operating member 12 is released, the driving member 11 and the operating member 12 are pushed back to their original state by the spring member 5 and at the same time, the third push switch S3. Operation is released.

Moreover, in the shanghai-dong of this operation member 12, the connection member 15 changes the inclination angle by making the engagement part 15b of the rotating body 10 side into a support point, but the engagement 15b is this time. It slides along the flat surface of the recessed part 10a and / or the recessed part 14a to the direction of rotation axis G1, and / or to the direction of rotation axis G2.

In this manner, the operation of the input device of the present invention is performed.

The rotating electrical component R1 in the above embodiment may be an electrical component such as a rotating variable resistor, and the recesses 10a and 14a are provided in the rotating body 10 and the operation member 12. Although it demonstrated, the protrusion which has a non-circular engagement part is provided in the rotating body 10 and / or the operation member 12, and it is made to engage with the non-circular recessed part provided in the connection member 15. You may also do it.

The first, second, and third push switches S1, S2, and S3 have been described as being installed on the printed board 1, but they are installed on the bottom wall installed on the box body 4, and so on. Of course it can be applied.

Next, an input device of a second embodiment of the present invention will be described in detail with reference to the drawings. FIG. 6 is a plan view of the input device according to the second embodiment of the present invention, FIG. 7 is a sectional view taken along the line AA of FIG. 1, FIG. 8 is a sectional view taken along the line BB of FIG. 6, and FIG. It is the top view which notched part which shows an arrangement. 10 is a plan view for showing the internal structure of the operation member, FIG. 11 is a right side view of the operation member, FIG. 12 is a plan view of the driving body, FIG. 13 is a plan view of the box body, and FIG. 14 is of FIG. It is sectional drawing in CC line. 15 to 18 are explanatory views showing the operation of the input device of the present invention.

The input device of the second embodiment includes an operating member 80 connected to the rotary electrical component R1 by a connecting member 40, a drive body 20 for rotatably holding the operating member 80, and It has a box body 30 which accommodates a drive body, a pair of 2nd and 3rd push switches S2 and S3 and the 1st push switch S1 arrange | positioned under the drive body 20, and drive The sieve 20 can be operated in a seesaw operation in a direction orthogonal to the up and down direction based on its rotation axis G2 direction, and supports one end in a direction perpendicular to the up and down direction based on the longitudinal center line G3 direction of the seesaw. This makes it possible to operate the hardness. In addition, the connection member 40 is transmitted by rotating the operation member 80 so that the rotary electric component R1 rotates.

The operation member 80 is formed of a molded article made of synthetic resin, has a substantially cylindrical shape as shown in FIGS. 7, 10, and 11, and a plurality of irregularities 83 are formed on the surface thereof. And this operation member 80 is a cylindrical cylindrical part 81 which has a bottom formed in the other end direction from the center part of the side of the one end side, and has a circular hole part 81a of a cross section, and especially as shown in FIG. It has the non-circular (hexagonal) recessed part 82 formed in the center part of the side wall of the other end.

The drive body 20 is formed of a molded product made of synthetic resin, and has a semicircular arc-shaped portion 21 having a shape in which the cylinder is roughly half in the longitudinal direction as shown in FIGS. 7, 8, 12, and 15, and the semicircular arc shape. It is mainly located in the center part of the upper part 21, and has mainly the columnar protrusion part 22 connected to the edge part of this semi-circular arc shape 21. As shown in FIG. In addition, at one end side of the position orthogonal to the rotation axis G2 and at the other end side, the cylindrical first and second shaft portions 23 and 24 face each other at the center of the longitudinal side of the semi-circular arc-shaped portion 21. Protruding toward In addition, a pair of first and second protrusions 25 and 26 protrude from the outer periphery of the semicircular arc-shaped portion 21, and the other end between the first and second protrusions 25 and 26. The third protrusion 27 protrudes downward from the side.

And the hole part 81a of the operation member 80 is inserted in the protrusion part 22 of this drive body 20, and the operation member 80 is accommodated in the semi-circular arc-shaped part 21 of the drive body 20, and in this state It is possible to rotate.

The box body 30 is formed of a molded product made of synthetic resin, and has a substantially rectangular box shape as shown in FIGS. 7, 8, 13, and 14, and penetrates in the height direction inside the side wall portion surrounded by four sides. An approximately rectangular second accommodating portion 32 which is smaller than the first accommodating portion 31 and the first accommodating portion 31 and penetrates in the height direction and is provided adjacent to the first accommodating portion 31. Has And as shown in FIG. 14, the engaging part 33 which consists of a circular hole of diameter slightly larger than the said 1st shaft part 23 is formed in one side wall part which forms the 1st accommodating part 31, In the other side wall part in the position which opposes this engaging part 33, the guide hole 34 slightly longer than the engaging part 33 is formed. In addition, the engaging part 33 and the guide hole 34 may be comprised by the recessed part which does not penetrate a side wall part, and the engaging part 33 may not be circular. In addition, a circumferential protrusion 36 protruding inward is formed below the side wall portion where the guide hole 34 is formed. In addition, an insertion portion 35 made of a notch is formed in the side wall portion positioned between the first and second accommodating portions 31 and 32, and a part of the lower portion (lower right in FIG. 8) of the angular portion of the side wall portion is formed. It is notched and the 2nd stop part 38 is formed. On the other hand, a part shown in FIG. 8 is notched and the 1st locking part 37 is formed in the lower part of the angular part of the side wall part which opposes the side wall part in which the insertion part 35 etc. are formed.

The torsion coil spring 60 is formed by winding an elongated metal wire. The torsion coil spring 60 is wound around the winding portion 61, the first arm portion 62 extending from the winding portion 61, and the first arm portion 62. It has a second arm portion 63 extending in the opposite direction.

The bitrim coil spring 60 inserts the winding portion 61 into the protrusion 36 of the box body 30 and simultaneously frees the free ends of the first and second arm portions 62 and 63. It is provided in the box body 30 in the state which stopped at the 2nd stop part 37 and 38, and is located in the 1st accommodating part 31. As shown in FIG.

And the drive body 20 provided with the operation member 80 is accommodated in the 1st accommodating part 31 of the box body 30 which consists of such a structure. That is, the drive body 20 is positioned above the first housing part 31 and pushed downward so that the first and second shaft parts 23 and 24 exceed the tapered surface provided at the edge of the box body 30. And snap-fit to the engaging portion 33 and the guide hole 34, the drive body 20 is installed. In addition, the torsion coil spring 60 is assembled below the box body 30 with the first and second arm portions 62 and 63 bent slightly, so that the drive body 20 is connected to the box body 30. When installed, as shown in FIG. 8, the 1st, 2nd arm part 62, 63 of the torsion coil spring 60 protrudes from the both ends of the longitudinal direction of the drive body 20, and formed the 1st, 2nd It is in contact with the lower ends of the extension protrusions 28 and 29. At this time, the 1st and 2nd arm parts 62 and 63 have some clearance gap between the 1st stop part 37 or the 2nd stop part 38, and, therefore, the 2nd shaft part 24 Is elastically pressurized to the upper end of the guide groove 34 by the torsion coil spring 60 and at the same time the winding portion 61 of the torsion coil spring 60 is located below the second shaft portion 24.

The printed circuit board 70 is made of a rigid insulated substrate, and second and third push switches S2 and S3 are provided at both ends thereof, and the second and third push switches S2 and S3 are provided. In the middle portion, the first push switch (2) is fitted at a position opposite to the first shaft portion 23, which is the hardness point of the driving body 20, with the rotation axis G2 interposed therebetween, that is, the second shaft portion 24 side in FIG. S1) is installed.

The second push switch S2 has a first fixed contact 71a formed of a wiring pattern, a second fixed contact 72a formed to be spaced apart from the surroundings, and a metal placed on an upper portion of the second fixed contact 72a. The dome-shaped movable contact 73a is formed, and the 1st and 2nd fixed contact 71a is formed by screen printing. Similarly, the third push switch S3 is also composed of the first fixed contact 71b, the second fixed contact 72b, and the dome-shaped movable contact 73b, and the first push switch S1 is also fixed first. The contact 71c, the 2nd fixed contact 72c, and the dome-shaped movable contact 73c are comprised. The movable contacts 73a to 73c of each push switch are covered by a holding sheet (not shown) provided with an adhesive layer and fixed to the printed circuit board 70 in a reversible manner. Although not shown, the printed circuit board 70 is provided with a wiring pattern and the like.

The bottom surface of the box body 30, in which the driving body 20, the operation member 80, the connection member 40, and the like are assembled is mounted on the printed board 70. That is, installation is performed by inserting the boss 30a formed at the bottom edge of the box body 30 into an insertion hole (not shown) formed in the printed circuit board 70.

When the box body 30 is installed in this way, the first protrusion 25 of the driving body 20 is positioned to face the second push switch S1, and the second protrusion 26 is positioned on the third push switch ( Opposite S3), the third projection 27 is positioned to face the first push switch (S1).

The operation member 80 can be rotated about the rotation axis G2 as a central axis. When the operation member 80 is rotated, the operation member 80 rotates around the protrusion 22 of the driving body 20. In addition, when the central portion of the side surface of the operation member 80 is pressed in the direction of the arrow Y1 (see FIG. 15), the operation member 80 resists the torsion coil spring 60 so that the hardness decreases along the driving body 20. It works.

15, 16, this longitudinal motion makes the 1st shaft part 23 pivotally engaged with the engagement part 33, and the 2nd shaft part 24 moves up and down inside the guide groove 34. As shown in FIG. The first push switch S1 is operated by this longitudinal motion. As shown in FIGS. 17 and 18, when both end portions of the side surfaces of the operation member 80 are pressed in the direction of the arrow Y2 or the arrow Y3, the operation member 80 is applied to the torsion coil spring 60. Resistor is driven along the drive body 20 with the first and second shaft portions 23 and 24 as the support shafts, and the second push switch S2 or the third push switch S3 is driven by this seesaw operation. Will be manipulated.

Moreover, the operation member 80 is connected to the rotary electrical component R1 by the connection member 40.

The connecting member 40 is made of a metal material or the like, and has a rod-shaped portion 41 and engaging portions 42 provided at both ends of the rod-shaped portion 41. The engagement portion 42 has a hexagonal cross section in a plane perpendicular to the formation direction of the rod-shaped portion 41, and an end surface in the formation direction of the rod-shaped portion 41 as an arcuate surface.

The rotating electrical component R1 is formed of an encoder, an installation plate 50 serving as an installation portion for the printed circuit board 70, an insulator base 52 having a fixed contact 51, and the insulator base 52. It is comprised by the rotating body 54 which is rotatably held in the inside, the movable contact 53 is provided in the outer peripheral surface, and has the non-circular recessed part 55 which consists of hexagonal holes etc. provided in the center part.

The rotary electrical component R1 is housed in the second housing portion 32 of the box body 30, and the mounting plate 50 is soldered and fixed to the printed circuit board 70, and the fixed contact 51 is It is soldered to the printed board 70 and electrically connected to a wiring pattern (not shown).

In addition, when the rotary electric component R1 is accommodated in the box body 30, the recessed part 55 of the rotating body 54 faces the insertion part 35, and this rotating body 54 rotates. As a result, the movable contact 53 comes out of contact with the fixed contact 51 to generate a pulse.

The connecting member 40 is disposed in an inclined state over the first accommodating part 31 and the second accommodating part 32 of the box body 30. At this time, the rod-shaped portion 41 is inserted into the insertion portion 35 so that one engagement portion 42 is engaged with the recess 82 of the operation member 80 and the other engagement portion is engaged. 42 is engaged with the recessed part 55 of the rotating body 54. As shown in FIG.

When the operation member 80 is rotated about the rotation axis G2, the connecting member 40 rotates through the engaging portion 42, and when the connecting member 40 rotates, the engaging portion of the other end side ( The rotary body 54 of the rotary electric component R1 is rotated via 42 to operate the rotary electric component R1.

Next, the operation of the input device of the second embodiment having the above configuration will be described in detail with reference to the drawings. In the state shown in FIG. 7, when the operation member 80 is operated in the rotational direction at right angles to the rotation axis G2, the rotation is performed around the protrusion 22.

Then, the connecting member 40 is rotated via the engaging portion 42 by the operating member 80, and the rotation of the connecting member 40 is transmitted to the rotating body 54, and as a result, the rotating body 54. ) Rotates to generate a pulse signal, so that the rotating electrical component R1 is operated.

Next, as shown in FIG. 15, FIG. 16, a pressurization operation | movement of the center part of the side surface of the operation member 80 in the direction perpendicular to the rotation axis G2, ie, press the side surface of the operation member 80 to arrow Y1 direction In operation, the operation member 80 is positioned up and down with respect to the longitudinal center line G3 passing through the center portion of the seesaw operation as a support point at a position orthogonal to the center portion in the direction of the rotation axis G2 along the driving body 20. The hardness is made by using the first shaft portion 23 as a supporting point in the direction perpendicular to each other. As described above, since the first shaft portion 23 and the engaging portion 33 have a slight clearance, it is possible to make the hardness in this manner. That is, as shown in FIG. 16, the 2nd shaft part 24 will circularly move using the 1st shaft part 23 on the longitudinal center line G3 as a support point. The third protrusion 27 of the driving body 20 presses the movable contact 73c of the first push switch S1 so that the first and second fixed contacts 71c and 72c conduct. S1) is operated. At this time, since the third projection 27 is formed to be shifted to the second shaft portion 24 side, a large stroke can be obtained even by a slight positive pressure operation, and the first push switch S1 is reliably operated. In addition, since a slight positive pressure operation is performed, there is a reduced risk of the first and second protrusions 25 and 26 misoperating the second and third push switches S2 and S3.

In addition, referring to FIG. 8, when the operating member 80 is pressed in the direction of the arrow Y1, the first arm portion 62 and the second arm portion 63 of the torsion coil spring 60 are moved to the first position of the driving body 20. The first extension protrusion 28 and the second extension protrusion 29 are pressed to be bent by the same amount. Then, when the pressing operation against the operation member 80 is released, the torsion coil spring 60 returns, and the free ends of the first and second arm portions 62 and 63 move to the first and second of the box body 30. It stops at the bottom of the stop parts 37 and 38. By doing so, the operation member 80 along the drive body 20 is pushed back to its original state and the operation of the first push switch S1 is released.

17 and 18, when the end side of the operation member 80 is pressed in a direction perpendicular to the rotation axis G1, that is, when the side surface of the operation member 80 is pressed in the direction of the arrow Y2, The operation member 80 resists the torsion coil spring 60 and performs the seesaw operation along the driving body 20 with the first and second shaft portions 23 and 24 as the supporting shafts, and as a result, the first projections ( The second push switch S2 is operated by 25).

As shown in FIG. 18, when the operation member 80 is pressed in the direction of the arrow Y2, the first arm portion 62 of the torsion coil spring 60 is connected to the first extension protrusion 28 of the driving body 20. Pressurized and bent. Then, when the pressing operation against the operation member 80 is released, the torsion coil spring 60 returns, and the free end of the first arm portion 62 hangs on the lower end of the first stopping portion 37 of the box body 30. Stops By doing so, the operation member 80 along the drive body 20 is pushed back to its original state and the operation of the second push switch S2 is released. In addition, when the operation member 80 is pressed in the direction of the arrow Y3, the third push switch S3 is operated by the second projection 26 so that the second arm portion 63 of the torsion coil spring 60 is moved to the second. The engagement member 80 along the drive body 20 is pushed back to its original state by being engaged with the stop 38. Since this operation is the same as the operation in the direction of arrow Y2, detailed description is omitted.

Moreover, of course, it is also possible to operate the 1st push switch S1 when the operation member 80 is seesaw operation.

In addition, in the seesaw operation of the operation member 80, the inclination angle of the connecting member 40 is changed by using the engaging portion 42 of the rotating electrical component R1 side as a supporting point. Each engaging portion 42 is a rotation axis direction G2 of the operation member 80 and / or a rotation axis direction of the rotor 54 along the flat surface of the recess 12 and / or recess 55. It slides to G1.

In the present embodiment, since the hardness center line G3 serving as the rotation axis of the seesaw operation is configured to be long at the time of the operation of the first push switch S1, it is wrong when the first push switch S1 is operated. It is unlikely that the second and third push switches S2 and S3 will be driven.

In addition, the rotating electrical component R1 in the second embodiment may be an electrical component such as a rotating variable resistor, and the concave portions 55 and 12 are provided in the rotating body 54 and the operating member 80. As described above, the protrusion 54 having the non-circular engaging portion is provided on the rotating body 54 and / or the operation member 80, and the protrusion is engaged with the non-circular recess provided in the connecting member 40. You may also do so.

In addition, in the second embodiment, the operation member 80 is rotatably held on the protrusion 22, and at the same time, the coupling member 40 is coupled between the operation member 80 and the rotary electrical component R1. However, as in the prior art, a through hole having a shape that decreases in diameter as it is moved to the center of the operation member is provided, and the shaft is fitted to the through hole so that rotation and hardness are possible. It may be a structure provided with.

In addition, in the second embodiment, the first shaft portion 23 is circumferential and the engaging portion 33 is also a round hole, and there is a slight clearance between both, so that the first shaft portion 23 can be inclined by that amount. 23) may be spherical. That is, as long as the 1st shaft part 23 and the engagement part 33 may be restrict | limited in the up-down direction so that the 1st shaft part 23 may rotate and it is a support point at the time of longitudinal movement. The second shaft portion 24 and the guide hole 34 may have a relationship in which the second shaft portion 24 is rotatable, and is restricted in the upward direction so as to be movable downward. In addition, the outer circumferential surface of the semi-circular arc-shaped portion 21 is made into a cylindrical shape, and it does not stick to the wall surface of the box body 30 when the first push switch S1 is operated. Or a shape which does not stick. In addition, the uneven relationship between the first shaft portion 23 and the engaging portion 33 may be reversed, and the uneven relationship between the second shaft portion 24 and the guide hole 34 may also be reversed.

Although the first, second, and third push switches S1, S2, and S3 have been described as being formed three, it is also possible to increase the number of the protrusions of the driving body 20 and increase the number of the push switches. In addition, the push switch has been described as being formed on the printed circuit board 70 in which the box body 30 is assembled with each component, but is formed in advance before installation on the printed board 70 in the bottom wall installed in the box body 30 Of course, various configurations such as soldering the terminal to the printed circuit board 70 can be applied.

In the input device of the present invention, the rotation axis G2 of the operation members 12 and 80 is positioned in front of the rotation axis G1 of the rotation bodies 10 and 54, and the operation member is connected to the operation members 15 and 40. The rotary electric parts R1 are operated by connecting the 12 and 80 and the rotating bodies 10 and 54 to operate the rotary electric parts R1 via the connecting members 15 and 40 by the rotation operation of the operating member 12. The component R1 can be lowered on the installation position side to provide a compact input device.

In addition, one end side of the connecting members 15 and 40 is engaged with one end side of the operation members 12 and 80, and the other end side of the connecting members 15 and 40 is hooked to the rotary bodies 10 and 54. FIG. Since the connecting members 15 and 40 are arranged in an inclined state between the rotary bodies 10 and 54 and the rotation axes G1 and G2 of the operating members 12 and 80, the shaft penetrates the shaft in the center of the operating member as in the prior art. Therefore, it is not necessary to make the connecting members 15, 40 shorter than the conventional art, and at the same time, it is possible to provide an input device having a small bending and long life.

In addition, the short connecting members 15 and 40 can reduce the size in the lateral direction, and have good assembly and low cost.

Moreover, the 1st push switch S1 is provided in the position which opposes the side back side of the operation member 12, 80, and the operation member 12, 80 in the direction perpendicular to the rotation axis of the operation member 12, 80. By operating the first push switch (S1) by the pressing operation of) can provide a multi-function input device.

Moreover, the drive bodies 11 and 20 which rotatably support the operation members 12 and 80 are provided, and the 1st push switch passes through the drive bodies 11 and 20 by the press operation of the operation members 12 and 80. Moreover, as shown in FIG. Since S1 is operated, the drive bodies 11 and 20 can provide an input device having a simple and inexpensive configuration by combining the holding of the operation members 12 and 80 and the operation of the first push switch S1.

Moreover, it has the box bodies 4 and 30 which install the drive bodies 11 and 20, and the drive bodies 11 and 20 are snap-fastened to the box body 4, and the drive bodies 11 and 20 are box bodies 4, respectively. ), The installation of the drive bodies 11 and 20 is easy and productivity is obtained.

Moreover, the drive bodies 11 and 20 have semi-circular arc-shaped parts 11a and 21 and protrusions 11d and 22 which are located in the center part of this semi-circular arc-shaped part 11a and 21, and the operation member 12 and 80 of The projections 11d and 22 are fitted into the holes 13b and 81a provided on the other end side, and the operation members 12 and 80 are rotatably supported by the projections 11d and 22, and the operation member ( 12, 80 are covered with semi-circular arc portions 11a, 21 to operate the first push switch S1 with the semi-circular arc portions 11a, 21, so that the drive bodies 11, 20 are compact. And it can be miniaturized, and can provide a further smaller input device.

Moreover, when the 2nd and 3rd push switches S2 and S3 are provided in the both sides of the 1st push switch S1, and the both ends of the side front side of the operation members 12 and 80 are respectively pressed, the operation member Since the 12 and 80 are longitudinally operated to operate the second and third push switches S2 and S3 through the driving bodies 11 and 20, respectively, the multifunctional input device can be further provided.

In addition, non-circular engaging portions 15b and 42 having an outer surface arc-shaped are provided at both ends of the connecting members 15 and 40, and the engaging portions 15b and 42 are rotated bodies 10 and 54. And the non-circular recesses 10a, 14a, 82, and 55 provided in the operating members 12 and 80 to transmit the rotation operation of the operating members 12 and 80 to the rotating bodies 10 and 54. Since the configuration is simple, it is possible to cope with a change in the inclination of the connecting members 15 and 40.

In addition, flat surfaces extending in the rotation axis directions G1 and G2 are provided in the recesses 10a, 14a, 82, and 55 of the rotating bodies 10, 40 and / or the operation members 12, 80. Since the engaging portions 15b and 42 are made to slide in the rotational axis directions G1 and G2 on the flat surface, the movement of the engaging portions 15 and 40 due to the change of the inclination of the connecting members 15 and 40 is prevented. It becomes smooth and the thing with good operability is obtained.

In addition, in the input device of the present invention, both ends of the driving body 20 can be seesawed in a direction orthogonal to the rotation axis direction with the central portion in the rotation axis direction of the operating member 80 as the center of hardness. It is held in the box body 30 so that the longitudinal movement is possible, with the position orthogonal to the center portion of the rotation axis direction being supported, and the second and third push switches S2 and S3 are respectively operated by the seesaw operation of the drive body 20. Since the first push switch S1 is operated by the longitudinal movement of the drive body, the input device has a good feeling of operation and less misoperation because the axes are determined during the longitudinal movement. Can be provided.

Moreover, the 2nd and 3rd push switches S2 and S3 in the input device of this invention are provided in parallel with the rotation axis direction of an operation member, and the 1st push switch S1 is a 2nd and 3rd push switch. Since the rotation axis is inserted in the middle of S2 and S3 and arranged on the side opposite to the hardness point of the drive body 20, when the drive body 20 is longitudinally operated in a relatively small amount, the first push switch is used. Is operated, the risk of misoperation of the second and third push switches according to the hardness operation can be reduced, and an input device with good reliability can be provided.

In addition, while the first shaft portion 23 in the input device of the present invention is pivotally engaged, the second shaft portion 24 is movable up and down in the guide groove 34, Since the seesaw operation is performed with the first and second shaft portions as the support shafts, and the longitudinal motion of the drive body is configured by the second shaft portion moving the guide grooves 24 with the first shaft portion as the support points. It is possible to reliably realize the seesaw operation and the hardness operation by the configuration, thereby providing an input device having good mass productivity and reliability.

In addition, since the input device of the present invention is configured to return the driving body 20 to its original state during the seesaw operation and hardness operation by the torsion coil spring 60, a simple configuration using the torsion coil spring 60 is used. Automatic return can be realized.

In addition, since the torsion coil spring 60 is configured to be held by the protrusion 36 provided in the box body 30, the torsion coil spring 60 can be easily maintained, so that an excellent mass production input device can be provided. have. In addition, the space efficiency is also good.

The torsion coil spring 60 is disposed on the side opposite to the hardness point of the driving body 20 while sandwiching the rotation axis, and the winding portion of the torsion coil spring 60 is held by the projection 36, and the projection ( Since the torsion coil spring 60 is the opposite side of the hardness point, the return force is reliably obtained while the winding portion is located at the center, so Appropriate return force is obtained for the operation and the hardness operation.

Claims (16)

A rotating electrical component having a rotating body, an operating member for rotating operation, and a connecting member for transmitting the rotating operation of the operating member to the rotating body, The operation member is provided to perform a rotation operation from the side front side of the operation member in a direction perpendicular to the rotation axis of the operation member which is an axis of the rotation operation, The rotating body is rotated by rotating the axis of rotation of the rotating body by the rotating operation of the operating member transmitted through the connecting member, And the operation member is provided such that the rotation axis of the operation member is located on the side front side of the operation member rather than the rotation axis of the rotating body. The method of claim 1, One end side of the connecting member is engaged with one end side of the operating member, and the other end side of the connecting member is engaged with the rotating body such that the connecting member is between the rotational axis of the rotating body and the operating member. Input device, characterized in that disposed in the inclined state. The method of claim 1, The first push switch is provided at a position opposite the side rear side of the operation member, and the first push switch is operated by the pressing operation of the operation member in a direction perpendicular to the rotation axis of the operation member. Input device characterized in that. The method of claim 3, And a driving body rotatably supporting the operating member, and operating the first push switch via the driving body by a pressing operation of the operating member. The method of claim 4, wherein And a box body for installing the drive body, wherein the drive body is snap-fastened to the box body and the drive body is installed in the box body. The method of claim 4, wherein The drive body has a semi-circular arc-shaped portion and a protrusion located at the center portion of the semi-circular arc-shaped portion, and the protrusion is fitted to a hole provided on the other end side of the operating member to rotatably support the operating member on the protrusion. And at the same time, covering the rear side of the side surface of the operation member with the semi-circular arc portion, and operating the first push switch in the semi-circular arc portion. The method of claim 4, wherein When the second and third push switches are provided on both sides of the first push switch, and when both end sides of the side front side of the operation member are pressed respectively, the operation member is longitudinally moved to pass through the drive body. And inputting the second and third push switches, respectively. The method of claim 1, Both ends of the connecting member are provided with non-circular engaging portions whose outer surfaces are arc-shaped, and the engaging portions engage with the non-circular recesses provided in the rotating body and the operation member. Input device for transmitting the rotating operation of the operation member to the rotating body. The method of claim 8, And a flat surface extending in the rotation axis direction in the concave portion of the rotating body and / or the operation member, and the engaging portion makes the engaging portion slide in the rotation axis direction. delete An operating member which is connected to the rotating electrical component by a connecting member and manipulates the rotating electrical component via the connecting member by a rotating operation, a driving body for holding the operating member rotatably, and holding the driving body. Has a box body and at least first, second and third push switches disposed below the drive body, The drive body is formed with a first shaft portion and a second shaft portion serving as a support shaft for the seesaw operation of the drive body with the rotation axis therebetween, The first shaft portion is pivotally engaged to the engagement portion formed in the box body, and the second shaft portion is movable up and down in a guide groove formed in the box body. Seesaw operation of the drive body is performed with the first and second shaft portions as the support shafts, and the longitudinal movement of the drive body is carried out by the second shaft portion moving the guide grooves with the first shaft portion as the support point. Done, The second and third push switches are operated by the seesaw operation of the drive body, and the first push switches are operated by the longitudinal motion of the drive body. The second and third push switches are disposed in parallel with the rotation axis direction of the operation member, and the first push switch is fitted at the intermediate portion of the second and third push switches to sandwich the rotation axis. Input device, characterized in that disposed on the opposite side to the hardness point. An operating member which is connected to the rotating electrical component by a connecting member and manipulates the rotating electrical component via the connecting member by a rotating operation, a driving body for holding the operating member rotatably, and holding the driving body. Has a box body and at least first, second and third push switches disposed below the drive body, The drive body is formed with a first shaft portion and a second shaft portion serving as a support shaft for the seesaw operation of the drive body with the rotation axis therebetween, The first shaft portion is pivotally engaged to the engagement portion formed in the box body, and the second shaft portion is movable up and down in a guide groove formed in the box body. Seesaw operation of the drive body is performed with the first and second shaft portions as the support shafts, and the longitudinal movement of the drive body is carried out by the second shaft portion moving the guide grooves with the first shaft portion as the support point. Done, And the second and third push switches are operated by the seesaw operation of the drive body, and the first push switch is operated by the longitudinal motion of the drive body. The method of claim 12, And a torsion coil spring which abuts against the drive body and adds the drive body, and the torsion coil spring returns the drive body to the state before operation during the seesaw operation and the longitudinal operation. The method of claim 13, And the torsion coil spring is held by a protrusion provided in the box body. The method of claim 14, The torsion coil spring is arranged on the side opposite to the hardness point of the drive body by sandwiching the rotation axis, and the winding portion of the torsion coil spring is held by the projection, and the projection is located at the center of the rotation axis direction of the operation member. Input device, characterized in that located. The method of claim 15, The torsion coil spring has a pair of arm portions sandwiching the winding portion and extending in opposite directions and in the direction of the rotation axis, and the free end side of the arm portion makes it possible to engage the engaging portion provided in the box body. Input device, characterized in that.