KR20140096026A

KR20140096026A - Bearing structure for rotary control-type electronic component

Info

Publication number: KR20140096026A
Application number: KR1020147007987A
Authority: KR
Inventors: 하지메 후쿠시마; 타로 후쿠나가
Original assignee: 도쿄코스모스덴키가부시키가이샤
Priority date: 2011-11-04
Filing date: 2012-10-19
Publication date: 2014-08-04
Also published as: JPWO2013065507A1; CN103843094B; TW201335501A; JP5852669B2; WO2013065507A1; KR101900897B1; TWI521154B; CN103843094A; HK1194201A1

Abstract

A holding portion 120 having an outer diameter smaller than the outer diameter and extending in the axial direction so as to form a step portion 100S from one end of the operating portion 110 and a rotating portion 130 having a driving portion 130 further extending in the axial direction from the holding portion 120 And a bearing 200 having one end thereof opposed to the step portion 100S and having a shaft hole 230 through which the holding portion 120 is inserted and which rotatably holds the operating shaft 100, And a tapered surface 100T extending from the radial intermediate position of the stepped portion to the outer peripheral surface of the holding portion 120 is formed in the pivotal operation shaft 100, A tapered surface 200T having an inner diameter larger toward the outside is formed at the inner peripheral edge of the shaft hole 230 at one end of the bearing 200. The annular ring 210 cut between the tapered surfaces 100T and 200T, A bearing structure in which a spring (300) is mounted.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a bearing structure of a rotatable electronic component,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a bearing structure of a rotatable operation type electronic part used as a rotary switch or a variable resistor of a portable electronic device such as a radio device.

Conventionally, a bearing structure adopted in a rotary switch or a variable resistor has a structure in which a shaft is inserted into a bearing as shown in, for example, Patent Document 1 or Patent Document 2. Therefore, there is not provided a structure for reducing the backlash in the thrust direction or the radial direction of the shaft, and the backlash is determined by the dimensional accuracy of the bearing and the shaft.

Patent Document 3 discloses a rotary switch having a bearing structure in which an O-ring for waterproofing is interposed between the inner wall surface of the case and the outer peripheral surface of the rotary body. The bearing structure can suppress rattling in the radial direction, but can not suppress rattling in the axial direction.

Japanese Patent Publication No. 4759071 Japanese Utility Model Publication No. 62-168607 Japanese Patent Publication No. 3698270

A rotary switch of a portable electronic device is required to be downsized, and its operation handle is large enough to satisfy ease of operation. Therefore, the backlash at the knob operating position is increased due to the size of the knob, and does not give a smooth touch to the operator when operating the knob.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a bearing structure of a rotary operation type electronic part capable of suppressing backlash in the axial direction and radial direction in view of the above-described problem.

A bearing structure of a rotary operation type electronic part according to the present invention is a bearing structure of a rotary operation type electronic part comprising a cylindrical operating part and a stepped part formed from one end of the operating part so as to have a small outer diameter and extending in the axial direction, A rotating operation shaft including a driving portion, a bearing having a shaft hole through which the holding portion is inserted and which rotatably holds the rotating shaft, one end of which is opposed to the step portion, And a first tapered surface extending from a radially intermediate position of the stepped portion to the outer peripheral surface of the holding portion is formed in the pivotal operation shaft, A second tapered surface having an inner diameter larger toward the outer side is formed at an inner circumferential edge of the first, And a ring is fitted in the annular groove formed on the outer periphery of the end portion on the side of the driving portion of the holding portion and engaged with the other end of the bearing, .

According to the present invention, since the external force for pressing the ring spring by the tapered surface is divided in the axial direction and the radial direction, the axial and radial rattling can be suppressed.

1 is an exploded perspective view of a rotary switch according to a first embodiment of the present invention.
2 is an axial sectional view of the embodiment of Fig.
Fig. 3 is a perspective view of the holder 6 in Fig. 1 as viewed from the housing recess 23 side.
4 is an exploded perspective view of a variable resistor according to a second embodiment of the present invention.
5 is an axial cross-sectional view of the embodiment of Fig.
6A is a perspective view of the holder 6 'in FIG. 5 as viewed from the housing recess 23 side, and FIG. 6B is a plan view of the holder 6' in FIG. 5 as seen from the housing recess 23 side. to be.
7 is a perspective view of a rotor 7 'showing a modification of the embodiment of Fig.
8 is an exploded perspective view of a rotary switch according to a third embodiment of the present invention.
9 is an axial sectional view of the rotary switch of Fig.
Fig. 10A is a perspective view of the click spring in Fig. 9 and the click spring support plate before it is attached, and Fig. 10B is a perspective view of the click spring support plate after attaching the click spring.
Fig. 11A is a top view of the rotor in Fig. 9, Fig. 11B is a cross-sectional view of the rotor in Fig. 9, and Fig. 11C is a bottom view of the rotor in Fig.
FIG. 12A is a view showing connection patterns of the upper and lower contact pieces in FIG. 9, and FIG. 12B is a view showing a sliding contact piece in which the connection pattern is folded and formed.
13A is a bottom view of the lower holder, and Fig. 13B is a top view of the upper holder.
Fig. 14 is an exploded perspective view of a second embodiment of the rotary switch according to the present invention.
15 is a schematic diagram for conceptually illustrating the bearing structure of the present invention.

[First Embodiment]

Fig. 1 is an exploded perspective view of an embodiment of a rotary switch to which a bearing structure according to the present invention is applied, and Fig. 2 is a sectional view in the axial direction.

The rotary switch includes a cylindrical rotary operation shaft 10, a bearing 20 through which the rotary operation shaft 10 is inserted, a rotor 7 mounted and fixed to the rotary operation shaft 10, And a holder (6).

The pivoting operation shaft 10 is constituted by a cylindrical operating portion 11 formed of resin or metal and having an outer peripheral surface that is chamfered in parallel in the axial direction and a cylindrical portion 11 having a small diameter from the one end of the operating portion 11, Shaped holding portion 12 and a columnar driving portion 13 having a smaller diameter from the one end of the holding portion 12 and extending in the axial direction. The end surface of the operating portion 11 on the side of the holding portion 12 is formed with a radial stepped portion 10S from the outer peripheral edge of the operating portion 11 and the radial direction intermediate position of the stepped portion 10S, A tapered surface 10T extending to the outer peripheral surface of the tapered surface 10A is formed. An annular groove 12a is formed on the outer periphery of the holding portion 12 adjacent to the end face of the operating portion 11 on the opposite side. The driving section 13 has a shape in which both sides of the driving section 13 are chamfered with the axial center line interposed therebetween in parallel with the axial direction, and thus the cross section perpendicular to the axial center line is a circular arc having two sides opposite to each other.

The bearing 20 is made of resin or metal and has a cylindrical portion 21 having an axial hole 24 into which the holding portion 12 is inserted and having an inner diameter smaller than the outer diameter of the operating portion 11 of the pivotal operation shaft 10 And a substantially rectangular parallelepiped housing portion 22 integrally formed at one end of the cylindrical portion 21. [ On the outer circumferential surface of the cylindrical portion 21, there is formed a screw for attaching to a housing of a device in which the rotary switch is used. A tapered surface 20T is formed on the inner circumferential edge of the shaft hole 24 at the tip end portion of the cylindrical portion 21 so as to have an inner diameter larger toward the outside of the shaft hole 24 with respect to the axial direction. The housing portion 22 is formed with a circular receiving recess 23 communicating with the shaft hole 24 and concentric with the shaft hole 24 and having a larger diameter than the shaft receiving hole 23, It is open. The tapered surface 10T formed in the stepped portion 10S and the tapered surface 20T formed in the cylindrical portion 21 are in such a relationship as to be inclined toward the stepped portion 10S .

And the outer diameter of the annular ring spring (12) is substantially the same as the outer diameter of the holding portion (12), the outer diameter thereof is smaller than the outer diameter of the operating portion (11) 3 are resiliently fitted between the tapered surfaces 10T and 20T to be mounted on the turning operation shaft 10 and the holding portion 12 is inserted into the shaft hole 24 of the bearing 20, The annular groove 12a of the end portion of the holding portion 12 protruding into the accommodating concave portion 23 has an outer diameter larger than the inner diameter of the shaft hole 24 and a ring- And is engaged with the bottom surface 23a of the accommodating concave portion 23 adjacent to the shaft hole 24 to prevent the turning operation shaft 10 from slipping out. At this time, the ring spring 3 sandwiched between the tapered surfaces 10T and 20T is resiliently pressed toward the stepped portion 10S by the tapered surface 20T, and the elastic ring 3 is elastically . When an axial and / or radial external force is given to the pivoting operation shaft 10, the ring spring 3 is further pushed up toward the stepped portion 10S, further deformed to open the ring, The resilient force of the ring spring 3 resists the external force by pushing the tapered surface 20T in the axial direction. As a result, the backlash in the axial and radial directions of the pivotal operation shaft 10 relative to the bearing 20 is resiliently restrained. Therefore, the operator can obtain a smooth turning operation feeling.

The rotor 7 is formed of a resin and has a rotary shaft 7A in which a shaft hole 7D having the same sectional shape as that of the drive unit 13 of the rotary operation shaft 10 is formed, And has a disk portion 7B integrally formed on the shaft and having a plate surface at one end thereof perpendicular to the axial direction. The disk portion 7B is rotatably disposed in the accommodating concave portion 23 of the housing portion 22. A sliding contact piece 7C formed by stamping a metal plate so as to be flush with the surface of the disc portion 7B on the side opposite to the bearing 20 is attached by integral molding.

The holder 6 is formed of a resin and has a rectangular parallelepiped shape having a cross section perpendicular to the axial direction of the housing portion 22 and covering the housing portion 22 from above the rotor 7. [ 3 shows a perspective view of the holder 6 as viewed from the side of the housing part 22. The holder 6 has a circular receiving recess 6A for extending the receiving recess 23 on the side of the housing part 22 And a shaft hole 6D penetrating the holder 6 is formed at the center thereof. Elastic contacts 6C1 and 6C2 and two elastic contacts 6C3 protrude inwardly from the inner circumferential surface of the accommodating concave portion 6A and the elastic contact 6C1 and one set of the elastic contacts 6C3 and the elastic contact 6C2 And elastic contact 6C3 are located opposite to each other with shaft hole 6D interposed therebetween and the elastic contact 6C1, 6C2 and 6C3 are arranged such that the tip ends of these elastic contacts 6C1, It is folded so as to protrude. The other ends of the elastic contacts 6C1 and 6C2 protrude outward from the side surface of the holder 6 and serve as terminals 6T1 and 6T2, respectively. The other ends of the two elastic contacts 6C3 are integrally formed and protrude outward from the side surface of the holder 6 as a terminal 6T3.

The drive portion 13 protruding into the accommodating concave portion 23 is inserted into the shaft hole 7D of the rotor 7 to dispose the disk portion 7B of the rotor 7 in the accommodating concave portion 23 The holder 6 is loaded in such a manner that the tip end of the driving part 13 is rotatably projected from the shaft hole 6D of the holder 6 and the receiving recess 23 is covered from above the rotor 7, The pin 8 is inserted into the fixing hole 6a of the holder 6 and the fixing hole 22a of the housing portion 22 and the tip is caulked by the rivet to complete the rotation type switch.

The rotor 7 is rotated by rotating the operating portion 11 of the turning operation shaft 10. [ The distal ends of the elastic contacts 6C1 and 6C2 and 6C3 provided on the holder 6 are located at different radial positions from the axial center of the pivoting operation shaft 10. [ That is, in this example, the two elastic contacts 6C3 sharing the terminal 6T3 are located on both sides of the rotary shaft 7A of the rotor 7, and the elastic contacts 6C1 and 6C2 6C2 are respectively positioned and slidingly contacted with the sliding contact piece 7C provided on the plate surface of the disc portion 7B by the rotation of the rotor 7. [ The sliding contact piece 7C conducts between the terminals 6T1 and 6T3 in the first predetermined rotation angle range (may be plural) of the rotor 7, and the second predetermined rotation angle range The number of the sliding contact pieces 7C, the respective arc angles, the radial positions and widths, and the like are determined so that the terminals 6T2 and 6T3 are electrically connected to each other.

The pressing force exerted on the ring spring 3 by the tapered surface 20T can be set as desired by adjusting the axial position of the annular groove 12a and thus the axial position of the stationary ring 4 as desired, The frictional force with the ring spring 3 can be set as desired between the teeth 10T and 20T and an appropriate turning operation feeling can be given to the operator.

[Second Embodiment]

Figs. 1, 2 and 3 show a first embodiment in which the bearing structure of the present invention is applied to a rotary switch. Fig. 4 shows an exploded perspective view of an embodiment applied to a variable resistor, and Fig. This variable resistor includes a rotary operation shaft 10, a bearing 20, a rotor 7 ', a holder 6', a ring spring 3, a stationary ring 4, 8, and only the rotor 7 'and the holder 6' are different from those of the first embodiment shown in Figs. 1, 2 and 3. Therefore, the following description will focus on the different parts, and a description of common parts will be omitted as much as possible.

The rotor 7 'has a rotating shaft 7A and a disc portion 7B similar to the rotor 7 of Fig. 1 except that the sliding contact piece 7C in place of the sliding contact piece 7C in Fig. 'C is attached to the surface of the disc portion 7B. The sliding contact piece 7'C is formed by press working with a resilient metal plate and has a substantially semicircular base portion 7'Cb and a base portion 7'Cb extending from the side edge of the base portion 7'Cb on the side of the rotation axis 7A, And two contacts 7'C1 which are bent to be apart from the plate surface of the disc portion 7B and which extend from the base 7'C1 to the outside of the base 7'C1 from the outside of the two contacts 7'C1, And a contact 7'C2 that extends from the side edge and is bent to be separated from the plate surface of the disc portion 7B.

The base 7'Cb is fixed to the fixing hole 7'Aa formed in the base by pressing a projection (not shown) protruding from the surface of the disk 7B. The tip ends of the contacts 7'C1 and 7'C2 are folded back to the plate surface side of the disk portion 7B to form convex bent portions 7'C1a and 7'C2a toward the holder 6 ' As shown in Fig. The bent portions 7'C1a and 7'C2a are arranged in a straight line orthogonal to the rotation center line and the bent portions 7'C1a of the two contacts 7'C1 are located on both sides adjacent to the pivot 7A , The bent portion 7'C2a of the contact 7'C2 is located radially outwardly of the bent portion 7'C1a of the one contact.

6A and a plan view of the holder 6 'as seen from the side of the rotor 7' and a shaft hole 6D on the bottom surface 6B of the accommodating concave portion 6A, A common conductor ring 6C formed by pressing a metal plate so as to surround the common conductor ring 6C and an arc-shaped resistor 6R provided concentrically and spaced apart from the common conductor ring 6C. Both ends of the resistor 6R are connected to the terminals 6T1 and 6T2, respectively. The terminal 6T3 extends between the opposite ends of the resistor 6R and integrally extends from the common conductor ring 6C.

The curved portion 7'C1a of the two contacts 7'C1 of the sliding contact piece 7'C is in elastic contact with the common conductor ring 6C while the holder 6 ' , The bent portion 7'C2a of the contact 7'C2 makes elastic contact with the resistor 6R. Therefore, when the rotor 7 'is rotated, the electrical resistance between the terminals 6T1 and 6T3 and the electrical resistance between the terminals 6T2 and 6T3 change.

5 also shows a tapered surface 20T formed on the inner peripheral edge of the shaft hole 24 at the tip end of the cylindrical portion 21 of the bearing 20 as shown in the axial cross section in Fig. The ring spring 3 can be deformed so as to be widened so as to restrain the rotation of the pivoting operation shaft 10 relative to the bearing 20 in the axial and radial directions.

[Modifications]

6A, the resistor 6R and the common conductor ring 6C are provided on the bottom surface 6B of the housing recess 6A of the holder 6 ', and the rotor 7' A sliding contact piece 7'C having contacts 7'C1 and 7'C2 is provided on the disk portion 7B of the disk 7B. As a modified example, as shown in Fig. 7, a resistive member 7R in the form of an arc-shaped strip and a common conductor ring 7Cc are provided on the surface of the disc portion 7B of the rotor 7 ' The holder 6 of Fig. 2 is used and the resistor 7R and the common conductor ring 7Cc are brought into sliding contact with the elastic contacts 6C1 and 6C3, respectively. However, the elastic contact 6C2 and the terminal 6T2 are not provided. In this case, in the rotor 7 ', one end of the resistor 7R is connected to the common conductor ring 7Cc.

[Third Embodiment]

FIG. 8 is an exploded perspective view of an embodiment in which a bearing structure according to the present invention is applied to a rotary switch disclosed in Patent Document 1, and FIG. 9 is an axial sectional view of the rotary switch. The rotary switch of this embodiment is configured to increase the number of switches as well as increase the clicking feeling to the operator at a desired rotation angle interval of the rotary operation shaft 10 in the rotary type switches of Figs.

8, the rotary switch includes a rotary operation shaft 10, a ring spring 3, a bearing 20, a click disc 30, a click spring 40, A lower holder 80, a rotor 70, an upper holder 60, a cover 90, and other components. The combination of the upper holder 60 and the cover 90 corresponds to the holder 6 in Fig. 1, and the lower holder 80 having elastic contact is also provided in this embodiment, and the number of switches is increased have.

The pivoting operation shaft 10 has the same structure as the pivoting operation shaft 10 of Fig. 1 and is formed into a cylindrical shape by machining a metal rod. The pivoting operation shaft 10 has an operating portion 11, And a driving section 13 extending in the same axis from the tip end of the holding section 12 and having a diameter smaller than that of the holding section 12. The driving section 13 has a diameter smaller than that of the holding section 12, An annular groove 12a is formed on the outer peripheral surface adjacent to the tip end of the holding portion 12. The driving unit 13 is formed with at least one plane 13a formed so as to be cut parallel to the central axis. In the example shown in the drawing, two parallel planes are formed symmetrically with the rotation center of the rotation operation shaft 10 interposed therebetween.

The bearing 20 has a cylindrical portion 21 having an attaching screw formed on the outer periphery thereof and a rectangular housing portion 22 formed integrally with one end of the cylindrical portion 21. [ The bearing 20 is formed with a shaft hole 24 through which the holding portion 12 of the pivoting operation shaft 10 is pivotally inserted and passed through the cylindrical portion 21 at the center. A fixing hole 22a is formed in one set of diagonal corner portions and a positioning hole 22b is formed in another set of diagonal corner portions on the upper surface of the housing portion 22. In the center of the upper surface of the housing part 22, a circular receiving recess 23 is formed coaxially with the cylindrical part 21, and a shaft hole 24 is concentrically opened on the bottom surface. The tip end portion of the holding portion 12 of the turning operation shaft 10 inserted into the bearing 20 in a state in which the ring spring 3 is mounted so as to be in contact with the tapered surface 10T of the turning operation shaft 10, And the stationary ring 4 is mounted on the annular groove 12a at the tip end thereof to prevent disconnection.

In this embodiment, the housing portion 22 receives the click disc 30. The click disc 30 has a shaft portion 31 at the center thereof and concave and convex portions are arranged in the circumferential direction by convex troughs 32 extending radially on the upper side of the shaft portion 31. [ The shaft portion 31 is formed with a shaft hole 33 into which the rotating shaft 71 of the rotor 70 is inserted in the axial direction. The shaft hole 33 projects from the inner periphery of the shaft hole 33 toward the center, Further, an engagement key 34 extending in the axial direction is formed. The front end face of the engaging key 34 toward the center is a plane which is in contact with the plane 13a of the driving part 13 so as to engage with it. When the turning operation shaft 10 is rotated, And the plane of the engaging key 34 is engaged with the plane 13a of the driven unit 13 to rotate the click disc 30.

The annular click spring 40 is formed by punching a spring-like metal plate, and two engaging projections 41 protruding toward the click disc 30 are formed at two positions on one diameter of the annular upper portion. And two fixed terminals 42 extending outwardly from two places on the other right-angled diameter on the extension line of the diameter. The fixed terminal 42 is curved at an intermediate portion to the opposite side of the click disc 30 at approximately 45 degrees with respect to the flat surface. The click spring 40 is bent by 45 degrees so that the engagement of the click spring support plate 50 with the step groove 55 described later can be made shallow so that the thickness of the click spring support plate 50 is reduced can do.

The click spring 40 is attached to the lower surface of the click spring support plate 50. 10A and 10B are perspective views of the click spring 40 before and after attachment. Here, the set of the click spring 40 and the click spring support plate 50 shown in Fig. 8 is shown rotated around the center line 5X by 180 degrees. The click spring support plate 50 is formed in the same rectangular shape as the housing portion 22 and has an annular recess 52 for receiving a click spring 40 on the lower surface thereof, . The diameter of the shaft hole 51 is such that the turning shaft 71 of the rotor 70, which will be described later, is rotatably inserted and allowed to pass therethrough. Two positioning holes 53b are formed adjacent to one side of the click spring support plate 50. A fixing hole 53a is formed in the vicinity of one set of diagonal corner portions, The positioning projections 54 are formed.

The two fixed terminals 42 of the click spring 40 are inserted and engaged in a forked groove 55 formed to extend from the fixing hole 53a of the click spring support plate 50 in the center direction. In this state, the click spring support plate 50 allows the drive portion 13 to be inserted into the shaft hole 51, to close the receiving concave portion 23 containing the click disk 30 from above, And is attached to the upper surface. At this time, the positioning projections 54 of the click spring support plate 50 are press-fitted into the positioning holes 22b on the upper surface of the housing part 22. [

Fig. 11A is a top view of the rotor 70, Fig. 11B is a cross-sectional view taken along line 11B-11B in Fig. 11A, and Fig. 11C is a bottom view rotated by 180 占 around the line 11B- . In this embodiment, in order to increase the number of switches that can be used, the elastic contact and the sliding contact piece can be brought into contact with and separated from each other on both the one surface and the other surface of the disc portion of the rotor. That is, the rotor 70 includes a rotary shaft 71, a disk portion 72 located in the middle of the rotary shaft 71 in the longitudinal direction thereof and coaxial with the rotary shaft 71, And the sliding contact piece 7C is integrally formed by insert molding. A shaft hole 73 having the same cross-sectional shape as the shaft hole 33 of the click disk 30 is formed on the pivot shaft 71. Further, a cutout portion 74 cut out by a predetermined length in the axial direction from the lower end of one circular arc portion of the lower end of the rotary shaft 71 is formed. The cutout portion 74 is engaged with the engaging key 34 in the shaft hole 33 of the click disc 30 through the shaft hole 51 so that the rotation shaft 71 are inserted into the shaft hole 33a by the axial length of the notch portion 74. [

The sliding contact piece 7C is composed of an upper contact piece 7C1 and a lower contact piece 7C2 and is formed by punching one sheet of metal plate as shown in Fig. 12A to form upper and lower contact pieces 7C1 and 7C2 The pattern is formed by folding the pattern at the connecting portion 7Cc and folding the lower contact piece 7C2 to the lower side of the upper contact piece 7C1 as shown in FIG. 12B.

In this embodiment, the upper and lower contact pieces 7C1 and 7C2 are formed in a pattern in contact with a common circle C1 indicated by a broken line in Fig. 12B, concentric with the circle C1, B2, and B3 adjacent to each other and having widths sandwiched by the circles C2, C3, and C4, respectively, and in each of the ring-shaped zones B1, B2, A contact piece pattern having a desired number of arcuate regions of length (angular range) as contact piece regions is predetermined.

In the upper contact piece 7C1 of Fig. 11A, the annular band B1 is filled with one contact piece area C1a of a predetermined angular range and a void area G1a of the remaining angular range. The annular bands B2 are respectively filled with two contact piece regions C1b1 and C1b2 having a predetermined angular range and gapped regions G1b1 and G1b2 between adjacent two contact piece regions. The annular band B3 is filled with one (360 占) empty area G1c. The blank areas G1a, G1b1, G1b2, and G1c are areas where the metal surface of the contact piece 7C1 is exposed, and the blank areas G1a, G1b1, G1b2, and G1c are in the same plane as the surface of the contact piece area. 72).

On the other hand, in the lower contact piece 7C2 shown in Fig. 11C, the annular band B1 is divided into four contact piece regions C2a1, C2a2, C2a3, and C2a4 having a predetermined angular range, (G2a1, G2a2, G2a3, G2a4) adjacent to each other. The annular bands B2 are respectively filled with two contact piece regions C2b1 and C2b2 of a predetermined angular range and gapped regions G2b1 and G2b2 between adjacent two contact piece regions. The annular band B3 is filled with the contact piece area C2c of one (360). The hollow regions G2a1, G2a2, G2a3, G2a4, G2b1, and G2b2 are regions where the metal surfaces of the contact pieces are exposed, and the void regions (C2a1, C2a2, Is an insulator surface of the disc portion 72 that is in the same plane as the surface.

In this embodiment, the upper holder 60 and the lower holder 80 have exactly the same structure, and the holders formed as the same parts can be used as the upper and lower holders by changing their vertical directions. Likewise, the cover 90 and the click spring support plate 50 have a completely identical structure. The same structure as above can reduce the manufacturing cost of the switch.

13A shows a bottom surface of the lower holder 80 and a part of the lower surface of the rotor 70 shown thereon. A circular rotor accommodating recess 82 is formed on the upper surface of the lower holder 80 and a substantially rectangular window 81 is formed on the bottom of the rotor accommodating recess 82. The side wall portion of the rotor accommodating recess 82 adjacent to one side of the lower holder 80 has an engaging convex portion 85 (see Fig. 8) protruding from the lower surface thereof toward the upper holder 60 And an engaging concave portion 86 (see Fig. 8) formed adjacent to the engaging convex portion 85 and having the same width as the side wall portion is formed. A fixing hole 84a is formed in the vicinity of one set of diagonal corners of the lower holder 80 and a positioning hole 84b is formed in the vicinity of another set of diagonal corners. In addition, two positioning projections 83 are formed adjacent to one side to which the terminals 8T1, 8T2, 8T3 are led out.

The lower holder 80 includes three elastic contacts 8C1, 8C2 and 8C3 and integrally formed with the terminals 8T1, 8T2 and 8T3 protruding outward from one side of the lower holder 80, . The three resilient contacts 8C1, 8C2 and 8C3 extend inwardly from the edge of the window 81 and their tip ends are annular bands B1 and B2 defined in the sliding contact piece 7C of the rotor 70, , B3). Each of the elastic contacts 8C1, 8C2, 8C3 has two branch arms, and the contact stability and reliability are improved by making two points of contact in each ring-shaped band.

13B shows a part of the upper surface of the upper holder 60 and the upper surface of the rotor 70 shown below. As described above, the structure of the upper holder 60 is completely the same as that of the lower holder 80. [ A circular rotor accommodating concave portion 62 is formed on the lower surface of a substantially rectangular upper holder 60 similar to the housing portion 22. A ceiling of the rotor accommodating concave portion 62 is provided with a substantially rectangular window 61 Is formed. The side wall portion of the rotor accommodating recess 62 adjacent to one side of the upper holder 60 is provided with an engaging convex portion 65 protruding from the lower surface of the lower holder 80 toward the side of the lower holder 80, An engaging concave portion 66 is formed adjacent to the side wall 65 and cut out of the side wall portion with the same width. A fixing hole 64a is formed in one set of diagonal corner portions of the upper holder 60 and a positioning hole 64b is formed in another set of diagonal corner portions. In addition, two positioning projections 63 are formed adjacent to one side to which the terminals 6T1, 6T2, 6T3 are led.

The upper holder 60 includes three elastic contacts 6C1, 6C2 and 6C3 and the terminals 6T1, 6T2 and 6T3 integrally extended from them and projecting outward from one side of the upper holder 60, . The three resilient contacts 6C1, 6C2 and 6C3 extend inward from the edge of the window 61 and their tip ends are annular bands B1 and B2 defined by the sliding contact piece 7C of the rotor 70, , B3). In this example, each of the elastic contacts 6C1, 6C2, 6C3 has two branch arms, and each ring-shaped band makes two-point contact.

8, the positioning projections 83 (see Fig. 13A) of the lower holder 80 are fitted into the positioning holes 53b of the click spring support plate 50, The holder 80 is positioned and fixed. The rotor 70 is rotated from its upper position to the shaft hole 73 of the rotor 70 so that a substantially lower half portion of the disk portion 72 of the rotor 70 is disposed in the rotor accommodating concave portion 82 of the lower holder 80 The lower end of the rotating shaft 71 is inserted into the shaft hole 33 of the click disc 30 through the shaft hole 51 of the click spring support plate 50 while the drive unit 13 of the operation shaft 10 is inserted Insert and hang it.

The upper holder 60 is placed over the rotor 70 so as to receive substantially the upper half of the disc portion 72 of the rotor 70 in the rotor accommodating recessed portion 62 of the upper holder 60, And is fixed to the lower holder 80 in a superimposed manner. At this time, the engaging convex portion 65 and the engaging concave portion 66 (see Fig. 13B) of the upper holder 60 are engaged with the engaging concave portion 86 of the lower holder 80 and the engaging convex portion 85, Respectively, and are positioned with respect to each other. The upper end of the rotating shaft 71 of the rotor 70 is inserted into the shaft hole 91 of the cover 90 to overlap the cover 90 from above the upper holder 60 to position the positioning protrusion 94 Fitted into the crystal hole 64b, and the positioning projection 63 is fitted in the positioning hole 93b. The elastic contacts 8C1, 8C2 and 8C3 of the lower holder 80 are elastically held in contact with the lower surface of the disk portion 72 of the rotor 70 and the elastic contacts 6C1 , 6C2 and 6C3 are resiliently held in contact with the upper surface of the disc portion 72 of the rotor 70. [

The fixing holes 93a of the cover 90, the fixing holes 64a of the upper holder 60, the fixing holes 84a of the lower holder 80, and the click spring supporting plate 50 are assembled in this state, Two fixing pins 8 are inserted into the fixing holes 53a of the bearing 20 and the fixing holes 22a of the bearing 20 so that the tips of the pins 8 are riveted and integrally fixed to each other.

By assembling the rotary switch in this manner, the drive unit 13 is inserted into the shaft hole 73 of the rotary shaft 71 of the rotor 70 inserted through the click disk 30 and the click spring support plate 50, And is supported in the shaft hole 91 of the cover 90. The cross section perpendicular to the axial center of the shaft hole 73 of the rotor 70 is formed by cutting a circular arc in a straight line in the same manner as the cross section of the drive section 13, The rotator 70 is rotated and the click disk 30 is also rotated. As a result, the protrusion 41 of the click spring 40 fixed to the click spring support plate 50 is engaged with the radial protrusion of the click disc 30 to be pivoted, and when the rotation operation shaft 10 is rotated, And sliding contact between the contact pieces 7C1 and 7C2 on the upper and lower sides of the rotor 70 and the elastic contacts 6C1, 6C2, 6C3 and 8C1, 8C2 and 8C3 of the upper and lower holders, , It is possible to generate divergence.

As can be understood from the above description, in the third embodiment, in the annular regions different in radial direction on the upper and lower sides of the disc portion of the rotor 70, So that there is an advantage that the degree of freedom of design is high. That is, there is a high degree of freedom in designing the angular range of opening and closing of the plurality of switches, and the relative timing, in accordance with the demand.

In the above-described third embodiment, the annular bands B1, B2, and B3 are defined for the contact pieces 7C1 and 7C2 on the upper and lower sides of the rotor 70, The number and width of the shape bands are defined separately for the upper side and the lower side and the number and arrangement of the elastic contacts of the upper holder 60 and the lower holder 80 can be determined by fitting the respective ring- Of course.

[Fourth Embodiment]

Fig. 14 shows a fourth embodiment of the rotary switch according to the present invention. In the third embodiment described above, the lower holder 80 is integrally formed by insert molding together with the elastic contacts 8C1, 8C2, 8C3, and the elastic contacts 8C1, 8C2, 8C3 are formed in the window 81 The lower holder 80 and the click spring support plate 50 are separated from each other by bending the elastic contacts 8C1, 8C2 and 8C3 at a predetermined angle in advance, The lower holder 80 and the click spring support plate 50 may be formed as a lower holder (first holder) 80 'integrally formed with each other as shown in FIG. Likewise, the upper holder 60 and the cover 90 in the third embodiment may also be formed as an upper holder (second holder) 60 'integrated with each other as shown in Fig. The other configuration is the same as that of the third embodiment, and a description thereof will be omitted.

[Concept of the Invention]

Fig. 15 shows a configuration diagram of a rotary operation type electronic part for conceptualizing and explaining the above-described various embodiments and modified examples to which the bearing structure according to the present invention is applied. A pivoting operation shaft 100 of a cylindrical shape includes an operating portion 110 that receives a turning operation, a holding portion 120 whose diameter is smaller than that of the operating portion 110 and which extends in the same axis as the holding portion 120, And the boundary between the operating portion 110 and the holding portion 120 forms a stepped portion 100S. The holding ring 120 is inserted into the shaft hole 230 of the bearing from the one end side of the bearing 200 so as to be rotatable and the holding ring 400 fixed on the outer periphery of the rear end of the holding portion 120 is inserted into the bearing 200 are engaged with the outer peripheral edge of the shaft hole 230 at the other end. The driving unit 130 extending and protruding from the holding unit 120 rotates the rotor 700 in the electromechanical signal control unit 600 installed at the other end of the bearing 200. [ The electromechanical signal controller 600 includes a variable resistance mechanism for generating a resistance change due to sliding between a contact and a resistor by the rotation of the rotor 700 or a variable resistance mechanism for causing a contact / And controls the signal given to the terminal 6T by electromechanical control.

The electromechanical signal controller 600 includes a holder 6 and 6 'in the embodiment of FIGS. 1 and 4, a rotor 7 and 7', and a housing portion 22 for housing the rotors 7 and 7 ' And corresponds to a configuration including the upper holders 80 and 80 ', the lower holders 60 and 60' and the rotors 70 received therebetween in the embodiment of FIGS. 8 and 14, respectively.

The bearing structure of the present invention has the tapered surface 100T extending from the radial intermediate position of the stepped portion 100S of the pivotal operation shaft 100 to the outer peripheral surface of the holding portion 120, The ring spring 300 is pressed against the tapered surface 100T by the tapered surface 200T having a larger diameter toward the outside formed on the inner peripheral edge of the shaft hole 240 in the bearing cross section opposite to the bearing surface . The tapered surfaces 100T and 200T are angled with respect to each other so as to open toward the stepped portion 100S in the axial direction.

The ratio of distributing the external force given to the ring spring 300 from the tapered surface 200T to the axial component and the radial component can be changed by changing the tilt angle of the tapered surfaces 100T and 200T.

Claims

A bearing structure of a rotation-operated electronic component,
A rotation operation shaft including a cylindrical portion having an operating portion, a holding portion having a stepped portion formed from one end of the operating portion and having an outer diameter reduced and extending in the axial direction, and a driving portion further extended from the holding portion in the axial direction,
A bearing having a shaft hole through which the holding portion is inserted and in which the holding portion is rotatably held,
/ RTI >
And an electromechanical signal control section for performing signal control by the rotation of the rotor fixed to the drive section is provided at the other end of the bearing,
A first tapered surface extending from a radially intermediate position of the stepped portion to the outer peripheral surface of the holding portion is formed in the rotation operation shaft,
Wherein the bearing has a second tapered surface having an inner diameter larger toward the outside on the inner peripheral edge of the shaft hole at the one end of the bearing, and an annular ring spring inserted and cut between the first and second tapered surfaces is mounted And,
Characterized in that a retaining ring is mounted on an annular groove formed in the outer periphery of the end portion on the side of the drive portion of the retaining portion and engaged with the other end of the bearing to prevent the rotation operation shaft from falling out .

2. The bearing structure of the rotary operation type electronic part according to claim 1, wherein the first and second tapered surfaces are angled with respect to each other so as to be opened toward the stepped portion.

3. The bearing structure of the rotation-operated electronic part according to claim 1 or 2, wherein the electromechanical signal control part includes a rotation switch mechanism.

The bearing structure of the rotation-operated electronic part according to claim 1 or 2, wherein the electromechanical signal control part includes a variable resistance mechanism.

The bearing structure of the rotation-operated electronic part according to any one of claims 1 to 4, wherein the ring spring is formed of a metal spring material.