JP2024077605A - Knob mounting structure and electronic device - Google Patents

Abstract

[Problem] To provide a knob mounting structure that prevents a knob from coming off the shaft of a rotary electronic component, and prevents malfunctions in the mounting portion of the rotary electronic component even if the knob is pushed in. [Solution] A rotary electronic component 3 is mounted on a second side of the plate-shaped member 1a opposite to the first side, with a shaft 31 protruding from the through hole 12a to a first side, and the plate-shaped member 1a is provided with a claw slit 12b formed in an arc or ring shape centered on the axis CL1 of the shaft 31, a knob 2 having a claw portion 2b formed to engage with the plate-shaped member 1a, including a protruding portion 2b2 that hooks on a second side surface 12e2 of an outer bank portion 22 that is outside the claw slit 12b, and an arch portion 12d that connects an inner island portion 21 on the inside of the claw slit 12b and the outer bank portion 22. [Selected Figure] Fig. 6

Description

The present invention relates to a knob mounting structure and electronic device.

Patent document 1 describes a structure for attaching a knob to the shaft of a rotary electronic component such as a rotary volume. The structure described in patent document 1 prevents the knob from coming off the shaft by providing the knob with a claw portion that engages with the opposite side of the mounting hole in the operation plate.

JP 2001-126589 A

The knob mounting structure described in Patent Document 1 has a large depth because the rotary electronic component is mounted on a separate member disposed behind the operation plate.
Therefore, when attempting to mount a rotating electronic component on an operation plate in order to form a similar structure compactly, it is necessary to form an arc-shaped slit that serves as a passageway for the claw portion of the knob, surrounding the mounting portion of the rotating electronic component on the operation plate.

In this configuration, when the knob is turned at a large angle, the angle at which the slit is formed becomes large, and the mounting portion of the rotating electronic component is connected to the base material only within a small angular range, resulting in a decrease in bending rigidity.
Therefore, depending on the strength of the external force applied to press the knob, there is a risk of problems such as damage to the mounting portion of the rotating electronic component.

The problem that the present invention aims to solve is to provide a knob mounting structure and electronic device that can be formed compactly, that is unlikely to cause the knob to come off the shaft of the rotating electronic component, and that is unlikely to cause problems in the mounting part of the rotating electronic component even if the knob is pushed in.

In order to solve the above problems, the present invention has the following configurations 1) and 2).
1) A plate-shaped member;
A through hole provided in the plate-like member;
a rotary electronic component having a shaft attached to a second side of the plate-like member opposite to the first side such that the shaft protrudes from the through hole toward the first side of the plate-like member;
A claw slit is formed in the plate-like member in an arc shape or an annular shape centered on the axis of the shaft;
a knob attached to the shaft from the first side and having a claw portion formed to engage with the plate-like member, the claw portion including a base portion inserted into the claw slit and a protruding portion at a tip of the base portion that hooks onto a surface of the second side of an outer bank portion that is outside the claw slit of the plate-like member;
An arch portion connecting an inner island portion on the inner side of the claw slit and the outer bank portion;
The present invention relates to a knob mounting structure.
2) a housing;
1) The knob mounting structure according to the present invention;
Equipped with
a plate-like member in the knob mounting structure is the housing,
When the claw slit is formed in an arc shape, the rotary electronic component is a rotary volume or a rotary switch, and when the claw slit is formed in a ring shape, the rotary electronic component is an electronic device that is a rotary encoder.

According to one aspect of the present invention, the knob can be formed compactly, the knob is unlikely to come off the shaft of the rotating electronic component, and even if the knob is pushed in, malfunctions are unlikely to occur in the mounting portion of the rotating electronic component.

FIG. 1 is a perspective view showing an electronic device 91 according to a first embodiment of the present invention. FIG. 2 is a partial front view showing the vicinity of the knob 2 of the electronic device 91. As shown in FIG. FIG. 3A is a side view of the knob 2. FIG. 3B is a view taken along the arrow Y1 in FIG. 3A. FIG. 4 is a perspective view of the knob attachment portion 12 of the housing 1 of the electronic device 91, as viewed diagonally from the lower right front. FIG. 5 is a perspective view of the knob attachment portion 12 of the housing 1 as viewed diagonally from the lower left rear. FIG. 6 is a cross-sectional view of electronic device 91 taken along line S6-S6 in FIG. FIG. 7 is a cross-sectional view of the housing 1 taken along the line S7-S7 in FIG. FIG. 8 is a partial front view showing the vicinity of a knob 2A of an electronic device 91A according to a second embodiment of the present invention. FIG. 9 is a front view of the knob attachment portion 12A of the housing 1A of the electronic device 91A. FIG. 10 is a rear view of the knob attachment portion 12A of the housing 1A. FIG. 11 is a cross-sectional view taken along the line S11-S11 in FIG. FIG. 12 is a cross-sectional view taken along the line S12-S12 in FIG.

The knob mounting structure TK, which is a first aspect of an embodiment of the present invention, and electronic device 91 equipped with the same will be described as Example 1 with reference to Figs. 1 to 7. The knob mounting structure TKA, which is a second aspect, and electronic device 91A equipped with the same will be described as Example 2 with reference to Figs. 1 and 8 to 12. In the following description, the up, down, left, right, front, and back directions are defined by the directions of the arrows shown in Fig. 1.

Example 1
FIG. 1 is a perspective view showing an electronic device 91 according to a first embodiment of the present invention. FIG. 2 is a partial front view showing the vicinity of a knob 2 of the electronic device 91. FIG. 3A is a side view of the knob 2. FIG. 3B is a view taken along the arrow Y1 in FIG. 3A. FIG. 4 is a perspective view of a knob mounting portion 12 in a housing 1 of the electronic device 91, seen from a diagonally lower right front side. FIG. 5 is a perspective view of a knob mounting portion 12 in a housing 1, seen from a diagonally lower left rear side. FIG. 6 is a cross-sectional view of the electronic device 91 at a position corresponding to the S6-S6 position in FIG. 4. FIG. 7 is a cross-sectional view of the housing 1 at a position corresponding to the S7-S7 position in FIG. 6.

The electronic device 91 shown in FIG. 1 is, for example, a receiver. The electronic device 91 has a box-shaped housing 1 and a knob 2 attached to the front wall 1a of the housing 1 so as to protrude forward. The knob 2 turns a shaft 31 of a rotary electronic component 3 (see FIG. 6) such as a rotary volume or a rotary switch arranged inside the housing 1, and is rotatable around an axis CL1 extending in the front-rear direction. The housing 1 and the knob 2 are formed, for example, by injection molding of resin.

As shown in Figures 2 and 3A, the knob 2 is formed in a round barrel shape having a disk-shaped top wall portion 2f centered on the axis line CL2 and a peripheral wall portion 2a that is raised in an annular shape from the periphery of the top wall portion 2f.
A visible mark 2m is provided on the surface of the top wall 2f at one circumferential location near the periphery. A plurality of slightly recessed finger hook recesses 2c are formed at equal angular intervals on the outer circumferential surface of the peripheral wall 2a.
6, a cylindrical shaft receiving portion 2e having a shaft engaging portion 2d which is a bottomed hole centered on the axis line CL2 is formed inside the knob 2. An abutment portion 2d1 which protrudes onto the axis line CL2 is formed at the bottom of the shaft engaging portion 2d.

As shown in FIGS. 3A and 3B, the knob 2 has a claw portion 2b extending downward from the inside of the peripheral wall portion 2a at the circumferential position where the mark 2m is formed.
The claw portion 2b has a base portion 2b1, a protruding portion 2b2, a guide portion 2b3, and an inclined portion 2b4.

The base 2b1 is a rectangular portion extending parallel to the axis CL2 on the side opposite the top wall 2f. The protrusion 2b2 is a portion for hooking that protrudes radially outward at the tip of the base 2b1. The guide portion 2b3 is an inclined portion on the surface of the protrusion 2b2 on the side opposite the top wall 2f, the thickness of which becomes thinner toward the tip. The inclined portion 2b4 is a C-shaped chamfered portion formed on the circumferential edge of the protrusion 2b2.
The knob 2 is disposed so that the tip side of the peripheral wall portion 2a fits into a knob mounting portion 12 of the housing 1, which will be described next.

The knob mounting portion 12 of the housing 1 will be described with reference to Figures 2 and 4 to 7. The knob mounting portion 12 is the portion of the housing 1 where the rotary volume 3 and the knob 2 are attached.

As shown in FIGS. 4 and 5, the knob mounting portion 12 has a shaft hole 12a, an annular rib 12h, a claw slit 12b, and a recess 1a1.
The shaft hole 12a is a circular through hole centered on the axis line CL1, and as shown in Figure 6, the shaft 31 of the rotary volume 3 is inserted from the rear side (second side) to the front side (first side).
The annular rib 12h is an annular rib that is concentric with the shaft hole 12a, has a larger diameter than the shaft hole 12a, and protrudes forward.

The claw slit 12b is an arc-shaped slit having a predetermined width in the radial direction centered on the axis line CL1. The radial position and slit width of the claw slit 12b are set so that at least the base 2b1 of the claw portion 2b can pass through the slit without interference when the knob 2 attached to the shaft 31 is rotated.
That is, the base 2b1 of the claw portion 2b of the knob 2 attached to the shaft 31 is inserted into the claw slit 12b, allowing the base 2b1 to move when the knob 2 is turned.

The pawl slits 12b are formed in an angular range that allows at least rotation of the knob 2 in the circumferential direction.
In this example, the claw slits 12b are formed in a range of 240° excluding a range of 120° consisting of 60° on each side of the lower left and right with respect to the axis CL1.

As shown in Figures 4 and 5, the knob mounting portion 12 has a disk-shaped inner island portion 21 formed on its inner side by the claw slit 12b. The outer bank portion 22 is the portion on the outer side of the inner island portion 21, sandwiched between the claw slit 12b. In this example, the inner island portion 21 and the outer bank portion 22 are connected only at the connecting base portion 23 in the lower 120° range.

As shown in Figures 4 and 6, the inner wall 12c on the outer bank portion 22 side has a plurality of circumferential rib-like engagement flanges 12e that protrude radially inward toward the axis line CL1 and are formed intermittently in the circumferential direction.
The radial position at which the engagement flange portion 12e is formed is outside the base 2b1 of the claw portion 2b in the knob 2 attached to the shaft 31, and the inner tip edge portion corresponds to the position of the protrusion 2b2 of the claw portion 2b.
The knob attachment portion 12 also has a bridge portion 12BG that connects the inner island portion 21 and the outer bank portion 22 within the angular range in which the claw slits 12b are formed.
As shown in FIG. 6, the bridge portion 12BG has a plurality of arch portions 12d each having a radial cross-sectional shape that is U-shaped and protrudes rearward.

As shown in Figures 5 and 7, the bridge portion 12BG has an arc-shaped inner edge rib 12g formed on the inner island portion 21, an arc-shaped outer edge rib 12f formed on the outer bank portion 22, and multiple arch portions 12d connecting the tip of the inner edge rib 12g and the tip of the outer edge rib 12f. In this example, there are six multiple arch portions 12d.

As shown in FIG. 7, adjacent arch portions 12d are formed radially around axis CL1 at intervals of angles θb1 to θb5. In this example, angles θb1 to θb5 are equal to each other, for example, 30°. Angles θb1 to θb5 may be different.

The width of each of the plurality of arch portions 12d is formed to be an angle width of angles θc1 to θc6. The width of each of the plurality of arch portions 12d is narrower than the width of the protruding portion 2b2 of the claw portion 2b.
As shown in Figure 4, in injection molding in which the mold is opened and closed in the front-to-back direction, in order to allow the mold that forms the front side of the arch portion 12d to enter from the front side, the engagement flange portion 12e is missing an area corresponding to the planar shape of the arch portion 12d.

At the clockwise end (lower left end) of the claw slit 12b in FIG. 5, the arch portion 12d is not formed, and this portion is made into a reference opening 12k whose circumferential length is longer than the width of the claw portion 2b of the knob 2. At least at the reference opening 12k, the claw slit 12b has a radial width and circumferential length that allow the protrusion 2b2 to pass through when the claw portion 2b of the knob 2 is bent radially inward.

As shown in Figures 4 and 6, a guide portion 12e1 that slopes backward as it goes inward is formed on the front surface of the engagement flange portion 12e at the reference opening 12k. The guide portion 12e1 abuts against the protruding portion 2b2 of the claw portion 2b that enters the reference opening 12k from the front side, encouraging the claw portion 2b to bend inward, facilitating its entry.

2, 4, and 6, the knob mounting portion 12 of the front wall portion 1a formed as a plate-like member is formed with a circular recess 1a1 carved out toward the rear. The inner island portion 21 and the outer bank portion 22 correspond to the bottom wall of the recess 1a1.
The inner diameter of the recess 1a1 is slightly larger than the outer diameter of the open side of the peripheral wall portion 2a of the knob 2, so that the end portion of the open side of the knob 2 can enter the recess 1a1.

As shown in FIG. 2, multiple marks 1m are printed or engraved around the periphery of the recess 1a1 at a predetermined angular interval of angle θb. Each of the multiple marks 1m corresponds to the reference opening 12k, and this mark 1m is also referred to as the reference mark 1m1. In FIG. 2, the mark 1m is indicated as a black circle, and the reference mark 1m1 is indicated as a white circle. In FIG. 2, nine marks 1m are indicated within the range of angle θa.

As shown in FIG. 6, the rotary volume 3 is attached to the rear surface (second side surface) of the inner island portion 21, which is the front wall portion 1a. Specifically, the rotary volume 3 has its shaft 31 inserted into the shaft hole 12a from the rear side (second side) of the inner island portion 21. As a result, the male threaded portion 32a formed on the shaft root portion 32 at the base of the shaft 31 protrudes forward (first side) from the shaft hole 12a. The male threaded portion 32a protrudes forward and is exposed, and is fixed to the inner island portion 21 by tightening the lock nut 6 from the front side.

The shaft receiving portion 2e of the knob 2 is fitted from the front side onto the shaft 31. When the knob 2 is inserted a certain amount onto the shaft 31, the abutment portion 2d1 comes into contact with the tip surface of the shaft 31, and the knob 2 is positioned in the front-rear direction.
The shaft 31 has a so-called D-cut shape, and the shaft receiving portion 2 e also has a hole shape corresponding to the D-cut shape of the shaft 31 .

When the knob 2 is attached to the shaft 31 with the D-cut shape aligned in this way, the mark 2m of the knob 2 is set to a rotation position that corresponds to the reference mark 1m1 of the housing 1 when the rotary volume 3 is in the minimum position (throttling position) as shown in FIG. 2. The rotation position of the knob 2 where the mark 2m corresponds to the reference mark 1m1 is hereinafter referred to as the mounting position.

The specific procedure for mounting the knob 2 on the knob mounting portion 12 is as follows.
First, the shaft receiving portion 2e of the knob 2 is slightly inserted so that the D-cut shape is aligned with the tip of the shaft 31, and in this state, the knob 2 is rotated fully counterclockwise. As a result, the rotation position of the knob 2 becomes the mounting position as shown in FIG.

Next, the knob 2 is pushed in. In the attached position, the claw portion 2b of the knob 2 is in a position corresponding to the reference opening 12k. Therefore, when the knob 2 is pushed in, the protrusion 2b2 of the claw portion 2b abuts against the guide portion 12e1 of the engagement flange portion 12e in the reference opening 12k. Then, as the protrusion 2b2 is guided by the guide portion 12e1, the claw portion 2b is deflected radially inward, and when the protrusion 2b2 passes through the reference opening 12k and comes out to the back side (rear side) of the engagement flange portion 12e, the deflection of the claw portion 2b is eliminated and it returns to its original shape.

When the knob 2 is slightly pushed after the claw portion 2b has returned to its original shape, the abutment portion 2d1 of the shaft engagement portion 2d abuts against the tip of the shaft 31, restricting movement, and attachment to the knob attachment portion 12 is completed.
When an attempt is made to remove the knob 2 forward from the shaft 31 with a normal force, the protrusion 2b2 comes into contact with the rear surface 12e2 of the engagement flange 12e to restrict movement, thereby preventing the knob 2 from coming off the shaft 31. When an attempt is made to remove the knob 2 forward with intentionally excessive force, the claw portion 2b is forcibly deflected radially inward, and the engagement of the protrusion 2b2 with the engagement flange 12e is released, allowing the knob to be removed.

The engaging flange 12e is missing where the arch portion 12d is formed, but the circumferential width of the missing portion is set to be narrower than the width of the protruding portion 2b2 of the knob 2. Therefore, the claw portion 2b does not slip out forward at the missing portion of the engaging flange 12e.

The knob 2 attached to the knob attachment portion 12 has a rotatable range determined by the formation range of the claw slits 12b, and the rotary volume 3, which is a rotary electronic component to which the knob 2 is attached, performs an electrical operation according to the rotation angle of the knob 2.
Since the claw portion 2b of the knob 2 is formed with the inclined portion 2b4, even if the engaging flange portion 12e is formed intermittently in the circumferential direction, the protruding portion 2b2 is always guided to be caught by the engaging flange portion 12e when the knob 2 is turned. This makes the turning operation of the knob 2 smooth.

As described above, according to the mounting structure TK of the first aspect of the present invention, the knob 2 mounted on the knob mounting portion 12 does not easily come off the shaft 31 because the protruding portion 2b2 of the claw portion 2b engages with the engaging flange portion 12e of the outer bank portion 22 of the housing 1. In addition, the rotary volume 3, which is a rotary electronic component, is mounted on the inner island portion 21, which is the inner portion of the claw slit 12b. The inner island portion 21 is connected to the outer bank portion 22, which is located radially outward, by a plurality of arch portions 12d, sandwiching the claw slit 12b, so that it has high bending rigidity even if the claw slit 12b is formed. Therefore, even if the knob 2 is pushed in, the inner island portion 21, which is the mounting portion of the rotary volume 3, which is a rotary electronic component, is unlikely to be damaged or bent.
Furthermore, the mounting structure TK is compact since the rotary volume 3, which is a rotary electronic component, is mounted on the front wall portion 1a, which is a plate-like member with which the protruding portion 2b2 of the claw portion 2b engages.

Example 2
1, the reference symbols in parentheses indicate the reference symbols of components of an electronic device 91A according to the second aspect of the present invention. That is, the electronic device 91A has a housing 1A having a front wall portion 1Aa and a knob 2A instead of the housing 1 having a front wall portion 1a and the knob 2 in the electronic device 91. Also, an axis CL1A is the axis of the knob 2A that corresponds to the axis CL1 of the knob 2.

In electronic device 91A, the rotary electronic component in electronic device 91 is not a rotary volume 3 having a shaft 31 that rotates within a predetermined angle range, but a rotary encoder 3A in which shaft 31A rotates infinitely. Knob 2A is the same as knob 2, except that mark 2m is not provided, as shown in FIG. 8. That is, knob 2A has top wall 2Af, peripheral wall 2Aa, claw 2Ab, shaft engagement 2Ad, and shaft receiver 2Ae, which correspond to top wall 2f, peripheral wall 2a, claw 2b, shaft engagement 2d, and shaft receiver 2e in knob 2, as shown in FIG. 11. In addition, claw 2Ab has base 2Ab1, protrusion 2Ab2, guide 2Ab3, and inclined portion 2Ab4, which correspond to base 2b1, protrusion 2b2, guide 2b3, and inclined portion 2b4 in knob 2, respectively.

Next, the knob mounting portion 12A on the housing 1A of the electronic device 91A will be described with reference to Figures 8 to 12. The knob mounting portion 12A is a portion that corresponds to the knob mounting portion 2 on the housing 1, and is a portion on the housing 1A where the rotary encoder 3A and the knob 2A are attached.

The knob mounting portion 12A has a shaft hole 12Aa (see FIG. 11), a claw annular slit 12Ab, and a recess 1Aa1. The shaft hole 12Aa is a circular through hole centered on the axis line CL1A, and as shown in FIG. 11, the shaft 31A of the rotary encoder 3A is inserted from the rear side (second side) to the front side (first side).

The annular claw slit 12Ab is a circular slit (opening) with a predetermined width in the radial direction centered on the axis CL1A. The radial position and slit width at which the annular claw slit 12Ab is formed are set so that the base 2Ab1 of the claw portion 2Ab can pass through without interference at least when the knob 2A attached to the shaft 31A is rotated together with the shaft 31A. In other words, the annular claw slit 12Ab is inserted with the base 2Ab1 of the claw portion 2Ab of the knob 2A attached to the shaft 31A, and allows the base 2Ab1 to move when the knob 2A is rotated.

The disk-shaped inner island portion 21A formed inside the annular claw slit 12Ab is connected to the outer bank portion 22A, which is the outer portion of the annular claw slit 12Ab, by a bridge portion 12ABG. As shown in FIG. 11, the bridge portion 12ABG has multiple arch portions 12Ad whose radial cross-sectional shape is U-shaped and protrudes rearward.

As shown in Figures 9, 10, and 11, the inner wall 12Ac on the outer bank portion 22A side has multiple circumferential rib-like engagement flange portions 12Ae that protrude radially inward toward the axis line CL1A and are formed intermittently in the circumferential direction.
The radial position at which the engagement flange portion 12Ae is formed is outside the base 2Ab1 of the claw portion 2Ab on the knob 2A attached to the shaft 31A, and the tip edge portion which forms the inner edge corresponds to the position of the protrusion 2Ab2 of the claw portion 2Ab.

The knob attachment portion 12A also has a bridge portion 12ABG that connects the inner island portion 21A on the inside and the outer bank portion 22A on the outside, with the claw annular slit 12Ab in between.
10 and 11, the bridge portion 12ABG has an annular inner edge rib 12Ag formed on the inner island portion 21A, an annular outer edge rib 12Af formed on the outer bank portion 22A, and a plurality of arch portions 12Ad connecting the tip of the inner edge rib 12Ag and the tip of the outer edge rib 12Af. In this example, the plurality of arch portions 12d are 12 in number and spaced apart from each other in the circumferential direction.

As shown in FIG. 12, the circumferentially adjacent arch portions 12Ad are formed radially around the axis CL1A at intervals of angles θb1 to θb12. In this example, the angles θb1 to θb12 are equal to each other, 30°, but some or all of the angles θb1 to θb12 do not have to be equal.

The width of each of the multiple arch portions 12Ad is formed with an angular width of angles θc1 to θc12. The width of the multiple arch portions 12Ad is narrower than the width of the protruding portion 2Ab2 of the claw portion 2Ab. As shown in FIG. 9, in injection molding in which the mold is opened and closed in the front-to-rear direction, the engagement flange portion 12Ae is missing an area corresponding to the planar shape of the arch portion 12Ad so that the mold that forms the front side of the arch portion 12Ad can be inserted from the front side.

As shown in Figures 9 to 11, the annular claw slit 12Ab has a reference opening 12Ak at a location corresponding to one of the 12 arch portions 12Ad. The annular claw slit 12Ab has a radial width and circumferential length that allow the protrusion 2Ab2 to pass through at least the reference opening 12Ak when the claw portion 2Ab of the knob 2A is bent radially inward.

9 and 11, the front surface of the engagement flange 12Ae at the reference opening 12Ak is formed with a guide portion 12Ae1 that inclines backward as it goes inward. The guide portion 12Ae1 abuts against the protruding portion 2Ab2 of the claw portion 2Ab that enters the reference opening 12Ak from the front side, urging the claw portion 2Ab to bend inward, facilitating its entry. In this example, the tip edge 12Ae3 of the engagement flange 12Ae at the reference opening 12Ak is formed in a straight line perpendicular to the diameter. Of course, it may be formed in an arc shape like the tip edges of the other engagement flanges 12Ae. The shape of the tip edge 12Ae3 should be set in accordance with whether the tip shape of the protruding portion 2Ab2 at the claw portion 2Ab of the knob 2A is arc shape or straight shape. This reduces the amount of deflection of the claw portion 2Ab at the reference opening 12Ak, making it easier to attach the knob 2A and harder to remove.

As shown in FIG. 11, a rotary encoder 3A is attached to the rear surface (second side surface) of the inner island portion 21A, which is the front wall portion 1Aa, in the same manner as the rotary volume 3.

The shaft 31A of the rotary encoder 3A has a D-cut shape. The shaft receiving portion 2Ae of the knob 2A has a shaft engaging portion 2Ad that corresponds to the D-cut shape of the shaft 31A. After the knob 2A is slightly inserted at a position that corresponds to the D-cut shape of the shaft 31A, the knob 2A is rotated and positioned so that the claw portion 2Ab corresponds to the position of the reference opening 12Ak, and then the knob 2A is pushed in.
As a result, the claws 2Ab are guided by the guides 12Ae1 and bend radially inward, and when the protrusions 2Ab2 pass through the reference openings 12Ak and exit the rear side (rear side) of the engagement flange 12Ae, the claws 2Ab are released and return to their original shape. As shown in Fig. 11, the tip of the claws 2Ab that have passed through the engagement flange 12Ae is lower than the arch portion 12Ad and does not interfere with it. Therefore, the knob 2A can be rotated smoothly and infinitely in the clockwise and counterclockwise directions (see the arrow DR in Fig. 8).

In electronic device 91A, like electronic device 91, when an attempt is made to pull knob 2A forward from shaft 31A with normal force, protrusion 2Ab2 abuts against rear surface 12Ae2 of engagement flange 12Ae, restricting movement and preventing knob 2A from coming off shaft 31A. When an attempt is made to pull knob 2A forward with intentional excessive force, claw portion 2b is forcibly deflected radially inward, and protrusion 2b2 disengages from engagement flange 12e, allowing knob 2A to be pulled out.

The engaging flange 12Ae is missing where the arch portion 12Ad is formed, but the circumferential width of the missing portion is set to be narrower than the width of the protruding portion 2Ab2 of the knob 2A. Therefore, the claw portion 2Ab does not slip out forward at the missing portion of the engaging flange 12Ae.

Because the annular claw slit 12Ab is a circular slit, the knob 2A can be rotated infinitely. At that time, since the inclined portion 2Ab4 is formed on the claw portion 2Ab of the knob 2A, even if the engagement flange portion 12Ae is formed intermittently in the circumferential direction, the protrusion portion 2Ab2 is guided so that it always hooks onto the engagement flange portion 12Ae when the knob 2A is rotated. This allows for smooth infinite rotation of the knob 2A.

As described above, according to the mounting structure TKA of the second aspect of the present invention, the knob 2A mounted on the knob mounting portion 12A does not easily come off the shaft 31A because the protruding portion 2Ab2 of the claw portion 2Ab engages with the engaging flange portion 12Ae of the outer bank portion 22A of the housing 1A. In addition, the rotary encoder 3A, which is a rotating electronic component, is mounted on the inner island portion 21A, which is the inner portion of the claw annular slit 12Ab. The inner island portion 21A is connected to the outer bank portion 22A located radially outward across the claw annular slit 12Ab by a plurality of arch portions 12Ad, so that it has high bending rigidity even if the claw annular slit 12Ab is formed. Therefore, even if the knob 2A is pushed in, the inner island portion 21A, which is the mounting portion of the rotary encoder 3A, which is a rotating electronic component, is unlikely to be damaged or bent.
Furthermore, the mounting structure TKA is compact since the rotary encoder 3A, which is a rotary electronic component, is attached to the front wall portion 1Aa, which is a plate-like member with which the protrusions 2Ab2 of the claw portions 2Ab engage.

The embodiment described above is not limited to the configuration, and may be modified without departing from the spirit of the present invention.

Hereinafter, when the symbols of the second embodiment are written together with the symbols of the first embodiment, the position and number of the arch portions 12d (12Ad) in the bridge portion 12BG (12ABG) are not limited. In the first embodiment, the arch portion 12d is not provided near the end opposite the reference opening 12k in the claw slit 12b shown in Figs. 5 and 7 to avoid interference with the substrate housed in the housing 1. In the second embodiment, a plurality of arch portions 12Ad are provided around the entire circumference of the claw annular slit 12Ab. As a result, the inner island portion 21 (21A) is connected to the outer bank portion 22 (22A) with sufficient bending rigidity by the plurality of arch portions 12d (12Ad) formed corresponding to the angles θc1 to θc6 (θc1 to θc12). Therefore, even if the knob 2 (2A) is pressed in, the inner island portion 21 (21A), which is the mounting portion for the rotary volume 3 (rotary encoder 3A), which is a rotary electronic component, is unlikely to become deformed or otherwise defective.

The electronic device 91 (91A) is not limited to the receiver shown as an example, but may be various devices and equipment such as communication equipment, in-vehicle equipment, imaging equipment, audio equipment, etc.

As described above, the rotary electronic device includes both a shaft that can be continuously rotated through an infinite angle of 360° or more, and a shaft that can be reciprocated within an angle range of less than 360°. The knob mounting structure of the first aspect of the present invention rotates the knob 2 back and forth within a predetermined angle range of less than 360° according to the angle range of the claw slits 12b, regardless of the specifications of the rotary electronic device. Moreover, the knob mounting structure of the second aspect of the present invention allows the knob 2A to be rotated infinitely.
The rotary electronic components are not limited to rotary volumes, rotary switches, and rotary encoders, but include any components whose electrical characteristics change when a knob attached to a shaft is rotated.

1, 1A Housing 1a, 1Aa Front wall 1a1 Recess 1m Mark 1m1 Reference mark 12, 12A Knob mounting portion 12BG, 12ABG Bridge portion 12a, 12Aa Shaft hole 12b Claw slit 12Ab Annular claw slit 12c Inner peripheral wall 12d, 12Ad Arch portion 12e, 12Ae Engagement flange 12e1, 12Ae1 Guide portion 12e2, 12Ae2 Rear surface 12Ae3 Tip edge 12f, 12Af Outer edge rib 12g, 12Ag Inner edge rib 12h Annular rib 12k, 12Ak Reference opening 2, 2A Knob 2a, 2Aa Circumferential wall 2b, 2Ab Claw portion 2b1, 2Ab1 Base portion 2b2, 2Ab2 Protruding portion 2b3, 2Ab3 Guide portion 2b4, 2Ab4 Inclined portion 2c Finger recess 2d, 2Ad Shaft engagement portion 2d1 Abutment portion 2e, 2Ae Shaft receiving portion 2f, 2Af Top wall portion 2m Mark 21, 21A Inner island portion 22, 22A Outer bank portion 23 Connection base portion 3 Rotary volume (rotary electronic component)
31, 31A Shaft 32 Shaft root 32a Male thread 3A Rotary encoder 6 Lock nut 91, 91A Electronic device CL1, CL2, CL1A Axis TK, TKA Mounting structure θa, θb, θb1 to θb12, θc1 to θc12 Angle

Claims (6)

A plate-like member;
A through hole provided in the plate-like member;
a rotary electronic component having a shaft attached to a second side of the plate-like member opposite to the first side such that the shaft protrudes from the through hole toward the first side of the plate-like member;
A claw slit is formed in the plate-like member in an arc shape or an annular shape centered on the axis of the shaft;
a knob attached to the shaft from the first side and having a claw portion formed to engage with the plate-like member, the claw portion including a base portion inserted into the claw slit and a protruding portion at a tip of the base portion that hooks onto a surface of the second side of an outer bank portion that is outside the claw slit of the plate-like member;
An arch portion connecting an inner island portion on the inner side of the claw slit and the outer bank portion;
A knob mounting structure having the same. The claw slit has a peripheral rib-shaped engagement flange protruding inward from an inner peripheral wall of the outer bank portion,
2. The knob mounting structure according to claim 1, wherein the protruding portion of the claw portion is hooked onto the engaging flange portion to prevent the knob from coming off the shaft. The knob mounting structure according to claim 2, wherein, when viewed from the axial direction, the engaging flange is missing from the portion where the arch portion is formed, and the circumferential width of the arch portion is narrower than the width of the protrusion. The knob mounting structure according to claim 3, wherein the arch portion is not formed in an angle range greater than the width of the protrusion, and a reference opening is provided in the pawl slit such that the width of the pawl slit allows the protrusion to pass through. The knob mounting structure according to claim 4, wherein the claw slit is formed in the arc shape, and the range within which the knob can rotate is determined by the range within which the claw slit is formed. A housing and
A knob mounting structure according to any one of claims 1 to 5,
Equipped with
a plate-like member in the knob mounting structure is the housing,
An electronic device in which the rotary electronic component is a rotary volume or a rotary switch when the claw slit is formed in an arc shape, and the rotary electronic component is a rotary encoder when the claw slit is formed in an annular shape.

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