JPH0356979Y2 - - Google Patents

Description

[Detailed Description of the Invention] The present invention relates to a rotary switch, in particular, which performs detent switching by rotating on one axis, and after exceeding a predetermined detent position and continuing to rotate in the same direction to switch contacts, It is an object of the present invention to provide a rotary switch that automatically returns to the original detent position by the elastic force of a spring when the shaft is released.

Hereinafter, embodiments of the present invention will be described based on the drawings.

1 to 6 each show an embodiment of the present invention, and FIG. 1 is a sectional view of a rotary switch according to an embodiment of the present invention, in which 1 is a shaft, and 1a is a shaft. The collar portion 1, 1b is a cutting portion with an oval cross section, and 1c is a connecting portion to another drive mechanism. 2 is a bearing, 3,
Reference numeral 4 denotes a divisible insulating case, which can be combined and integrated. Insulation case 3, 4
are the same, so to explain only the insulating case 3 using FIG. 2, 3a is a ridge provided on the outer periphery, 3b is a concave bottom surrounded by the ridge 3a, and the concave bottom 3b has: One common contact 5M integrated with terminal 5M', which also has other terminals 5a', 5b',
5c', 5d' and four fixed contacts 5a, 5b,
5c and 5d are arranged around the shaft hole 3c.

3e is a ridge provided on the same surface as the jetty 3a across the recess 3d, and 3a' is the recess 3d of the jetty 3a.
3f is a pair of locking pieces provided at both ends of the jetty 3e, and when both insulating cases 3 and 4 are combined facing each other, the ball 10 is The pressing spring 11 is fitted into the notches 3a', 3a' of both the insulating cases 3, 4, while the pressing spring 11 is locked with a pair of locking pieces 3f, 3f at the tips of the projections 3e, 3e. , ball 10 second
It is now being suppressed upwards in the figure. Reference numeral 7 denotes a rotating body made of an insulator that is housed in the above-mentioned insulating cases 3 and 4 and rotates together with the shaft 1. An oval hole 7a is inserted into the oval cut portion 1b of the shaft 1. As shown in FIG. 3A, on the circumferential surface of the rotating body 7, stopper projections 3h, 3h of the insulating cases 3, 4
a notch 7b that engages with to define the rotatable angle of the rotating body 7, and a convex portion 7 for performing detent operation.
c, recesses 7d ₁ and 7d ₂ , and locking pieces 7e ₁ and 7e ₂ form a cam surface. Rotating body 7 shown in Fig. 3A
In order to make the explanation easier to understand, the surface facing the insulating case 3 is shown as the front surface, but in reality,
The surface of the insulating case 3 shown in FIG. 2 and the surface of the rotating body 7 shown in FIG. 2 are mounted facing each other.

FIG. 6 is a plan view showing a state in which the rotating body 7 is fitted into the insulating case 3. As shown in the figure, when the rotating body 7 is fitted into the insulating case 3, one contact 8a of the movable contact 8 contacts one of the fixed contacts 5a, 5b, 5c, and 5d formed on the insulating case 3, and the other contact 8b, which can conduct with the contact 8a, contacts the common contact 5M also formed on the insulating case 3. It's becoming like that. Therefore, when the shaft 1 is rotated, the common contact 5M and any one of the fixed contacts 5a to 5d become electrically connected via the movable contact 8.
Contact switching is performed.

The movable contact 9 switches the contact of the switch inside the insulating case 4 in exactly the same manner.

Fig. 4 A, B, and C are a plan view, sectional view, and side view of the driver 13 equipped with the torsion coil spring 14 for automatic return, and Fig. 5 A, B are the insulating case housing the driver 13. 12 is a plan view of FIG. As shown in these figures, a spacer 13b with an oval hole 13c is provided in the center of the drive body 13, and this oval hole 13c is inserted into the oval cut portion 1b of the shaft 1. . Further, the driving body 13 is provided with a jetty 13a concentrically with the spacer 13b, and the torsion coil spring 14 is wound around the base of the spacer 13b in an annular recess 13d between the spacer 13b and the jetty 13a of the driving body 13. has been done.
Both free ends 14a of the torsion coil spring 14,
The middle part of 14b is clamped to step parts 13e ₁ and 13e ₂ provided at the open end of jetty 13a,
As a result, both free ends 14 of the torsion coil spring 14
a and 14b are opened at a predetermined angle.

A driving body 13 around which the torsion coil spring 14 can be wound.
As shown in FIG. 5, the jetty 1 of the insulating case 12
It is housed in an annular recess 12b surrounded by 2a. In this case, both free ends 1 of the torsion coil spring 14
4a and 14b are both step portions 13e ₁ and 1 of the driving body 13.
Both regulating walls 1 of the insulating case 12 are clamped to 3e ₂ .
Since the angle range is restricted to be narrower than the distance between 2d ₁ and 12d ₁ , when assembling the driving body 13 into the insulating case 12, as shown in FIG. After forming the torsion coil spring 14 into a unit, the unit body can be easily assembled into the insulating case 12 without bending the torsion coil spring 14.

In this embodiment, while the ball 10 is located in the detent position of either the recess 7d ₁ or 7d ₂ of the rotating body 7, both free ends 14a of the torsion coil spring 14, as shown in FIG. 14b is a regulating wall 1 formed at the end of the jetty 12a of the insulating case 12.
2d ₁ and 12d ₂ , and between the free end 14a and the regulating wall _12d1 and between the free end 14b and the regulating wall 1.
A predetermined interval is formed between 2d _{and 2} . In contrast, if the shaft 1 is rotated in either direction beyond the rotation angle between the two detent positions, the ball 1
0 is locked to either of the locking pieces 7e ₁ or 7e ₂ at both ends of the rotating body 7, as shown in FIG. , regulating wall 12d ₁ , 12 of insulating case 12
d It is set to be clamped to either one of ₂ .

Note that the insulating case 12 into which the driver 13 is fitted
is attached to one of the insulating cases 4 by a mounting plate 15 and an E-shaped washer 16, as shown in FIG.

The rotary switch according to this embodiment has the structure described above, and its operation will be explained next.

As shown in FIG. 6, when the ball 10 is fitted into the recess _7d2 of the rotating body 7, one contact 8a is placed on the fixed contact 5b of the insulating case 3, and the other contact 8b is placed on the common contact 5M. and both these contacts 5
The power is inserted between b and 5M.

In this state, when the shaft 1 is rotated, for example, the rotating body 7 is rotated clockwise in _FIG . 8a is the adjacent fixed contact 5c
Moving on, since the contact 8b slides on the common contact 5M, the connection between the two contacts 5c and 5M is closed. During this time, the driving body 13 also rotates, but as shown in FIG. 5A, both free ends 14a of the torsion coil spring 14,
14b are both the regulating walls 12 of the insulating case 12.
Since it is spaced apart from d ₁ and 12d ₂ , the torsion coil spring 14 does not function as a return spring during the detent operation.

From this state, when the shaft ₁ is further rotated in the same direction as shown in FIG. Since 8b slides on the common contact M, the contacts 5d and 5M are now closed. During this time, the torsion coil spring 1 rotates in the same direction as the driver 13, as shown in FIG.
One free end 14b of the drive body 13 is elastically engaged with the regulating wall _12d2 of the insulating case 13, and an elastic force in the direction of the arrow is stored in the drive body 13.

When the shaft 1 is released in this state, the driving body 13 rotates in the opposite direction due to the elastic force stored in the torsion coil spring 14, the ball 10 fits into the recess 7d ₁ , and the contact 8a
returns to the state before it was turned on from the fixed contact 5d to the fixed contact 5c.

In exactly the same way, when the shaft 1 is turned counterclockwise from the state where the ball 10 is fitted into the recess _7d1 in FIG. 6, the contact 8a moves from the fixed contact 5c to the fixed contact 5b, and then the same. When it rotates in the direction, it moves to the fixed contact 5a, and when the shaft 1 is released, it automatically returns to the original state where it was connected to the fixed contact 5b.

As explained above, according to the present invention, when switching contacts that involve detent operation, a detent mechanism consisting of a spring, a ball, and a cam surface is used, without involving a torsion coil spring, to provide a clear detent feel. In addition, when switching other contacts beyond a predetermined detent position, the elastic force of the torsion coil spring can be used to automatically return the contact. It is extremely convenient to apply the type switch to, for example, changing the filter operation of a video camera. In addition, since the torsion coil spring is housed and wound in an annular recess provided in the drive body, the opening angle of both free ends is regulated, so the torsion coil spring is assembled into the drive body in advance to form a unit. After that, the unit body can be assembled into the narrow space of the case without bending the torsion coil spring, and the assembly work efficiency can be improved.

[Brief explanation of the drawing]

The figures all relate to embodiments of the present invention; Figure 1 is a side sectional view of the entire rotary switch, Figure 2 A and B are a plan view and sectional view of the insulating case, and Figure 3 A and B are the rotating body. Plan view and side view of Figure 4 A, B,
C is a plan view, a sectional view, and a side view of the driving body;
Figure A is a plan view showing the driving body fitted into the insulating case, Figure 5 B is a plan view showing its operating state,
FIG. 6 is a plan view showing a state in which the rotating body is fitted into the insulating case. 1...Shaft, 2...Bearing, 3, 4...Insulation case, 5M...Common contact, 5a, 5b, 5c, 5d
... Fixed contact, 7 ... Rotating body, 7d ₁ , 7d ₂ ... Recess, 7e ₁ , 7e ₂ ... Locking piece, 8, 9 ... Movable contact, 10 ... Ball, 11 ... Pressing spring, 12...
Insulating case, 13...driver, 14...torsion coil spring, 14a, 14b...free end, 15...mounting plate, 16...E type washer.

Claims (1)

[Scope of utility model registration request] A rotating body comprising: a shaft inserted into a case; a rotating body that rotates integrally with the shaft and has a cam surface made of uneven parts on its periphery; and a ball pressed against the cam surface by a spring, and rotates the shaft. In a rotary switch whose contacts are switched with a detent sensation when operated, the shaft is provided with a driver that rotates together with the shaft, an annular recess is provided in the driver, and an outer wall of the annular recess is provided. A pair of step parts are formed by cutting out a part of the jetty forming the annular recess, and a torsion coil spring stored and wound within the annular recess is elastically locked to both the step parts. The free end is restricted to a predetermined opening angle, and the case is provided with a pair of restriction walls that face both free ends of the torsion coil spring in a spaced state, and while the shaft is rotated to generate a detent feeling, The torsion coil spring is made out of contact with the restriction wall, and when the shaft is rotated beyond a predetermined detent position, one of the free ends of the torsion coil spring is pressed against one of the restriction walls. A rotary switch characterized in that it is configured to be locked so that switching of a contact other than the contact is performed.