JP2001014985A - Rotation-operated encoder unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To generate an object signal, even in the case of rotating a rotary knob by mistake in depressing a push button switch. SOLUTION: A rotary knob 10 and a rotary encoder part 20 are formed as separate parts and connected by rollers 13, 21 detachable according to pressing operation to the rotary knob 10. In normal action, the rotation of the rotary knob 10 is transmitted to the rotary encoder part 20 by interlocking the rollers 13, 21 fitted to the rotary knob 10 and the rotary encoder part 20 respectively. In depressing a push button switch, the rotating action of the rotary knob 10 is not transmitted to the rotary encoder part 20 by detaching the rollers 13, 21 from each other.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rotary operation type encoder unit which generates a signal in accordance with the rotation of a rotary knob and operates a push button switch in response to pressing on the rotary knob.

[0002]

2. Description of the Related Art A rotary operation type encoder unit of this type is disclosed, for example, in Japanese Utility Model Laid-Open No. 5-55432 (hereinafter referred to as Conventional Example 1) and Japanese Patent Laid-Open Publication No. 10-326144 (hereinafter referred to as Conventional Example 2). Are included.

The rotary operation type encoder unit of the prior art 1 is provided as a rotary electronic component with a push button switch which has a simple structure, a small number of parts, and is easy to assemble.
It has a rotary switch that has a projection for pressing the push button switch and is rotatably mounted on itself. In particular, in the rotary operation type encoder unit of Conventional Example 1, a rotary encoder for detecting its own rotation is built in the rotary switch. The rotary operation type encoder unit of Conventional Example 1 having such a configuration can be operated by rotating the rotary knob of the rotary switch, and when the rotary switch is pressed, the protrusion of the rotary switch causes the push button switch to operate. Can be pressed.

On the other hand, the rotary operation type encoder unit of the prior art 2 is capable of operating not only a rotary encoder portion but also a switch portion by rotating and tilting an operation shaft provided with an operation knob. It is provided as a type electronic component, and has a structure in which one of the rotating shafts protruding from the rotating knob on both sides is connected to the rotary encoder unit and the other rotating shaft is incorporated in the switch unit. is there.

[0005]

As described above, Conventional Example 1
Also, in each of Conventional Example 2, the rotary encoder is formed integrally with a rotary knob (rotary switch). Since their main applications are remote controllers for televisions, computer peripherals such as mice, mobile phones, etc., measures were taken to reduce the number of parts in order to make them as small and easy as possible. It is also the result.

[0006] However, such a configuration is not suitable for large FAs.
Not suitable for equipment or OA equipment. As described above,
If the rotary knob and the rotary encoder are integrally formed, the whole unit tends to become large as a result. Moreover, in order to press the push button switch, such a large unit has to be pushed down, which makes it very difficult to handle.

Further, if the rotary knob and the rotary encoder are integrally formed, the rotary knob is erroneously rotated when the push button switch is pressed, and a signal corresponding to an unintended rotation state is generated. There is a possibility that the problem described above may occur. This is a problem not only in large devices such as FA devices, but also in the small devices described above.

Therefore, the present invention is not limited to the whole unit and is easy to handle. In addition, even if the rotary knob is erroneously rotated when the push button switch is pressed, a desired signal is generated. It is an object of the present invention to provide a rotary operation type encoder unit that can perform the operation.

[0009]

According to the present invention, in order to solve the above-mentioned problems, the rotary knob and the rotary encoder are formed as separate parts. In addition, in the normal operation, the rotation of the rotary knob is transmitted to the rotary encoder unit by a roller, a gear, and the like, and when the push button switch is pressed, the rollers and the like are separated from each other, so that the rotation operation is performed by the rotary encoder Not to be transmitted to any part.

Specifically, the present invention provides the following rotary operation type encoder unit as specific means for solving the above-mentioned problems.

That is, according to the present invention, as a first rotary operation type encoder unit, a rotary knob having a rotary knob shaft rotatably supported, connected to the rotary knob, and through rotation of the rotary knob shaft An encoder unit for detecting rotation of the rotary knob and generating a predetermined signal corresponding to the rotation of the rotary knob, and operated in response to the rotary knob being pressed in a pressing direction orthogonal to the rotary knob shaft. In a rotary operation type encoder unit including a push button switch for generating a switch signal, a fixed portion for supporting the encoder portion, the rotary knob, and the rotary knob shaft of the rotary knob rotatably supported and supported. A rotating knob support that is elastically supported so as to be movable in the pressing direction with respect to the fixed portion, and that the push button switch is pressed when pressed in the pressing direction. A rotary knob assembly provided with a pressing contact portion for performing a pressing operation in contact with a switch, and connecting the rotary knob shaft which is always at a predetermined position to the encoder portion, and from the predetermined position, the rotary knob shaft A rotary operation type encoder unit characterized by having a detachable connection mechanism that disconnects the connection when moved in the pressing direction.

Further, according to the present invention, as the second rotary operation type encoder unit, in the first rotary operation type encoder unit, the push button switch comprises:
A rotary operation type encoder unit is provided, which has a fixed relationship with respect to the fixing portion and is fixedly supported at a fixed position facing the pressing contact portion in the pressing direction.

Further, according to the present invention, as the third rotary operation type encoder unit, in the first or second rotary operation type encoder unit, the detachable connecting mechanism is a part of the rotary knob shaft. And a second connection portion provided on the encoder portion, wherein the first connection portion is connected to the second connection portion when the rotation knob shaft is at the predetermined position. The rotation of the rotary knob shaft and the rotation of the first connecting portion.
The rotary operation type encoder unit is transmitted to the connecting portion, while being separated from the second connecting portion in the pressing direction when the rotary knob shaft moves in the pressing direction.

According to the present invention, as a fourth rotary operation type encoder unit, in the third rotary operation type encoder unit, the first and second connecting portions are
Both are rollers made of a material having a large coefficient of friction, and when the rotary knob shaft is at the predetermined position, the first
The rotation operation type encoder unit is characterized in that the second connection portion rotates in accordance with the rotation of the first connection portion by the frictional contact between the second connection portion and the second connection portion.

According to the present invention, as a fifth rotary operation type encoder unit, in the third rotary operation type encoder unit, the first and second connecting portions are
Both are formed of gears, and the first and second connecting portions are engaged when the rotary knob shaft is at the predetermined position, so that the second connecting portion is rotated in accordance with the rotation of the first connecting portion. A rotary operation type encoder unit characterized by rotating is obtained.

According to the present invention, as a sixth rotary operation type encoder unit, in the first rotary operation type encoder unit, the rotary knob support is related to the fixed portion, and one end thereof is fixedly supported. The other end of the rotary knob support is provided so as to be movably supported in the pressing direction, and the other end of the rotary knob support is operated as the pressing contact portion. can get.

Further, according to the present invention, as the seventh rotary operation type encoder unit, the sixth rotary operation type encoder unit further includes a substrate having one surface on which the fixing portion is provided, and The knob support has the one end fixedly supported on the one surface with the other end floating from the substrate, and the push button switch includes:
A rotary operation type encoder unit is obtained, which is fixedly supported at a fixed position on the substrate facing the other end of the rotary knob support as the pressing contact portion in the pressing direction.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A rotary operation type encoder unit according to an embodiment of the present invention will be described below in detail with reference to the drawings.

Referring to FIGS. 1 and 2, a rotary operation type encoder unit according to the present embodiment includes a rotary knob 10.
And a rotary encoder unit 20 provided separately on the substrate 30.

The rotary knob 10 includes an operation unit 11 that is rotated and pressed, and a rotary knob shaft 12 serving as a rotation axis thereof.
And a rotation knob-side roller 13 provided at one end of the rotation knob shaft. Here, the rotation knob shaft 12 is rotatably supported by a rotation knob bearing 40 as described later, and the rotation knob side roller 13 always
It is at a predetermined position when viewed from 0.

On the other hand, the rotary encoder 20 has an encoder-side roller 21 corresponding to the rotary knob-side roller 13. In the present embodiment, the encoder-side roller 21 is located at substantially the same position as viewed from the substrate 30.
3 is in contact. However, as described later, the rotation knob 1
When 0 is pressed, it is separated.

In particular, in the present embodiment, the rotary knob-side roller 13 and the encoder-side roller 21 are formed of a material having a large coefficient of friction, such as rubber, for example. Is rotated, the encoder unit-side roller 21 rotates accordingly.

Therefore, when _a force fa is applied to the operating portion 11 of the rotary knob 10 and the rotary knob 10 is rotated in a state where the rollers are in contact with each other, the rotary knob shaft 12 is rotated accordingly, and one end of the rotary knob shaft 12 is rotated. The encoder unit-side roller 21 rotates through the rotation of the rotation knob-side roller 13 provided in the encoder. As a result, the rotation on the rotary knob 10 side is transmitted to the rotary encoder unit 20 side. As a result, the rotary encoder 20 generates a predetermined signal according to the rotation of the rotary knob 10. The connecting portion composed of the rollers 13 and 21 may be any as long as it can appropriately transmit the rotation of the rotary knob 10 to the rotary encoder 20. For example, a gear or the like is used instead of the rollers 13 and 21. be able to.

Further, the rotary operation type encoder unit according to the present embodiment includes the rotary knob bearing 40 that rotatably supports the rotary knob shaft 12 as described above.

This rotary knob bearing 40 is shown in FIGS.
, As seen from the top,
It is composed of a structure having a U-shaped portion having different lengths of the opposing sides. More specifically, the U-shaped portion stands perpendicular to the substrate 30. In addition, from a portion 41 connecting opposite sides of the U-shape, a bearing fixing portion 42 extends so as to be parallel to the substrate 30 and protrude inside the U-shape. The bearing fixing portion 42 is fixed to the substrate 30 by a bearing fixing screw 43, and the bearing fixing portion 42 and the U-shaped portion 41 are configured to have elasticity. Such a bearing fixing portion 42 and a U-shaped portion 41 can be obtained by, for example, bending and manufacturing one metal piece.

A bearing portion for bearing the rotary knob shaft 12 is provided on each of the opposite sides of the U-shape, and the rotary knob shaft 12 is fitted into the bearing portion. In addition, one end of the longer side of the opposite sides of the U-shape is connected to the protrusion 44 as shown in FIGS.
Therefore, in a plane perpendicular to the substrate 30, the shape is not rectangular but one corner is missing. From the protruding portion 44 on the substrate 30 side, a pressing contact portion 45 for pressing the push button switch 50 is provided so as to protrude in parallel with the substrate 30 and inside the U-shape.

As understood from this structure, the rotary knob bearing 40 has one end in the longitudinal direction fixed to the substrate 30 by the bearing fixing screw 43, while the other end in the longitudinal direction is not fixed at all. That is, the rotary knob bearing 4
0 has a kind of cantilever structure. In other words, the rotary knob bearing 40 is elastically supported so as to be movable in the pressing direction with respect to the substrate 30. Therefore, when the rotary knob 10 is pressed by receiving a force f _{b in} a direction perpendicular to the substrate 30, the rotary knob 10 moves with the bearing fixing portion fixed by the bearing fixing screw 43 as a fulcrum. The part 45 presses the push button switch 50 with a force f _b ′ in a direction perpendicular to the substrate 30. Further, the push button switch 50 generates a switch signal indicating that the push button switch is pressed by this operation.

Here, in the present embodiment, the rotary encoder section 20 is
The encoder unit fixing angle 22 is fixed to the substrate 30 by fixing screws 23. Therefore, the encoder unit-side roller 21 always stays at substantially the same position with respect to the substrate 30 irrespective of the operation of the rotary knob 10 side.

On the other hand, the rotation knob-side roller 13
In the direction perpendicular to 0, the encoder side roller 21
And is fixed to a rotary knob bearing 40 that is elastically movable in a direction perpendicular to the substrate 30 as described above.

Therefore, when the rotary knob bearing 40 is elastically moved in the direction perpendicular to the substrate 30 with the bearing fixing portion 42 as a fulcrum when the rotary knob 10 is pressed, the rotary knob-side roller 13 moves to the substrate side. As a result, the rotation knob-side roller 13 and the encoder unit-side roller 21 are separated from each other. That is, when the pressing contact portion 45 presses the push button switch 50,
The operation of the rotary knob 10 is performed by the rotary encoder 20.
Is not transmitted to Therefore, even when the rotation knob 10 is pressed by mistake, even if the rotation operation is mistakenly added to the pressing operation, the rotary encoder unit 20 does not detect the rotation due to the erroneous rotation operation. There is no problem that a signal corresponding to an unintended rotation state is generated.

These components are housed in a case 60. The case 60 and the substrate 30 have a substantially fixed relationship with each other in an actual use environment.
The case 60 is provided with a guide portion 61 for supporting the rotation knob 10 in a direction parallel to the substrate 30, and in cooperation with the rotation knob bearing 40, the rotation knob 10 is moved in a direction perpendicular to the substrate. Prevents wobbling. Further, the case 60 has an opening 62 through which a part of the operation unit 11 of the rotary knob 10 projects outside the case 60. In an actual use environment, the user can execute the above-described operation by pressing or rotating a part of the operation unit 11 protruding from the opening 62.

As described above, according to the present embodiment, the rotary knob 10 and the rotary encoder section 20 are separately provided, and the connection is made between the two rollers 1.
The rotation of the rotary knob 10 can be appropriately transmitted to the rotary encoder 20 during the rotation operation of the rotary knob 10, while the rotation of the rotary knob 10 can be appropriately transmitted. At the time of operation, the operation of the rotary knob is not transmitted to the rotary encoder unit 20, so that a malfunction that has conventionally occurred can be prevented.

Further, in the present embodiment, since the rotary knob 10 and the rotary encoder section 20 are separately provided, when it is necessary to replace one of the components during maintenance, the corresponding component is required. Only the rotary knob and the rotary encoder unit need not be replaced.

In addition, since the shape of the rotary knob, particularly the shape of the operation unit, has no relation to the operation of the rotary encoder, the degree of freedom in selecting the shape is large. Therefore, it is possible to prepare various variations as the design of the rotary knob and to cope with it.

The rotary operation type encoder unit according to this embodiment can be variously modified as described below under the concept of the present invention.

For example, in the above-described embodiment, the position where the push button switch 50 is provided is on the substrate 30 and at a position facing one end of the rotary knob bearing 40. The pressing contact portion 45 that presses the push button switch 50 by the pressing operation on the rotary knob 10 is provided at one end of the rotary knob bearing 40, but is limited to such a configuration. Not necessarily.

That is, the pressing contact portion 45 is connected to the rotary knob bearing 4
0 may be provided in another portion, and in that case, it is sufficient that the push button switch is provided at a position pressed by the pressing contact portion. For example, in the above-described embodiment, the pressing contact portion 45 is provided at one end of the rotary knob bearing 40 so as to protrude inside the U-shape, but is protruded outward from the same position. The push button switch may be provided at a position on the substrate corresponding to the pressed contact portion.

Further, a part of the operation part 11 of the rotary knob 10 may be handled as a pressing contact part. In this case, the push button switch is fixed by any fixing means provided below the substrate 30, and is pressed by the rotary knob 11 being pressed in a direction perpendicular to the substrate and moving in the pressing direction.

In these cases, the pressing contact portion has a rotary knob 10.
Alternatively, the rotary knob 10 and the rotary knob bearing 40 and the pressing contact portion are separately provided as long as they can perform an operation equivalent to the above-described operation. Needless to say, it is good.

In the above-described embodiment, the coupling mechanism for constantly transmitting the rotation operation of the rotary knob 10 to the rotary encoder unit 20 includes the rotary knob-side roller 13 and the encoder unit-side roller 21. However, the present invention is not limited to this. That is, it is sufficient that the rotary knob shaft 12 is always connected to the rotary encoder unit 20 side and the connection can be disconnected when the rotary knob 10 is pressed. For example, as described above, each roller is constituted by a gear, and the two gears are always meshed with each other to transmit the rotation and to disengage the gears according to the pressing operation. A similar function may be achieved by a simple mechanism.

[0041]

As described above, according to the present invention, the rotary knob shaft of the rotary knob is always connected to the rotary encoder side, while the connection is disconnected when the rotary knob is pressed. When the rotary knob is operated to rotate, the rotation of the rotary knob can be appropriately transmitted to the rotary encoder while the rotary knob is pressed. The operation of the rotary knob is not transmitted, so that a malfunction that has conventionally occurred can be prevented.

[Brief description of the drawings]

FIG. 1 is a sectional view of a main part of a rotary operation type encoder unit according to an embodiment of the present invention.

FIG. 2 is a cross-sectional view of the rotary operation type encoder unit shown in FIG. 1 when viewed from a line 2-2.

FIG. 3 is a sectional view of the rotary operation type encoder unit shown in FIG. 1 when viewed from a line 3-3.

FIG. 4 is a cross-sectional view of the rotary operation type encoder unit shown in FIG. 1 when viewed from line 4-4.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Rotation knob 11 Operation part 12 Rotation knob shaft 13 Rotation knob side roller 20 Rotary encoder part 21 Encoder part roller 22 Encoder part fixing angle 23 Fixing screw 30 Substrate 40 Rotation knob bearing 42 Bearing fixing part 43 Bearing fixing screw 45 Press contact part Reference Signs List 50 push button switch 60 case 61 guide part 62 opening

Claims (7)

[Claims] A rotation knob having a rotation knob shaft rotatably supported; and a rotation knob connected to the rotation knob, detecting rotation of the rotation knob through rotation of the rotation knob shaft, and responding to the rotation of the rotation knob. A rotary operation type encoder including: an encoder unit for generating a predetermined signal; and a push button switch that generates a switch signal by being operated in response to the rotation knob being pressed in a pressing direction orthogonal to the rotation knob axis. In the unit, a fixed portion that supports the encoder portion, the rotation knob, and the rotation knob shaft of the rotation knob are rotatably supported and elastically supported so as to be movable in the pressing direction with respect to the fixed portion. A rotary knob assembly comprising a rotary knob support and having a pressing contact portion for pressing and operating by pressing the push button switch when pressed in the pressing direction; The rotary knob shaft which is always in a predetermined position is connected to the encoder unit, and the connection mechanism is detachable when the rotary knob shaft moves in the pressing direction from the predetermined position. And a rotary operation type encoder unit. 2. The rotary operation type encoder unit according to claim 1, wherein the push button switch has a fixed relationship with respect to the fixed portion, and is fixedly supported at a fixed position facing the pressing contact portion in the pressing direction. A rotary operation type encoder unit characterized in that: 3. The rotary operation type encoder unit according to claim 1, wherein the detachable connection mechanism is provided on a first connection portion provided on a part of the rotary knob shaft and on the encoder portion. A second connecting portion, wherein the first connecting portion is in contact with the second connecting portion when the rotary knob shaft is at the predetermined position, and controls the rotation of the rotary knob shaft to the first connecting portion. The rotation operation type encoder unit transmits the rotation of the rotary knob to the second connecting portion, and separates from the second connecting portion in the pressing direction when the rotary knob shaft moves in the pressing direction. . 4. The rotary operation type encoder unit according to claim 3, wherein the first and second connecting portions are both rollers made of a material having a large coefficient of friction, and wherein the rotary knob shaft is at the predetermined position. Wherein the first and second connecting portions are brought into frictional contact with each other to rotate the second connecting portion in accordance with the rotation of the first connecting portion. 5. The rotary operation type encoder unit according to claim 3, wherein both the first and second connecting portions are formed of gears, and the first and second connecting portions are provided when the rotary knob shaft is at the predetermined position. The rotation operation type encoder unit, wherein the second connection portion rotates in accordance with the rotation of the first connection portion when the second connection portion is engaged. 6. The rotary operation type encoder unit according to claim 1, wherein one end of the rotation knob support is fixedly supported, and the other end of the rotation knob support is movably supported in the pressing direction. The rotary operation type encoder unit, wherein the other end of the rotary knob support operates as the pressing contact portion. 7. The rotary operation type encoder unit according to claim 6, further comprising a substrate having one surface on which the fixing portion is provided, wherein the rotation knob support has the other end floated from the substrate. The one end is fixedly supported on the one surface, and the push button switch is a fixed position on the substrate facing the other end of the rotary knob support as the pressing contact portion in the pressing direction. A rotary operation type encoder unit, which is fixedly supported by the rotary encoder.