JP2022099872A - push button - Google Patents

Abstract

To provide a push button that allows a user to clearly recognize that the user have pushed the push button.SOLUTION: A button body 2 is supported so as to be pushed and rotated. A protrusion member 30 is provided on the button body 2 and has a slope 40 formed so as to be inclined in the circumferential direction of the button body 2 with respect to the direction along the stroke direction. When the button body 2 is pushed in, a guide member 10 guides the protrusion member 30 in the circumferential direction of the button body 2 while contacting the slope 40 of the protrusion member 30. The pressing member 20 is provided on the button body 2, and the switch is pressed by pushing the button body 2. The button body 2 rotates as the protrusion member 30 is guided by the guide member 10.SELECTED DRAWING: Figure 2

Description

The present invention relates to a push button.

Patent Document 1 discloses a switch element capable of an input operation for pushing the operation knob downward and an input operation for rotating the operation knob. Patent Document 2 discloses a rotary push switch device in which a push knob interlocks and pushes when a rotary push knob is pushed, and the push knob interlocks and does not rotate when the rotary push knob is operated in a rotary manner.

Japanese Unexamined Patent Publication No. 2015-103509 Japanese Unexamined Patent Publication No. 2004-241317

For example, when it is difficult to visually recognize the installation position and function of the push button, and the user cannot clearly recognize that the desired push button has been pushed, the push button may be operated incorrectly. In the technique according to the above-mentioned patent document, since the member is simply pushed when the pushing operation is performed, there is a possibility that the user cannot clearly recognize that the desired push button is pushed.

In view of the above problems, it is an object of the present invention to provide a push button capable of clearly recognizing that the push button has been pushed.

INDUSTRIAL APPLICABILITY The present invention includes a button body that is supported so that it can be pushed and rotated, and a button body that is provided on the button body and has a direction along a first direction in which the button body is pushed. When the button body is pushed in, the protrusion member having a slope formed so as to be inclined in the circumferential direction is in contact with the slope of the protrusion member, and the protrusion member is guided in the circumferential direction of the button body. It has a guide member and a push member provided on the button body and pressing a switch by pushing the button body, and the button body is guided by the guide member. Provides a push button that rotates.

According to the present invention, it is possible to provide a push button capable of clearly recognizing that the push button has been pushed.

It is a figure which shows the push button which concerns on Embodiment 1. FIG. It is a figure which shows the push button which concerns on Embodiment 1. FIG. It is a figure which shows the neighborhood of the protrusion member and the guide member which concerns on Embodiment 1. FIG. It is a figure which shows the operation of the push button which concerns on Embodiment 1. FIG. It is a figure which shows the operation of the push button which concerns on Embodiment 1. FIG. It is a figure for demonstrating the arrangement between a pressing member and a switch which concerns on Embodiment 1. FIG. It is a figure for demonstrating the arrangement between a pressing member and a switch which concerns on Embodiment 1. FIG. It is a figure which shows the protrusion member which concerns on the 1st modification of Embodiment 1. It is a figure which shows the protrusion member which concerns on the 2nd modification of Embodiment 1. FIG. It is a figure which shows the protrusion member which concerns on the 3rd modification of Embodiment 1. FIG. It is a figure which shows the push button which concerns on Embodiment 2. It is a figure which shows the operation of the push button which concerns on Embodiment 2. FIG. It is a figure which shows the operation of the push button which concerns on Embodiment 2. FIG. It is a figure which shows the push button device which concerns on Embodiment 3. FIG.

(Embodiment 1)
Hereinafter, embodiments of the present invention will be described with reference to the drawings. The substantially same components are designated by the same reference numerals.

1 and 2 are views showing a push button 1 according to the first embodiment. FIG. 1 shows a perspective view of the push button 1 according to the first embodiment, and FIG. 2 shows a side view of the push button 1 according to the first embodiment.

The push button 1 has a button body 2, a guide member 10 (10A, 10B), a push member 20, and a protrusion member 30 (30A, 30B). Although two protrusion members 30A and 30B are shown in FIG. 1, the number of protrusion members 30 is arbitrary. Further, although two guide members 10A and 10B are shown in FIG. 1, the number of guide members 10 is arbitrary. The number of guide members 10 may be the same as the number of protrusion members 30. These things are the same in other embodiments described later.

When the push button 1 (button body 2) is pushed in the direction indicated by the arrow A in FIGS. 1 and 2, the push member 20 moves toward the switch 4, so that the push member 20 pushes the switch 4. As a result, the switch 4 operates and a predetermined function is executed. Further, as will be described later, in the present embodiment, when the push button 1 (button body 2) is pushed in the direction of the arrow A, the push button 1 (button body 2) has a cylindrical shape as shown by the arrow Br. The button body 2 is configured to rotate along the circumferential direction. Therefore, when the push button 1 (button body 2) is pushed in, it advances in the direction of arrow A while rotating in the direction of arrow Br. The direction indicated by the arrow A, that is, the direction in which the button body 2 is pushed is referred to as a stroke direction (first direction). Further, the direction indicated by the arrow Br is referred to as a rotation direction.

Here, for convenience of explanation, the XYZ orthogonal coordinate axes are introduced. 1 and 2 show a right-handed XYZ coordinate system. The Y-axis direction corresponds to the direction along the stroke direction. The stroke direction corresponds to the −Y direction. Further, the rotation direction of the push button 1 corresponds to the direction along the ZX plane. Further, when the button body 2 is viewed from the + Y side, the rotation direction is counterclockwise.

The button body 2 has a cylindrical shape. The button body 2 is formed in a circular shape when viewed in the direction of arrow A (-Y direction). The user brings a finger or the like into contact with the top surface 2a formed on the + Y side of the button body 2 and pushes the button body 2 in the direction of arrow A (-Y side). The top surface 2a may be subjected to fine knurling. Since the top surface 2a is knurled, the user can feel that the button body 2 is rotating with a stronger tactile sensation. Further, a protrusion member 30 and a pressing member 20 are provided on the bottom surface 2b of the button body 2. The protrusion member 30 and the pressing member 20 may be integrally formed with the button body 2.

Further, the button body 2 is supported so that it can be pushed and rotated. For example, the button body 2 may be supported by the support member 6 so as to be able to push and rotate. As described above, the pushing motion is the motion in the direction of the arrow A, and the rotational motion is the motion in the direction of the arrow Br. The support member 6 may be, for example, the upper surface of a housing for accommodating the push button 1. The support member 6 may be formed with a hole having a shape corresponding to the circular shape of the button body 2, and the button body 2 is pushed in by sliding the hole and the side surface 2c of the button body 2. And rotational operation may be supported. The method in which the support member 6 supports the button body 2 is not limited to such a configuration. For example, the support member 6 may support the central axis (rotational axis) provided on the button body 2.

The pressing member 20 presses the switch 4 when the button body 2 is pushed. In the first embodiment, the switch 4 is arranged on the −Y side of the pressing member 20. The pressing member 20 according to the first embodiment is formed so as to extend from the bottom surface 2b of the button body 2 to the side of the switch 4, that is, in the −Y direction. When the button body 2 is pushed in the direction of arrow A, that is, in the −Y direction, the pressing member 20 also moves in the direction of arrow A, that is, in the −Y direction. As a result, the pressing member 20 presses the switch 4 in the direction of arrow A, that is, in the −Y direction. Further, an inclined surface 22 is provided on the −Y side of the pressing member 20, that is, a portion facing the switch 4. When the pressing member 20 presses the switch 4, any position of the inclined surface 22 may come into contact with the switch 4.

The protrusion members 30 (30A, 30B) are formed so as to project from the bottom surface 2b of the button body 2 to the side of the switch 4, that is, in the −Y direction. Further, a hook portion 32 that can be engaged with the guide member 10 may be formed at the tip of the protrusion member 30. Further, in FIG. 1, two protrusion members 30A and 30B are provided at positions facing each other on the bottom surface 2b of the button body 2 with the center of the bottom surface 2b interposed therebetween. For convenience, it is assumed that two protrusion members 30A and protrusion members 30B are provided along the X-axis direction in the initial state. A protrusion member 30A is provided on the + X side and a protrusion member 30B is provided on the −X side with respect to the center of the circular bottom surface 2b. Further, a slope 40 is formed on the protrusion member 30.

The guide member 10 (10A, 10B) is provided in the vicinity of the protrusion member 30. The guide member 10A is provided in the vicinity of the protrusion member 30A, and the guide member 10B is provided in the vicinity of the protrusion member 30B. Further, in FIG. 1, the guide member 10 is formed in a substantially arc shape. The guide member 10 is provided between the two protrusion members 30 along the circumferential direction of the button body 2. However, the guide member 10 may have a shape such that it is arranged only in the vicinity of the corresponding protrusion member 30. The guide member 10 may be fixed to, for example, a housing that accommodates the push button 1. That is, the guide member 10 may be fixed to the support member 6 that supports the button body 2 with 0 degrees of freedom. As will be described later, the guide member 10 guides the protrusion member 30 in the direction of arrow B. As will be described later, when the button body 2 is pushed in, the guide member 10 guides the protrusion member 30 in the circumferential direction of the button body 2 while contacting the slope 40 of the protrusion member 30. As the protrusion member 30 moves in the direction of arrow B, the button body 2 rotates in the direction of arrow Br. The direction of the arrow B is the direction corresponding to the direction of the arrow Br.

FIG. 3 is a diagram showing the vicinity of the protrusion member 30 and the guide member 10 according to the first embodiment. The protrusion member 30 has a slope 40. The slope 40 is formed so as to be inclined in the circumferential direction of the button body 2 with respect to the direction along the stroke direction (Y-axis direction). In other words, the slope 40 is formed so as to be inclined in the direction opposite to the rotation direction with respect to the Y-axis direction when viewed from the side opposite to the button body 2. In other words, the slope 40 is formed so as to be inclined in the direction of arrow Bx (+ Z direction in FIG. 3), which is the direction opposite to the direction of arrow B (-Z direction in FIG. 3) when viewed from the −Y side. ing.

Further, an inclined surface 12 may be formed on the surface of the guide member 10 facing the protrusion member 30. The inclined surface 12 is formed so as to be inclined to the same side as the inclined surface 40 of the protrusion member 30. Further, preferably, the inclination of the inclined surface 12 is larger than the inclination of the inclined surface 40.

When the button body 2 is pushed in the direction of the arrow A, the protrusion member 30 also moves in the direction of the arrow A in conjunction with the push. As a result, the tip 12a of the guide member 10 abuts on the slope 40. Further, when the button body 2 is pushed in the direction of the arrow A and the protrusion member 30 moves in the direction of the arrow A, the slope 40 slides the tip 12a of the guide member 10 in the direction of the arrow C. Then, due to the inclination of the slope 40, the protrusion member 30 moves not only in the direction of arrow A but also in the direction of arrow B.

That is, when the button body 2 is pushed in, the guide member 10 guides the protrusion member 30 in the circumferential direction (direction of arrow B) while contacting the slope 40. In other words, when the button body 2 is pushed in, the guide member 10 makes contact with the slope 40 and causes the protrusion member 30 to move in the direction of arrow B, that is, in the direction opposite to the direction in which the slope 40 is tilted (direction of arrow Bx). I will guide you to. As a result, the button body 2 rotates in the direction of the arrow Br in conjunction with the operation of the protrusion member 30. Therefore, when the button body 2 is pushed in, the button body 2 rotates in the direction of the arrow Br while moving in the direction of the arrow A. That is, when the button body 2 is pushed in, the button body 2 rotates counterclockwise when viewed from the + Y side while moving in the direction of the arrow A.

Here, let θ be the inclination angle of the slope 40, which is the inclination angle in the circumferential direction with respect to the direction along the Y-axis direction. In this case, when the button body 2 is pushed by a certain pushing amount (pushing length) S, the larger the inclination angle θ, the larger the moving amount of the protrusion member 30 in the circumferential direction (direction along the ZX plane). Therefore, when the button body 2 is pushed by the pushing amount S, the larger the tilt angle θ, the larger the rotation amount R. For example, when the button body 2 is pushed by the pushing amount S, the rotation amount R can be proportional to S * tan θ.

Further, the hook portion 32 is formed so as to project toward the guide member 10 along the ZX plane at the tip of the protrusion member 30. When the button body 2 tries to move to the + Y side, that is, to the side opposite to the pushing direction, the hook portion 32 abuts on the bottom surface 10b on the −Y side of the guide member 10. As a result, the movement of the button body 2 to the + Y side is restricted. Therefore, it is possible to prevent the button body 2 from being detached from the housing or the like in which the push button 1 is housed.

The push button 1 may have an urging member. The urging member is configured to move the button body 2 to its original position when the user stops pushing the button body 2 and the pushing operation to the button body 2 is released. The urging member may be formed of an elastic member such as a spring. The urging member may urge the button body 2 or the protrusion member 30 in a direction opposite to the rotation direction of the button body 2 (direction of arrow Br in FIG. 3). As a result, when the pushing operation to the button body 2 is released, the protrusion member 30 is urged in the direction opposite to the arrow B. Then, the slope 40 slides the tip 12a of the guide member 10 in the direction opposite to the arrow C. As a result, the button body 2 moves to the + Y side while rotating clockwise when viewed from the + Y side.

4 and 5 are diagrams showing the operation of the push button 1 according to the first embodiment. The operation of the push button 1 will be described with reference to FIGS. 2, 4, and 5. It is assumed that the button body 2 is pushed in the direction of the arrow A from the state shown in FIG. Then, as shown in FIG. 4, the protrusion member 30A is guided by the guide member 10A and moves in the direction of the arrow Ba, as described above. Similarly, on the −X side of the protrusion member 30A, the protrusion member 30B is guided by the guide member 10B and moves in the direction of the arrow Bb. Therefore, the button body 2 rotates counterclockwise when viewed from the + Y side, that is, in the direction of the arrow Br. Further, since the button body 2 is pushed in the direction of the arrow A, the pressing member 20 moves in the −Y direction, that is, in the direction indicated by the arrow Ac, and approaches the switch 4. Further, at this time, since the button body 2 rotates counterclockwise when viewed from the + Y side, the pressing member 20 also rotates counterclockwise when viewed from the + Y side.

It is assumed that the button body 2 is further pushed in the direction of the arrow A from the state shown in FIG. Then, as shown in FIG. 5, as described above, the protrusion member 30A is guided by the guide member 10A and further moves in the direction of the arrow Ba. Similarly, on the −X side of the protrusion member 30A, the protrusion member 30B is guided by the guide member 10B and further moves in the direction of the arrow Bb. Therefore, the button body 2 further rotates counterclockwise when viewed from the + Y side, that is, in the direction of the arrow Br. Further, since the button body 2 is pushed in the direction of the arrow A, the pressing member 20 moves in the −Y direction, that is, in the direction indicated by the arrow Ac. Then, the pressing member 20 presses the switch 4 in the −Y direction, that is, in the direction indicated by the arrow Ac. At this time, since the button body 2 rotates counterclockwise when viewed from the + Y side, the pressing member 20 also rotates counterclockwise when viewed from the + Y side.

As described above, in the push button 1 according to the first embodiment, when the button body 2 is pushed in, the slope 40 of the protrusion member 30 slides on the guide member 10, and the guide member 10 guides the protrusion member 30. , The button body 2 is configured to rotate. As a result, the user who presses the push button 1 can tactilely sense that the button body 2 has rotated when the button body 2 is pressed.

Here, if the button body does not rotate, the user determines whether or not the button body is pressed only by detecting the movement of the button body in the stroke direction. If the user cannot clearly recognize that the desired push button has been pressed, such as when it is difficult to visually recognize the installation position and function of the push button, the push button may be operated incorrectly.

On the other hand, in the present embodiment, the user can sense the feeling that the button body 2 rotates in conjunction with pressing the button body 2. That is, when the button body 2 is pushed in, the user senses that the button body 2 moves not only in the stroke direction but also in the rotation direction. This increases the sensation that the user can perceive when the button body 2 is pressed. Therefore, the user can more clearly recognize that the button body 2 has been pressed.

The rotation direction of the button body 2 can be changed by changing the inclination direction of the slope 40 of the protrusion member 30. Specifically, in the example shown in FIG. 3, the slope 40 is formed so as to be inclined in the + Z direction when viewed from the −Y side. As a result, when the button body 2 is pushed in, the protrusion member 30 is guided in the −Z direction by the guide member 10, and the button body 2 rotates counterclockwise when viewed from the + Y side.

On the other hand, contrary to the example of FIG. 3, the slope 40 may be formed so as to be inclined in the −Z direction (opposite to the arrow Bx) when viewed from the −Y side. As a result, when the button body 2 is pushed in, the protrusion member 30 is guided in the + Z direction (in the direction opposite to the arrow B) by the guide member 10. Therefore, the button body 2 rotates clockwise when viewed from the + Y side.

Then, the two push buttons 1 having different rotation directions may be arranged side by side in the housing. As a result, when the user presses the two push buttons 1, the user can tactilely sense the rotation in different rotation directions. Therefore, the user can distinguish between the two push buttons 1 by tactile sensation. That is, the user can distinguish between the two push buttons 1 simply by pressing the push button 1 without visually recognizing the push button 1.

Further, the functions of the switches 4 operated by the above two push buttons 1 may be different from each other. That is, the function of the switch 4 corresponding to each of the two push buttons 1 may be associated with the rotation direction of each of the two push buttons 1. For example, the switch 4 corresponding to the push button 1 rotating counterclockwise may activate the UP operation, and the switch 4 corresponding to the push button 1 rotating clockwise may activate the DOWN operation. With this configuration, when the push button 1 is pressed, the user can recognize the function corresponding to the push button 1 by tactile sensation. Therefore, it is possible to suppress a user's mistake in pressing the push button 1. In particular, even when the user cannot visually recognize the push buttons 1, the user can recognize the functions corresponding to the plurality of push buttons 1 arranged side by side.

As another means for making the user recognize that the push button 1 is pushed, for example, a method of giving vibration to the push button 1 when the push button 1 is pushed may be adopted. In such a method, a mechanism for giving vibration to the push button 1 is required, and the structure of the device becomes complicated. On the other hand, in the first embodiment, by forming the protrusion member 30 having the slope 40 on the button body 2, the button body 2 can be rotated when the button body 2 is pushed in. As described above, the simple structure such as the protrusion member 30 allows the user to clearly recognize that the push button 1 has been pushed.

Further, in the first embodiment, by forming the slope 40 on the protrusion member 30 on which the hook portion 32 is formed to prevent the hook portion 32 from being detached, the button body 2 can be rotated when the button body 2 is pushed in. As described above, the structure in which the protrusion member 30 is provided with a mechanism for preventing detachment and a mechanism for rotating the button body 2 makes it clear that the user has pushed the push button 1 with a simpler structure. Can be recognized.

Further, in the present embodiment, when the button body 2 is pushed in, the button body 2 rotates, so that the pressing member 20 also rotates in conjunction with the rotation of the button body 2. Utilizing this, the degree of freedom in design such as the arrangement of the switch 4 can be increased. This will be described with reference to FIGS. 6 and 7.

6 and 7 are diagrams for explaining the arrangement between the pressing member 20 and the switch 4 according to the first embodiment. FIG. 6 shows a case where the facing surface 20a of the pressing member 20 facing the switch 4 is flat, that is, parallel to the ZX plane. In this case, in the initial state, the distance between the facing surface 20a of the pressing member 20 and the switch 4 is constant at L. Therefore, the pushing amount (stroke) for pushing the button body 2 from the initial state until the pushing member 20 pushes the switch 4 is constant at L.

FIG. 7 shows a case where the inclined surface 22 is provided on the surface of the pressing member 20 facing the switch 4. In this case, in the initial state, the distance between the inclined surface 22 of the pressing member 20 and the switch 4 can take any value from L1 to L2. Here, L1 is the shortest distance between the inclined surface 22 and the switch 4, and L2 is the longest distance between the inclined surface 22 and the switch 4.

In this case, as in the state (A), when the button body 2 is pushed by the pushing amount L1, the pushing member 20 is the switch 4 at the tip of the pushing member 20, that is, on the most side of the switch 4 of the inclined surface 22. Can be pressed. Further, in the first embodiment, since the pressing member 20 rotates with the rotation of the button body 2, the inclined surface 22 also rotates. Therefore, as in the state (B), the pressing member 20 can be configured to come into contact with the switch 4 for the first time at an arbitrary position on the inclined surface 22. In this case, the pushing amount until the pushing member 20 first contacts the switch 4 can be an arbitrary amount from L1 to L2. Therefore, it is possible to improve the degree of freedom in designing the pushing amount until the switch 4 is pressed and the degree of freedom in designing between the switch 4 and the pressing member 20.

Further, as will be described later, by changing the inclination angle of the slope 40, the tactile sensation received by the user when the user presses the button body 2 changes. That is, as will be described later, even when the button body 2 is pushed in the same manner, the amount of rotation increases as the inclination angle with respect to the Y-axis direction increases, and the weight (resistance force) against the pushing operation increases. Therefore, by adjusting the tilt angle, the tactile sensation when the button body 2 is pressed can be appropriately adjusted.

<Modified example of the first embodiment>
Next, a modified example of the first embodiment will be described. In the modified example of the first embodiment, the slope 40 of the protrusion member 30 has a plurality of slope portions 42 having different inclination angles.

FIG. 8 is a diagram showing a protrusion member 30X according to the first modification of the first embodiment. The slope 40 of the protrusion member 30X according to the first modification has a slope portion 42A (first slope portion) and a slope portion 42B (second slope portion). The slope portion 42B is provided on the + Y side of the slope portion 42A, that is, on the side opposite to the stroke direction. Assuming that the inclination angle of the slope portion 42A is θa and the inclination angle of the slope portion 42B is θb, θa> θb. That is, the inclination angle θb of the slope portion 42B is smaller than the inclination angle θa of the slope portion 42A.

Therefore, the amount of rotation when the button body 2 is pushed in by the amount S when the guide member 10 is in contact with the slope portion 42A is the amount of push in the button body 2 when the guide member 10 is in contact with the slope portion 42B. It is larger than the amount of rotation when only S is pushed in. That is, while the button body 2 is pushed in from the initial state and the guide member 10 is in contact with the slope portion 42A, the user senses the rotation of the button body 2 by a large amount of rotation with respect to the pushed amount. On the other hand, when the button body 2 is pushed in and the guide member 10 is in contact with the slope portion 42B, the user can rotate the button body 2 with respect to the pushing amount as compared with the case where the guide member 10 is in contact with the slope portion 42A. I feel like I'm getting smaller.

Further, the weight (resistance force) for the pushing motion felt by the user when the guide member 10 is in contact with the slope portion 42A is the weight for the pushing motion felt by the user when the guide member 10 is in contact with the slope portion 42B. Greater than (resistance). Therefore, when the guide member 10 is in contact with the slope portion 42A, the user feels a great resistance to the pushing operation. On the other hand, when the button body 2 is pushed in and the guide member 10 is in contact with the slope portion 42B, the user feels that the resistance to the pushing operation is smaller than when the guide member 10 is in contact with the slope portion 42A. ..

Here, the change in resistance will be described. First, consider the case where resistance is regarded as normal force. Assuming that the normal force acting on the slope portion 42 is N, the component of the normal force in the Y-axis direction is Nsin θ. Therefore, when the inclination angle θ is large, the component of the normal force in the Y-axis direction also increases. Therefore, the resistance felt by the user when pushing the button body 2 in the Y-axis direction is greater when the guide member 10 is in contact with the slope portion 42A than when the guide member 10 is in contact with the slope portion 42B. big. Next, consider the case where the resistance force is regarded as the frictional force. Let F be the pushing force in the −Y direction with respect to the button body 2. When the guide member 10 is in contact with the slope portion 42A, the normal force Na corresponding to F1a = Fsinθa may be applied to the slope portion 42A. Therefore, a frictional force (dynamic frictional force) proportional to the normal force Na acts on the slope portion 42A. On the other hand, when the guide member 10 is in contact with the slope portion 42B, a normal force Nb corresponding to F1b = Fsinθb may be applied to the slope portion 42B. Therefore, a frictional force (dynamic frictional force) proportional to the normal force Nb acts on the slope portion 42B. Here, since θa> θb, Na> Nb. Therefore, the frictional force applied to the slope portion 42A is larger than the frictional force applied to the slope portion 42B. Since the direction of motion on the slope portion 42 corresponds to the inclination direction, the resistance force on the slope portion 42 corresponds to the frictional force. Therefore, the weight (resistance force) for the pushing motion felt by the user when the guide member 10 is in contact with the slope portion 42A is the weight for the pushing motion felt by the user when the guide member 10 is in contact with the slope portion 42B. Greater than (resistance).

By forming the slope 40 of the protrusion member 30X into such a shape, for example, the following configuration can be considered. The push button 1 is such that the guide member 10 is in contact with the slope portion 42A until the push member 20 is in contact with the switch 4, and after the push member 20 is in contact with the switch 4, the guide member 10 is in contact with the slope portion 42B. Components and switch 4 are arranged.

As a result, the user can sense a large resistance force to the pushing operation and a large amount of rotation of the button body 2 before the switch 4 operates. As a result, the user can prevent the switch 4 from being operated by mistake. That is, since the resistance to the pushing operation before the switch 4 operates is large, it is difficult to push the pushing button 1 just by touching the pushing button 1 with a light force, so that the malfunction can be suppressed. Further, by sensing a large amount of rotation of the button body 2, it is possible to more clearly recognize that the push button 1 is pushed when the push button 1 is accidentally touched, so that malfunction can be suppressed.

Further, as described above, when the function of the switch 4 corresponding to each of the two push buttons 1 and the rotation direction of each of the two push buttons 1 are associated with each other, the user can use the switch 4 before the switch 4 is pressed. The function corresponding to the push button 1 can be recognized. That is, when the push button 1 is pushed in, the amount of rotation of the push button 1 before the switch 4 operates is large. Therefore, when the push button 1 is pushed, the user can more clearly recognize the rotation direction of the push button 1 before the switch 4 operates. For example, as described above, it is assumed that the switch 4 corresponding to the push button 1 rotating counterclockwise activates the UP operation, and the switch 4 corresponding to the push button 1 rotating clockwise activates the DOWN operation. In this case, the user pushes a push button 1 in an attempt to activate the UP operation, but when the user senses that the push button 1 has rotated clockwise, the user pushes the push button 1 before the switch 4 operates. It can be recognized that the button 1 was an error. Further, when the user pushes the push button 1 that is trying to activate the UP operation and the user senses that the push button 1 has rotated counterclockwise, the user pushes the push button before the switch 4 operates. You can recognize that 1 is correct. Therefore, the correct button operation can be performed more reliably.

FIG. 9 is a diagram showing a protrusion member 30Y according to the second modification of the first embodiment. The slope 40 of the protrusion member 30Y according to the second modification has a slope portion 42C (third slope portion) and a slope portion 42D (fourth slope portion). The slope portion 42D is provided on the + Y side of the slope portion 42C, that is, on the side opposite to the stroke direction. Assuming that the inclination angle of the slope portion 42C is θc and the inclination angle of the slope portion 42D is θd, 0 ≦ θc <θd. That is, the inclination angle θd of the slope portion 42D is larger than the inclination angle θc of the slope portion 42C.

Therefore, the amount of rotation when the button body 2 is pushed in by the amount S when the guide member 10 is in contact with the slope portion 42C is the amount of push in the button body 2 when the guide member 10 is in contact with the slope portion 42D. It is smaller than the amount of rotation when only S is pushed in. That is, while the button body 2 is pushed in from the initial state and the guide member 10 is in contact with the slope portion 42C, the user senses the rotation of the button body 2 by a small amount of rotation with respect to the pushed amount. That is, while the guide member 10 is in contact with the slope portion 42C, if θc ≠ 0, the user feels that the rotation of the button body 2 is small, and if θc = 0, the user rotates the button body 2. I feel I don't. Further, since the inclination angle θc of the slope portion 42C is small, the resistance to the pushing operation is small. Therefore, when the guide member 10 is in contact with the slope portion 42C, the user feels that the resistance to the pushing operation is small.

Further, the slope 40 of the protrusion member 30Y according to the second modification has a step portion 43 between the slope portion 42C and the slope portion 42D. Therefore, when the button body 2 is pushed in and the guide member 10 comes into contact with the step portion 43, a large resistance force acts against the pushing operation. Further, when the user pushes the button body 2 against this resistance force and the guide member 10 touches the slope portion 42D, the user touches the button as compared with the case where the guide member 10 touches the slope portion 42C. I feel that the amount of rotation with respect to the amount of pushing of the main body 2 has increased. Further, the user feels that the resistance to the pushing operation is increased as compared with the case where the guide member 10 is in contact with the slope portion 42C.

By forming the slope 40 of the protrusion member 30Y into such a shape, for example, the following configuration can be considered. The push button 1 is such that the guide member 10 is in contact with the slope portion 42C until the push member 20 is in contact with the switch 4, and after the push member 20 is in contact with the switch 4, the guide member 10 is in contact with the slope portion 42D. Components and switch 4 are arranged. Further, immediately before the pressing member 20 comes into contact with the switch 4, the components of the push button 1 and the switch 4 are arranged so that the guide member 10 comes into contact with the step portion 43.

As a result, the user can push the button body 2 with a light force before the switch 4 operates, and feels a large resistance force immediately before the switch 4 operates. Therefore, the user can more clearly sense the moment when the switch 4 is operated. Further, while the pressing member 20 presses the switch 4, the user can sense a large amount of rotation of the button body 2. This allows the user to clearly recognize that the switch 4 is functioning. Therefore, it is possible to improve the tactile sensation (haptics) for the operation of the push button 1 by the user.

FIG. 10 is a diagram showing a protrusion member 30Z according to a third modification of the first embodiment. The slope 40 of the protrusion member 30Z according to the third modification has a slope portion 42E (first slope portion), a slope portion 42F (second slope portion, a third slope portion), and a slope portion 42G (third slope portion). It has a slope portion of 4). The slope portion 42F is provided on the + Y side of the slope portion 42E, that is, on the side opposite to the stroke direction. The slope portion 42G is provided on the + Y side of the slope portion 42F, that is, on the side opposite to the stroke direction.

Assuming that the inclination angle of the slope portion 42E is θe, the inclination angle of the slope portion 42F is θf, and the inclination angle of the slope portion 42G is θg, θe> θf and θf <θg. That is, the inclination angle θf of the slope portion 42F is smaller than the inclination angle θe of the slope portion 42E. Further, the inclination angle θg of the slope portion 42G is larger than the inclination angle θf of the slope portion 42F.

Since θe> θf, the amount of rotation when the button body 2 is pushed by the pushing amount S when the guide member 10 is in contact with the slope portion 42E is the button when the guide member 10 is in contact with the slope portion 42F. It is larger than the rotation amount when the main body 2 is pushed in by the pushing amount S. That is, while the button body 2 is pushed in from the initial state and the guide member 10 is in contact with the slope portion 42E, the user senses the rotation of the button body 2 by a large amount of rotation with respect to the pushed amount. On the other hand, when the button body 2 is pushed in and the guide member 10 touches the slope portion 42F, the user can rotate the button body 2 with respect to the pushing amount as compared with the case where the guide member 10 is in contact with the slope portion 42E. I feel like I'm getting smaller.

Further, the weight (resistance force) for the pushing motion felt by the user when the guide member 10 is in contact with the slope portion 42E is the weight for the pushing motion felt by the user when the guide member 10 is in contact with the slope portion 42F. Greater than (resistance). Therefore, when the guide member 10 is in contact with the slope portion 42E, the user feels a great resistance to the pushing operation. On the other hand, when the button body 2 is pushed in and the guide member 10 is in contact with the slope portion 42F, the user feels that the resistance to the pushing operation is smaller than when the guide member 10 is in contact with the slope portion 42E. ..

Further, since θf <θg, the rotation amount with respect to the push-in amount S when the guide member 10 is in contact with the slope portion 42G is more than the rotation amount with respect to the push-in amount S when the guide member 10 is in contact with the slope portion 42F. Is also big. That is, when the button body 2 is pushed in and the guide member 10 touches the slope portion 42G, the user can rotate the button body 2 with respect to the pushing amount as compared with the case where the guide member 10 is in contact with the slope portion 42F. I feel like I've grown up.

Further, the weight (resistance force) for the pushing motion felt by the user when the guide member 10 is in contact with the slope portion 42G is the weight for the pushing motion felt by the user when the guide member 10 is in contact with the slope portion 42F. Greater than (resistance). Therefore, when the button body 2 is pushed in and the guide member 10 is in contact with the slope portion 42G, the user feels that the resistance to the pushing operation is increased as compared with the case where the guide member 10 is in contact with the slope portion 42F. ..

By forming the slope 40 of the protrusion member 30Z into such a shape, for example, the following configuration can be considered. Until the push member 20 comes into contact with the switch 4, the components of the push button 1 and the switch 4 are arranged so that the guide member 10 comes into contact with the slope portion 42E. Further, the components of the push button 1 and the switch 4 are arranged so that the guide member 10 comes into contact with the slope portion 42F from the time when the push member 20 comes into contact with the switch 4 until the switch 4 is brought into the deeply pressed state. .. Further, after the switch 4 is deeply pressed by pressing the pressing member 20, the components of the push button 1 and the switch 4 are arranged so that the guide member 10 comes into contact with the slope portion 42G.

Here, the "deep push state" is a state in which the switch 4 is pushed deeply to operate a function different from the case where the push depth of the switch 4 is shallow. The "deep press state" may be, for example, an operation corresponding to a so-called "long press state". For example, when the switch 4 activates the volume UP function, the volume may be increased faster in the deeply pressed state than in the case where the pressing depth of the switch 4 is shallow. Further, for example, when the switch 4 activates the function of the power supply of the device, if the push depth of the switch 4 is shallow, the sleep state of the device is released, and in the deep push state, the power of the device is turned off or turned on. You may do so.

As a result, as in the first modification, the user can sense a large resistance force to the pushing operation and a large amount of rotation of the button body 2 before the switch 4 operates. As a result, the user can prevent the switch 4 from being operated by mistake. Further, when the switch 4 is in the deeply pressed state, a large resistance force to the pushing operation can be sensed, and a large amount of rotation of the button body 2 can be sensed. As a result, the user can more clearly recognize that the switch 4 has been pressed deeply.

(Embodiment 2)
Next, the second embodiment will be described. In the second embodiment, the positional relationship between the pressing member and the switch is different from that in the first embodiment. Since the other configurations of the push button 1 according to the first embodiment are substantially the same as those according to the first embodiment, the description thereof will be omitted as appropriate.

FIG. 11 is a diagram showing a push button 1 according to the second embodiment. Similar to the first embodiment, the push button 1 according to the second embodiment has a button main body 2, a guide member 10, a push member 20, and a protrusion member 30. Also in the second embodiment, the XYZ orthogonal coordinate axes substantially the same as those in the first embodiment are introduced.

Similar to the first embodiment, the push button 1 (button body 2) is pushed in the direction indicated by the arrow A, that is, in the −Y direction, so that the push member 20 pushes the switch 4. As a result, the switch 4 operates and a predetermined function is executed. Further, as in the first embodiment, when the push button 1 (button body 2) is pushed in the direction of the arrow A, the push button 1 (button body 2) is rotated around the button body 2 as shown by the arrow Br. It is configured to rotate along the direction.

Here, the shapes of the button body 2, the guide member 10, and the protrusion member 30 according to the second embodiment are substantially the same as those of the first embodiment. Further, the positional relationship between the guide member 10 and the protrusion member 30 is substantially the same as that of the first embodiment. Therefore, the mechanism by which the button body 2 rotates is substantially the same as that of the first embodiment. Therefore, the description of the mechanism by which the button body 2 rotates will be omitted.

Here, in the first embodiment, the switch 4 is arranged on the −Y side of the pressing member 20. On the other hand, in the second embodiment, the switch 4 is arranged on the rotation direction side of the pressing member 20. In FIG. 11, the switch 4 is arranged on the −X side of the pressing member 20.

Similar to the first embodiment, when the button body 2 is pushed in the direction of the arrow A, that is, in the −Y direction, the pressing member 20 also moves in the direction of the arrow Ac, that is, in the −Y direction. Further, as in the first embodiment, since the button body 2 rotates in the direction of the arrow Br, the pressing member 20 also rotates in the direction indicated by the arrow Bc in conjunction with the rotation. Then, the side surface 24 formed in the rotation direction of the pressing member 20 abuts on the switch 4. As a result, the pressing member 20 presses the switch 4 in the direction of the arrow Bc, that is, in the rotation direction of the pressing member 20.

12 and 13 are diagrams showing the operation of the push button 1 according to the second embodiment. It is assumed that the button body 2 is pushed in the direction of the arrow A from the state shown in FIG. Then, as shown in FIG. 12, the button body 2 rotates in the direction of the arrow Br. In conjunction with the operation of the button body 2, the pressing member 20 moves in the direction of the arrow Ac and rotates in the direction of the arrow Bc. As a result, the side surface 24 of the pressing member 20 approaches the switch 4.

It is assumed that the button body 2 is further pushed in the direction of the arrow A from the state shown in FIG. Then, as shown in FIG. 13, the button body 2 further rotates in the direction of the arrow Br. In conjunction with the operation of the button body 2, the pressing member 20 further moves in the direction of the arrow Ac and further rotates in the direction of the arrow Bc. Then, the side surface 24 of the pressing member 20 abuts on the switch 4. As a result, the pressing member 20 presses the switch 4 in the direction of the arrow Bc, that is, in the rotation direction of the pressing member 20.

In the present embodiment, the button body 2 is configured to rotate when the button body 2 is pushed. Therefore, the pressing member 20 integrally formed with the button body 2 also rotates. In the second embodiment, the pressing member 20 is configured to press the switch 4 by utilizing the rotational operation of the pressing member 20. That is, the switch 4 is arranged on the side in the rotation direction of the pressing member 20, and the side surface 24 of the pressing member 20 presses the switch 4 by the rotational operation of the pressing member 20. With such a configuration, it is not necessary to arrange the switch 4 on the −Y side of the push button 1, that is, in the direction in which the button body 2 is pushed. This increases the degree of freedom in design regarding the arrangement between the push button 1 and the switch 4. Then, for example, as compared with the case of the first embodiment, it is possible to reduce the arrangement space of the push button 1 and the switch 4 in the Y-axis direction.

(Embodiment 3)
Next, the third embodiment will be described.
FIG. 14 is a diagram showing a push button device 100 according to the third embodiment. The push button device 100 has a push button 1 (1A, 1B) according to the above-described embodiment and a housing 102. In the example of FIG. 14, the push button device 100 has two push buttons 1, but the number of push buttons 1 can be any number of 2 or more. The push button device 100 can be any device having a plurality of push buttons.

The housing 102 accommodates the push button 1. Holes 110A and 110B are formed on the upper surface 102a of the housing 102. A push button 1A is embedded in the hole 110A. A push button 1B is embedded in the hole 110B. The push button 1A may be supported by a hole 110A so that it can be pushed and rotated. The push button 1B may be supported by a hole 110B so that it can be pushed and rotated.

Since the push button 1 according to the third embodiment has substantially the same configuration as that of the above-described embodiment, the description thereof will be omitted. Further, although not shown, a switch 4 operated by the corresponding push button 1 is provided in the vicinity of each push button 1 inside the push button device 100. Here, the two switches 4 operate different functions when pressed.

The push buttons 1A and 1B are configured to rotate in opposite directions when pushed. That is, the rotation directions of the push buttons 1A and 1B when the button bodies 2A and 2B are pushed are different from each other for the push buttons 1A and 1B. For example, when the button body 2A of the push button 1A is pushed in, the button body 2A of the push button 1A rotates counterclockwise as shown by the arrow B1. Further, when the button body 2B of the push button 1B is pushed in, the button body 2B of the push button 1B rotates clockwise as shown by the arrow B2.

It should be noted that preferably, the button body 2 is arranged so that the top surface 2a of the button body 2 does not protrude from the upper surface 102a of the housing 102. By arranging in this way, the protrusion of the surface of the upper surface 102a of the housing 102 can be reduced. Since the button main body 2 according to the present embodiment is formed in a circular shape when viewed in the pushing direction, the rotation of the button main body 2 is formed on the upper surface 102a of the housing 102 even if the button main body 2 rotates. It is suppressed that the hole 110 is obstructed.

Since the push button device 100 according to the third embodiment is configured as described above, the function corresponding to the push button 1 can be recognized only by pushing the push button 1 without visually recognizing the push button 1. can do. For example, assume that the switch 4 corresponding to the push button 1A activates the UP operation and the switch 4 corresponding to the push button 1B activates the DOWN operation. In this case, since the user senses tactilely that when the push button 1A is pushed, it rotates counterclockwise, it can be recognized that the function corresponding to the push button 1A is the UP operation. Similarly, since the user senses tactilely that when the push button 1B is pushed, it rotates clockwise, it can be recognized that the function corresponding to the push button 1B is the DOWN operation. Therefore, it is possible to suppress a user's mistake in pressing the push button 1.

In addition, it is generally used to inform visually impaired users who cannot visually recognize the operation of a push button by adding Braille indicating the function of the button to the button or the vicinity of the button to inform the function of the button. It has been. However, if the user repeatedly touches the Braille, the protrusion of the Braille may be consumed or deteriorated, and the user may not be able to properly recognize the Braille. On the other hand, in the third embodiment, the push button 1 is configured to rotate in a different direction for each function. Therefore, even a visually impaired user can easily recognize the function of the push button 1.

Although the push button device 100 according to the third embodiment is said to have two push buttons 1, it may have three or more push buttons 1. In this case, the functions of the three or more push buttons 1 are recognized by tactile sensation by making the rotation direction and the rotation amount (resistance force against the pushing operation) of the three or more push buttons 1 different from each other. Can be done. For example, the push button device 100 may have four push buttons 1. In this case, for example, the rotation direction of the first push button and the second push button is counterclockwise, and the rotation direction of the third push button and the fourth push button is clockwise. Further, the rotation amount of the first push button (resistance force to the pushing operation) is made larger than the rotation amount of the second push button (resistance force to the pushing operation). Further, the rotation amount of the third push button (resistance force to the pushing operation) is made larger than the rotation amount of the fourth push button (resistance force to the pushing operation). With such a configuration, the functions corresponding to the four push buttons 1 can be recognized by touch. That is, by making the rotation methods of the plurality of push buttons 1 different from each other, the functions corresponding to the four push buttons 1 can be recognized by tactile sensation.

(Modification example)
The present invention is not limited to the above embodiment, and can be appropriately modified without departing from the spirit. For example, the configuration of the modified example of the first embodiment and the configuration of the second embodiment are applicable to each other. Therefore, for example, the protrusion member according to the second embodiment may be used as the protrusion member according to the first modification.

Further, in the above-described embodiment, the hook portion 32 is formed on the protrusion member 30, but the hook portion 32 may not be formed on the protrusion member 30. The hook portion for preventing the button body 2 from coming off may be provided on a component other than the protrusion member 30. However, since the slope 40 is formed on the protrusion member 30 on which the hook portion 32 is formed, it is not necessary to separately provide the hook portion and the protrusion member. Therefore, the structure of the push button 1 is simplified.

1 Push button 2 Button body 4 Switch 6 Support member 10 Guide member 12 Inclined surface 20 Pushing member 22 Inclined surface 24 Side surface 30 Protruding member 32 Hook portion 40 Slope 42 Slope portion 43 Step portion 100 Push button device 102 Housing 110A, 110B Hole

Claims (5)

A button body that is supported for pushing and rotating movements,
A protrusion member provided on the button body and having a slope formed so as to be inclined in the circumferential direction of the button body with respect to a direction along a first direction which is a pushing direction of the button body.
When the button body is pushed in, a guide member that guides the protrusion member in the circumferential direction of the button body while contacting the slope of the protrusion member.
It has a pressing member provided on the button body and pressing a switch by pushing the button body.
The button body rotates as the protrusion member is guided by the guide member.
push button. The slope has a plurality of slope portions having different inclination angles, which are inclination angles in the circumferential direction of the slope with respect to a direction along the first direction.
The push button according to claim 1. The slope is
The first slope and
A second slope portion provided on the side opposite to the first direction with respect to the first slope portion and having an inclination angle smaller than the inclination angle of the first slope portion, and a second slope portion.
Have,
The push button according to claim 2. The slope is
The third slope and
A fourth slope portion provided on the side opposite to the first direction of the third slope portion and having an inclination angle larger than the inclination angle of the third slope portion, and a fourth slope portion.
Have,
The push button according to claim 2. The pressing member rotates in conjunction with the rotation of the button body, and presses the switch in the rotation direction of the pressing member.
The push button according to any one of claims 1 to 4.

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