JP2008059929A - Slide switch device, and remote control unit equipped with it - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To achieve a compact structure enabled to prevent a slide knob from falling off a case of a remote controller with the small number of components. <P>SOLUTION: The slide switch device is provided with a case 1a with guide holes 11, 12 formed, and a slide knob 2 arranged in free sliding between a first and a second positions along the guide holes 11, 12 and with a claw part 21 formed, with the guide holes 11, 12 equipped with an opening width capable of attaching and detaching the claw part 21 elastically deforming it. Flat parts 11a, 11b, 12a, 12b with opening widths narrower than other parts for regulating elastic deformation of the claw part 21 so as not to release its engagement state with the guide holes 11, 12 are provided at least at either end of each guide hole 11, 12, so that, when the slide knob 2 reaches either the first or the second position, the claw part 21 is to be regulated from elastically deforming by the flat parts. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a slide switch device capable of switching functions and the like by a slide operation. The present invention also relates to a remote control device equipped with such a slide switch device.

  2. Description of the Related Art In recent years, portable audio players (hereinafter referred to as players) that have rapidly spread are equipped with a remote control capable of remotely controlling the player on a headphone cable that is worn by a user to listen to music. There are many. In particular, a portable audio player capable of reproducing music data recorded in a semiconductor memory is required to be further downsized because the size of the player body is small.

  In addition to the operation buttons, the remote control attached to the player often has a slide operation switch. The slide switch generally includes a switch element having two or more contacts, and is often used for on / off switching operation of various functions, mode selection operation, and the like. In this manner, by mounting the slide switch, a plurality of functions can be assigned and the number of operation buttons and the like can be reduced, so that the remote control can be downsized.

  Hereinafter, an example of a remote controller equipped with a slide switch will be described.

  FIG. 9 is a perspective view showing an appearance of a remote control unit on which the slide switch device is mounted. In this configuration, a remote control unit equipped with a slide switch device is taken as an example.

  In FIG. 9, the remote control unit 101 is disposed, for example, in an intermediate portion of a cable of a headphone unit that can be connected to the player body, and can perform various operations on the player body. The remote control unit 101 is covered with a first casing 101a and a second casing 101b. A substantially oval concave portion 101c is formed on the surface of the first housing 101a. A slide knob 102 that is slidable in the direction of arrow A or in the opposite direction is disposed in the recess 101c. The second casing 101b is provided with a switch element that is switched by the slide knob 102 and various electric circuit boards (not shown). Further, since the remote control unit 101 of this configuration is arranged in the middle of the cable of the headphone unit, a left cable 104a and a right cable 104b that can transmit a control signal, an audio signal, and the like are provided at both ends in the longitudinal direction of the remote control unit 101. Is arranged.

  The left cable 104a and the right cable 104b incorporate signal lines capable of transmitting audio signals. Further, the right cable 104b incorporates a signal line capable of transmitting a control signal. The left cable 104a in FIG. 1 is connected to the headphone speaker, and the right cable 104b is connected to the player body.

  The slide knob 102 is formed in a substantially oval shape. The length of the slide knob 102 in the longitudinal direction is at least shorter than the length in the longitudinal direction of the recess 101c, and is slidable within the range of the recess 101c. Further, the slide knob 102 is configured to be slidable at, for example, three positions of a first position, a second position, and a third position. The first position is a position shown in FIG. 9 and is a position where the illustrated right end portion of the slide knob 102 is in contact with or close to the illustrated right end portion of the recess 101c. The second position is a position shown in FIG. 9 that is slid from the first position in the direction of arrow A, and the illustrated left end portion of the slide knob 102 is in contact with or close to the illustrated left end portion of the recess 101c. The 3rd position is a position between the 1st position and the 2nd position, and is a state where slide knob 102 is located in the approximate center of the longitudinal direction of crevice 101c. Therefore, even if the slide knob 102 is in any of the first to third positions, a part of the recess 101c is always exposed.

  In FIG. 9, the concave portion 101 c is always exposed to the outside regardless of the position of the slide knob 102 from the first to third positions, and a gap is always generated between the concave portion 101 c and the slide knob 102. Therefore, fingers and clothes are easily caught on the end 102a of the slide knob 102, and the slide knob 102 may be detached in the direction indicated by the arrow B.

Such a configuration for preventing the slide knob from being detached is disclosed in, for example, Patent Document 1 or 2.
JP-A-9-139152 Japanese Patent Laid-Open No. 11-163555

  However, in the configuration disclosed in Patent Document 1 or 2, it is possible to prevent the slide knob from being detached from the remote control housing, but the remote control body cannot be reduced in size and the number of parts can be reduced. There was a problem that could not.

  For example, in the configuration disclosed in Patent Document 1, in order to prevent the flange portion having the operation knob from being detached from the housing case, a part of the housing case is sandwiched by an elastic member provided on the back surface of the flange portion. The configuration is adopted. Therefore, a space for arranging the elastic member is required, and the number of parts is increased.

  Moreover, in the structure currently disclosed by patent document 2, in order to prevent the drop of a slide knob, the stopper is provided and the structure which pinches | interposes a slide knob with a housing | casing cover and a stopper is employ | adopted. Therefore, a space for arranging the stopper is required and the number of parts is increased.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a slide switch device that can realize a configuration that can prevent the slide knob from being detached from the remote control housing with a small number of parts. And Moreover, it aims at providing the remote control apparatus provided with the slide switch apparatus.

  In order to achieve the above object, a slide switch device according to the present invention is arranged to be slidable between a housing in which a guide hole is formed and a first position and a second position along the guide hole. And a slide knob that is elastically deformable in a direction substantially perpendicular to the slide direction and has a claw portion that is engaged with the guide hole, and a slide operation of the slide knob that is engaged with the slide knob. And the guide hole is a slide switch device having an opening width that can be attached and detached while elastically deforming the claw portion, at least at both ends of the guide hole. Is narrower than other portions, and includes a restricting portion that restricts elastic deformation of the claw portion so that the engagement state between the claw portion and the guide hole is not released, and the slide knob is in the first position. Or when it reaches the second position, the claw portion is configured such that elastic deformation is restricted by the restricting portion.

  The remote control device of the present invention is a remote control device in which an electronic device can be remotely operated and a slide switch device capable of sliding operation is mounted. The slide switch device has a guide hole formed therein. The housing is slidable between the first position and the second position along the guide hole, and is elastically deformable in a direction substantially perpendicular to the sliding direction. A slide knob in which a claw portion to be engaged is formed; and a switch element that is engaged with the slide knob and is switched in accordance with a slide operation of the slide knob, and the guide hole includes the claw portion. An opening width that can be attached and detached while elastically deforming the guide hole. At least at both ends of the guide hole, the opening width is narrower than other portions, and the claw portion and the guide hole A restricting portion for restricting elastic deformation of the claw portion so that the engagement state of the claw portion is not released, and when the slide knob reaches the first position or the second position, the claw portion is the restriction portion. Therefore, the elastic deformation is restricted.

  According to the present invention, the configuration for preventing the slide knob from falling off the housing can be realized with a small number of parts and at low cost.

  In the slide switch device according to the present invention, the restricting portion includes a first restricting portion formed at one end portion of the guide hole and a second restricting portion formed at the other end portion of the guide hole. And a third restricting portion formed between the first restricting portion and the second restricting portion, and the guide hole includes the first restricting portion and the third restricting portion. An opening that can be attached to and detached from the guide hole while elastically deforming the claw portion between at least one of the restriction portion and between the second restriction portion and the third restriction portion. It can be set as the structure provided with the wide part which has a width | variety. With this configuration, it is possible to prevent the slide knob from falling off even in a slide switch device equipped with switch elements having three or more contacts.

(Embodiment 1)
FIG. It is a perspective view which shows the external appearance of the remote control unit in which the slide switch apparatus in Embodiment 1 is mounted. In this embodiment, a remote control unit is cited as an example of a device equipped with a slide switch device. However, at least as long as the device can be equipped with a slide switch device, an electronic device other than the remote control unit (for example, a player body) is used. Can also be installed.

  In FIG. 1, the remote control unit 1 is arranged in the middle part of the cable of the headphone unit that can be connected to the player body in the present embodiment, and can perform operations for giving various commands to the player body. The remote control unit 1 is covered with a first casing 1a and a second casing 1b. A substantially oval recess 1c is formed on the surface of the first housing 1a. A slide knob 2 slidable in the direction of arrow A or in the opposite direction is disposed in the recess 1c. The second casing 1b is provided with a switch element 3 (to be described later) that is switched by a slide knob 2 and various electric circuit boards (not shown). Further, the remote control unit 1 of the present embodiment is arranged in the middle of the cable of the headphone unit. The cable is composed of a left cable 4a and a right cable 4b.

  The left cable 4a and the right cable 4b incorporate signal lines capable of transmitting audio signals. Further, the right cable 4b incorporates a signal line capable of transmitting a control signal output from the remote control unit 1 to the player body. In the present embodiment, the left cable 4a in FIG. 1 is connected to the headphone speaker, and the right cable 4b is connected to the player body. The cables 4a and 4b are not limited to both ends in the longitudinal direction of the remote control unit 2, and may be arranged at other positions. Further, in the configuration in which signal transmission between the remote control unit 1 and the player body is performed wirelessly, the cables 4a and 4b can be omitted.

  The slide knob 2 is formed in a substantially oval shape. The length of the slide knob 2 in the longitudinal direction is at least shorter than the length of the recess 1c in the longitudinal direction. In this embodiment, the slide knob 2 is configured to be slidable at three positions, ie, a first position, a second position, and a third position. The first position is a position shown in FIG. 1 and is a position where the illustrated right end portion of the slide knob 2 is in contact with or close to the illustrated right end portion of the recess 1c. The second position is a position where the illustrated left end portion of the slide knob 2 is in contact with or close to the illustrated left end portion of the concave portion 1c by sliding in the arrow A direction from the first position shown in FIG. The 3rd position is a position between the 1st position and the 2nd position, and is a state where slide knob 2 is located in the approximate center of the longitudinal direction of crevice 1c. In addition, a concave portion that fits the tip of the finger and a plurality of concave and convex portions that reduce the sliding of the finger can be formed on the upper surface of the slide knob 2 so that the user can easily perform a sliding operation with the finger. In addition, a function name or the like can be written on a portion corresponding to the slide position of the slide knob 2 on the upper surface of the slide knob 2 or the upper surface of the first housing 1a.

  FIG. 2 is an inside perspective view of the first housing 1a, which is drawn at an angle at which the inside of the first housing 1a can be seen. Further, a slide knob 2 is held in the first housing 1a shown in FIG. Moreover, FIG. 3A is a principal part top view of the site | part by which the slide knob 2 in the inside of the 1st housing | casing 1a is mounted | worn. 3B is a cross-sectional view of the ZZ portion in FIG. 3A.

  2 and 3, a first guide hole 11, a second guide hole 12, a guide hole 14, and a sliding portion 13 are formed in the first housing 1a. Further, the slide knob 2 is formed with a claw portion 21 and a protrusion 22. Further, in FIG. 3A, the switch element 3 is indicated by a temporary wire.

  The first guide hole 11 and the second guide hole 12 are formed symmetrically with each other. Further, the first guide hole 11 and the second guide hole 12 can hold the slide knob 2 slidably. Moreover, the 1st guide hole 11 and the 2nd guide hole 12 penetrate from the bottom face of the recessed part 1c (refer FIG. 1) formed in the 1st housing | casing 1a to the inner surface of the 1st housing | casing 1a. Is formed. Moreover, the 1st guide hole 11 and the 2nd guide hole 12 are formed in the mutually symmetrical shape.

The first guide hole 11 has a first flat portion 11a (first restriction portion), a second flat portion 11b (second restriction portion), and a first triangular protrusion 11c (third restriction portion). Portion), a first recess 11d (wide portion), a second recess 11e (wide portion), and a third flat portion 11f. The first flat portion 11a, the second flat portion 11b, and the third flat portion 11f are formed substantially in parallel. The first flat portion 11 a and the second flat portion 11 b are formed at both ends of the first guide hole 11, respectively, and have flat surfaces substantially parallel to the longitudinal direction of the first guide hole 11. Yes. The first triangular protrusion 11 c is formed substantially at the center in the longitudinal direction of the first guide hole 11, and is formed so as to protrude toward the inside of the first guide hole 11. In the first guide hole 11, the width dimension of the gap between the first flat part 11a and the third flat part 11f and the width dimension of the gap between the second flat part 11b and the third flat part 11f. The width dimension of the gap between the top portion of the first triangular protrusion 11c and the third flat portion 11f is the same dimension W3. The first recess 11d is formed between the first flat portion 11a and the first triangular protrusion 11c. The second recess 11e is formed between the second flat portion 11b and the first triangular protrusion 11c. The pitch between the first recess 11 d and the second recess 11 e is substantially the same as the pitch of the claw portions 21 engaged with the first guide hole 11. Therefore, when the slide knob 2 is in the position shown in FIG. 3A, the first concave portion 11d and the second concave portion 11e and the claw portion 21 are in positions facing each other. In addition, the first recess 11d and the second recess 11e have a width dimension of the gap between the first recess 11d and the third flat portion 11f of W4 (the second recess 11e and the third flat portion 11f. The width dimension of the gap is the same dimension), the width dimension of the claw portion 21 is D1, and the width dimension of the portion engaging with the sliding portion 13 (engagement allowance) in the claw portion 21 is W1.
(D1 + W1) <W4 (Formula 1)
The relationship is established. As a result, as shown in FIG. 3A, when the claw portion 21 is in a position facing the first recess portion 11d and the second recess portion 11e, the claw portion 21 and the first recess portion 11d and the second recess portion 11e A space in which the claw portion 21 can be elastically deformed in the direction of arrow C shown in FIG.

  Further, the second guide hole 12 has a fourth flat portion 12a (first flat portion), a fifth flat portion 12b (second flat portion), and a second triangular protrusion 12c (third flat portion). Portion), a third recess 12d (wide portion), a fourth recess 12e (wide portion), and a sixth flat portion 12f. The fourth flat portion 12a, the fifth flat portion 12b, and the sixth flat portion 12f are formed substantially in parallel. The fourth flat portion 12a and the fifth flat portion 12b are formed at both ends of the second guide hole 12, respectively, and have flat surfaces substantially parallel to the longitudinal direction of the second guide hole 12. Yes. The second triangular protrusion 12 c is formed at approximately the center in the longitudinal direction of the second guide hole 12 and is formed so as to protrude toward the inside of the second guide hole 12. In the second guide hole 12, the width dimension of the gap between the fourth flat part 12a and the sixth flat part 12f and the width dimension of the gap between the fifth flat part 12b and the sixth flat part 12f. And the width dimension of the gap between the top of the second triangular protrusion 12c and the sixth flat portion 12f is that the first guide hole 11 and the second guide hole 12 are symmetrical, This is the same as the dimension W3 in the guide hole 11. The fourth recess 12d is formed between the fifth flat portion 12a and the second triangular protrusion 12c. The third recess 12e is formed between the fifth flat portion 12b and the second triangular protrusion 12c. Further, the pitch between the third recess 12 d and the fourth recess 12 e is substantially equal to the pitch of the claw portions 21 engaged with the second guide holes 12. Therefore, when the slide knob 2 is in the position shown in FIG. 3A, the third recess 12d and the fourth recess 12e and the claw portion 21 are in positions facing each other. Further, the third recess 12d and the fourth recess 12e are formed so that the relationship of Equation 1 is satisfied because the first guide hole 11 and the second guide hole 12 are symmetrical. Yes. As a result, as shown in FIG. 3A, when the claw portion 21 is in a position facing the third recess portion 12d and the fourth recess portion 12e, the claw portion 21, the third recess portion 12d, and the fourth recess portion 12e A space in which the claw portion 21 can be elastically deformed in the direction of arrow C shown in FIG.

  The guide hole 14 is formed such that its longitudinal direction substantially coincides with the slide direction of the slide knob 2. Further, the guide hole 14 is movably fitted with a protrusion 22 formed on the back surface of the slide knob 2, and can guide the slide operation of the slide knob 2.

  The claw portion 21 includes a first claw portion 21a, a second claw portion 21b, a third claw portion 21c, a fourth claw portion 21d, and a concave portion 21e. The claw portion 21 is formed on the back surface of the slide knob 2. Moreover, the 1st-4th nail | claw parts 21a-21d are formed so that elastic deformation is possible to the arrow C direction shown to FIG. 3B, or the reverse direction. Further, the first claw portion 21 a and the second claw portion 21 b are engaged with the first guide hole 11. Further, the third claw portion 21 c and the fourth claw portion 21 d are engaged with the second guide hole 12. In this embodiment, the recess 21e is formed at least between the first claw portion 21a and the second claw portion 21b. The operation lever 3a (see FIG. 4) of the switch element 3 is fitted into the recess 21a.

  The protrusion 22 is formed in a substantially cylindrical shape on the back surface of the slide knob 2. The protrusion 22 is fitted in the guide hole 14 and slides in the guide hole 14 as the slide knob 2 slides, thereby reducing the backlash of the slide knob 2.

  Next, a slide switch device and a method for assembling a remote control unit including the slide switch device will be described.

  First, in FIG. 3A, the claw portion 21 of the slide knob 2 is engaged with the first guide hole 11 and the second guide hole 12 from the surface side of the first housing 1a. That is, as shown in FIG. 3A, the first claw portion 21a formed on the back surface of the slide knob 2 is aligned with the first concave portion 11d, and the second claw portion 21b is positioned at the second concave portion 11e. The third claw portion 21c is aligned with the third recess 12d, and the fourth claw portion 21d is aligned with the fourth recess 12e. Next, the first claw portion 21 a and the second claw portion 21 b are inserted into and engaged with the first guide hole 11, and the third claw portion 21 c and the fourth claw portion 21 d are inserted into the second guide hole 12. Insert and engage. At this time, as shown in FIG. 3B, the distance H1 between the tips of the claw portions 21 is larger than the distance H2 between the third flat portion 11f and the sixth flat portion 12f. When engaging the portions 21a to 21d with the first guide hole 11 and the second guide hole 12, the first to fourth claw portions 21a to 21d are engaged while being elastically deformed in the direction of arrow C.

The width dimension W1 of the engagement margin between the claw part 21 and the sliding part 13 and the width dimension W2 of the gap between the fourth claw part 21d and the fourth recess 12e are:
W1 <W2 (Formula 2)
Therefore, the fourth claw portion 21d can be elastically deformed to a deformation amount that can be engaged with the second guide hole 12. The gap between the first recess 11d and the first claw portion 21a, the gap between the second recess 11e and the second claw portion 21b, and the gap between the third recess 12d and the third claw portion 21c, Each is the same size as W2.

  Furthermore, when the 1st-4th nail | claw part 21a-21d is inserted in the 1st guide hole 11 and the 2nd guide hole 12 until the back surface of the slide knob 2 contact | abuts or adjoins to the bottom face of the recessed part 1c, The first to fourth claw portions 21a to 21d are elastically restored, and the engaging portion 21f formed at the tip of each claw portion is positioned so as to overlap the sliding portion 13 on the projection surface. Thereby, the movement of the first to fourth claw portions 21a to 21d in the separation direction is restricted.

  As described above, the slide knob 2 is mounted in the recess 1c of the first housing 1a.

  Next, the first casing 1a on which the slide knob 2 is mounted is mounted on the second casing 1b. At this time, the slide knob 2 is arranged at the third position shown in FIG. 3A, and the operation lever 3a of the switch element 3 arranged in the second casing 1b is located at the center, so that the first When one housing 1a is mounted on the second housing 1b, the operation lever 3a is fitted into the recess 21e. Thereby, the assembly of the remote control unit is completed.

  Next, the operation of the slide switch device will be described.

  In the present embodiment, since the three-contact switching type switch element 3 is used, the slide position of the slide knob 2 is three (first to third positions). 3A shows the third position, FIG. 4 shows the first position, and FIG. 5 shows the second position.

  First, when the slide knob 2 is slid to the first position shown in FIG. 4, the first claw portion 21a moves to a position sandwiched between the first flat portion 11a and the third flat portion 11f. The second claw portion 21b moves to a position sandwiched between the first triangular protrusion 11c and the third flat portion 11f. The third claw portion 21c moves to a position sandwiched between the fourth flat portion 12a and the sixth flat portion 12f. The fourth claw portion 21d moves to a position sandwiched between the second triangular protrusion 12c and the sixth flat portion 12f.

At this time, the gap between the third claw portion 21c and the fourth flat portion 12a is W7, the gap between the fourth claw portion 21d and the second triangular protrusion 12c is W8, the third claw portion 21c or the fourth claw portion 4c. When the engagement between the claw portion 21d and the sliding portion 13 is W1,
W7 <W1 (Formula 3)
W8 <W1 (Formula 4)
Are in a relationship. Note that the clearance between the first claw portion 21a and the first flat portion 11a and the engagement margin between the first claw portion 21a or the second claw portion 21b and the sliding portion 13 are the same as in Equation 3. There is a relationship. Further, the clearance between the second claw portion 21b and the first triangular protrusion 11c and the engagement margin between the first claw portion 21a or the second claw portion 21b and the sliding portion 13 are the same as those in Equation 4. There is a relationship.

  Therefore, the third claw portion 21c and the fourth claw portion 21d do not elastically deform greatly in the direction of arrow C shown in FIG. 3B, and the engagement with the first guide hole 11 and the second guide hole 12 is not caused. It is in a state that cannot be removed. That is, in the state shown in FIG. 4, when the third claw portion 21c and the fourth claw portion 21d are elastically deformed, the third claw portion 21c comes into contact with the fourth flat portion 12a, and the fourth claw portion 21d abuts on the second triangular protrusion 12c and cannot be further elastically deformed. At this time, since the third claw portion 21c and the fourth claw portion 21d have the relations of the mathematical expressions 3 and 4, there is an allowance for the sliding portion 13. Therefore, it is difficult or impossible to release the engagement state between the third claw portion 21c and the fourth claw portion 21d and the second guide hole 12.

  The same applies to the first claw portion 21a and the second claw portion 21b. Even if the first claw portion 21a is elastically deformed in the direction of arrow C in FIG. 3B, the first claw portion 21a contacts the first flat portion 11a. The second claw portion 21b contacts the first triangular protrusion 11c. At this time, since the first claw portion 21a and the second claw portion 21b have the same relationship as the mathematical formulas 3 and 4, there is a margin for the sliding portion 13. Therefore, it is difficult or impossible to release the engagement state between the first claw portion 21 a and the second claw portion 21 b and the first guide hole 11.

  As described above, when the slide knob 2 is in the first position shown in FIG. 4, it is in a state where it cannot be easily detached from the first housing 1a.

  On the other hand, when the slide knob 2 is slid to the second position shown in FIG. 5, the first claw portion 21a moves to a position sandwiched between the first triangular protrusion 11c and the third flat portion 11f. The second claw portion 21b moves to a position sandwiched between the second flat portion 11b and the third flat portion 11f. The third claw portion 21c moves to a position sandwiched between the second triangular protrusion 12c and the sixth flat portion 12f. The fourth claw portion 21d moves to a position sandwiched between the fifth flat portion 12b and the sixth flat portion 12f.

At this time, the gap between the fourth claw portion 21d and the fifth flat portion 12b is W9, the gap between the third claw portion 21c and the second triangular protrusion 12c is W10, the third claw portion 21c or the fourth claw portion 4c. When the engagement between the claw portion 21d and the sliding portion 13 is W1,
W9 <W1 (Formula 5)
W10 <W1 (Formula 6)
Are in a relationship. The clearance between the first claw portion 21a and the first triangular protrusion 11c and the engagement margin between the first claw portion 21a or the second claw portion 21b and the sliding portion 13 are the same as in Formula 5. There is a relationship. Further, the clearance between the second claw portion 21b and the second flat portion 11b and the engagement margin between the first claw portion 21a or the second claw portion 21b and the sliding portion 13 are the same as those in Expression 6. There is a relationship.

  Therefore, the third claw portion 21c and the fourth claw portion 21d do not elastically deform greatly in the direction of arrow C shown in FIG. 3B, and the engagement with the first guide hole 11 and the second guide hole 12 is not caused. It is in a state that cannot be removed. That is, in the state shown in FIG. 5, when the third claw portion 21c and the fourth claw portion 21d are elastically deformed, the third claw portion 21c comes into contact with the second triangular protrusion 12c, and the fourth claw portion 21d contacts the fifth flat portion 12b and cannot be further elastically deformed. At this time, since the third claw portion 21c and the fourth claw portion 21d have the relations of Formulas 5 and 6, there is a margin for the sliding portion 13. Therefore, it is difficult or impossible to release the engagement state between the third claw portion 21c and the fourth claw portion 21d and the second guide hole 12.

  The same applies to the first claw portion 21a and the second claw portion 21b. Even if the first claw portion 21a is elastically deformed in the direction of arrow C in FIG. 3B, the first claw portion 21a contacts the first triangular protrusion 11c. The second claw portion 21b comes into contact with the second flat portion 11b and cannot be further elastically deformed. At this time, since the first claw portion 21a and the second claw portion 21b have the same relationship as the mathematical formulas 5 and 6, there is a margin for the sliding portion 13. Therefore, it is difficult or impossible to release the engagement state between the first claw portion 21 a and the second claw portion 21 b and the first guide hole 11.

  As described above, when the slide knob 2 is in the second position shown in FIG. 5, it is in a state where it cannot be easily detached from the first housing 1a.

  When the slide knob 2 is slid to the third position shown in FIG. 3A, the first claw portion 21a moves to a position facing the first recess 11d, and the second claw portion 21b moves to the second position. The third claw portion 21c moves to a position facing the third recess 12d, and the fourth claw portion 21d moves to a position facing the fourth recess 12e. Therefore, since the flat portion and the triangular protrusion are not at positions where elastic deformation of the first to fourth claw portions 21a to 21d can be restricted, the first to fourth claw portions 21a to 21d are indicated by arrows shown in FIG. 3B. It will be in the state which can be greatly elastically deformed to C direction. Therefore, when the pulling force is applied to the slide knob 2 in the direction indicated by the arrow B (see FIG. 1), the first to fourth claw portions 21a are compared with the case where the slide knob 2 is in the first position or the second position. ˜21d is likely to be disengaged from the first guide hole 11 and the second guide hole 12, and the slide knob 2 is likely to be detached from the first housing 1a.

However, as shown in FIG. 3A, when the slide knob 2 is in the third position, the width dimension of the gap from the longitudinal end of the recess 1c to the longitudinal end of the slide knob 2 is T1, the first The width dimension of the gap from the longitudinal end of the recess 1c to the longitudinal end of the slide knob 2 at the position is T2 (see FIG. 4), and the longitudinal dimension of the slide knob 2 from the longitudinal end of the recess 1c at the second position. When the width dimension of the gap to the direction end is T3 (see FIG. 5),
T1 <T2 (Formula 7)
T1 <T3 (Formula 8)
(In this embodiment, T1≈T3 / 2, T1≈T2 / 2)
It becomes a relationship. Therefore, when the slide switch 2 is in the third position, it is unlikely that a user's finger or clothes will be accidentally caught on the longitudinal end of the slide knob 2, and the slide knob 2 is in the first casing. The possibility of leaving 1a is low.

  As described above, according to the present embodiment, the first flat portion 11a, the second flat portion 11b, the first guide hole 11 and the second guide hole 12 that hold the slide knob 2 slidably, By forming the third flat part 11f, the first triangular protrusion 11c, the fourth flat part 12a, the fifth flat part 12b, the third flat part 12f, and the second triangular protrusion 12c, a slide knob is formed. When 2 is in the first position or the second position, the first to fourth claw portions 21a to 21d may not be easily detached from the first guide hole 11 and the second guide hole 12. it can. Therefore, even if a force is applied to the slide knob 2 in the separating direction (the direction of arrow B shown in FIG. 1), it can be prevented that the slide knob 2 is easily detached from the remote control unit 1.

  In addition, since the configuration for preventing the slide knob 2 from being detached is realized only by devising the shape of the guide hole, the number of parts can be increased and the cost can be reduced.

  Further, since the first concave portion 11d, the second concave portion 11e, the third concave portion 12d, and the fourth concave portion 12e are formed, the slide knob 2 can be easily inserted into the first guide hole 11 when the slide switch device is assembled. And it can be made to engage with the 2nd guide hole 12, and an assemblability can be improved.

  In the present embodiment, two pairs of claw portions (first to fourth claw portions 21a to 21d) are provided, but the effect of the present invention can be obtained as long as the number of pairs is one or more.

  Further, the shape of the triangular protrusion is not limited to a triangle, and may be other shapes such as a quadrangle and a semicircle. Any shape that can restrict elastic deformation of the claw portion may be used.

  Further, in each guide hole, the number of restricting portions (triangular protrusions in the present embodiment) formed other than both ends is not limited to one, and two or more restricting portions may be provided. By providing two or more, it is possible to deal with switching elements having four or more contacts.

(Embodiment 2)
Next, the configuration of the slide switch device according to the second embodiment will be described. 6 to 8 show the configuration of the slide switch device in the second embodiment, the same components as those in the first embodiment described above are given the same reference numerals and detailed description thereof is omitted. Omitted.

  FIG. 6 is a plan view showing the configuration of the slide switch device according to the second embodiment, and shows a state in which the slide knob 2 is in the first position. FIG. 7 shows a state where the slide knob 2 is in the second position. FIG. 8 shows a state in which the slide knob 2 is in the third position.

  The slide switch device according to the second embodiment is different from the slide switch device according to the first embodiment in the shape of the guide hole that holds the slide knob 2. The guide holes are formed independently in the first guide hole and the second guide hole in the first embodiment, respectively, but in the second embodiment, one guide hole 31 is formed.

  The guide hole 31 is formed in a substantially H shape as shown in FIG. The guide hole 31 includes a first flat portion 31a, a second flat portion 31b, a third flat portion 31c, a fourth flat portion 31d, a fifth flat portion 31e, and a sixth flat portion 31f. Is formed. The 1st flat part 31a, the 2nd flat part 31b, and the 5th flat part 31e are formed in the movement range of the 1st nail | claw part 21a and the 2nd nail | claw part 21a. The third flat portion 31c, the fourth flat portion 31d, and the sixth flat portion 31f are formed within the movement range of the third claw portion 21c and the fourth claw portion 21d. Further, the first flat portion 31a and the second flat portion 31b are formed to face a part of the fifth flat portion 31e and be substantially parallel to each other. The third flat part 31c and the fourth flat part 31d are opposed to a part of the sixth flat part 31f and are formed substantially in parallel. The fifth flat portion 31e and the sixth flat portion 31f are formed substantially parallel to each other, and are formed so as to partially face each other. In addition, the control part is comprised by the 1st-4th flat parts 31a-31d.

  Hereinafter, the sliding operation will be described.

  In the present embodiment, since the three-contact switching type switch element 3 is used, the slide position of the slide knob 2 is three (first to third positions).

  First, when the slide knob 2 is slid to the first position shown in FIG. 6, the first claw portion 21a moves to a position sandwiched between the first flat portion 31a and the fifth flat portion 31e, The second claw portion 21b moves to a position facing only the fifth flat portion 31e, and the third claw portion 21c moves to a position sandwiched between the third flat portion 31c and the sixth flat portion 31f, The fourth claw portion 21d moves to a position facing only the sixth flat portion 31f.

At this time, the engagement margin of the first claw portion 21a with respect to the sliding portion 13 is W11, the gap between the first claw portion 21a and the first flat portion 31a is W12, and the sliding portion 13 of the third claw portion 21c. When the wage for W13 is W13 and the gap between the third claw portion 21c and the third flat portion 31c is W14,
w12 <w11 (Formula 9)
w14 <w13 (Equation 10)
Are in a relationship.

  Accordingly, the first claw portion 21a and the third claw portion 21c are not greatly elastically deformed, and are not easily disengaged from the guide hole 31. That is, in the state shown in FIG. 6, when the first claw portion 21a and the third claw portion 21c are elastically deformed, the first claw portion 21a comes into contact with the first flat portion 31a, and the third claw portion 21c abuts on the third flat portion 31c and cannot be further elastically deformed. At this time, since the first claw portion 21a and the third claw portion 21c have the relationship of Expressions 9 and 10, there is a margin for the sliding portion 13. Therefore, it is difficult or impossible to release the engagement state between the first claw portion 21 a and the third claw portion 21 c and the guide hole 31.

  As described above, when the slide knob 2 is in the first position shown in FIG. 6, it is in a state where it cannot be easily detached from the first housing 1a.

  On the other hand, when the slide knob 2 is slid to the second position shown in FIG. 7, the first claw portion 21a moves to a position facing only the fifth flat portion 31e. The 2nd nail | claw part 21b moves to the position pinched | interposed by the 2nd flat part 31b and the 5th flat part 31e. The third claw portion 21c moves to a position facing only the sixth flat portion 31f. The fourth claw portion 21d moves to a position sandwiched between the fourth flat portion 31d and the sixth flat portion 31f.

At this time, the engagement margin of the second claw portion 21b with respect to the sliding portion 13 is W15, the gap between the second claw portion 21b and the second flat portion 31b is W16, and the sliding portion 13 of the fourth claw portion 21d. When the engagement allowance is W17 and the gap between the fourth claw portion 21d and the fourth flat portion 31d is W18,
W16 <W15 (Formula 11)
W18 <W17 (Formula 12)
Are in a relationship.

  Therefore, the second claw portion 21b and the fourth claw portion 21d are not greatly elastically deformed and are not easily disengaged from the guide hole 31. That is, in the state shown in FIG. 7, when the second claw portion 21b and the fourth claw portion 21d are elastically deformed, the second claw portion 21b comes into contact with the second flat portion 31b, and the fourth claw portion 21d abuts on the fourth flat portion 31d and cannot be further elastically deformed. At this time, since the second claw portion 21b and the fourth claw portion 21d have the relations of Expressions 11 and 12, there is a margin for the sliding portion 13. Therefore, it is difficult or impossible to release the engagement state between the second claw portion 21b and the fourth claw portion 21d and the guide hole 31.

  As described above, when the slide knob 2 is in the second position shown in FIG. 7, it is in a state where it cannot be easily detached from the first housing 1a.

  Further, when the slide knob 2 is slid to the third position shown in FIG. 8, the first claw portion 21a and the second claw portion 21b move to positions facing only the fifth flat portion 31e. Moreover, the 3rd nail | claw part 21c and the 4th nail | claw part 21d move to the position which opposes only the 6th flat part 31f. Accordingly, the first to fourth claw portions 21a to 21d are greatly elastically deformable. Therefore, when the pulling force is applied to the slide knob 2 in the direction indicated by the arrow B (see FIG. 1), the first to fourth claw portions 21a are compared with the case where the slide knob 2 is in the first position or the second position. ˜21d is likely to be disengaged from the guide hole 31, and the slide knob 2 is likely to be detached from the first housing 1a.

However, as shown in FIG. 8, when the slide knob 2 is in the third position, the width dimension of the gap from the longitudinal end of the recess 1c to the longitudinal end of the slide knob 2 is T11, The width dimension of the gap from the longitudinal end of the recess 1c to the longitudinal end of the slide knob 2 at the position is T12 (see FIG. 6), and the longitudinal dimension of the slide knob 2 from the longitudinal end of the recess 1c at the second position. When the width dimension of the gap to the direction end is T13 (see FIG. 7),
T11 <T12 (Formula 13)
T11 <T13 (Formula 14)
(In this embodiment, T11≈T13 / 2, T11≈T12 / 2)
It becomes a relationship. Therefore, when the slide switch 2 is in the third position, it is unlikely that a user's finger or clothes will be accidentally caught on the longitudinal end of the slide knob 2, and the slide knob 2 is in the first casing. The possibility of leaving from 1a is low.

  As described above, according to the present embodiment, the first flat portion 31a, the second flat portion 31b, the third flat portion 31c, and the fourth flat portion are provided in the guide hole 31 that slidably holds the slide knob 2. By forming the flat portion 31d, the fifth flat portion 31e, and the sixth flat portion 31f, when the slide knob 2 is in the position of the first position, the first claw portion 21a is moved to the first flat portion. The third claw portion 21c can be sandwiched between the third flat portion 31c and the sixth flat portion 31f. Therefore, the first claw portion 21 a and the third claw portion 21 c can be prevented from being easily detached from the guide hole 31. When the slide knob 2 is in the second position, the second claw portion 21b is sandwiched between the second flat portion 31b and the fifth flat portion 31e, and the fourth claw portion 21d is clamped to the fourth flat portion 31d. And the sixth flat part 31f. Therefore, the second claw portion 21 b and the fourth claw portion 21 d can be prevented from easily coming off from the guide hole 31. Therefore, even if a force is applied to the slide knob 2 in the separating direction, it can be prevented that the slide knob 2 is easily detached from the remote control unit 1.

  In addition, since the structure for preventing the slide knob 2 from being detached is realized only by devising the shape of the guide hole, the number of parts does not increase and the cost is not significantly increased. That is, it can be realized with a small number of parts and low cost.

  Further, by providing the third position where only one flat portion is opposed to each claw portion, when assembling the slide switch device, the slide knob 2 can be easily engaged with the guide hole 31, and the assemblability is improved. Can be improved.

  In the present embodiment, the slide switch 2 is configured to be slidable at three positions (first to third positions), but at two positions such as power on / off switching. Even if it is a structure which can be slid to 4 positions or more, it can be realized with a structure similar to the above structure.

  The slide knob mounting structure according to the present invention can be used for electronic devices such as recording / reproducing apparatuses that require a slide switch, regardless of whether the slide knob is small or large.

The perspective view which shows the external appearance of the remote control unit in which the slide switch apparatus in Embodiment 1 of this invention is mounted. The perspective view of the slide switch apparatus in Embodiment 1 Plan view of slide switch device according to Embodiment 1 (third position) Sectional drawing of the ZZ part in FIG. 3A Plan view of slide switch device according to Embodiment 1 (first position) Plan view of slide switch device according to Embodiment 1 (second position) Plan view of slide switch device according to Embodiment 2 (first position) Plan view of the slide switch device according to the second embodiment (second position) Plan view of slide switch device according to embodiment 2 (third position) The perspective view which shows the structure of the remote control unit in which the conventional slide switch apparatus is mounted.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Remote control unit 1a 1st housing | casing 1b 2nd housing | casing 2 Slide knob 11 1st guide hole 11a 1st flat part 11b 2nd flat part 11c 1st triangular protrusion 11d 1st recessed part 11e 2nd 11f 3rd flat part 12 2nd guide hole 12a 4th flat part 12b 5th flat part 12c 2nd triangular projection 12d 3rd recessed part 12e 4th recessed part 12f 6th flat part 21 nail Part 21a first claw part 21b second claw part 21c third claw part 21d fourth claw part 31 guide hole 31a first flat part 31b second flat part 31c third flat part 31d fourth Flat part 31e 5th flat part 31f 6th flat part

Claims (3)

A housing in which a guide hole is formed;
A claw that is slidably disposed between the first position and the second position along the guide hole and that is elastically deformable in a direction substantially perpendicular to the slide direction and is engaged with the guide hole. A slide knob in which a part is formed,
A switch element that is engaged with the slide knob and is switched according to a slide operation of the slide knob;
The guide hole has an opening width that is detachable while elastically deforming the claw portion.
A slide switch device,
At least at both ends of the guide hole, the opening width is narrower than the other part, and includes a restricting portion that restricts elastic deformation of the claw portion so that the engagement state between the claw portion and the guide hole is not released,
The slide switch device is configured such that when the slide knob reaches the first position or the second position, elastic deformation of the claw portion is restricted by the restricting portion. The regulation part is
A first restricting portion formed at one end of the guide hole;
A second restricting portion formed at the other end of the guide hole;
A third restricting portion formed between the first restricting portion and the second restricting portion;
The guide hole is
The claw portion is elastically deformed between at least one of the first restricting portion and the third restricting portion or between the second restricting portion and the third restricting portion. While having a wide portion having an opening width detachable with respect to the guide hole,
The slide switch device according to claim 1. A remote control device equipped with a slide switch device capable of remotely operating electronic devices and capable of sliding operations,
The slide switch device is
A housing in which a guide hole is formed;
A claw that is slidably disposed between the first position and the second position along the guide hole and that is elastically deformable in a direction substantially perpendicular to the slide direction and is engaged with the guide hole. A slide knob in which a part is formed,
A switch element that is engaged with the slide knob and is switched according to a slide operation of the slide knob;
The guide hole has an opening width that is detachable while elastically deforming the claw portion,
At least at both ends of the guide hole, the opening width is narrower than the other part, and includes a restricting portion that restricts elastic deformation of the claw portion so that the engagement state between the claw portion and the guide hole is not released,
The remote control device, wherein the claw portion is configured to be restricted from elastic deformation by the restricting portion when the slide knob reaches the first position or the second position.

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