JP2017112090A - Operating device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an operating device including a click mechanism provided in a scroll wheel, the operating device being excellent in assembling properties and providing good click feeling.SOLUTION: An operating device including a scroll wheel 120 includes: a stationary shaft 140 inserted into a ring-shaped inside of the scroll wheel and rotatably supporting the scroll wheel while the stationary shaft is not rotatable; a wave-shaped section 121a formed on the inner peripheral surface of the scroll wheel; a hole section 144 formed recessed beyond the position of the center of the stationary shaft from a predetermined outer peripheral surface position in the axial direction of the stationary shaft, the predetermined outer peripheral surface position corresponding to the wave-shaped section; an elastic member 160 inserted into the hole section; and a click pin 150 sliding along the inner peripheral surface of the hole section, the front end portion of the click pin being energized against the wave-shaped section by the elastic member.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an operating device that performs input to a predetermined device by rotating a scroll wheel.

  As a conventional operation device, for example, an operation device described in Patent Document 1 is known. The operating device (camera dial operating device) of Patent Document 1 is arranged on the upper side of a plate-like appearance member, and is operated by a flat umbrella-shaped dial member that is rotated and an operator when the dial member is rotated. And a click mechanism that gives a click feeling to the.

  A shaft portion extending toward the umbrella-shaped opening is formed at the center of rotation of the dial member. Further, a wavy friction sliding portion that is continuous in the circumferential direction is formed on the inner peripheral surface of the dial member. On the other hand, the plate-like appearance member is provided with a flat cylindrical protrusion that protrudes along the internal space of the dial member. A shaft hole is provided at the center of the projecting portion, and the shaft portion of the dial member is inserted into the shaft hole so that the dial member is rotatably supported. Moreover, the hole part dug toward the axial part side of the dial member is formed in the predetermined position of the surrounding surface of a protrusion part. A ball as a sliding member is disposed near the opening of the hole, and a coil spring that urges the ball toward the wavy friction sliding part is accommodated in the hole. The wavy friction sliding portion, the hole, the ball, and the coil spring form a click mechanism.

  In the operation device of Patent Document 1, when the dial member is rotated, the ball moves in the radial direction of the dial member along the wavy friction sliding portion, and a click feeling at the time of the rotation operation can be obtained. ing.

JP-A-7-28151

  However, the operating device of Patent Document 1 has a structure in which the shaft portion of the dial member is inserted into the shaft hole of the protruding portion, and therefore the depth dimension of the hole portion for the click mechanism is restricted by the shaft portion. Therefore, the sliding member (ball) provided in the hole and the dimension of the coil spring in the radial direction of the dial member are naturally limited.

  Therefore, the sliding member is already in a state where it can be easily dropped from the hole when the sliding member is set in the hole, and the assembly of the dial member to the protruding portion seems to be poor. Moreover, since the dimension of the coil spring is restricted, it is difficult to generate a good biasing force against the sliding member, and it seems that a good click feeling is difficult to obtain.

  In view of the above problems, an object of the present invention is to provide an operating device that is provided with a click mechanism in a scroll wheel and is excellent in assembling of the click mechanism and can provide a good click feeling.

  In order to achieve the above object, the present invention employs the following technical means.

In the present invention, in an operating device including a scroll wheel (120) rotated by an operator for input to a predetermined device,
The scroll wheel has a ring shape, part of which protrudes from an opening (112) formed in the operation surface (111) on the operator side of the casing (110), and extends in a direction along the operation surface within the casing. The axial direction is formed,
A rotation shaft (130) provided on one side of the scroll wheel in the axial direction and rotating together with the scroll wheel;
On the other side of the scroll wheel in the axial direction, a fixed shaft (140) that is inserted into a ring-like interior and is non-rotating and rotatably supports the scroll wheel;
On the inner peripheral surface of the scroll wheel, a wave shape portion (121a) formed so that the wave shape is continuous in the circumferential direction;
A hole (144) dug beyond the center position of the fixed shaft from a predetermined outer peripheral surface position corresponding to the corrugated portion in the axial direction of the fixed shaft;
An elastic member (160) inserted into the hole;
And a click pin (150) that slides along the inner peripheral surface of the hole and whose tip is urged toward the corrugated portion by an elastic member.

  According to this invention, a wave shape part, a click pin, and an elastic member (click mechanism) can be arrange | positioned inside a scroll wheel, and the space for providing a click mechanism in the outer side of a scroll wheel is not required.

  And since the hole part is dug deeply beyond the center position of the fixed shaft, the degree of freedom in setting the dimension of the elastic member and the click pin in the hole depth direction can be increased. Therefore, the click pin can be formed to be elongated along the depth direction of the hole, and the sliding area can be increased along the inner peripheral surface of the hole, so click from the hole before assembly. The pin can be made difficult to fall off. And it becomes possible to assemble | attach the fixed axis | shaft in which the click pin was set with respect to a scroll wheel easily. In addition, since the degree of freedom in setting the dimensions of the elastic member can be increased, setting of the urging force for the click pin by the elastic member becomes easy.

  In general, in the case where the click mechanism is provided in the scroll wheel, it is possible to provide an operating device that is excellent in assemblability of the click mechanism and that provides a good click feeling.

  In addition, the code | symbol in the bracket | parenthesis of each said means shows a corresponding relationship with the specific means of embodiment description mentioned later.

It is sectional drawing which shows the whole structure of the operating device of 1st Embodiment. It is the arrow view seen from the II direction of FIG. It is an exploded view which shows the rotating shaft and fixed shaft in the scroll wheel of 1st Embodiment. It is sectional drawing which shows the III-III part of FIG. It is sectional drawing which shows the IV-IV part of FIG. It is sectional drawing which shows the whole structure of the operating device of 2nd Embodiment. It is an exploded view which shows the rotating shaft and fixed shaft in the scroll wheel of 2nd Embodiment.

  A plurality of modes for carrying out the present invention will be described below with reference to the drawings. In each embodiment, parts corresponding to the matters described in the preceding embodiment may be denoted by the same reference numerals, and redundant description may be omitted. When only a part of the configuration is described in each mode, the other modes described above can be applied to the other parts of the configuration. Not only combinations of parts that clearly indicate that the combination is possible in each embodiment, but also a combination of the embodiments even if they are not clearly specified unless there is a problem with the combination. It is also possible.

(First embodiment)
The operating device 100 of 1st Embodiment is demonstrated using FIGS. 1-5. The operating device 100 is, for example, a device for changing (inputting) a set value of a predetermined control item in a vehicle air conditioner (predetermined device), and is provided in a center console of the vehicle. Here, the operating device 100 changes, for example, the set temperature of the conditioned air as a predetermined control item. The operating device 100 includes a casing 110, a scroll wheel 120, a rotating shaft 130, a fixed shaft 140, a click pin 150, a spring 160, a display 170, and the like. Each member excluding the spring 160 (steel material) and the indicator 170 is made of, for example, a resin material.

  The casing 110 is a box-shaped member that accommodates each member constituting the operating device 100, and includes an operation surface 111, an opening 112, support walls 113 to 115, and the like.

  The operation surface 111 is a surface on the operator (hereinafter, occupant) side of the casing 110 and forms an operation panel for air conditioning. The surface of the operation surface 111 is basically coated with, for example, a light-shielding paint and serves as a light-shielding portion. However, a region corresponding to the display 170 on the operation surface 111 is a portion where light-shielding coating is not applied and is a light-transmitting portion.

  The opening 112 is a hole for causing a part of the scroll wheel 120 to protrude toward the occupant side. A gap 112 a is formed between the opening 112 and the scroll wheel 120 around the opening 112.

  The support wall 113 is a member that supports the rotation shaft 130 (first shaft portion 131), and is provided on one side of the scroll wheel 120 in the axial direction in the casing 110 and intersects the operation surface 111. The wall surface is formed in. As shown in FIG. 4, the support wall 113 is formed in a U shape. The support wall 113 has a semicircular receiving portion 113a that receives the rotation shaft 130, and an opening 113b that opens from the receiving portion 113a to the operation surface 111 side. A rotating shaft 130 is inserted into the receiving portion 113a from the opening 113b side, and the support wall 113 rotatably supports the rotating shaft 130 by the receiving portion 113a.

  The support wall 114 is a member that supports the rotating shaft 130 (second shaft portion 132). A parallel wall surface is adjacent to the support wall 113 on the opposite side of the scroll wheel 120 in the casing 110. Forming. As shown in FIG. 5, the support wall 114 is formed in a C shape. The support wall 114 has a C-shaped receiving portion 114a that receives the rotation shaft 130, and an opening 114b that opens from the receiving portion 114a to the operation surface 111 side.

  The plate thickness of the support wall 114 is set such that the opening 114b can be elastically deformed in the radial direction (left-right direction in FIG. 5). The rotating shaft 130 is inserted into the receiving portion 114a from the opening 114b side. When the rotating shaft 130 is inserted into the receiving portion 114a, the opening 114b bends so as to expand outward in the radial direction, and after being inserted, the opening 114b returns to the inner side in the radial direction. Yes. The support wall 114 supports the rotary shaft 130 in a rotatable manner and restricts the position in the radial direction.

  The support wall 115 is a member that supports the fixed shaft 140 (fixed portion 141). The support wall 115 is provided on the other side in the axial direction of the scroll wheel 120 in the casing 110 and has a wall surface in a direction intersecting the operation surface 111. Is forming. The support wall 115 is provided with a locking hole 115 a for locking the locking claw 141 a of the fixed shaft 140. The support wall 115 is provided with a plurality of wall portions that are in surface contact with the fixed shaft 140 such that the fixed shaft 140 does not rotate. The support wall 115 is a wall for fixing (non-rotating) the fixed shaft 140.

  The scroll wheel 120 is a member that is rotated by an occupant to change (input) the set temperature of the conditioned air to the air conditioner, and is formed in a ring shape. A part of the scroll wheel 120 protrudes from the opening 112 of the operation surface 111 and is axially supported in the casing 110 in a direction along the operation surface 111. For example, when the operating point on the outer peripheral surface of the scroll wheel 120 is rotated to one side in the rotational direction, the operating point of the scroll wheel 120 is changed to the rotational direction. When it is rotated to the other side, the set temperature of the conditioned air is changed to a smaller side.

  A cylindrical portion 121 is provided on the inner peripheral surface of the scroll wheel 120. The cylindrical portion 121 is a bottomed cylindrical member, and the bottom surface of the cylindrical portion 121 is disposed on one side in the axial direction of the scroll wheel 120. The cylindrical portion 121 is inserted into the ring-shaped scroll wheel 120, and the outer peripheral surface of the cylindrical portion 121 is fixed to the inner peripheral surface of the scroll wheel 120. The inner peripheral surface of the cylindrical portion 121 forms the inner peripheral surface of the scroll wheel 120.

  The axial length of the cylindrical part 121 is set to be equal to or slightly shorter than the axial length of the scroll wheel 120. On the inner peripheral surface of the cylindrical portion 121, a wave shape portion 121a is formed at an intermediate position in the axial direction. The wave-shaped portion 121a constitutes a click mechanism, and is a concavo-convex portion continuous in the circumferential direction of the cylindrical portion 121 like an internal gear. The inner diameter (wave part inner diameter) of the corrugated part 121a is the dimension Dw (FIG. 3).

  A first sliding surface 121b is formed on the inner peripheral surface of the cylindrical portion 121 on the rotating shaft 130 side of the corrugated portion 121a. The first sliding surface 121b is a surface that is supported by the first receiving portion 142 (outer peripheral surface) of the fixed shaft 140 and rotates and slides. An inner diameter (first inner diameter) of the first sliding surface 121b is a dimension D1 (FIG. 3).

  A second sliding surface 121c is formed on the inner peripheral surface of the cylindrical portion 121 on the opposite side of the corrugated portion 121a from the rotating shaft 130. The second sliding surface 121c is a surface that is supported by the second receiving portion 143 (outer peripheral surface) of the fixed shaft 140 and rotates and slides. The inner diameter (second inner diameter) of the second sliding surface 121c is a dimension D2 (FIG. 3).

  In the present embodiment, the wave portion inner diameter Dw, the first inner diameter D1, and the second inner diameter D2 are set such that the first inner diameter D1 <the wave portion inner diameter Dw <the second inner diameter D2. That is, the inner diameter is set so as to decrease in order from the opening side of the cylindrical portion 121 toward the bottom surface side.

  A recessed portion 121 d that is recessed toward the rotating shaft 130 is formed at the center position of the bottom surface of the cylindrical portion 121. The convex portion 145 of the fixed shaft 140 enters the concave portion 121d.

  The rotating shaft 130 is fixed to one side of the scroll wheel 120 in the axial direction, that is, the center position of the bottom surface of the cylindrical portion 121 fixed to the scroll wheel 120 and is a member that rotates together with the scroll wheel 120 and the cylindrical portion 121. ing. The rotating shaft 130 includes a first shaft portion 131, a second shaft portion 132, a gear portion 133, a flange portion 134, and the like. The first shaft portion 131, the second shaft portion 132, the gear portion 133, and the flange portion 134 are integrally molded products made of a resin material together with the cylindrical portion 121.

  The first shaft part 131 is an axis extending from the center position of the bottom surface of the cylindrical part 121. The second shaft portion 132 is a shaft connected to be coaxial with the first shaft portion 131, and has a larger shaft diameter than the first shaft portion 131.

  The gear portion 133 is connected to the distal end portion of the second shaft portion 132 and serves as an output gear that outputs the rotational force of the scroll wheel 120. For example, a rotation detection mechanism is connected to the gear unit 133 so that the rotation state (the rotation direction, the rotation amount, and the like) of the scroll wheel 120 can be detected. In the center region of the gear portion 133, a thinning portion 133a is provided for suppressing the shrinkage of the tooth portion during resin molding.

  The flange portion 134 is a disk-shaped member provided between the scroll wheel 120 and the gear portion 133 on the rotating shaft 130. Here, the collar portion 134 is provided between the first shaft portion 131 and the second shaft portion 132. The outer diameter of the collar part 134 is set to be larger than the outer diameter of the gear part 133. The collar part 134 is a member corresponding to the blocking part of the present invention, and prevents foreign matter that has entered from the gap 112a from moving to the gear part 133 side.

  The dimension between the bottom surface of the cylindrical part 121 (the axial end part of the scroll wheel 120) and the flange part 134 is set to be slightly larger than the plate thickness dimension of the support wall 113. The support wall 113 is sandwiched between the bottom surface of the cylindrical portion 121 and the flange portion 134. Therefore, the axial position of the rotation shaft 130 (first shaft portion 131) is regulated with respect to the support wall 113 by the bottom surface of the cylindrical portion 121 and the flange portion 134.

  The fixed shaft 140 is partially inserted in the scroll wheel 120 (inside the cylinder part 121) in the axial direction, and is not rotated to rotate the scroll wheel 120, the cylinder part 121, and the rotary shaft 130. It is a supporting member. The fixed shaft 140 includes a fixed portion 141, a first receiving portion 142, a second receiving portion 143, a hole portion 144, a convex portion 145, and the like.

  The fixing portion 141 is a portion that is fixed to the support wall 115. For example, the fixing portion 141 has a quadrangular cross-sectional shape, and a locking claw 141a is provided at an axial end portion. One or more surfaces of the outer peripheral surface of the fixed portion 141 are in contact with a contact surface provided on the support wall 115 to prevent rotation around the axis. The locking claw 141a is locked in the locking hole 115a. Note that the radial dimension of the fixed portion 141 (here, the dimension of one side of the rectangular cross section) is set to be smaller than the inner diameter (second inner diameter D2) of the cylindrical portion 121.

  The first receiving portion 142 is provided at a position corresponding to the first sliding surface 121 b of the cylindrical portion 121 at the tip end opposite to the fixed portion 141. The first receiving portion 142 has a circular cross-sectional shape and is a portion that receives the first sliding surface 121b (first inner diameter D1) by the outer peripheral surface.

  The second receiving portion 143 is provided between the fixed portion 141 and the first receiving portion 142 at a position corresponding to the second sliding surface 121c of the cylindrical portion 121. The second receiving portion 143 has a circular cross-sectional shape and is a portion that receives the second sliding surface 121c (second inner diameter D2) by the outer peripheral surface. The outer diameter of the second receiving portion 143 is set larger than the outer diameter of the first receiving portion 142 and is formed in a disc shape. In addition, a columnar portion having the same outer diameter as that of the first receiving portion 142 is formed between the first receiving portion 142 and the second receiving portion 143.

  In the cylindrical portion, the hole portion 144 extends from a predetermined outer peripheral surface position corresponding to the corrugated portion 121a of the cylindrical portion 121 to the outer peripheral surface on the side facing the virtual center line position (center position). Thus, the portion is deeply dug so as to have a predetermined bottom plate thickness. Note that a lubricant (such as grease) for improving the slidability of the click pin 150 may be provided on the inner peripheral surface of the hole 144.

  The convex portion 145 is provided at the tip of the fixed shaft 140 on the rotating shaft 130 side, and is a portion that enters the concave portion 121 d of the cylindrical portion 121.

  The position of the fixed shaft 140 in the axial direction is regulated between the support wall 115 and the recess 121 d of the cylindrical portion 121.

  The click pin 150 constitutes a click mechanism together with the corrugated portion 121a, and includes a main body portion 151, a convex portion 152, a thinning portion 153, and the like.

  The main body 151 is formed in a cylindrical shape, and its axial dimension is set to be slightly smaller than the depth dimension of the hole 144, so that it can slide corresponding to the wave height of the corrugated part 121a. It has become. The axial length of the main body 151 is set to be larger than the outer diameter of the main body 151 and is formed to be elongated in the axial direction.

  Further, the convex portion 152 is provided on the opening side of the hole portion 144 in the main body portion 151. For example, the convex part 152 is formed in a spherical shape on the tip side so that it can enter the valley of the corrugated part 121a.

  The thinned portion 153 is a portion that has been thinned on the opposite side of the convex portion 152 in the main body portion 151, and forms a space in which the spring 160 is accommodated.

  The spring 160 is an elastic member, and for example, a coil spring is used. The spring 160 is accommodated in the decapture portion 153 of the click pin 150 so as to apply an urging force to the click pin 150 toward the wave shape portion 121a. It has become.

  The wave shape portion 121a, the hole portion 144, the click pin 150, and the spring 160 constitute a click mechanism that gives a click feeling when the occupant rotates the scroll wheel 120.

  The display unit 170 displays an input state corresponding to the rotation operation of the scroll wheel 120, and is disposed adjacent to the back side of the operation surface 111 on the other side in the axial direction of the scroll wheel 120. Here, as shown in FIG. 2, the display 170 displays the temperature of the conditioned air whose setting has been changed. As the display 170, for example, a flat light-emitting display (organic EL display) is used. The display content (image) displayed on the display 170 is visually recognized by the occupant through the light transmitting portion of the operation surface 111.

  On the operation surface 111, a switch unit for changing (inputting) a setting value (setting condition) of another control item of the air conditioner in a region opposite to the display 170 with respect to the scroll wheel 120. 171 is provided. The switch unit 171 is, for example, an auto (AUTO) switch for setting the operating state of the air conditioner to an automatic control state.

  The operation device 100 of the present embodiment is configured as described above, and the operation and effect thereof will be described below.

  When the occupant rotates the protruding portion of the scroll wheel 120 with a fingertip, the rotation of the scroll wheel 120 is transmitted to the gear portion 133 via the cylindrical portion 121 and the first and second shaft portions 131 and 132 of the rotating shaft 130. The At this time, the occupant obtains a click feeling at the time of the rotation operation by the convex portion 152 of the click pin 150 entering the valley portion of the corrugated portion 121a formed in the cylindrical portion 121 or being pushed out to the peak portion side. Is possible.

  Then, the rotation detection mechanism connected to the gear 133 detects the rotation state (rotation direction, rotation amount, etc.) of the scroll wheel 120, and the set temperature of the air conditioner is changed according to this rotation state. become. In addition, the display content on the display 170 (here, the temperature display of the conditioned air) is switched. Note that an instruction to the air conditioner (an instruction to perform automatic control) is made according to the input state to the switch unit 171.

  In the present embodiment, the corrugated portion 121 a is provided on the inner peripheral surface of the ring-shaped scroll wheel 120 (cylindrical portion 121), and the click pin 150 and the hole 144 of the fixed shaft 140 inserted into the cylindrical portion 121 are provided. A spring 160 is provided. Therefore, the wave shape portion 121a, the click pin 150, and the spring 160 (click mechanism) can be arranged inside the scroll wheel 120, and a space for providing the click mechanism outside the scroll wheel 120 is not required.

  Since the hole 144 is formed by being deeply dug beyond the position of the virtual center line of the fixed shaft 140, the degree of freedom in setting the dimensions of the spring 160 and the click pin 150 in the hole depth direction can be increased. it can. Therefore, the click pin 150 can be formed to be elongated along the depth direction of the hole 144 and the sliding area can be increased along the inner peripheral surface of the hole 144. The click pin 150 may be difficult to drop off from the portion 144. The fixed shaft 140 on which the click pin 150 is set can be easily assembled to the scroll wheel 120. In addition, since the degree of freedom in setting the dimensions of the spring 160 can be increased, it is easy to set the urging force of the spring 160 against the click pin 150.

  In general, in the case where the click mechanism is provided in the scroll wheel 120, it is possible to provide the operating device 100 that is excellent in assemblability of the click mechanism and that provides a good click feeling.

  In the cylindrical portion 121, the inner diameter dimensions are set such that the first inner diameter D1 <the wave portion inner diameter Dw <the second inner diameter D2. Thereby, the inner diameter of the scroll wheel 120 (cylindrical part 121) can be set to a shape in which the inner diameter gradually decreases toward the rotating shaft 130 when viewed from the opposite side of the rotating shaft 130. Therefore, when the fixed shaft 140 is inserted into the inner diameter side of the scroll wheel 120, it serves as a tapered guide, and the insertion and assembling property can be improved (FIG. 3).

  When a lubricant such as grease is provided in the hole 144 to improve the slidability of the click pin 150, the portion of the fixed shaft 140 corresponding to the second sliding surface 121c (second receiving portion 143). ) Serves as a lid member that closes the inner peripheral opening of the scroll wheel 120, so that the lubricant can be prevented from leaking to the outside.

  Further, on the rotating shaft 130, a collar portion 134 is provided between the scroll wheel 120 and the gear portion 133. Thereby, since the foreign material which penetrate | invades from the clearance gap 112a can be prevented from adhering to the gear part 133 with the collar part 134, the deterioration of the rotation feeling of the gear part 133, and also malfunctioning etc. can be prevented. it can.

  Further, the rotation shaft 130 is configured such that the axial position of the rotation shaft 130 is restricted with respect to the support wall 113 by the axial end portion of the scroll wheel 120 and the flange portion 134. Thereby, the collar part 134 can be used also as a positioning member in the axial direction of the rotating shaft 130.

(Second Embodiment)
An operation device 100A according to the second embodiment is shown in FIGS. 100 A of operating devices of 2nd Embodiment change the structure of the scroll wheel 120 and the rotating shaft 130 with respect to the operating device 100 of the said 1st Embodiment.

  The scroll wheel 120 is formed as an assembly with a plurality of members. The plurality of members are a first wheel 120a, a second wheel 120b, and a third wheel 120c.

  The first wheel 120 a is a ring-shaped member disposed on one side of the scroll wheel 120 in the axial direction. The first wheel 120 a is formed of a resin material, and is formed integrally with the resin cylinder 121 on one side of the cylinder 121 in the axial direction. That is, the first wheel 120a and the cylindrical portion 121 are integrally molded parts made of a resin material. A predetermined number of locking claws 1211 that are locked in locking holes 120c2 of a third wheel 120c, which will be described later, are provided at an intermediate position in the axial direction of the outer peripheral surface of the cylindrical portion 121. The surface of the first wheel 120a is painted with a predetermined color. The painting can be glossy or matte.

  The second wheel 120 b is a ring-shaped member that is disposed in an intermediate region in the axial direction of the scroll wheel 120. The second wheel 120b is formed from a resin material or a metal material. When the second wheel 120b is made of resin, for example, the surface of the second wheel 120b is coated with metallic luster. Further, when the second wheel 120b is made of metal (for example, made of aluminum), the surface has a gloss of a metal base.

  The third wheel 120 c is a ring-shaped member disposed on the other side in the axial direction of the scroll wheel 120. The third wheel 120c is formed of a resin material, and a predetermined color coating is applied to the surface of the third wheel 120c. The painting can be glossy or matte.

  And the 2nd wheel 120b side of the 3rd wheel 120c is hollow, and the site | part which forms the inner peripheral side in a ring shape is the cylindrical cylindrical part 120c1. A predetermined number of locking holes 120c2 for locking the locking claws 1211 are provided on the first wheel 120a side of the cylindrical portion 120c1 in the circumferential direction. Further, in the third wheel 120c, the end of the outer wall 120c3 adjacent to the opening 112 toward the center position extends to the axial center side of the scroll wheel 120 from the position of the second inner diameter D2 of the cylindrical portion 121, and is circular. The extended portion 120c5 forms the opening 120c4. The opening inner diameter D3 of the opening 120c4 is set to be smaller than the second inner diameter D2 of the cylindrical portion 121 (about several mm). That is, the extending part 120c5 of the outer wall part 120c3 covers the line (inner diameter line) of the second inner diameter D2.

  The first to third wheels 120a to 120c and the fixed shaft 140 are assembled as shown in FIG. First, the fixed shaft 140 to which the click pin 150 is assembled is inserted into the first wheel 120a. A lubricant (such as grease) for improving the slidability of the click pin 150 is provided on the inner peripheral surface of the hole 144 of the fixed shaft 140.

  Next, the second wheel 120b is disposed so as to pass through the outer peripheral side of the cylindrical portion 121 from the fixed shaft 140 side and come into contact with the first wheel 120a. And the 3rd wheel 120c is assembled | attached to the cylinder part 121 from the fixed shaft 140 side. At this time, the second wheel 120b is sandwiched and fixed between the first wheel 120a and the third wheel 120c. In addition, the inner peripheral surface of the cylindrical portion 120c1 of the third wheel 120c is inserted so as to contact the outer peripheral surface of the cylindrical portion 121, and the locking claw 1211 is locked to the locking hole 120c2, so that the third The wheel 120c is fixed to the first wheel 120a (cylinder part 121).

  In this embodiment, the scroll wheel 120 is formed as an assembly of a plurality of members, that is, the first to third wheels 120a to 120c, and the color, gloss, etc. can be set to be different among the three parties. Thus, the scroll wheel 120 rich in design can be obtained.

  Further, as described in the first embodiment, the second receiving portion 143 of the fixed shaft 140 closes the inner peripheral opening of the scroll wheel 120 with respect to the second sliding surface 121c of the cylindrical portion 121. To play a role. In addition, since the extended portion 120c5 of the outer wall 120c3 of the third wheel 120c covers the line of the second sliding surface 121c (second inner diameter D2), the lubricant is further externally added. To prevent leakage.

  Further, the extended portion 120c5 of the outer wall portion 120c3 serves to prevent the fixed shaft 140 from coming off, and the fixed shaft 140 does not fall off the cylindrical portion 121 after assembly.

  Further, since the first wheel 120a and the cylindrical portion 121 are integrally formed, the click vibration (click feeling) by the click pin 150 is directly transmitted to the first wheel 120a, and the feeling obtained by the click vibration. Can be improved.

(Other embodiments)
In the first embodiment, the inner peripheral surface of the ring-shaped scroll wheel 120 is formed by the cylindrical portion 121, but the cylindrical portion 121 may be formed integrally with the scroll wheel 120. In this case, the rotating shaft 130 is connected and fixed to one side of the scroll wheel 120. Moreover, the scroll wheel 120, the cylinder part 121, and the rotating shaft 130 are good also as what is shape | molded integrally.

  Further, the cross-sectional shape of the fixed portion 141 of the fixed shaft 140 is not limited to a quadrangle as long as it is a non-circular shape, and may be, for example, a polygon other than a quadrangle, a cross, or the like.

  In addition, the collar 134 may be abolished if the influence on the intrusion of the foreign matter from the gap 112a is small. In this case, using the step portion between the first shaft portion 131 and the second shaft portion 132 having different shaft diameters, the support wall 113 is sandwiched between the end portion in the axial direction of the scroll wheel 120 and the step portion, so that the rotation shaft It is only necessary to regulate the position of 130 in the axial direction.

  In the first and second embodiments, the scroll wheel 120 is used to change the set temperature of the conditioned air in the air conditioner. However, the present invention is not limited to this. It can be applied to other uses such as changing the volume of an audio device, and other devices.

DESCRIPTION OF SYMBOLS 100 Operation apparatus 110 Casing 111 Operation surface 112 Opening part 112a Crevice 113 Support wall 120 Scroll wheel 120a 1st wheel (plural members)
120b Second wheel (plural members)
120c third wheel (multiple members)
120c5 Extension part 121a Wave shape part 121b First sliding surface 121c Second sliding surface 130 Rotating shaft 133 Gear part (output gear)
134 Buttocks (Blocking Section)
140 Fixed shaft 144 Hole 150 Click pin 160 Spring (elastic member)
Dw Wave part inner diameter D1 First inner diameter D2 Second inner diameter

Claims (6)

In an operating device including a scroll wheel (120) rotated by an operator for input to a predetermined device,
The scroll wheel has a ring shape, and part of the scroll wheel protrudes from an opening (112) formed in the operation surface (111) on the operator side of the casing (110), and the operation surface is within the casing. The axial direction is formed in the direction along
A rotating shaft (130) provided on one side of the scroll wheel in the axial direction and rotating together with the scroll wheel;
On the other side of the scroll wheel in the axial direction, a fixed shaft (140) that is inserted into the ring-shaped interior and is non-rotating and supports the scroll wheel,
On the inner peripheral surface of the scroll wheel, a wave shape portion (121a) formed so that the wave shape is continuous in the circumferential direction;
A hole (144) dug beyond a center position of the fixed shaft from a predetermined outer peripheral surface position corresponding to the corrugated portion in the axial direction of the fixed shaft;
An elastic member (160) inserted into the hole;
An operating device comprising: a click pin (150) that slides along an inner peripheral surface of the hole portion, and a tip portion of which is urged toward the corrugated portion by the elastic member. On the inner peripheral surface of the scroll wheel,
A first sliding surface (121b) that is provided on the rotating shaft side of the corrugated portion and slides on the outer peripheral surface of the fixed shaft;
A second sliding surface (121c) that is provided on the opposite side of the corrugated portion from the first sliding surface, slides on the outer peripheral surface of the fixed shaft, and reaches the inner peripheral opening of the scroll wheel. Is formed,
When the inner diameter of the corrugated portion is the corrugated inner diameter (Dw), the inner diameter of the first sliding surface is the first inner diameter (D1), and the inner diameter of the second sliding surface is the second inner diameter (D2),
The operating device according to claim 1, wherein the first inner diameter <the wave portion inner diameter <the second inner diameter. The rotary shaft is provided with an output gear (133) for outputting the rotational force of the scroll wheel,
In the rotating shaft, a blocking unit (134) that prevents foreign matter intruding between the scroll wheel and the output gear from the opening and the gap (112a) between the scroll wheel from moving to the output gear side. 3. The operating device according to claim 1, further comprising: The casing is provided with a support wall (113) that rotatably supports the rotating shaft,
The support wall is disposed so as to be sandwiched between the axial end portion of the scroll wheel and the blocking portion,
The operating device according to claim 3, wherein an axial position of the rotation shaft is regulated with respect to the support wall by an axial end portion of the scroll wheel and the blocking portion.   The operating device according to any one of claims 1 to 4, wherein the scroll wheel is formed as an assembly of a plurality of members (120a, 120b, 120c) arranged in the axial direction. The radial dimension on the other side in the axial direction of the scroll wheel of the fixed shaft is set smaller than the inner diameter of the ring-shaped scroll wheel,
The member located on the other side in the axial direction of the scroll wheel among the plurality of members is provided with an extending portion (120c5) extending to the axial center side and covering the ring-shaped inner diameter line. 5. The operating device according to 5.

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