JP2008124253A - Substrate fixing structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a substrate fixing structure which can eliminate or reduce screws. <P>SOLUTION: In the substrate fixing structure, a substrate 4 is fixed to a case 1 by means of a fixing means substantially parallel to a case front side 1a in a housing part 1b provided to an inside of the case front side 1a. A plurality of encoder switches 3 fixed to the substrate 4 are provided through the case front side 1a, a fixing means is provided to a case through portion of the encoder switch 3 and the substrate 4 is fixed to the case 1 via the encoder switch 3 by fixing the encoder switch 3 to the case. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a substrate fixing structure for fixing a substrate in a state of being accommodated in a case, and more particularly to a substrate fixing structure suitable for use in a control panel portion of an air conditioner installed in an instrument panel of an automobile.

Conventionally, in an automobile or the like, an air conditioner control panel is provided on an instrument panel, and on this control panel, there are electronic components that generate signals by operating switches or illuminate display portions provided on the switches. A device provided with a mounted substrate is known (see Patent Document 1).
In such a conventional technique, the substrate is generally fixed to the case with a plurality of screws while being accommodated in the case.
Japanese Patent Laid-Open No. 10-278549

  However, in the structure in which the substrate is fixed to the case with a plurality of (for example, 10 or more) screws as described above, there is a problem that the operation of fixing the substrate is troublesome and the weight increases.

  The present invention has been made paying attention to the conventional problems as described above, and by providing a substrate fixing structure capable of eliminating or reducing screws, it is easy to fix a substrate and reduce weight and cost. The purpose is to achieve.

In order to achieve the above object, according to the first aspect of the present invention, the substrate is fixed to the case by the fixing means in a state of being substantially parallel to the front surface of the case in the accommodating portion provided inside the front surface of the case. In the substrate fixing structure, a plurality of switches fixed to the substrate are provided so as to protrude from the substrate and penetrate the front surface of the case, and the fixing means is provided in a case penetration portion of the switch, The substrate fixing structure is characterized by comprising switch fixing means for fixing the substrate to the case via the switch by fixing the switch to the case.
According to a second aspect of the present invention, in the substrate fixing structure according to the first aspect, the fixing means is provided in the case, and the substrate can be slidably guided along the front surface of the case. The substrate fixing structure is characterized in that a slide guide rail is provided for restricting movement of the substrate in the direction of penetrating the switch with respect to the case by sandwiching the edge portion of the substrate.
According to a third aspect of the present invention, in the substrate fixing structure according to the first or second aspect, the switch is a rotating member that is rotatably supported by a switch base portion fixed to the substrate. A switch that outputs a signal in response to the rotation of the rotation base, wherein the rotation member is disposed in the accommodating portion and is rotatably supported by the switch base portion, and an outer side of the front surface of the case And the pivot tip portion and the pivot base portion are formed so as to be connectable by a coupling means, and the switch fixing means is formed through the penetrating portion of the switch base portion. A pedestal-side screw portion formed with the direction as an axis, and a support member that is mounted on the outer periphery of the rotating tip portion so as to be capable of relative rotation and engages with the pedestal-side screw portion. , The support member It was a substrate fixing structure, characterized in that comprises an engaging flange against over scan front is engageable formed in the through direction.

  In order to achieve the above-mentioned object, the invention according to claim 4 is a substrate in which the substrate is fixed to the case by a fixing means in a state of being substantially parallel to the front surface of the case in the accommodating portion inside the front surface of the case. A fixing structure, wherein the fixing means is provided in the case, and the substrate can be slidably guided along the front surface of the case; The substrate fixing structure includes a slide guide rail that restricts movement of the substrate in a through direction and a slide restricting unit that restricts the substrate from sliding relative to the slide guide rail.

In the vehicle air conditioner of the present invention, the substrate is accommodated in the case in a state where a plurality of switches fixed to the substrate are passed through the front surface of the case, and the switch is fixed by the switch fixing means provided in the case penetration portion of the switch. Is fixed to the case. Since this switch is fixed to the substrate, the substrate is fixed to the case.
Thus, in the present invention, since the substrate is fixed to the case using the switch, the screws for fixing the substrate to the case can be eliminated or reduced.
Simplification of fixing work and reduction in weight and cost can be achieved by eliminating or reducing the screwing.

According to the second aspect of the present invention, when the substrate is fixed, the substrate is slid along the slide guide rail of the case so that the substrate is along the front surface of the case and disposed at a predetermined position of the housing portion. And as above-mentioned, a board | substrate is fixed to a case by fixing the penetration part of a switch with a switch fixing means.
In this state, the edge portion of the substrate is held between the slide guide rails, and movement of the switch in the penetrating direction is restricted.
In this way, by holding the edge of the board with the slide guide rail, the board can be positioned easily and the burden of the switch fixing means is reduced compared to the case where the case is fixed only by the switch fixing means. Thus, the durability can be improved and the weight and size can be reduced.

In the invention according to claim 3, when fixing the substrate, the rotating member of the switch is divided into a rotating base portion and a rotating tip portion in advance, and the substrate is accommodated in the case in the divided state. Placed at a predetermined position of the section.
Next, the rotating tip portion and the rotating base portion are connected to each other by the connecting means, and the tip side screw portion of the support member attached to the turning tip portion is engaged with the base side screw portion of the switch base portion. .
By this engagement, the support member is displaced in the axial direction of the rotating member with respect to the switch pedestal portion fixed to the substrate, and the engagement flange is engaged with the front surface of the case in the axial direction and is brought into pressure contact. Thereby, a board | substrate is fixed to a case.
Thus, in the invention described in claim 3, the switch rotation member can be divided into the rotation base portion arranged in the housing portion inside the case front surface and the rotation tip portion outside the case front surface. For this reason, when the substrate is disposed in the housing portion of the case, the case penetration portion of the switch can be prevented from interfering with the case, and the workability is excellent. In particular, in the structure in which the substrate is slid along the slide guide rail as in the invention described in claim 2, it is not necessary to form an elongated hole or the like in the case for preventing the switch from interfering with the case. The appearance quality of the case can be improved as compared with the case in which such a shape for preventing interference is formed on the case.

In the invention according to claim 4, when the substrate is fixed, the substrate is slid in a state of being sandwiched between the slide guide rails formed on the case and arranged at a predetermined position, and then the substrate is mounted on the case by the fixing means. Fix against non-sliding.
Thus, in the invention described in claim 4, since the board is sandwiched by the slide guide rail and the movement in the sliding direction is restricted by the fixing means, the screw stopper can be eliminated or reduced. As much as is eliminated or reduced, simplification of fixing work and reduction in weight and cost can be achieved.
In addition, since the substrate is sandwiched between the slide guide rails, it is possible to reduce the burden on the fixing means, to reduce the burden on the fixing means, and to improve durability and reduce the weight and size.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
The substrate fixing structure of this embodiment is configured such that the substrate (4) is fixed in a state in which the substrate (4) is substantially parallel to the case front surface (1a) in the housing portion (1b) provided inside the case front surface (1a). A plurality of switches (3) fixed to the substrate (4) projecting from the substrate (4) and penetrating through the front surface (1a) of the case. The fixing means is provided in a case penetrating portion of the switch (3), and the switch (3) is fixed to the case (1), whereby the substrate (4) is interposed via the switch (3). ) Is provided with switch fixing means (32b, 38j) for fixing to the case (1).

  Below, based on FIGS. 1-6, the board | substrate fixing structure of Example 1 of this Embodiment is demonstrated.

In explaining the substrate fixing structure of the first embodiment, an example applied to the operation panel CP of the vehicle air conditioner (not shown) will be shown.
The operation panel CP is attached to an instrument panel (not shown) with the case front surface 1a of the case 1 being exposed to a vehicle compartment (not shown). The operation panel CP is exposed to the case front surface 1a and includes a plurality of push switches 2. Operation buttons 2b for operation are provided, and four encoder switches 3 are provided at the four corners of the case 1 so as to protrude in the direction of the arrow RM so as to be exposed to the passenger compartment when installed.

The case 1 is formed in a cubic box shape surrounding the accommodating portion 1b inside the case front surface 1a, and an opening 1c is provided on one side of the side surface for communicating the accommodating portion 1b with the outside.
Further, in the vicinity of the four corners of the case front surface 1a, through-holes 1d through which an operation shaft 31 of an encoder switch 3 described later is passed are opened.
Further, in the side wall 1e erected on both sides in the width direction of the case 1 (the direction of the arrow W in the figure), the slide guide rail 11 is provided on the inner side surface on the housing portion 1b side so as to be substantially parallel to the case front surface 1a. Are integrally formed.
In the slide guide rail 11, two sandwiching pieces 11b and 11b are opposed to each other with the slide groove 11a interposed therebetween.

A substrate 4 is accommodated in the accommodating portion 1 b of the case 1.
The substrate 4 is formed in a substantially rectangular shape as shown in the figure by a plate material made of resin (for example, PP material, GE material, CPE, CGE, etc.), and the push switch 2 and the encoder switch 3 described above, or an integration not shown. Electronic components such as a circuit, a resistor, and a capacitor are mounted, and wirings that configure the electronic circuit by connecting the components are formed.

  And the board | substrate 4 is the state in which the both ends of the width direction (arrow W direction) were inserted in the slide groove | channel 11a of the slide guide rail 11, and were clamped, and the arrow SL in the figure was controlled. It is supported so that it can slide in the direction of.

  The encoder switch 3 mounted on the substrate 4 includes a switch pedestal portion 32 fixed to the substrate 4 and an operation shaft (rotation tip of the rotation member) supported by the switch pedestal portion 32 so as to be rotatable. 31).

As shown in FIG. 2, the switch pedestal portion 32 is erected on a substantially rectangular parallelepiped housing portion 32a and an upper surface of the housing portion 32a, and has a cylindrical shape in which a male screw-like pedestal side screw portion 32b is formed on the outer periphery. And a pair of leg-like terminals 32d and a pair of spring-like spring legs 32e protruding downward from the side surface of the housing portion 32a.
As shown in FIG. 3, the terminal 32d is soldered to a wiring (not shown) provided on the substrate 4 in a state where the tip is bent and the tip is bent and engaged with the substrate back surface 4b. Yes.
Further, the spring leg 32e is made of a metal plate, and its tip is brought into contact with the substrate surface 4a in the illustrated mounting state, and the switch base 32 elastically receives the load input in the direction of the arrow P. It has a function.

  An accommodation hole 33 is formed inside the switch pedestal 32. As shown in the figure, the accommodation hole 33 is coaxially formed in order from the bottom surface side to the largest diameter large diameter portion 33a and the large diameter portion 33a, and is formed to be smaller in diameter than the large diameter portion 33a. The small-diameter portion 33b and the small-diameter portion 33b are formed continuously with the smallest-diameter insertion port 33c formed in the inner peripheral wall portion of the fastening inner cylinder 32c.

  Further, a contact point 36 connected to the terminal 32d is disposed on the bottom surface of the large diameter portion 33a.

  A built-in rotation member (a rotation base of the rotation member) 34 is rotatably accommodated across the large-diameter portion 33a and the small-diameter portion 33b of the accommodation hole 33.

The built-in rotation member 34 and the operation shaft 31 are portions where the encoder switch 3 is rotated, and the operation shaft 31 and the built-in rotation member 34 are integrally rotated in the assembled state described later. In addition, the encoder switch 3 has a push switch function to be described later, and the operation shaft 31 and the built-in rotation member 34 are relative to each other in the axial direction in order to absorb the push operation input to the operation shaft 31. It is divided to be movable.
As shown in FIG. 4A, the built-in rotation member 34 includes a conical cylindrical tube portion 34a, a lid portion 34b provided by closing an end portion on the small diameter side of the cylindrical portion 34a, and a cylindrical portion. The other end portion of 34a is formed in a substantially hat shape by an annular flange portion 34c formed so as to expand in the diameter increasing direction.

The lid portion 34b has a circular opening 34d and a pair of locking grooves 34e and 34e formed continuously from the opening 34d and extending in the outer diameter direction at a symmetrical position about the axis. Is formed.
On the upper surface side of the flange portion 34c, there is formed a click uneven portion 34f in which uneven projections and grooves are alternately arranged in the circumferential direction to make contact with the side surface of the large diameter portion 33a of the switch pedestal portion 32 and to provide a click feeling. ing.
Further, on the back surface of the flange portion 34c, as shown in FIG. 4 (b), there is provided an electrode 35 having an annular shape and having convex portions extending in the outer diameter direction at a predetermined interval.
That is, as shown in FIG. 3, the flange portion 34 c of the built-in rotating member 34 is accommodated in the large-diameter portion 33 a of the switch pedestal portion 32. The pulse signal corresponding to the rotation angle is output by switching the connection state between the unit and the contact 36. Hereinafter, this pulse output is referred to as an encoder output.

  Further, a push switch 37 is provided at the bottom axial center position of the accommodation hole 33, and the operation shaft 31 performs an operation of encoder output and ON / OFF output by the push switch 37.

The operation shaft 31 includes a shaft main body 31a, a pair of engagement pieces 31b and 31b provided at the base end portion of the shaft main body 31a, and an engagement receiving portion 31c provided at the distal end portion of the shaft main body 31a. Yes.
The shaft main body 31 a is formed to have an outer diameter dimension that can be inserted into the opening 34 d of the lid portion 34 b of the built-in rotation member 34.

The engagement piece 31b constitutes a coupling means for coupling the operation shaft 31 and the built-in rotation member 34 with the locking groove 34e. That is, the engagement pieces 31b are plate-like ones protruding from the shaft main body 31a in the outer diameter direction, and are arranged symmetrically with respect to the shaft center of the shaft main body 31a as shown in FIG. When 31a is inserted into the opening 34d of the lid portion 34b of the built-in rotation member 34, the coupling state is established in which the pair of locking grooves 34e and 34e are inserted. In this coupled state, the operation shaft 31 can move relative to the built-in rotation member 34 in the axial direction, but engages in the circumferential direction and rotates integrally.
The dimension of the engagement piece 31b in the axial direction is such that the engagement state with the locking groove 34e can be maintained even if the operation shaft 31 is moved in the axial direction by the operation amount of the push switch 37. Has been.

  The engagement receiving portion 31c is for engaging an operation knob (not shown), and as shown in FIG. 2, an engagement groove 31d is formed along the axis, and the sliding resistance is increased on the outer periphery. Jagged processing is applied.

On the outer periphery of the shaft main body 31a of the operation shaft 31, a fastening outer cylinder member 38 that constitutes a fixing means with the fastening inner cylinder 32c is mounted.
As shown in FIGS. 2 and 3, the fastening outer cylinder member 38 includes a cylindrical main body 38a, and an engaging flange 38b and a partition wall 38c are integrally formed at an intermediate portion of the main body 38a. In the upper end portion, an insertion hole 38d is opened.

The main body 38 a includes a cylindrical base end portion 38 e sandwiching the engagement flange 38 b and a conical inclined tip end portion 38 f, and the base end portion 38 e can be inserted into the through hole 1 d of the case 1. The outer diameter is formed.
Further, the insertion hole 38d formed at the distal end of the distal end portion 38f is formed in a circular shape having an inner diameter dimension through which the shaft main body 31a and the engagement piece 31b of the operation shaft 31 can be inserted (see FIG. 6A). .
As shown in FIG. 6B, a shaft insertion hole 38g and a locking piece insertion hole 38h are opened in the partition wall 38c.
The shaft insertion hole 38g is formed in a circular shape having an inner diameter through which the shaft main body of the operation shaft 31 can be inserted.
The locking piece insertion hole 38h is formed to have a dimension capable of inserting the engagement piece 31b.

The engagement flange 38b is formed to have an outer diameter that can be engaged with the outer peripheral edge of the through hole 1d in the insertion direction when the base end 38e of the main body 38a is inserted into the through hole 1d of the case 1. .
On the inner periphery of the base end portion 38e, a female screw-like distal end side screw portion 38j that can mesh with the pedestal side screw portion 32b is formed.
The tip side threaded portion 38j is formed so as to be able to mesh with the pedestal side threaded portion 32b of the switch pedestal portion 32, and when the both are meshed and rotated, the fastening outer cylinder member 38 is The switch base 32 is configured to be displaced in the axial direction.

Next, the operation of the first embodiment will be described.
When assembling the operation panel CP of the first embodiment, the substrate 4 in a state where the operation shaft 31 and the fastening outer cylinder member 38 of the encoder switch 3 are removed from the switch base 32 as shown in FIG. It is inserted into the housing 1b of the case 1. At this time, both edge portions in the width direction of the substrate 4 are inserted into the slide grooves 11a of the slide guide rail 11, and the substrate 4 is slid along the slide guide rail 11 substantially parallel to the front surface 1a of the case. The fastening inner cylinder 32c and the through hole 1d of the case 1 are arranged at positions that are substantially coaxial.

Next, the base end portion 38e of the fastening outer cylinder member 38 is inserted into the through-hole 1d from the case front surface 1a side, and the fastening outer cylinder member 38 is rotated around its axis while the base end portion. The tip side screw part 38j formed on 38e and the base side screw part 32b formed on the fastening inner cylinder 32c of the switch base part 32 are engaged with each other.
As a result, the fastening outer cylinder member 38 is displaced in the axial direction with respect to the fastening inner cylinder 32c while rotating, and the engagement flange 38b is engaged with the case front face 1a in the axial direction and pressed. The substrate 4 is fixed to the case 1.

That is, the width direction both ends of the board | substrate 4 are clamped by the clamping pieces 11b and 11b of the slide guide rail 11 of the case 1, and relative displacement with respect to the case 1 to the vehicle interior direction which is the arrow RM direction, and its reverse direction. To be regulated.
In this state, when the fastening outer cylinder member 38 moves in the axial direction and the axial distance between the engagement flange 38c and the substrate 4 becomes narrower, the case 1 has the engagement flange 38c and the clamping piece of the slide guide rail 11 It is strongly sandwiched between the substrate 4 at the position 11b. Thus, the substrate 4 is restricted from moving in the width direction that is the arrow W direction and the sliding direction that is the arrow SL direction with respect to the case 1.

In addition, after the fastening outer cylinder member 38 and the fastening inner cylinder 32c are fastened, or before the fastening, the operation shaft 31 of the encoder switch 3 is accommodated in the accommodation hole 33 of the switch base portion 32. The built-in rotation member 34 is coupled.
In this connection, the engaging piece 31b protruding from the shaft main body 31a of the operation shaft 31 is inserted into the locking groove 34e opened in the lid portion 34b of the built-in rotation member 34, and the shaft main body 31a is inserted. This is done by inserting it into the opening 34d.

In this coupled state, since the engaging piece 31b engages with the locking groove 34e in the circumferential direction, when the operating shaft 31 is rotated, the operating shaft 31 and the built-in rotating member 34 rotate integrally. The encoder output is made.
When a push operation for pushing the operation shaft 31 is performed, the operation shaft 31 moves relative to the built-in rotation member 34 and the switch base 32 in the direction opposite to the arrow RM in the axial direction, and the push switch 37 can be switched ON / OFF.

As described above, in the first embodiment, when fixing the substrate 4 to the case 1, the conventional screws are abolished and both end edges of the substrate 4 are inserted into the slide guide rails 11 of the case 1, and the case front surface 1 a The substrate 4 is fixed to the case 1 by restricting the relative movement of the substrate 4 with respect to the slide guide rail 11 by using the encoder switch 3 penetrating therethrough.
Therefore, the work of fixing the board 4 includes a work of sliding the board 4 and a work of connecting the divided encoder switches 3, and the work can be simplified as compared with performing a plurality of screwing work. At the same time, the weight and cost can be reduced.
Moreover, as described above, the substrate 4 is fixed to the case 1 by the fastening of the slide guide rail 11 and the fastening inner cylinder 32c and the fastening outer cylinder member 38. Therefore, the load by the operation force to the push switch 37 of the encoder switch 3, which is a particularly large load among the loads input to the substrate 4, is supported by the slide guide rail 11. For this reason, it is easy to secure the fixing strength of the substrate 4 as compared with the case where only the fastening portion is fixed, the burden due to the fastening portion can be reduced, and the fastening structure portion can be reduced in size and strength. And durability can be ensured.

  Further, since the substrate 4 is sandwiched between the slide guide rails 11, the positioning of the substrate 4 is easier and the assembling workability is excellent compared to the positioning of the substrate 4 only by the fastening portion.

In addition, the input to the operation shaft 31 of the encoder switch 3 may be input to the switch pedestal portion 32, but the solder portion between the terminal 32d of the switch pedestal portion 32 and the substrate 4 is less likely to occur. .
That is, the terminal 32d is penetrated through the substrate 4 and is fixed by soldering in a state where the tip of the terminal 32d is bent along the substrate 4. Further, the lower surface of the switch pedestal 32 is supported by spring legs 32e. For this reason, in the input to the switch pedestal 32, the input in the direction of arrow P in FIG. 3 is transmitted to the substrate 4 by the spring leg 32e, and the solder of the terminal 32d is hardly peeled off. Further, the input in the direction excluding the arrow P direction is transmitted to the substrate 4 without passing through the solder portion through the portion of the terminal 32d penetrating the substrate 4 and the bent portion, and the solder portion is hardly peeled off. .
As described above, the solder portion is hardly peeled off in all directions of the substrate 4 in the horizontal direction, the arrow P direction, and the opposite direction.

  In the first embodiment, the encoder switch 3 is divided into the operation shaft 31 on the outer side of the case front surface 1a and the built-in rotating member 34 in the switch base portion 32 on the inner side of the case front surface 1a. On the other hand, when the slide guide rail 11 is slid, the encoder switch 3 does not interfere with the case 1 by dividing the both 31 and 34. Therefore, the appearance quality can be improved at a lower cost than the structure in which a long hole or the like for preventing the interference with the encoder switch 3 is formed in the case 1, and the case of the substrate 4 can be obtained using this divided structure. Since the fixing to 1 is performed, the manufacturing cost can be reduced as compared with the case where a member for fixing the substrate 4 is additionally set.

  As mentioned above, although Embodiment and Example 1 of this invention were explained in full detail with reference to drawings, the concrete structure is not restricted to this Embodiment and Example 1, and does not deviate from the summary of this invention. A degree of design change is included in the present invention.

  That is, in the first embodiment, the substrate fixing structure is applied to the operation panel CP of the vehicle air conditioner. However, as long as the substrate is fixed to the case, the application range is not limited thereto. For example, the present invention can also be applied to industrial equipment other than vehicles, home appliances, and other electrical equipment.

  In the first embodiment, the case 1 formed in a box shape is shown as a case for fixing the substrate. However, as the case used in the present invention, a slide guide rail that slidably supports the substrate is formed, and As long as the substrate can be fixed, the shape may be other than the box shape shown in the first embodiment. For example, as illustrated in FIG. 7, a case 701 in which the case 1 used in the first embodiment is vertically divided may be used. The case 701 has a reverse concave shape in cross section with the entire case 701a and side walls 701e and 7011e, and a slide guide rail 711 is formed on each of the side walls 701e and 701e.

In the first embodiment, as the switch fixing means, the means for meshing the pedestal side screw portion 32b and the tip side screw portion 38j is shown, but means other than such a screw may be used. For example, in a state where the engagement flange 38b is in pressure contact with the case front surface 1a, the engagement claw formed on the fastening outer cylinder member 38 side is engaged with the engagement hole formed on the switch base portion 32 side, thereby The substrate 4 may be fixed to the case 1.
Further, even when a screw structure is used as the switch fixing means, the male-female relationship between the pedestal side screw portion 32b on the fastening outer cylinder member 38 side and the distal end side screw portion 38j on the switch pedestal portion 32 side is reversed. You may form in.

  In the first embodiment, the encoder switch 3 having a rotating shaft is shown as the switch. However, the switch is not limited to the encoder switch as long as it passes through the case. In this case, a switch other than an encoder switch having a rotation axis can be used, and an ON / OFF switch without a rotation axis can be used.

  In the first embodiment, the substrate 4 is sandwiched between the slide guide rails 11. However, in the invention described in claim 1, the slide guide rail 11 may not be used. That is, if the substrate 4 or the switch pedestal 32 has a means for positioning the substrate 4 with respect to the case 1, the slide guide rail 11 may not be provided. For example, the substrate 4 is provided with a plurality of positioning projections (for example, four), the back surface of the case is brought into contact with the front end surface of the projection, and the substrate is positioned. Then, fixing such as fastening with the fastening inner cylinder 32c may be performed. Alternatively, as the protrusion provided on the substrate 4, the upper surface of the switch pedestal portion 32 may be used as a positioning surface, and the rear surface of the case front surface 1 a may be brought into contact with the upper surface to perform positioning.

In the invention according to claim 4, if the slide guide rail 11 is formed in the case 1 and the substrate 4 is sandwiched by the slide guide rail 11, the substrate 4 moves relative to the slide guide rail 11. As a means for restricting the operation, a configuration other than the fastening portion of the encoder switch 3 shown in the first embodiment may be used.
For example, as shown in FIG. 8, when the substrate 804 is slid with respect to the slide groove 811 b of the slide guide rail 811 and reaches a predetermined position, the slide guide rail 811 is held in the engagement hole 804 a formed in the substrate 804. The engagement spring piece 811c provided to protrude from the slide groove 811b in the piece 811a may be engaged to perform positioning and slide regulation of the substrate 804.
In this case, the substrate 804 can also be applied to a substrate that is not provided with a switch that penetrates the case, such as the encoder switch 3.
Even with such a configuration, the screwing can be eliminated or reduced, and the fixing operation can be simplified correspondingly, and the weight and cost can be reduced.

It is an exploded perspective view showing an operation panel CP to which the substrate fixing structure of Example 1 which is the best mode of the present invention is applied. 3 is an exploded perspective view showing an encoder switch 3 used in the substrate fixing structure of Embodiment 1. FIG. 3 is a longitudinal sectional view showing an encoder switch 3 used in the board fixing structure of Embodiment 1. FIG. It is a figure which shows the internal rotation member as a rotation base of the rotation member in the board | substrate fixed structure of Example 1, Comprising: (a) is a perspective view, (b) is a bottom view. FIG. 6 is a bottom view of an operation shaft 31 as a rotation tip portion of a rotation member in the substrate fixing structure according to the first embodiment. It is a figure which shows the outer cylinder member 38 for fastening which comprises the fixing means in the board | substrate fixing structure of Example 1, Comprising: (a) is a top view, (b) is a bottom view. It is a front view which shows the principal part of the other Example of embodiment of this invention. It is sectional drawing which shows the principal part of the other Example of embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Case 1a Case front surface 1b Accommodating part 3 Encoder switch 4 Board | substrate 11 Slide guide rail 11a Slide groove 11b Nipping piece 31 Operation axis | shaft (rotating member: rotation front-end | tip part)
31b Engagement piece (coupling means)
32 Switch base part 32b Base side screw part (switch fixing means)
34 Built-in turning member (turning member: turning base)
34d Opening (coupling means)
34e Locking groove (coupling means)
38. Outer cylinder member for fastening (switch fixing means: support member)
38b Engagement flange 38j Tip side thread

Claims (4)

A substrate fixing structure in which the substrate is fixed to the case by a fixing means in a state of being substantially parallel to the front surface of the case in the accommodating portion provided inside the front surface of the case,
A plurality of switches fixed to the substrate are provided so as to protrude from the substrate and pass through the front surface of the case.
The board having a switch fixing means provided in a case penetrating portion of the switch, and fixing the switch to the case so that the board is fixed to the case via the switch. Fixed structure.   The fixing means is provided in the case, and the substrate can be slidably guided along the front surface of the case. The substrate moves in the penetrating direction of the switch with respect to the case while sandwiching an edge of the substrate. The board fixing structure according to claim 1, further comprising a slide guide rail that restricts the movement of the board. The switch is a switch that outputs a signal according to the rotation of a rotation member that is rotatably supported by a switch base portion fixed to the substrate,
The rotating member can be divided into a rotating base disposed in the accommodating portion and rotatably supported by the switch pedestal portion, and a rotating tip portion disposed outside the front surface of the case. In addition, the pivot tip and the pivot base are formed to be coupled by a coupling means,
The switch fixing means is mounted on a pedestal side threaded portion formed around the penetrating direction in the switch pedestal portion and an outer periphery of the rotating tip portion so as to be relatively rotatable, and meshes with the pedestal side threaded portion. The support member is provided with a possible tip side screw portion, and the support member is provided with an engagement flange formed to be engageable with the front surface of the case in the penetrating direction. The substrate fixing structure according to claim 1 or 2. A substrate fixing structure in which the substrate is fixed to the case by fixing means in a state of being substantially parallel to the front surface of the case in the accommodating portion inside the front surface of the case,
The fixing means is provided in the case, and the substrate can be slidably guided along the front surface of the case. The substrate moves in the penetrating direction of the switch with respect to the case while sandwiching an edge of the substrate. A substrate fixing structure comprising: a slide guide rail that restricts the sliding of the substrate, and a slide restricting unit that restricts the substrate from sliding relative to the slide guide rail.

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