JP3273422B2 - Motor driven slide type variable resistor - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a motor driven slide type variable resistor, and more particularly to a structure for connecting a belt rotating by driving a motor and a movable body of the variable resistor.

[0002]

2. Description of the Related Art A motor driven slide type variable resistor has a resistance value which can be adjusted by both a motor driving operation and a manual operation. The rotation of the motor is controlled by a belt wound around a pair of pulleys. Is transmitted to the movable body of the variable resistor. In this case, it is necessary to fix the movable body to a part of the belt, and as an example of a connection structure between the belt and the movable body, a structure described in Japanese Utility Model Laid-Open No. 4-52705 proposed by the present applicant is known. ing.

[0003] The motor driven slide type variable resistor described in the above publication comprises a drive section and a variable resistor section. The drive section includes a drive pulley rotated by a motor, a plurality of driven pulleys, these drive pulleys, A belt is stretched between the driven pulleys, and a gear portion is formed on each pulley, and the belt is also formed with teeth that mesh with the gear portion. On the other hand, the variable resistor section includes a resistive substrate having a resistor printed on the surface thereof, and a movable body having a slider that is in sliding contact with the resistor, and the movable body includes a slider receiver, a lever, and the like. Having. A groove having an uneven portion is formed on the inner wall surface of the slider receiver, and the movable body is formed on the belt by inserting the belt into the groove and engaging the uneven portion and the tooth portion of the belt. It is fixed.

In the motor driven slide type variable resistor configured as described above, when the operator manually operates the lever of the movable body, the relative position between the slider piece and the resistor changes, and the manual operation is performed. Is used to adjust the resistance value. Further, when the motor is rotated by an external signal, the rotation rotates the driving pulley, and further, the mesh rotates between the driving pulley and the driven pulley due to the engagement between the gear portion and the tooth portion. The movable body fixed to the belt moves,
The resistance value is adjusted by driving the motor.

[0005]

In the above-described conventional motor driven slide type variable resistor, when the movable member is fixed to the belt, the belt must be inserted into a groove formed in the slider receiver. However, since the belt is made of a material having excellent flexibility such as rubber, there has been a problem that the assembling workability is poor. In addition, since the holding force between the movable body and the belt depends only on the engagement between the concave and convex portions of the groove and the teeth of the belt, it is necessary to increase the number of concave and convex portions in order to increase the holding force. In addition, there is also a problem that the length of the groove is increased and miniaturization is hindered.

SUMMARY OF THE INVENTION The present invention has been made in view of such circumstances of the prior art, and an object of the present invention is to provide a motor driven slide type variable resistor which can easily and reliably fix a movable body to a belt. .

[0007]

To achieve the above object, the present invention provides a drive pulley rotated by a motor,
A driven pulley that is installed facing the drive pulley at a predetermined interval, a belt stretched between the drive pulley and the driven pulley, a movable body fixed to a part of the belt, A held sliding piece, and a resistive substrate slidably contacting the sliding piece, and a resistance change caused by a change in a sliding contact position between the sliding piece and the resistive substrate due to reciprocation of the movable body. In a motor-driven slide type variable resistor whose value is adjusted, the movable body includes a lever manually operated by an operator and a slider receiver for holding the slider piece. The most important feature is that the belt is sandwiched between the child receivers. In the above configuration, as a means for holding the belt, a recess is provided in one of the lever and the slider receiver, and a protrusion inserted into the recess is provided in one of the other, and the recess and the protrusion are provided. The drive pulley and the driven pulley are provided with a gear portion, the belt is formed with a tooth portion that meshes with the gear portion, and the protrusion is provided with the tooth portion of the belt. It is also possible to provide unevenness that meshes with. Further, in the above configuration, it is possible to provide a holding portion for holding the belt and a fixing portion for integrating the lever and the slider receiver at different positions. It has a leg provided on one of the moving element receivers and a guide hole provided on the other, and slidably connects the leg and the guide hole, and snaps the two together. It is also possible to provide a coupling.

[0008]

After the belt is stretched between the driving pulley and the driven pulley, the lever and the slider piece are joined and integrated so as to sandwich the belt, whereby the movable body can be easily fixed to the belt. . At this time, a recess is provided in one of the lever and the slider receiver, and a protrusion is provided in the other, and the belt is sandwiched between the recess and the protrusion. Is securely held between the inner wall and the projection. In addition, when the protrusions are provided with irregularities that mesh with the teeth of the belt, the fixing of the belt and the movable body is further ensured.
Further, if the holding portion for holding the belt and the fixing portion for integrating the lever and the slider receiver are provided at different positions, the force for integrating the lever and the slider receiver affects the belt holding portion. This makes it difficult to provide, and can improve the assembly workability. Further, as this fixing portion, a leg piece provided on one of the lever and the slider receiver is slidably connected to a guide hole provided on the other, and the leg piece is inserted into the guide hole. When adopting the structure of snap-in, when the lever and the slider receiver are integrated, the legs are guided by the guide holes,
The assembly workability can be further improved.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is an exploded perspective view showing the overall configuration of a motor driven slide variable resistor according to one embodiment of the present invention, FIG. 2 is a perspective view of a motor drive unit, and FIG. 3 is an exploded perspective view showing a drive pulley support structure. 4 is an explanatory view showing the positional relationship between the driving pulley and the guide member, FIG. 5 is a cross-sectional view showing an attached state of the guide member, FIG. 6 is an exploded perspective view showing a supporting structure of the driven pulley, and FIG. FIG. 8 is an exploded perspective view of a movable body, FIG. 9 is a side view of a lever, FIG.
0 is a plan view of the slider receiver, FIG. 11 is a rear view of the slider receiver, FIG. 12 is a plan view showing a state where the movable body is being mounted on the belt, and FIG. 13 is along the line AA in FIG. FIG. 14 is a cross-sectional view, FIG. 14 is a plan view showing a state where the movable body has been attached to the belt, and FIG. 15 is a cross-sectional view along the line BB of FIG.

The motor driven slide type variable resistor according to the present embodiment includes a motor drive unit 1 shown in FIG. 2, a pair of covers 2 covering the front and rear surfaces and the bottom surface of the motor drive unit 1, and a motor drive unit 1 shown in FIG. , A pair of holders 3 covering the left and right sides of the motor drive unit 1, a blind plate 4 covering the upper surface of the motor drive unit 1, and a resistance substrate 5 installed facing the motor drive unit 1. Resistors and current collectors (both not shown) are formed on the surface of the resistor substrate 5 to be in sliding contact with the respective slider pieces described later, and positioning holes 5 a are formed on both side edges of the resistor substrate 5. Are drilled. On the other hand, a pair of positioning grooves 2a extending in the longitudinal direction is formed on the inner surface of the cover 2, and the resistor substrate 5 is inserted between the positioning grooves 2a.

As shown in FIG. 2, the motor drive unit 1 includes a metal frame 6, a motor 7 fixed to one end of the frame 6, and a drive pulley 8 fixed to a rotating shaft of the motor 7. A guide member 9 surrounding the driving pulley 8, a driven pulley 10 supported at the other end of the frame 6, a belt 11 stretched relatively loosely between the driving pulley 8 and the driven pulley 10, The frame 6 includes a pair of guide shafts 12 and 13 bridged between both ends of the frame 6 and a movable body 14 that can reciprocate along the two guide shafts 12 and 13. Unitized.

The frame 6 has a positioning projection 15a.
, A second receiving plate 16 bent at a right angle from the upper end of the left leg 15 shown in the figure, and a first receiving plate facing the second receiving plate 16 at a predetermined interval. 17 and
A support plate 18 that is bent substantially at a right angle from the upper end of the right leg 15 in the drawing, and a pair of upstanding pieces 19 that are bent at a right angle from the first receiving plate 17 and the support plate 18 are formed. Pressed from a plate. Grooves 15b and 19a are formed in the leg piece 15 and the standing piece 19, respectively. The guide shafts 12 and 13 are fixed to the frame 6 by caulking the open ends of the grooves 15b and 19a. In addition, each of the positioning projections 1
5a is engaged with each positioning hole 5a of the resistance board 5, and thus, by regulating the resistance board 5 in the three-dimensional direction by the positioning groove 2a of the cover 2 and the positioning protrusion 15a of the leg piece 15, The resistance substrate 5 is fixed to the frame 6 without using screws or caulking.

As shown in FIG. 3 to FIG.
The support plate 18 is formed with a circular through hole 18a and a rectangular regulating hole 18b, and an upright piece 19 on the right side in the drawing is formed with a locking hole 19b. The motor 7 is screwed to the lower surface of the support plate 18, and the rotating shaft 7 a of the motor 7 passes through the through hole 18 a and protrudes above the support plate 18. Note that the support plate 18 is bent at a slightly acute angle with respect to the leg piece 15, and as a result,
The rotation shaft 7a of the motor 7 attached to the support plate 18 is inclined outward by a predetermined angle with respect to a line perpendicular to the guide shafts 12 and 13 (in the case of the present embodiment, the inclination angle is 1 ° 30). '). On the other hand, a gear portion 8a is formed on the outer peripheral surface of the drive pulley 8, and a flange portion 8b is formed at a lower end of the gear portion 8a. This drive pulley 8 is press-fitted into a rotary shaft 7a of the motor 7.・ It is fixed. here,
The shaft hole of the drive pulley 8 and the rotary shaft 7a are each formed in a D-shaped cross section, and the D-shape ensures that the rotation of the rotary shaft 7a is transmitted to the drive pulley 8. As described above, the driving pulley 8 has the belt 11
The teeth 11 a formed on the inner peripheral surface of the belt 11 mesh with the gear 8 a of the driving pulley 8. At this time, the rotating shaft 7a of the motor 7 is inclined so as to slightly outward with respect to a line perpendicular to the two guide shafts 12 and 13, and the driving pulley 8
Rotates, the belt 11 wound around the driving pulley 8
Since the downward force with the flange 8b always acts on the driving pulley 8, the belt 11 can be reliably prevented from falling off only by forming the flange 8b only at the lower end of the driving pulley 8.

The guide member 9 is formed in a bag shape with an open lower end, and a hole 9a is formed in the upper surface thereof. A first snap claw 9b extending downward is formed on one of the opposed side walls of the guide member 9, and a second snap claw 9c extending upward is formed on the other, respectively. Is formed with a hanging piece 9d slightly shorter than the first snap claw 9b. The width of the first snap claw 9b is set to be slightly smaller than the restriction hole 18b of the support plate 18, and similarly, the second snap claw 9b
The width of the snap claw 9c is determined by the locking hole 1 of the upright piece 19.
It is set slightly smaller than 9b. Further, the guide member 9 is formed with a pair of regulating portions 9e facing each other via the first snap claws 9b.
Are formed in a curved shape.

The guide member 9 constructed as described above is put on the drive pulley 8 and the belt 11 wound therearound. The guide member 9 locks the first snap claw 9b in the regulating hole 18b, and the second snap By snapping the claws 9c into the locking holes 19b, respectively, as shown in FIG.
The rotary shaft 7a is rotatably mounted on the support plate 18 of the frame 6 with the rotary shaft 7a protruding from the support plate 18. That is, the first
And the second snap claws 9b and 9c are provided with the restriction holes 1 respectively.
Since the guide member 9 can be moved by a small amount in the width direction with respect to the hole 8b and the locking hole 19b, the guide member 9 can rotate by a small angle around the hole 9a. The belt 11 is stretched around the driven pulley 10 through the space between the first snap claw 9b and both regulating portions 9e, and is in contact with both regulating portions 9e in the vicinity of the exit of the guide member 9. Belt 1 in the regulation part 9e
1 is pressed inward, the tooth portion 1 of the belt 11 is pressed.
1a is reliably engaged with the gear portion 8a of the drive pulley 8. At this time, since the guide member 9 is rotatably mounted on the support plate 18, if the belt 11 is strongly pressed against the one restricting portion 9e due to, for example, the eccentricity of the drive pulley 8 or the deformation of the belt 11. Then, the guide member 9 rotates following the rotation of the guide member 9, and the contact state between the belt 11 and the two regulating portions 9e is always kept good. Further, FIG.
As shown in FIG. 4, a gap is maintained between the winding portion of the belt 11 meshing with the driving pulley 8 and the inner surface of the guide member 9 to keep them in a non-contact state. It is set smaller (a <b) than the tooth size b of the 11 tooth portions 11a.

As shown in FIG. 6, the first frame 6
The receiving plate 17 has an elongated hole 17a extending in the direction of the support plate 18, and the second receiving plate 16 has an elongated engaging hole 16a.
a is formed so as to face the long hole 17a. On the other hand, a gear portion 10a is formed on an outer peripheral surface of the driven pulley 10, and a support shaft 20 having a concave groove 20a on an upper peripheral surface is inserted into a shaft hole 10b of the driven pulley 10. As shown in FIG. 7, the support shaft 20 is inserted into the long hole 17a so that the concave groove 20a sandwiches the first receiving plate 17, and a portion projecting below the driven pulley 10 is engaged. The driven pulley 10 is rotatably supported by the support shaft 20 until it comes into contact with the back of the hole 16a. At this time, the belt 11 is wound around the driven pulley 10 in advance as a force for sliding the support shaft 20 to the inner side of the long hole 17a and the engagement hole 16a, and if the tension of the belt 11 is used, the support shaft 20 is moved to the frame. 6 can be easily locked.

As shown in FIG. 8, the movable body 14 comprises a metal lever 21 and a slider receiver 22 made of synthetic resin.
2 is joined and integrated. As shown in FIG. 9, the lever 21 has a knob 21a, a guide hole 21b through which the blind plate 4 is inserted, a cylindrical portion 21c inserted into the guide shaft 12, and a cylindrical portion 21c.
A hanging piece 21d hanging down from c is formed, and a sliding cylinder 23 made of synthetic resin is snapped into both ends of the cylindrical portion 21c. An L-shaped bent portion 21e, a guide protrusion 21f, and a support protrusion 21 are provided on the front surface of the hanging piece 21d.
g is formed, and a locking claw 21h and a stopper step 21i are formed on the back surface of the hanging piece 21d, and the first slider piece 24 is press-fitted into the support projection 21g.

As shown in FIGS. 10 and 11, the slider receiver 22 has a frame portion 22b having a storage hole 22a therein.
A projecting piece 22c extending upward from the frame portion 22b;
An annular portion 22d inserted into the guide shaft 13 is formed, and a stepped locking groove 22e is formed on the inner wall of the frame portion 22b. An uneven portion 22f having the same shape as the teeth 11a of the belt 11 is formed at the upper end of the protruding piece 22c, and a guide groove 22g is formed on the back surface of the protruding piece 22c. Further, the frame 22
A plurality of bosses 22h are formed on the front surface of b, and the first slider piece 24 and the second and third slider pieces 25 and 26 are caulked and fixed to these bosses 22h.

The movable member 14 constructed as described above is fixed to the belt 11 as described above. In this case, first, as shown in FIGS. Of the slider holder 2
The second protruding piece 22c is moved upward. At that time, lever 2
The one support protrusion 21g abuts one side surface of the protruding piece 22c, and the guide protrusion 21f is engaged with the guide groove 22g. The support protrusion 21g and the guide protrusion 21f allow the protruding piece 22c to be smoothly moved relative to the lever 21. Can be moved to Then, at the position where the upper end of the projecting piece 22c slightly enters the inside of the bent portion 21e, the upper end of the locking groove 22e abuts on the lower end of the stopper step 21i, and the force required to move the projecting piece 22c is reduced. In order to increase, the projecting piece 22
The movement of c is temporarily stopped. In this state, the belt 11 is hung on the upper end of the protruding piece 22c, and the teeth 11a of the belt 11 mesh with the uneven portions 22f of the protruding piece 22c. Thereafter, when the protruding piece 22c is further moved upward, as shown in FIGS. 14 and 15, the upper end of the protruding piece 22c completely enters the inside of the bent portion 21e. It is clamped by the portion 21e. At the same time, the locking claw 21h gets over the step of the locking groove 22e and snaps in, so that the lever 21 and the slider receiver 22 are integrated.

Next, the process of assembling the motor-driven slide type variable resistor configured as described above will be described.

First, the motor 7 is mounted on the support plate 18 of the frame 6.
And a driving pulley 8 is attached to the rotating shaft 7a of the motor 7.
Press-fit and fix. Then, the shaft hole 10 of the driven pulley 10
b, the groove 20a of the support shaft 20 is inserted into the elongated hole 17a, and the lower end of the support shaft 20 is inserted into the engagement hole 16a with the belt 11 wound around the driven pulley 10. I do. Thereafter, when the belt 11 is wound around the driving pulley 8, the tension of the belt 11 causes the support shaft 20 to move into the elongated hole 17 a.
The driven pulley 10 is rotatably supported by the support shaft 20 locked in the elongated hole 17a and the engagement hole 16a. Next, the guide member 9 is attached to the drive pulley 8, and before and after this, the cylindrical portion 21c of the lever 21 is moved.
One guide shaft 12 is inserted into the sliding cylinder 23 snapped into the groove, and both ends of the guide shaft 12 are caulked and fixed to the groove 19 a of the frame 6. Next, the respective slider pieces 24, 25 and 26 are caulked and fixed to the slider receiver 22, and the projecting piece 22c of the slider receiver 22 is slightly inserted into the bent portion 21e of the lever 21. A part of the belt 11 is hung on the upper end of the protruding piece 22c, and the tooth portion 1 of the belt 11 is
1a is engaged with the uneven portion 22f of the protruding piece 22c. Thereafter, the protruding piece 22c is further moved upward, the belt 11 is sandwiched between the protruding piece 22c and the bent portion 21e, and the locking claw 21h is snapped into the step portion of the locking groove 22e so that the lever 21 and the lever 21 are engaged. The movable pair 14 is fixed to the belt 11 by integrating the slider receiver 22. Next, the first slider piece 24 is press-fitted into the support projection 21g, so that the first slider piece 2
4 and the lever 21 are electrically connected, and the other guide shaft 13 is inserted into the annular portion 22d of the slider receiver 22, and both ends of the guide shaft 13 are caulked and fixed to the groove 15b of the frame 6. And the motor drive unit 1 shown in FIG.

Next, the resistance board 5 is inserted between the positioning grooves 2a of the one cover 2 and the cover 2 is mounted on the cover 2 such that the positioning projections 15a of the frame 6 fit into the positioning holes 5a of the resistance board 5. Overlap the motor drive unit 1,
At the same time, the other cover 2 is overlaid on the opposite side of the motor drive unit 1 and both covers 2 are screwed. In this state, most of the components of the resistance board 5 and the motor drive unit 1 are accommodated in the covers 2, but the knob 21 a and the guide hole 21 b of the lever 21 protrude from the gap at the upper end of the covers 2. . Next, the blind plate 4 is inserted into the guide holes 21.
b to cover the gap between the upper ends of the two covers 2 and finally screw the holders 3 to the left and right sides of the two covers 2 to fix both ends of the blindfold plate 4 to the holders 3. The assembly of the driving slide type variable resistor is completed.

When the motor driven slide type variable resistor is disassembled in order to replace the resistor substrate 5, the reverse of the above-described assembling process may be performed. Since the positioning groove 2a and the positioning protrusion 15a of the frame 6 are positioned and held, the slide slides along the positioning groove 2a of the cover 2 without complicated work such as removing a caulking or loosening a screw. With this simple operation, the resistance substrate 5 can be taken out.

Next, the operation of the motor driven slide type variable resistor configured as described above will be described.

When the motor 7 rotates in either the forward or reverse direction in response to an external signal, the driving pulley 8 rotates in accordance with the rotating direction, and the rotational force of the driving pulley 8 is applied to the gear portion 8a and the tooth portion 11a. Since the transmission is reliably transmitted to the belt 11 by the engagement, the belt 11 is driven by the driving pulley 8 and the driven pulley 1.
It turns around zero. When the belt 11 rotates, the movable body 14 fixed to the belt 11 is
It reciprocates along arrows 2 and 13 in the direction of arrow P or Q in FIG. Each of the sliders 24 to 26 is held by the movable member 14. The resistor (not shown) on the resistor substrate 5 and the second and third slider members 2 are moved by the movement of the movable member 14.
Since the position of sliding contact with 5, 26 changes, a resistance value corresponding to the sliding position is output. At that time, when the movable body 14 moves to the ends of both the guide shafts 12 and 13, the movable body 14 and the belt 11 cannot move any more and stop.
When the motor 7 continues to rotate, the phase of the gear portion 8a of the rotating drive pulley 8 and the tooth portion 11a of the stopped belt 11 are shifted, so that the belt 11 is pushed outward by the drive pulley 8, It comes into contact with the inner wall of the guide member 9. Here, since the minimum gap dimension a between the belt 11 and the guide member 9 is set smaller than the toothed dimension b of the tooth portion 11a of the belt 11, when the belt 11 is pushed outward by the dimension a, the guide is extended. The member 9 stops the belt 11 from spreading. Therefore,
The gear portion 8a of the driving pulley 8 cannot get over the tooth portion 11a of the belt 11, and the rotation of the driving pulley 8 and the motor 7 is forcibly locked by the belt 11, so that the gear portion 8a
The abnormal noise caused by the engagement and disengagement between the tooth 11a and the tooth 11a does not occur.

On the other hand, the operator operates the knob 21 of the lever 21.
When a finger touches a, static electricity charged to the operator is output through the first slider piece 24 and a current collector (not shown) on the resistance substrate 5 slidingly contacting the first slider piece 24, and based on the output signal. As a result, the rotation of the motor 7 stops. Then, the operator operates the knob 2
When the movable body 14 is reciprocated in the direction of the arrow P or Q in FIG. 1 by pinching 1a, the belt 11 rotates together with the driving pulley 8 and the driven pulley 10, and the movement of the movable body 14 is performed in the same manner as when the motor is driven. Is output. At this time, the belt 11 is in contact with both regulating portions 9 e of the guide member 9, and the relative position between the belt 11 and the guide member 9 is slightly shifted depending on the moving direction of the movable body 14. Is absorbed by That is, when the movable body 14 moves in a direction (arrow P direction) approaching the drive pulley 10, the movable body 14 and the drive pulley 10
When the movable body 14 moves in a direction away from the drive pulley 10 (in the direction of arrow Q), a force in the compression direction acts on the belt 11 between the movable body 14 and the drive pulley 1.
Although a force in the pulling direction acts on the belt 11 between zero, the guide member 9 rotates following such deformation of the belt 11, so that the belt 11 always comes into contact with both regulating portions 9e with good balance, The rotation of the belt 11 is not hindered by the guide member 9.

In the above embodiment, the protrusion of the tip of the protruding piece 22c formed on the slider holder 22 is inserted into the recess of the bent portion 21e formed on the lever 21.
The case in which the belt 11 is clamped between the concave portion and the projection has been described.
May be inserted into a recess formed in the slider receiver 22.

[0028]

As described above, according to the present invention,
The movable body is composed of a lever and a slider piece that are joined and integrated with each other, and the belt is sandwiched between these levers and the slider piece, so that the movable body can be easily fixed to the belt. Can be. At this time, a recess is provided in one of the lever and the slider holder, and a protrusion is provided in the other, and the belt is sandwiched between the recess and the protrusion. Can reliably be clamped between the inner wall and the projection. In addition, if the protrusions are provided with irregularities that mesh with the teeth of the belt, the movable body can be securely fixed to the belt even if the holding portion is made smaller, so that the size of the motor-driven slide variable resistor can be reduced. Further, if the holding portion for holding the belt and the fixing portion for integrating the lever and the slider receiver are provided at different positions, the force for integrating the lever and the slider receiver affects the belt holding portion. Since it is difficult to provide, it is possible to improve the assembling workability. Further, as this fixing portion, a leg piece provided on one of the lever and the slider receiver is slidably connected to a guide hole provided on the other, and the leg piece is inserted into the guide hole. When the snap-in structure is adopted, the leg pieces are guided by the guide holes when the lever and the slider receiver are integrated, so that the assembling workability can be further improved.

[Brief description of the drawings]

FIG. 1 is an exploded perspective view showing the overall configuration of a motor-driven slide variable resistor according to one embodiment of the present invention.

FIG. 2 is a perspective view of a motor drive unit provided in the motor driven slide type variable resistor.

FIG. 3 is an exploded perspective view showing a support structure of a drive pulley provided in the motor drive unit.

FIG. 4 is an explanatory diagram showing a positional relationship between the driving pulley and a guide member.

FIG. 5 is a cross-sectional view showing an attached state of the guide member.

FIG. 6 is an exploded perspective view showing a support structure of a driven pulley provided in the motor drive unit of FIG. 2;

FIG. 7 is a sectional view showing an attached state of the driven pulley.

8 is an exploded perspective view of a movable body provided in the motor drive unit of FIG.

FIG. 9 is a side view of a lever provided on the movable body.

FIG. 10 is a plan view of a slider receiver provided on the movable body.

FIG. 11 is a rear view of the slider receiver.

FIG. 12 is a plan view showing a state in which the movable body of FIG. 8 is being attached to a belt.

FIG. 13 is a sectional view taken along the line AA of FIG.

FIG. 14 is a plan view showing a state where the movable body of FIG. 8 has been attached to a belt.

FIG. 15 is a sectional view taken along the line BB of FIG. 14;

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Motor drive unit 5 Resistance board 6 Frame 7 Motor 7a Rotating shaft 8 Drive pulley 8a Gear part 8b Flange part 9 Guide member 9b First snap claw 9c Second snap claw 9e Restriction part 10 Follower pulley 10a Gear part 11 Belt 11a Tooth portion 12, 13 Guide shaft 14 Movable body 16 Second receiving plate 16a Engagement hole 17 First receiving plate 17a Long hole 18 Support plate 18a Through hole 18b Restriction hole 19 Standing piece 19b Lock hole 20 Support shaft 20a Recess Groove 21 Lever 21a Knob 21d Hanging piece 21e Bend 21f Guide protrusion 21h Locking claw 21i Stopper step 22 Slider receiver 22a Storage hole 22c Projection piece 22e Lock groove 22f Uneven part 22g Guide groove 24, 25, 26 Slider piece

Claims (5)

(57) [Claims] A drive pulley rotated by a motor;
A driven pulley that is installed facing the drive pulley at a predetermined interval, a belt stretched between the drive pulley and the driven pulley, a movable body fixed to a part of the belt, A held sliding piece, and a resistive substrate slidably contacting the sliding piece, and a resistance change caused by a change in a sliding contact position between the sliding piece and the resistive substrate due to reciprocation of the movable body. A motor-driven slide type variable resistor whose value is adjusted, wherein the movable body includes a lever manually operated by an operator, and a slider receiver for holding the slider piece. A motor-driven slide type variable resistor, wherein the belt is sandwiched between a slider receiver. 2. The device according to claim 1, wherein a recess is provided in one of the lever and the slider receiver, and a protrusion inserted into the recess is provided in one of the other, and the recess and the protrusion are provided. A motor driven slide type variable resistor characterized in that the belt is held between the variable resistor and the slide. 3. The motor-driven slide according to claim 1, wherein a fixed portion for integrating the lever and the slider receiver and a holding portion for holding the belt are provided at different positions. Type variable resistor. 4. The gear according to claim 2, wherein a gear portion is formed on the driving pulley and the driven pulley, a tooth portion is formed on the belt so as to mesh with the gear portion, and the tooth portion is formed on the projection. A motor driven slide type variable resistor characterized by having irregularities which mesh with the motor. 5. The fixing device according to claim 3, wherein the fixing portion includes a leg provided on one of the lever and the slider receiver, and a guide hole provided on the other.
A motor-driven slide type variable resistor, characterized in that the leg piece and the guide hole are slidably connected and a snap joint is provided to integrate the two.