JP2005101420A - Rotary variable resistor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a rotary variable resistor in which an adjusting groove of an operating shaft is discriminated easily even when the variable resistor is a small-sized semifixed type. <P>SOLUTION: The rotary variable resistor is provided with: an insulating substrate 11 on which a resistor 12 is formed; a slider 10 which relatively rotates and moves on the resistor 12; and a rotating body 8 which is integrated with either one of the insulating substrate 11 and slider 10 so that the body 8 may become rotatable and has an adjusting section 8c composed of recessed and projecting sections. The resistor is also provided with a case 1 which houses the rotating body 8. The adjusting section 8c is made easily distinguishable by improving the visibility of the section 8c by marking by marking the recessed sections or projecting sections of the section 8c. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a rotary variable resistor suitable for use in a semi-fixed variable resistor.

  As a structure of a conventional rotary variable resistor, a structure having an operation groove (driver groove) on an operation shaft is known (for example, see Patent Document 1).

Hereinafter, the structure of a conventional rotary variable resistor will be described with reference to the drawings.
FIG. 13 is a longitudinal sectional view showing a conventional rotary variable resistor, and FIG. 14 is a plan view showing the conventional rotary variable resistor.

  In the figure, 51 is a central plate made of a conductive metal material having a central hole 51a, a lead terminal portion 51d, and a fixing claw portion 51e, and 54 is a movable body made of a conductive material having elasticity. One surface side 54a is in contact with one side 51b of the central plate 51 and is disposed so as to engage with the central hole 51a of the central plate 51, and an engaging claw portion 54d is formed by caulking, whereby the central plate 51 is formed. The movable body 54 is attached to the other surface side 54b of the movable body 54, and a contact 54c is formed.

  52 is a case made of an insulating synthetic resin material by inserting a part of the central plate 51. The case 52 has an opening 52a on one side 51b of the central plate 51, and on the other side 51c of the central plate 51. An operation hole 52b is formed, and a protrusion 52c is formed in a part of the operation hole 52b.

  53 is an operation shaft made of the same synthetic resin material as the case 52, and has a shaft head 53a in the operation hole 52b of the case 52 on the other side 51c of the center plate 51, and the center hole 51a of the center plate 51 and the movable body. A small-diameter portion 53d is formed on the other surface side 54b side of the movable body 54 so as to pass through the central portion where the engagement claw portion 54d of 54 is formed, and is disposed so as not to fall off and to be movable with respect to the central plate 51. A protrusion 53c is formed from the center of the shaft head 53a toward the operation hole 52b of the case 52, and operation grooves 53b and 53e are formed at the ends of the shaft head 53a and the small diameter portion 53d, respectively. Yes.

  That is, after the movable body 54 is attached to the central plate 51, the case 52 and the operation shaft 53 are integrally formed on the central plate 51 and the movable body 54, and the movable body 54 rotates together with the operation shaft 53. Will be.

  Reference numeral 55 denotes a substrate made of an insulating material having a through hole 55a. An arc-shaped resistor film is formed on one main surface 55b of the substrate 55, and lead terminals 58 are respectively connected to both ends of the resistor film by solder 57. Is connected.

  Here, the lead terminal portion 51d and the fixing claw portion 51e of the central plate 51 formed integrally with the case 52, the operation shaft 53, and the movable body 54 are bent in the direction of the opening 52a of the case 52, and after being bent. The lead terminal portion 51d is formed, the contact 54c of the movable body 54 is pressed against the resistor film on the one main surface 55b of the substrate 55, and the small-diameter portion 53d of the operation shaft 53 passes through the through hole 55a of the substrate 55. After the substrate 55 is disposed so as to seal the opening 52a of the case 52, the claw portion 51e for fixing the center plate 51 is further bent toward the other main surface 55c of the substrate 55, thereby A fixing claw portion 51e is formed, and the central plate 51 and the substrate 55 are fixed.

  As an operation of the rotary variable resistor having the above-described configuration, a jig such as a screwdriver is provided in the operation groove 53b formed in the shaft head 53a of the operation shaft 53 or the operation groove 53e formed in the small diameter portion 53d. When the operation shaft 53 is engaged and moved, the contact 54c of the movable body 54 slides on the resistor film formed on the substrate 55 together with the operation shaft 53, and a desired resistance value is obtained.

JP-A 61-256605

  However, in the conventional rotary variable resistor described above, since the operation groove of the operation shaft becomes extremely small with the miniaturization of the semi-fixed variable resistor, it is difficult to distinguish the operation shaft. There is a problem in that adjustment in this becomes difficult and adjustment time becomes long.

  Therefore, the present invention solves the above-described problems, and provides a rotary variable resistor that is easy to discriminate the adjustment groove (adjustment portion) of the operation shaft even with a miniaturized semi-fixed variable resistor and has excellent workability. For the purpose.

  In order to solve the above-mentioned problems, the present invention provides as a first solution means an insulating substrate on which a resistor is formed, a slider that relatively rotates on the resistor, and the insulating substrate or the sliding member. A rotating body that is integrated with any one of the elements and is rotatable, and has an adjustment part composed of a concavo-convex part, and a case that accommodates the rotating body, and marking the concave or convex part of the adjustment part. The configuration was as follows.

As a second solution, the marking is performed by irradiating the concave portion or the convex portion of the adjustment portion with a laser.
As a third solving means, the marking is applied to the concave portion of the adjusting portion.
Further, as a fourth solution, the case and the rotating body are formed of the same material, a code representing the resistance value of the resistor is provided on one surface of the case, the code applied to the case, and the adjustment unit The marking was applied by the same means.
As a fifth solution, the rotating body is made of a dark synthetic resin.

  As described above, the rotary variable resistor of the present invention includes an insulating substrate on which a resistor is formed, a slider that relatively rotates on the resistor, and either the insulating substrate or the slider. Because it is integrated with one side and is rotatable, it has a rotating body with an adjustment part consisting of uneven parts, and a case that houses the rotating body, and the concave part or convex part of the adjustment part is marked, so marking Since the visibility of the adjustment unit is improved, the determination of the adjustment unit is facilitated, and the efficiency of manual adjustment work can be improved.

In addition, since the marking is performed by irradiating the adjustment unit with laser, it is possible to perform the marking efficiently even with a small size. Moreover, since the marking is applied to the concave portion of the adjustment portion, the marking is not removed.
In addition, the case and the rotator are formed of the same material, and a code representing the resistance value of the resistor is provided on one surface of the case, and the code applied to the case and the marking of the adjustment unit are applied by the same means, so that the same process Since the sign and marking can be formed, productivity is good.
Further, since the rotating body is formed of a dark colored synthetic resin, even if it is a dark colored synthetic resin whose unevenness is difficult to be identified, the adjustment portion can be easily identified by marking.

  1 to 12 show one embodiment of a rotary variable resistor according to the present invention. 1 is a perspective view of a rotary variable resistor of the present invention, FIG. 2 is a plan view of the rotary variable resistor, FIG. 3 is a bottom view of the rotary variable resistor, and FIG. 4 is a side view of the rotary variable resistor. 5 is a cross-sectional view of the rotary variable resistor, FIG. 6 is a plan view of a state in which the rotating body and the case are connected, FIG. 7 is a bottom view showing the internal state of the case, and FIG. 8 is a main portion of FIG. FIG. 9 is a plan view of the slider, FIG. 10 is a side view of the slider, FIG. 11 is a bottom view of the slider holding the slider, and FIG. 12 is a plan view of the insulating substrate. .

In the figure, the case 1 is made of an insulating material such as a synthetic resin and has an outer shape that is substantially rectangular. The case 1 has a rectangular upper plate portion 1a on one surface side, and a housing portion 1b formed of a concave portion is provided at the center portion of the case 1. Further, a support portion 1c formed of a stepped portion is provided on the other surface side facing the upper plate portion 1a of the case 1, and a plurality of projecting portions 1d are provided outside the support portion 1c.
Moreover, as shown in FIG. 2, the code | symbol 1e which shows the resistance value etc. of the resistor 12 mentioned later is formed in the one end side of the upper board part 1a.

The first contact plate 2 is made of a conductive metal plate, has a plate-like base portion 2a, and a circular opening 2b provided at the center of the base portion 2a, and from the outer periphery of the base portion 2a. A first terminal portion 3 is formed integrally with the first contact plate 2 in a conductive state and extends outward from the case 1.
The first contact plate 2 is attached so that the outer peripheral portion of the base portion 2a is integrally embedded in the case 1 and does not move relatively. The center of the base portion 2a is located in the storage portion 1b, and 1 terminal portion 3 protrudes outward from case 1.

The second contact plates 4 and 5 are also made of a conductive metal plate, plate-like base portions 4a and 5a, and elastic contact portions 4b and 5b serving as connection portions provided on one end side of the base portions 4a and 5a. A second terminal portion 6 that is formed integrally with the second contact plates 4 and 5 from the outer periphery of the base portions 4a and 5a and is formed integrally by the same member and extends outward from the case 1. 7 are respectively extended.
The second contact plates 4 and 5 are attached such that a part of the bases 4a and 5a is embedded in the case 1 integrally. The elastic contact portions 4b and 5b are bent so as to be located in the storage portion 1b, and the second terminal portions 6 and 7 protrude outward from the case 1.

The rotating body 8 is made of an insulating material such as synthetic resin, and is provided with a disk-shaped holding portion 8a, an operation portion 8b provided protruding above the holding portion 8a, and a front surface of the operation portion 8b. A cross-shaped adjustment groove 8c that constitutes a driver engaging adjustment portion made up of a concavo-convex portion is provided.
Further, the holding portion 8a is provided with a central concave portion 8d and a groove portion 8e connected from the central concave portion 8d to the outer peripheral portion of the holding portion 8a. A plurality (three in this embodiment) of the groove portions 8e are provided, and are formed corresponding to connecting portions 10c of the slider 10 described later. Further, when viewed as shown in FIG. 5, the groove 8e corresponds to the inclination of the connecting portion 10c so as to be located upward from the central recess 8d, that is, with an insulating substrate 11 described later. Is inclined so that the distance from the central recess 8d increases outward.

The rotating body 8 is integrally formed and embedded in the opening 2b provided in the center of the base 2a of the first contact plate 2 in a state where the rotating body 8 is positioned in the housing 1b of the case 1, and is attached to the case 1. It has been.
That is, the first contact plate 2 is embedded in the case 1 and the rotating body 8 and is held by the case 1, and the rotating body 8 is supported by the first contact plate 2 and the opening 2 b. Can be rotated endlessly. The rotating body 8 and the case 1 are each provided with a stopper portion formed of a convex portion, and the rotating body stopper portion located in the storage portion 1b abuts with the stopper portion of the case 1 so that the rotating body 8 rotates. You may comprise so that it may stop.

Further, the rotating body 8 and the case 1 are manufactured simultaneously by the same molding die, and when the rotating body 8 and the case 1 are manufactured simultaneously by molding, As shown in FIG. 8, the case 1 is connected by a crosspiece 9 made of synthetic resin.
A plurality of the crosspieces 9 are formed as thin portions in the circumferential direction on the upper and lower sides with the base 2a of the first contact plate 2 as a boundary.

  During the molding process, the resin is injected from the side surface of the case 1 into the molding die through one or a plurality of resin injection ports called side gates. Since the portion 9 serves as a resin passage between the case 1 and the rotating body 8, it can be easily molded.

As described above, when the rotating body 8 or the case 1 is rotated in a state where the case 1 and the rotating body 8 are integrated by the first contact plate 2, the crosspiece 9 is cut and the rotating body 8 can rotate. At the same time, the lower surface of the base portion 2a is in an exposed state so as to be in contact with a slider 10 to be described later.
Further, when the case 1 and the rotating body 8 are integrated by the first contact plate 2, the gap formed by the storage portion 1b located between the case 1 and the rotating body 8 is closed by the base portion 2a. ing.

In the present embodiment, the rotating body 8 is made of a synthetic resin containing a dark glass component such as liquid crystal polyester, and includes a concavo-convex portion provided on the front surface of the operation portion 8 b of the rotating body 8. The adjustment portion for engaging the driver is marked on the concave portion (adjustment groove 8c) or the convex portion (portion located between the adjustment grooves 8c) so that the cross-shaped adjustment groove 8c of the rotating body 8 can be easily identified. ing. Note that the dark color in this case is a color with low brightness such as black, brown, or blue, that is, a color that has a low visual reflectance and feels dark.
As described above, since the marking is made on the concave portion or the convex portion constituting the adjustment groove 8c, the visibility of the adjustment groove 8c is improved by the marking, so that the adjustment groove 8c can be easily discriminated, and manual adjustment work can be performed. The efficiency can be improved.

The marking method in this embodiment is formed by irradiating the concave portion of the adjustment groove 8c with a laser as shown by hatching in FIG. In this case, even if it is a dark synthetic resin where it is difficult to distinguish irregularities by irradiating with a laser, the glass component inside the synthetic resin burns and develops color, so that the irradiated part becomes gray. It can be marked with good characteristics.
Further, since the marking is applied by irradiating the concave portion of the adjustment groove 8c with a laser, it is possible to perform marking efficiently even with a small size, and the marking can be taken because the marking is applied to the concave portion. Absent. Moreover, even if it is a dark synthetic resin with which it is hard to distinguish an unevenness | corrugation, it is possible to identify the adjustment groove | channel 8c easily by marking.

The rotating body 8 and the case 1 are made of the same material (synthetic resin) and are simultaneously manufactured by the same molding die. That is, when the rotating body 8 and the case 1 are manufactured simultaneously by molding, the rotating body 8 and the case 1 are connected by the crosspiece 9 made of the same synthetic resin.
Therefore, when marking is performed on the adjustment groove 8 c of the rotating body 8, the marking and the reference numeral 1 e representing the resistance value of the resistor 12 may be formed on one surface of the case 1 by the same means.
In this case, since the reference numeral 1e of the case 1 and the marking of the adjustment portion (adjustment groove 8c) of the rotating body 8 can be formed in the same process, productivity is improved. In addition, there are methods such as laser and printing as means for applying markings and codes, and the marking position is not limited to the concave portion (adjusting groove 8c) of the adjusting portion, but may be a convex portion positioned between the adjusting grooves 8c. .

  The slider 10 is made of a conductive metal plate having elasticity, and a central plate that engages with an annular portion 10a that surrounds the outer periphery of the holding portion 8a of the rotating body 8 and a central recess 8d of the holding portion 8a. It has a portion 10b and a connecting portion 10c that is connected to the central plate portion 10b and the annular portion 10a and engages with the groove portion 8e of the holding portion 8a. The connecting portion 10c engages with the groove portion 8e of the holding portion 8a, whereby the slider 10 is held by the holding portion 8a of the rotating body 8.

  As described above, the holding portion 8a of the rotating body 8 is formed with the central recessed portion 8d and the groove portion 8e connected to the outer peripheral portion of the holding portion 8a from the central recessed portion 8d. An annular portion 10a surrounding the outer periphery of 8a, a central plate portion 10b corresponding to the central recess portion 8d, and a connecting portion 10c corresponding to the groove portion 8e are formed, and by engaging the connecting portion 10c with the groove portion 8e, the sliding portion Since the moving element 10 is held on the holding portion 8a of the rotating body 8, no caulking work is required to attach the slider 10 to the holding portion 8a of the rotating body 8, so that the assembly workability is good. The cost can be reduced.

A sliding contact 10d that slides on a resistor 12 of an insulating substrate 11 described later is provided on the annular portion 10a of the slider 10. Further, a plurality of connecting portions 10 c of the slider 10 are formed corresponding to the groove portions 8 e of the holding portion 8 a of the rotating body 8. In this case, the connecting portions 10 c sandwich the rotation center of the rotating body 8. At least one is formed at a position facing the sliding contact 10d.
As a result, the sliding contact 10d and the one connecting portion 10c are arranged at positions opposed to each other with the rotation center of the rotating body 8 interposed therebetween, so that the elastic force is balanced and the slider 10 is securely held. Can do.

Further, the central plate portion 10b of the slider 10 is formed with the connecting portion 10c inclined so as to be positioned on the insulating substrate 11 side described later than the annular portion 10a.
Further, the central plate portion 10b of the slider 10 is in contact with the insulating substrate 11 due to the elasticity of the connecting portion 10c, and correspondingly, a part of the annular portion 10a is always the first contact plate. 2 is in contact with and conductive.
That is, the slider 10 is held by the holding portion 8a of the rotating body 8 so that a part of the annular portion 10a is always in contact with the first contact plate 2 and rotates together with the rotating body 8. It has become.

Thus, the central plate portion 10b of the slider 10 is formed with the connecting portion 10c inclined so as to be positioned closer to the insulating substrate 11 than the annular portion 10a, and is engaged with the groove portion 8e. Since the annular portion 10a is separated from the insulating substrate 11, the annular portion 10a other than the sliding contact 10d does not come into contact with the pattern made of the resistor 12, and an accurate signal can be obtained.
Further, the central plate portion 10b of the slider 10 is in contact with the insulating substrate 11 due to the elasticity of the connecting portion 10c, and a part of the annular portion 10a corresponding to this is always the first contact plate 2. Therefore, the slider 10 can be prevented from falling off, and an appropriate sliding pressure can be obtained when the rotating body 8 is rotated, so that a stable contact pressure can be obtained.

The insulating substrate 11 is made of a plate-like insulating material such as ceramic, and a horseshoe-shaped resistor 12 made of a conductor such as carbon is provided on the upper surface. In addition, electrode portions 13 and 14 made of a conductive material such as silver are formed at both ends of the resistor 12 and are laminated in a conductive state.
The insulating substrate 11 is placed on a support portion 1 c provided at the lower portion of the case 1 with the resistor 12 facing upward.

Then, the first terminal portion 3 and the second terminal portions 6 and 7 extending outward from the case 1 are bent along the side plate portion of the case 1, and this bent tip portion is Further, the insulating substrate 11 is pressed against the support portion 1c by the bent portions 3a, 6a, and 7a bent to the lower surface side of the case 1. The bent portions 3a, 6a, and 7a are soldered when the rotary variable resistor is surface-mounted on a circuit board (not shown) such as an electronic device.
That is, the insulating substrate 11 is attached to the lower portion of the case 1 by the first terminal portion 3 and the second terminal portions 6 and 7.

As described above, the second contact plates 4 and 5 are provided with the elastic contact portions 4 b and 5 b by bending the metal plate, and the elastic contact portions 4 b and 5 b are the electrode portions 13 and 14 at the end of the resistor 12. By superposing the insulating substrate 11 on the other surface side of the case 1 so as to be electrically connected to each other, and bending the first terminal portion 3 and the second terminal portions 6 and 7 to the other surface side of the insulating substrate 11, Since the insulating substrate 11 is held in the case 1, the first terminal portion 3 and the second terminal portions 6 and 7 made of a metal plate are provided with a terminal for external connection and a mounting piece for holding the insulating substrate. Therefore, it is possible to reduce the number of parts without separately requiring a terminal member that is electrically connected to the resistor 12.
In addition, since the elastic contact portions 4b and 5b are formed in the contact portions that are in conduction with the electrode portions 13 and 14 at the end portions of the resistor 12, the conduction is more reliable due to the elasticity of the metal plate. Since it is not necessary to provide a caulking hole, the size can be reduced.

Further, at this time, the second terminal portions 6 and 7 are opposed to the elastic contact portions 4 b and 5 b of the second contact plates 4 and 5 through the insulating substrate 11 by being bent to the other surface side of the insulating substrate 11. The elastic contact portions 4b and 5b and the electrode portions 13 and 14 provided at both ends of the resistor 12 are sandwiched between the case 1 and the second terminal portions 6 and 7 in a conductive state. For this reason, electrical connection between the second contact plates 4 and 5 and the end of the resistor 12 can be reliably obtained.
In addition, the elastic contact portions 4b and 5b of the second contact plates 4 and 5 that are electrically connected to the electrode portions 13 and 14 of the resistor 12 are formed by bending the metal plate. Conductivity with the parts 13 and 14 is obtained with certainty.

  When the insulating substrate 11 is attached, the projecting portions 4b and 5b of the second contact plates 4 and 5 are in contact with the electrode portions 13 and 14 provided at both ends of the resistor 12, respectively. When the resistor 12 faces the first contact plate 2, the sliding contact 10 d of the slider 10 comes into contact with the resistor 12, and when the slider 10 is rotated by the rotating body 8, The moving element 10 slides in a state in which the resistor 12 and the first contact plate 2 are electrically connected to each other, and detects a change in the resistance value of the resistor 12 at this time, thereby detecting the first The terminal part 3 and the second terminal part 6 or 7 are taken out from between the terminal part 3 and the second terminal part 6.

  In the present embodiment, a support portion 1c including a step when attaching the insulating substrate 11 is provided on the other surface facing the upper plate portion 1a of the case 1, and outside the support portion 1c. Is provided with a plurality of protrusions 1d.

And the 1st terminal part 3 and the 2nd terminal parts 6 and 7 are bend | folded along the side-plate part of case 1, and the insulated substrate 11 is the 1st terminal part 3 and the 2nd terminal part. 6 and 7, which are attached to the lower part of the case 1, but in the present embodiment, the first terminal portion 3 in which these protrusions 1 d are further bent to the other surface side of the insulating substrate 11, and It is caulked to the other surface side of the insulating substrate 11 so as not to protrude from the second terminal portions 6, 7, that is, thermally welded, so that the insulating substrate 11 is securely held at the lower portion of the case 1.
In this case, the caulking portion of the protruding portion 1d is formed between the first terminal portion 3 and the second terminal portions 6 and 7 (see FIG. 3).

For this reason, the insulating substrate 11 can be reliably held in the case 1 by the respective first terminal portions 3 and the second terminal portions 6 and 7 and the respective protruding portions 1d.
Further, even when the first terminal portion 3 and the second terminal portions 6 and 7 are mounted on the surface of a circuit board such as an electronic device, the terminal portion does not float by the protrusion 1d. The reliability at the time of mounting can be improved.
Further, since the caulking portion is formed between each of the first terminal portion 3 and the second terminal portions 6 and 7, the insulating substrate 11 can be held more reliably.

It is a perspective view which shows the rotary type variable resistor of this invention. It is a top view which shows the rotary type variable resistor of this invention. It is a bottom view which shows the rotary type variable resistor of this invention. It is a side view which shows the rotary type variable resistor of this invention. It is sectional drawing which shows the rotary type variable resistor of this invention. It is a top view which shows the state with which the rotary body of this invention and the case were connected. It is a bottom view which shows the state inside the case of this invention. It is principal part sectional drawing of FIG. 6 of this invention. It is a top view which shows the slider of this invention. It is a side view which shows the slider of this invention. It is a bottom view which shows the state which hold | maintained the slider on the rotary body of this invention. It is a top view which shows the insulated substrate of this invention. It is sectional drawing which shows the conventional rotary type variable resistor. It is a top view which shows the conventional rotary type variable resistor.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1: Case 1a: Upper board part 1b: Storage part 1c: Support part 1d: Protrusion part 1e: Code | symbol 2: 1st contact plate 2a: Base part 2b: Opening part 3: 1st terminal part 3a: Bending part 4 : Second contact plate 4a: base portion 4b: elastic contact portion 5: second contact plate 5a: base portion 5b: elastic contact portion 6: second terminal portion 6a: bent portion 7: second terminal portion 7a: Bending part 8: Rotating body 8a: Holding part 8b: Operation part 8c: Adjustment groove (adjustment part)
8d: Central concave portion 8e: Groove portion 9: Crosspiece portion 10: Slider 10a: Annular portion 10b: Central plate portion 10c: Connection portion 10d: Sliding contact 11: Insulating substrate 12: Resistor 13: Electrode portion 14: Electrode portion

Claims (5)

  An insulating substrate on which a resistor is formed, a slider that relatively rotates and moves on the resistor, and is integrated with either the insulating substrate or the slider so as to be rotatable. A rotary variable resistor comprising: a rotating body having an adjustment portion comprising: a case housing the rotation body; and a marking provided on a concave portion or a convex portion of the adjustment portion.   The rotary variable resistor according to claim 1, wherein the marking is performed by irradiating the concave portion or the convex portion of the adjustment portion with a laser.   The rotary variable resistor according to claim 1, wherein the marking is applied to the concave portion of the adjustment unit.   The case and the rotating body are formed of the same material, a code representing the resistance value of the resistor is provided on one surface of the case, and the code applied to the case and the marking of the adjustment unit are applied by the same means. The rotary variable resistor according to claim 1. 5. The rotary variable resistor according to claim 1, wherein the rotating body is made of a dark synthetic resin.

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