KR100241563B1 - Rotation type rheostat - Google Patents

Abstract

The present invention miniaturizes the stopper structure for regulating the rotational angle of the perturbator and increases its positional accuracy.

A resistor 5 is formed on the surface of the base 1 made of synthetic resin having a recess 1a in the center, and the pair of terminals 3 and the intermediate terminal 4 are out put on the base 1. To integrate. A pair of stopper pieces 10 are bent on the intermediate terminal 4 along the bending line L, and a cross section substantially perpendicular to the bending line L is exposed into the recess 1a to stopper 10a. To form. In addition, the small hole member 6 is integrally formed in the intermediate terminal 4, and the small hole member 6 supports the perturbator 2 on the base 1 while being rotatably supported. The contact portion 9a provided on the copper plate 2 is elastically contacted on the resistor 5. In addition, the rotational angle of the perturbator 2 is controlled by the protrusion 8c formed on the perturbator 2 in contact with the stopper 10a during the rotation operation of the perturbator 2.

Description

Rotary Variable Resistor {ROTATION TYPE RHEOSTAT}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a rotary variable resistor that adjusts a resistance value by varying the resistance position of the resistor and the perturbator by rotating the perturbator with an adjusting jig such as a driver. .

Conventionally, Japanese Unexamined Patent Application Publication No. 5-1044 and the like have proposed a rotary variable resistor that employs a stopper structure for controlling the rotation of a perturbator. The rotary variable resistor described in the above publication is composed of a pair of terminals, a base of a synthetic resin having one intermediate terminal inserted therein, and a perturbator rotatably supported on the base, and a pair of stoppers on the intermediate terminal. The side is formed. These stopper pieces are bent at a right angle so that the plate surface faces the protrusion of the perturbator. A resistor is formed on the upper surface of the base, and both ends of the resistor are connected to a pair of terminals. The perturbator is provided with a contact portion which contacts the upper surface of the resistor, and the perturbator is connected to the intermediate terminal. In addition, a recess is formed in the base to surround the resistor, and a percussion part is formed in the perturbator. The plate surface of the pair of stopper pieces formed in the intermediate terminal is exposed as a recess.

In the rotary variable resistor configured as described above, when the perturbator is rotated using an adjustment jig such as a driver, the perturbator's contact portion, the resistor, and the perturbation position change, so that the change of the resistance value is detected through the intermediate terminal. Moreover, when the protrusion formed in the perturbator abuts on the plate surface of either stopper piece, the rotation angle of the perturbator is regulated.

In the conventional stopper structure, a stopper piece for regulating the rotational angle of the perturbator is formed at the intermediate terminal, and the stopper piece is formed at the intermediate terminal made of a metal plate so that the protrusion of the perturbator is brought into contact with the base of the synthetic resin. Compared with the stopper structure, the stopper strength can be increased.

However, since the stopper piece exposes a plate surface bent at right angles to the metal plate, if the right angle of the stopper piece is not maintained correctly, the position of the perturbator protrusion is disturbed. In general, the bending process of the metal plate involves spring back. Therefore, it was difficult to maintain the squareness of the stopper piece accurately. Moreover, when a load from the perturbator was applied, the stopper piece was easily deformed around the bending point, and there was a problem that the stopper strength could not be increased. In addition, because the plate surface of the stopper piece is exposed to the concave portion, the stopper piece cannot be made small in order to secure a certain stopper strength, and it is applicable to a chip-shaped rotary variable resistor having a small external dimension (for example, about 2 to 3 mm). There was also a problem that was difficult to do.

The present invention has been made in view of the situation of the prior art, and an object thereof is to provide a rotary variable resistor suitable for miniaturization because the rotation angle of the perturbator can be regulated with high precision.

1 is a plan view of a rotary variable resistor according to an embodiment of the present invention;

2 is a side view of the variable resistor;

3 is a rear view of the variable resistor,

4 is a perspective view of a terminal and an intermediate terminal provided in the variable resistor;

5 is a plan view of the base plate provided in the variable resistor;

6 is a cross-sectional view taken along the line A-A of FIG.

7 is an exploded perspective view of the variable resistor,

8 is a perspective view illustrating a modification of the stopper structure.

(Explanation of symbols for the main parts of the drawing)

1: Foundation stage 1a: Concave portion

1b: convex portion 1c: flat portion

2: perturbator 3: terminal

4: middle terminal 5: resistor

6: small hole member 7: top plate

8: cylindrical part 8a: through hole

8b: adjustment groove 8c: projection

9: bottom plate 9a: contact portion

10: stopper piece 10a: stopper

12: stopper piece 12a: stopper

According to the present invention, a stopper piece is bent on a metal plate, and the metal plate is out-formed on a base of a synthetic resin, and a cross section substantially perpendicular to the bend line of the stopper piece is exposed to form a stopper. In this way, if the stopper has a cross section that is substantially orthogonal to the bending line of the stopper piece, the angle of the cross section functioning as the stopper is maintained even during machining and under load regardless of the bending angle of the stopper piece. This eliminates mismatches and reduces the size of the stopper structure. In addition, since the stopper piece is buried in the synthetic resin, the metal sheet itself is held by the synthetic resin, and the stopper strength can be increased in this respect.

In the rotary variable resistor of the present invention, the base plate made of a synthetic resin having a resistor formed on a surface thereof, and a perturbator rotatably installed on the base plate, and a stopper piece is bent on a metal plate, and the metal plate is formed on the base plate. The cross section orthogonal to the bending line of the stopper piece was exposed at the same time as the end formation, and the end face was brought into contact with the perturbator to obtain a stopper.

The metal flat plate on which the stopper piece is formed may be any type as long as it is out- put on the base plate.

Further, by forming a concave portion into which the perturbator is inserted into the base, and exposing the end face of the stopper piece to the concave portion, it is possible to reduce the external dimension of the rotary variable resistor together with the stopper structure, and further to the perturbator. If the cylindrical part which rotates in the said recessed part is formed, and the protrusion part which can contact the said stopper is formed in the said cylindrical part, the external dimension of a rotary type variable resistor can be reduced significantly.

(Example)

1 is a plan view of a rotary variable resistor, FIG. 2 is a side view of the variable resistor, FIG. 3 is a rear view of the variable resistor, and FIG. 4 is a terminal provided with the variable resistor. 5 is a plan view of a base plate provided in the variable resistor, FIG. 6 is a cross-sectional view taken along line AA of FIG. 1, and FIG. 7 is an exploded perspective view of the variable resistor.

As shown in these figures, the rotary variable resistor according to the present embodiment is composed of a base 1 made of synthetic resin and a metal perturbator 2 rotatably provided on the base 1. In the center of the surface of the base 1, a substantially circular concave portion 1a is provided in plan view, and a pair of convex portions 1b protruding slightly inward are formed around the concave portion 1a. . The outer side of the concave portion 1a is formed of a flat portion 1c that is substantially horseshoe-shaped in plan view, and portions except the flat portion 1c are formed in a short-circuit shape. Vertical grooves 1d are formed on one side of the base 1, and an upper end of the vertical grooves 1d reaches the short circuit portion 1e positioned between the two convex portions 1b.

A pair of terminals 3 and one intermediate terminal 4 are provided on the rear surface of the base 1, and both of these terminals 3 and the intermediate terminal 4 are formed by forming a metal flat plate in a predetermined shape. It is made and integrated with the base 1 by the out molding. As shown in FIG. 4, each terminal 3 is bent in concave shape. One upper end 3a of the bent portion is exposed to the flat portion 1c. The resistor 5 is printed on the entire area of the flat portion 1c which is in the same plane as the upper end 3a of each terminal 3 and the flat part 1c, and includes the upper end 3a of these terminals 3. Formed. On the other hand, a pair of stopper pieces 10 and a small hole member 6 are integrally formed in the intermediate terminal 4, and the small hole member 6 is located at the center of the recess 1a. Each stopper piece 10 is bent along the bending line L and embedded in the convex portion 1b of the base 1, but the cross section substantially perpendicular to the bending line L has the convex portion 1b. The side surface is exposed and these cross sections form the stopper 10a.

The perturbator 2 has a ring-shaped top plate 7 and a cylindrical portion 8 directed downward from the center of the top plate 7 and a ring folded back from the outer edge of the top plate 7. Having a bottom plate 9 in shape, they are formed by pressing a sheet of metal flat plate. A perforation 8a is formed in the bottom of the cylindrical portion 8, and the perturbator 2 is inserted into the perforation 8a by caulking by inserting the small hole member 6 into the perforation 8a. While being rotatably supported on 1), the perturbator 2 and the intermediate terminal 4 are electrically connected. A contact portion 9a is formed in the lower plate 9, and the contact portion 9a is in elastic contact with the resistor 5. In addition, four adjustment grooves 8b having fracture surfaces on both sides are formed in the upper portion of the cylindrical portion 8, and projections 8c having fracture surfaces on both sides similarly from the upper portion of the cylindrical portion 8 to the lower portion. Is formed, and the groove formed inside the protruding portion 8c is continuous with one of the adjustment grooves 8b. That is, among the adjustment grooves 8b, the three adjustment grooves 8b are connected to the inner circumference of the upper plate 7 and the circumferential surface of the cylindrical portion 8, but the remaining adjustment grooves 8b are the upper plate 7 Is connected to the inner circumferential edge of the circumference and the upper end of the protrusion 8c. Each of the adjustment grooves 8b is arranged in a cross shape at equal intervals of 90 degrees, and the adjustment jig 11 for drivers or the like is engaged with these adjustment grooves 8b during the rotation operation of the perturbator 2. (See FIG. 6). The lower part of the protrusion 8c is located in the recess 1a of the base 1, and the fracture surface of the protrusion 8c is exposed into the recess 1a during the rotation operation of the perturbator 2. By contacting with the stopper 10a, the rotational angle of the perturbator 2 is regulated within a predetermined range.

The rotatable variable resistor configured as described above is surface-mounted on the printed board by soldering both terminals 3 and the intermediate terminal 4 to solder lands of a printed board (not shown). As a result, for example, when a predetermined voltage is applied between both terminals 3 and the intermediate voltage is drawn from the intermediate terminal 4 connected to the perturbator 2 via the small hole member 6, the perturbator ( The change of the resistance value according to the contact position of the contact portion 9a and the resistor 5 of 2) can be output. In the case of finely adjusting the resistance value, when the tip of the adjusting jig 11 is rotated while being engaged with the adjusting groove 8b, the perturbator 2 rotates around the small hole member 6 so that the contact portion ( 9a) receives the phase of the resistor 5, and the resistance value changes. At this time, the lower part of the cylindrical part 8 provided in the perturbator 2 rotates inside the recessed part 1a of the base 1, but of the protrusion part 8c protruding to the peripheral surface of this cylindrical part 8, When the fracture surface is in contact with any one of the pair of stoppers 10a, the perturbator 2 cannot be rotated more than that, so that the rotational angle of the perturbator 2 is regulated within a predetermined angle range.

Thus, in the said Example, the stopper piece 10 bent | folded in the intermediate terminal 4 is put out to the base stand 1, and the cross section orthogonal to the bending line L of this stopper piece 10 is exposed. Since the stopper 10a is used as the stopper 10a, the right angle of the stopper 10a is maintained regardless of the bending angle of the stopper piece 10, and the rotation angle of the perturbator 2 can be precisely defined and the stopper strength is increased. The stopper structure can be miniaturized. Moreover, it is comprised so that the protrusion part 8c may protrude in the cylindrical part 8 of the perturbator 2, and abuts the stopper 10a which exposed this protrusion part 8c in the recessed part 1a of the base stand 1. As a result, the foundation 1 and the perturbator 2 can be prevented from being enlarged in the radial direction, and the size can be reduced.

In the embodiment shown in FIG. 8, a stopper is formed in the pair of terminals 3 instead of the intermediate terminal 4. That is, the stopper piece 12 is bent and formed in each terminal 3 along the bending line L, and these stopper pieces 12 are embedded in the convex part 1b of the base 1, A cross section substantially perpendicular to L is exposed from the side surface of the convex portion 1b to form a stopper 12a. Therefore, in this embodiment, when the protrusion 8c of the perturbator 2 contacts any one of the pair of stoppers 12a, the rotational angle of the perturbator 2 is regulated, and thus the same effect as in the above embodiment is achieved. Have In addition, when the protrusion 8c of the perturbator 2 abuts on one of the stoppers 12a, the intermediate terminal 4 and one of the terminals 3 are short-circuited through the perturbator 2 so that the rotation ends. The residual resistance at the position can be zero.

In addition, in each of the above embodiments, the base 1 having the flat portion 1c which is substantially horseshoe-shaped in plan view has been described. However, the present invention is also applicable to the base of a uniform flat surface having no horseshoe-shaped end.

The present invention is implemented in the form described above, and has the effect as described below.

It functions as a stopper regardless of the bending angle of the stopper piece by bending the stopper piece on the metal plate and out forming the metal plate on the base plate made of synthetic resin, and exposing a stopper that is substantially perpendicular to the bend line of the stopper piece. Since the angle of the cross section is maintained, the stopper position inconsistency caused by the inconsistency of the bending angle of the stopper piece can be eliminated, and the stopper structure can be increased to reduce the stopper structure.

In addition, when the stopper piece is formed at the intermediate terminal connecting to the perturbator or at the terminal connected to both ends of the resistor, it is possible to prevent the component score from increasing, and in particular, when the stopper piece is formed at the terminal connected to both ends of the resistor. The residual resistance at the end of rotation can be zero.

Further, by forming a concave portion into which the perturbator is inserted in the base, and exposing the end face of the stopper piece to the concave portion, it is possible to reduce the external dimension of the rotary variable resistor together with the stopper structure. By forming a cylindrical portion that rotates in the concave portion and forming a protruding portion in contact with the stopper in the cylindrical portion, the external dimension of the rotary variable resistor can be greatly reduced.

Claims (6)

A base of synthetic resin made of a resistor formed on the surface thereof; It is provided with a perturbator rotatably installed on the base, In the rotational variable resistor in which the rotation angle of the perturbator is restricted by bringing the stopper provided on the base and the protrusion of the perturbator into contact with each other, The stopper piece is bent along the bending line on the metal plate, and the metal plate is out molded on the base plate, The base of the synthetic resin is provided with recesses for accommodating the perturbator, and convex portions formed at both ends of the recess in the rotational direction, A part of said stopper piece is embedded in the convex part of the said base stand, and the cross section which is substantially orthogonal to the said bend line is exposed in the side surface of the said convex part, The said cross-sectional part forms the said stopper, The said rotary resistance machine characterized by the above-mentioned. The method of claim 1, And the metal plate is an intermediate terminal connected to the perturbator. The method of claim 1, And the metal plate is a terminal connected to both ends of the resistor. The method of claim 1, Forming a recess into which the perturbator is inserted at the center of the base; The convex portion is formed so as to protrude inwardly of the concave portion, and the end face of the stopper piece is exposed in the concave portion. The method of claim 4, wherein And the end section of the stopper piece is extended in the height direction and exposed to the recessed portion. The method of claim 5, And a cylindrical portion for rotating the inside of the concave portion in the perturbator, and a protruding portion in contact with the stopper in the cylindrical portion.

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