KR940003669Y1 - Control device - Google Patents

Abstract

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Description

Interlocking Variable Resistors

1 is a cross-sectional view of a housing which is a main component of an interlock type variable resistor according to the present invention.

Figure 2a, b is a left side view and a right side view of the housing according to the present invention.

3 is a side view of the rotor according to the present invention.

4 is a cross-sectional view of the interlocking variable resistor according to the present invention.

5a, b are a cross-sectional view and a side view for showing the structure of a conventional housing.

6 is a side view of a conventional rotor.

* Explanation of symbols for main parts of the drawings

1: resistor plate 2: resistor

10a: housing 11: bulkhead

12: space part 15a, 16a: lead terminal

15: inner electrode plate 16: outer electrode plate

17, 17a: cutting portion 18: electrode plate

20A: Rotor 21: Rotor Body

23,24: Elastic contact terminal

The present invention relates to an interlocking variable resistor in which the resistance value of two sets of variable resistors is interlocked by one rotating shaft, which is used in various acoustic devices, and in particular, the structure of the housing and the rotor which are the main components of the interlocking variable resistor. It is designed to greatly improve the productivity of interlocking variable resistors and to reduce the unit cost.

A typical interlock type variable resistor has a rotor of one phase having contact terminals 22a and 22b on both sides of a housing 10 having a power supply lead terminal 13 at the lower side and a contact terminal 14 at the inner center thereof. 20) are installed (see FIGS. 5 and 6), and resistor plates formed with resistors on one side thereof are provided on both sides thereof, and both rotors are interlocked by one rotation shaft. Therefore, when the rotating shaft is rotated, the relative position between each resistance surface and the contact terminal of the rotor is changed, and the output voltage of the front and rear speakers of each channel is changed according to this resistance value so that the output balance of the front and rear speakers can be adjusted. It is.

Looking at the housing 10 and the rotor 20 which are the main components installed and used in such a general interlocking variable resistor according to the attached drawings 5a, b and 6 as follows.

5A and 5B are cross-sectional views and side views for illustrating a structure of a conventional housing 10. A partition 11 is integrally formed at an inner center of the housing 10. Cylindrical spaces 12 are formed on both sides, and below the housing 10, the spaces 11 are opposite to each other, i.e., both spaces, in a state of being integrally connected to one end of the pair of lead terminals 13. It is bent in the (12) direction.

And the rotor 20 installed on both sides of the housing 10 is composed of a rotor body 21 and the contact terminal 22, as shown in Figure 6, the contact terminal 22 is the housing ( On the opposite side of the contact terminal 22a in which one side is formed in the shape of a disk to be in contact with the bent contact terminal 14 of FIG. 10, the contact terminal 22b is provided with a resistor 2 of the resistor plate 1 as shown in FIG. And outward bending to elastically contact

The disc-shaped contact terminal 22a and the outwardly bent contact terminal 22b are integrated with each other and fixed to the rotor body 21.

However, this is very difficult to manufacture the housing 10, which is the main component of the interlocking variable resistor, there is a problem in workability. The reason will be briefly explained according to the manufacturing state.

First, the metal plate is pressed to form a portion to be a contact terminal 14 in a circular shape, and at the same time, a press work is performed such that a pair of lead terminals 13 are formed on both sides below.

Thereafter, the metal plate obtained in the above operation is molded with a synthetic resin material to form the housing 10, and the two sides are in opposite directions while cutting the predetermined position of the circular metal plate (see section "A" in FIG. 5B of the cutaway drawing). It is bent to form a contact terminal 14 to complete the manufacture of the housing (10).

However, this is because the housing having a very small dimension is manufactured in the same manner as described above, the contact terminal 14 needs to be cut and folded in two places using a relatively expensive elastic material. As a reason for the increase in the unit cost, and the rotor 20 rotated between the housing 10 and the resistor plate 1, the contact terminal 22b is elastically bent outwardly only on the resistor plate 1 side, so that the rotor 20 The elasticity of the contact terminal 22b is non-uniformly applied during the rotation of C. Thus, the resistor 2 of the resistor plate 1 and the contact terminal 22b are inhomogeneously contacted, resulting in an unstable output resistance.

Therefore, the present invention is to completely solve the above-mentioned problems, and by changing the structure of the rotor rotating contact with the housing while significantly changing the structure of the product, as well as improving the productivity of the product as well as cheap quality products It is to be able to provide as.

This will be described in detail according to the accompanying drawings. 2A and 2B show the structure of the housing 10A according to the present invention, and the electrode plate 18 is formed of the inner electrode plate 15 and the outer electrode plate 16 in a concentric manner, respectively. Under the plate 15 and 16, presses are formed to form respective lead terminals 15a and 16a, but a cutout portion is provided below the outer electrode plate 16 so as to separate the lead terminals 15a and 16a. 17 to form an electrode plate 18, and both lead terminals 15a and 16a protrude downward on the electrode plate 18 and cylindrical spaces 12 on both sides by the central partition wall 11. Molding the housing (10a) is formed, one side surface of the partition 11 is exposed to the circular shape of the outer electrode plate 16 is cut down as shown in Figure 2a, the inner electrode plate ( 15 is separated and partially molded at a predetermined angle.

In addition, the inner and outer electrode plates 15 and 16 are exposed on the surface of the other partition 11 so as to be opposite to the left side partition, that is, the second aa, which is the outer electrode plate 16 as shown in FIG. The inner electrode plate 15 is molded to be exposed in the form of a circular plate while being partially exposed at an angle.

Afterwards, one side of the outer electrode plate 16 and the upper side of the lead terminal 15a of the inner electrode plate 15 are separated so that the electrode plate 18 is completely separated into the inner electrode plate 15 and the outer electrode plate 16. Is cut (see cutout part 17a in Figs. 2a and b).

3 and 4 illustrate a rotor 20a installed on both sides of the housing 10a, and an interlocking variable resistor in which the housing 10a and the rotor 20a are coupled according to the present invention. Rotates so as to contact the resistor 2 of the resistor plate 1 and the inner and outer electrode plates 15 and 16 on both sides of the partition wall 11 which are provided in both side space portions 12 of the 10a and are provided on both sides outside. On both sides of the electromagnetic body 21, each of the elastic contact terminals 23 and 24 bent outwardly to both sides is integrally bent and molded.

Referring to the operating state of the present invention configured as described above are as follows. As shown in FIG. 4, the resistor plate 1 having the rotors 20a respectively inserted in the space portions 12 on both sides of the housing 10a according to the present invention and having resistors 2 on both sides thereof. After the installation, the known heat sink 3 is assembled to both sides of the resistor plate 1.

Subsequently, the shaft supporting portion 4, on which the rotating shaft 5 is fitted, is assembled on one side of the resistor plate 1 to complete the assembly of the interlocking variable resistor.

The lead terminals 15a and 16a protruding downwardly into the housing 10a of the assembled interlocking potentiometer and the resistor plate 1 are soldered and fixed to a printed board (not shown). .

After soldering each lead terminal to the printed board as described above, when the rotary shaft 5 is rotated, both rotors 20a rotate between the resistor plate 1 and the housing 10a in association with the rotary shaft 5. Done.

At this time, the contact terminal 23 in contact with the resistor 2 of the resistor plate 1 of the two elastic contact terminals 23 and 24 provided on the rotor 20a rotates while being in contact with the resistor 2 and the other side contact. Since the terminal 24 rotates while contacting the inner and outer electrode plates 15 and 16 of the housing 10a, respectively, the lead terminals 15a and 16a of the housing 10a and the leads of the resistor plate 1 are rotated. The resistance value between the terminals is changed.

The rotation angle of the rotary shaft 5 is controlled so that the stopper plate 6 provided between the shaft support part 4 and the heat sink 3 hits one of the heat sinks 3 on one side of the heat sink 3 and is restricted to a predetermined range. Heat generated from the resistor is to be radiated to the outside through both heat sinks 3.

In addition, the rotor 20a installed at both sides of the housing 10a has contact terminals 23 and 24 elastically installed outwardly on both sides of the rotor body 21 so that the resistor 2 of the resistor plate 1 is provided. And elastically contact and rotate the inner and outer electrode plates 15 and 16 of the housing 10a, respectively, so as to eliminate rotational imbalance between the contact terminals 23 and 24 so as to discharge a constant rotation and resistance value. will be.

On the other hand, looking at the manufacturing state of the housing 10a of the present invention constructed and acted as described above, as shown in 2a, b, two inner and outer electrode plates 15 on the concentric circles using the metal plate of the conductor ) 16 is formed and the lower end of each of the lead terminals 15a and 16a is integrally formed to form an electrode plate 18 of a predetermined type.

At this time, the inner and outer electrode plates 15 and 16 are cut at predetermined positions below the outer electrode plate 16 so that the inner and outer electrode plates 15 and 16 can be electrically separated last, and the inner and outer electrode plates 15 and 16 are completely separated. Press work is performed so that one side of the inner and outer electrode plates 15 and 16 is stuck.

In this way, the conventional housing is molded on the completed electrode plate 18, and the inner and outer electrode plates 15 and 16 are partially or partially disposed on both side walls of the central partition wall 11 as shown in FIGS. 1 and 2a and b. Molded as a synthetic resin material to be exposed to.

After the second molding process is completed, the inner and outer electrode plates 15 and 16 are completely separated to form a separate circuit so that the inner and outer electrode plates 15 and 16 are molded. A hole in the hole (see cutout 17a) is drilled out so that the outer electrode plates 15 and 16 are completely separated.

In addition, the rotor 10a to be in contact with the housing 10a and the inner and outer electrode plates 15 and 16 having a flat shape will be described with the inner and outer electrode plates 15 and 16 having a flat shape. On both sides of the rotor body 21 so as to be in contact with the resistor 2 of the resistor plate 1, the contact plates 23 and 24, which are elastically fixed by bending metal plates outward, are fixed to the rotor 20a. To form. Therefore, the present invention can reduce the unit cost without the need for fine cutting and expensive elastic materials in the housing, and the interlocking variable resistor can provide good quality with less assembly and contact, less defects.

As described above, the present invention has a very useful effect of improving the productivity by reducing the working time and the defective rate during the production of the housing, in particular, by simply improving the working process of manufacturing the compact housing.

Claims (2)

The rotor is provided with a pair of resistor plates formed with a resistor on one side, and a rotor to which the contact terminals are fixed and rotate integrally with each other, and a case for supporting both resistor plates at the same time as including the rotor. In the interlocking variable resistor in which each of the rotor contact terminals rotates the resistor in contact with each other, the housing 10a molds a synthetic resin material on the plate-shaped electrode plate 18 to form the center partition 11. The inner and outer electrode plates 15 and 16 are formed on both sides, but are separated from each other by the cutting parts 17 and 17a to form separate circuits, and the rotors 20a respectively coupled to both sides of the housing have one side. The inner and outer electrode plates 15 and 16 are in contact with each other, and the other side of the resistor plate 1 is formed by bending the elastic contact terminals 23 and 24 into contact with each other. Interlocking variable resistor. The electrode plate 18 of the housing 10a is press-processed so that the inner and outer electrode plates 15 and 16 are formed on concentric circles, and the inner and outer electrode plates 15 are respectively formed. (16) The linked variable resistor, characterized in that each lead terminal (15a) (16a) is formed integrally below.