KR900000636Y1 - Rotating adjustable resistor - Google Patents

Abstract

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Description

Rotating Variable Resistors

1 is an explanatory diagram showing a resistance pattern of an embodiment of the present invention.

2 is a diagram showing the resistance change characteristic of FIG.

3 is an explanatory diagram showing a resistance pattern of a conventional example.

* Explanation of symbols for main parts of the drawings

11: annular current collector 12: inner resistor circuit

12c, 13c: low resistance area 12D, 13D: high resistance area

12E, 13E: Connection portion 13: External resistor circuit

The present invention relates to a variable resistor for rotation, and more particularly, to a small and simple rotary variable resistor in which a low resistor circuit is arranged in two rows in and out of a horseshoe shape.

In general, as the compact and simple rotary type variable resistor, as shown in FIG. 3, a carbon hoof circuit is formed by horseshoe printing on an insulating substrate. More specifically, in FIG. 3, reference numeral 1 denotes an annular current collector formed by printing a paste on an insulating substrate, and 2 and 3 respectively form concentric circles around the outer side of the annular current collector 1. It is a carbon resistance circuit. 1A, 2A, and 3A denote terminal connection electrodes of the annular current collector 1, carbon resistance circuits 2 and 3, respectively, and 2B and 3B denote terminal electrodes. And a sliding member (not shown) extends from the main core of the annular current collector 1 in the direction of the carbon resistance circuits 2 and 3, and is assembled to be reciprocally rotatable, wherein the terminal connection electrode 1A The resistance value of a suitable magnitude | size is set between (2A) and between electrodes (1A) and (3A).

However, in the above conventional example, the length dimension of the outer resistor circuit 3 is longer than the length dimension of the inner resistor circuit 2, so that the resistance values of the inner and outer resistor circuits 2 and 3 are the same. Due to this relationship, the width dimension of the outer resistor circuit 3 must be set to be larger than the width dimension of the inner resistor circuit 2, and as a result, the overall insulating board becomes large, and thus, one of the serious obstacles to the problem of miniaturization of the variable resistor. do.

The present invention is to provide a gray type variable resistor which improves the drawbacks of the conventional example and equalizes the overall resistance values of the circuits of the inner and outer resistor circuits and at the same time reduces the size of the insulating substrate, that is, the size of the variable resistor. The purpose.

Here, the present invention is a two-row band-shaped resistor circuit disposed in the shape of a horseshoe and a rotating sliding contacting and sliding at the same time to change the resistance value, and is disposed on the rotation center side of the sliding contact and contacted with the sliding member. In a rotary variable resistor having a toroidal current collector, each resistor circuit is formed by connecting an electrically conductive material having a low resistance value and a resistor material having a high resistance value in the middle thereof, and the respective widths of the inner resistor circuit and the outer resistor circuit are respectively formed. The dimensions are approximately the same, and at the same time, the resistance values of the whole are identically formed, thereby achieving the above performance.

Hereinafter, an embodiment of the present invention will be described with reference to FIGS. 1 and 2.

1 shows the resistance pattern of the variable resistor in this embodiment. In the figure, 11 denotes an annular current collector formed of an on-closed yeast printed on an insulating plate, and 12 and 13 denote carbon resistive circuits which are concentric with this and printed in a horseshoe shape on the outside of the current collector. 11A, 12A and 13A indicate the annular current collector 11 and the terminal connection electrodes for the carbon resistor circuits 12 and 13, and 12B and 13B indicate the terminal electrodes.

Each of the resistor circuits 12 and 13 is formed with the same width dimension by a thick bay printing method.

Each of the inner resistor circuit 12 and the outer resistor circuit 13 is connected to the low resistance regions 12C and 13C in the direction of the arrow W at the sliding point S of the slider (not shown). It is divided into high resistance regions 12D and 13D. In this case, the specific resistance of each of the low resistance regions 12C and 13C is the same, and the specific resistance of each of the high resistance regions 12D and 13D is also the same.

In addition, 12E and 13E show the connection part of each resistance area | region provided in the said internal and external resistance circuits 12 and 13. As shown in FIG.

Among them, the connecting portion 12E of the inner resistor circuit 12 is a position closer to the sliding point S than the connecting portion 13E of the outer resistor circuit 13 as shown in the drawing, and at the same time the midpoint of the resistance change rotation range ( It is set in front of C). On the other hand, the connecting portion 13E of the outer resistance circuit 13 is set behind the midpoint C as shown in the figure. The overall resistance change characteristic of this embodiment configured as described above is obtained by rotating a slider (not shown) from the start point S to the terminal electrodes 12B and 13B of the sliding end point in the direction of the arrow W. FIG.

2 shows the resistance change characteristic in this case.

In the figure, A denotes a characteristic curve of the outer resistor circuit and B denotes a characteristic curve of the inner resistor circuit. As apparent from the diagram of FIG. 2, in the present embodiment, the characteristics of the resistor circuits 12, 13 are substantially the same at the sliding start point S, the intermediate point C, and the end point E. FIG. . Therefore, each of the resistance change characteristics A and B is approximated as a whole, and thus it can be used as a simple rotary type variable resistor equivalent to the conventional one.

Thus, in the present embodiment, the width dimensions of the internal and external resistor circuits 12 and 13, which are concentrically arranged with the current collector 11, can be made the same, and thus, the overall size can be reduced compared with the conventional one. In addition, by making the specific resistance of each resistance area of the internal and external resistance circuits 12 and 13 the same, the printing forming process can also be performed by printing two types of resistance ink, and at the same time, each resistance circuit 12, 13 The resistance change characteristics of the circuit can be approximated by the same width dimension of each resistor circuit, so that a small and simple variable resistor can be obtained for the simple volume or sound quality adjustment.

As described above, according to the present invention, two or more inner and outer band-shaped resistance circuits arranged in a horseshoe shape, a rotational sliding contacting and sliding of the resistance circuits, and arranged on the rotational center of the sliding contact In the rotary variable resistor having an annular current collector contacting the same person, each of the resistor circuits is electrically connected between a resistor material having a low resistance value and a resistor material having a high resistance value. By adopting a configuration in which the number of rules is about the same and the resistance values of the entire body are formed at the same time, the same characteristics as those of the related art can be maintained while maintaining the same characteristics as those of the conventional art, and at the same time, it can be further miniaturized. Being able to provide a practical rotary potentiometer .

Claims (3)

Two-row band-shaped resistor circuits (12) and (13) disposed in the shape of a horseshoe, and a rotating slide contacting the angular resistor circuit and sliding at the same time to change the resistance value, and are disposed on the side of the center of rotation of the slide. In a rotary variable resistor having an annular current collector 11 abutting on a copper plate, a resistance material having a low resistance value and a resistance material having a high resistance value are connected to each of the resistor circuits in the middle, and these internal resistor circuits ( 12) The variable resistance resistor of the external resistance circuit (13) is formed in substantially the same width, and the resistance value of the whole is formed the same, and the resistance of the whole resistance is formed, respectively, The rotary variable resistor characterized by the above-mentioned. 2. The connecting portion of the inner resistor circuit 12 is located ahead of the 50% position of the resistance change rotation range, and at the same time the connecting portion of the outer resistor circuit 13 is behind the 50% position of the resistance change rotation range. Rotary variable resistor, characterized in that. The position (12E), (13E) of the connection portion of each of the internal and external resistor circuits (12) and (13) so that the resistance change characteristics at the starting point, the intermediate point, and the termination point position of each resistor circuit are equal to each other. Rotary variable resistor, characterized in that set.