JPH03204904A - Variable resistor - Google Patents

Abstract

PURPOSE:To form a highly precise resistance pattern, and to obtain excellent characteristics by a method wherein a resistance base, on which a resistance pattern is formed on the surface of the mounting part of the resistance base, is orthogonally combined, a sliding piece is attached to a collector electrode terminal which is buried in the resin base, and a protruding piece, which is protruding to the surface of the resin base and used to control the range of rotation, is provided on the collector electrode terminal. CONSTITUTION:A mounting part 5 of the prescribed depth is formed on the upper surface of a resin base 2, a pair of electrode terminals 6 are buried in its one end part 2a, and its edge parts 6a are exposed to the surface of the resin base 2. A resistance base 1, on which a resistance pattern 4 is formed, is attached to the mounting part 5, and the edge part 4 of the resistance pattern 4 and the edge part 6a of the electrode terminal 6 are electrically connected using a conductive bonding agent 7 and the like. A collector electrode terminal 8 buried in the resin base 2 passing through a through hole 3, and a sliding piece 9, which slidingly moves on the resistance pattern 3 and has a positioning protrusion 10, is supported by the protruding end of the collector electrode terminal 8. On the other hand, a protruding piece 8a, which is branched from the midway of the terminal 8 protruding to the surface of the resin base 2 and engages to the positioning protrusion 10 of the sliding piece 9, is formed.

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial Application Field> The present invention mainly relates to a so-called semi-fixed type variable resistor, and specifically relates to a rotation regulating structure of a slider thereof.

<Prior Art> Conventionally, as shown in FIG. 3, this type of variable resistor has a ceramic resistance substrate 20 made of alumina or the like formed into a substantially rectangular flat plate shape, and a pair of ceramic resistance substrates attached to this. A device equipped with an electrode terminal 21 is known. On the surface of this ceramic resistance substrate 20, a substantially arc-shaped resistance pattern 22 made of, for example, cermet is formed, and at one end thereof, each of the edge portions of the resistance pattern 22 arranged in parallel is formed. A pair of connected extraction electrode patterns 23 are formed by baking a silver base or the like. Furthermore, terminal mounting holes (not shown) are formed at positions corresponding to the extraction electrode patterns 23 of the ceramic resistance board 20, and terminals are inserted through these terminal mounting holes to the surface side of the ceramic resistance board 20. The end edge portion 21a of the electrode terminal 21 that protrudes up to this point is bent along the surface of the ceramic resistance substrate 20 and then tightened. Then, the edge portions 21 of these electrode terminals 21
a and the extraction electrode pattern 23 are electrically connected to each other via solder 24.

Furthermore, a through hole 25 is formed at approximately the center of this ceramic resistance board 20, and a collector electrode terminal (not shown) is inserted through this through hole 25 and protrudes above the surface of the ceramic resistance board 20. has resistance pattern 22
A slider (not shown) that slides thereon is rotatably supported.

Note that this slider is provided with a positioning projection for regulating its rotation range.

On the other hand, as shown in FIG. 4, a variable resistor according to another conventional example has a pair of electrode terminals 30 and a collector electrode terminal 3.
Some resistor substrates are equipped with resin resistor substrates Fi32 in which 1 is embedded, and a substantially arcuate resistor pattern 33 is formed on the surface of this resin resistor substrate 32. The resistance pattern 33 is formed using carbon, for example, and its edge portions 33a are connected to the edge portions 30a of the electrode terminals 30 exposed on the surface of the resin resistance substrate 32, respectively. Further, the collector electrode terminal 31 has a collector electrode portion 31a exposed in a hole 32a formed at a substantially central position of the resin resistance board 32, and this collector electrode portion 31a has a slider (not shown). )
can be installed.

<Problems to be Solved by the Invention> By the way, each of the conventional variable resistors described above has the following disadvantages.

First, in the variable resistor shown in FIG.
1 by soldering, it is necessary to use expensive silver paste as a material for forming the extraction electrode pattern 23, resulting in high material costs and When inserting the terminal 21 into the terminal mounting hole of the ceramic resistance board 20 or caulking the edge portion 21a of the electrode terminal 21 along the surface of the ceramic resistance board 20, an excessive external force is applied to the ceramic resistance board 20. The process of baking the silver paste onto the ceramic resistor substrate 20 to form the lead electrode pattern 23 and the process of forming the electrode terminal 21 are Process of caulking to ceramic resistance board 20, electrode terminal 2
Since the process of soldering the edge part 21a of 1 to the lead-out electrode pattern 23 and the process of cleaning the flux after soldering are required, the manufacturing process becomes complicated and the manufacturing cost increases.

On the other hand, in the variable resistor shown in FIG.
2, it is necessary to use carbon, which has a low baking temperature, as the material for forming the resistance pattern 33 formed on its surface. For boat fishing, it is better to use cermet as a forming material than when carbon is used, and it is possible to form patterns with higher precision and to obtain better properties, but carbon seizing is affected by temperature. Approximately 150~
200°C, whereas the baking temperature of cermet is as high as about 750 to 850°C, so by using cermet, the resistance pattern 3 is formed on the surface of the resin resistance board 32
3 cannot be formed. In other words, if the resin resistance board 32 is exposed to high temperature, the resin will melt.
Resistance pattern 3 is used for baking using high temperature cermet.
3, and as a result, it is currently difficult to realize a variable resistor with high precision and high characteristics.The present invention was devised in view of such conventional disadvantages. Therefore, there is no need to use expensive silver paste to form the extraction electrode pattern, and the resistor pattern can be formed using a high-temperature forming material. Another object of the present invention is to provide a variable resistor having a structure that can reduce manufacturing costs and also reliably control the rotation range of a slider.

<Means for Solving the Problems> In order to achieve the above object, the present invention provides a resistor substrate having a substantially arc-shaped resistor pattern formed on its surface, and a mounting portion for attaching the resistor substrate formed on the top surface. A variable resistor includes a resin substrate and a slider that slides on a resistance pattern, the resin substrate having a pair of electrode terminals electrically connected to an edge of the resistance pattern. It is characterized in that a collector electrode terminal is embedded that penetrates the resistor substrate and rotatably supports the slider. In addition, the collector electrode terminal is provided with a protruding piece that branches from its midpoint and protrudes onto the surface of the resin substrate, and engages with a positioning protrusion formed on the slider to restrict its rotation range. ing.

<Operation> According to the above configuration, the resistance board on which the resistance pattern is formed and the resin board on which the mounting part for attaching the resistance pattern is formed are prepared separately from each other, and the resistance board is fixed to the mounting part of the resin board. After the components are combined and integrated, a slider is attached to the collector electrode terminal embedded in the resin substrate, thereby completing the variable resistor. At this time, since the collector electrode terminal is provided with a protruding piece for regulating the rotation range that protrudes above the surface of the resin substrate, the positioning protrusion of the slider engages with this protruding piece. Therefore, the rotation range of the slider is reliably regulated.

<Example> Embodiments of the present invention will be described below based on the drawings.

FIG. 1 is an exploded perspective view showing the overall configuration of a variable resistor according to the present invention, and FIG. 2 is an enlarged sectional view showing the main parts thereof.

This variable resistor includes a resistance substrate 1 made of a ceramic material such as alumina and formed into a substantially rectangular flat plate shape, and a resin substrate 2 made of a resin material such as PPS resin. A through hole 3 is formed at approximately the center of the resistor substrate 1, and a generally arcuate resistor pattern 4 made of carbon, cermet, etc. is formed on the surface of the through hole 3. The end edge portions 4a of the resistor substrate 1 are each extended to one end of the resistor substrate l and are arranged in parallel.

Further, a mounting portion 5 having a predetermined depth is provided on the upper surface of the resin substrate 2.
On the other hand, electrode terminals 6 made of a pair of metal plates are embedded in one end portion (left side in the figure) 2a by insert molding, and each of these edge portions 6a is connected to the surface of the resin substrate 2. exposed above. The resistance board 1 is attached to this attachment part 5 by a fixing method such as adhesive, and the edge 4 of the resistance pattern 4 is attached to the attachment part 5.
a and the end edge 6a of the electrode terminal 6 are bonded together with a conductive adhesive 7.
electrically connected via etc.

Furthermore, a collector electrode terminal 8 is embedded in the resin substrate 2 by insert molding, and is formed by bending a metal plate and extends through the through hole 3 and protrudes onto the surface of the resistor substrate 1. A slider 9 that slides on the resistor pattern 3 is rotatably supported at the protruding end of the collector electrode terminal 8. A slider 90 made by bending a metal plate or the like is formed with a positioning protrusion IO at a predetermined position, and the collector electrode terminal 8 is branched from its midpoint as shown in FIG. A protruding piece 8a is formed which protrudes onto the surface of the resin substrate 2 and engages with the positioning protrusion 10 of the slider 9. Therefore, the rotation range of the slider 9 is regulated by the engagement of the positioning protrusion 10 with the protruding piece 8a, and as a result, the maximum and minimum resistance values of the variable resistor are set. It turns out. Note that at this time, the protruding piece 8a that protrudes onto the surface of the resin substrate 2 may be surrounded by resin (not shown) extending from the resin substrate 2.

<Effects of the Invention> As explained above, the variable resistor according to the present invention includes a resistance substrate and a resin substrate that are configured separately from each other, and a resistance pattern is formed on the resistance substrate. , its edge portion is arranged parallel to one end portion of the resistor substrate. A mounting part for attaching the resistor board is formed on the resin board, and a pair of electrode terminals electrically connected to the resistor pattern and a collector electrode terminal that rotatably supports the slider are buried all at once. has been done.

Therefore, in this variable resistor, there is no need to use expensive silver paste, the baking temperature is high, and it is possible to form a highly accurate resistance pattern and obtain high characteristics. This greatly simplifies the process and significantly reduces material and manufacturing costs.

Moreover, the effect that the rotation range of the slider can be reliably restricted by the protruding piece that engages with the positioning protrusion of the slider can also be obtained.

[Brief explanation of drawings]

1 and 2 show an embodiment of the present invention; FIG. 1 is an exploded perspective view showing the overall configuration of a variable resistor, and FIG. 2 is an enlarged cross-sectional view showing the main parts thereof. Moreover, each of FIG. 3 and FIG. 4 is an external perspective view showing a schematic configuration of a variable resistor according to a conventional example. In the figure, 1 is a resistance board, 2 is a resin board, 4 is a resistance pattern, 4a is its edge, 5 is a mounting part, 6 is a t-pole terminal, 6a is its edge, 8 is a collector electrode terminal, 8a 9 is a slider, and 10 is a positioning protrusion. Note that the same reference numerals in the drawings indicate parts and portions that are the same or correspond to each other.

Claims (2)

[Claims] (1) A resistance board (1) with a substantially arc-shaped resistance pattern (4) formed on its surface, and a mounting part (5) to which it is attached.
is formed on the upper surface of the resin substrate (2), and the resistor pattern (
4) A variable resistor equipped with a slider (9) that slides on the resin substrate (2), the resin substrate (2) having an edge portion (4) of the resistance pattern (4).
Along with a pair of electrode terminals (6) electrically connected to a), a collector electrode terminal (8) is buried through the resistive substrate (1) and rotatably supports the slider (9). A variable resistor characterized by: (2) The collector electrode terminal (8) has a part that branches from its midway point, protrudes onto the surface of the resin substrate (2), and engages with the positioning protrusion (10) formed on the slider (9). 2. The variable resistor according to claim 1, further comprising a protruding piece (8a) for regulating the rotation range of the variable resistor.