DE3327413A1 - Adjustable resistor - Google Patents

Abstract

The invention describes an adjustable resistor in which a film resistance element is applied on an insulating carrier. This film resistance element consists of a resistance film surface which extends between an initial connecting electrode and a final connecting electrode. If required, a collector can also be applied on the carrier. The collector can also be formed by a metal shaft. A wiper, whose sliding contacts produce an electrical connection between the film resistance element and the collector, is moved by means of an operating device. In order now to obtain a desired voltage jump in the voltage curve, it is provided that an auxiliary electrode is provided in the initial region and in the final region of the film resistance element, which auxiliary electrode extends parallel to the resistance film surface but is electrically isolated from it and is electrically connected only to the initial and final electrodes. Furthermore, the wiper has yet another sliding contact which slides on the auxiliary electrode.

Description

Adjustable resistance

The invention is based on an adjustable resistor according to the preamble of claim 1 from.

There are adjustable resistors in a wide variety of designs for a wide variety of applications. With regard to the electrical properties the curve shape is probably the most important characteristic. The curve shapes differ one e.g. linear curves, linear curves with taps, rising or falling exponential Curves, rising rising or falling falling exponential curves, S-shaped curves etc. It is practically possible to make any desired curve shape if necessary.

One way to influence the shape of the curve is to use the Design the start and end connections accordingly. So is from DE-GM 1 910 592 already known a sheet resistance element with a non-linear curve shape, in which an annular resistance plate widens inwards in the starting area and is provided with a lead-out electrode.

Its boundary line is approximately tangential to the inner plate edge and it is bent towards the edge of the plate at the end. So you get an upscale exponential Curve.

From DE-GM 6 803 110 there is another sheet resistance element known, in which at the beginning or at the end of the actuation path no resistance or Voltage jumps should occur. This problem is solved by the fact that the initial and end connections made of material with good electrical conductivity in the direction of movement of the wiper have short approaches that are arranged on both sides of the grinding path and the extend to the edge of the circular sheet resistance element. Usually the resistance layer is first applied over the entire surface. Then that happens Applying the start and end connections with the approaches. This means that under the start and end connections with the approaches the resistance layer lies. The approaches are thus over their entire surface including their edges with the resistance layer in electrical connection.

An arrangement of lead electrodes on both sides of the wiper track is described in DE-GM 1 950 262. At the end the lead electrodes are through stepped edge incisions limited. Such fixed lead electrodes are intended for both linear and circular resistance elements. These are real lead electrodes, which over their entire length with the Resistive layer are in electrical connection.

In most cases there is a steady, continuous curve progression he wishes. But there are also applications in which, on the other hand, a curve jump is downright desirable.

The object of the present invention is to provide a with simple means to create adjustable resistance according to the type mentioned at the beginning, which is and / or end of its adjustment distance after passing through a section from Start and / or end area from or between the start and end area one has precisely defined curve jump.

This object is achieved according to the invention by the in the labeling part of claim 1 specified features solved.

Advantageous refinements result from the subclaims.

The invention is based on several exemplary embodiments the drawings described in more detail.

Of the figures, FIG. 1 shows a plan view of a straight line Sheet resistance element, Figure 2 is a graphical representation of the tapped Wiper voltage, Figure 3 is a plan view of another straight sheet resistor element figure 4 shows a plan view of a circular sheet resistance element, FIG. 5 a Top view of a further sheet resistor element, FIG. 6 shows a top view a section of another sheet resistance element.

In the figures, a sheet resistance element is shown that is intended for use in adjustable resistors. From the adjustable resistance For the sake of simplicity, no, in particular no mechanical details are shown, since they are of no importance for the invention.

The mechanical start stop is only symbolic of the grinder A and the mechanical end stop E indicated as continuous lines. The between the stops A and E as a dash-dotted line indicated paths are the grinder paths S1, S2 and S3, whereby the slider path S1 for the collector is not always (see figure 4) must be present.

The sheet resistance element consists of a carrier 1 from a insulating material. This can be e.g. hard paper, ceramic or some other suitable one Be material. On this carrier is now in one of the conventional techniques, as e.g. in screen printing technology, first apply a flat resistance mass in a desired Layout applied. The resistance surface is denoted by 3 in FIG. To Once the resistance surface has dried on, another application takes place, e.g. likewise in screen printing technology, the collector 2 and the two electrodes 3, 4. Together with these become the secondary electrodes on one or both sides in the same manufacturing step 6.7 applied. Because the collector, electrodes and secondary electrodes have good electrical conductivity should be, a conductive silver is preferred as a screen-printable mass.

An embodiment of the sheet resistance element is also conceivable, where the collector, electrodes and secondary electrodes consist of copper conductors, which are initially produced in one of the known processes. On this will then the resistor surface is printed on.

In a final process step, after drying of the conductive silver hardened the resistance mass. With that one can, starting from a certain resistance value of the resistance mass and with a defined burn-in time and baking temperature, a certain input reach resistance. If you only choose a homogeneous resistor mass, you get the same width a linear curve.

As can be seen from Figure 1, the secondary electrode extends 6 parallel to the resistance layer section at the start electrode.

Of course, another secondary electrode 7 can be used in the same way be present on the end electrode. The secondary electrode is only at the beginning with the corresponding electrode electrically connected. In the further course is the secondary electrode electrically separated from the resistor surface by a separating slot 8 or 9, respectively. It is of particular importance that the wiper has another sliding contact that slides along the secondary electrode. The additional loop path is marked with S3. S2 symbolically represents the usual Schleiferweg. The Schleiferweg S1 does not have to be present on the collector. The tapped tension could can also be passed on by e.g. a metal shaft or in some other way.

The diagram in Figure 2 shows the wiper voltage as a function from the adjustment path. It is of course assumed that the grinder has the Sliding contacts are in electrical connection with each other, which is the case with slide springs made of metal is common.

In the initial area, the sliding contacts move over a short distance from S1, S2 and S3 on the start electrode and the collector, respectively. Then comes the Sliding contact from S2 to the resistance surface. Since the sliding contact of S3 is still on the secondary electrode, the resistance is the initial section short-circuited via the slider, i.e. it is not effective. According to a desired Adjustment distance, which depends on the length of the secondary electrode, slides the sliding contact from S3 from the secondary electrode via the separating slit 8 to the resistor surface.

As soon as the sliding contact of S3 no electrical connection to the Secondary electrode has more, the resistance of the initial section is fully effective, so that the wiper voltage makes a desired jump. The height of the jump depends on the geometric relationships and on the resistance value of the used Mass from. If the sliding contacts of S2 and S3 are both on the resistor surface slide, the tapped wiper voltage increases linearly. It is constant Assuming width. If necessary, a jump can be provided at the end in the same way will. If the width changes, non-linear curve shapes can also be achieved will.

Further embodiments are shown in FIGS. 3, 4 and 5.

In the embodiment according to FIG. 1, the resistance area is which lies in the area of the secondary electrode is tapered. The same width as the starting stretch has the resistance surface 13 of the embodiment according to FIG. The sliding contact of S3 runs after leaving the secondary electrodes 16 or 17 on the carrier 11. It is only a question of dimensioning which of the two embodiments one gives preference.

With regard to the function of the jump according to FIG both embodiments are similar.

The corresponding reference symbols have also been chosen. The carrier is marked with 11, the collector with 12 and the resistance surface with 13. The start and end electrodes are located at the beginning and at the end of the resistance surface 14 and 15 with their secondary electrodes 16 and 17, respectively. The separating slits are corresponding denoted by 18 and 19.

While the two embodiments of a sheet resistance element are suitable for slide resistors according to Figures 1 and 3, one can use the embodiment use according to Figure 4 for a rotary resistance. The carrier made of insulating material is denoted by 21. The resistance area is marked with 23. At others At the beginning is the start electrode 24 and at the end of it is the end electrode 25. The secondary electrodes in electrical connection with the electrodes are denoted by 27 and 28. The secondary electrodes are separated from the resistor surface 23 through the separating slots 28 and 29. In contrast to the other two embodiments this sheet resistance element does not have a collector. The tapped tension is passed on e.g. via the metal shaft.

FIG. 5 shows a further exemplary embodiment for a slide resistor suitable sheet resistance element. The embodiments described so far have the disadvantage that the total resistance measured between points A and E. depends on the sliding contact position. Is there e.g. the sliding contact of S3 on the secondary electrode, then carries the resistance of the parallel initial section to the total resistance nothing, since the sliding contacts with each other in electrical Connected.

Only when the sliding contact of S3 on the resistance surface or the iso- If the carrier runs, the total resistance is again equal to the total value. You can avoid this effect by taking the partial route the resistance surface, which is parallel to the secondary electrodes, with an insulating layer 40 and 41 covered. The total resistance between terminals A and E is then always constant regardless of the grinder position. Is the sliding contact of S3 is on the secondary electrode, so the sliding contact of S2 is on the insulating layer.

The resistance of the section is therefore for the total resistance, as it is not short-circuited via the sliding contact of S3, fully effective.

The sheet resistance element consists of the carrier 31 on which the collector 32, the resistive surface 33 and the start and end electrodes 34 and 35 are located. The secondary electrodes are designated by 36 and 37. S1, S2 and S3 again symbolically represent the slider paths. Compared to the other exemplary embodiments additionally applied insulating layers are denoted by 40 and 41.

Another embodiment of the sheet resistance element is shown in FIG shown in FIG. The secondary electrode can not only in the initial and / or End area can be provided, but there is also the possibility in between to provide a so-called tap. It is a web 42, which is in electrical connection with the resistance surface 44. As if from a figure 6 shows, the web can extend over the entire width. But he can also be shorter. The secondary electrode extends from this web. The parallel The lying resistance surface can also be covered with an insulating layer be. With this embodiment, jumps in the wiper voltage e.g. can be reached in the middle of the adjustment path.

Reference number 1 carrier 2 collector 3 resistance surface 4 starting electrode 5 End electrode 6 Secondary electrode to the start electrode 7 Secondary electrode to the end electrode 8 separation slot in the beginning area 9 separation slot in the end area 11 carrier 12 collector 13 Resistance surface 14 Start electrode 15 End electrode 16 Secondary electrode to the start electrode 17 Secondary electrode to the end electrode 18 Separating slot in the starting area 19 Separating slot in the end area 21 carrier 23 resistance surface 24 start electrode 25 end electrode 26 Secondary electrode to the start electrode 27 Secondary electrode to the end electrode 28 Separating slot in the beginning area 29 separating slot in the end area 31 carrier 32 collector 33 resistance surface 34 Start electrode 35 End electrode 36 Secondary electrode to start electrode 37 Secondary electrode to the end electrode 38 separating slot in the start area 39 separating slot in the end area 40 insulating layer in the end area 41 insulating layer in the starting area S1 wiper track 1 S2 wiper track 2 S3 wiper track 3 42 web 43 secondary electrode 44 resistance surface - Blank page -

Claims (10)

Adjustable resistance Adjustable resistance - with an on an insulating support applied sheet resistance element, consisting of a resistive layer surface extending between a start and end connection electrode, - with a collector and - with a grinder movable by an actuator, its sliding contact sliding along the sheet resistance element is an electrical one Establishes connection between sheet resistance element and collector, characterized in that <angs- and / or end area of the sheet resistance element one with the start and / or end connection electrode (4, 5, 14, 15, 24, 25, 34, 35) in electrical connection standing, flat secondary electrode (6, 7, 16, 17, 26, 27, 36, 37) is present, which extends approximately parallel to the resistive layer surface (3, 13, 23, 33), but which is electrically separated from it, and - that another sliding contact (S3) of the wiper is present, which is on the secondary electrode (6, 7, 16, 17, 26, 27, 36, 37) slides. 2. Adjustable resistor according to claim 1, characterized in that that the secondary electrode (6, 7, 16, 17, 26, 27, 36, 37) extends only over a partial distance of the total path of the grinder. 3. Adjustable resistor according to claim 1, characterized in that that the resistance layer surface (3, 13, 23, 33) in the area of the secondary electrode (6, 7, 16, 17, 26, 27, 36, 37) is tapered. 4. Adjustable resistor according to claim 1, characterized in that that the adjustable resistor is a rotating or sliding resistor. 5. Adjustable resistor according to claim 1, characterized in that that the secondary electrode (6, 7, 16, 17, 26, 27, 36, 37) from the same electrical highly conductive material such as the start and end connection electrodes (4, 5, 14, 15, 24, 25, 34, 35) and that it is applied in the same process. 6. Adjustable resistor according to claim 1, characterized in that that the further sliding contact (S3) after leaving the secondary electrode (6, 7, 16, 17, 26, 27, 36, 37) slides on the resistive layer surface (3, 13, 23, 33). 7. Adjustable resistor according to claim 1, characterized in that that the further sliding contact (S3) after leaving the secondary electrode (6, 7, 76, 17, 26, 27, 36, 37) on an uncoated part of the insulating carrier (1) slides. 8. Adjustable resistor according to claim 1, characterized in that that the collector (2, 12, 22, 32) is approximately parallel to the sheet resistance element extends. 9. Adjustable resistor according to one of claims 1 to 8, characterized characterized in that the partial resistance layer section lying parallel to the secondary electrode (36, 37) is covered by an insulating layer (40, 41). 10. Adjustable resistor according to one of claims 1 to 9, characterized characterized in that the secondary electrode extends from one between the start and end regions of the sheet resistance element lying tap extends from.