DE7046321U - Step adjustable, non-linear potentiometer - Google Patents

Description

Nippon Kocaku K.K. P 20 61 788.3-34

Tokyj / Japan May 4th 1972

Step-adjustable, non-linear potentiometer "" "" ".

The invention relates to a step-adjustable, non-linear potentiometer with a large number of adjacent potentiometers Pick-offs, one end in the path of a grinder and the other end one 'outside The partially shaped resistance hole arranged on the wiper track in each case contact them on their 2-arm-length.

Potentiometers of this general type can be found everywhere wherever a certain desired control curve is required with great accuracy and high reproducibility, e.g. an exponential function is to be simulated. An example this is the regulation of the photo current in cameras with automatic exposure for input of each used barking parameters (film speed, aperture value, etc.).

In many cases such a function potentiometer is used requires that it cover a very high range of resistance values, created by a wedge-shaped resistance layer is no longer feasible, because on the wedge tip side a certain minimum width of the counter

Btandßbahn not undercut for manufacturing reasons may be.

So far one has calibrated to further enlarge the swept Resistance range so that you simply have several such wedge-shaped resistance layers together with associated tapping strips arranged one behind the other along the wiper track, each of which is next Resistance section made of a material with higher », specific Sheet resistance than the previous one was established. However, this method has the disadvantage that a separate coating process is required for each resistive layer section, whereby the Manufacturing process obviously more expensive.

The object of the invention is therefore to design the potentiometer in question in such a way that there is no appreciable increase in temperature a much higher resistance range covered and the entire resistance with high reproducibility can be easily manufactured.

According to the invention, this task is for the potentiometer the type described in the introduction is achieved in that the wedge-shaped resistance layer on the wedge tip side a resistance track in zigzag curve shape is connected downstream, the reversal points of which facing the wiper track of

further tapping strips are contacted in an equidistant arrangement, that a further increase in the resistance value between each two adjacent tapping strips hinge of the further sliding track is achieved by a known corresponding increase in the amplitude of the zigzag curve shape of the resistance track and that with the same division of zigzag curve shape and Abgriffsstreifen is the width of the contacted by the ibgriffsstrelfen reversal points greater than d \ i of Abgriffsstreifen.

According to the invention, the resistance track of the potentiometer consists of two sections, namely one wedge-shaped section and a downstream zigzag-shaped section Section. The entire Widerstar.dsbahn can therefore in a single operation by conventional methods, for example by vacuum deposition, sputtering, electroplating or the like. aside from that the advantage is achieved that the potentiometer according to the invention is considerably more resilient than before, because the increase in resistance values between adjacent tap strips in the zigzag resistor section slightly more by reducing the resistive layer area is effected.

The suggestion for a potentiometer to be meandering Using a running resistance track is from the DT-AS

1,057,672 known per se.

The further feature of the invention, "with the same pitch of the zigzag curve shape and Abgri.C .: _; strip to make the width of the reversal points contacted by the tapping strips larger than the width of the tapping strips, one obtains the advantage that there are practically no noteworthy alignment difficulties for the masks used to produce the resistive layer on the one hand and the entirety of the tapping strips on the other; because of the greater width of the reversal points compared to the tapping strips, a certain mutual displacement of the two parts is harmless.

The alignment difficulties can in particular be significantly reduced if the width of the Incisions between every two adjacent inverted parts is chosen to be equal to the width of the tapping strips.

In the following the invention is explained in detail with reference to the drawing; show it!

Fig. 1 is a development view of a variable resistor according to an older proposal,

2 is a plan view of a device according to the invention changeable resistance,

Fie. 3 shows a detail view ν, ΐ cor arrangement according to FIG. 3 and

FIG. 4 shows a representation corresponding to the view according to FIG. 3 to explain the effects of alignment errors.

In Fig = 1, a stepped variable resistor is shown, as it is described in the older DT-OS 20 04 335.0; the resistance layer and the tapping strips are produced by vacuum deposition or cathode sputtering with the aid of a mask. The resistance value of this variable resistor changes according to a continuous function. The pick-off strips 3, 3 'and 3' run at right angles to the path K ^{1 of} a grinder. The resistor consists of three sections: The width of the wedge-shaped resistor layer 1 provided first changes according to the desired continuous function. The adjoining stepped ^{resistance band section P 1} has resistive layer strips 2 which are connected to a ^{tapping strip 3 'outside the track K 1} and Je. Finally, there follows a section Q 'with zigzag resistors; it has resistive layer strips 2 ', two of which from each tapping strip 3 ¹

go out. The resistive layer strips 2 and 2 'in the stepped resistor section P' and in the zigzag resistor section Q ¹ are connected to one another by connecting strips 4 and 4, respectively. With a variable resistance

704632122.3.73 f

of this type, the bases of the tapping strips 3 'in section P ¹ and the position of the connecting strips 4 must be changed according to the desired function. Accordingly, the two elements 3 ¹ and 4 and the resistance strips 2 must not only get an exact shape, but also selj? be arranged precisely. Since two resistance film strips are formed for each tap strip in the zigzag resistance portion Q ', sufficient accuracy can only be achieved if the resistance film strips and the tap strips are manufactured accurately. There is a risk that, as a result of alignment errors, the resistance layer strips will not have any contact with the tapping strips, so that interruptions in the resistance track can occur.

In the preferred embodiment of the invention (Fig. 2) a wiper J makes contact with the tabs 7 and 7 'ago. The latter are made of a material

r ensures perfect electrical contact with the highly wear-resistant grinder J. A wedge-shaped resistance layer 5 with a relatively high surface resistance changes its width S ¹ in a known manner in such a way that a resistance which changes the resistance value according to the desired function results. The tapping strips 7 and the wedge-shaped resistor layer 5 together form the wedge-shaped resistor section P. Furthermore, a

Wi ~ "-, and 6 deposited in a zigzag pattern in a vacuum at the same time with a wedge-shaped resistor layer 5 next to it, a branch of the zigzag resistor 6 being provided for each tapping strip 7 ^f . The tapping strips 7 ¹ and the zigzag '. Wlderstand-6 together form the zigzag resistor portion Q. the zigzag resistor 6 is located partially on the Abgriffsstreifen 7 ¹ "but outside the trajectory K of the grinder J. According to Fig. 3, the width W of the B Anzapfteils Abgriffsstreifen.7 * kept smaller than * ie the width W ¹ Jt of the reversal point A of the zigzag resistor 6, while the distance C between the reversal points A is chosen to be as large as the width W of the actual tapping part B of the tapping strips.

The electrically insulating disk 8, on which the above-mentioned resistance layers are deposited, is provided with a notch Oa which is provided approximately in the middle of the zigzag resistor section Q and into which a dowel pin 9 engages during the deposition process in order to avoid alignment errors when applying the zigzag resistance 6 to the tapping strips 7 ¹ can arise. The loop. J strokes the web K and its contact parts J1 ^ s J5 are arranged at an angle (FIG. 2), so that these contact parts can make contact with at least two tap strips at the same time. Numeral N denotes a connection terminal.

If a resistance is required, ti-ssen '-'ert lorarith.nisch increases, so the value of the wedge-shaped V.'iderstrnceschicht must

5 gradually increase from the terminal N in the circumferential direction. For this purpose v.'i: i made the width SI of the wedge-shaped resistance layer 5 smaller with increasing length of this layer. However, with regard to manufacture, there is a lower limit for the smallest width. Since the resistance is proportional to the length and inversely proportional to the width, the zigzag resistor Q has a constant width S (Fig. 3) and a zigzag pattern so that a level can be achieved within a limited space is than that achievable in the wedge-shaped resistance section with a given minimum width of the resistance layer. Fig. 3 shows the case that the width W ^{1 of} the zigzag resistor

6 is greater than the width W of the tapping part B of the tapping strips 7'i while the distance C between the sections A is kept equal to the width W of the tapping part B. the tap tire 7 'is made, that is, when an error iu a <.; Location of Anzapfteils B opposite to the portion A is present (such as at E in Fig. A), is still located the tap section B to the section A, wern and as long as this * error less 1st than half of a pitch distance D = V ^ -W ¹ is. But if the error exceeds the value D / 2, the tapping strip Contact receives the required

Neighboring opponents 3tandsnbLi: linitt _r because the distance C between the sections A is made equal to the width W of the tapping tool B. This means that even if the error is greater than half the value of the division distance D, this makes no difference to the previous case, in which the error was assumed to be less than half the division distance »The short circuit or the interruption that then occurs If the error is exactly half the pitch D (at F in FIG. 4), this results very rarely for statistical reasons. The amount of scrap based specifically on this error is therefore extremely small.

When producing the resistor according to the older proposal (Fig. 1), a pin 11 engages in the notch 1Üa of the base during the deposition of the individual layers. The resistance layer 2, the tapping strips 3, 3 'and 3 ¹¹ and the connecting strips 4 and 4' are deposited independently of one another, so that alignment errors of these layers are inevitable, which results in defective resistors with uneven changes in current flow when the wiper is adjusted. In particular, the resistance areas are ^{affected at the beginning of the areas P 1} and Q ¹ , because this is where an alignment error between the connecting strips 4 and the tapping strips 3 ^{1 in the direction of the resistance strips 2 is} the greatest. The error can easily exceed the tolerance limit. On the other hand, sideways

borrowed alignment errors between the resistance strips 2,; |

2 · and the tap 3 ^; , 3 ¹¹ or connection strelfen j

4, 4 'easily leads to short circuits j, especially in the area Q ^f

individual resistance strips or interruptions]

to lead. Therefore, in a further development of the invention, the ί

zigzag-shaped resistive layer in section Q in |

ί Fig. 2 shape shown, so that the connecting strips ^;

4 and 4 * can be omitted and only the tap I

j strips 7 and 7 'to be applied to the resistance layers | Bind Therefore, between the wedge-shaped resistance; layer and the zig-zag-shaped resistance do not see any
there are interruptions due to alignment errors. Since the pattern of the resistance layers is flawless
Bind, the manufacturing process is simplified, and it can be done
reproducibly produce a functional resistor with great stability, with wide resistance ranges at the same time
can be covered.

Claims (2)

efr claims 1. Step adjustable, non-linear3 potentiometer with a large number of tap strips lying next to each other, one end of which are in the path of a grinder and the other end is arranged outside the path of the grinder contact wedge-shaped resistance layer on its entire third, characterized in that the wedge-shaped resistance slide (S1) is followed by a resistance track (6) in a zigzag curve shape on the wedge tip side, the reversal points (A) facing the slide track (K) being ^{contacted by further tapping strips (7 1} ) in an equidistant arrangement, that a further increase in the resistance value between every two adjacent tap strips along the further wiper track is achieved by a known corresponding increase in the amplitude of the zigzag curve shape of the resistance track and that with the same division dimension (D) of zigzag curve shape and tap strips the width (W ¹ ) the reverse section (A) contacted by the tapping strips (7 ¹ ) is larger., Is the width (W) of the tapping strips. 2. Potentiometer according to claim 1, characterized in that that the width (C) of the incisions between each 2v: ei neighboring Urakohrstellen (A) is equal to the width (V) of the tapping strips (7 ^? ).