DE3136045C2 - Coding rotary switch - Google Patents

Abstract

An 8-4-2-1 rotary encoder switch with several conductor tracks lying on concentric scanning circles, which are scanned by a rotatable collector, which has scanning contacts arranged on both sides of the axis of rotation, is for the purpose of a radial reduction in size without loss of switching and contact reliability designed that with 2 ↑ n collector rotation positions of different counting values distributed over the switch circumference, the conductor tracks lie on n-1 concentric scanning circles and are acted upon by n + 1 scanning contacts. As a result, the conductor tracks of a hexadecimal switch (n = 4) are placed on three concentric circles and are scanned with five contacts. As a result, compared to the five conductor tracks previously required in the prior art, a considerable radial reduction in size of the printed circuit board is possible, with the radial distances between the conductor tracks not having to be minimized.

Description

genes per collector revolution are relatively high.

From DE-OS 26 42 887 an electrical switch with a rotor assembly is also known in which five sensing contacts of a collector lie on a straight line, but not through the collector axis of rotation The five scanning contacts act on conductor tracks, which are arranged on a total of four scanning circles are; the switch is built relatively expansive in terms of its radial dimensions two contacts arranged at the same distance from the fulcrum of the rotor

Finally, a rotary switch is known from US-PS 33 98 245, in which the collector scanning contacts are arranged in a circle around the collector axis of rotation and act on contact surfaces, all of which lie on a scanning circle.

The invention is based on the object of a rotary encoder scanner to be designed in such a way that it is in its - radial dimensions with respect to the collector axis of rotation can be reduced without any loss of switching and contact reliability and the number of switch-on and switch-off operations per collector revolution is reduced * This task is made possible by the characteristic of the claim 1 solved

As the core of the invention, it is considered that - as far as the conductor tracks with the lower valences (except for the conductor track of the highest valence) are concerned - in each case two symmetrically opposite to the pivot point, i. h, contacts offset by 180 ° act on the same conductor track. This principle can be referred to as the repetition principle and means that every point on the circuit board is used twice in succession for one full revolution of the collector. This makes it possible to get by with a reduced number of circular conductor tracks. This can be built not only switch smaller dimensions - which is already significant in itself advantages - even the functionality of the switch of the invention is improved because He conductor tracks smaller number can be made wider, can keep a greater radial spacing and the number of inputs Switch-off processes with a full collector revolution is reduced

According to claim 2, the conductor track with the highest valency (in the exemplary embodiment valency 8) are only acted upon by a sensing contact during a half-turn. This conductor path should be on be arranged the outermost scanning circle, on the opposite side of the Zu-Ableitungsn of the sensing contact. This is advantageous insofar as the conductor track the other (inner) more or less semicircular and thus includes the supply lines due to the special arrangement according to claims 3 and 4 can be manufactured more easily. The further subclaims contain advantageous ones Features, in particular what the geometric arrangement of the conductor tracks of the switch according to the invention regards

The invention is explained in more detail using an exemplary embodiment shown in the drawing. It shows

F i g. 1 shows a schematic representation of the conductor track arrangement a hexadecimal switch and

F i g. 2 shows a schematic representation of the conductor track arrangement according to FIG. 1 associated collector.

(The reader is foaled to study the Fig.! and FIG. 2 is a transparency copy of FIG. 2 to make and rotatable about the axis of rotation to F i g. 1 to be attached.)

The rotary coding switch has an 8421 coding and essentially consists of a printed circuit board 1 and a collector 2, with several conductor tracks 3-7 being arranged on the printed circuit board 1, which have different values (counts 8.4, 2.1 or C) . The conductor tracks 3-7 lie on three scanning circles 9, 10, 11 which are concentric to the axis of rotation 8 and are with

ίο leads 12,13,14,15 or a supply line 16 connected. The lead labeled "12" is assigned to conductor track 7, that labeled "13" to conductor track 6, that labeled "14" to conductor track 5 and the one labeled "15" to conductor track 4. Lead 16 belongs to conductor track 3 with the valence C = co.nmon.

The collector 2 is provided with five sensing contacts 17-21, which the conductor tracks 3-7 under contact spring pressure apply. The scanning contacts 18 and 19 are the scanning circuit 9, the scanning contacts 17 and 20 to the scanning circuit 10 and the scanning contact 21 to the Scanning circle 11 assigned to all scanning cycles 17-21 lie on a straight line 22 running through the axis of rotation 8 /, the scanning contacts 17, 18 being the scanning contacts 19, 20 are opposite symmetrical to the axis of rotation E.

When the collector 2 is rotated relative to the Printed circuit board 1, the contact patterns described below are possible, successively referring to those with the Rotational position specifications 0-15 designated rotary positions is received. When speaking of a certain rotational position, this means that the in Fig. 2 arrow 23 on the rotation position indication with the corresponding rotation position number (0—15) shows

Rotation position 0:

The contacts 17, 20 and 21 apply exclusively to the conductor 3 with the valence C. Since the conductor 3 covers a segment of a circle of slightly more than 180 °, it is ensured that before leaving the / the sensing contact assigned to this conductor, the one collector side of the the other collector side symmetrically opposite sensing contact (z. B. 17) already made contact with the conductor track 3. This means that the conductor path is already "taken over" by the opposite sensing contact before the opposite sensing contacts leave the conductor path. This ensures that the conductor track 3 is contacted with the valence C in every rotational position

Rotation position 1:

Casting contact 17 remains on conductor track 3, which act on opposite scanning contacts 19, 20, 21 the conductor track 4. It is important that in the rotational position range 1 the conductor track 4 extends in the radial direction over all three scanning circles 9, 10, if and radially outward into the Derivation 15 passes over.

Rotation position 2:

Scanning contact 17 remains on conductor track 3, scanning contact 20 acts on conductor track 5.

Rotation position 3:

Scanning contact 17 remains on conductor track 3, scanning contact 18 is applied on the same side

of the axis of rotation 8, the conductor track 4 in the conductor track segment 4 ^MI , on the opposite side the sensing contact 20 remains on the conductor track 5.

Rotation position 4:

Scanning contact 17 remains on conductor track 3, the one diametrically and symmetrically opposite it The sensing contact 20 applies the value 4 to the conductor track 6.

Rotation position 5:

Like rotary position 4, the conductor track 4 is also acted upon with valence 1 by the sensing contact 18 (as already in rotary position 3).

Rotation position 6: As for the rotary position 4. in addition, scanning I ._l. » ΛΛ _i :. I ^ "-.- UU - C U -... -J -.-." .. C ~~ · --- * - · Cl IVUIItdlM 17 UIC UCIlCI U4XIIII JU £ .tr. UCI (.11 ^ 1 (.5IHVIIt. *

applied.

Rotation position 7:

Like the rotary position 6, the conductor track 4 is in turn contacted by the sensing contact 18 (Segment 4 ').

Rotary position 8:

In this rotary position, sensing contact 20 takes over the conductor path together with sensing contact 17 3. The radially outer scanning contact 21 hits the conductor track 7 with the valency 8.

Rotary pitch 9:

The scanning contact 17 has left the conductor track 3, so that this is now exclusively from the scanning contact 20 was "taken over". The scanning contacts 17 and 18 act on the conductor track 4. Sensing contact 21 remains on conductor track 7.

Rotation position 10:

Scanning contact 20 remains on conductor track 3, scanning contact 21 on conductor track 7; Sensing contact 17 applies value 2 to conductor track 5.

Rotary position 11:

As in the rotary position 10, but the sensing contact 19 also makes contact with the conductor track 4 (segment 4 ″ ¹ ).

Rotary position 12:

Scanning contact 20 remains on conductor track 3, scanning contact 2Z on conductor track 7; Sensing contact 17 contacts conductor track 6 with valence 4.

Rotation position 13:

As in the rotary position 12, but in addition the sensing contact 19 makes contact with the conductor track 4 (segment 4 ″).

Rotation position 14:

Sensing contacts 17, 20 and 21 remain on conductor tracks 6, 3 and 7, respectively; Scanning contact 18 acts on the conductor track 5 (segment 5 ¹ ).

Rotary position 15:

As in the rotary position 14, but additionally the sensing contact 19 acts on the segment 4 ′ of the conductor track 4.

For this purpose 2 sheets of drawings

Claims (6)

1 2 (value C) a circle segment of more than 180 ° Patent claims: covered (takeover principle). 7. Rotary coding switch after removing the previous 1. Rotary coding switch (mit8-4-2-l coding) with existing claims, characterized in that the 5 conductor track (3) connected to the supply line (16) - Several in a plane arranged conductor (valence C) on the second outermost scanning circle tracks (3-7), which (10) and lies on a circle segment that extends radially - have different values (count value is within the circle segment, on which 8-4-2-1 or C = common) have, the conductor track (7) with the highest value - Is arranged continuously on concentric circles (9, 10, io ti) and 8. rotary coding switch after one of the previous - With a supply line (16) and several outgoing claims, characterized in that at lines (12-15) are connected and a rotary coding switch with 16 rotary encoder - One around a perpendicular to the plane of the lines (hexadecimal coding switch with three Abterbahnen (3- T) arranged axis of rotation (8) 15. Feeler circles) on the innermost scanning circle (9) the rotatable collector (2), the conductor paths with the valences "1" and "2" - A plurality of interconnected middle scanning circle (10), the conductor tracks with which scanning contacts (17-21) have the values "2" and "4" and "Q" and on which the outermost scanning circle (11) has the conductor track the - lie on both sides of the axis of rotation (8), value »8«,
are in order - a radial distance from this indicate the radial distance of the conductor tracks assigned to them (3-7) from the axis of rotation (8). The invention relates to a rotary coding switch speaks, and the features of the preamble of claim 1. - On a through the axis of rotation (8) from DE-OS 23 14 £ 77 a coding switch is known, running straight lines (22) are the ten different rotational positions and allows whose code pattern has the code number 141 characterized, 30 is characterized. With this code pattern there is a 8-4-2-1 coding, in addition a so-called - That with 2 "distributed on the switch circumference called complementary coding available.
Collector rotary pitches of different As usual with such switches, in a level count the several conductor tracks are arranged by the sensing contacts ne, which have different values, on concentric sensing circles (3--7 ) lie on n— 1 concentric scanning lie and with a supply line and several deflection circles (9,10,11), lines are connected. To be perpendicular to the plane - From a total of n + 1 scanning contacts (17-21) of the conductor tracks arranged axis of rotation is acted upon by a KoI, rotatable lektor, which is a plurality, 'of each other - where / 7 is> 2 and has 40 connected sensing contacts that are on both sides - Each of the conductor tracks (3-6) are arranged except for the axis of rotation and are the one from this (7) with the highest valence, with a radial distance equal to the radial distance full collector rotation of two each stood the conductor tracks assigned to them from the corresponds diametrically and point-symmetrically to the axis of rotation. All sensing contacts are on axis (8) opposite scanning contacts 45 of a straight line running through the axis of rotation. (17.20 or 18.19) is applied The known coding switch is disadvantageous in that than each individual scanning device present on the collector 2. Rotary coding switch according to claim 1, characterized in that a separate scanning circuit (conductor track) contact is marked, that the conductor track (7) is in line with the. For example, one of the drawing figures shows Valence only during a half turn of the 50 ren from DE-OS 23 14 277 nine sensing contacts that on Collector (2) from a scanning contact (21) circulate nine separate scanning circles. is beat. The type and geometry of the arrangement of the conductor 3. Rotary coding switch according to claim 1 or 2, da- bahns of the known switch requires on the one hand characterized in that the conductor track (7) with a relatively large diameter of the switch, wherein highest value on the outermost scanning circle 55 is the relatively complicated interlacing of the conductor (k'l) lies. tracks and the associated connecting tracks a 4. Bring the rotary coding switch to one of the previously relatively narrow strip conductors. Darhenden claims, characterized in that the number of on-off operations in the conductor track (7) with the highest value on a full collector revolution is relatively high, which is opposite to the supply and discharge lines (12-16) - 60 can lead to malfunctions. lowing side of the scanning circle is arranged. From DE-OS 26 55 814 a coding switch is known- 5. Rotary coding switch according to one of the previous ones, the collector of which has three groups of scanning hands Claims, characterized in that the contacts, the sensing contacts each Conductor track (7) with the highest valence a vector group lie on a straight line that forms the rotating circle segment covered by less than 180 °. 65 axis of the collector intersects. The straight lines are under- 6. Rotary coding switch arranged after one of the previous one at an angle of 120 °. Such a devoted one Claims, characterized in that the ge collector arrangement is complicated and expensive, the conductor track (3) connected to the supply line (16), in particular, is also the number of on / off switching