DE3310471A1 - Coupling between two functional elements mounted with a spacing from one another which is subject to tolerance - Google Patents

Abstract

Spacing tolerances occur between two functional elements, e.g. an operating knob (8) and a switch (9a), when the latter are mounted on separate carrier boards, e.g. a front board (11) and a printed circuit board (12). By means of the invention, a coupling is provided which compensates the positional tolerances in the direction of all three axes of a three-dimensional coordinate cross. In this case, at least one first end piece (1a) of the power line (1) is guided in a first groove (4) by the width and height thereof in such a way that the position of the power line (1) is displaceable in a sliding manner in the direction of two axes of a three-dimensional coordinate cross. In this case, the power line (1) can be constructed as a flat bar cross (1), a second end piece (1b) and an associated second groove (5) being offset by 90 DEG relative to the first end piece (1a) and the second groove (5) allowing displacement of the second end piece (1b) in the direction of the third axis of a three-dimensional coordinate cross. However, cams (6a, 6b) can also be constructed at least on the first end piece (1a) on both sides of the power line (1) between the latter and the guide walls (4a, 4b) of the first groove (4), which cams act as a slip joint and permit a tilting movement of the power line (1) in the direction of the third axis of a three-dimensional coordinate cross, a joint which also carries out the tilting movement also being constructed on the second end piece. <IMAGE>

Description

Coupling between two at a distance subject to tolerances

Functional elements assembled to one another The invention relates to a Coupling of the type mentioned in the preamble of claim 1.

Should two functional elements, e.g. a switch and a control button are connected to each other, you need a coupling. In the simplest case such a coupling can be realized by a rigid connecting axis. Is a direct mounting of the switch on the front panel of the respective device not possible, between its installation site and the installation site of the control button Distance tolerances occur on the front panel with a rigid connection axis cannot be compensated or only unsatisfactorily.

For electric cookers, where the switch is often a considerable distance away Must be arranged by the control button, it is known with fork couplings, cardan joints and flexible shafts to work (DE-PS 10 74 123, DE-PS 11 56 869, DE-PS 10 87 220).

These means are sometimes very complex mechanically, or in their own right Function in as far as not satisfactory as that in the direction of rotation of the control knob occurring play is inadmissibly large, at least for precision devices. It is coming added that a full tolerance compensation over all three axes of a spatial coordinate system not with the known couplings or at most with the use of screwing means is possible.

In electrical measurement technology, where also of the mechanical elements highest precision is required, one tries to keep the assembly tolerances so small keep that rigid couplings can be used. With measuring instruments it is therefore it is still common practice to use the control button with the switch via a switch blade connect to. But especially in the case of complicated measuring devices with many operating functions this technology causes considerable costs. It should be noted that not only many different types of switches, but also buttons and potentiometers require a clutch.

The object of the invention is to provide a coupling that has two Functional elements mounted with one another at a distance subject to tolerances connects, here a tolerance compensation in the direction of all axes of a spatial coordinate system is simple and easy to assemble. This task the features characterized in claim 1 are thereby achieved. Advantageous configurations and further developments of the invention are characterized in the subclaims.

In the case of the coupling, the two opposite to each other Functional elements formed recordings and a force conductor acting between these there is a tolerance compensation in the direction of two axes of a spatial coordinate system initially created by designing one of the two recordings as the first groove is, in which a first end piece of the force conductor is slidably arranged. The first Groove that grips the force leader on both sides in such a way that there is no play in this direction remains, on the other hand, is wider than the force conductor and so deep that this sliding up and down as well as sideways is possible. The training of the second end piece of the force conductor depends on the type of recording that is on the second Functional element is provided and thus ultimately of the task that this Has to perceive functional element.

If the second receptacle can also be designed as a groove, this is the case in order to offset 900 compared to the first groove and also the force conductor must be a flat bar cross be designed with two end pieces arranged at right angles to one another. Since the second groove is also made wider than the second end piece, thus position tolerances are also compensated in the direction of the third axis of a spatial coordinate system.

A cross-wise arrangement of the grooves and power conductor end pieces can be waived if at least on the first end piece on both sides of the force conductor, between this and the guide walls of the first groove, cams are formed, which act as a sliding joint and a tilting movement of the power head in the direction of the allow third axis of a spatial coordinate system. The one by the cam on the first Tilting movement made possible by the end piece of the force conductor, the second end piece must of course can participate. The joint required for this on the second end piece can in turn be formed in the same way by cams or by conventional articulated links.

For the sake of plastic injection molding, it is easier to use the cams to be attached to two opposite sides of the force conductor. the However, the principle of operation of the coupling also allows the formation of cams on the inside of the guide walls of the respective groove.

If both functional elements are provided with grooves, it is useful to train the force conductor as a flat bar or as a flat bar cross. Owns one of the functional elements, for example a potentiometer, is coupled to a shaft must be, one of the two end pieces of the force conductor can be used as a plug-on part be carried out, which can be plugged onto the shaft.

The ones on the outer edges of one or both end pieces of the flat bar or flat bar cross attached cams can be on both sides of the outer edge a continuous wu: like thickening. However, the thickening is better to be interrupted in the middle, so that four cams are formed, of which two each opposite to the enclosing inner walls of the groove four point-shaped Form requirements. This reduces the friction that occurs during the tilting movement.

The two bulge-like thickenings, each forming two cams, are seen in cross-section oval or almost pointed towards the end. In cooperation this special form of thickening with flexible guide walls the groove is achieved that a unilaterally free force conductor is always in the groove set up vertically.

During assembly, the force conductor does not have to be in the desired position Position are brought and allows its shape at the same time a light Insertion into the groove.

If the second end piece of the force conductor is designed as a clip-on part, so it must be connected to the first end piece by a hinge. It's functional To use a tape hinge here, which is particularly easy in plastic injection molding is to be established. The hinge is preferably designed with three arms to ensure that the tilting movement can only take place in one direction and also no torsional play can arise when the functional elements rotate.

The assembly of the coupling elements can be made easier, that where a groove is used to accommodate the force conductor, this groove is a cross groove is formed and the force conductor when inserted facing the plug-in opening the groove is widened like a funnel. Otherwise, however, the distance between the guide walls of the groove remain the same.

It is first of all thought of using a control button through the coupling to be connected to electrical switches or control elements, e.g. potentiometers. However, the clutch can also act between the switching levels of a switch, if these switching levels, e.g. on several parallel printed circuit boards are distributed.

It can be advantageous for the assembly if the second end piece of the force conductor is designed as a plug-in or slip-on part. The force leader can thereby firmly connected to a functional element on one side and arrives at Insertion of this functional element automatically into the groove of the other functional element. The fixed connection of the force conductor can be through a tape hinge or by a partially closed groove that prevents sliding out can be achieved.

Further details and advantages of the subject matter of the invention are based on exemplary embodiments in the drawings and are shown below explained in more detail.

They show: FIG. 1: The coupling for connecting an operating button with a rotary switch.

Figure 2: The coupling as a connection of a control button with a Potentiometer.

Figure 3: A force conductor designed as a flat bar.

Figure 4: A force conductor designed as a flat bar cross.

Figure 5: A force conductor with a flat bar and a plug-on part.

FIG. 6: A receptacle designed as a cross groove in a top view.

Figure 7: The cross groove shown in a side view in section.

Figure 8: The design of a button with the coupling according to the invention.

Figure 9: Representation of the tolerance compensation by tilting movements of the Force conductor with an offset groove in two coordinate directions.

FIG. 10: Representation of the tolerance compensation in the third coordinate direction.

Figure 11: Principle of operation of a force conductor with a joint (tape hinge) and one-sided attachment to the control button.

Figure 12: Principle of operation of a force conductor with a joint (tape hinge) and one-sided attachment to the control element.

As Figure 1 shows, there is between a control button 8 and a rotary switch 9a acting coupling from a groove 4 in the control knob 8, a groove 5 in the rotary switch 9a and a force conductor acting between the grooves 4, 5 1. The latter is designed as a flat bar cross, the one shown in FIG. 4 again in perspective is shown. Here, the two end pieces 1a, 1b are offset by 900 to one another. The outer edges of the two end pieces 1a, 1b each have bead-like thickenings 6a, 6b, 10a, 10b, which are interrupted in their middle and on both sides of the end pieces Form cams.

Those resting point-like on the inner walls 4a, 4b, 5a, 5b of the grooves 4, 5 Cams 6a, 6b, 10a, 10b are through their small contact surface and thus correspondingly low friction compared to continuous bead-like thickenings preferable. For this reason, but also for an even greater tolerance compensation to enable, expediently, one designed as a flat bar cross is also expedient Force conductor provided with cams, although in principle there are no cams in this case bulge-like thickenings would still be required. Because in contrast to the one in figure 3 illustrated as a straight flat bar force conductor 2 must be a flat bar cross to compensate for tolerances cannot perform tilting movements like the cams allow.

The grooves 4,5 are designed so that their flexible inner walls 4a, 4b, 5a, 5b press against the cams 6a, 6b, 1Oa, 1Ob so that there is no play between them.

Rotational movements of the control button 8 are thus play-free on the Transfer switch 9a. Otherwise, however, the two grooves are 4.5 as wide and so deep that a displacement of the force conductor 1 is possible, which a tolerance compensation in the direction of all three axes of a spatial coordinate system. Distance tolerances a front panel 1 to a circuit board 12, which inevitably also on the Functional elements worn by you, so here on the control button 8 and the Rotary switch 9a have no adverse effects.

Not all switching or adjusting elements are constructed in such a way that it is possible a groove is to be formed as a receptacle for the force conductor. At least it would be uneconomical In the case of supplied parts such as a rotary potentiometer, the positioning axis can be added later to be provided with a groove. In this case, as shown in FIG. 2 and FIG is, the second end piece of a force conductor 3 designed as a push-on part 3b. The slip-on part 3b can be plugged onto the adjusting axis 15 of a potentiometer 9b like a cap. Distance tolerances between the front panel 11, on which a control button 8 by means of Latching hook 13 is attached and a printed circuit board carrying the potentiometer 9b 12 are balanced by the first end piece 3a of the force conductor 3. This with End piece 3a provided with cams 6a, 6b slides in a groove as already described 4, the flexible inner walls 4a, 4b of which press against the cams 6a, 6b. With it tilting movements of the first end piece 3a compared to the push-on part 3b are possible between both a band hinge 7 is arranged. The three arms 7a, 7b, 7c of the belt hinge are only flexible in one direction, namely the tilting direction, but especially in the direction of rotation so stable that no unwanted play occurs here.

The assembly of the coupling elements is facilitated in that, as shown in Figure 6 and 7, the groove at its opening facing the force conductor is expanded like a funnel. When seen in cross-section, they are oval or almost tapered Bead-like thickenings or cams of the force conductor thus allow easy Insertion into the groove. Due to the special shape of the cams and the elasticity the inner walls of the groove pressing against the cams are also achieved that the force conductor moves into a straight position without external influence.

Figure 8 shows the application of the clutch according to the invention in a Pressure switch. Since there is no rotary but an up and down movement of the control button must be transferred to the switch, the ratios are nits something else. There is no play of the functional elements when lifting up and down Avoid completely, but in this case it is not worth mentioning if the stroke is sufficient Meaning. From Figure 8 it can also be seen that it is also possible, at least to form a groove in such a way that it grips the force conductor on the cam like a forceps, so that the force conductor after its insertion into the groove only with increased force can be removed from this again. Rotary switches can also be installed during assembly this can be an advantage because the force conductor is thus at least connected to one of the functional elements is firmly connected and therefore cannot be lost.

Based on the schematic representations in FIGS. 9 to 12, once illustrates the principle mode of operation of the clutch. Figure 9 shows this End piece 1a, 2a, 3a of a force conductor, as already known from FIGS. 1 to 8 is. This force conductor slides in a groove 4. By sliding and tilting movements of the end piece 1a, 2a, 3a is a tolerance compensation in the direction of all three axes X, Y, Z. a spatial coordinate cross possible. FIG. 9 shows the tolerance compensation in the direction the X and Z axes, Figure 10 shows it in the direction of the Y axis.

It is assumed that a groove 4 formed in, for example, an operating knob is, its position in relation to a fixed point F, which is also the pivot point of the end piece 1a, 2a, 3a is changed starting from their normal position. The normal situation is thereby determines that the points A, B, C coincide and together the extreme end of the Form groove 4. The groove can now move in the direction of the X-axis by + X1 / 2 to the point Move A1 or A2.

The maximum permissible displacement X1 is determined by the Tilt angle Alpha of the end piece 1a, 2a, 3a is determined. There is a shift in the direction of the Z-axis of the groove 4 by + Z1 / 2 from point B to point B1 or B2 possible. The allowable displacement Z1 is determined by the depth of the groove. Finally, as Figure 10 shows, also in the direction of the Y-axis a shift of the groove by Y1 / 2 to the point C1 or C2 take place. Here, the width of the groove determines the maximum permissible displacement Y1. No further explanation is required that the individual shifts Add vectorially on the X, Y and Z axes and thus position tolerances Each type can be compensated within a permissible range.

Although this leaves a lot of leeway with regard to manufacturing tolerances arises, an almost backlash-free power transmission is guaranteed in the direction of rotation R.

The first end piece 1a, 2a, 3a of the force conductor 1,2,3 can tilt movements only execute if the second end piece 1b, 2b, 3b joins these tilting movements or is provided with a joint 7. FIGS. 11 and 12 show force conductors 3 with a hinge 7, which can be designed, for example, as a band hinge. The joint 7 corresponds to the fixed point F from FIG. 9. While in FIG. 11 the second end piece 3b of the force conductor 3 is firmly connected to the actuator 9, this is shown in FIG second end piece 3b firmly connected to the control button 8.

Otherwise, the mode of operation is the same for both clutches.

List of reference symbols for-E 3664 1,2,3 force conductor 1 force conductor as Flat bar cross 1a first end piece on the flat bar cross ib second end piece on the flat bar cross 2 force conductors as flat bar 2a first end piece on flat bar 2b second end piece on the flat bar 3 force conductor as a push-on part 3a first end piece on the push-on part 3b second end piece on the push-on part 4 first groove (in the control knob) 4a, b guide walls of the first groove 4 4c opening of the groove 4 5 second groove (in the switching or adjusting element) 5a, b guide walls of the groove 5 6 bead-like thickening on the first end piece 6a, b cams on the first end piece 7 tape hinge 7c middle arm of the tape hinge 7a, b lateral Arms of the hinge 8 control button 9 switching or adjusting element 9a switch 9b Potentiometer 10 bead-like thickening on the second end piece 10a, b cams on the second End piece 11 front panel 12 printed circuit board 13 snap-in hooks 14 ring groove 15 rotating shaft

Claims (12)

ANS A N S P R tJ C H E Coupling between two in tolerance-afflicted Functional elements mounted at a distance from one another Coupling for the transmission of rotary and / or strokes between two functional elements that are subject to tolerances Distance to each other are mounted and between which a force conductor acts that the Transfers movements of the first functional element to the second functional element, the two end pieces of the force conductor attacking receptacles on the two Functional elements are formed, characterized in that at least one first end piece (la, 2a, 3a) of the force conductor (1,2,3) in the associated as the first Groove (4) designed recording by corresponding width and height of the first groove (4) is guided so that the position of the force conductor (1,2,3) in the direction of two Axes (Y, Z) of a space coordinate cross is slidably displaceable, and the force conductor (1,2,3) is designed either as a flat bar cross (1), the second end piece (1b) and an associated second groove (5) opposite the first end piece (1a) by 900 are offset and the second groove (5) a displacement of the second end piece (1b) in the direction of the third axis (Y) of a spatial coordinate system, or at least at the first end piece (la, 2a, 3a) on both sides of the force conductor (1,2,3) between this and the guide walls (4a, 4b) of the first groove (4) cams (6a, 6b) are formed, which act as a sliding joint and cause a tilting movement of the ters (1,2,3) in the direction of the third axis (Y) of a spatial coordinate system, wherein a joint (7,10) is also formed on the second end piece (2b, 3b), which the Tilting movement participates. 2. Coupling according to claim 1, characterized in that the cams (6a, 6b) on two opposite outer sides of the force conductor (1,2,3) or Inner sides of the guide walls (4a, 4b) of the first and / or second groove (4, 5) are formed are. 3. Coupling according to claim 1 or 2, characterized in that the Force ladder as a flat bar (2) or as a flat bar cross (1) with two at right angles Flat bars lying opposite one another or as a flat bar (3) with a second, as a slip-on part executed end piece (3b) is formed. 4. Coupling according to at least one of the preceding claims, characterized characterized in that the cams (6a, 6b) on both sides of the outer edge of one or both End pieces of the flat bar (2) or flat bar cross (1) a continuous or in form the middle interrupted bead-like thickening (6), this thickening (6) is oval or almost pointed towards the end when viewed in cross section. 5. Coupling according to at least one of the preceding claims, characterized characterized in that the bead-like thickenings (6) of the end piece (1a, 1b, 2a, 2b, 3a) of flexible guide walls (4a, 4b) of the first and / or second groove (4,5) in a press fit are recorded. 6. Coupling after at least one of the preceding the Claims, characterized in that the second end piece (3b) of the force conductor (3) formed joint is formed by a band hinge (7). 7. Coupling according to claim 6, characterized in that the hinge (7) is designed with three arms, whereby from the rod-shaped part of the force conductor (3) a middle band (7c) goes out and on each side a support band (7a, 7b) is provided and the two support bands arcuate the two end pieces (3a, 3b) connect with each other. 8. Coupling according to at least one of the preceding claims, characterized characterized in that the first and / or second groove (4,5) is designed as a cross groove and the plug-in opening (4c) facing the force conductor (1,2,3a) when it is inserted the groove (4) is widened like a funnel, but otherwise the distances between the guide walls (4a, 4b) of the groove are the same. 9. Coupling according to at least one of the preceding claims, characterized characterized in that the two functional elements (8,9) between those of the force conductor (1,2,3) acts, on the one hand a control button (8) and on the other hand an electrical one Switching or adjusting element (9) are. 10. Coupling according to at least one of claims 1 to 8, characterized characterized in that the two functional elements (8,9) between those of the force conductor (1,2,3) has two switching levels of a switch consisting of several switching levels are. 11. Coupling after at least one of the preceding the Claims, characterized in that the second end piece (3b) of the force conductor (3) is designed as a plug-in or plug-in part and with one of the functional elements (9) must be connected in such a way that it cannot be lost. 12. Coupling according to at least one of the preceding claims, characterized in that the force conductor (1,2,3) on one side on the switching or adjusting element (9) or attached to the control button (8) with a tape hinge or partially by a closed groove (4,5) is prevented from sliding out and only the other Groove (5,4) allows the force conductor (1,2,3) to slide out.