EP0173874B1 - Spring-return detent mechanism with rotary range limitation for rotary switches - Google Patents

Description

The invention relates to a return mechanism with rotation range limitation for rotary switches according to the preamble of claim 1.

With rotary switches, there is a need to close an electrical contact that remains closed only as long as the actuating handle is held in its position, so that the contact is automatically opened again when the actuating member is released. Such a switch is known for example from DE-PS 930600. Here, a spiral spring is arranged between the shaft and the housing of the rotary switch, which is tensioned when the shaft is rotated and which causes the shaft to be automatically pushed back into the starting position when the actuator is released.

A similar rotary switch is known from DE-A 2403565. There, the restoring torque is generated by a helical spring, which in the end-of-rotation position is pressed against a stop by a pin that is also rotated, and is thereby preloaded.

There are also known rotary switches in which a plurality of contacts can be closed in succession by rotating the rotor. In order to ensure that the rotor remains in the desired position after the actuator is released, a locking mechanism is usually provided, which causes the rotor to be held in the respectively set switching position. To continue rotating the rotor from one switching position to the next, it is necessary to overcome the holding force of the locking mechanism. Such latching mechanisms are usually constructed in such a way that a latching contour consisting of elevations and depressions is arranged in the interior of the housing, on which resilient latching elements arranged in the rotor slide. When switching from one locking position to the next, it is necessary to overcome the spring force of the locking elements.

But there are also known magnetic detent mechanisms in which an annular multi-pole magnet is provided which interacts with an opposing magnet. Here the rotor is held in the respective locking position by magnetic forces. Here too, the holding force of the magnet must be overcome when switching on.

Since it is not always desirable to turn the rotor of the rotary switch over the full rotation range of 360 °, rotation range limits are provided in such locking mechanisms, with which the angle of rotation of the rotor is limited to a desired range. Limits of rotation range in which the stops are designed to be changeable are particularly advantageous, so that a respectively desired rotation angle range can be set. Latching mechanisms with such a variable range of rotation limitation are known for example from DE-A-2238476, DE-C-2600368 and DE-C-3139205.

In such ratchets with rotation range limitation, there is still the need to design the last switching position of the rotating range so that after the actuator is released, the rotor automatically returns from the last to the penultimate switching position. This requires at least one additional spring in the locking mechanism. Such locking mechanisms are referred to as return locking mechanisms and are known from DE-B-1946887, DE-A-2403565, DE-C-2403959, DE-PS 3140772 and US-A-3515832. In order to spring back the rotor from the last switching position into the penultimate switching position, an additional spring is required in such locking mechanisms, which is either a coil spring or a leg spring. These have to be accommodated in the locking mechanism, the overall height of the locking mechanism and thus of the switch being increased not insignificantly. In addition, the locking mechanism must be adjusted accordingly so that the locking mechanism does not hinder the springback of the rotor from the last switching position to the penultimate switching position. For example, in the case of a locking mechanism with a locking contour, the locking tooth must be removed at the springback point. The advantage of the variable rotation range limitation, for example by moving stop pins, is partially nullified. If the range of rotation limitation is changed while maintaining the return contact, then the locking contour of the locking mechanism and, if necessary, the arrangement of the return spring would also have to be changed. Attempts have been made to reduce the overall height of a return locking mechanism by arranging the return spring outside the locking housing (DE-C-2403959). However, a return spring is still required as an additional component and there is still the above-mentioned here. Disadvantage that the rotation range limitation cannot be set arbitrarily.

The object of the invention is to provide a return mechanism with rotation range limitation for rotary switches, which is constructed more simply with a low overall height and allows any adjustment of the rotation range limitation while maintaining the return contact. The invention further makes it possible to arrange return contacts at both ends of the rotary range, which would otherwise only be possible by inserting a second return spring with a further increase in the overall height.

This object is achieved by the features of the characterizing part of claim 1.

The invention is based on the knowledge that a resilient force is already present in a normal locking mechanism due to the resilient locking elements. According to the invention, this restoring force is used to actuate the return contact at the end of the rotation range. It is only necessary to use the rotation range limitation to slightly less than half the angle of rotation in the last locking position Limit the detent angle. As a result, in the last locking position, the rotor can only be rotated so far that the dead center of the locking is not exceeded, so that the rotor automatically springs back into the previous locking position after the actuating member is released.

This achieves significant advantages. In the case of a return locking mechanism according to the invention, no additional return spring is required, so that this component is completely eliminated and the overall height of the locking mechanism does not have to be changed. Furthermore, no special training of the locking mechanism at the return point, such as the omission of a tooth of the locking contour, is required. Since the latching of a latching mechanism acts in the same way in both directions of rotation, return contacts can be arranged at both ends of the rotating range of the rotor, for which purpose a springback mechanism would require two return springs. Finally, the advantages of an adjustable rotation range limitation, for example by moving corresponding stop pins or stop bolts, can be fully utilized, so that return contacts can be arranged at any point. It may only be necessary to offset the corresponding fixed or movable contact of the rotary switch by a small angular range. Since the fixed contacts of rotary switches are in many cases designed as a printed circuit board, this means no additional effort.

The invention will now be explained in more detail with reference to the figures.

• Fig. das geöffnete Gehäuse des Rücksprungrastwerks gemäss der Erfindung,
• Fig. 2 in Draufsicht den Rotor des Rastwerkes von Fig. 1,
• Fig.3 einen Schnitt durch das Rastwerkgehäuse nach Fig.1 längs der Schnittlinie A-B und
• Fig.4 einen Schnitt durch den zugehörigen Rotor,
• Fig.5 Teile des Rastwerkes und der Drehbereichsbegrenzung zur Erläuterung der Wirkungsweise der Erfindung.

Show it:

• FIG. 1 shows the open housing of the return framework according to the invention,
• 2 is a plan view of the rotor of the locking mechanism of FIG. 1,
• 3 shows a section through the locking mechanism housing according to FIG. 1 along the section line AB and
• 4 shows a section through the associated rotor,
• Fig.5 parts of the locking mechanism and the range of rotation to explain the operation of the invention.

1 shows the open latch mechanism housing 1. A square plate 18 with fastening holes 17 is formed on the cylindrical latch mechanism housing, which are used to fasten the rotary switch parts to the latch mechanism.

A locking contour 8 is arranged on the inner circumference of the cylindrical cavity 2 of the locking mechanism housing 1. In the bottom of the locking mechanism housing, an annular channel 5 is provided, in the circumference of which, in the locking contour, corresponding angular divisions, slots 6 are formed, into which stop pins 7 can be inserted. In the middle of the locking mechanism housing 1 is the rotor bearing bore 3, which continues into an integrally formed threaded bush 4.

A rotor 9 with an integrally formed shaft 10 is arranged in the cavity 2 of the locking mechanism housing 1. The rotor has axial bores 12 into which stop bolts 13 can be inserted. Furthermore, the rotor has radial bores 14 at two opposite points, in which locking balls 15 and coil springs 16 are arranged. When the two parts are assembled, the rotor shaft 10 is located in the rotor bearing bore 3 and the rotor body 11 in the cavity 2, the locking balls 15 being pressed into the recesses of the locking contour 8 by the springs 16. To turn the rotor by means of the rotor shaft 10, the spring force of the helical springs 16 must be overcome, since the locking balls 15 are pressed into the bores 14 on the elevation of the locking contour. The rotation angle is limited in such a way that stop bolts 9 are arranged in the axial bores 12 of the rotor, which protrude into the ring channel 5 of the locking mechanism housing 1 and interact with the stop pins 7 in the sense of a rotation angle limitation. The rotation angle limitation can be changed in such a way that the stop pins 7 are inserted into other slots 6, or also in such a way that further bores 12 are provided in the rotor and the stop bolts 13 are inserted in another bore of the rotor. 3 and 4 show corresponding longitudinal sections through the parts of FIGS. 1 and 2, the two parts being in the position in relation to one another as they are assembled. It can be seen from this that when the rotor shaft 10 is inserted into the rotor bearing bore 3 of the threaded bushing 4, the stop bolts 13 protrude into the ring channel 5 at the bottom of the locking mechanism housing. If a stop pin 7 is inserted into the slot 6 of the ring channel 5, the stop bolt 13 strikes the stop pin 7 during the rotary movement of the rotor, thereby limiting the rotary movement of the rotor. In the latching mechanism shown in FIG. 1, ten switching positions are provided over the entire circumference, so that ten latching positions and ten stop positions are provided on the circumference, each corresponding to an angle of rotation of 36 °.

According to the invention, the rotation angle limitation is now arranged in such a way that in the last locking position the rotation angle is limited to less than half the locking angle. This means that either corresponding slots 6 are provided for the stop pins 7, or corresponding bores 12 in the rotor for the stop bolts 13. It is of course advisable to provide corresponding bores 12 in the rotor, because this is much easier than additional slots 6 in the locking mechanism housing to provide.

The mode of operation of the invention will be explained in more detail with reference to FIG. During normal locking, the locking ball 15 slides in the locking contour 8 and has a position in the recess of the locking contour in each switching position, as shown in FIG. 5 at 15a. After each rest, it is Locking ball 15 shifted by the angle a in the locking contour, which corresponds to an angle of 36 ° in the arrangement of a ten-part locking according to Fig.1. According to the invention, the rotation angle limitation is arranged in such a way that in the last locking position it can be rotated by only slightly less than half the locking angle, for example by correspondingly arranging the stop pin 7 to the stop bolt 13. The rotor can then only be rotated via the angle of rotation b , wherein the detent ball 15 reaches position 15b, ie does not quite reach the inner elevation of the detent contour. This angle b is, for example, 15 ° with a detent angle of 36 °. As a result, the dead center of the detent is not exceeded, so that when the actuating member is released, the rotor slides back under the action of the detent spring 16 acting on the detent ball 15 until the detent ball 15 again lies in the largest recess of the detent contour 8. A return is thus automatically achieved without additional means, such as, for. B. return springs are required. In the case of a limitation of the angle of rotation, as was described with reference to FIGS. 1 to 4, this can be achieved in a very simple manner by making a corresponding axial bore 12 in the rotor body 11. This angle of rotation limitation is therefore preferably suitable for carrying out the invention. Such a locking mechanism can therefore be converted into a return locking mechanism simply by making an additional hole. If several corresponding bores are provided, a return can easily be achieved at both ends of the rotation range. The limitation of the range of rotation can then be easily moved as desired, with the return taking effect at the end of the range of rotation.

Although the invention can be implemented particularly well with a rotation angle limitation with interchangeable stop pins, its application is also possible with other rotation angle limitations. Also, the locking does not necessarily have to be carried out by means of resilient locking members that slide in a locking contour, but can also be designed differently, for example than the magnetic locking described at the beginning.

Claims (3)

1. Jump-back detent mechanism with a turning-range limiter (7, 13) for use with rotary switches having a cylindrical housing (1), a shaft (10) extending concentrically therethrough, a detent device (8, 15) for defined switching positions acting between the housing (1) and the shaft (10), and a turning range limiter (7, 13) adjustable on at least one side of the turning range for restricting the rotary movement of the shaft (10) inside the housing (1), with the shaft (10) springing back from a last switch position at the end point of the rotary movement into the last detent position, characterized in that the turning-range limiter (7, 13) restricts the rotary movement of the shaft (10) from the last detent stage to said last switch_'position to less than half the detent angle, the return springing being brought about by the detent device alone.

2. A jump-back type detent mechanism as claimed in claim 1, characterized in that for effecting the turning-range limitation (7, 13) inside the housing (1) there are provided radially disposed displaceable stop pins (7) and, in boreholes of a rotor body (11) connected to the shaft (10), there are provided axially disposed displaceable stop bolts (13).

3. A jump-back type detent mechanism as claimed in claim 1 or 2, characterized in that a detent contour (8) is provided on the inside wall of the housing (1), which cooperates with detent members (15,16) which are resiliently disposed in radial boreholes (14) provided in the rotor body (11 and that the turning-range limiter (7, 13) is so disposed that in the last detent stage the detent members (15) will not quite reach the projection of the detent contour (8) projecting furthest towards the inside.

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