DE1283066B - Spring lever locking mechanism with locking mechanism engaging on both sides - Google Patents

Description

The invention relates to a spring lever locking mechanism with double-sided engaging latches, in particular for devices for converting torsional vibrations in rotating movements in the same direction, preferably for switching timing instruments, consisting of a shaft carrying indexing means, which contact surfaces for leaf spring legs having. Spring lever locking mechanisms of this type are known. The contact surfaces having Shaft is designed as a square shaft, and it is in each case on two parallel Contact surfaces each have a leaf spring leg. Through to the indexing means of the wave Acting forces are broken down into four sub-steps every full revolution of the shaft. The number of sub-steps is therefore determined by the number of those assigned to the wave Contact surfaces. Is it necessary, for example, to complete a full turn of one of these To disassemble the selector shaft into six switching steps, six contact surfaces are provided.

In devices for converting torsional vibrations into the same direction Rotary movements, preferably for switching timing instruments, is when six switching steps are to be carried out, the switching shaft a hexagonal prism assigned, although the shaft only has three indexing pins serving as indexing means Od. Like. Are assigned to act on the arms of a rotary oscillator. If Now, as proposed according to the invention, the cross-section of the shift shaft is triangular trains and ensures that the leaf spring legs one leg in the web area pivotably mounted, U-shaped bent leaf spring in a manner known per se then one full turn of the selector shaft can be done in six switching steps split up, although only three contact surfaces are provided. The swiveling storage is the leaf spring leg cooperating with the contact surfaces of the selector shaft not required per se, but useful in devices for switching Timing instruments that have to work precisely because of the loss of energy and the maximum service life is increased. By reducing the Number of contact surfaces with the same number of rest points within one single rotation of the selector shaft, the structure of the device is simplified.

The invention is based on an embodiment shown in the drawing explained below. It shows F i g. 1 a top view of one with three increments or the like. And three contact surfaces provided shift shaft according to the invention with its associated U-shaped, pivotably mounted leaf spring, F i g. 2 a Amplitude and impact force diagram of the device according to FIG. 1.

The selector shaft 1 carries three indexing pins 2 designed as cylinder journals, which represent the indexing means. In addition, the selector shaft 1 is assigned three contact surfaces 3 which can be produced simultaneously with the production of the indexing pins or the like. A U-shaped bent leaf spring 5, pivotable with respect to a bearing journal 4 , interacts with its two legs 6 and 7 with the three contact surfaces 3. In each case, one of the two legs rests on a contact surface. The other leg then lies parallel to the former and acts on a tip of the cross-sectional triangle. The tips of the cross-sectional triangle are easily broken, as indicated in the drawing, unless the diameter of the control shaft is dimensioned so that the peripheral surfaces of the control shaft correspond to these broken tips.

The shift shaft 1 is supported by arms 8 and 9 of a not shown Torsional oscillator rotated step by step when the torsional oscillator executes oscillatory movements. This rotary oscillator is arranged so that its axis of rotation and the axis of rotation of the Shift shaft 1 not only lie in the same plane, but also both axes of rotation are still perpendicular to each other. So in the case of FIG. 1 the rotary transducer pivoted so that the arm 9 hits against the indexing pin 2 closest to it, then the selector shaft 1 is rotated by one switching step, and there are six switching steps to be carried out when the selector shaft is to rotate once around its axis.

In the diagram according to FIG. 2 an oscillation amplitude of the torsional vibrator of qao = 270 ° is assumed. If the angle between the two arms 8 and 9, which are arranged one above the other on the rotary transducer, is denoted by ", then an impact exerted by the arms of the rotary transducer on the indexing pins of the switching shaft begins after about 7 ° behind half the angle a and ends after another angle of rotation that is slightly smaller than the angle x and that in FIG. 2 is labeled cps. The oscillating system is loaded only for the movement of the rotary oscillator extending over the range of cps, which is also in the range of the maximum speed of the oscillator, since the leaf spring 5 has to be raised in this area. The impact force F, which is shown in FIG. 2 is also shown, but decreases again very quickly because the leaf spring 5 gives off part of its clamping force again and forces the selector shaft into the new position. The shock duration t is thus very short and thus ensures only a brief reaction of the locking mechanism on the oscillating system of the torsional oscillator.

Claims (1)

Claim: Spring lever locking mechanism with locking mechanism engaging on both sides, in particular for devices for converting torsional vibrations into rotational movements in the same direction, preferably for switching timing instruments, consisting of a switching shaft carrying switching means, which has contact surfaces for leaf spring legs, characterized in that the cross section of the switching shaft (1) in Area whose contact surfaces (3) is triangular and the leaf spring legs are legs (6, 7) of a leaf spring (5) which is pivotably mounted in the web area and bent in a known manner in a U-shape.