DE1833072U - FINE MECHANICAL SPRING LOCK. - Google Patents

Description

Precision mechanical spring locking mechanism.

In addition to ratchet and ball or rolling element locks are used in precision engineering often also Federrichtgesperre used, in which the entrainment by a wrapping Spring is accomplished. However, such Federrichtgesperre have a relatively large overall length and a lot of dead play.

A shortening of the overall length is achieved in a known manner by that in a cylindrical pin, which is wrapped by a clock spring, a circular keyway is cut into which a single turn of the spring is located nestles under pretension, while its free end is led away radially outward is. This well-known locking mechanism ensures despite the short overall axial length safe and play-free transport. It needs to spin in the freewheeling direction However, due to the friction caused by the preload, a force is required, which is not always permissible for watches.

The task of the innovation is to protect a spring alignment lock, which not only works with as little play as possible, but above all in the release direction only requires a small amount of force to spin.

For this purpose, it is proposed according to the innovation that the directional lock through two nested, cylindrical bodies and one wrapped between them, on one side with the inner one Cylinder body connected via the Length to form on the outer cylinder body from the inside abutting spring.

Details of the innovation can be found in the description below of an embodiment shown in the drawings.

Fig. 1 shows a Federrichtgesperre according to the innovation according to a Section I-I in Fig. 2.

Fig. 2 shows a section through the lock according to 11-11 in Fig. 1.

As Fig. 2 illustrates, is on a shaft 1, which has a spring core 2 for a clockwork spring 3, on one side a socket 4, on the other Side a hollow shaft 5 loosely rotatably mounted. With the hollow shaft 5 is a spring 3 receiving barrel 6 connected. On the socket 4 are a gear 7 and a cylindrical disc 8 attached.

As can be seen from FIG. 1, the disk 8 has a slot 9 on. A gear wheel 10 is attached to the shaft 1 adjacent to the spring core 2, which is provided with a cylindrical recess 11 in the rear Part 12 is stabbing. In the undercut part 12 of the gear 10 is a spring wire 13, which is not or only slightly preanced, with about two to three turns inserted. One end 14 is angled radially inward and protrudes into the Slot 9 of the disc 8, which dips so far into the recess 12 of the gear wheel 10, that at least the first turn of the spring 13 is supported or placed on it can. The outside diameter of the disc 8 and the inside diameter of the undercut Part 12 are dimensioned so that after inserting the spring wire 13 between this and the disc 8 almost no slack, i. H. a gap of only a few tenths Millimeters remains.

With reference to Fig. 1, it can be seen that in the rest position the spring wire 13 lies snugly in the recess 12 from the inside. Will the disc 8 rotated clockwise, the tension of the spring 13 is released and the Wire 13, which is detected by the slot 9 at the angled end 14, about one half a turn wound onto the disc 8, the rest sliding in the recess 12 followed. However, if the disk 8 is rotated counterclockwise, so the slot 9 presses on the wire end 14. The spring wire 13 presses over his entire length from the inside against the recess 12 and takes the gear 10 frictionally with. The recess 12 is so wide that so many turns of the spring wire 13 just have space next to each other, as required to transfer the force are. The optimum was about two for the object according to the exemplary embodiment up to three spring coils determined. If the number of turns is greater, it will also be more Force required to spin in the freewheeling direction * If the number of turns is smaller, so the force mentioned is also smaller, but so is the reverse rotation braking. The dead game is kept low above all that between the disc 8 and the recess 12 is just so much distance that the beginning of the spring 13 has space to swivel from the disc 8 to the recess 12 or vice versa, however, no room for radial or axial evasion.

The Federrichtgesperre described has the advantage that it completely works noiselessly, has a short return path, little power to spin in the freewheeling direction is required and is simple and inexpensive to manufacture.

Claims (6)

S c h u t z ans p r ü ehe. 1. Precision mechanical spring alignment lock, especially between two coaxial members of a clock, characterized in that daajßichtgesperre through two immersed, cylindrical bodies (8, 10) and one between them, in particular wrapped in a recess (12) of the outer body (10) on one side with the inner cylinder body (8) connected over its length on the outer cylinder body (10) or its recess (12) is formed from the inside resting spring (13). 2. locking mechanism according to claim 1, characterized in that the inner The cylinder body (8) is designed as a disc which has a slot (9), into which a radially inwardly projecting end (14) of the spring (13) can be inserted. 3. locking mechanism according to claim 1 and 2, characterized in that as Locking spring a spring wire (13) is used, the windings of which in the recess (12) are wrapped next to each other. 4. locking mechanism according to claim 1, characterized in that that the spring wire (13) is not or only slightly pre-curved. 5. locking mechanism according to claim 1, characterized in that the outer diameter of the inner body (8) so to the inner diameter of the outer body (10) or its recess (12) is dimensioned that the spring (13) only very little, i. h, a few tenths of a millimeter has radial play. 6. locking mechanism according to claim 1 to 5e, characterized in that the Spring (13) has about two to three turns and the width of the recess as follows is dimensioned so that the turns have no lateral play. 7 * locking mechanism according to claim 1 to 6, characterized in that the Inner body (8) dips so deep into the outer body (10) that when turning in the freewheeling direction Place at least the first turn of the spring (13) on the inner body (8) can.