DE1027142B - Clock with oscillating mass winding - Google Patents

Description

Clock with oscillating mass winding The storage of the oscillating mass of a clock self-winding poses a delicate problem in any case where a flat watch and the greatest possible distance between the vibration mass bearings is desirable i, st.

It is already known to mass for itself by means of special bridges to store, between an upper and a lower. Bridge, a construction which has been simplified by omitting the lower bridge and adding a The bearing embedded in the bridge of the minute wheel has been replaced. But it doesn't have any these arrangements allowed the distance between the bearings of the oscillating mass to enlarge to a significant extent.

The invention fulfills this purpose in that with a clock with automatic lift by an oscillating mass, the lower bearing of the same., which rotates in the center of the work, lies on a shaft, which is in a bore of the hollow shaft of the minute wheel extends into it, in which a Camp lies.

This solution allows the distance between the bearings in one to enlarge significant dimensions, and also gives this storage because of the length of the shaft an additional elasticity, which to some extent as a shock-absorbing Establishment works.

The drawing shows four exemplary embodiments of the subject matter of the invention, wherein each figure represents an axial section through the axis of rotation of the oscillating mass.

In the first embodiment according to FIG. 1, the upper bridge is used 1 for receiving the upper bearing 2 of the oscillating mass 3, which carries the scratch] 4.

The lower bearing 5 of the mass is on the shaft 6, the length of which is at least four times its diameter.

This shaft is with the common shaft 7 of the pinion 8 and the Minute wheel 9 coaxially and lies in the provided in said shaft, axial Hole 10.

The crack] 8 is driven by the barrel 11.

In 12 is the one that acts as the lower bearing of the minute wheel Work plate, the minute wheel bridge 13 of which forms the upper bearing.

As ersichtli, ch, is the lower bearing 5 of the mass 3 in the Shaft 7 drilled. Hole 10 practically at the height of the work plate 12.

The distance between bearings 2 and 5 is thus compared to that what has been achieved so far is very great.

Learned in the figures relating to the three other embodiments parts 1 to 4 and 8 to 13 no changes: they are therefore not given reference numerals Mistake.

In the second. Embodiment according to FIG. 2 consists of the lower bearing the mass instead of a thickening of a thinner pin 14, which is in a introduced into the bore 10 of the minute wheel, bearing shell 15 is located.

This solution is advantageous because, ß the axial play of the? Mass is limited by the two bearing shells 15 and 16, the latter being the usual bearing shell is.

In the example according to the first embodiment of FIG. 1, this was the case Play through the latter bearing on the one hand, and through the upper part on the other the shaft 7 of the minute wheel is limited, which is a less clever solution.

In the third embodiment according to FIG. 3, one is used in the shaft the minute wheel introduced sleeve 17 at the same time as the upper bearing of the same and as the lower bearing of the shaft journal 18 of the mass.

To this end, the bottom of this sleeve is pierced to make the lower one Shank end to serve as a bearing, while the upper edge of the sleeve from the wheel shaft protrudes and turns in the minute wheel bridge 13.

As can be seen, this solution allows the bearing diameter to enlarge something. It also limits the axial play to the play between the upper bearing 16 and the floor. of the sleeve 17. The fourth embodiment 4 provides, similar to the first embodiment of FIG. 1, that the storage between an upper bearing 2, which rotates in an upper bearing shell 16, and a The lower bearing consists of a rotating in. The hollow shaft 7 of the minute wheel Thickening is formed.

Here, however, this thickening consists of a sleeve 19, which with the Shaft 20 is connected and rotates. The connection is through a socket 21 at the end of the shaft.

In the embodiments according to FIGS. 2 to 4, the added Bearing parts 15, 17 and 19 made of metal or another material, that differs from that of the other parts of the work. There can be stones in particular Find application.

As can be seen in all the examples shown and described the distance between the two bearings of the mass is great without making the clock higher fails.

Claims (7)

PATENT CLAIMS: 1. Self-winding watch in which the oscillating weight pin connected to the oscillating weight is mounted coaxially with the minute shaft in a bridge at the top and in the clockwork at the bottom, characterized in that the pin (6) in a bore (10) of the minute shaft (7) protrudes. 2. Self-winding watch according to claim 1, characterized in that the oscillating weight pin (6) has play protrudes into the bore (7) and only to a depth which is at least four times corresponds to its diameter, is stored in the bore. 3. Self-winding watch according to claim 2, characterized in that the mounting of the oscillating mass journal (6) is at the level of the lower bearing (12) of the minute shaft (Fig. 1, 2, 4). 4th Bearing for the oscillating weight pin. the self-winding watch according to claim 2 or 3, characterized by a thickening (5) at its lower end (Fig. 1). 5. Storage according to claim 4, characterized in that the thickening (19) consists of another Material exists as the pin (20 in Fig. 4). 6. Bearing for the oscillating weight pin the self-winding watch according to claim 2 or 3, characterized in that in the bore (10) a bearing bush (15) is arranged (Fig. 2). 7. Storage according to claim 6, characterized in that the bearing bush in the bottom, one pushed into the bore Sleeve (17) is formed with its upper end as a journal of the minute shaft serves. Considered publications: Deutsche Patentschrift \ r.834074; Swiss Patents \ 7r. 164 587, 244 882, 279 956.