DE2025073A1 - Mechanical rotary resonator for timing devices - Google Patents

Description

11 May 1970

Additional patent to main patent no. (Patent application P1773671.9-52) Fabriques Movado, La Chaux-de-Fonds (Switzerland)

Mechanical rotary resonator for timing devices

The main patent relates to a rotary resonator with at least a cantilevered mass around an axis of symmetry can perform a torsional vibration, characterized in that the mass is mounted on its carrier by means of several springs, whose active part between a first connection to the mass and a second connection to the carrier part-cylindrical shape with surface lines running parallel to the axis of oscillation of the resonator and maintains this property in the course of the elastic deformation caused by the torsional vibration, wherein the length and width dimensions of the active spring part in the cylindrical surface, while the thickness of the springs are transverse to it and that the developed length of the active part of each

009850/1468

■ "2 - ~

the spring is larger than the distance between its ends.

In practice, the active part of the springs can be turned into
Split straight or nearly straight sections that are connected to one another by strongly curved sections (hairpins). The curved active sections suffer from two major disadvantages, namely:

a) It is very difficult or impossible to do them with great mechanical Establish accuracy.

b) They bring about an unavoidable inhomogeneity in cold stretching of the material, which affects the elastic properties the spring has a detrimental effect.

The present invention is based on the idea of replacing the strongly curved active spring parts mentioned by connecting parts that are related to those caused by the vibration
Stresses have great rigidity, such that
these connecting parts practically do not participate in the elastic deformation of the system. The resonator according to the invention is characterized in that its elastic system has springs which are constructed from straight active sections, which sections are measured against the stresses occurring
very stiff connecting parts are connected to one another in such a way that the effective length of the sections mentioned is precisely defined, with only these sections being subjected to the elastic deformation due to the oscillation of precisely defined lengths
are.

The drawing shows two exemplary embodiments of the inventive Resonator, only the parts necessary for understanding are shown.

009850 / U66

Fig. Γ shows a flat blank for producing a Spring of the first type, before bending,

Fig. 2 is a view of the bent spring looking perpendicular to the plane of vibration,

Fig. 3 is a view of the bent spring in the viewing direction parallel to the plane of vibration and

FIGS. 4 to 6 are representations of a second embodiment corresponding to FIGS. 1 to 3.

The spring blank shown in FIG. 1 has three straight sections 1 to 3 which will form the active spring parts the. The intermediate connecting parts are denoted by 4 and 5, while the connecting parts provided at the spring ends are denoted by 6 and 7 are designated. The tongue 8 is intended for the attachment of a pawl, which serves to control the oscillating movement of the spring to be transformed into a rotary movement by acting on a ratchet wheel in a manner known per se.

Figures 2 and 3 are two views of the spring bent along the dashed lines in Fig. 1, all bends being made at right angles with the exception of the bending point on the tongue Λ 8, the angle of which must be adapted to the conditions of the research device. In FIG. 2, the straight active sections 1, 2 and 3 that have arisen can be seen parallel to one another, while in FIG. 3 they partially overlap.

The connecting parts 4 and 5 are for the stresses resulting from the vibration due to the adjacent pairs Stiffened bending points. As FIG. 3 in particular shows, in the present case these bending points are opposite to the plane of vibration inclined at 45 °. This gives the bending points a tendency

009850 / U66

the connecting parts 4 and 5 also have an increased rigidity against Interference stresses that act at right angles to the plane of vibration,

in]
what is not the connecting parts lying in the vibration plane

would be the case.

The connection points 5 and 6 provided at the spring ends are intended to enable the spring to be soldered in place. To this end are these connecting parts are bent into the plane of oscillation, resulting in tangential soldering with practically no static preloads the spring allows what good time-keeping properties of the spring matters.

Fig. 4 shows the second embodiment of the spring in a flat, unbent condition. This spring has three straight sections 9, 10 and 11 which will form the active parts of the bent spring. The intermediate connecting parts are numbered 12 and 13, the connecting parts denoted by 14 and 15 at the spring ends. The tongue 16 is used to attach a pawl in the manner mentioned above and for the same purpose.

5 and 6 show the bent spring from two different directions, with all bending points being at right angles with Except for those of the tongue 16.

The connecting parts 12 and .13 lie in the plane of oscillation so that they can withstand the stresses caused by the oscillation Oppose maximum resistance.

The connecting parts 14 and 15 are used to solder the spring ends. They are in the oscillation plane and thus allow soldering in place in the advantageous manner mentioned above.

As can be seen from the main patent, the complete resonator eight springs of the type described above, namely four for each of the two masses of the resonator. , 0 0 ^ 9850 / U 66

Claims (6)

■■■ · ■■ ■ - 5 ■ - ■ ..: .. ■ ■. ■■■; ■■. ■ ·. ■ :: '■■: V: "■ Claims; \ (l) j Mechanical rotary resonator for a timepiece, according to the main patent, characterized in that its elastic system has springs which are made up of straight active sections (1-3, 9-11), which sections are very stiff when measured against the stresses occurring Connecting parts (4, 5; 12, 13) are connected to one another in such a way that the effective length of the sections mentioned (1-3, 9-11) is precisely defined, with only these sections of precisely defined length of elastic J see deformation are subject to vibration. 2) resonator according to claim 1, characterized in that each of the said springs consists of a suitably bent Stamped part consists. 3) resonator according to claim 2, characterized in that the connecting parts (4, 5) inclined with respect to the plane of vibration are in such a way that they are stiff both for the stresses caused by the oscillation and for stresses acting at right angles to the plane of oscillation. ^ j 4) resonator according to claim 3, characterized in that the connecting parts (4, 5) with respect to the plane of vibration are inclined. 5) resonator according to claim 2, characterized in that the connecting parts (12, 13) lie in the plane of vibration to oppose the stresses caused by the vibration with maximum resistance. 6) resonator according to claim 2, characterized in that the connecting parts (6, 7; 14, 15) provided at the spring ends, 0098 50 / U66 which serve to solder the spring »in one to the plane of vibration parallel plane to allow a flat soldering without static preload of the spring. 009850 / U66 re Blank page