CH701421A2 - mechanical oscillator. - Google Patents

Abstract

The present invention, which relates to the field of horology, relates to a mechanical oscillator oscillating about a pivotless oscillation axis, said oscillator comprising: a serge (18) centered on the axis of oscillation and mounted on a first attachment portion (32) located on said oscillation axis; - a fixing portion (10) intended to be fixed to a frame of a watch movement; - a plurality of elastic systems connecting the serge and the fixing portion. According to the invention, at least some of the elastic systems are suspended and are free with reference to said frame.

Description

Technical area

The present invention relates to the field of mechanical watchmaking. It relates, more particularly, to a mechanical oscillator oscillating about a pivotless oscillation axis. Such an oscillator comprises: a serge centered on the axis of oscillation and mounted on a first attachment portion located on said oscillation axis, a fixing portion intended to be fixed to a frame of a clockwork movement, a plurality of elastic systems connecting the serge and the fixing portion.

State of the art

In mechanical watches, the energy for the operation of the movement is provided, conventionally, by a spring that is armed. It gradually releases its energy, thanks to an escapement mechanism, regulated by a mechanical oscillator. In the most common watch mechanisms, the oscillator is a balance-spring, well known to those skilled in the art. The sprung balance is provided with pivots cooperating with bearings. For the regularity of the oscillation and limit the amount of energy that the sprung balance must receive for its oscillations are maintained, it is easy to understand that the friction conditions at the pivots of the sprung balance must be optimal. Significant efforts have been made to improve the quality of bearings or lubrication.

EP1 736 838 discloses a pivotless oscillator. The latter comprises a body, centered on the oscillation axis of the oscillator, this body being connected to the frame of the movement by four U-shaped springs, deforming during the oscillation. This system, particularly interesting in the reduction of friction, since it has no pivot, however, is limited in its applications. Indeed, it is particularly adapted to the escape mechanism described in the corresponding document, which operates at a high frequency, but with a limited amplitude of oscillations. In fact, it can not be applied to a conventional escapement, of Swiss anchor type, for example.

The present invention aims to provide a mechanical oscillator without pivot, enjoying the advantages of the oscillator in reducing friction, but free from its disadvantages and adaptable to a conventional exhaust.

Disclosure of the invention

More specifically, the invention relates to an oscillator as defined in the claims. Brief description of the drawings

Other features of the present invention will appear more clearly on reading the description which follows, with reference to the accompanying drawing, in which: <tb> - fig. 1 and FIG. 2 <sep> are respectively perspective and side views of a first embodiment of an oscillator according to the invention, <tb> - fig. 3 <sep> is a perspective view of a second embodiment, and <tb> - fig. 4 <sep> provides a top view of an oscillator control system according to the invention, with a close-up view.

Mode (s) of realization of the invention

[0007] FIG. 1an oscillator according to the invention, intended to be mounted in a clock movement not shown. For attachment to the frame of the movement, the oscillator comprises a fixing portion 10, which may consist of a plate 12 provided with at least two holes 14 for receiving fixing screws. The use of a plate 12 is interesting because it provides a good stability to the oscillator, which is not connected to the frame by point areas. The fixing portion 10 may further have flanks 16 straight and parallel to cooperate with guide walls of a housing formed in the frame and intended to receive the fixing portion. In this case, the orifices 14 may be in the form of oblongs oriented parallel to these flanks 16. Thus, the longitudinal position of the fastening portion 10 with reference to the housing can be adjusted to adjust the position of the oscillator. The person skilled in the art will of course be able to adapt other systems for adjusting the position of the fastening portion 10, either in the plane or at the height, possibly by means of micrometer screws or the like.

The oscillator comprises a truncated or annular serge 18, acting as a conventional balance beam. The center of the serge 18 defines the oscillation axis of the oscillator. In its center, the serge 18 is arranged so that it can be mounted on a fastening portion to be connected to the other elements of the oscillator, as will be described later. According to the example illustrated in the drawing, the serge 18 comprises an opening 20, centered on the axis of oscillation, inside which is rigidly placed a fastening portion of the neighboring element of the oscillator.

The serge 18 is ideally made of a high density material, such as gold or platinum, but it can also be made of a brass-like material, usually used to make rockers. The serge 18 carries, at its central portion, a finger, for example silicon, or a ruby ellipse, acting as a plateau pin of a conventional balance wheel and schematically represented under the reference 19 - on the FIG. 2. This ellipse or finger is arranged projecting parallel to the axis of oscillation and is intended to cooperate with the anchor or with a release pallet of the escape mechanism of the movement.

The serge 18 is connected to the fixing portion 10 by a series of return members. Each return member is formed of a pair of resilient blades 22 consisting of a first and a second blades located in the same plane perpendicular to the axis of oscillation. The blades 22 of a pair are connected, by a first of their ends, to an intermediate attachment portion 24 located on the axis of oscillation. The second end of the resilient blades 22 is connected to a suspended frame 26 which is coplanar with the blades that it connects. The blades 22 of a pair define between them an angle of between 45 and 120 °, typically between 60 and 105 °, typically close to 90 °.

The frame 26 is preferably circular in shape, concentric with the axis of oscillation. The blades 22 of a pair are then located on the spokes of the circle defined by the frame. All the elastic blades therefore have the same length.

In a first embodiment shown in FIGS. 1 and 2, return members are assembled two by two, being rigidly connected only by their frame 26. In other words, two return members are superimposed, at least partially, which defines an upper return member and a control member. lower recall, with reference to the drawing, with the serge 18 which is located on the lower side. In the example, two return members are entirely superimposed. The frames 26 are fixed to each other, for example by an intermediate frame 28, maintaining a distance between them so that the blades 22 of the two return members do not touch. The intermediate attachment portions 24 of the return members whose frames are connected, are free one with reference to the other. They are not directly related to each other. In the present description, it is considered that the assembly formed by two return members connected to each other by their frame, is called an elastic system.

Several elastic systems can thus be assembled to one another, through the intermediate attachment portions 24 of the first and second return members. The intermediate attachment portion 24 of an upper return member of a first elastic system may be rigidly connected to the intermediate attachment portion 24 of a lower return member of a second elastic system. The connection may advantageously be via a spacer 30 so as to prevent the elastic blades of two return members touching.

Similarly, the intermediate attachment portion 24 of a lower biasing member of the first elastic system can be rigidly connected to the intermediate fastening portion 24 of an upper biasing member of a third elastic system.

In the example shown, there are only two elastic systems regularly distributed around the axis of oscillation. Thus, the intermediate attachment portion 24 of the lower return member of the first elastic system is connected to the serge 18, as mentioned above. A spacer forming a first attachment portion 32, ensures that the serge 18 or the arms holding the serge does not rub against the elastic blades 22. The spacer connects the intermediate attachment portion 24 of the lower return member and is inserted rigidly into the opening 20 of the serge 18.

The intermediate attachment portion 24 of the upper return member of the second elastic system is connected to the fixing portion 10. The latter is provided with two elastic blades 34, similar to those of a return member and meeting in a last attachment portion 36 centered on the axis of oscillation. A spacer 30 ensuring that the elastic blades of the fixing portion do not rub against the elastic blades of the return member, rigidly connects the intermediate attachment portion 24 of the upper return member and the last attachment portion 36.

The return members are preferably made of silicon by deep etching from a wafer, which allows to realize monolithically the frame 26, the blades 22 and the intermediate attachment portion 24. D Other materials may be envisaged, including polycrystalline synthetic diamond. In the case of silicon parts, their surface can be oxidized so as to stabilize the natural frequency of the system in temperature and a better handling stability.

The set of elastic blades 22 and 34 is arranged and calculated in such a way that all the degrees of freedom of the serge 18 are minimized, with the exception of the oscillation around the axis of oscillation. Thus, all the degrees of freedom of the serge are rigid, that is to say greater, compared to the degree of freedom around the axis of oscillation. The angular stiffness of the oscillator around this axis is calculated so as to ensure a frequency determined at the oscillator. There is therefore no spring-spiral. During the oscillations, the elastic blades are deformed but, thanks to the fact that the frames 26 of the return members are free and that they are assembled two by two, they move radially with reference to the axis, but without disturbing or move the attachment portions 24 remaining on the oscillation axis.

Depending on the space available in the movement and the proximity of the other elements of the movement, the different elastic systems are rigid enough to prevent that, in case of shocks, parts of the oscillator come into collision with other parts of the movement or so, limitation stops are provided to avoid these collisions that could damage the fragile parts, silicon.

In a second embodiment proposed in FIG. 3, the return members of an elastic system are not entirely superimposed. Nevertheless, they are preferably located equidistant from the center of oscillation and all the blades 22 have the same length. Only part of their frame 26 is superimposed to allow their joining. The attachment portion is not shown for reasons of clarity of the drawing.

A possible option is shown in FIG. 4. A system of prestressing in compression or traction of the blades of a return member is proposed, such a system being able to be implemented either at the level of each return member or at the level of each elastic system. By exerting a tensile pretension on the blades 22, the angular rigidity of the blades is reduced, and exerting a prestress in compression on the blades 22, the angular rigidity of the blades is increased, which makes it possible to adjust the natural frequency of the system and play the role of a raquetterie (to adjust the average time and therefore the running of the watch).

As shown in FIG. 4, can be made on the wall of the frame or frames 26, optionally on the intermediate frame 28, a fastener 38 at several positions, for example having a toothing. A spring system 40 having a point of attachment on the center of oscillation has at its other end an attachment member 42 capable of cooperating with the fastening member 38. For example, the attachment member 42 is obtained by one or two teeth 44 shaped to cooperate with the toothing. The toothing of the fastener member may be elastically movable to allow adjustment of the position of the fastening member 42 in the toothing. The spring system 40 is arranged so as to exert on the frame 26 a tensile or compressive stress of the blades 22. Other adjustment systems may be envisaged, but this is advantageous because the elements can be made directly, from monolithic way, during the engraving of the return organs.

Note that for an annular serge, the heavy periphery, made of a metallic material, can be connected to the fastening portion for a silicon bond coming integrally with the fastening portion. This makes it possible to accentuate the distribution of the mass outside.

Thus is proposed an oscillator having no friction or wear and does not require lubrication. The amplitudes of the flat and the hanged are equalized, because of the absence of pivot. Such an oscillator can be adapted to escapements and conventional movements, thanks to the amplitudes and frequencies reached. Typically, the amplitude is 100 ° (remember that, for the skilled person, the amplitude is defined in each direction relative to the center line). In addition, since there is no pivot, the oscillator is not held by a balance bridge covering the axis of oscillation. The oscillator can be fully visible from the outside of the movement. Finally, the series setting of the return members increases the number of elastic blades involved in the design of the oscillator, which reduces their stiffness for given characteristics of the oscillator.

Claims (15)

A mechanical oscillator oscillating about a pivotless oscillation axis, said oscillator comprising: a serge (18) centered on the axis of oscillation and mounted on a first attachment portion (32) located on said axis of oscillation, a fixing portion (10) intended to be fixed to a frame of a clockwork movement, a plurality of elastic systems connecting the serge and the fixing portion, characterized in that at least some of the elastic systems are suspended and are free with reference to said frame. 2. Mechanical oscillator according to claim 1 characterized in that said fixing portion is provided with two resilient blades (34), located in the same plane perpendicular to the axis of oscillation and connected in a last attachment portion (36). ) located on said oscillation axis. 3. Mechanical oscillator according to claim 2, characterized in that it comprises an even number of return members comprising: a pair of resilient blades (22) consisting of a first and a second blade located in the same plane perpendicular to the axis of oscillation and connected at one end to an intermediate attachment portion; (24) located on said oscillation axis, and - A frame (26) suspended connected to the blades of a pair by their second end, said frame being coplanar with the blades that it connects, and in that a lower return member and an upper return member are rigidly connected in pairs only by their frame (26) suspended to form a first elastic system, the intermediate attachment portion of the lower return member being connected to the intermediate attachment portion of an upper return member of a second elastic system or to the first attachment portion, the intermediate attachment portion of the upper return member being connected to the portion of attaching a lower biasing member of a third resilient system or the last attachment portion. 4. Oscillator according to claim 3, characterized in that it comprises a plurality of elastic systems evenly distributed around the axis of oscillation. 5. Oscillator according to one of claims 3 and 4, characterized in that all the elastic blades are of the same length. 6. Oscillator according to claim 3, characterized in that said frames (26) suspended are concentric with the axis of oscillation. 7. Oscillator according to one of claims 3 to 6, characterized in that the first and second return members of an elastic system are superimposed. 8. Oscillator according to one of claims 3 to 6, characterized in that the first and second return members of an elastic system are angularly offset. 9. Oscillator according to one of claims 3 to 6, characterized in that the return members are made of silicon. 10. Oscillator according to claim 9, characterized in that the silicon is covered with an oxide layer. 11. Oscillator according to one of claims 3 to 10, characterized in that the return members are made of polycrystalline synthetic diamond. 12. Oscillator according to one of claims 3 to 11, characterized in that it comprises at least one preload system in tension or in compression of the blades of a return member. 13. Oscillator according to claim 12, characterized in that the prestressing system is monolithic with the return member. Oscillator according to one of Claims 11 to 13, characterized in that the prestressing system comprises: an attachment member (38) at several positions in connection with a frame of the return member, - A spring system (40) having a point of attachment on the center of oscillation and having at its other end an attachment member (42) capable of cooperating with the fastening member and to occupy several different positions in reference to the fastener. 15. Oscillator according to one of the preceding claims, characterized in that the serge comprises a projecting member, parallel to the axis of oscillation, to cooperate with an exhaust mechanism.