EP2233989A1 - Hairspring and its index-assembly - Google Patents

Abstract

The hairspring (10) has an end fixed to a balance-spring stud (14), and an interior end fixed to a collet (12), where the hairspring is made of monocrystalline silicon/diamond and obtained by a deep etching process. The silicon is covered with an oxide/diamond layer. An exterior coil of the hairspring is terminated at an end fixed to the stud. The coil has a portion divided into two strips (16) that define an oblong opening (18). A radius of curvature of the strips is equal to that of the coil. The opening receives an adjustment unit (20) whose position is movable with respect to the opening.

Description

Technical area

The present invention relates to a spiral spring obtained by deep etching, a first inner end is associated with a ferrule and whose outer turn ends in a second end associated with a stud. The invention also relates to an assembly consisting of a spiral spring and its racking.

State of the art

In clocks, clocks and mechanical or electronic watches, there is always a regulating member allowing, as its name indicates, to regulate the running of the timepiece. In the case of a mechanical watch, the regulating member consists of a balance and a spiral spring.

These two elements play a fundamental role in the setting of the watch, which is the technique that allows the watchmaker to ensure that the watch indicates at all times the most accurate time. To do this, it is necessary to adjust the oscillation period of the balance spring by acting, traditionally, either on the inertia of the balance, or on the pair of the spiral and its inner and outer connection. The action on the inertia of the pendulum is long and delicate. It is reserved for high-end parts, equipped with a balance with inertial adjustment.

It is more commonly used on the spiral. This one is a blade, generally metallic, of rectangular section wound on itself in the form of Archimedean spiral. It is fixed at its center on the balance shaft, by a part called ferrule. The outside of the hairspring is attached to a pendulum bridge, called rooster, by a piece called piton. The piton is attached either directly to the cock or via a mobile peg holder. A system called racket or raquet, allows to adjust the counting point, that is to say to adjust the active length of the spiral. The counting point is defined by two points of support, arranged with frolicking on both sides of the hairspring. These supports are obtained by two pins, or a pin and a key, and can rotate at a certain angle to change the actual position of the counting point and thus to change the torque of the hairspring.

A peg carrier may be provided to rotate the entire balance-spring to locate it so that when the pendulum is stopped, the plateau pin is on the line of anchor-balance centers.

Silicon or silicon coated silicon spirals have recently been developed in order to improve the behavior of the regulating organ and to facilitate the production of these spirals and to have perfect reproducibility of their characteristics. However, the adjustment of the regulating member is generally done via an adjustable inertia beam.

The present invention therefore aims to provide an improved and simplified adjustment system for silicon-based spirals, taking advantage in particular of the ease of shaping silicon-based spirals, by modern etching techniques.

Disclosure of the invention

More specifically, the invention relates to a spiral spring obtained by deep etching, a first inner end is associated with a ferrule and whose outer turn ends in a second end associated with a stud. According to the invention, the outer coil of the spiral comprises a portion divided into two blades, said blades defining between them an oblong opening, having a radius of curvature substantially equal to that of the last turn, said opening being intended to receive a body of setting whose position is movable with reference to the opening.

The invention also relates to an assembly consisting of such a spiral spring and a single adjustment member arranged on a support movable concentrically to the last turn, inside the opening defined by the two blades.

Brief description of the drawings

Other features of the present invention will appear more clearly on reading the description which follows, made with reference to annexed drawing, in which the Figures 1 to 4 show, in plan view, schematic views of different embodiments according to the invention.

Mode (s) of realization of the invention

The figure 1 represents a flat spiral spring 10, made of silicon. It comprises a first inner end associated with a ferrule 12. Typically, as allowed by the shaping techniques of the silicon type materials, the ferrule 12 is made in one piece with the rest of the spiral. The outer turn ends in a second end conventionally associated with a peak 14, shown schematically.

Over most of its length, the hairspring 10 is made in a single strand.
Particularly to the invention, the last turn comprises a portion divided into two blades 16. The blades 16 are arranged symmetrically with reference to the virtual curve that would have followed the last turn of a conventional hairspring, at rest, this virtual curve being represented in dotted line. The blades 16 thus define between them an oblong opening 18 and each have a radius of curvature substantially equal to that of the last turn. As will be seen below, this opening 18 is intended to receive a control member 20 whose position is movable with reference to the opening.

In the embodiment of the figure 1 the two blades are relatively thin, that is to say that they are flexible and participate in the elastic behavior of the spiral 10, so that they have a non-zero influence in the determination of the elastic torque of the spiral. To fix ideas, the width of the blades is less than or equal to the width of the strand forming the turns.

Note that the last turn may comprise a second portion, comprising first and second strands 22, but one of the strands is located on the normal curve of the hairspring, the other strand being positioned substantially parallel and being connected with rigidly by connecting beams 24 to the first strand. This arrangement makes it possible to reduce the center of action of the spiral in correspondence with the center of the balance associated with the spiral, in order to correct the spiral of its non-concentric development.

Another important aspect of the invention relates to a device for adjusting the frequency of the sprung balance, comparable to a conventional racking. The adjustment member 20, typically made by means of a pin, is mounted on a support not shown, so as to take place inside the opening 18 defined by the two blades. The support is rotatably mounted, centered on the balance shaft, concentrically at the last turn.

In the embodiment of the figure 1 , the adjusting member 20 is formed by means of a cylindrical pin, whose diameter d is smaller than the distance e between the two blades 16. The pin is located substantially in the middle of the two blades, so that, when the hairspring is at rest, there is a substantially equal play between the pin and each of the blades 16.

Thus, by angularly moving the pin inside the opening 18, the actual position of the counting point is modified, which makes it possible to adjust the frequency of the balance-spring.

In the embodiment shown on the figure 2 , the blades 16 of the spiral 10 are relatively thick, that is to say they are stiffer than the strand forming the remainder of the spiral and do not participate in the elastic behavior of the spiral, so they have not no influence in the determination of the elastic torque of the spiral. To fix ideas, the width of the blades 16 is at least greater than the width of the strand forming the turns. The end of the hairspring 10, located between the portion comprising the two blades 16 and the pin 14, is flexible. An adjusting member 20 similar to that described with respect to the embodiment of the figure 1 is disposed inside the opening 18.

In this case, the circular displacement of the adjusting member 20 inside the opening 18, will act on the amplitude of the variations that can present the arrow of the second end of the spiral, embedded in the peak 14. Indeed, it flexes like a recessed beam and it is understood that in the embodiment of the figure 2 , the parameter on which will act the position of the adjusting member 20 will be the bending angle that can present the end of the spiral embedded in the peak 14, during In fact, the counting point is fixed and is located at the beginning of the portion with two blades 16, since these are rigid.

The Figures 3 and 4 illustrate two other embodiments of the adjusting member 20, may be used with either a spiral whose two blades 16 are rigid, or with a spiral whose two blades 16 are flexible. For example, the figure 3 offers 16 rigid blades, while the figure 4 proposes flexible blades 16.

In the embodiment of the figure 3 , in addition to having the mobile mounted support as described above, the adjusting member 20 is pivotally mounted on the support. It is made by means of a pin, of oblong shape, symmetrical with respect to its axis of pivoting. The largest dimension of the pin is smaller than the distance e between the two blades. Thus, when the pin pivots, the clearance between the adjusting member 20 and each of the blades 16 is varied. An identical result can be obtained with a cylindrical pin mounted eccentrically.

The embodiment of the figure 4 is similar to that of the figure 3 , except that the adjusting member 20 is larger in its greater dimension than the distance e between the two blades 16. Thus, by rotating the adjustment member on the support, it is possible to vary the clearance between the adjustment member 20 and each of the blades 16, possibly until you eliminate any play and obtain a blockage. When the clearance between the pin and the blades 16 is eliminated, a single recess is obtained, like what can be achieved with an adjustable inertia beam, the position of this recess point can be adjusted. Note that, to lock the hairspring by means of the adjusting member, there may be provided a special tool for holding the two blades in place during the actuation of the pin.

The present description has been given by way of non-limiting illustration of the invention and the person skilled in the art can also provide various alternatives directly from the description given above, without departing from the scope defined by the claims. . It should nevertheless be noted that the support carrying the adjustment member may be associated with a graduation allowing locate the angular position of the pin in the opening, with reference to the center of the hairspring. It is also possible, for the embodiments providing for the pin to be pivotally mounted on the support, to provide a mark for visualizing the angular position of the pin relative to the support. With these marks, it is thus possible to quantify the adjustment made. Note also that the two blades can be located at the second end of the spiral, and be directly associated with the peak. Finally, the invention can be applied generally to all the spirals made in conformable materials by deep etching techniques, particularly to silicon-based spirals, in particular monocrystalline silicon, optionally covered with an oxide layer. silicon, but also to spirals made of diamond, obtained by growth then by deep etching, or to spirals made in DCS (English Diamond Coated Silicon), that is to say silicon spirals covered diamond.

Claims (15)

Spiral spring (10) obtained by deep engraving, a first inner end of which is associated with a ferrule (12) and whose outer turn terminates in a second end associated with a stud (14),
characterized in that the outer coil of the spiral comprises a portion divided into two blades (16), said blades defining between them an oblong opening (18) having a radius of curvature substantially equal to that of the last turn, said opening being intended to receive an adjusting member whose position is movable with reference to the opening. Spring according to claim 2, characterized in that said blades (16) meet before the second end, so that the spiral has a single strand to cooperate with the peak. Spiral spring according to one of claims 1 and 2, characterized in that said blades (16) are stiffer than the turns of the remainder of the spiral. Spiral spring according to one of claims 1 and 2, characterized in that said blades (16) are flexible and participate in the determination of the elastic torque of the spiral. Spiral spring according to one of claims 1 to 4, characterized in that the blades (16) are arranged symmetrically with reference to the virtual curve of the last turn, at rest. Spiral spring according to one of claims 1 to 5, characterized in that it is made of monocrystalline silicon. Spiral spring according to one of claims 1 to 5, characterized in that it is made of monocrystalline silicon coated with an oxide layer. Spiral spring according to one of claims 1 to 5, characterized in that it is made of silicon coated with a diamond layer. Spiral spring according to one of Claims 1 to 5, characterized in that it is made of diamond. Assembly comprising a spiral spring (10) according to one of claims 1 to 9 and a single adjusting member (20) arranged on a support movable concentrically to the last turn, inside the opening (18) defined by both blades. Assembly according to claim 10, characterized in that the adjusting member (20) is fixed on the support and in that said adjustment member is substantially located in the middle of the two blades (16). An assembly according to claim 10, wherein the blades are spaced from each other by a distance e , characterized in that the adjusting member (20) is, in its largest dimension, smaller than e , and in that it is pivotally mounted on the support so as to vary the clearance between the adjustment member and each of the blades (16). An assembly according to claim 12, characterized in that the adjusting member (20) is eccentrically mounted. Assembly according to claim 12, characterized in that the adjusting member (20) is oblong and is symmetrical with respect to its pivot axis. An assembly according to claim 10, wherein the blades (16) are spaced from each other by a distance e , characterized in that the adjusting member (20) is larger in its larger dimension e , and in that it is pivotally mounted on the support so as to vary the clearance between the adjustment member and each of the blades, possibly to eliminate any play.

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