CH705461A1 - Control device for a timepiece. - Google Patents

Abstract

The present invention relates to a control device for a timepiece, comprising a control lever (1) adapted to occupy a first rest position and, on actuation of a control member, a second actuating position, the device comprising a spring (3) for defining a threshold value for the necessary actuating force on said control member so that the control lever (1) moves from its first position to its second position, the control lever (1 ) comprising a projecting element (2) cooperating with said spring (3), and said projecting element (2) comprising at least a first guide means adapted to cooperate with at least a second guide means (3.1.1.1) mounted on a fixed structure of the timepiece. The present invention also relates to a timepiece comprising such a device.

Description

The present invention relates to a control device for a timepiece, comprising a control lever adapted to occupy a first rest position and, on actuation of a push button or other control member, a second actuating position, the device comprising a spring for defining a threshold value for the necessary actuating force on said push button so that the control lever moves from its first position to its second position.

This kind of device is known in principle, for example EP 0 240 778 or EP 0 498 212, and is intended to provide a dynamic spring for use in combination with a pusher or other control device similar. In general, a dynamic spring makes it possible to define a certain threshold value for the force needed to overcome its lifting and thus to trigger the command. Once the dynamic spring is lifted, the available force pushes the control to the end of the function without additional effort. By thus ensuring a complete function of the control, such a dynamic spring makes it possible to provide a pusher or other control device with a high level of security with regard to its activation or even non-activation.

The solutions of the prior art currently known are, on the one hand, quite specific because of their intended application and therefore have, at least in part, a fairly complex structure. On the other hand, the mere fact of providing a dynamic spring is not enough to best prevent a malfunction of the control device, which also includes other parts whose structure or cooperation may lead to problems during the operation of the order.

There is always the need to have a control device of the aforementioned kind whose construction is relatively uncomplicated and the operation is safe with respect to several aspects. In particular, apart from the need to make the use of the control devices safer in the sense, on the one hand, to prevent a pusher from being inadvertently actuated by an action not exceeding the threshold required by a control device. dynamic spring and, on the other hand, to ensure complete actuation when the pusher is actuated, it is desirable to use in control devices of the aforementioned kind elements whose structure and their cooperation are as simple as possible, of way to avoid at best deformations or even fractures of parts or other difficulties during the operation of the order. These objectives should be completed while guaranteeing moderate production costs as well as offering attractive aesthetics, for example for use in skeleton watches.

The object of the present invention is therefore to overcome the disadvantages of known devices and achieve the above advantages, in particular to allow the realization of a control device, equipped with a dynamic spring, which is simple in its design and reliable during its operation, without increasing the complexity, the volume occupied or the production costs of the device.

For this purpose, the present invention provides a control device of the aforementioned type, in particular for a mechanical timepiece, which is distinguished by the features set forth in claim 1, and a corresponding timepiece comprising a such device. In particular, in a device according to the present invention, the control lever comprises a projecting element cooperating with said spring, said projecting element comprising on its circumference at least a first guide means adapted to cooperate with at least one second guide means mounted on a fixed structure of the timepiece.

In the preferred embodiment of the device according to the present invention, the projecting element is formed by a pin, the first guide means is formed by a groove arranged on the circumference of this pin of the control lever, and the second guide means is formed by a guide portion arranged on said spring which is mounted on the frame of the timepiece, at least said guide portion of the spring being housed in the groove.

By these measures, because the spring is still present in the groove of the pin and therefore serves as a guide rail for the control lever, we obtain a maintenance of the control lever, which leads to a particularly safe and reliable operation of this kind of device.

In preferred embodiments, the groove and / or the spring are arranged in a specific manner, leading to other corresponding advantages. Thus, the control device may for example be arranged to be ideally suited for use in combination with either a flip-flop or a monostable push-button.

Other features, as well as the corresponding advantages, will become apparent from the dependent claims, as well as from the description which sets forth the invention in more detail.

The accompanying drawings show schematically and by way of example an embodiment of the invention. <tb> Fig. 1a <sep> shows a schematic perspective view of a control device according to the present invention, mounted on the frame of a timepiece; <tb> fig. 1b <sep> is a top view of the device illustrated in FIG. 1a; <tb> fig. 1c <sep> shows a section through the device along the line A-A shown in FIG. 1b; <tb> fig. 1d <sep> shows an enlargement of zone B around the pin indicated in fig. 1b, some parts being illustrated in transparency for a better understanding; <tb> fig. 1e <sep> shows schematically and by way of example a top view of the shape of a dynamic spring used in the control device according to the present invention. <tb> Figs. 2a to 2c <sep> show schematically, from above views, the operation of a control device according to the present invention which is particularly suitable for use in combination with a flip-flop, this in three steps during its operation, ie when the device is in its rest position, in its intermediate position, and in its actuated position. <tb> Figs. 3a to 3c <sep> show schematically, with top views similar to FIGS. 2a to 2c, the operation of a control device according to the present invention which is particularly suitable for use in combination with a monostable pushbutton, this in its three stages during its operation. <tb> Fig. 4 <sep> schematically shows, by a cross-section similar to Fig.1c, an alternative embodiment having an inverted arrangement at the groove and the guide member, a flange being provided on the pin, while a groove is arranged on a bridge of the frame.

The invention will now be described in detail with reference to the accompanying drawings illustrating by way of example two embodiments of the invention.

A control device according to the present invention is intended to be integrated into a timepiece, preferably in a mechanical watch, especially in a wristwatch. As will become clearer later, the control device may for example be connected to a flip-flop or a monostable pusher of the timepiece, or to any other such control mechanism, regardless of the function controlled by the device and the type of the timepiece.

As schematically illustrated and by way of example in the perspective view of FIG. 1a, the control device comprises a control lever 1 adapted to occupy a first rest position and, upon actuation of a push button or other control element not shown, a second actuating position. The control lever 1 is normally pivotally mounted about an axis 1.1 on the frame 4 of the watch, which is not illustrated in detail in the figures because not important for the present invention. The device also comprises a dynamic spring 3 generally of the type mentioned in the introduction which makes it possible to define a threshold value for the necessary actuating force on said pushbutton so that the control lever 1 moves from its first position to its first position. second position. As mentioned above, the term "push button" is used in this context in the sense that this piece makes it possible to transmit a force coming from the user of the watch to the control lever 1, independently of the fact that it is indeed a single push button, so monostable, or a push button integrated into a bistable flip-flop. In addition, instead of a push button, the control lever 1 can also be controlled by other types of control members of a timepiece, for example by a crown or a wheel.

FIG. 1a also shows that the control lever 1 comprises a pin 2 or another element such as a pin, this pin 2 or this post is normally mounted integrally on the lever 1. The pin 2 could also be mounted so as to be free in rotation about its axis in the control lever 1, to reduce the friction forces with the other parts of the device with which it is in cooperation. Indeed, the pin 2 cooperates with said dynamic spring 3, said pin 2 comprising for this purpose on its lateral circumference at least one groove 2.1 in which at least a portion of the spring 3 is housed. This arrangement is also visible in FIGS. 1b and 1illustrating a top view of the device, respectively a section through the device along the line A-A shown in fig.1b. The circumferential groove 2.1 of the pin 2 and the housing of the spring 3 in this groove 2.1 are particularly clearly visible in FIG. 1d showing an enlargement of the zone B around the pin 2 indicated in FIG. 1b, some parts being illustrated in transparency in FIG. 1d for a better understanding of the structure of the device.

Preferably, the groove 2.1 arranged on the circumference of the pin 2 of the control lever 1 has a height corresponding substantially to the height of said spring 3. In addition, the groove 2.1 arranged on the circumference of the pin 2 of the lever 1 is preferably located in a range of 40% to 150% of the width of the part of the spring 3 intended to be housed in the groove 2.1, in particular of the free part of said spring 3, without this being necessary. is necessary for the arrangement of the device. Thus, the groove 2.1 defines an inner diameter Di of the pin 2, as indicated symbolically in FIG. 1 C. It is not necessary that the groove 2.1 be circular, it could occupy only part of the circumference of the pin, for example laterally on both sides of the pin 2, where the spring 3 must be housed when its cooperation with the pin 2. It is also conceivable that the groove 2.1 is formed only on one side of the pin 2, for example in front of a single portion of the spring 3, preferably and for reasons which will become clear later in the description that which is attached to the frame 4 of the watch.

In order to continue the description of the structure of the device according to the present invention and as visible in the top view of FIG. 1 illustrates schematically and by way of example the shape of a dynamic spring used in this control device, it should be noted that the spring 3 comprises, according to this preferred embodiment, a first portion 3.1 substantially U-shaped. This first U-shaped part 3.1 has a fixed end 3.1.1 which is adjacent to a second portion 3.2 of the spring, the latter being fixed to the timepiece, for example to the frame 4, so that the fixed end 3.1.1 can be seen as being integral with the frame 4. The other end 3.1.2 of the first portion 3.1 U-shaped is free. As schematically illustrated in FIG. 1d showing an enlargement of the area around the pin 2 and the fixed ends 3.1.1 and free 3.1.2 of the spring 3, the distance between the tip of the free end 3.1.2 and the fixed end 3.1.1 is in the rest position of the spring 3 or the control device respectively, less than the inner diameter Di of the pin 2 at its groove 2.1, so that a predefined force is necessary to move the free end 3.1. 2 of the fixed end 3.1.1. The threshold value of this force can be chosen, apart from varying the internal diameter Di of the pin 2, by varying the shape and / or the dimensions of the spring 3, for example by varying the distance between the tip of its end free 3.1.2 and its fixed end 3.1.1, the thickness of the leaf spring or its length, and its height.

It is also visible in FIGS. 1det 1eque the free end 3.1.2 of the spring 3 has a substantially L-shaped tip whose base 3.1.2.1 is oriented outwardly of the U-shape of the spring 3 and forms a stop that presses, in the position resting spring 3, at the groove 2.1 of the pin 2, that is to say on its inner circumference. The angle between the base 3.1.2.1 and the arm of the free end 3.1.2 of the spring 3 is a functional part of the dynamic spring and is another parameter for influencing the threshold value of this spring. On the other side of the pin 2, the fixed end 3.1.1 of the spring 3 comprises at its tip a guide portion 3.1.1.1 having a substantially straight shape which supports, in the rest position of the spring 3, also at the the groove 2.1 of the pin 2. In a preferred embodiment of the device, said guide portion 3.1.1.1 is arranged concentrically with respect to the pivot axis 1.1 of the control lever 1, such as schematically indicated in FIG. 1b using the radius R and best visible at the magnification of FIG. 1d. In this way, the cooperation between the guiding portion 3.1.1.1 of the fixed end 3.1.1 of the spring 3 and the groove 2.1 of the pin 2 optimally achieves, during the pivoting of this lever 1, a guiding of the pin 2 respectively of the lever 1. The guide portion 3.1.1.1 of the fixed end 3.1.1 is preferably, but not necessarily, followed by a curved portion 3.1.1.2 which is adapted to receive said pin 2 in the position d actuation of the spring 3. If in the preferred embodiment of the device this curved portion 3.1.1.2 only serves to stabilize the fixed end 3.1.1 of the spring 3, in particular to reinforce said guide portion 3.1.1.1 , the curved part 3.1.1.2 could also serve as a stop for the control lever 1; in the preferred embodiment, this stop lever is made by other means not illustrated because not important for the present invention. In this way, the base 3.1.2.1 of the L-shaped tip of the free end 3.1.2 and the guide portion 3.1.1.1 of the fixed end 3.1.1 form, in the rest position of the spring 3 , substantially V pressing, at the groove 2.1 of the pin 2, two opposite sides on the inner diameter D of the pin 2, which is apparent in FIG. 1det 1st.

It remains to be noted that, depending on the combination of the control device according to the present invention is with a flip-flop or with a monostable push button or with another type of control member, the free end 3.1 .2 of the spring 3 can be arranged differently. In particular, for cooperation with a flip-flop, the free end 3.1.2 of the spring 3 may have a length and / or a geometrical shape chosen so that the distance between the tip of the free end 3.1.2 and the fixed end 3.1.1, in the actuated position of the spring 3, is smaller than the internal diameter Di of the pin 2 at its groove 2.1 and that the axis of the pin 2 is, in this position, on the other side of the tip of the free end 3.1.2 relative to the rest position of the spring 3, so that the control device has two stable positions. Conversely, for one embodiment of the device adapted for cooperation with a monostable pushbutton, the free end 3.1.2 of the spring 3 should have a length and / or a geometric shape chosen so that the distance between the tip of the free end 3.1.2 and the fixed end 3.1.1, in the actuating position of the spring 3, is less than or substantially equal to the internal diameter Di of the pin 2 at its groove 2.1 so that the pin 2 is preloaded to return to its rest position, so that the control device has a single stable position. Alternatively, these characteristics can be realized, instead of varying the length of the free end 3.1.2, giving a corresponding geometric shape to the free end 3.1.2. For example, it is easily understandable by comparing figs. 2aet 3a varying the angle between the base 3.1.2.1 and the arm of the free end 3.1.2 of the spring 3, adding for example a linear part 3.1.2.2 being, in the rest position of the lever 1, substantially parallel to the guide portion 3.1.1.1, a dynamic spring is particularly suitable for use in cooperation with a monostable pushbutton. The linear part 3.1.2.2 defines in effect with the guide portion 3.1.1.1 a path for the pin 2, the two walls are, in the rest position of the spring 3, substantially parallel. These walls can then form, following their separation in the actuating position of the spring and as it will become clearer thereafter, a predefined angle so as to exert a prestressing force on the pin 2 which pushes it back to its position rest. The functional shape of the tip of the free end 3.1.2 of the spring 3 is indeed not only a parameter for selecting the threshold value of this spring, but also allows to adapt the spring according to its intended use. Other corresponding embodiments of a dynamic spring 3 according to the present invention are, without it being possible to describe them all in detail, within the reach of those skilled in the art having the technical instruction according to the invention. this description.

Having available the detailed description above of the preferred embodiment of the control device according to the present invention, it is also clear to the skilled person that there are also several alternatives with respect to relates to the cooperation between the groove 2.1 arranged, in said preferred embodiment described above, on the pin 2 and the guiding portion 3.1.1.1 which is in this case secured to the fixed portion 3.1.1 of the spring 3 mounted on the frame 4. A first non-illustrated alternative to this configuration may for example consist in that the guide portion 3.1.1.1 which acts as a guide element on the fixed frame side is replaced by another element that is, is mounted on the frame, or is made of a part with the latter, as a correspondingly shaped projecting portion of a bridge mounted on the frame. If the arrangement of the other parts of the watch would require it, another alternative not illustrated in the figures may consist in mounting such a bridge having a guide element replacing said guide portion 3.1.1.1 on the other side of the pin 2 relative to the fixed part 3.1.1 of the spring, therefore for example the side of the free portion 3.1.2 of said spring 3. Finally, and as schematically illustrated in FIG. 4, it is also possible to invert the arrangement at the groove and the guide element, that is to say to provide a guide element such as a flange 2.2 on the pin 2, while a groove 4.1, or even only a support at the top or bottom for this kind of collar, is arranged on the side of the bridge respectively of the frame 4, whether of one, the other, or both sides of the pin 2. In addition, the flange 2.2, or in the configuration opposite the groove 2.1, on the pin 2 may be at a different height than the spring 3, provided that it is arranged at the same height as the groove 4.1 respectively corresponding guide element 3.1.1.1, on the bridge or the frame 4, so as to separate the two dynamic spring functions and guide the lever by different structural elements. The groove 2.1 and the guide portion 3.1.1.1 mentioned in the context of the preferred embodiment described above first are therefore generally to be considered as first and second guide means which can be arranged according to the needs side pin 2, that is to say on the lever side 1, or spring side 3, that is to say on the frame side 4, to allow cooperation carrying out the guidance of the control lever 1. As mentioned above, these means In the preferred embodiment, the dynamic spring and lever guide functions are advantageously achieved by combining the structural means for these functions.

In view of the detailed description of the structure of a device according to the present invention above, the operation of the device is easily understandable with the help of Figs. 2a to 2c schematically illustrating, in plan views, three steps during its operation, namely when the device is in its rest position, in an intermediate position, and in its actuating position, this for a use of the control device in combination with a flip-flop. The operation of the device is described with reference to the preferred embodiment described above first, but this description is also valid analogically for the aforementioned alternatives. Fig. 2a corresponds to the rest position of the spring 3 respectively of the control lever 1, or even of the entire device, already illustrated for example in FIGS. 1a, 1c, and 1d. As mentioned above, in this position, the base 3.1.2.1 of the free end 3.1.2 forming a stop abuts on one side at the groove 2.1 of the pin 2. On the other side of the pin 2, it is the guide portion 3.1.1.1 of the fixed end 3.1.1 of the spring 3 which bears at the level of the groove 2.1 of the pin 2, so that the predefined force for the spacing of the two ends 3.1.1, 3.1.2 is necessary from the user of the corresponding watch in order to switch the control lever 1 to the intermediate position illustrated in FIG. 2b. In this position, said predefined force has been provided by the user actuating the push button, leading to the spacing of the free end 3.1.2 of the fixed end 3.1.1, so that the distance between the tip of the free end 3.1.2 and the fixed end 3.1.1 is equal to the inner diameter Di of the pin 2 at its groove 2.1. The lifting of the dynamic spring 3 being performed in this intermediate position, the force supplied by the user of the watch then makes it possible to push the control until the end of the function without additional effort, that is to say to guarantee completion of the actuating position illustrated in FIG. 2c. The pin 2 is in this position received by the curved portion 3.1.1.2 of the fixed end 3.1.1. As has already been mentioned briefly above, the distance between the tip of the free end 3.1.2 and the fixed end 3.1.1 is in this operating position of the spring 3 again lower than the inner diameter Di pin 2 at its groove 2.1, and the axis of the pin 2 is, in this position, on the other side of the tip of the free end 3.1.2 relative to the rest position of the spring 3. It is therefore necessary to provide a new preset force for spacing the two fixed ends 3.1.1 and free 3.1.2 in this position to return the pin 2 or the control lever 1 in its position of rest. In this way, it is possible to provide a control device which has two stable positions and which is therefore particularly suitable for use in combination with a flip-flop type control.

As regards the embodiment of the control device according to the present invention described above which is particularly suitable for use in combination with a pushbutton-type control monostable, FIG. 3c shows schematically, in a view from above, the operation of a corresponding control device in its third step, namely when the device is in its actuating position. Indeed, while the first - and second stages of its operation illustrated in FIGS. 3a and 3b are similar to what has been said with respect to FIGS. 2a and 2b above, FIG. 3c shows that, in the actuating position of this embodiment of the device, the distance between the tip of the free end 3.1.2 and the fixed end 3.1.1 may be less than or substantially equal to the inner diameter Di pin 2 at its groove 2.1 because of the presence of the linear part 3.1.2.2 mentioned above. As a result of their spacing, the linear part 3.1.2.2 of the tip of the free end 3.1.2 and the guiding part 3.1.1.1 of the fixed end 3.1.1 of the spring 3 form, in fact, in the position of actuating the spring 3 of this embodiment, substantially a V, but with a smaller angle relative to the V formed in the rest position by the base 3.1.2.1 and the guide portion 3.1.1.1. Even in the actuating position, the pin 2 is prestressed by the guiding portion 3.1.1.1 and the linear part 3.1.2.2 to return to its rest position. In this embodiment, it is therefore not necessary to separate again the two fixed ends 3.1.1 and free 3.1.2 of the spring 3, or even to provide a new force to return the pin 2, even the control lever 1 in its rest position, so that the device automatically returns to its rest position as soon as the user no longer presses the push button. In this way, this control device has only one stable position and is therefore particularly suitable for use in combination with a push button type monostable control.

It should be noted that in the preferred embodiment and during all the steps of operation of this device, the relevant parts 3.1.1.1, 3.1.2.1 of the fixed ends 3.1.1 and free 3.1.2 of the spring 3 are always in the groove 2.1 of the pin 2. The spring 3, in particular the guide portion 3.1.1.1 of the fixed end 3.1.1 of the spring 3 which is fixed to the frame 4 of the timepiece, but also the free end 3.1.2, therefore serves as a guiding structure for the control lever 1. Since the direction of movement of the control lever 1 is, in general in this kind of control devices as in the present case, often perpendicular to the longitudinal axis of said lever 1, which can lead to deformation or even fractures of this part or other parts cooperating with the lever 1 during its actuation, the arrangement according to the technical instruction of this i nvention provides a maintenance height and in the transverse direction relative to the longitudinal axis of the control lever 1. Advantageously, one thus obtains a holding of the control lever 1 in two directions substantially perpendicular in space, the third direction of space not being critical in this respect. This optimally avoids any deformation or fracture of the control lever and ensures a particularly safe and reliable operation of this kind of control device. These advantages are achieved analogically in the other alternative embodiments mentioned above, either by having separate or combined structural means for dynamic spring functions and lever guidance.

At the same time, the dynamic spring 3 of a particular form according to the present invention makes it possible to perform the function known in principle in the prior art that the corresponding push button requires a predefined threshold value of the force of support to lead to the actuation of the corresponding function, this by a relatively simple design of said spring 3. In addition, the choice of the geometric shape, dimensions, and / or spacing of the two arms of the spring 3 allows vary this threshold value. Likewise, the choice of the length of the spring arm 3 providing its free end or its geometrical shape, in particular parts 3.1.2.1 and 3.1.2.2 of the free end 3.1.2 makes it possible to adapt the control device to use either with a monostable pushbutton or with a flip-flop.

While being relatively simple structure and little complex compared to the prior art and keeping a small footprint, the device can then be declined in many variants and allows flexible use. Indeed, it is clear that a control device comprising the features mentioned above has the important advantage of being able to cooperate in a conventional manner with the other parts of the timepiece in which it is intended to be integrated, in particular with its basic movement, so that the mechanism can easily be integrated into existing timepieces without requiring too much adjustment or even a major revision of the design of these parts. Moreover, because of the relatively simple structure of the device, these advantages are obtained without increasing the volume occupied, or even the production costs of the device respectively of the watch equipped with such a control device, as well as offering an attractive aesthetic for integration into skeleton watches in view of the framed structure of the device. Preferably, the mechanism is integrated into a chronograph watch, but it can also be used in other watches having functions which are preferably controlled by push buttons of the kind mentioned above. Finally, it remains to note that the control device according to the present invention can be integrated into any kind of timepiece, whether mechanical or electronic, preferably in wristwatches.

Claims (16)

1. Control device for a timepiece, comprising a control lever (1) adapted to occupy a first rest position and, on actuation of a control member, a second actuating position, the device comprising a spring (3) for defining a threshold value for the necessary actuating force on said control member so that the control lever (1) moves from its first position to its second position, characterized by the fact that the control lever (1) comprises a projecting element (2) cooperating with said spring (3), said projecting element (2) comprising at least a first guiding means (2.1) able to cooperate with at least one second guiding means (3.1.1.1 ) mounted on a fixed structure (4) of the timepiece. 2. Device according to the preceding claim, characterized in that the projecting element is formed by a pin (2), and that the first guide means is formed by a groove (2.1) arranged on the circumference of the pin (2). ) of the control lever (1), the second guide means being formed by a guide portion (3.1.1.1) arranged on the spring (3) mounted to the frame (4) of the timepiece, at least said portion guide (3.1.1.1) of the spring (3) being housed in the groove (2.1). 3. Device according to the preceding claim, characterized in that the groove (2.1) arranged on the circumference of the pin (2) of the control lever (1) has a height substantially corresponding to the height of said spring (3). 4. Device according to one of the preceding claims 2 to 3, characterized in that the groove (2.1) arranged on the circumference of the pin (2) of the control lever (1) has a depth within a range of 40. % to 150% of the width of said at least a portion of said spring (3) intended to be housed in the groove (2.1), so as to define an inside diameter (DI) of the pin (2). 5. Device according to the preceding claim, characterized in that the groove (2.1) is circular or arranged on one or both sides of the pin (2). 6. Device according to one of the preceding claims 2 to 5, characterized in that the spring (3) comprises a first portion (3.1) substantially U-shaped having a fixed end (3.1.1) is adjacent to a second part (3.2) of the spring which is fixed to the frame (4) of the timepiece, and the other end (3.1.2) of which is free, the distance between the tip of the free end (3.1.2) and the fixed end (3.1.1) being, in the rest position of the spring (3), less than the inside diameter (DI) of the pin (2) at its groove (2.1). 7. Device according to the preceding claim, characterized in that the free end (3.1.2) of the spring (3) has a substantially L-shaped tip whose base (3.1.2.1) forms a stop and supports, in the rest position of the spring (3) at the groove (2.1) of the pin (2) on its inner circumference. 8. Device according to one of the preceding claims 6 to 7, characterized in that the fixed end (3.1.1) of the spring (3) comprises at its tip said guide portion (3.1.1.1) followed by a curved portion (3.1.1.2) adapted to receive said pin (2). 9. Device according to the preceding claims 7 and 8, characterized in that the base (3.1.2.1) of the L-shaped tip of the free end (3.1.2) and the guide portion (3.1.1.1) of the fixed end (3.1.1) form, in the rest position of the spring (3), substantially a V pressing at the groove (2.1) of the pin (2) of two sides on its inner diameter (DI ). 10. Device according to one of the preceding claims 2 to 9, characterized in that the guide portion (3.1.1.1) arranged on the spring (3) is concentric with respect to the pivot axis (1.1) of the lever control (1). 11. Device according to one of the preceding claims 6 to 10, characterized in that the free end (3.1.2) of the spring (3) has a length and / or a geometric shape chosen so that the distance between the tip of the free end (3.1.2) and the fixed end (3.1.1), in the actuating position of the spring (3), is less than the inside diameter (DI) of the pin (2) at its groove (2.1) and that the axis of the pin (2) is on the other side of the tip of the free end (3.1.2) relative to the rest position of the spring (3), so that the control device has two stable positions. 12. Device according to one of the preceding claims 6 to 10, characterized in that the free end (3.1.2) of the spring (3) has a length and / or a geometric shape chosen so that the distance between the tip of the free end (3.1.2) and the fixed end (3.1.1), in the actuating position of the spring (3), is less than or substantially equal to the inside diameter (DI) of the pin (2) at its groove (2.1) so that the pin (2) is preloaded to return to its rest position, so that the control device has a single stable position. 13. Timepiece, characterized in that it comprises a control device according to one of the preceding claims. 14. Timepiece according to the preceding claim, characterized in that it is a mechanical watch, including a wristwatch. 15. Timepiece according to one of the preceding claims 13 or 14 and claim 11, characterized in that the control device is connected to a flip-flop. 16. Timepiece according to one of the preceding claims 13 or 14 and claim 12, characterized in that the control device is connected to a monostable pusher.