CH717182B1 - Timepiece movement comprising a mechanical oscillator and a device for stopping said oscillator. - Google Patents

Abstract

The invention relates to a timepiece movement comprising a mechanical oscillator (1) comprising a balance wheel (3) provided with a rim (4) and an elastic member (2), and a device for stopping said oscillator comprising a stopping element (14) and an actuating member (16) of said stopping element (14). The serge (4) comprises, on its peripheral edge, a stopping protuberance (8) ending in at least one cutout (10, 12) in the serge (4) revealing at least one stopping wall (4a, 4b ) forming a stop and positioned so as to form with the line of centers (L) an angle α substantially equal to the stationary amplitude. In addition, the stopping element (14) is arranged to move between an inactive position without contact with the serge (4), an initial active position in which, after activation by the actuating member (16), it is capable of coming into contact with the stopping protuberance (8), and a final active position in which it abuts against the stopping wall (4a, 4b) of the serge (4) and stops the balance wheel (3). The stopping protuberance (8) has a geometry chosen so that the force (F) resulting from the action of the stopping element (14) on the stopping protuberance (8) is such that the moment exerted by the stop element (14) on the oscillator (1), from the initial active position of the stop element (14) in contact with the stop projection (8) to the final active position of the stopping element (14), is non-zero and of constant sign so as to bring back and maintain the serge (4) in abutment against the stopping element (14).

Description

[0001] The present invention relates to a timepiece movement comprising a mechanical oscillator comprising a balance wheel and an elastic member, and a device for stopping said oscillator comprising a stopping element and a member for actuating said element. stop.

[0002] Such a device for stopping an oscillator, sometimes called a "stop-balance", may be necessary to stop the oscillation of the balance of a mechanical watch to set the time of the second hand in it. positioning at 12 o'clock, from the control stem of the watch, in order to restart the movement at a precise moment, indicated for example by a time signal.

[0003] A device for stopping an oscillator may also be necessary to stop the oscillation of a balance wheel dedicated to a chronograph. Such a pendulum only starts moving when timing is carried out and must be stopped once the measurement has been carried out.

[0004] The balance stop devices traditionally used include a stop lever controlled by the time setting position of the rod or by pressure on a STOP pusher to come to bear against the rim or against the balance axis in order to stop it. Another solution, as described in US patent 2,212,535, proposes using several balance screws distributed on the rim and directed outwards like stops arranged to cooperate with a pin provided at the end of a lever. stop when said stop lever is actuated.

The disadvantage of such devices is that the angular position of stopping of the oscillator by the stopping lever is random. There is in particular a risk that the pendulum is stopped while the elastic member has zero potential energy, so that the pendulum will not be able to restart. If the pendulum is stopped while the elastic member has a non-zero potential energy, this energy will be different depending on the angular position of the pendulum when it stops. As a result, the amplitude of the pendulum when it restarts will vary so that the resumption of movement will not be precise.

[0006] A solution was proposed by US patent 3,733,805 which consists of providing on the periphery of the rim of the balance, at least one serrated portion consisting of a series of concave indentations alternating with convex protuberances, said serrated portion being positioned on the rim so that the balance is stopped in an angular position different from the neutral position to which it is returned by the hairspring. Each serrated portion extends over an angular sector of 30° to 90°, the indentations and protuberances being rounded so that when a flexible spring wire mounted at the end of a lever cooperates with said serrated portion to stop the balance, said spring wire passes over several protuberances before stopping the balance. Thus the constraints due to a sudden stop are avoided. However, even if this solution makes it possible to not stop the balance in the position in which the elastic member has zero potential energy due to the positioning of the serrated portion, the angular position of stopping of the balance by the spring wire is random. , the spring wire passing over a random number of protuberances before the balance stops. The amplitude of the balance when restarting will vary, leading to inaccuracy when restarting, which is not acceptable, particularly when the balance is dedicated to a chronograph, supposed to measure time with great precision.

[0007] Another solution was proposed by application EP 2 221 678 which consists of providing a heart-shaped cam secured to an axis of a balance wheel associated with a spiral spring and a lever in the form of a hammer, which when activated, comes to rest on the heart to block the pendulum. The heart is positioned so as to cause the balance to stop in a determined angular position for which the spiral spring has a non-zero potential energy.

[0008] This solution has the disadvantage of necessarily requiring an additional component which constitutes the core. In addition, this construction lacks compactness because it requires a certain height in order to be able to position the heart on the axis of the balance wheel as well as a large hammer which must pass under the oscillator to be able to reach the heart.

[0009] The present invention aims to remedy these drawbacks by proposing a device for stopping an oscillator making it possible to stop the oscillator in a predetermined angular position to guarantee rapid and precise resumption of operation.

[0010] The present invention also aims to provide a device for stopping an oscillator making it possible to stop said oscillator in a position with non-zero potential energy allowing immediate self-starting.

[0011] For this purpose, the present invention relates to a timepiece movement comprising a mechanical oscillator comprising a balance wheel and an elastic member, and a device for stopping said oscillator comprising a stopping element and an actuating member of said stopping element.

[0012] According to the invention, the stopping device comprises a blocking element integral in rotation with the balance and having, on its peripheral edge, a stopping protrusion ending in at least one cutout in said blocking element revealing at minus a stopping wall forming a stop and positioned so as to form with the line of centers an angle α substantially equal to the stationary amplitude. Furthermore, the stopping element is arranged to move between an inactive position without contact with the blocking element, an initial active position in which, after activation by the actuating member, it is able to come into contact of the stopping protuberance, an intermediate active position in which it slides on the stopping protuberance and a final active position in which, engaged in the cutting, it abuts against the stopping wall of the blocking element and stops the pendulum. In addition, the stopping protuberance has a geometry chosen so that the force resulting from the action of the stopping element on the stopping protuberance is such that the moment exerted by the stopping element on the blocking element, from the initial active position of the stopping element in contact with the stopping protuberance to the final active position of the stopping element, is non-zero and of constant sign so as to reduce and maintaining the blocking element abutting against the stopping element.

[0013] Thus the oscillator stopping device makes it possible to guarantee the stopping of the oscillator always in the same predetermined ideal angular position, at non-zero potential energy, and to guarantee, at each stop, a precise and precise restart. immediately to its steady state, with a stabilized amplitude.

[0014] The stationary amplitude is between 10° and 160°, preferably between 20° and 45°, the angle α being equal to the stationary amplitude ± 10%.

[0015] According to a first embodiment, the balance wheel is provided with a rim, said rim constituting the blocking element, the elastic member being able to be a system of elastic blades or a spiral spring.

[0016] According to a second embodiment, the movement comprises an escapement mechanism comprising a plate secured to the balance wheel, said plate constituting the blocking element, the elastic member being a spiral spring.

[0017] Other characteristics and advantages of the present invention will appear on reading the following detailed description of different embodiments of the invention, given by way of non-limiting examples, and made with reference to the appended drawings in which : – Figures 1 to 4 show an oscillator and a stopping device according to a first embodiment of the invention, the stopping element being respectively in the inactive position, in the initial active position, in the intermediate active position, and in final active position; and – Figure 5 shows an oscillator and a blocking element of a stopping device according to a second embodiment of the invention.

[0018] With reference to Figures 1 to 4, a first embodiment of the invention is shown, according to which the mechanical oscillator 1 of a watch movement comprises a balance wheel 3 provided with a rim 4, of general shape circular, said serge constituting the locking element integral in rotation of the balance. Furthermore, according to a first variant, said mechanical oscillator 1 is a flexible pivot oscillator 1 comprising as elastic return member a system of elastic blades, and designed to pivot without a physical axis of rotation around a virtual axis of rotation.

The mechanical oscillator with flexible pivot 1 comprises a fixing part 2 and a movable part which surrounds the fixing part 2, which, in operation, oscillates relative to the fixing part 2 and thus plays the role of the pendulum 3. The fixing part 2 is used to mount the oscillator 1 on a support such as a plate or an escapement member, for example an anchor, of a watch movement. The fixing part 2 and the balance 3 are connected by elastic blades 5, 6 of the same length which cross without contact by extending in two different parallel planes. In plan view from above, these elastic blades 5, 6 intersect at a point P which constitutes the center of rotation of the balance 3 relative to the fixing part 2. The straight line passing through the point P and perpendicular to the plane of the oscillator 1 (plane of Figure 1) constitutes the axis of rotation of the balance 3 relative to the fixing part 2, and therefore the axis of rotation of the blocking element. The elastic blades 5, 6 exert on the balance 3, relative to the fixing part 2, a restoring torque like the balance spring of a balance-spring oscillator. Oscillator 1 is associated with an escapement (not shown) which can be of a classic type such as a Swiss lever escapement or of any other type.

[0020] Such an oscillator can be manufactured monolithicly, for example in silicon or in any other suitable material using the deep reactive ion etching technique known as “DRIE” (Deep Reactive Ion Etching), in nickel, nickel alloy or any other suitable material according to the LIGA technique (lithography, electroplating, casting), in steel, beryllium copper, nickel silver or other metallic alloy by milling or electroerosion, or in metallic glass by casting.

[0021] Such a mechanical oscillator with flexible pivot 1 is described in application WO 2017/055983 and does not require a more detailed description here.

[0022] There is also provided a device for stopping the oscillator, comprising a stopping element 14 as well as a manual actuation member 16 of said stopping element 14 arranged to control said stopping element 14.

[0023] According to the invention, said stopping device comprises a blocking element integral in rotation with the balance 3, constituted here by the rim 4, which comprises, on its external peripheral edge, a single and unique stopping protuberance 8 terminated by at least one cutout 10 or 12 in the blocking element constituted here by the serge 4 revealing at least one stopping wall 4a or 4b forming a stop.

The stopping protuberance 8 has a profile (shape seen from the front) comprising a vertex 8a facing the outside of the blocking element and at least one side 8b or 8c extending from the vertex 8a, said side 8b or 8c being terminated by the cutout 10 or 12 in the blocking element, here constituted by the serge 4, revealing at least one stopping wall 4a or 4b.

[0025] In a preferred embodiment of the invention, the stopping protrusion 8 has a profile (front view shape) comprising a (single) vertex 8a facing the outside of the serge 4 and two sides 8b, 8c extending on either side of the top 8a, each side 8b, 8c being terminated respectively by the cutout 10, 12 in the blocking element constituted here by the serge 4, said cutout 10, 12 revealing respectively, facing said corresponding side 8b, 8c, the stopping wall 4a, 4b arranged to form a stop, as will be described below.

[0026] Thus, for a serge whose external peripheral edge has a radius R, the vertex 8a of the stopping protuberance 8 has a radius preferably equal to R and the sides 8b, 8c of the stopping protuberance 8, at the level of the cutout 10, 12 have a radius less than R.

Preferably, the stopping protuberance 8 is made monolithic with the rest of the serge 4.

[0028] It is obvious that in another embodiment of the invention not shown, the stop protuberance 8 can be configured so as to have a profile comprising only one side 8b or 8c extending from the top 8a and a single corresponding cutout 10 or 12 in the serge revealing, facing said side 8b or 8c, a single corresponding stopping wall 4a or 4b forming a stop. The vertex 8a is then positioned between the line of centers and the stopping wall.

[0029] Advantageously, the stopping wall 4a, 4b is positioned on the blocking element so as to form, between the center line L (line connecting the centers of the balance and the anchor) and the straight line passing through the outer vertex of the stopping wall 4a, 4b and the axis of rotation of the blocking element, an angle α substantially equal to the predefined stationary amplitude of the oscillator. In the present description, the stationary amplitude is defined as the angle corresponding to the predetermined amplitude allowing the oscillator to resume operation at its stationary regime immediately.

[0030] The stationary amplitude is advantageously between 10° and 160°, preferably between 15° and 100°, more preferably between 20° and 45°, in particular when the oscillator has a flexible pivot, and more preferably between 25° and 30°, the angle α being equal to the stationary amplitude ± 10%. The stationary amplitude is less than or equal to the maximum amplitude of the oscillator, which is preferably less than 180°, preferably less than or equal to 110°, more preferably less than or equal to 50° and more preferably less than or equal at 30°.

[0031] Furthermore, in accordance with the invention, the stopping element 14 is arranged to move between an inactive position without contact with the blocking element constituted here by the serge 4 as shown in Figure 1, a position initial active in which, controlled by the actuating member 16, it is able to come into contact with the stopping protuberance 8, as shown in Figure 2, an intermediate active position in which it slides on one of the sides 8b, 8c of the stopping protuberance 8, as shown in Figure 3, and a final active position in which, engaged in the cutout 10 or 12, it is supported and abuts against one of the stopping walls 4a, 4b of the blocking element constituted here by the serge 4 and stops the balance 3, as shown in Figure 4. For this purpose, the stopping element 14 is a stopping lever pivotally mounted at A on the movement frame in order to be able to move between its inactive position and its final active position once actuated by the actuating member 16. The stop lever can be pivoted by means of a physical axis or by flexible pivoting . A spring (not shown) can be provided to hold the stopping element 14 against the blocking element constituted here by the serge 4 when it is in the active position, and more particularly when it is in the final active position. This spring can be monolithic to the stop lever 14, and monostable or bistable.

The stopping element 14 is positioned on the movement frame outside the balance 3, and substantially in the same plane. It advantageously presents at its end towards the blocking element constituted here by the serge 4 a nozzle 14a arranged to be able to be in contact with the stopping protuberance 8, to slide on one of the sides 8b, 8c of the protuberance stop 8 and to engage in the cutout 10 or 12 and abut against the stop wall 4a or 4b, when the stop element 14 moves between its initial active position and its final active position.

[0033] Advantageously, the nose 14a of the stopping element 14 can comprise a rolling roller 18 in order to reduce friction between the sides 8b, 8c of the stopping protuberance 8 and the nose 14a of the stop element 14.

[0034] In the case of a stopping device of the stop-balance type for a standard movement, the actuating member 16 of the stopping element 8 is connected to a time-setting rod .

[0035] In the case where the movement comprises a chronograph mechanism and the stopping device is provided to stop the oscillation of the balance wheel dedicated to the chronograph, the actuating member 16 of the stopping element 14 is connected to a column wheel of the chronograph mechanism which determines at least the “STOP” position of the chronograph.

The actuating member 16 can be a pusher, a lever, a monostable or bistable spring, or any other suitable actuating means.

[0037] It is possible to provide safety stops (not shown) arranged on the movement frame to limit the movement of the stopping element 14, avoid excessive pressure on the oscillator, and limit rebounds.

[0038] In accordance with the invention, the stopping protuberance 8 has a geometry chosen so that the force F resulting from the action of the stopping element 14 on the stopping protuberance 8 is such that the moment exerted by the stopping element 14 on the blocking element, from the initial active position of the stopping element 14 in contact with the stopping protrusion 8 to the final active position of the blocking element stop 14, is non-zero and of constant sign so as to bring back and maintain the blocking element constituted here by the serge 4 abutting against the stop element 14.

When the profile of the stopping protuberance 8 only includes one side on which the stopping element 14 bears, it is said side which has the geometry defined according to the invention.

[0040] When the profile of the stopping protuberance comprises two sides on one of which the stopping element 14 can come to bear as shown here, the sides 8b, 8c of the stopping protuberance 8 each have a geometry chosen so that the force F (see Figure 3) resulting from the action of the stopping element 14 bearing on one of the sides 8b or 8c of the stopping protuberance 8 is such that the moment of said force F exerted by the stopping element 14 on the blocking element constituted here by the serge 4 rotating around its axis, from the initial active position of the stopping element 14 in contact with said side 8b or 8c from the stopping protuberance 8 to the final active position of the stopping element 14 abutting against the corresponding stopping wall 4a or 4b which faces the same side 8b or 8c of the protuberance stop 8 on which the stop element 14 has come to rest, is non-zero and of constant sign so as to bring back and maintain said stop wall 4a or 4b of the serge 4 in abutment against the stop element stop 14.

[0041] A person skilled in the art knows how to determine the appropriate geometry to give to the sides 8b and 8c of the stopping protuberance 8 according to the definition given above, in the same way as calculating the profile of a heart associated with a hammer generally used in a chronograph mechanism.

[0042] It can still be specified that the sides 8b and 8c of the stopping protuberance 8 are configured so that the force F exerted by the stopping element 14 on the blocking element secured in rotation of the oscillator 1 does not pass through the axis of rotation of the blocking element so that the moment of the force F which is exerted on the blocking element is never zero, and makes it possible to overcome the restoring force of the elastic member 2 in order to maintain the balance, secured to the blocking element, in the stopped position. This makes it possible to guarantee that the balance, once in contact with the stopping element 14, always has an angular position for which the elastic member 2 has a non-zero potential energy, and that said balance 3 will stop only when it will come into abutment against the stopping wall, the stopping element then being in its final active position, and to guarantee self-starting.

[0043] Furthermore, the moment of the force F exerted by the stopping element 14 on the rotation blocking element has a constant clockwise or counterclockwise sign so as to obtain the rotation of the balance 3 in the direction necessary for bring the stopping wall 4a or 4b which is located on the same side as the side 8b or 8c of the stopping protuberance 8 on which the stopping element 14 has come to rest, abutting on said stopping element 14, whatever the direction of rotation of the balance 3.

The sides 8b and 8c of the stop protuberance 8 are configured so that the profile of the stop protuberance 8 preferably has an axis of symmetry.

[0045] In a particularly advantageous manner, the sides 8b and 8c of the stopping protuberance 8 are configured so that the profile of the stopping protuberance 8 has the shape of a heart point, for example the shape of a logarithmic spiral.

[0046] Thus, the moment of the force F exerted by the stopping element 14 on the blocking element in rotation around its axis is constant.

[0047] Preferably, the stopping protuberance 8 is positioned on the blocking element constituted here by the serge 4 so that its axis of symmetry, and therefore its vertex 8a, passes through the line of centers (line connecting the centers of the balance and anchor).

[0048] Thus, the stopping device makes it possible to block the balance independently of the alternation, avoiding any blockage with the escapement.

[0049] The length of the side or sides 8b and 8c of the stopping protuberance 8 is therefore determined as a function of the positioning of the vertex 8a of the stopping protuberance 8 on the blocking element so that the stopping wall 4a, 4b is positioned according to the angle α as defined above.

[0050] Thus, the balance wheel 3 is stopped with certainty always in the same ideal predetermined angular position making it possible to guarantee an immediate and precise restart at its stable amplitude. When the stopping protuberance has only one side and therefore only one stopping wall, this angular stopping position of the oscillator is unique. When the stopping protuberance has two sides and therefore two stopping walls with predefined positioning, there are then only two possible angular stopping positions of the oscillator, preferably symmetrical with respect to the line of centers, guaranteeing, each time the oscillator stops, a precise and immediate restart of the oscillator at its stable amplitude.

Preferably, the cutout 10, 12 has an angle preventing the stopping element 14 from exiting the cutout 10, 12 when it is in its final active position.

The operation of the stopping device used in the present invention is as follows: In normal operation, the stopping element 14 is in its inactive position, without contact with the balance wheel 3, as shown in Figure 1.

[0053] When the balance must be stopped, the user controls the actuating member 16 in order to actuate the stopping element 14 and tilt it so that it is positioned in its initial active position, in which it can come into contact with the stopping protuberance 8, as shown in Figure 2.

[0054] When the stopping protuberance 8 on the rim 4 of the oscillator 1 rotating around its axis meets the stopping element 14, the latter presses with its nose 14a on the side 8b, 8c of the stopping protuberance 8 with which it came into contact. With reference to Figure 3, the force F of the stopping element 14 exerted on the stopping protuberance 8 is represented by its line of action perpendicular to the surface of the side 8c of the stopping protuberance 8, and d is the distance from the axis of rotation of oscillator 1 to the normal of F. The moment M exerted by the stopping element 14 on the oscillator is equal to F x d. The particular heart-shaped shape of the stopping protuberance 8 makes it possible to have a non-zero moment M of constant sign, here a negative moment causing a rotation of the serge in the clockwise direction A, and this whatever the direction of oscillation of the balance 3. The force exerted on the side 8c of the stopping protuberance 8 by the stopping element 14 makes it possible to rotate the balance 3 in the clockwise direction so as to bring back the stopping wall 4b of the serge 4 associated with the side 8c of the stopping protuberance 8 abutting against said stopping element 14. This is then in its final active position as shown in Figure 4, in which the balance 3 is stopped, blocked due to the stopping wall 4b held in abutment against the stopping element 14. The stopping wall 4b of the cutout 12 has been positioned to form the angle α as defined above , so that the only possible stopping position of the balance 3 corresponds with certainty to its predetermined stationary amplitude as a function of the elastic member 2 and to non-zero potential energy, making it possible to guarantee, at each stop of the balance, a time of resuming operation at its stationary speed as short as possible and precise.

[0055] Similarly, pressing the stopping element on the side 8b of the stopping protuberance 8 generates a positive moment causing a rotation of the serge in the counterclockwise direction, regardless of the direction d. oscillation of the balance 3, so as to bring back and maintain the stopping wall 4a of the serge 4 associated with the side 8b of the stopping protuberance 8 abutting against the stopping element 14.

[0056] Thus the stopping device used in the present invention makes it possible to stop the oscillator in a determined angular position to guarantee good isochronism when it starts. It will thus very quickly regain its stabilized amplitude. It also has the advantages of requiring a small height requirement, the stopping element being substantially in the same plane as the balance wheel, and of being able to be used with an oscillator without a physical axis.

[0057] In another variant not shown of the first embodiment, the oscillator can have a physical axis, the elastic member then being a spiral spring mounted on this physical axis. The amplitude of the balance and the dimensions of the stopping protuberance can be adapted accordingly, the condition of positioning the stopping wall according to the angle α being respected.

[0058] With reference to Figure 5, a second embodiment of the invention is shown, according to which the mechanical oscillator 21 of a watch movement comprises a balance wheel 23 provided with a rim 24 of generally continuous circular shape or discontinuous and an elastic member 22 in the form of a spiral spring. The oscillator 21 cooperates with an escapement mechanism comprising a plate 25, and more particularly a double plate of generally circular shape. The double plate 25 is integral with the axis of the balance 23 so as to be integral in rotation along the axis of rotation of the balance 23. It carries the pin 26. Such a double plate is known to those skilled in the art and does not require further description.

[0059] In this second embodiment, the plate 25 constitutes the locking element integral in rotation with the balance 23 and comprising on its external peripheral edge, a single and unique stopping protuberance 28 ending in at least one cutout 30 or 32 in the blocking element constituted here by the plate 25 revealing at least one stopping wall 25a or 25b forming a stop.

[0060] The stopping protuberance 28 has a profile (front view shape) comprising a vertex 28a facing the outside of the blocking element and at least one side 28b or 28c extending from the vertex 8a, said side 28b or 28c being terminated by the cutout 30 or 32 in the blocking element, here constituted by the plate 25, revealing at least one stopping wall 25a or 25b.

[0061] In a preferred embodiment of the invention, the stopping protrusion 28 has a profile (front view shape) comprising a (single) vertex 28a facing the outside of the plate 25 and two sides 28b, 28c extending on either side of the top 28a, each side 28b, 28c being terminated respectively by the cutout 30, 32 in the blocking element constituted here by the plate 25, said cutout 30, 32 showing respectively, face said corresponding side 28b, 28c, the stopping wall 25a, 25b arranged to form a stop.

[0062] It is obvious that in another embodiment of the invention not shown, the stopping protuberance 28 can be configured so as to present a profile comprising only one side 28b or 28c extending from the top 28a and a single corresponding cutout 30 or 32 in the plate revealing, facing said side 28b or 28c, a single corresponding stopping wall 25a or 25b forming a stop. The vertex 28a is then positioned between the line of centers and the stopping wall.

As described above, the stopping wall 25a, 25b is positioned on the blocking element 25 so as to form, between the line of centers L (line connecting the centers of the balance and the anchor) and the line passing through the outer vertex of the stopping wall 25a, 25b and the axis of rotation of the blocking element 25, an angle α substantially equal to the stationary amplitude.

[0064] There is also provided a stopping element with its nozzle and a roller, and an actuating member similar to the stopping element 14 with its nozzle 14a and the roller 18, and to the actuation 16 of the first embodiment, the stopping element being arranged to come into contact with the stopping protuberance 28 on the plate 25 instead of the stopping protuberance 8 on the serge 4.

The shape of the sides 28b and 28c of the stopping protuberance 28 is similar to the shape of the sides 8b and 8c of the stopping protuberance 8 described above for the first embodiment, for example the shape d 'a logarithmic spiral. More particularly, the sides 28b and 28c of the stopping protuberance 28 are configured so that the force F exerted by the stopping element on the blocking element, constituted here by the plate 25, integral in rotation with the oscillator 21, does not pass through the axis of rotation of the blocking element 25 so that the moment of the force F which is exerted on the blocking element is never zero, and makes it possible to overcome the force return of the elastic member 22 in order to maintain the balance 23, secured to the blocking element 25, in the stopped position. This ensures that the balance 23, once in contact with the stopping element, will only stop when it has reached the stopping wall, the stopping element then being in its final active position , this stop position corresponding to an angular position for which the elastic member 22 has a non-zero potential energy, which allows self-starting.

[0066] Furthermore, the moment of the force F exerted by the stopping element on the rotation blocking element 25 has a constant clockwise or counterclockwise sign so as to obtain the rotation of the balance 23 in the direction necessary for bring the stop wall 25a or 25b which is located on the same side as the side 28b or 28c of the stop protuberance 28 on which the stop element has come to rest, in abutment on said stop element, whatever the direction of rotation of the balance 23.

[0067] The length of the side or sides 28b and 28c of the stopping protuberance 28 is determined as a function of the positioning of the top 28a of the stopping protuberance 28 on the plate 25 so that the stopping wall 25a, 25b is positioned according to the angle α as defined above. Preferably, the stopping protuberance 28 is positioned on the plate 25 so that its axis of symmetry, and therefore its vertex 28a, passes through the line of centers.

[0068] Thus, the predefined positioning of the stopping walls 25a, 25b according to the angle α and the shape of the sides of the stopping protuberance 28 make it possible to stop the balance wheel 23 with certainty, by means of a stop of the plate 25, always in one or other of the ideal predetermined angular positions, preferably symmetrical with respect to the line of centers, making it possible to guarantee, at each stop of the oscillator, a precise and immediate restart of said balance 23 at its stable amplitude.

[0069] Furthermore, the positioning of the stop protuberance 28 on the plate 25 makes it possible not to add any additional components, and not to modify the height of the mechanism.

Claims (15)

1. Timepiece movement comprising a mechanical oscillator (1, 21) comprising a balance wheel (3, 23) provided with an elastic member (2, 22), and a device for stopping said oscillator comprising an element of stop (14) and an actuating member (16) of said stopping element (14), characterized in that the stopping device comprises a blocking element (4, 25) integral in rotation with the balance (3, 23) and having, on its peripheral edge, a stopping protuberance (8, 28) ending in at at least one cutout (10, 12; 30, 32) in said blocking element (4, 25) revealing at least one stopping wall (4a, 4b; 25a, 25b) forming a stop and positioned so as to form with the line of centers (L) an angle α substantially equal to the stationary amplitude, in that the stopping element (14) is arranged to move between an inactive position without contact with the blocking element (4, 25), an initial active position in which, after activation by the actuating member (16), it is able to come into contact with the stopping protuberance (8, 28), an intermediate active position in which it slides on the stopping protuberance (8, 28) and a final active position in which, engaged in the cutout (10, 12; 30, 32), it abuts against the stopping wall (4a, 4b; 25a, 25b) of the blocking element (4, 25) and stops the balance (3, 23 ), and in that the stopping protuberance (8) has a geometry chosen so that the force (F) resulting from the action of the stopping element (14) on the stopping protuberance (8, 28) is such as the moment exerted by the stopping element (14) on the blocking element (4, 25), from the initial active position of the stopping element (14) in contact with the stopping protuberance (8, 28) up to the final active position of the stopping element (14), is non-zero and of constant sign so as to bring and maintain the blocking element (4, 25) in abutment against the stopping element (14). 2. Movement according to claim 1, characterized in that the stopping protuberance (8, 28) has a profile comprising a vertex (8a, 28a) and two sides (8b, 8c; 28b, 28c) extending on either side and on the other side of the top (8a, 28a), each side (8b, 8c; 28b, 28c) being terminated by the cutout (10, 12; 30, 32) in the blocking element (4, 25) revealing , facing said side (8b, 8c; 28b, 28c), the stopping wall (4a, 4b; 25a, 25b) forming a stop, and in that the sides (8b, 8c; 28b, 28c) of the protrusion d stop (8, 28) have a geometry chosen so that the force (F) resulting from the action of the stopping element (14) on one of the sides (8b, 8c; 28b, 28c) of the stopping protuberance (8, 28) is such that the moment exerted by the stopping element (14) on the blocking element (4, 25), from the initial active position of the stopping element ( 14) in contact with said side (8b, 8c; 28b, 28c) of the stopping protuberance (8, 28) until the final active position of the stopping element (14) abutting against the wall of stop (4a, 4b; 25a, 25b) corresponding, is non-zero and of constant sign so as to bring and maintain said stopping wall (4a, 4b; 25a, 25b) in abutment against the stopping element (14). 3. Movement according to claim 1 or 2, characterized in that the stopping protuberance (8, 28) has a profile having an axis of symmetry. 4. Movement according to claim 3, characterized in that the axis of symmetry of the profile of the stopping protuberance (8, 28) passes through the line of centers. 5. Movement according to one of the preceding claims, characterized in that the stopping protuberance (8.28) has a profile having the shape of a heart point. 6. Movement according to one of the preceding claims, characterized in that the stationary amplitude is between 10° and 160°, preferably between 20° and 45°, and in that the angle α is equal to the stationary amplitude ± 10%. 7. Movement according to one of the preceding claims, characterized in that the stop element (14) is a stop lever pivotally mounted between its inactive position and its final active position and having a beak (14a) arranged to be able to be in contact with the stopping protuberance (8, 28) and engage in the cutout (10, 12; 30, 32) when the stopping element (14) moves between said initial active position and said position final active. 8. Movement according to claim 7, characterized in that the nozzle (14a) of the stop lever comprises a rolling roller (18). 9. Movement according to one of the preceding claims, characterized in that the cutout (10, 12; 30, 32) in the blocking element (4, 25) has an angle preventing the exit of the stopping element (14). 10. Movement according to one of the preceding claims, characterized in that the actuating member (16) of the stopping element (14) is connected to a time setting rod. 11. Movement according to one of claims 1 to 9, characterized in that it comprises a chronograph mechanism and in that the actuating member (16) of the stopping element (14) is connected to a column wheel of the chronograph mechanism. 12. Movement according to one of the preceding claims, characterized in that the elastic member (22) is a spiral spring. 13. Movement according to one of claims 1 to 11, characterized in that the elastic member (2) is a system with elastic blades. 14. Movement according to one of the preceding claims, characterized in that the balance (3) is provided with a seam, said serge constituting the blocking element. 15. Movement according to one of claims 1 to 12, characterized in that it comprises an escapement mechanism comprising a plate (25) integral with the balance (23), said plate (25) constituting the blocking element.