EP3401739B1 - Timepiece movement comprising a constant force device - Google Patents

Description

The present invention relates to a watch movement comprising a so-called "constant force" device, that is to say a watch movement comprising between its motor member and its escapement an intermediate spring which is periodically armed by the driving member and which delivers its energy in the exhaust. Such an intermediate spring makes it possible to provide the escapement with a force which theoretically does not depend on the degree of arming of the motor unit, thus improving the constancy of the amplitude of the oscillator of the watch movement.

• un rouage,
• un organe moteur pour entraîner le rouage,
• un échappement,
• un oscillateur agencé pour coopérer avec l'échappement,
• une bascule portant un mobile intermédiaire qui relie l'échappement au rouage,
• un ressort de stockage périodique d'énergie agencé pour agir sur la bascule, et
• un organe de blocage pour immobiliser et libérer le rouage, cet organe de blocage étant commandé par la bascule,

le mouvement horloger étant agencé pour fonctionner selon un cycle comprenant une première phase pendant laquelle l'organe de blocage immobilise le rouage, permettant au ressort de stockage périodique d'énergie de se détendre et de déplacer la bascule dans un premier sens par pas au rythme des alternances de l'oscillateur jusqu'à ce que l'organe de blocage libère le rouage, et une seconde phase déclenchée par la libération du rouage pendant laquelle la bascule est déplacée dans le sens opposé au premier sens sous l'action du rouage pour réarmer le ressort de stockage périodique d'énergie et ramener l'organe de blocage dans une position où il pourra de nouveau immobiliser le rouage.More particularly, the present invention relates to a watch movement comprising:

• a cog,
• a driving member for driving the gear,
• an exhaust,
• an oscillator arranged to cooperate with the escapement,
• a rocker carrying an intermediate mobile which connects the escapement to the wheel,
• a periodic energy storage spring arranged to act on the rocker, and
• a locking member for immobilizing and releasing the gear train, this locking member being controlled by the rocker,

the watch movement being arranged to operate according to a cycle comprising a first phase during which the locking member immobilizes the wheel, allowing the periodic energy storage spring to relax and move the rocker in a first direction step by step alternations of the oscillator until the locking member releases the gear, and a second phase triggered by the release of the gear during which the rocker is moved in the opposite direction to the first direction under the action of the gear for reset the periodic energy storage spring and return the locking member to a position where it can again immobilize the train.

Such a watch movement is described in the patent EP 1528443 . In the latter, the locking member is a spout or pallet carried by the rocker and intended to engage in teeth wolf teeth of a stop wheel forming part of the gear train. Throughout the first phase of the operating cycle, the stop wheel bears against the blocking member secured to the rocker, so that the movement of the rocker causes friction. This friction consumes a part of the energy supplied by the periodic energy storage spring and disturbs the regularity of oscillations of the oscillator due to the fact that they vary according to the state of arming of the organ engine.

The present invention aims to alleviate this problem and proposes for this purpose a watch movement according to claim 1 and a timepiece, such as a watch or a pendulum, comprising it. The present invention differs from the watch movement according to the patent EP 1528443 in particular in that the locking member is a lever arranged for, during the first phase of the operating cycle, be prevented by the latch to release the gear during a non-zero integer N alternating (s) of the oscillator and be driven by the rocker only after the (the) N alternating (s) to release the cog.

• les figures 1 à 4 sont des vues de dessus d'un mouvement horloger selon l'invention à différents instants de son cycle de fonctionnement ;
• la figure 5 est une vue de dessus montrant plus précisément un levier de blocage du mouvement horloger selon l'invention et un dispositif de réglage de ce levier de blocage.

Other features and advantages of the present invention will appear on reading the following detailed description given with reference to the accompanying drawings in which:

• the Figures 1 to 4 are top views of a watch movement according to the invention at different times of its operating cycle;
• the figure 5 is a top view showing more precisely a locking lever of the watch movement according to the invention and a device for adjusting this locking lever.

In the context of the present invention, the term "axis" or "axis of rotation" is understood to mean an imaginary axis, that is to say an ideal line around which a rotation occurs.

With reference to the figure 1 , a watch movement 1 according to the present invention comprises a driving member 2, a gear train 3, an escapement 4 and an oscillator 5. The driving member 2 and the oscillator 5 are typically constituted by a barrel and a sprung-balance, respectively . The exhaust 4 is for example a Swiss lever escapement. It comprises an escape wheel composed of a coaxial and integral exhaust wheel 4a and a 4c exhaust pinion, and an anchor 4c, the anchor 4c cooperating in a conventional manner with the escape wheel 4a and With the oscillator 5, the wheel 3 comprises, in the illustrated example, a center wheel 3a meshing with the motor member 2, a mobile of average 3b meshing with the center wheel 3a, a second wheel 3c carrying a second indicator needle (not shown) and meshing with the mobile of average 3b, a first intermediate mobile 3d meshing with the second mobile 3c, a second intermediate mobile 3e meshing with the first intermediate mobile 3d, and a stopping mobile 3f meshing with the second intermediate mobile 3e. Each of the mobiles 3a to 3e is formed of a wheel and a pinion coaxial and solidarity. The stop mobile 3f comprises a pinion 3g and a finger 3h coaxial and integral with the pinion 3g.

A rocker 6 is pivotally mounted about the axis A1 of the second mobile 3c, freely rotatable relative to said mobile 3c, but could alternatively rotate about an axis distinct from the axis A1. An intermediate mobile 7 carried by the rocker 6 meshes with the second mobile 3c and the exhaust pinion 4b to connect the exhaust 4 to the wheel 3. This intermediate mobile 7 is typically a wheel pivotally mounted about an axis A2 which moves with the rocker 6. The rocker 6 is subjected to the action of a periodic energy storage spring 8 tending to pivot the rocker 6 in the clockwise direction of the figure 1 . The spring 8 is preferably a spring blade as represented but could be in another form, such as a hairspring. The rocker 6 cooperates with a lever 9 pivoting about an axis A3. The lever 9 is not subjected to the action of a return spring. It carries a spout 9a which most of the time holds the finger 3h, thus blocking the gear 3 and the motor member 2. As the axis A1, and unlike the axis A2 which moves with the rocker 6, the axis A3 is fixed relative to the frame of the watch movement 1.

For its cooperation with the lever 9, the rocker 6 has at one end a first actuating surface 6a, a second actuating surface 6b and an abutment surface 6c. The abutment surface 6c is in circular arc concentric with respect to the axis of rotation A1 of the rocker 6. The actuating surfaces 6a, 6b are eccentric with respect to the axis of rotation A1 of the rocker 6 and connected by the abutment surface 6c. The first actuating surface 6a is preferably flat and directed towards the axis of rotation A1 of the rocker 6. The second actuating surface 6b is constituted by a corner of said end of the rocker 6, more precisely by the zone connecting the abutment surface 6c and a surface 6d of the rocker 6 opposite the first actuating surface 6a. The actuating surfaces 6a, 6b are cams interacting with first and second teeth 9b, 9c of a fork defined by the end of the lever 9 other than that carrying the spout 9a.

Watch movement 1 operates according to the following cycle.

During the time when the beak 9a holds the finger 3h ( figure 1 ), the spring 8 expands and moves the rocker 6 clockwise. The intermediate mobile 7 moves with the rocker 6 and its meshing in the manner of a sun gear with the mobile of second 3c, while fixed, rotates it clockwise to drive the mobile escape 4a, 4b. This displacement of the rocker 6 and the intermediate mobile 7 is made in steps, at the rate of the releases of the escape wheel 4a by the oscillator 5 via the anchor 4c, the rocker 6 pivoting and a step at each alternation of the oscillator 5.

After a predetermined integer number N of alternations of the oscillator 5, the rocker 6 pivots the lever 9 in the counterclockwise direction so that its spout 9a disengages from the finger 3h and releases the wheel 3 and the motor member 2 ( figures 2 and 3 ). Under the action of the motor unit 2 the second mobile 3c then rotates the intermediate mobile 7 in the counterclockwise direction, and the meshing of the intermediate mobile 7 with the exhaust pinion 4b, which at this moment is fixed in because of the support of the escape wheel 4a against the anchor 4c, brings the rocker 6 back to its initial position by arming the spring 8 ( figure 4 ). This movement of the gear train 3, the intermediate mobile 7 and the rocker 6 is almost instantaneous. It is used to display the time and to drive other mechanisms, without disturbing the torque transmitted to the escapement 4 and to the oscillator 5. During this movement, the rocker 6 pivots the lever 9 clockwise so that the beak 9a comes back to cut the trajectory of the finger 3h ( figure 4 ). The finger 3h, having traveled one turn, comes back against the spout 9a, which stops the gear 3 and the motor member 2 ( figure 1 ). The cycle is then repeated. During each cycle the oscillator 5 performs a predetermined integer number M of alternations (M> N).

Thus, the energy received by the escapement 4 comes from the expansion of the spring 8, which is periodically armed by the drive member 2. The rocker 6, the intermediate mobile 7 and the spring 8 form a so-called "constant force device" Which improves the constancy of the amplitude of the oscillator 5.

Preferably, the duration of each cycle is 1 second, allowing the second mobile 3c and the pointer of the second door to move it by performing a jump to ^1/60 revolution per second.

Maintaining the nozzle 9a of the lever 9 in its position where it intersects the trajectory of the finger 3h to stop it ( figure 4 ) and retain it ( figure 1 ) is obtained by the abutment surface 6c of the rocker 6 which moves while remaining opposite the top of the second tooth 9c, the latter immediately abutting against the abutment surface 6c as soon as the lever 9 attempts to pivot in the direction counterclockwise. During said N alternations of the oscillator 5, the actuating surfaces 6a, 6b are inactive, in particular the first actuating surface 6a is not in contact with the first tooth 9b. The movement of the rocker 6 does not cause or almost no friction between the rocker 6 and the lever 9.

During the (N + 1) ^th alternation of the oscillator 5, the first actuating surface 6a comes into contact with the first tooth 9b of the lever 9 ( figure 2 ) and pushes it to rotate the lever 9 counterclockwise and release the finger 3h ( figure 3 ). This (N + 1) ^th alternation is the last alternation of the cycle, in other words M = N + 1.

The release of the finger 3h allows the gear 3 to rotate under the action of the drive member 2. The gear 3 returns the rocker 6 to its initial position, starting by causing the return of the lever 9 in its position where the spout 9a cut the trajectory of the finger 3h ( figure 4 ). The return of the lever 9 in its position where the nose 9a intersects the path of the finger 3h is obtained from the passage of the latch 6 in its position corresponding to the (M-1) ^th alternation of each cycle. To do this, the second actuating surface 6b comes into contact with the inner side of the second tooth 9c ( figure 3 ) then pushes this inner flank until the abutment surface 6c is placed opposite the top of the second tooth 9c to lock the lever 9 ( figure 4 ).

In the present invention, the friction between the rocker 6 and the lever 9 during the expansion of the spring 8 are very low, they occur essentially at the end of each cycle. As a result, the constant force device 6, 7, 8 is very little disturbed by the variations in force of the driving member 2 and is even less dependent on the degree of arming of the driving member 2 than the force device. constant according to EP 1528443 wherein the rocker carries the spout which cooperates with the stopping mobile.

In practice, the number N of alternations during which the flip-flop 6 does not cause the lever 9 can vary from one cycle to another. Thus, one can have N = M-1 (most general case) in some cycles and N = M-2 or N = M-3 in other cycles. Indeed, in the configuration described, the lever 9 having no stop preventing it from engaging more deeply in the finger 3h, it can in some cycles stop in a position that reduces the number N. It can be made that number N equal to M-1 in all cycles by the recourse to such a stop. It can also be done so that the number N is the same in each cycle while being different from M-1 (for example equal to M-2 or M-3). In any case, when N is strictly less than M-1, the first actuating surface 6a comes into contact with the first tooth 9b of the lever 9 before the ^Mth alternation but ends up clearing the lip 9a of the finger 3h when said M ^th alternation.

The number M of alternations per cycle depends on the frequency of the oscillator 5 and the duration of the cycle. For example, if the frequency of oscillator 5 is 4 Hz (8 cycles per second) and the cycle time is 1 second, then M = 8. If the frequency of oscillator 5 is 3 Hz (6 vibrations per second) and the cycle time is 1 second, then M = 6. If the frequency of oscillator 5 is 4 Hz (8 cycles per second) and the cycle time is 0.5 seconds, then M = 4.

In a particular exemplary embodiment, the number M of alternations of the oscillator 5, and therefore the number of steps of the flip-flop 6, in each cycle is equal to eight, the flip-flop 6 traverses an angle of 2 ° per cycle, ie 0 , 25 ° in steps, the gear ratios in the gear train 3 are chosen so that a turn of the finger 3h corresponds to this angle of 2 ° and the number N of alternations during which the rocker 6 moved by the spring 8 n The lever 9 is equal to seven, six or five depending on the cycle.

It goes without saying that other numerical values could be chosen. For example, the number M of alternations of the oscillator 5 per cycle could be two and the number N of alternations where the flip-flop 6 does not cause the lever 9 could be equal to one.

In general, the number N of alternations of the oscillator 5 during which the flip-flop 6 does not cause the lever 9 in each cycle is at least equal to one, preferably at least two, more preferably at least three, more preferably at least four, more preferably at least five, more preferably at least six, preferably at least at least equal to seven.

Another advantage of the present invention is that the lever 9 interacts with the finger 3h which could be likened to a stop wheel having only one tooth. This configuration makes it possible to control the locking safety and the unlocking safety in a single position, unlike that of the movement described in the patent. EP 1528443 where the stop wheel carries 10 teeth.

Yet another advantage of the present invention is that one can play on the length of the arms of the lever 9, more precisely provide a shorter distance between the axis of rotation A3 and the fork 9b, 9c that between the axis rotation A3 and the spout 9a, so that a displacement of the portion (fork 9b, 9c) in contact with the rocker 6 causes a greater displacement of the portion (spout 9a) in contact with the stopper 3f. Increasing the stroke of the nozzle 9a makes it possible to increase the accuracy of the moment of unlocking of the stopping mobile 3f and thus to improve the operational safety. This also makes it possible to widen manufacturing tolerances and thus reduce manufacturing costs.

The present invention is not limited to the shape of the fork 9b, 9c and the end 6a, 6b, 6c, 6d of the latch 6 as shown. In another embodiment, replacing the surfaces 6a, 6b, 6c the flip-flop 6 could carry a pin which would be engaged in an L-shaped hole of the lever 9, this hole replacing the teeth 9b, 9c.

As visible on the figure 5 , the watch movement 1 according to the invention may comprise a device for adjusting the position of the axis of rotation A3 of the lever 9, for adjusting the depth of penetration of the spout 9a in the finger 3h. This adjustment device comprises, for example, a pivoting lever 10 around an axis A4 and a bridge 11 fixed to this lever 10, the lever 9 being mounted between this lever 10 and this bridge 11. The lever 9 is secured to a shaft which defines the axis of rotation A3 and whose two ends pivot in stones (one of them, 11a, is visible at the figure 5 ) respectively carried by the rocker 10 and the bridge 11, thereby reducing friction. The angular position of the adjusting device 10, 11 around its axis of rotation A4 can be adjusted to adjust the position of the axis of rotation A3 of the lever 9 relative to the axis of rotation of the stopping wheel 3f and of his finger 3h. An eccentric 12 and a plating spring 13 allow fine adjustment of the device. Maintaining the adjusting device 10, 11 in its set position is provided by screws 14 passing through oblong holes 15 of the rocker 10 and screwing into the frame of the watch movement 1.

The watch movement 1 according to the invention can be used in a watch or a pendulum, in particular a table clock.

Claims (12)

1. Timepiece movement (1) comprising

   - a gear train (3),

   - a drive member (2) to drive the gear train (3),

   - an escapement (4),

   - an oscillator (5) arranged to cooperate with the escapement (4),

   - a control lever (6) supporting an intermediate mobile (7) which connects the escapement (4) to the gear train (3),

   - a spring for periodic storage of energy (8) arranged to act on the control lever (6), and

   - a locking member (9) to lock and release the gear train (3), this locking member (9) being controlled by the control lever (6),

   the timepiece movement (1) being arranged to operate in a cycle comprising a first phase during which the locking member (9) locks the gear train (3), allowing the spring for periodic storage of energy (8) to relax and to move the control lever (6) in a first direction in steps at the rate of the alternations of the oscillator (5) until the locking member (9) releases the gear train (3), and a second phase actuated by the release of the gear train (3) during which the control lever (6) is moved in the opposite direction to the first direction under the action of the gear train (3) to charge the spring for periodic storage of energy (8) and to return the locking member (9) to a position where it will be able to lock the gear train (3) again, characterised in that the locking member (9) is a lever arranged to, during the first phase

   - be prevented by the control lever (6) from releasing the gear train (3) during a non-zero integer number N of alternation(s) of the oscillator (5), and

   - be driven by the control lever (6) only after the N alternation(s) to release the gear train (3).
2. Timepiece movement (1) as claimed in claim 1, characterised in that the control lever (6) comprises a first actuation surface (6a), a second actuation surface (6b) and an abutment surface (6c), and in that the lever (9) comprises first and second teeth (9b, 9c), the abutment surface (6c) being arranged to move while remaining facing the tip of the second tooth (9c) during the N alternation(s), the first actuation surface (6a) being arranged to be out of contact with the first tooth (9b) during the N alternation(s) and to cooperate with the first tooth (9b) after the N alternation(s) in order to drive the lever (9) and to release the gear train (3), the second actuation surface (6b) being arranged to cooperate with the second tooth (9c) to return the locking member (9) to said position during the second phase.
3. Timepiece movement (1) as claimed in claim 2, characterised in that the abutment surface (6c) is in the form of a circular arc concentric with the rotational axis (A1) of the control lever (6).
4. Timepiece movement (1) as claimed in any one of claims 1 to 3, characterised in that the lever (9) has a beak (9a) arranged to cooperate with a stopping mobile (3f) of the gear train (3) during the first phase.
5. Timepiece movement (1) as claimed in claim 4, characterised in that the stopping mobile (3f) comprises a toothed wheel (3g) meshing with another mobile (3e) of the gear train (3) and a finger (3h) coaxial with and fixedly attached to the toothed wheel (3g), this finger (3h) being arranged to cooperate with the beak (9a).
6. Timepiece movement (1) as claimed in any one of claims 1 to 5, characterised in that the number N is equal to at least two, preferably at least three, more preferably at least four, more preferably at least five, more preferably at least six, more preferably at least seven.
7. Timepiece movement (1) as claimed in any one of claims 1 to 6, characterised in that the number of alternations of the oscillator (5) in each operating cycle of the timepiece movement (1) is equal to eight.
8. Timepiece movement (1) as claimed in any one of claims 1 to 7, characterised in that the distance between the rotational axis (A3) of the lever (9) and a first end (9b, 9c) of the lever (9) intended to be in contact with the control lever (6) is shorter than the distance between said rotational axis (A3) and a second end (9a) of the lever (9) intended to cooperate with the gear train (3).
9. Timepiece movement (1) as claimed in any one of claims 1 to 8, characterised in that it comprises a device (10, 11) allowing the position of the rotational axis (A3) of the lever (9) to be adjusted.
10. Timepiece movement (1) as claimed in claim 9, characterised in that the adjusting device (10, 11) comprises an adjusting control lever (10) supporting the lever (9), the angular position of this adjusting control lever (10) being adjustable.
11. Timepiece movement (1) as claimed in claim 10, characterised in that the adjusting device (10, 11) further comprises a bridge (11) fixed to the adjusting control lever (10), and in that the lever (9) is mounted on a shaft, of which the two ends pivot in stones (11a) supported by the adjusting control lever (10) and this bridge (11) respectively.
12. Timepiece, such as a watch or clock, comprising a timepiece movement (1) as claimed in any one of the preceding claims.

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