EP1708050B1 - Timepiece with a minute-repeater mechanism - Google Patents

Abstract

The mechanism has a gong emitting two sounds of different frequencies, and pallets (36). Hammers are moved by the pallets to strike the gong, where the pallets are arranged coaxially. The pallet has a tip cooperating with toothed sectors mounted movably in movement in order to pivot the tip. A spring is supported on a positioning surface to maintain the pallet in a rest position. The pallet has a pallet fork to directly act on a pin having the hammers to strike the gong.

Description

Technical area

The present invention relates to the field of mechanical watchmaking. It relates more particularly to a mechanism known to those skilled in the art as the minute repeater.

State of the art

Such a device makes it possible to indicate, on demand, the hour to the minute, by means of blows struck by two hammers on two different stamps. The hammers are operated by lifts that are raised by a striking mechanism. This includes a room of hours, a quarter and a minute, with twelve, three and fourteen teeth respectively to ring the hours, quarters and minutes.

In order to regulate the movement of these pieces, a snail of the hours is arranged on a star with twelve teeth, advancing one step per hour, while a quarter snail and another minute are adjusted on the bolster of the roadway . Three flip-flops, each equipped with a probe cooperating with these snails, make it possible to determine the stroke of the parts of the hours, quarters and minutes and to adjust the number of blows sounded.

Further details on this kind of complications can be found, especially on the driving force of the repetition or on the step of recess, that is to say on the triggering of the ring, in the book " Theory of Watchmaking "by Reymondin et al, Federation of Technical Schools, 1998, ISBN 2-940025-10-X, pages 219-224 . An example of a repeating watch taken from the patent literature is the document US 447,939 .

One of the many complexities of this mechanism is the large number of parts that need to be coordinated and adjusted in order to function properly.

The object of the present invention is to propose a new minute repetition mechanism employing a relatively small number of parts, which makes it easier to develop.

Disclosure of the invention

• un bec qui coopère avec des secteurs dentés montés mobiles dans ledit mouvement afin de faire pivoter lesdites levées,
• une surface de positionnement sur laquelle appuie un organe élastique pour maintenir les levées dans leur position de repos, et
• une palette qui agit directement sur une goupille que comportent les marteaux.

More specifically, the invention relates to a striking mechanism comprising at least one sound device capable of emitting at least two different frequency sounds, at least two coaxially disposed lifts each comprising:

• a spout which cooperates with toothed sectors mounted movably in said movement in order to rotate said lifts,
• a positioning surface on which supports an elastic member to maintain the lifts in their rest position, and
• a pallet that acts directly on a pin that includes hammers.

The striking mechanism further comprises at least two hammers each having a pin on which the pallet acts directly to make them strike said sound organ.

Advantageously, the pallet of a first lift is positioned to act on the pin of a first hammer during a rising phase of its rotational movement in a first direction, and the pallet of a second lift is positioned. in order to act on the pin of a second hammer during a downward phase of its rotational movement in said first direction.

Advantageously, the hammers are arranged on either side of the lifts. In addition, one of the hammers can be coaxial with the lifts.

According to a preferred embodiment, in which the toothed sectors comprise an hour sector, a quarter sector and a minute sector, the hours sector is in the plane of the beak of only one of the lifts, the sector of the minutes is in the plane of the beak of the other leaven and the sector of quarters embraces, in its thickness, the beaks of the two lifts.

Brief description of the drawings

• les figures 1a et 1b sont des vues de dessus du mécanisme au repos, la vue globale ayant été partagée sur les deux figures,
• les figures 2 et 3 sont des gros plans, en vue de dessus, d'une part, de la zone du mécanisme proche du barillet et, d'autre part, des levées, des timbres et des marteaux, et
• les figures 4 à 7 représentent différentes positions du mécanisme au cours d'une sonnerie de 10h40.

Other details will appear more clearly on reading the description which follows, made with reference to the appended drawing in which:

• the figures 1a and 1b are top views of the mechanism at rest, the overall view having been shared on the two figures,
• the figures 2 and 3 are closeups, in plan view, on the one hand, of the zone of the mechanism close to the barrel and, on the other hand, levies, stamps and hammers, and
• the Figures 4 to 7 represent different positions of the mechanism during a 10h40 ring.

Mode (s) of realization of the invention

The minute repetition mechanism according to the invention is described below with reference to the figure 1 . It takes place in a classic watch movement whose current elements, for the sake of clarity, have not been represented. Similarly, the plate, on which the pieces of the repetition are mounted, does not appear in the drawing.

Winder and actuation

The energy required for the operation of the repetition is provided by a ringer barrel 10 which is armed, either by a rack that the wearer actuates, either by an automatic winding system with oscillating weight, or by manual winding.

In the illustrated example, the barrel 10 is automatically reassembled. It is held in the armed position by means of a wolf-tooth wheel 12. More specifically, the end of a first rocker 14 visible on the figure 2 and pivotally mounted at the periphery of the movement, forms a pawl that locks the wheel 12. When the wearer of the watch wants to operate the repeater mechanism to minutes, it presses a pusher 16 protruding outside the box. The latter actuates a second latch 18, also located on the periphery of the movement, pivoting at a point X and having a pin 20 which cooperates with the first latch 14, the side of the center of the movement.

A pressure on the pusher 16 pivots the lever 18 whose pin 20 pushes the rocker 14. The pawl is then raised, which has the effect of releasing the barrel 10.

By a train of conventional wheels, the barrel 10 rotates a clock-driven driving wheel 22, pivoting in a clockwise direction (SAM below) at a point A, under the other parts of the mechanism. of repetition. The unwinding of the barrel is slowed down by a brake 23 or an escapement disposed at the outlet of the barrel 10.

The flip-flop 18 further comprises a lug 18c taking up, at rest, in one of the two notches 200 formed on a diameter of a counting wheel 202, so named because, as will be understood hereafter, it makes it possible to determine the duration of a cycle of the repetition mechanism.

A gear train located at a lower level with respect to the elements already described, connects the barrel 10 to an intermediate mobile located under the counting wheel 202, coaxially and integrally with it. It is therefore not visible in the drawing.

When the pusher 16 is pressed, the rocker 18 is raised and the barrel 10 is released. The counting wheel 202 is then rotated and, when the pusher 16 is released, the lug 18c bears on the edge of the counting wheel 202 which has rotated, which keeps the latch 18 in position and prevents the ratchet to fall back and lock the barrel 10. When the wheel 202 has made a half turn, the lug 18c goes down into the other notch 200 and the latch 18 falls. The pin 20 of the rocker 18 no longer pushes on the rocker 14, the pawl can then fall, blocking the barrel 10. The rotational speed of the counting wheel 202 is adjusted to allow the striking mechanism to perform a complete cycle while this wheel makes a U-turn.

As we see better on the figure 2 , the barrel 10 is kinematically connected with a gear train 210 performing a turn in a period substantially equal to that of the power reserve of the barrel. This wheel is used to display, in a window of the dial, information on the power reserve of the barrel ring.

Advantageously, the gear 210 carries, on its axis, a cam 212 intended to cooperate with a finger 216a of a flip-flop 216. One end of the latter ends near the rocker 18, particularly a hook 18a that it involves. This end is provided with a pillar 216b located on the cam and a stop 216c located below it and intended to act with the hook 18a. A jumper spring 218 has two contiguous housings 218a and 218b which cooperate with the pillar 216b. The interaction between the cam 212 and the finger 216a is used to drive the pillar 216 from one to the other of the housing, the pressure of the spring 218 allowing the rocker 216 to occupy only two positions.

The cam 212 is positioned so as to cross the finger 216a when the power reserve of the barrel does not make it possible to carry out a complete ringing repetition cycle at minutes, that is to say when it is approximately less than 30. % of the total reserve.

When the power reserve is greater than this value, the flip-flop 216 is in the first of its positions, the pillar 216b being located in the housing 218a and the stop 216c leaving free the hook 18a. When the reserve falls below this value, the rotation of the gear 210 and the position of the cam 212 allow it to push the finger 216a and pass the latch 216 in its second position. The pillar 216b is then located in the housing 218b and the stop 216c is positioned in the hollow of the hook 18a.

Thus, when the wearer presses the pusher 16 to trigger the minute repeater, the latch 18 can not be actuated because the stop 216c blocks it at the hook 18a. The barrel 10 can not be released and there is no ring.

Preferably, the display indicates in the window, when the rocker is in its first position, that the repeat mechanism is usable, for example by means of a sector of a first color and, when the rocker is in its second position, that the mechanism is blocked, by means of a pellet of another color.

Counting organ

To take information relating to the current time, the mechanism is provided with a counting member which comprises a set of snails of known type, driven by the finishing gear. In summary, it comprises a minute snail 24 with four arms each provided with fourteen teeth, adjusted on a tigeron of the roadway in the center of the movement, and a quarter snail 26 provided with three teeth, in solidarity with the surprise. In addition, a snail of hours 28 is disposed on a star with twelve teeth 30, advancing one step per hour.

Advantageously and as shown in the figures, the minutes snail 24 is provided with a surprise, of conventional type, provided with a jumper 31. This mechanism is intended to prevent, at the time of passage from one quarter to another, the minute probe (described below) falls directly to the "0 minute" level. Explanations of this well-known device can be found in the reference cited in the introduction.

Stamps and levees

As is particularly the case figure 3 , the repetition comprises, at its periphery, two stamps 32a and 32b that two hammers 34a and 34b, driven by upper and lower levies 36, sound. The stamps 32a and 32b can be made in one or more independent pieces. The springs and counter-springs of the hammers are not shown.

• un bec 38a, 38b qui coopère avec des secteurs dentés 102,106,136d afin de les faire pivoter,
• une surface de positionnement 40 sur laquelle appuie un ressort 42 pour les maintenir dans leur position de repos, et
• une palette 44a, 44b qui agit directement sur une goupille 46a, 46b que comportent les marteaux 34a, 34b pour leur faire frapper les timbres 32a, 32b.

According to an important characteristic of the invention, these lifts are arranged coaxially. They each present:

• a spout 38a, 38b which cooperates with toothed sectors 102, 106, 136d in order to rotate them,
• a positioning surface 40 on which a spring 42 presses to hold them in their rest position, and
• a pallet 44a, 44b which acts directly on a pin 46a, 46b that includes the hammers 34a, 34b to make them hit the stamps 32a, 32b.

For the upper lift 36a, the pallet 44a is positioned to act on the pin 46a during a rising phase of its rotational movement in the counter-clockwise direction (SIAM below).

For the lower lift 36b, the pallet 44b is positioned to act on the pin 46b during a downward phase of its rotational movement in the SIAM.

When the toothed sectors pivot in the SIAM and operate the lifts 36 from right to left, with reference to the figure 1b , these are driven into the SAM, which has no effect on the hammers 34a, 34b (as it makes the pallets move away from the pin 46a, 46b), then they resume their initial position under the effect of spring 42.

When the toothed sectors pivot in the SAM and actuate the lifts 36 from left to right, with reference to the figure 1b , these are trained in the SIAM. The pallets 44a, 44b then push the pins 46a, 46b. which allows to operate the hammers 34a and 34b and to ring, respectively, the stamps 32a and 32b.

As will be understood below, the lifts can, thanks to their structure, be operated separately or together, depending on the shape and especially the thickness of the toothed sectors. In addition, in the case where one of the toothed sectors embraces the thickness of the two lifts, the relative positioning of the nozzles makes it possible to adjust the offset in time of hammer strike.

Set of ringing pieces (Figure 1)

Particularly to the invention, a ringing part 100 is pivotally mounted at A. It comprises a base 100a of generally triangular shape, the point A being located near one of the corners, and a rake 100b. The latter presents successively from left to right, along its outer edge, that is to say on the outside of the movement, a toothed sector of the hours 106 positioned, in the direction of the thickness of the mechanism, at the level of the lower lift 36b, a free space of teeth 104 whose role will appear later, and a toothed sector minutes minutes 102, positioned in the direction of the thickness of the mechanism, at the upper lift 36a. A hollow 107, visible on the Figures 4 to 7 and whose role will appear later, is provided at the level of the free space 104.

• un premier ressort 108 situé à proximité des secteurs dentés 102 et 106, et destiné à exercer une pression au niveau de l'espace libre 104, et
• un deuxième ressort 110 de type sautoir, dont le rôle apparaîtra plus loin, positionné au niveau d'un des angles de la base 100a à l'exclusion de celui portant le point A.

The bell part 100 carries on it:

• a first spring 108 located near the toothed sectors 102 and 106, and intended to exert pressure at the free space 104, and
• a second spring type jumper, whose role will appear later, positioned at one of the corners of the base 100a to the exclusion of that bearing the point A.

In addition, the bell part 100 carries, beneath it, a flip-flop 112 visible on the Figures 4 to 7 and pivoting at a point B. The latter is provided with a first pin 114 intended to cooperate with the ring driving wheel 22, and a second pin 116 rising on the dial side and passing through the piece 100 through an opening 118 As will be seen below, this pin 116 serves to actuate the rocker.

Furthermore, a spring 120 is fixed on one side to the plate and, on the other side to the striking piece 100 and exerts a force tending to drive the piece 100 in the SIAM. The stop means blocking the piece 100 will be explained hereinafter.

A part called trigger 122 is pivotally mounted at A on the striking piece 100 and is coupled thereto by a rod 124 (or a screw, for example) which passes through an oblong hole in the piece 100. The trigger 122 comprises a first 128 and a second arm 130 in the form of circular arcs, concentrically oriented to the driving wheel 22. The first arm 128 terminates with a probe 128a intended to collaborate with the snail minutes 24. The second arm 130 ends with a probe 130a intended to collaborate with the snail of hours 28.

In addition, the trigger 122 has a housing 132 in which takes place the pin 116 of the flip-flop 112. Thus, thanks to the clearance left by the oblong 126, the piece 100 can move relative to the trigger 122, which causes the pivoting of the rocker 112 and engages the pin 114 on the driving wheel 22.

The second arm 130 is provided on its outer edge with a lug 134 intended to cooperate with the spring 110. The latter positions the trigger 122 in abutment on one or other end of the oblong 126. It therefore forces the rocker 112 to be in one or other of its extreme positions, that is to say, engaged or completely disengaged.

With reference to the figure 6 , a quarter piece 136 is pivotally mounted, by known means, at a point C on the ringing piece 100. This piece 136 has, overall, the shape of a conventional ring rake. More particularly, one of its corners 136a delimits, on one side, a locking surface 136b and, on the other side, a bearing surface 136c. This is formed by the edge of the piece 136 located on the side of the center of the movement which draws a portion of a circle centered on the point A.

The quarter piece 136 has, in addition, a toothed portion 136d, arranged to be positioned in the free space 104. This portion 136d has only three teeth, respectively intended to ring the first, the second and the third quarter the current time. His thickness and its positioning allow the teeth to cross, in their race, the nozzles 130 of the two lifts 36. Given the structure of the latter described above, each tooth first actuates one 36b and then immediately afterwards. other 36a raises, thus producing the sound usually identifying the quarters.

In addition, the quarter part 136 is provided with a pressure surface 136e with which the spring 108 cooperates, exerting a force which tends to tilt the toothed portion 136e towards the center of the movement. Near this surface, the piece 136 has a shoulder 136g for cooperating with the recess 107 of the ringing part.

Finally, the piece 136 has a boss 136f. The latter and the toothed portion 136d are located on either side of the pivot point C. Thus, the boss makes it possible to actuate and rotate the workpiece 136.

A quarter control 138 is mounted, under the ringing piece 100, rotatable about the point A. It comprises a first arm 140 ending in a probe 140a intended to cooperate with the quarter snail 26. It comprises, in addition , a second arm 142 having a wedge 142a defining, on one side, a locking sector 142b, and, on the other side, a bearing sector 142c. This is formed by the edge of the arm 142 located on the periphery side of the movement and draws a portion of a circle centered on the point A. It will be explained hereinafter how the control 138 and the quarter piece 136 cooperate. .

As will be better understood below, a pin 144 is positioned in the plate to limit the stroke of the command 138 in the SIAM.

Breakaway organs

As we see best on Figures 4 to 7 , the second latch 18 mentioned above has a second hook 18b cooperating with a connecting rod 148 formed essentially of a first arm 148a and a second arm 148b. The rod is pivotally mounted on the plate at a point D located at the first end of the arm 148a. The arms 148a and 148b are articulated at a point E located at the second end of the arm 148a and at the first end of the arm 148b. A spring 150 connecting the first arm 148a at the second end of the second arm 148b exerts a force holding the arms of the rod in a semi-folded position.

The second end of the arm 148b has a first narrow cylindrical portion 152 and a larger diameter platen 154 for acting on the boss 136f of the quarter piece 136 to rotate it.

A pin 156 is fixed in the plate. It is truncated and has a flat part 156a intended to cooperate with the part 152 to guide the movement of the connecting rod 148.

When the pusher is pressed, the latch 18, via the hook 18b pushes the rod 148 near the point D so as to rotate around this point. The cylindrical portion 152 rests on the flat part 156a, and the arms 148a and 148b unfold, putting the spring 150 under tension. At the end of the race, the plate 154 pushes the boss 136f, then the portion 152 exceeds the flat. Under the effect of the spring 150, the rod 148 then resumes its initial position, in order to prevent the plate hinders the stroke of the quarter piece 136.

Rest position

For clarity, the figure 4 gives a close-up of the area specific to the rehearsal mechanism in the rest position. The sector 142b of the control 138 and the blocking surface 136b of the quarter part 136 are facing each other. Indeed, the spring 108 presses the part of the quarters 136, but it is positioned in abutment with the support of the shoulder 136g on the recess 107. The sector 142b and the surface 136b rely one on the other under the effect of the springs 120 and 108. With the spring 120, all the ringing parts is positioned by the support of the quarter control 138 on the pin 144 which form a stop member.

The rocker is not engaged on the driving wheel which does not rotate, the ringer barrel being kept blocked by the ratchet rocker 14.

The following paragraphs refer to Figures 5 to 7 and explain the operation of the mechanism during the ringing corresponding to the indication of 10:40.

recess

To operate the buzzer, the carrier presses on the pusher 16. On the one hand, this causes, via the latches 14 and 18, the release of the ringing barrel 10 which rotates the driving wheel 22. On the other hand, the rod 148 presses on the boss 136f and pivots the piece 136. The sector 142b and the blocking surface 136b, respectively of the control 138 and the quarter piece 136 slide over each other.

When, while the pivoting of the piece 136 continues, the wedges 136a and 142a escape from each other, all the ringing parts formed by the piece 100, the trigger 122 and the quarter piece 136, turn in the SIAM around the point A, until the probe hours 130a bears on the snail hour 28. The toothed sectors 102 and 136d operate the lifts 36 without any effect on the hammers . The ringing part 100 is positioned so that ten teeth are upstream of the lifts, that is to say they are ready to actuate them again when the ringing parts will turn in the SAM, with, this time, an effect on the hammers 34.

The relative movement of the ring pieces, particularly of the quarter piece 136, relative to the quarter control 138, brings the bearing surface 136c into contact with the bearing section 142c. The spring 108 presses on the pressure surface 136e of the quarter piece 136 which rests on the arm 142 of the quarter control 138. The toothed portion 136d remains at the toothed sectors of minutes 102 and hours 106 and is likely to cross the beaks 38 of the lifts 36.

The movement in the SIAM of all the ringing parts has the effect of engaging the latch 112 on the driving wheel 22. Due to the combined action of the jumper spring 110, the clutch occurs only after the Probe 130a took its information on the snail of hours 28.

Once engaged, the driving wheel 22 brings all the ringing parts back into the SAM. Under the effect of the pressure of the spring 108, the friction generated between the bearing surface 136c and the support sector 142c also drives the control of the quarters in the SAM.

The ten teeth of the hours sector 106 positioned upstream of the lift 36a successively cross the spout 38a and actuate the hammer 34a which strikes the stamp 20a to ring the ten strokes of the hours.

Then, still moved by the wheel 22, the teeth portion 136d in turn cross the beaks levées. Because of their thickness, they successively push the two lifts 36 and actuate the two hammers 34b and 34a which strike, in an offset manner, the stamps 32b and 32a to ring the quarters.

When, still driven by the friction of the striking piece, the probe 142b of the quarter control 138 is supported on the quarter snail 26 to take the information relative to the number of quarters of the current time, the piece 138 stops his movement. The corner 142a of the quarter control 138 is then positioned in such a way that when the corner 136a of the quarter piece 136 reaches the level of the corner 142a of the control, the number of teeth useful for the ringing crosses the lifts 36 .

In the example shown on the figure 6 (40 minutes), when two quarters sounded, all the ringing parts continuing their movement, the corners 136a and 142a escape again. The part of the quarters 136 is then no longer supported on the second arm 142 and tilts under the effect of the spring 108 until the shoulder 136g rests on the recess 107. In this way, the teeth of the quarter unnecessary to the ring (the third tooth in the example) are erased and do not cross the lifts 36 during the subsequent movement of the ringing parts.

The piece 100 and the quarter piece 136 continue their rotation, still under the action of the driving wheel 22. The teeth of the minutes sector 102 then cross the spout 38b of the lift 36b and push it successively to actuate the hammer 34b which hit the 20b stamp to ring the minutes.

The minute buzzer continues until the minute probe 128a comes to take its information on the minutes snail 24, which stops the trigger movement 122 ( figure 5 ). The number of teeth then crossed the lift 36b corresponds to the number of minutes to ring (10 in the example). The ringing part 100 is still driven by the wheel 22. Thanks to the oblong opening, the parts 100 and 122 then have a relative movement which actuates the rocker 112 and disengages the wheel 22.

All the ringing parts are then no longer driven, the spring 120 brings the rings and quarters in the rest position described above. The counting wheel 202 allows the barrel 10 to remain free during the cycle of the repetition mechanism.

Thus is proposed a minute repeater mechanism comprising a reduced number of parts. As a result, it is easier to set up and adjust, especially at the quarter ring level.

As a variant, the three teeth of the quarter sector can actuate non-coaxial lifts, but whose centers of rotation are very close. It suffices, indeed, that the distance between the two nozzles is less than the distance separating two consecutive teeth.

Claims (4)

1. Striking mechanism for timepiece movement comprising:

   • at least one resonant element (32) which can emit at least two sounds of different frequencies,

   • at least two pallets (36) disposed coaxially and each comprising:

   - a beak (38a, 38b) which cooperates with toothed sectors (102, 106, 136d) mounted mobile in said movement in order to cause said pallets (36) to rotate,

   - a positioning surface (40) whereon bears an elastic element (42) to keep the pallets (36) in their resting position, and

   - a pallet stone (44a, 44b)

   • at least two hammers (34a, 34b) each comprising a pin (46a, 46b) whereon said pallet stones (44a, 44b) act directly to cause them to strike said resonant element (32a, 32b),

   characterized in that the pallet stone (44a) of a first pallet (36) is positioned so as to act on the pin (46a) of a first hammer (34a) during an ascending phase of its rotational movement in a first direction, and in that the pallet stone (44b) of a second pallet (36b) is positioned so as to act on the pin (46b) of a second hammer (34b) during a descendant phase of its rotational movement in said first direction.
2. Striking mechanism according to claim 1, characterized in that the hammers (34a, 34b) are arranged on either side of said pallets (36).
3. Mechanism according to one of claims 1 and 2, characterized in that one of the hammers (34a, 34b) is coaxial with the pallets (36).
4. Striking mechanism according to one of claims 1 and 2, wherein said toothed sectors (102, 106, 136d) comprise an hour sector (106), a quarter sector (136d) and a minute sector (102), characterized in that the hour sector (106) is in the plane of the beak (38a, 38b) of only one of the pallets (36), the minute sector (102) in the plane of the beak of the other (38b, 38a) and the quarter sector (136d) embraces, in its thickness, the beaks (38a, 38b) of the two pallets (36).

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