CH716150A1 - Watchmaking mechanism for locking a jumping mobile and movement for a chronograph watch including it. - Google Patents

Abstract

The invention relates to a clock mechanism (1) for blocking a jumping mobile (40), comprising - a main control member (30), - a secondary control member (20), - said jumping mobile (40), comprising a set of teeth (401), - a rocker (10) arranged to pivot about an axis of rotation (100) under the action of the main control member (30) between - a raised position, in which the rocker (10) is remote from the jumping mobile (40) so that the jumping mobile (40) is free to rotate, and - a blocking position, in which the rocker (10) blocks the rotation of the jumping mobile (40) . The rocker (10) is also arranged to pivot around the axis of rotation (100) under the action of the secondary (20) and / or main (30) control member in order to occupy an intermediate position between the raised position and the locking position, and the rocker (10) also comprises an elastic element arranged to apply a stress on the jumping mobile (40) when the rocker (10) is in the intermediate position. The invention also relates to a movement for a chromograph watch comprising such a watch mechanism.

Description

Technical area

The present invention relates to a clock mechanism for blocking a jumping mobile.

State of the art

[0002] In this context, the expression “mobile” designates a mobile timepiece, that is to say which can be rotated. In this context, the expression "jumping mobile" designates a mobile which can be rotated by jumping or step by step. In particular, a jumping mobile carries or is linked to jumping information.

[0003] A wheel of a counter for a chronograph watch, for example a wheel of a minute or stopwatch seconds counter, is a non-limiting example of a jumping mobile. Such a wheel is generally linked to an indicator, for example a needle.

[0004] In the context of the present invention, the word “counter” indicates a means providing information relating to a counted duration. More precisely, a dial and an indicator form a counter. The needle is a non-limiting example of an indicator.

A disc, for example a disc which carries a jumping information such as the date (that is to say the serial number of each day in the month), the month, the day of the week, the name of the day of the week, the year, also the phases of the moon, etc., is another non-limiting example of a jumping mobile.

[0006] Known clockwork mechanisms for blocking a jumping mobile generally comprise a control member, for example a rotary control member, which may in particular be a cam or a column wheel. As these types of control members are known per se in the art, they will not be described here.

[0007] Known clockwork mechanisms for blocking a jumping mobile also include a rocker. The known rocker is arranged to pivot around an axis of rotation (real or virtual) under the action of the control member between <tb> - <SEP> a raised position, in which the rocker is moved away from the jumping mobile so that the jumping mobile is free to turn, and <tb> - <SEP> a blocking position, in which the rocker blocks the rotation of the jumping mobile.

[0008] In the case of a chronograph watch, for example, when the user actuates a control device (for example and without limitation a push-button) of the chronograph watch, the lever is in the raised position: the associated indicator the jumping mobile (a counter wheel in this case) and which is generally at rest on the zero division of the dial is therefore started (“START” phase).

[0009] A second actuation of the same control device or of another control device has the effect of putting the rocker in the locked position: in this case, the indicator stops at the precise point where it was at the time of this second actuation (“STOP” phase). The position of the indicator in the stop phase must be as precise as possible. In this way, it is possible to measure a duration in seconds, or in fractions of seconds such as 1 / 10ths etc.

[0010] In certain arrangements, by a third actuation, on the same control device or on another, the indicator quickly returns to its starting point, for example on the zero division of the dial (phase "RESET" or "RESET" A ZERO “or“ RESET ”).

[0011] In other arrangements, the measurement can be restarted from the stopping point, during a “RE-START” phase. In this case, from the "STOP" phase, a mechanism prevents pressing the "RESET" function. According to other arrangements, a function "FLYBACK" allows in the same position "START" and in a single sequence to carry out the functions "RESET" and "START" afterwards.

[0012] The three phases or functions of a chronograph watch are therefore the start or start, the stop or stop, and the reset or reset.

The stop and start phases are generally controlled by a control device other than that dedicated to the reset phase.

A possible known chronograph mechanism is the one with the column wheel which uses two push buttons or control devices, one for the start and stop functions and the other for the reset.

To perform these various operations, several systems have been developed, simple or complex depending on what it is desired to display and how. A large number of combinations and variations of mechanisms have been made depending on the type of control and display desired.

Conventional chronograph watches take the energy necessary for the operation of the part of the movement allowing the measurement of a duration, on the kinematic chain making it possible to count and display the current time, that is to say on the kinematic chain linking an energy source, for example a barrel, to the regulating member and to the watch wheels, which are linked to the watch indicators in order to display the hour, minutes and / or running seconds.

In order to take this energy necessary to set in motion the kinematic chain allowing the measurement of a temporal duration, it is necessary to perform a clutch between the kinematic chain linking an energy source (for example a barrel) to the regulator and to that which allows to measure a temporal duration.

[0018] There are different types of clutch devices known per se in the art, for example and without limitation vertical and horizontal clutch devices. These clutch devices will not be described here.

[0019] A jumping mobile can be associated with a heart. This heart is in turn associated with an indicator, for example a needle, which it allows to reset (or to control during the reset phase) and to orient in order to display the corresponding indications.

This heart can cooperate with a hammer, in order to perform functions such as reset to zero.

When a hammer tip is released from the core, for example in the case of a "START" after a "RESET", these two components being generally lubricated, there is a sticking effect. In other words, the hammer carries with it by a suction effect one of the sides of the flat of the heart and causes an unacceptable sudden rotation of the indicator. To overcome this phenomenon, most watchmaking solutions use permanent friction, like a foil, on the jumping mobile. However, this friction is by definition present during the operation of the jumping mobile and generates a significant consumption of energy, which may even become unacceptable, in particular for a high frequency needle.

In the case of a "RESET", when the hammer falls on a frictionless core, under certain conditions of contact angle, it can also occur an arching and instantly a rebound of the hammer and ultra rotation. -fast indicator.

[0023] It is therefore important to brake with friction the mobile jumping on the reset of a hammer-heart assembly. However, this friction is also present at the end of resetting, when the system reaches the critical position where the failure must come perfectly against the flat of the heart. At this time the system is at the end of its stroke and if the friction is too great, it can prevent precise zeroing of the needle.

[0024] There is therefore a need for a clock mechanism for blocking a jumping mobile free from these limitations of the prior art.

Brief summary of the invention

[0025] An object of the present invention is to provide a clockwork mechanism for blocking a jumping mobile free from known limitations.

Another object of the present invention is to provide a clockwork mechanism for blocking a jumping mobile without permanent friction, such as a foil, on the jumping mobile.

Another object of the present invention is to provide a watch mechanism for blocking a jumping mobile which allows a precise position of the hand after the execution of certain functions such as reset and stop.

[0028] According to the invention, these aims are achieved in particular by means of a clock mechanism for locking a jumping mobile according to claim 1.

The clockwork locking mechanism of a jumping mobile according to the invention comprises a main control member and a secondary control member. The two control members can actuate the rotation of a rocker around its axis of rotation.

The main control unit is generally actuated (directly or indirectly) by the user. It can be rotary, for example it can be a column wheel or a cam. The main control member can also move by a translational movement as in the case of a push button. The main control member can include both a member (s) which move (s) in a rotational movement and (s) member (s) which move (s) in a translational movement .

[0031] In the case of a chronograph watch, the secondary control member is a hammer, for example a hammer which cooperates with a heart associated with the jumping mobile. As a general rule, the secondary control member is a lever which acts on the jumping mobile.

[0032] The secondary control unit is generally actuated (directly or indirectly) by the main control unit. In other words, in one embodiment, the main control member is arranged to actuate on the one hand the rocker and on the other hand the secondary control member. The secondary controller can in turn actuate the rocker.

In one embodiment, during actuation of the latch by the main control member, the secondary control member does not actuate the latch and vice versa.

The clock mechanism for blocking a jumping mobile according to the invention also comprises: <tb> - <SEP> the jumping mobile, comprising a set of teeth, <tb> - <SEP> the rocker, arranged to pivot around an axis of rotation under the action of the main controller between <tb> <SEP> - <SEP> a raised position, in which the rocker is moved away from the jumping mobile so that the jumping mobile is free to turn, and <tb> <SEP> - <SEP> a blocking position, in which the rocker blocks the rotation of the jumping mobile.

According to the invention the rocker is also arranged to pivot about the axis of rotation under the action of the secondary control member and / or under the action of the main control member, in order to occupy an intermediate position between the raised position and the locked position.

According to the invention, the rocker also comprises an elastic element arranged to apply a stress on the jumping mobile when the rocker is in the intermediate position.

In other words, the elastic element of the rocker makes it possible to limit the freedom of the mobile jumping in the intermediate position, in order to allow the execution of certain functions (such as for example resetting in the case of (a chronograph watch or the date correction in the case of a date), without the indicator being able to rotate uncontrollably and / or at high speed, for example by braking the jumping mobile.

The clockwork locking mechanism of a jumping mobile according to the invention is advantageously devoid of permanent friction, such as a foil on the jumping mobile. The energy consumption of the mechanism according to the invention is therefore reduced compared to known solutions, in particular during the operating phase of the jumping mobile.

Thanks to this elastic element, the clockwork locking mechanism of a jumping mobile according to the invention also makes it possible to have a braking on the take-off of the hammer failure.

In one embodiment, the elastic element comprises a substantially rectilinear portion arranged to cooperate with the teeth of the jumping mobile, in order to apply the stress on the jumping mobile when the rocker is in the intermediate position.

In this context, the adverb "substantially" indicates that small variations can be tolerated, without departing from the scope of the invention or of its embodiments. For example, a portion is substantially rectilinear if its deviation from an exactly rectilinear portion is maximum 10% of the length of the portion. For example, a portion is substantially concentric with a rotation of an organ if its deviation from an exactly concentric portion is maximum 10% of the length of the portion.

[0042] In one embodiment, the rocker comprises a first arm extending from the axis of rotation, comprising a free end comprising a feeler to cooperate with the main control member.

In one embodiment, the rocker comprises a second arm extending from the axis of rotation, the second arm comprising a body and a free end which is substantially perpendicular to the body.

[0044] In one embodiment, this free end comprises a tooth arranged to cooperate with the teeth of the jumping mobile, in order to block the position of the jumping mobile in the blocking position. This allows precise positioning of the jumping mobile in the locked position.

[0045] In one embodiment, this free end comprises a hook.

[0046] In one embodiment, the elastic element is between the first arm and the second arm.

[0047] In one embodiment, the elastic element is a leaf spring.

In one embodiment, the elastic element comprises a finger, the elastic element being arranged to be armed by placing the finger behind the hook.

In one embodiment, the first arm comprises a portion substantially concentric with the rotation of the secondary control member about its axis of rotation, this portion being arranged to cooperate with the secondary control member or with a pin integral with the secondary control member, in order to drive the rocker in order to brake the jumping mobile during the intermediate position of the rocker. In one embodiment, the clockwork mechanism for blocking a jumping mobile according to the invention makes it possible to have braking during the fall of the secondary control member (a hammer for example) and this braking remains constant until at the end of the reset. In another variant, this braking can be gradually reduced (without canceling out) until the end of the reset.

In one embodiment, when the elastic element is armed, the body of the elastic element is substantially parallel to the body of the second arm of the lever.

In one embodiment, during actuation of the rocker by the main control member, the secondary control member does not actuate the latch and vice versa. This allows synchronization of functions.

In one embodiment, the secondary control member comprises a feeler to be actuated by the main control member.

In one embodiment, the latch is a single piece.

[0054] The present invention also relates to a movement for a chronograph watch comprising the horological mechanism according to the invention.

[0055] The present invention also relates to a chronograph watch comprising the horological mechanism or the movement according to the invention.

[0056] Other advantages and other embodiments of the invention are described in the following description and in the appended dependent claims.

Although some of the aforementioned advantages are associated more particularly with a mechanical timepiece, the invention is in no way limited to this type of timepiece. This timepiece could also be an electronic timepiece, in particular a quartz watch with a rotary display, in particular with an analog display. Likewise in the case of a mechanical timepiece, it may or may not be self-winding.

Brief description of the figures

Examples of implementation of the invention are indicated in the description illustrated by the appended figures in which: <tb> <SEP> FIG. 1 illustrates a perspective view of an embodiment of the horological mechanism according to the invention. <tb> <SEP> Figure 2 illustrates a top view of the watch mechanism of Figure 1. <tb> <SEP> FIG. 3 illustrates a perspective view of an embodiment of the rocker of the watch mechanism according to the invention, in a free or unarmed position, that is to say in a position in which the elastic element is not reinforced. <tb> <SEP> FIG. 4 illustrates a perspective view of the lever of FIG. 3, in an armed position, that is to say in a position in which the elastic element is armed. <tb> <SEP> FIG. 5 illustrates a perspective view of an embodiment of the rocker and of the secondary control member of the horological mechanism according to the invention. <tb> <SEP> FIG. 6 illustrates a top view of the watch mechanism of FIG. 1, in which the latch is in the intermediate position. <tb> <SEP> FIG. 7A illustrates a top view of the watch mechanism of FIG. 1, in which the latch is in a first phase of the raised position, which follows the intermediate position of FIG. 6. <tb> <SEP> FIG. 7B illustrates a top view of the clock mechanism of FIG. 1, in which the latch is in a second phase of the raised position, which follows the first phase of FIG. 7A. <tb> <SEP> FIG. 8 illustrates a top view of the watch mechanism of FIG. 1, in which the latch is in the blocked position. <tb> <SEP> FIG. 9A illustrates a top view of the watch mechanism of FIG. 1, in which the latch is in a first phase of the raised position, which follows the locking position of FIG. 8. <tb> <SEP> FIG. 9B illustrates a top view of the horological mechanism of FIG. 1, in which the latch is in a second phase of the raised position, which follows the first phase of FIG. 9A. <tb> <SEP> Figure 10 illustrates a sectional view of the watch mechanism along line A-A of Figure 6.

Example (s) of embodiment of the invention

In the following description provided by way of example, reference will be made, for the sake of simplification, to a counter wheel as an example of a jumping mobile. It should however be understood that the invention is not limited to such a jumping mobile, but also includes any other jumping mobile, such as for example a date disc.

The invention is also not limited to the field of horological mechanisms for chronograph watches, but also includes horological mechanisms for watches which are not necessarily chronograph watches.

In the case of a chronograph watch, the rocker is in the raised position in the start phase, it is in the intermediate position when a constraint is applied to the jumping mobile (a counter wheel for example), in particular in the starting phase. reset or at the beginning of a start phase after a reset, and it is in the blocked position in the stop phase.

In the case of a date, the rocker is in the raised position during the advancement of the jumping mobile, it is in an intermediate position when a constraint is applied to the jumping mobile (a date disc for example), in particular in phase of correcting the information displayed by the date, and it is in the blocking position when the jumping mobile is stopped.

The horological mechanism according to the invention is intended to be integrated into a movement for a timepiece, for example in a movement for a watch. This movement of the timepiece will not be described in detail here, insofar as this description is not necessary for an understanding of the invention.

FIG. 1 illustrates a perspective view of an embodiment of the watch mechanism 1 according to the invention. FIG. 2 illustrates a top view of the horological mechanism 1 of FIG. 1. In this embodiment illustrated in FIGS. 1 and 2, the horological mechanism 1 comprises: a main control member 30, in the example illustrated a column wheel, arranged to rotate around its axis of rotation 300, and a secondary control member 20, in the example illustrated a hammer, arranged to rotate around its axis of rotation 200.

The main control unit 30 is generally actuated (directly or indirectly) by the user. The secondary control unit 20 is generally actuated (directly or indirectly) by the main control unit 30.

In the example illustrated, the secondary control member 20 comprises a feeler 230 which cooperates (directly in the illustrated case) with the main control member 30 so that the main control member 30 can activate the secondary control unit 20.

In the example illustrated, the latch 10 also includes a feeler 130 which cooperates (directly in the illustrated case) with the main control member 30 so that the main control member 30 can actuate the latch 10.

In other words, in one embodiment, the main control member 30 is arranged to actuate on the one hand the rocker 10 (via the feeler 130) and on the other hand the secondary control member 20 (via the probe 230).

The secondary control member 20 is in turn arranged to actuate the latch 10. In the case illustrated in Figures 1 and 2, the actuation of the latch 10 by the secondary control member 20 is performed via a pin 50, integral with the secondary control member 20. During the rotation of the secondary control member 20, the pin 50 also rotates while moving along a portion 115 of a first arm 11 of the rocker 10. In one embodiment, this portion 115 has a shape that is concentric with the rotation of the secondary control member 20 about its axis 200.

The presence of the pin 50 is linked to the fact that in the example of Figures 1 and 2, the rocker 10 and the hammer 20 are superimposed, that is to say they belong to two different planes, as better visible in Figure 5. This makes it possible to reduce the horizontal space occupied by the mechanism according to the invention, while increasing its thickness. The height of the pin is greater than the thickness of the hammer, so that it can operate the rocker 10.

In another variant not shown, the lever 10 and the hammer 20 belong to the same plane. This makes it possible to reduce the thickness of the mechanism according to the invention, while increasing its horizontal occupation of space. In this case, a pin is not necessary, and the secondary control member 20 can be actuated directly, that is to say by direct contact, by the rocker 10.

In a preferred embodiment and as will be seen later, when actuating the latch 10 by the main control member 30, the secondary control member 20 does not actuate the latch 10 and vice versa.

The second control mechanism 20 in the example of Figures 1 and 2 is a hammer comprising a first arm 210 extending from the axis of rotation 200, the free end of which comprises a purlin arranged to cooperate with the heart 80 associated with the jumping mobile 40 in a known manner. The hammer also comprises a second arm 220 extending from the axis of rotation 200, the free end of which comprises a purlin arranged to cooperate with a core (not illustrated) associated with another mobile (not illustrated).

An adjustment eccentric 60 adjusts the distance between the first arm 210 and the second arm 220. In the example illustrated, the adjustment eccentric 60 is integral with the first arm 210 and comprises a notched portion 600, which cooperates with a roughness 260 of the second arm 220, visible in Figure 2.

In the example of Figures 1 and 2, the first arm 210 of the hammer cooperates with a second pin 70, which cooperates with a hammer jumper (not shown) to angularly position the hammer.

The mechanism 1 of Figures 1 and 2 also comprises the jumping mobile 40, in the example illustrated a counter wheel. In the example illustrated, the jumping mobile 40 comprises teeth 401 which are all equidistant. In another variant, at least a portion of the counter wheel 40 comprises teeth 401, in particular equidistant teeth 401. In another variation, at least a portion of the counter wheel 40 includes teeth 401 (slightly) non-equidistant. Two consecutive teeth are separated by a hollow 404.

The mechanism 1 of Figures 1 and 2 also comprises the rocker 10 which is arranged to pivot about the axis of rotation 100. This rocker 10 is best seen in Figure 3, which illustrates a perspective view of a embodiment of the rocker 10 in a free or unarmed position (that is to say in a position in which the elastic element is unarmed).

The rocker 10 of FIG. 3 comprises a first arm 11 extending from the axis of rotation 100, the free end of which comprises a feeler 130 to cooperate with the main control member. The feeler 130 in particular comprises a first portion forming a nose 1300 comprising two sides 1301 and 1302, as well as a second portion 1303, which is a substantially rectilinear portion in the illustrated case. The second portion is separated from the portion 115 intended to cooperate with the pin 50 by a roughness 1304.

The rocker 10 of Figure 3 also comprises a second arm 12 extending from the axis of rotation 100, the free end 120 of which is substantially perpendicular to the body 121 of the arm 12. This allows to create the space for the movement of the elastic element 14, as will be seen later.

In the variant of Figure 3, the free end 120 comprises a tooth 124 arranged to cooperate with the teeth of the jumping mobile, in order to block the position of the jumping mobile in the locking position. In particular, tooth 124 has a shape arranged to engage in a hollow 404 of the jumping mobile 40, thus locking its position. The tooth 124 in a preferred embodiment is pointed or it has a substantially triangular shape, the angle of the point being arranged to penetrate or slide between two consecutive teeth 401. In a preferred variant, the point is defined by two sides which press on the side surfaces defining the recess 404.

The blocking of the jumping mobile 40 can therefore be performed very precisely, to a tooth 401 of the jumping mobile 40.

The free end 120 of the second arm 12 also comprises a hook 123. In the example illustrated, this hook 123 is substantially perpendicular to the tooth 124. A substantially rectilinear portion 122 of the free end 120 of the second arm 12 separates the hook 123 from the body 121 of the arm.

In the example of Figure 3, the first arm 11 of the rocker 10 is substantially perpendicular to the second arm 12. However, this variant is not limiting and is mainly related to the arrangement of the other components of the watch mechanism 1 according to the invention and / or available to other components of the movement in which this mechanism 1 is placed.

In one embodiment, the angle α between the first arm 11 and the second arm 12 can vary in the range 30 ° -160 °.

In the variant of Figure 3, an elastic element 14 extends from the axis of rotation 100 between the first arm 11 and the second arm 12. The elastic element in the illustrated variant is a leaf spring having a first end 141 and a second end 140 which is free. The first end can be linked to the first arm 11, as in the example of FIG. 3, or to the second arm 12, provided that when the elastic element 14 is armed (as illustrated in FIG. 4), the body 141 the elastic element 14 is substantially parallel to the body of the second arm 12 of the lever.

In a variant, the width of the elastic element 14 is greater, in particular at least five times greater, than the smaller width of each of the arms 11 and 12.

In a preferred variant, the elastic element 14 and / or the entire rocker 10 is made of metal, for example of nickel or of a nickel alloy. In another variant, the elastic element 14 and / or the entire rocker 10 is made of silicon or of a silicon alloy.

In a preferred variant, the rocker 10 is a single piece. In another variant, the elastic element is a separate part which is connected, in particular by non-removable connection means, to a single piece comprising the first arm 11 and the second arm 12. In another variant, the elastic element 14, the first arm 11 and the second arm 12 are three separate parts which are connected together, in particular by non-removable connection means.

The free end 140 of the elastic element 14 comprises a finger 143. In a preferred variant, the elastic element 14 is arranged to arm itself by lifting the body 141 and bringing it closer to the second arm 12, as indicated by the arrow F1 in figure 4, so that the finger 143 is placed behind the hook 123 of the second arm 12. In this way, the elastic element 14 can only move with a rotational movement having its center in the end 145 in the space 240 delimited on the one hand by the second arm 12 and on the other hand by the position of the elastic element 14 when the finger 143 comes into contact with the hook 123, which prevents subsequently remove the elastic element 14 from the second arm 12.

After its manufacture the elastic element 14 is not armed, as illustrated in Figure 3. Before using it in the clock mechanism 1 according to the invention, it is necessary to arm it by placing the finger 143 behind hook 123.

The presence of the hook 123 implies a precise position of the elastic element 14 when the finger 143 comes into contact with the hook 123.

The elastic element 14 also comprises a surface 142, which is substantially perpendicular to the main direction of the elastic element 14, and which is intended to come into contact with the top of the teeth 401 of the jumping mobile when the rocker 10 is in an intermediate position, in order to apply a constraint on the jumping mobile 40, as illustrated for example in FIGS. 1 and 2. This surface therefore acts as a brake or as a pad. In this case, this pad is “integrated” into the elastic element.

In a variant not shown, the elastic element 14 has a substantially constant width over its entire length. In the example of Figures 1 to 4, the elastic element 14 comprises in correspondence of the free end a portion 144, which carries the finger 143 and which has a width L 'greater than the width L of the body 141 of the The resilient member 14. In this case, the portion 144 may comprise the surface 142 which acts as a pad. For this reason, the portion 144 can also be called a brake or a pad. It can form a single piece with the body 141 of the elastic element 14, or else be a separate part and linked with the body 141 of the elastic element 14, for example with non-removable connection means. The width L 'of the pad 144 makes it possible to compensate, if necessary, for the distance between the elastic element 14 and the jumping mobile 40.

The rocker 10 can also include one or more through openings 17 (two in the example of Figures 3 and 4) whose function is to reduce the weight of the rocker and / or better balance the rocker 10 in case of shocks.

The rocker 10 can also include another smaller through opening 19, which cooperates with a return spring (not shown) in order to press the rocker 10 against the main control member 30 and / or against the jumping mobile 40 .

The elastic element 14 is arranged to cooperate with the jumping mobile 40 when the rocker 10 is in an intermediate position, applying a constraint on the jumping mobile 40, in order to limit its freedom of rotation.

In particular, the rocker 10 can occupy three different positions: a raised position, in which it is not in contact with the jumping mobile, which is therefore free to turn; a blocking position, in which the tooth 124 is engaged in a hollow 404 of the jumping mobile 40, thus blocking its position; in this position the surface 142 of the pad 144 (or of the elastic element 14 in the case of an integrated pad) is in contact with the head of at least one tooth 401 and preferably at least two teeth 401 of the mobile jumping 40; an intermediate position between the raised position and the locked position; in this position, the tooth 124 is remote from the jumping mobile 40, which therefore a priori could be free to rotate, but the surface 142 of the pad 144 (or of the elastic element 14 in the case of an integrated pad) touches the head of at least one tooth 401 and preferably of at least two teeth 401 of the jumping mobile, thus limiting the freedom of rotation of the jumping mobile 40.

FIG. 6 illustrates a top view of the watch mechanism of FIG. 1, in which the rocker is in the intermediate position in the case of a resetting of the jumping mobile 40. This makes it possible to reset the jumping mobile. 40 by the action of the secondary control member 20 when the failure of the first arm 210 strikes the heart 80 of the jumping mobile 40.

Indeed, the tooth 124 is remote from the jumping mobile 40, which therefore a priori could be free to rotate, but the surface 142 of the pad 144 (or of the elastic element 14 in the case of an integrated pad) touches the head of several teeth 401 of the jumping mobile, thus limiting the freedom of rotation of the jumping mobile 40, which makes it possible to prevent the indicator associated with the core 80 from rotating in an uncontrolled manner and / or at high speed.

[0100] In the case of Figure 6, the rocker 10 has been actuated to go to this intermediate position by the secondary control member 20 via the interaction between the pin 50 and the portion 115 of the first arm 11 of the rocker 10.

[0101] In a preferred embodiment, the watch mechanism 1 according to the invention makes it possible to have a braking on the fall of the hammer 20, and which and until the end of the reset. Indeed in this embodiment the first arm 11 of the lever comprises a portion 115 substantially concentric with the rotation of the secondary control member and arranged to cooperate with the secondary control member or with a hammer pin, in order to 'drive the rocker 10 to brake the jumping mobile 40. In particular, the pin 50 moves along the portion 115 in the direction indicated by the arrow F2 in Figure 6: during this movement, the spout 124 remains away from the jumping mobile 40. In other words, the pin 50 allows the secondary control member 20 to act on the rocker 10, the purpose of which is to position the spout 124 in the intermediate position and to hold it there thanks to the shape of the lever. portion 115.

[0102] FIG. 7A illustrates a top view of the watch mechanism of FIG. 1, in which latch 10 is in a first phase of the raised position, which follows the intermediate position of FIG. 6 (start phase after a reset to zero).

[0103] During the initial rotation of the main control member 30 (a column wheel in this case), the secondary control member 20 switches in the counterclockwise direction indicated by the arrow F3 in FIG. 7A and releases the jumping mobile 40. In this case, the rocker 10 is actuated by the main control member 30 via the probe 130 but it is stationary thanks to the action of the pin 50 on the portion 115. Then, the side 1302 of the probe will remove braking entirely. In this first phase of the raised position, the duration of which is very short (for example of the order of a few microseconds), the tooth 124 is moved away from the jumping mobile 40 and the surface 142 from the pad 144 (or from the elastic element 14 in the case of an integrated shoe) touches the head of several teeth 401 of the jumping mobile, thus limiting the freedom of rotation of the jumping mobile 40, which makes it possible to brake the jumping mobile 40. This braking is carried out because the mobile jumping 40 could unlock before the secondary controller 20 begins to rotate. This makes it possible to counter the "suction cup" effect of the hammer 20 on the core 80.

[0104] FIG. 7B illustrates a top view of the watch mechanism of FIG. 1, in which latch 10 is in a second phase of the raised position, which follows the first phase of FIG. 7A (start phase after a reset to zero). In this case, the latch 10 is no longer actuated by the secondary control member 20 (for example, it can be seen that the pin 50 is no longer in contact with the latch 10), but its actuation is taken over by the control member. main control 30, via the feeler 130. In this phase, the elastic element is no longer in contact with the jumping mobile 40, which is therefore free to rotate. The rocker 10 is therefore passed from the intermediate position of FIG. 7A (braking of the board of the jumping mobile 40) to the raised position of FIG. 7B (without any contact with the jumping mobile 40).

[0105] FIG. 8 illustrates a top view of the watch mechanism of FIG. 1, in which the latch is in the locking position (stop).

In this case, the rocker 10 is actuated by the main control member 30, via the probe 130. Under the action of the main control member (the nose 1300 of the probe 130 falls into a column of the wheel column), the tooth 124 comes into contact with the teeth of the jumping mobile 40, by engaging in a hollow 404 and thus blocking the position of the jumping mobile 40. In this case, the surface 142 of the shoe 144 (or of the elastic element 14 in the case of an integrated shoe) touches the head of several teeth 401 of the jumping mobile.

[0107] FIG. 9A illustrates a top view of the watch mechanism of FIG. 1, in which latch 10 is in a first phase of the raised position, which follows the locking position of FIG. 8 (start phase after a stop).

In this case, the rocker 10 is still actuated by the main control member 30. In this first phase of the raised position, the tooth 124 is moved away from the jumping mobile 40 and the surface 142 of the pad 144 (or of the elastic element 14 in the case of an integrated pad) touches the head of several teeth 401 of the jumping mobile, thus limiting the freedom of rotation of the jumping mobile 40.

[0109] FIG. 9B illustrates a top view of the clock mechanism of FIG. 1, in which the latch is in a second phase of the raised position, which follows the first phase of FIG. 9A. This phase corresponds to the phase of FIG. 7B.

Reference numbers and signs used in figures

[0110] 1 Watch mechanism 10 Rocker 11 First arm of the rocker 12 Second arm of the rocker 14 Elastic element 17 First opening of the rocker 19 Second opening of the rocker 20 Secondary control member (hammer) 21 First arm of the device secondary control 22 Second arm of the secondary control device 30 Main control device 40 Jumping mobile 50 First pin 60 Adjustment eccentric 70 Second pin 80 Heart 100 Rotation axis of the rocker 110 Probe 115 Portion of the first arm 11 which cooperates with the pin 50 120 Free end of the second arm 12 121 Body of the arm 12 122 Portion adjacent to the hook 123 of the second arm 12 123 Hook of the second arm 12 124 Tooth of the second arm 12 130 Feeler of the rocker 10 140 Free end of the elastic element 14 141 Body of the elastic element 142 Surface of the elastic element which comes into contact with the teeth 401 143 Finger of the elastic element 144 Shoe (brake) 145 Extré non-free end of the elastic element 14 200 Axis of rotation of the secondary control member 210 Failure of the first arm 21 220 Failure of the second arm 22 230 Hammer feeler 20 240 Space between the elastic element 14 and the second arm 12 260 Asperity of the second arm 220 300 Rotation axis of the main control unit 400 Rotation axis of the jumping mobile 401 Teeth 404 Hollow 600 Notched portion of the adjustment eccentric 1300 First portion (nose) of the probe 130 1301 First side of the finger 1300 of the probe 130 1302 Second side of the finger 1300 of the probe 130 1303 Second portion of the probe 130 1304 Asperity of the probe 130 F1 Arrow F2 Arrow F3 Arrow L Width of the elastic element L 'Width of the element 144 α Angle between the first arm 11 and second arm 12

Claims (15)

1. Watchmaking mechanism (1) for blocking a jumping mobile (10), comprising - a main control unit (30), - a secondary control member (20), - said jumping mobile (40), comprising a set of teeth (401), - a rocker (10), said rocker (10) being arranged to pivot about an axis of rotation (100) under the action of the main control member (30) between - a raised position, in which the rocker (10) is moved away from the jumping mobile (40) so that the jumping mobile (40) is free to turn, and - a blocking position, in which the rocker (10) blocks the rotation of the jumping mobile (40), said rocker (10) also being arranged to pivot about said axis of rotation (100) under the action of the secondary control member (20) and / or the main control member (30) in order to occupy a intermediate position between the raised position and the locked position, said rocker (10) also comprising an elastic element (14) arranged to apply a stress on the jumping mobile (40) when said rocker (10) is in the intermediate position. 2. Watch mechanism (1) according to claim 1, said elastic element comprising a portion (142) substantially rectilinear arranged to cooperate with the teeth of the jumping mobile, in order to apply said stress on the jumping mobile (40) when said rocker ( 10) is in the middle position. 3. Watch mechanism (1) according to one of claims 1 or 2, said rocker (10) comprising a first arm (11) extending from the axis of rotation (100), the first arm (11) comprising a free end comprising a feeler (130) to cooperate with the main control member (30). 4. Watch mechanism (1) according to one of claims 1 to 3, said latch (10) comprising a second arm (12) extending from the axis of rotation (100), the second arm (12) comprising a body (121) and a free end (120), said free end (120) of the second arm (12) being substantially perpendicular to said body (121). 5. Watchmaking mechanism (1) according to claim 4, the free end (120) comprising a tooth (124) arranged to cooperate with the teeth (401) of the jumping mobile (40), in order to block the position of the jumping mobile ( 40) in the locked position. 6. Watch mechanism (1) according to one of claims 4 or 5, the free end (120) of the second arm (12) comprising a hook (123). 7. Watch mechanism (1) according to one of claims 4 to 6, said elastic element (14) being between the first arm and the second arm. 8. Watch mechanism (1) according to one of claims 1 to 7, said elastic element (14) being a leaf spring. 9. Watch mechanism (1) according to one of claims 6 to 8, said elastic element (14) comprising a finger (143), the elastic element being arranged to arm by placing the finger (143) behind said hook. (123). 10. Watch mechanism (1) according to one of claims 3 to 9, said first arm (11) comprising a portion (115) substantially concentric with the rotation of the secondary control member (20) about an axis of rotation (200) of the secondary control member (20), said portion (115) being arranged to cooperate with the secondary control member (20) or with a pin (50), in order to drive the rocker (10) ) to brake the jumping mobile (40) during the intermediate position of the rocker (10). 11. Watch mechanism (1) according to one of claims 9 or 10, wherein when the elastic element (14) is armed, a body (141) of the elastic element (14) is substantially parallel to the body (121 ) of the second arm (12) of the rocker (10). 12. Watch mechanism (1) according to one of claims 1 to 11, wherein when actuating the latch (10) by the main control member (10), the secondary control member (20) does not activate the rocker (10) and vice versa. 13. Watch mechanism (1) according to one of claims 1 to 12, wherein the secondary control member (20) comprises a feeler (230) to be actuated by the main control member (30). 14. Watch mechanism (1) according to one of claims 1 to 13, wherein the lever (10) is a single piece. 15. Movement for a chronograph watch comprising the horological mechanism 1 according to one of claims 1 to 14.