CH714406A1 - Mechanism for chronograph watch movement. - Google Patents

Abstract

The invention relates to a mechanism for chronograph watch movement comprising: - a counter wheel of a determined time (2), different from the wheel of the second chronograph (3), - an oscillating pinion (10) comprising: • a first tooth arrangement arranged to mesh with a power source (1, 1') of movement, • a second toothing arranged to move under the action of an actuating device (210, 220), so as to mesh with the counter wheel of a given time (2), thereby realizing an oscillating pinion clutch between the energy source (1, 1') and the counter wheel of a predetermined time (2). The mechanism according to the invention aims to separate the movement of the counter wheel by a predetermined time (2) from that of the second chronograph wheel (3) by means of an oscillating pinion (10).

Description

Description TECHNICAL FIELD [0001] The present invention relates to a mechanism for chronograph watch movement. The present invention also relates to a chronograph watch movement comprising such a mechanism, as well as a chronograph watch, in particular a wristwatch chronograph watch, comprising such a movement.

STATE OF THE ART [0002] A chronograph watch is a time device that makes it possible to measure duration. On the other hand, the chronometer is a precision time machine. A chronograph may or may not be a chronometer.

As a general rule, a chronograph watch is a watch comprising at least one indicator such as a needle which can be turned on, then stopped, by means of a pusher or other control device, in order to measure a duration. Then it can be brought back to its starting point. Many chronographs also have indicators for displaying the current time in addition to displaying the measured duration.

When one exerts a first pressure on a pusher (or another control device) of a chronograph watch, the indicator or second-hand needle (also called "second chronograph indicator" or "second chronograph hand" ), which is at rest on the zero division of the dial, starts ("START" phase), A second pressure on the same pusher or on another pusher has the effect of stopping the second hand at the precise point where it was during this pressure ("STOP" phase). By a third pressure, on the same pusher or on another, the second hand quickly returns to its starting point, that is to say on the zero division of the dial ("RESET" phase), In this way, it is possible to measure a duration in seconds.

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

The phases of "STOP" and "RESET" are generally controlled by another pusher than the one dedicated to the "START" phase.

A possible known chronograph mechanism is the one with the column wheel that uses two pushers or control devices, one for the "START" and "STOP" functions, the other for the reset ("RESET") ), [0008] To perform these various operations, several systems have been developed, simple or complex depending on what you want to display and how. A large number of combinations and variants of mechanisms have been made depending on the type of control and display desired.

The usual chronograph watches take the energy necessary for the operation of the part of the movement for measuring a duration, on the kinematic chain for counting and display the current time, that is to say on the kinematic chain linking an energy source, for example a cylinder, to the regulating member and to the wheels of the watch, which are linked to the indicators of the watch so as to display the hour, the minutes and / or the current seconds.

In the context of the present invention, the word "wheel" indicates a mobile which can be rotated and which allows a clutch with a toothing of another mobile. In a preferred embodiment, a wheel is a gear wheel. Such a wheel is generally linked to an indicator, for example a needle.

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.

In order to take this energy necessary to put in motion the kinematic chain for measuring a time duration, it is necessary to achieve a clutch between the kinematic chain linking a power source (for example a cylinder) to the regulating organ and that which makes it possible to measure a temporal duration.

[0013] Two main organs are used in the majority of the operations of the chronograph watch mechanisms, namely control devices and clutch devices.

The control devices can be cam or column wheel. As they are known per se in the field of technology, they will not be described here.

Known clutch devices can engage the seconds wheel of the current time (also called "second movement wheel" or "seconds wheel") to the second chronograph wheel. The second chronograph wheel is used to drive a seconds indicator that makes a full turn of the dial when the time has reached an integer of seconds, in most cases sixty seconds.

Then, the second chronograph wheel causes, for example through a multiplier gear, other wheels that can count a time timed, usually a chronograph minute wheel, or even a chronograph hour wheel .

In other words, the energy from the "base movement", that is to say the movement that displays the current time (seconds, minutes and / or hours) is then redistributed to different wheels that allow to count a time timed directly by the wheel of the second chronograph.

Different types of clutch devices, including vertical and horizontal clutch devices, are known.

Vertical clutch devices allow a so-called "vertical" clutch between the two kinematic chains, in particular between a wheel of a kinematic chain (that which makes it possible to determine the current time) and a wheel of the other chain. kinematic (the one that allows a measurement of a duration).

In the case of a vertical clutch, the transmission of energy is not by teeth, but by friction, for example on the wheel surfaces. The advantage of this type of clutch is that the drive of the counter that allows the measurement of a time duration is without starting jump. This clutch is compact and well suited for high volume productions. On the other hand, it is expensive because of the high number of pieces and its development remains rather difficult.

Documents CH 705 988 and CH 709 162 describe a clutch of the vertical type.

Lateral or horizontal clutch devices allow to couple two wheels by contacting them by their periphery (toothing). The disadvantage of this type of clutch is that when driving the counting wheel a timed time it is possible to have a departure jump caused by a misalignment of the teeth of the two wheels. The gap is all the smaller as there are teeth. However teeth with many teeth are difficult to manufacture and more prone to wear. In this type of device, there is no movement of oscillation or tilting of the elements of these devices.

EP 2 570 869 discloses a lateral or horizontal clutch device.

There are also oscillating gear clutch devices, which allow a transmission of energy from the second wheel to that of the second chronograph using an oscillating pinion. This oscillating pinion has a first toothing which is in permanent contact with the seconds wheel. This oscillating pinion, under the action of an actuating device such as a rocker, oscillates or tilts, so that its second toothing comes into contact with the wheel of the second chronograph, thereby also rotating it .

Document CH 700 808 discloses an oscillating pinion clutch device between the second movement wheel and the second chronograph wheel.

As mentioned, the energy of the chronograph second wheel is then redistributed to the different wheels that allow the measurement of a duration, including the chronograph minute wheel and the chronograph hour wheel.

However, the chronograph second wheel is one of the components where there is the least energy. Thus, any disturbance on this wheel, for example disturbances related to the fact that this wheel drives the chronograph minute wheels and chronograph hours, will have consequences on the operation of the various other mechanisms of the basic movement that allows to measure and display the current time, to which the second chronograph wheel is linked via the second movement wheel. For example, any disturbance on the second chronograph wheel will have consequences on the accuracy of the basic movement, the power reserve of the basic movement, etc.

In addition, in the mechanisms for chronograph watch movement known, the setting or the focus of the chronograph minute wheels and / or chronograph hours is complicated, because of their dependence on the second chronograph wheel.

Finally, the arrangement of mechanisms for chronograph watch movement known leads to a large footprint, which is undesirable in the case of certain movements of a chronograph watch.

BRIEF SUMMARY OF THE INVENTION An object of the present invention is therefore to provide a mechanism for chronograph watch movement which is less sensitive to disturbances with respect to known mechanisms.

Another object of the present invention is therefore to provide a mechanism for chronograph watch movement in which the focus of the wheels minutes and / or hours is less complicated.

Another object of the present invention is therefore to provide a mechanism for chronograph watch movement which generates less congestion than the known mechanisms.

Another object of the present invention is therefore to provide a mechanism for chronograph watch movement free from the limitations of known mechanisms.

According to the invention, these objects are achieved in particular by means of a chronograph watch movement mechanism comprising: a power source, a second chronograph wheel, a counter wheel of a determined time, different from the second chronograph wheel, an oscillating gear operating device, and this oscillating gear comprising: a first set of teeth arranged to mesh with the energy source of the movement; a second set of teeth arranged to move under the first gear; action of the actuating device so as to mesh with the counter wheel by a predetermined time, thereby realizing an oscillating pinion clutch between the energy source and the counter wheel of a predetermined time.

According to the invention, the counter wheel of a given time is thus driven solely by the energy source via the oscillating pinion, so that the rotation of the second chronograph wheel is not disturbed by the rotation of the counter wheel by a determined time.

In other words, the mechanism according to the invention makes it possible to dissociate the function of the wheel of the second chronograph from that of a given time counter, for example a counter of the minutes or timed hours, for the purpose not to disturb the movement of the basic movement when the chronograph is engaged.

The mechanism according to the invention thus makes it possible to separate the movement (or rotation) of the second chronograph wheel from that (or that) of the counter wheel by a predetermined time. In other words, the second chronograph wheel of the mechanism according to the invention no longer causes the counter wheel of a predetermined time. This also means that in the mechanism according to the invention there is never any contact between the second chronograph wheel and the counter wheel of a predetermined time. In other words, the transmission chain or kinematic chain of the mechanism according to the invention connects the second chronograph wheel and the counter wheel of a given time, only via the energy source and no other path.

In addition, as the oscillating pinion allows an oscillating pinion clutch between the energy source and the meter wheel of a predetermined time, the energy to drive the meter wheel of a given time is taken on a source of energy that has more energy than the second chronograph wheel. Consequently, the disturbances on this energy source will have no effect on the counter wheel for a given time, or will have a much lower incidence than the state of the art based on the second wheel energy chronograph. Finally, the disturbances on this source of energy will have no impact on the regulating organ of the basic movement, or will have a much lower incidence than that of the state of the art.

In other words, the counter wheel of a given time is no longer driven by the second chronograph wheel. It takes its energy from a source of energy providing it with much greater energy than that provided by the second chronograph wheel, and therefore less sensitive to disturbances.

In the context of the present invention, the expression "energy source" indicates a barrel or a linked intermediate mobile, particularly directly related to the barrel, that is to say in contact with a barrel.

It is therefore clear that a mobile that is connected to the barrel via a chain of other mobile, for example via a gear train, is not a source of energy in this context. For example, the second movement wheel is not a source of energy as defined in the context of this invention.

As explained above, the invention therefore aims to dissociate the movement of the counter wheel by a certain time from that of the wheel of the second chronograph using an oscillating pinion which is disposed between this counter wheel of a certain time and this second chronograph wheel. This separation and the presence of the oscillating pinion makes it possible to simplify the development and the operation of the counter wheel by a predetermined time, since this counter wheel of a given time is no longer driven by the wheel of the wheels. second chronograph. In addition, the oscillating pinion allows better access to the counter wheel of a given time.

This separation and the presence of the oscillating pinion also allow a space-saving arrangement while significantly reducing the starting jump to the counter wheel of a predetermined time.

In a preferred embodiment this counter wheel of a predetermined time is a chronograph minute wheel. In other words, in this preferred embodiment, the counter wheel of a predetermined time is a counter wheel N minutes, N being a positive integer. For example, it is a counter wheel sixty minutes (N = 60): it allows to drive a chronograph minute indicator that makes a full turn of a dial when the time has reached sixty minutes. In another variant, it is a counter wheel thirty minutes (N = 30): it allows to drive a chronograph minute indicator that makes a full turn of a dial when the time has reached thirty minutes. Any other integer N could be considered, in particular N = 45.

In another variant, this counter wheel of a predetermined time is a chronograph hour wheel. In other words, in this variant, the counter wheel of a predetermined time is a counter wheel M hours, M being a positive integer. For example, it is a twelve-hour counter wheel (M = 12): it allows to drive a chronograph hour indicator that makes a complete turn of a dial when the measured time reaches twelve hours. Any other integer number M could in principle be considered.

The mechanism according to the invention offers a large number of possibilities for the counters N minutes and / or M hours, because N and M can be chosen according to the gear ratios between the energy source and the wheel of counter of a predetermined time, the number of teeth of the energy source and / or the counter wheel of a given time, and / or according to their spacings.

According to an independent aspect of the invention, the counter wheel of a predetermined time is replaced by a downward wheel.

In a preferred variant, the oscillating gear is a first oscillating gear and the actuating device is a first actuating device. In this variant, the mechanism according to the invention also comprises: - a second movement wheel, - a second chronograph wheel, - a second oscillating gear.

This second oscillating gear comprises: - a first set of teeth arranged to mesh with the wheel of the second movement; a second set of teeth arranged to move under the action of the first actuating device or of a second actuating device, so as to mesh with the wheel of the second chronograph, thus producing an oscillating pinion clutch between the wheel second movement and second chronograph wheel.

The mechanism according to the invention in this variant thus comprises two oscillating gears. In this variant, the number of teeth of the second toothing of the first oscillating gear may be equal to the number of teeth of the second toothing of the second oscillating gear, which further simplifies the adjustment of the mechanism according to the invention. In other variants, the number of teeth of the second toothing of the first oscillating gear may be smaller or greater than the number of teeth of the second toothing of the second oscillating gear.

In a preferred embodiment, the counter wheel of a predetermined time is a first wheel and the mechanism according to the invention comprises a second counter wheel of a predetermined time. For example, if the first counter wheel of a given time is a chronograph minute wheel, the second wheel may be a chronograph hour wheel.

In this preferred embodiment, the mechanism comprises a third oscillating pinion making an oscillating pinion clutch between the energy source (or another source of energy) and the second counter wheel of a predetermined time.

For example the energy source is an intermediate mobile directly in contact with a cylinder, which can mesh on the one hand with the second toothing of the first oscillating pinion and on the other hand with the second toothing of the third oscillating pinion. thus making it possible to rotate, for example, a chronograph minute wheel (cooperating with the first oscillating gear) and a chronograph hour wheel (cooperating with the third oscillating gear).

In another example, the energy source cooperating with the first oscillating gear is different from that cooperating with the third oscillating gear. For example, the energy source cooperating with the first oscillating gear is a first intermediate gear in contact with a first toothing of a double-toothed cylinder, and the energy source cooperating with the third oscillating gear is a second intermediate gear. contact with a second toothing of the double-toothed cylinder.

In a variant, this third oscillating gear is actuated by the first actuating device (for example a rocker that can actuate either the first oscillating gear only, or both the first and the second oscillating gear).

In another variant, this third oscillating gear is actuated by the second actuating device which also actuates the second oscillating gear.

In yet another variant, this third oscillating pinion is actuated by a third actuating device which does not actuate any other oscillating pinion.

In all cases, the third oscillating pinion comprises a first set of teeth arranged to mesh with a source of energy of the movement and a second set of teeth arranged to move under the action of an actuating device (the first, the second or a third actuating device), so as to mesh with the second counter wheel by a predetermined time, thereby producing a swinging gear clutch between the energy source and the second counter wheel of a determined time.

The skilled person therefore understands that it is possible to add a fourth counter wheel of a determined time associated with a fourth oscillating pinion, this fourth oscillating pinion being actuated by an actuating device which already actuates another oscillating gear, or by another actuating device, and producing an oscillating pinion clutch between this fourth counter wheel and a movement energy source (for example a barrel, an intermediate mobile directly connected to the barrel and co-operating already with another oscillating pinion or another intermediate mobile directly connected to the barrel which cooperates only with the fourth oscillating pinion).

The skilled person will also understand that it is possible to continue adding a fifth, sixth, and so on. counter wheel of a determined time, each additional wheel being associated with a new oscillating gear, which new oscillating gear is actuated by an additional actuating device or by an actuating device which already actuates another oscillating gear, and realizing an oscillating pinion clutch between this wheel and an additional energy source (for example another intermediate mobile directly connected to the barrel which cooperates only with the additional oscillating pinion) or by a source of energy of the movement already cooperating with another swinging gear.

In a variant, the mechanism according to the invention comprises the first actuating device. This first actuating device can be arranged to control both the first and the second oscillating gear (and also any additional oscillating gear), which reduces the number of components of the mechanism and therefore its cost and bulk.

In another variant, the mechanism according to the invention comprises a second actuating device which makes it possible to control the second oscillating gear, the first oscillating gear being actuated by the first actuating device.

In a variant, the first actuating device and / or the second actuating device (and / or any other additional actuating device cooperating with any other additional gear) is a flip-flop.

In a variant, the mechanism according to the invention comprises a control device actuating the first and / or the second actuating device and / or any other additional actuation device, this control device being for example a device cam and / or column wheel control.

In a variant, the oscillating gear comprises more than two teeth on its axis. In this variant it is thus possible to achieve a double clutch with a single oscillating gear.

The invention also relates to a chronograph watch movement comprising the mechanism according to the invention.

In a variant, the mechanism according to the invention is a module that can be integrated into an already existing watch movement. For example, this module can be sold separately from the watch movement in which it can be integrated.

The invention also relates to a chronograph watch comprising the chronograph watch movement according to the invention.

BRIEF DESCRIPTION OF THE FIGURES [0069] Examples of implementation of the invention are indicated in the description illustrated by the appended figures in which:

Fig. 1 illustrates a sectional view of an embodiment of the mechanism according to the invention.

Fig. 2 illustrates a perspective view of an embodiment of the oscillating gear of the mechanism according to the invention.

Fig. 3 illustrates a front view of an embodiment of a chronograph watch according to the invention.

Fig. 4 illustrates a perspective view of an embodiment of a movement according to the invention.

Fig. 5 illustrates a top view of the embodiment of the movement of FIG. 4.

Fig. 6 illustrates the top view of FIG. 5, without the second chronograph wheel.

Fig. 7 illustrates a sectional view of an embodiment of a movement according to the invention.

Fig. 8 illustrates another sectional view of an embodiment of a movement according to the invention, the first oscillating pin being in contact with the counter wheel for a predetermined time and the second oscillating pinion being in contact with the seconds wheel chronograph.

Fig. 9 illustrates a sectional view of the embodiment of FIG. 8, the first oscillating gear not being in contact with the counter wheel for a predetermined time and the second oscillating gear not being in contact with the second chronograph wheel.

Example (s) of embodiment (s) of the invention [0070] FIG. 1 illustrates a sectional view of an embodiment of the mechanism according to the invention which comprises: a counter wheel of a determined time 2, this counter wheel having a predetermined time 2 being different from the seconds wheel; chronograph, and - an oscillating gear 10, allowing the clutch between a power source 1 and the counter wheel of a determined time 2.

In the following, reference will be made to a chronograph minute wheel as a counter wheel of a predetermined time. However, the invention is not limited to this embodiment and it includes any counter wheel of a predetermined time as far as it is different from the second chronograph wheel. For example, such a wheel may be a chronograph hour wheel.

The oscillating pinion 10, visible in perspective in FIG. 2, comprises an axis of the oscillating pinion 100 comprising two ends or pivots 1100 and 1200, which allow the cooperation of the oscillating pinion 10 with a plate respectively a rocker 210. In particular, the oscillating pinion 10 pivots between a plate and a rocker 210 (see for example Fig. 4). In the variant shown, these two ends 1100 and 1200 have a smaller section than that of the axis 100.

In correspondence of the first end 1100 (the lower end in FIG 1, for example dial face), the oscillating pinion 10 comprises a first toothing 110. A power source 1 meshes with the lower gear 110 of the pinion In a preferred variant, the contact between the energy source 1 and the lower toothing 110 is continuous and permanently. The oscillating gear 10 is thus rotated about the main axis of its axis 100.

In a variant (not shown) the oscillating pinion 10 may comprise more than two teeth on its axis. In this variant it is thus possible to achieve a double clutch with a single oscillating gear.

In the context of the present invention, the expression "energy source" indicates a barrel or a linked intermediate mobile, for example directly connected to the barrel.

For example, as it is visible in FIG. 4, the energy source is an intermediate mobile 1 directly connected to the barrel 1 '. In another variant, the energy source which meshes with the lower toothing 110 of the oscillating gear 10 is the barrel 1 'itself.

A "source of energy" in this context therefore indicates a mobile that can provide another mobile energy much greater than that the second chronograph wheel could provide.

In correspondence with the second end 1200 (that of the top in Fig. 1, for example on the bridge side), the oscillating gear 10 comprises a second toothing or wheel 120. This toothing 120 of FIG. 1 is in contact with the chronograph minute wheel 2.

In FIG. 2, the number of teeth of the first toothing 110 is different from that of the second toothing 120. However, it is possible to also provide an oscillating pinion in which the number of teeth of the first toothing 110 is equal to that of the second. toothing 120.

The oscillating pinion 10 also cooperates in correspondence of the second end 120 of the axis 100 with an actuating device of the oscillating pinion 210, for example a rocker, which is controlled by a control device, cam or column wheel, not shown in this figure.

A control device 8 is for example visible in FIGS. 4-6.

Under the action of this control device 8, and through the rocker 210, the second end 1200 of the axis 100 of the oscillating pinion 10 moves, including oscillates or rocker so that the upper toothing 120 comes into contact with the chronograph minute wheel 2. During the displacement of the second end 1200 of the axis 100 of the oscillating gear 10, the first end 1100 substantially maintains its position, thus ensuring the maintenance of the contact between the energy source 1 and the lower toothing 110 of the oscillating gear 10, and thus the rotation of the oscillating gear 10. In other words, under the action of the control device and thanks to the rocker 210, the oscillating gear 10 pivots around the end 1100, so that the upper toothing 120 comes into contact or meshes with the chronograph minute wheel 2.

When the upper toothing 120 comes into contact with the chronograph minute wheel 2, the rotational energy of the oscillating pinion 10 is transferred to the chronograph minute wheel 2, which therefore starts to rotate. In other words, as the oscillating pinion 10, and thus its upper toothing 120 is rotated, a rotational movement is transmitted to the chronograph minute wheel 2 following this contact. In this way, a swinging gear clutch between the chronograph minute wheel 2 and the energy source 1 is realized.

The latch 210 generally has two states: - first state: it allows a meshing between the second set of teeth 120 and the chronograph minute wheel 2; - Second state: it does not allow meshing between the second set of teeth 120 and the chronograph minute wheel 2.

The illustrated oscillating pinion clutch device has the advantage of significantly reducing the starting jump (retreat or step advance) of the chronograph minute wheel 2 when the chronograph is switched on.

As the oscillating pinion 10 allows an oscillating pinion clutch between the energy source 1 and the chronograph minute wheel 2, the energy to drive the chronograph minute wheel 2 is taken from an energy source 1 which has more energy compared to the chronograph second wheel 3, which is visible for example in FIG. 4. Consequently, the disturbances on this energy source 1 will have no impact on the chronograph minute wheel 2, or will have a much lower incidence than the known mechanisms.

The movement of the chronograph minute wheel 2 is thus completely disconnected from that of the second chronograph wheel 3. This is made possible by means of a provision according to the invention of the oscillating gear 10.

According to the invention, the chronograph minute wheel 2 is thus driven solely by the energy source via the oscillating pinion 10, so that the rotation of the wheel of the second chronograph 3 is not disturbed by the rotation of the chronograph minute wheel 2.

In other words, the mechanism according to the invention makes it possible to dissociate the function (therefore the movement) of the wheel of the second chronograph 3 from the function (therefore of the movement) of the chronograph minute 2, with the aim of not not interfere with the movement of the basic movement when the chronograph is engaged. This separation also makes it possible to simplify the development and operation of the chronograph minute wheel 2, since it is no longer driven by the wheel of the second chronographs 3. The simplification is also obtained by the presence of the oscillating gear 10, which allows an improvement of the meshing compared to a traditional system.

This separation and the presence of the oscillating pinion 10 also allow a space-saving arrangement while significantly reducing the starting jump to the chronograph minute wheel 2.

In the variant illustrated in FIGS. 4 to 9, the counter wheel of a predetermined time is a chronograph minute wheel 2. In other words, in this preferred embodiment, the counter wheel of a predetermined time is a counter wheel N minutes, N being a number positive integer (N = 15,30,45,60, etc.). It allows to drive a chronograph minute indicator (for example the indicator MC visible in Fig. 3) which makes a complete revolution of a dial C1 when the time measured reaches N minutes.

In another variant, this counter wheel of a predetermined time is a chronograph hour wheel. In other words, in this variant, the counter wheel of a predetermined time is a counter wheel M hours, M being a positive integer. It allows to drive a chronograph hour indicator (for example the HC indicator visible in Fig. 3) which makes a complete turn of a dial C2 when the measured time reaches M hours.

The mechanism according to the invention offers a large number of possibilities for the counters N minutes and / or M hours, because N and M can be chosen according to the gear ratios between the energy source 1 or 1 ' and the counter wheel of a predetermined time, the number of teeth of the energy source and / or the counter wheel of a given time, and / or according to their spacings.

In the variants of FIGS. 4 to 9, the mechanism 1000 according to the invention also comprises: a wheel of the second movement 4, a wheel of the second chronograph 3, a second oscillating gear 20.

This second oscillating gear 20 comprises: a first set of teeth arranged to mesh with the wheel of the second movement 4; a second set of teeth arranged to move under the action of a second actuating device 220, so as to mesh with the wheel of the second chronograph 3, thus producing an oscillating pinion clutch between the wheel of the second movement 4 and the second seconds wheel chronograph 3.

In another variant, not shown, the same actuating device 210 which actuates the first oscillating gear can actuate the second oscillating gear 20 or vice versa.

In a preferred embodiment (not shown), the mechanism according to the invention comprises a second counter wheel of a predetermined time. For example, if the first counter wheel of a given time is a chronograph minute wheel, the second wheel may be a chronograph hour wheel.

In this preferred embodiment, the mechanism comprises a third oscillating pinion making an oscillating pinion clutch between the energy source (or another energy source) and the second counter wheel of a predetermined time.

For example the energy source is an intermediate mobile 1 directly in contact with a barrel 1 ', which can mesh on the one hand with the second toothing of the first oscillating gear 10 and on the other hand with the second set of teeth. of the third oscillating pinion, thus making it possible to rotate, for example, a chronograph minute wheel 2 (cooperating with the first oscillating gear 10) and a chronograph hour wheel (cooperating with the third oscillating gear).

In another example, the energy source cooperating with the first oscillating gear is different from that cooperating with the third oscillating gear. For example, the source of energy cooperating with the first oscillating gear is a first intermediate gear 1 in contact with a first toothing of a double-toothed gear, and the energy source cooperating with the third oscillating gear is a second intermediate gear in contact with a second toothing of the double-toothed cylinder.

In a variant, this third oscillating gear is actuated by the first actuating device (for example a rocker that can actuate either the first oscillating gear only, or both the first and the second oscillating gear).

In another variant, this third oscillating gear is actuated by the second actuating device which also actuates the second oscillating gear.

In yet another variant, this third oscillating gear is actuated by a third actuating device which does not actuate any other oscillating gear.

In all cases, the third oscillating pinion comprises a first set of teeth arranged to mesh with a source of energy of the movement and a second set of teeth arranged to move under the action of an actuating device (the first, the second or a third actuating device), so as to mesh with this other counter wheel for a predetermined time, thereby producing a swinging gear clutch between the energy source and the second counter wheel of a determined time.

Those skilled in the art will also understand that it is possible to continue to add a fourth, fifth, sixth, and so on. counter wheel of a determined time, each new wheel being associated with a new oscillating pinion, actuated by a new actuating device or by an actuating device which already actuates another oscillating pinion, and producing a swinging pinion clutch between this wheel and a new energy source of the movement (for example another intermediate mobile directly connected to the barrel which cooperates only with the new oscillating pinion) or by a source of energy of the movement already cooperating with another oscillating pinion.

In another variant, the chronograph hour wheel is not driven by means of an oscillating pinion by an energy source, but it is in direct contact with the energy source (for example the barrel) and kept permanently braked if it must not move to allow the display of a measured time.

In a preferred variant, the number of teeth of the second toothing of the first oscillating gear 10 is equal to the number of teeth of the second toothing of the second oscillating gear 20 and / or the third oscillating gear (and / or of any other oscillating pinion), which further simplifies the adjustment of the mechanism according to the invention.

As can be seen for example in FIG. 4, the second chronograph wheel 3 and the chronograph minute wheel 2 are associated with the heart 33 respectively 22. Each heart is associated with an indicator, for example a needle, that can be controlled and oriented to display the corresponding indications. For example, the axis of a needle can be mounted directly on the axis of the corresponding heart, one linked to this axis of the heart by means of a gear chain as short as possible, for example a wheel and a pinion .

Thus, the heart 22 is associated with the chronograph minute indicator MC, visible in FIG. 3, where it is placed at three o'clock. The heart 33 is associated with the second chronograph indicator SC, visible in FIG. 3, where it is placed in the center. Another heart not shown is associated with the chronograph hours indicator HC, visible in FIG. 3, where it is placed at nine o'clock. Of course, the position of the indicators on the watch 2000 of FIG. 3 is non-limiting and any other position may be considered.

In a variant, the chronograph time indicators (SC, MC and / or HC) move continuously, that is to say without jumps or "dragging". In another variant, the mechanism could be arranged so that they move "step by step".

[0111] FIG. 8 illustrates a sectional view of an embodiment of a movement according to the invention, wherein a pusher (or another control device) "START" (not visible) of the chronograph watch has been engaged: indeed not only is the second oscillating gear 20 in contact with the second chronograph wheel 3 (reference T2 in Fig. 8), but also the first oscillating gear 10 is in contact with the chronograph minute wheel 2 (reference T-ι in Fig. 8). In this variant, the oscillating gears 10, 20 are substantially perpendicular to the faces of the wheels illustrated when they come into contact with the wheel of the second chronograph 3 respectively with the chronograph minute wheel 2.

[0112] FIG. 9 illustrates the sectional view of the embodiment of FIG. 8, when the pusher (or other control device) "STOP" (not visible) is selected. Indeed, the second oscillating gear 20 is no longer in contact with the second chronograph wheel 3 (reference E2 in Fig. 9, indicating the space between the second oscillating gear 20 and the second chronograph wheel 3), and also the first oscillating gear 10 is no longer in contact with the chronograph minute wheel 2 (reference E1 in Fig. 9 indicating the space between the first oscillating gear 10 and the chronograph minute wheel 2). In this variant, the oscillating gears 10, 20 are inclined to the faces of the illustrated wheels.

According to an independent aspect of the invention, the counter wheel of a predetermined time, the second chronograph wheel, the actuating device and the oscillating gear of the mechanism according to the invention form a module or kit which can be integrated into an already existing watch movement. For example, this module can be sold separately from the watch movement in which it can be integrated. In a preferred embodiment, this module is integrated in the bridge side (that is to say the opposite side of the dial) of an existing watch movement.

Reference numbers used in figures [0114] 1 Intermediate mobile 1 'Barrel 2 Chronograph minute wheel 3 Chronograph second wheels 4 Second wheels 6 Exhaust wheel 7 Adjusting gear 8 Column wheel 9 Train 10 First swing gear 20 Second oscillating gear 22 Core 33 Core 100 First oscillating gear 110 First gear of first oscillating gear 120 Second gear of first oscillating gear 210 First actuator 220 Second actuator 1000 Movement 1100 First end of axis 100 1200 Second end of axis 100 2000 Chronograph watch H Hour indicator M SC minute indicator Chronograph second indicator MC Chronograph minute indicator HC Chronograph hour indicator C1 First dial C2 Second dial E-ι Space E2 Space T-ι Contact T 2 Contact

Claims (13)

claims 1. Mechanism for chronograph watch movement comprising: - a source of energy (1, 1 '), - a second chronograph wheel (3), - a counter wheel of a predetermined time (2), said wheel being different from the chronograph second wheel (3), - an oscillating gear operating device (10), - said oscillating gear (10) comprising: • a first toothing (110) arranged to mesh with said source energy (1, 1 ') of the movement, • a second toothing (120) arranged to move under the action of said actuating device (210, 220), so as to mesh with the counter wheel by a predetermined time (2), thereby providing a swing pinion clutch between the energy source (1, 1 ') and the counter wheel of a predetermined time (2), said counter wheel of a determined time (2) being thus driven solely by the energy source (1, 1 ') via said oscillating pinion (10), so that that the rotation of the second chronograph wheel (3) is separated from the rotation of the counter wheel by a predetermined time (2). 2. Mechanism according to claim 1, the counter wheel of a predetermined time (2) being a chronograph minute wheel. 3. Mechanism according to claim 1, the counter wheel of a predetermined time (2) being a chronograph hour wheel. 4. Mechanism according to one of claims 1 to 3, said oscillating gear being a first oscillating gear, said actuating device being a first actuating device, said mechanism comprising: a wheel of the second movement (4), a second actuating device (220), - a second oscillating gear (20) comprising: • a first set of teeth arranged to mesh with the wheel of the second movement (4), • a second toothing arranged to move under the action of the first actuating device (210) or said second actuating device (220), so as to mesh with the wheel of the second chronograph (3), thus producing a swinging gear clutch between the second movement wheel (4) and the second chronograph wheel (3). 5. Mechanism according to one of claims 1 to 4, said counter wheel of a predetermined time being a first counter wheel of a given time and said energy source being a first energy source (1), said mechanism comprising: - a third actuating device, - a second counter wheel of a determined time, - a third oscillating gear comprising: • a first set of teeth arranged to mesh with said first energy source of the movement (1) or with a second energy source of the movement (1 '), • a second toothing arranged to move under the action of said first actuating device or said third actuating device, so as to mesh with said second wheel of counter of a determined time, thus realizing a swinging gear clutch between the first or the second energy source and the second counter wheel of a predetermined time mine. 6. Mechanism according to claim 5, the first counter wheel of a given time being a chronograph minute wheel (2) and the second counting wheel of a predetermined time being a chronograph hour wheel. 7. Mechanism according to one of claims 1 to 6, the number of teeth of the second toothing of the first oscillating gear (10) being equal to the number of teeth of the second toothing of the second oscillating gear (20) and / or to the number of teeth of the second toothing of the third oscillating gear. 8. Mechanism according to one of claims 1 to 7, the first actuator (210) and / or the second actuator (220) being a rocker. 9. Mechanism according to one of claims 1 to 8, comprising a control device (8) actuating the first and / or the second actuating device, said control device (8) being for example a cam control device and / or column wheel. 10. Mechanism according to one of claims 1 to 9, said energy source being a cylinder (1 ') or an intermediate mobile (1) which meshes with said barrel (1'). 11. Mechanism according to one of claims 1 to 3, said oscillating gear (10) comprising more than two teeth. 12. Chronograph watch movement comprising the mechanism according to one of claims 1 to 11. 13. Chronograph watch comprising the movement according to claim 12.