EP4328673A1 - Cam timepiece mechanism - Google Patents

Abstract

Clockwork mechanism comprising a kinematic chain comprising a first mobile (2, 2') fixed in rotation around a first axis of rotation (20, 20') and a second mobile (3, 3') fixed in rotation around 'a second axis of rotation (30, 30'), the first mobile (2, 2') being engaged with the second mobile (3, 3') at a contact point (4), the first mobile (2, 2') being configured to be driven directly or indirectly by a motor member and to directly drive the second mobile (3, 3'), a cam (1) for measuring and/or storing time information, the cam (1) comprising a variable diameter profile with at least one step (11) and at least one jump (12), the cam (1) being directly or indirectly driven by the second mobile (3, 3'), and a feeler to read the time information by pressing against the profile of the cam (1), characterized in that the first mobile (2, 2') and the second mobile (3, 3') are non-circular mobiles with combined profiles, and in that the kinematic chain is configured so that the ratio (R1/R2) between a first distance (R1) measured between the first axis of rotation (20, 20') and the contact point (4) and a second distance (R2) measured between the second axis of rotation (30, 30') and the contact point (4) is greater when the at least one step (12) faces the feeler than when part of the at least a step (11) is opposite the feeler. Timepiece comprising a watch movement and such a watch mechanism.

Description

The present invention relates to a cam clock mechanism. The present invention relates in particular to a cam clock mechanism in which the kinematic chain driving the cam comprises a pair of non-circular mobiles with conjugate profiles in direct engagement with each other and configured to allow optimal reading of the information transmitted by the cam.

Cams are commonly used in watchmaking, for example to measure and/or memorize time information which will be read by a probe resting against the profile of the cam. Typically, the probe is fixed to the end of a lever, the other end of the lever being configured to operate, for example, a display mechanism or a buzzer depending on the information read on the cam. Such cam mechanisms are used for example in dates, in repeaters or passing chimes, in chronographs, etc.

In certain applications, the information transmitted by the cam resides in the value of the diameter of the cam, for example in the height of a step located opposite the probe. If the cam includes several steps, each step can correspond for example to a discrete value of time information, for example a number of fractions of a second measured by a chronograph mechanism, a number of hours, quarter hours and /or minutes to sound, a day of the week to display, etc. The feeler is then preferably brought into contact with the profile of the cam at the request of a user or at times determined by the watch mechanism.

In other applications, the information transmitted by the cam resides in the passage opposite the probe of a jump in the profile of the cam, that is to say of a very short segment comprising a significant variation in the radius of the cam. The probe is then, for example, in continuous contact with the profile of the cam during its rotation and causes, for example, the incrementing of the display of a date or the triggering of a bell.

Whatever the application, the passage of a jump in the profile of the cam opposite the probe is a critical moment because it corresponds to a transition phase between two states of the watch mechanism. Positioning errors of the cam, in particular a jump in the profile, relative to the probe, due for example to the manufacturing tolerances of the parts and the different operating clearances, can lead to errors in reading the information on the cam and/or a time difference in the display of information.

In the case of snails, that is to say cams comprising one or more arms each comprising several steps, it is known to use an additional mechanical device called surprise in order to avoid any error if a reading of the information is requested while a jump between the highest and lowest rung is near the reading point. This safety device is fixed on the snail and extends the highest rung if a reading of the information is requested at that time. A disadvantage of this solution is that it is relatively bulky. The surprise in fact increases the thickness of the cam and therefore takes up space in height, for example in a watch case. Additionally, ordering the surprise requires adding additional parts. In addition, adjustments, for example by filing, must often be made on the “beak” of the probe to ensure correct reading on the steps of the snails.

An aim of the present invention is to propose a watch mechanism with cam having high reliability in reading information on a cam while being relatively compact and simple to produce.

This aim is achieved using the watch mechanism as claimed in claim 1 and a timepiece according to claim 10.

This goal and other advantages are achieved in particular by a clock mechanism comprising a kinematic chain comprising a first mobile fixed in rotation around a first axis of rotation and a second mobile fixed in rotation around a second axis of rotation rotation, the first mobile being engaged with the second mobile at a point of contact, the first mobile being configured to be driven directly or indirectly by a motor member and to directly drive the second mobile, a cam for measuring and/or memorization of time information, the cam comprising a profile with diameter variable with at least one step and at least one jump, the cam being directly or indirectly driven by the second mobile, and a sensor for reading the time information by pressing against the profile of the cam, the first mobile and the second mobile being non-circular mobiles with conjugate profiles, and the kinematic chain being configured so that the ratio between a first distance measured between the first axis of rotation and the point of contact and a second distance measured between the second axis of rotation and the point of contact contact is greater when the at least one step is facing the feeler than when part of the at least one step is facing the feeler. Preferably, the kinematic chain is configured so that the ratio between a first distance measured between the first axis of rotation and the point of contact and a second distance measured between the second axis of rotation and the point of contact is greater when the at least one step is facing the feeler only when the middle of at least one step is facing the feeler.

The use of non-circular mobiles for driving the cam thus makes it possible to modulate the rotational movement of the cam and ensure that the angular pitch of the cam is greater when passing a jump in the profile of the cam. cam facing the feeler only when passing a step, or at least part of a step, facing the feeler. In this way, the transition between two states of the watch mechanism occurs quickly, thus avoiding errors in reading and representing the information transmitted by the cam.

The first mobile and/or the second mobile has for example a profile in the shape of an ellipse and/or in the shape of a polygsteroid.

The first mobile and the second mobile are for example configured so that the second mobile makes a complete turn around the second axis of rotation when the first mobile makes a complete turn around the first axis of rotation.

According to other embodiments, the first mobile and the second mobile are configured so that the second mobile makes a whole number of complete turns around the second axis of rotation when the first mobile makes a complete turn around the first axis of rotation. rotation, or so that the second mobile makes a complete turn around the second axis of rotation when the first mobile completes a whole number of complete revolutions around the first axis of rotation.

Preferably, the cam comprises an integer number of steps and the same integer number of jumps, each jump being separated from the next jump along the profile by a step, the first mobile and the second mobile being configured so that the ratio between the first distance and the second distance are always greater when any of the jumps are facing the feeler than when any of the steps are facing the feeler.

The clock mechanism is for example a chronograph mechanism or a date mechanism or a repeater or passing chime mechanism.

The aim stated above and other advantages are also achieved by a timepiece comprising a watch movement and such a clockwork mechanism.

• La figure 1 illustre une came sous la forme d'un colimaçon comprenant un bras unique avec dix échelons ;
• La figure 2 illustre un engrenage non circulaire selon une forme d'exécution de l'invention ;
• La figure 3 illustre la modulation du pas angulaire obtenu à l'aide de l'engrenage de la figure 3 ;
• La figure 4 illustre un mécanisme horloger selon une forme d'exécution de l'invention ;
• La figure 5 illustre un mécanisme horloger selon une autre forme d'exécution de l'invention.

The present invention will be better understood on reading the detailed description illustrated by the figures, where:

• There figure 1 illustrates a cam in the form of a spiral comprising a single arm with ten rungs;
• There figure 2 illustrates a non-circular gear according to one embodiment of the invention;
• There Figure 3 illustrates the modulation of the angular pitch obtained using the gear of the Figure 3 ;
• There figure 4 illustrates a watch mechanism according to one embodiment of the invention;
• There figure 5 illustrates a watch mechanism according to another embodiment of the invention.

There figure 1 illustrates by way of example a cam 1 in the form of a snail whose peripheral profile comprises ten steps 11 and ten jumps 12, each step 11 being separated from the next step 11 by a jump 12. Such a cam in a watch mechanism allows for example to measure and/or memorize time information that can take ten distinct discrete values, for example example a number from zero to nine corresponding to a fraction of time: minutes, seconds, fraction of a second, or any other time information.

The information is read in a known manner, for example using a feeler, not shown in the figures, resting against the profile of the snail 1. The value of the information is determined by the height of the step 11 at the reading point, that is to say at the radius of the snail 1 facing the probe. The representation of the value read is then done in a manner also known, for example using a needle, a disk associated with an aperture, a ringing mechanism. The feeler is for example fixed to one end of a lever whose axis of rotation is fixed relative to the axis of rotation 10 of the cam 1, while the other end of the lever is linked to the representation mechanism of the information which is configured to represent the value read on the cam by the probe.

According to the invention, the cam 1 is rotated around its axis 10 by a kinematic chain comprising at least two non-circular mobiles in engagement with one another. An example of non-circular mobiles according to the invention is illustrated in figure 2 . According to this embodiment, the non-circular mobiles are two elliptical toothed wheels 2, 3 whose primitive profiles are combined, so that they remain constantly engaged with one another when they rotate around their axes of rotation 20, 30 respectively. Depending on the embodiment, the teeth aim at the center of rotation or are normal to the primitive. In the illustrated embodiment, the pitch profiles of the two elliptical gears 2, 3 are configured so that the average transmission ratio is 1, the driven elliptical gear 3 making exactly one complete revolution when the driving elliptical gear 2 makes a complete turn.

The toothed wheels 2, 3 being non-circular, their respective radii R1, R2 at the contact point 4, that is to say the distance measured between their respective axes of rotation 20, 30 and the contact point 4 corresponding to the point contact of the primitive trajectories of the toothed wheels 2, 3, vary according to their angular position. The ratio between the angular velocities of two mobiles engaged with one another being inversely proportional to the ratio between their radii at the point of contact, the ratio between the angular velocities of the elliptical toothed wheels 2, 3 also varies depending on their angular position. As illustrated in schematically Figure 3 for non-circular mobiles 2, 3 illustrated in figure 2 , this ratio varies periodically and passes through a maximum a1 and a minimum a2 at each revolution of the elliptical toothed wheels 2, 3.

Other forms of execution are however possible within the scope of the invention. It is for example possible to consider a non-circular gear whose gear ratio is different from 1 and/or whose mobiles have a more complex shape than an ellipse, for example in the shape of a star, as explained below. . The number of absolute or relative maxima or minima of the ratio of angular speeds per revolution of one or the other of the mobiles can then differ from 1.

The elliptical toothed wheels 2, 3 are for example driven by a mechanical watch movement. They then rotate step by step and the ratio between the angular steps of the elliptical gears 2, 3 also varies in a similar manner. The driving elliptical toothed wheel 2 is for example driven directly or indirectly by a watch movement at a constant rotation speed, that is to say with a constant angular pitch. Therefore, the angular pitch of the driven elliptical gear 3 varies to achieve a maximum angular pitch α1 and a minimum angular pitch a2 with each complete revolution.

It is however possible to drive the non-circular gear of the invention by other means and/or at a different rhythm, for example by a continuous and/or non-constant movement.

According to the invention, the kinematic chain driving the cam 1 and comprising two non-circular mobiles, is configured so that the angular pitch of the cam is higher when a jump passes opposite the probe than when a more central part of a step is next to the probe. In other words, the kinematic chain driving the cam 1 and comprising the two non-circular mobiles is configured so that the angular speed of the cam is higher when the position of the cam corresponds to a transition phase between two states of the cam. watch mechanism only when the position of the cam corresponds to another moment of such a phase.

In the case of a non-circular gear such as that illustrated in figure 2 driving a cam 1 such as that illustrated in figure 1 , for example, the cam 1 is for example driven by the driven wheel 3 through a reduction gear not shown, or reduction gear, with a ratio 1:10 configured so that the elliptical toothed wheels 2, 3 are in an angular position corresponding to the maximum angular pitch a1 each time a jump 12 of the cam 1 is opposite or close to the feeler and that the elliptical toothed wheels 2, 3 are in an angular position corresponding to the minimum angular step a2 each time the center of a step 11 is facing or close to the feeler. In this way, the rotation of the snail 1 is slowed down when the central parts of the rungs 11 are facing the feeler and accelerated when the jumps 12 pass facing the feeler.

Other configurations of the non-circular mobiles and/or the cam are however possible within the framework of the invention. For example, the profiles of the non-circular mobiles can be chosen so that the average transmission ratio is different from 1. Furthermore, the cam can take any appropriate shape to transmit discrete time information and include for example a single jump and a single rung, or several arms each comprising one or more jumps and rungs, etc. It is also possible in the context of the invention to combine several non-circular gears in a gear train to generate at the output variations in angular speed adapted to snails which have steps whose pitch is not constant, or to generate at output a rotation with a constant angular speed while certain intermediate mobiles rotate at variable angular speeds.

According to a first example, the watch mechanism of the invention is a chronograph mechanism with digital display configured to allow the counting and display of time information to the tenth of a second, part of the kinematic chain of which is illustrated schematically in there figure 4 . The digital display of the measured time is done for example in a known manner using a display mechanism not shown, comprising discs carrying numbers to be displayed through apertures. The digits include, for example, a tenths of a second digit, a seconds digit, a tens of a second digit, etc. According to certain embodiments, the display mechanism is for example mixed, including the display of numbers for the tenths of a second, seconds and tens of seconds, and a display by hand, for example retrograde, for minutes and/or hours.

The chronograph mechanism is preferably intended to be integrated into a timepiece, for example in a wristwatch, and is configured to be driven by a motor member, for example the movement of the timepiece and/or a dedicated motor organ. For reasons of readability, the motor unit is not shown in the figures. The motor organ is for example a mechanical movement whose frequency is 5Hz, thus taking one step every tenth of a second. When the chronograph is activated, a chronograph wheel 5 of the chronograph mechanism is rotated by the motor member, for example via a clutch wheel not shown and/or by restarting the member engine.

The chronograph movement further comprises a cam 1, for example for measuring and storing the unit digit of seconds, and a cam 9, for example for measuring and storing tenths of a second. These cams 1, 9 are rotated by the movement of the chronograph wheel 5 during timing through the kinematic chain 5, 6, 7, 2, 3 of the chronograph mechanism. When the timing is stopped, the cams 1, 9 are immobilized and the information concerning the number of seconds measured and concerning the number of tenths of a second measured during timing is then read on the profile of each cam 1, 9 by a probe respective and displayed, for example by a specific display mechanism on a dedicated part of the dial of the wristwatch. The cams 1, 9 are for example snails like the one illustrated in figure 1 , that is to say snails each comprising ten rungs 11 separated by ten jumps 12, each rung corresponding to a value from zero to nine. During timing, the seconds snail 1 rotates one revolution every ten seconds, while the tenths of a second snail 9 completes one revolution per second.

The kinematic chain of the chronograph mechanism comprises the chronograph wheel 5 which drives a multiplicative gear train comprising for example two mobiles 6, 7 which in turn drive the tenths of a second snail 9. During timing, the chronograph wheel 5 performs for example A revolution per minute. The multiplicative cog 6, 7 is configured so that the tenths of a second snail 9 completes one revolution per second. The frequency of the watch movement being 5 Hz, the tenths of a second snail 9 thus takes ten steps of 36° per complete revolution. The angular position of the tenths of a second snail 9 on its axis is preferably determined so that at each step the middle of a step of the tenths of a second snail 9 is positioned opposite the corresponding feeler.

According to the invention, the seconds cochlea 1 is driven by means of non-circular mobiles, for example by means of two elliptical toothed wheels 2, 3 with combined profiles, to complete one revolution in ten seconds during timing. The driving elliptical toothed wheel 2 is for example integral in rotation with the tenths of a second snail 9 and drives the driven elliptical toothed wheel 3 at the same frequency, i.e. one revolution per second. The driven elliptical toothed wheel 3 then drives the second snail 1 via a reduction gear having a transmission ratio of 1:10, comprising for example a pinion 4 coaxial and integral with the driven elliptical toothed wheel 3 and a wheel 13 driven by pinion 4, coaxial and integral with seconds cam 1.

The non-circular mobiles 2, 3 of the chronograph mechanism being elliptical, the angular pitch of the elliptical driven gear wheel 3 passes through a maximum and a minimum at each revolution, as illustrated in Figure Figure 3 . The seconds cochlea 1 being driven by the driven elliptical mobile 3 via the reduction gear 4, 13 having a transmission ratio of 1:10, its angular speed, and therefore its angular pitch, passes through ten maxima and through ten minimums in each round. According to the invention, the seconds snail 1 is oriented on its axis in such a way that the angular pitch is at a maximum when a jump of the tenths of a second snail 1 is opposite or at least in the immediate vicinity of the tenths feeler of seconds, and that the angular step is at a minimum when the middle of a step 11 of the seconds snail 1 is opposite or at least in the immediate vicinity of the seconds feeler.

The seconds snail 1 being configured to complete one revolution in ten seconds and the frequency of the watch movement being 5Hz, the snail seconds 1 takes ten steps per second, or one hundred steps per revolution. The average angular pitch is therefore theoretically 3.6°. According to the invention, it has been calculated that with elliptical wheels 2, 3 measuring for example 4 mm x 2.2 mm, the maximum pitch of the tenths of a second snail is 21.98°. By arranging the snail in such a way that the angular step is maximum when a jump 12 passes opposite or is at least in the immediate vicinity of the tenths of a second feeler, it is possible to prevent a reading of the measured time from occurring. made on a jump 12 or on the end of a rung, despite the possible positioning errors due to the manufacturing precision of the mobiles of the kinematic chain, which can lead to positioning errors of a few degrees. Those skilled in the art will understand that the angular position of the cam 1 relative to the angular position of the non-elliptical cog will be determined as a function of the angular position of the feeler relative to the axis 10 of the cam.

For reasons of readability, only the cams 9, 1 allowing the measurement and storage of the unit digit of the seconds measured and the tenths of a second are represented. The chronograph movement, however, preferably includes a third cam for measuring and storing the tens digit of the seconds measured. The third cam thus comprises, for example, six steps and six jumps and performs one revolution per minute. The tens of a second cam is for example driven by a gear train driven by the seconds wheel 13 or by another mobile part of the chronograph movement. The tens of a second cam is for example also driven via a non-circular gear train.

There figure 5 illustrates another form of execution of a chronograph movement according to the invention. According to this other form of execution, the kinematic chain comprises a multiplier cog 6, 8 to drive the tenths of a second cog 9 on the one hand, and a multiplier cog 6, 2', 3' to drive the seconds cog 1 According to this embodiment, the kinematic chain 6, 2', 3' driving the seconds cochlea 1 comprises a first non-circular mobile 2' in the form of a polygastrooid mobile with five branches and a second non-circular mobile 3 ' to the conjugated profile in the form of a polygastroid mobile with ten branches. The average transmission ratio between the two non-linear mobiles is therefore 1:2, the driven polygasteroid mobile 3' making a complete revolution while the leading polygasteroid mobile 2' makes two.

The seconds cochlea 1 is integral in rotation with the driven polygsteroid mobile 3' which completes one revolution in ten seconds, with a step every tenth of a second. During timing, the angular speed of the driving polygsteroid mobile 2' is preferably regular, while the angular speed of the driven polygsteroid mobile 3' passes through ten maxima and ten minima at each complete revolution. The angular position of the seconds snail 1 relative to the angular position of the polygasteroid mobiles 2', 3' is then chosen so that the angular step is at a maximum when a jump of the seconds snail 1 is opposite the feeler of the seconds seconds, and that the angular step is at a minimum when the middle of a step 11 of the seconds snail 1 is opposite the seconds feeler.

According to yet another embodiment of the invention, the watch mechanism is a repetition or passing striking mechanism. In known manner, one or more cams with an appropriate number of steps are used to determine the hours, quarter hours and/or minutes to strike on demand and/or at the passage of the said hour.

According to the invention, one or more cams of the repeater or passing ringing mechanism are driven by a kinematic chain similar to the kinematic chains described above and comprising at least a first non-circular mobile leading driven directly or indirectly by a movement of shows, engaged with a second non-circular mobile driven to the profile conjugate to that of the first non-circular mobile. The cam(s) driven by this kinematic chain are then arranged angularly so that the angular speed of the cam is maximum when a jump in their profile passes opposite the corresponding probe and the angular speed is minimum when the middle of a step is next to the probe. Preferably, the number of maxima and minima of the angular speed, or of the angular pitch per complete revolution of the cam corresponds to the number of jumps and of steps that the profile includes. In this way, the reading of the time for an on-demand ringing and/or the time accuracy of the ringing can be optimized without the use of a surprise mechanism.

According to another embodiment, the watch mechanism of the invention is a date mechanism. In known manner, the date mechanism comprises for example a single jump cam to increment the date display and/or a cam comprising several jumps and several steps corresponding for example to the months of the year and/or the days of the week.

According to the invention, one or more of these cams are driven by a kinematic chain comprising at least a first non-circular mobile leading into engagement with a second non-circular driven mobile which in turn drives one or more cams. The cam(s) are preferably arranged on the kinematic chain so that their angular speed is maximum at the time of the date change, that is to say when a jump in their profile passes opposite the corresponding probe, for example a tracking probe configured to increment a date display. The cam, for example a single-step, single-step cam, is driven by the watch movement via the kinematic chain of the date mechanism of the invention. The cam, for example, completes one revolution in twenty-four hours and is accelerated when the time displayed by the timepiece, for example a wristwatch, approaches midnight, so that the change in the date display be done as quickly as possible and as close to midnight as possible.

Claims (10)

Clockwork mechanism including: - a kinematic chain comprising a first mobile (2, 2') fixed in rotation around a first axis of rotation (20, 20') and a second mobile (3, 3') fixed in rotation around a second axis of rotation (30, 30'), the first mobile (2, 2') being engaged with the second mobile (3, 3') at a contact point (4), the first mobile (2, 2') being configured to be driven directly or indirectly by a motor unit and to directly drive the second mobile (3, 3'), - a cam (1) for measuring and/or storing time information, the cam (1) comprising a variable diameter profile with at least one step (11) and at least one jump (12), the cam (1) being directly or indirectly driven by the second mobile (3, 3'), and - a feeler to read the time information by pressing against the profile of the cam (1), characterized in that the first mobile (2, 2') and the second mobile (3, 3') are non-circular mobiles with conjugate profiles, and in that the kinematic chain is configured so that the ratio (R1/R2 ) between a first distance (R1) measured between the first axis of rotation (20, 20') and the contact point (4) and a second distance (R2) measured between the second axis of rotation (30, 30') and the contact point (4) is larger when the at least one step (12) is facing the feeler than when part of the at least one step (11) is facing the feeler. Clockwork mechanism according to the preceding claim, in which the kinematic chain is configured so that the ratio (R1/R2) between a first distance (R1) measured between the first axis of rotation (20, 20') and the point of contact (4) and a second distance (R2) measured between the second axis of rotation (30, 30') and the contact point (4) is greater when the at at least one step (12) is facing the feeler only when the middle of at least one step (11) is facing the feeler. Clockwork mechanism according to one of the preceding claims, in which the first mobile (2, 2') and/or the second mobile (3, 3') has an ellipse-shaped profile. Clockwork mechanism according to one of the preceding claims, in which the second mobile (3, 3') and/or the first mobile (2, 2') has a polygasteroid-shaped profile. Clockwork mechanism according to one of the preceding claims, in which the first mobile (2, 2') and the second mobile (3, 3') are configured so that the second mobile (3, 3') makes a complete revolution around the second axis of rotation (30, 30') when the first mobile (2, 2') makes a complete turn around the first axis of rotation (20, 20'). Clockwork mechanism according to one of claims 1 to 4, in which the first mobile (2, 2') and the second mobile (3, 3') are configured so that the second mobile (3, 3') performs an integer number of complete revolutions around the second axis of rotation (30, 30') when the first mobile (2, 2') makes a complete revolution around the first axis of rotation (20, 20'). Clockwork mechanism according to one of claims 1 to 4, in which the first mobile (2, 2') and the second mobile (3, 3') are configured so that the second mobile (3, 3') performs a complete revolution around the second axis of rotation (30, 30') when the first mobile (2, 2') performs a whole number of complete revolutions around the first axis of rotation (20, 20'). Clockwork mechanism according to one of the preceding claims, in which the cam comprises an integer number of steps (11) and the same integer number of jumps (12), each jump (12) being separated from the next jump. along the profile by a step (11), the first mobile and the second mobile being configured so that the ratio between the first distance (R1) and the second distance (R2) is always greater when any of the jumps (12) is facing the feeler only when any of the steps (11) is facing the feeler. Clock mechanism according to one of the preceding claims, the clock mechanism being a chronograph mechanism or a date mechanism or a repeater or passing chime mechanism. Timepiece comprising a watch movement and a timepiece mechanism according to one of the preceding claims, the timepiece mechanism being configured to be driven by the watch movement.

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