CH717278A1 - Watch movement with a display acceleration device, in particular for a large date calendar. - Google Patents

Abstract

The watch movement according to the invention comprises at least one display element a rotary drive member (36), such as a finger, arranged to move the at least one display element at determined times, a cam accelerator (86) and a drive device (38, 84) for driving the rotary drive member (36) and the accelerator cam (86). The rotary drive member (36) is arranged to rotate in a cycle divided into three phases: a first phase during which the drive device (38, 84) directly drives the rotary drive member (36) and during which the rotary drive member (36) does not move the at least one display element; a second phase during which the rotary drive member (36) is no longer driven directly by the drive device (38, 84) but is driven by the acceleration cam (86) and during which the member rotary drive (36) moves the at least one display element; and a third phase where the rotary drive member (36) is no longer driven by the acceleration cam (86) and remains stationary while waiting to be driven again directly by the drive device (38, 84).

Description

The present invention relates to a watch movement provided with a display element acceleration device.

[0002] More particularly, the present invention relates to a horological movement comprising at least one display element, a rotary drive member, such as a finger, arranged to move the at least one display element at times determined, an acceleration cam and a drive device for driving the rotary drive member and the acceleration cam.

The present invention will be described in the context of a watch movement comprising a date display device of the big date type. Such a display device comprises a first display element bearing the digits of the date units and a second display element bearing the tens digits of the date.

[0004] Several watch movements comprising a device for accelerating display elements are proposed in the literature.

[0005] Document CH 368751 describes an acceleration device employing a spring element of the jumper type cooperating with a cam portion carried by a twenty-four hour disc. Beyond a certain angle of cam rotation, the spring element discharges, causing the display to jump instantly or semi-instantaneously. A drawback of this acceleration device is that it consumes a lot of energy, since it requires arming the spring element by the cam before it is released for driving the display.

[0006] Document CH 699736 describes a needle date device designed so that at least one step out of the 31 made by the needle in a month is of a greater angular amplitude than those of the other steps. To do this, the device comprises several toothed sectors capable of meshing with each other, thus modifying the amplitude of movement of the needle (and the speed of movement of the needle during the step of greater amplitude). This device has the drawback of not making it possible to modify the speed ratio without significantly modifying the toothed sectors.

The present invention aims to provide a watch movement with a display acceleration device which overcomes, in part at least, the aforementioned drawbacks.

To this end, there is proposed a watch movement comprising at least one display element, a rotary drive member, such as a finger, arranged to move the at least one display element at times determined, an acceleration cam and a drive device for driving the rotary drive member and the acceleration cam, the rotary drive member being arranged to rotate in a cycle divided into three phases: a first phase during which the drive device directly drives the rotary drive member at a speed ω1 and during which the rotary drive member does not move the at least one display element; a second phase during which the rotary drive member is no longer driven directly by the drive device but is driven by the acceleration cam, typically at an angular speed ω2 greater than the speed ω1, and during which l the rotary drive member moves the at least one display element; and a third phase in which the rotary drive member is no longer driven by the acceleration cam and remains stationary while waiting to be driven again directly by the drive device.

[0009] Other characteristics and advantages of the present invention will become apparent on reading the following detailed description given with reference to the appended drawings in which: FIG. 1a is a top plan view of a mechanical watch movement with date display comprising an acceleration device according to the invention; FIG. 1b is a top plan view of the mechanical watch movement with date display comprising an acceleration device according to the invention, in which the major part of a unit display element and the major part of an element display tens have been removed to make visible the drive mechanism of these display elements; FIG. 2a is a top plan view of part of the mechanism for driving the display elements of the units and tens, this part comprising a control ring, a mobile for driving the control ring, a mobile drive units meshing with the control ring and a tens drive mobile unit meshing with the control ring; FIG. 2b is a perspective view of the part of the drive mechanism illustrated in FIG. 2a, showing this part in its position corresponding to date 29; FIG. 3 is a top plan view of the driving wheel set for the control ring comprising a pinion and a Maltese cross, the Maltese cross cooperating with a finger also forming part of the drive mechanism for the display elements of the ones and tens; FIGS. 4a to 4c are top plan views of a part of the drive mechanism for the units and tens display elements, provided with a device for accelerating the display elements.

Referring to Figures 1a and 1b, a mechanical watch movement 10 with date display comprising an acceleration device according to the invention comprises, on a plate 12, the traditional members (driving member, finishing gear, escapement, regulating organ, timer) allowing the measurement of time and the display of the time measured by means of indicator organs such as hour, minute and second hands. The mechanical watch movement 10 further comprises a date display device comprising two display elements 14, 16 coplanar and movable with respect to one another, namely a display element of the units 14 on which are affixed the digits "0" to "9" of the date units and a tens display element 16 on which are affixed the digits "0" to "3" of the tens of the date.

The display element of the units 14 rotates a tenth of a turn counterclockwise at the end of each day except during the passage from the 31st of a month to the 1 <er> of the following month when it remains motionless. The tens display element 16 rotates a quarter turn clockwise when changing from 9 to 10, 19 to 20, 29 to 30, and from 31 to 1 <er> of the following month. The current date is indicated by the juxtaposition of a tens digit carried by the tens display element 16 and a units digit carried by the units display element 14 in the movement zone located at 3 o'clock, this juxtaposition being visible through a window 18 made in the dial of the watch.

Referring to Figures 1b, 2a and 2b, the drive mechanism of the display elements 14, 16 comprises a control ring 22 provided with an internal toothing 24 distributed over two levels. On a first of the two levels, namely the lower level in the example shown, the internal toothing 24 comprises sixty teeth 26 plus an empty space 28 occupying the place of two teeth 26. On a second of the two levels, namely the level upper in the example shown, the internal teeth 24 comprises four separate groups of two adjacent teeth, one 30a of these groups being located to the right of the empty space 28 (see Figure 2b), each of the other three groups, designated by 30b, being formed by an extension in height of two adjacent teeth 26 of the first level (cf. FIG. 2b). The spaces between these four groups of teeth 30a, 30b together constitute an empty space 29 in the second level. The control ring 22 fulfills the dual function of driving and sequencing. It can replace the date display disc, bearing indications "1" to "31", of an existing simple date watch.

A drive pinion 32 with eight teeth meshes with the internal teeth 24 on the two levels. This drive pinion 32 is integral with a Maltese cross 34 which cooperates with a finger 36 coaxial with a twenty-four hour wheel 38 driven by the cog of the movement 10. The finger 36 is driven by the twenty-four hour wheel. four hours 38 and by an acceleration cam in a manner which will be described later, and makes one revolution per twenty-four hours. The finger 36 comprises (cf. FIG. 3) a circular body 36a mounted around the common axis of the finger 36 and the twenty-four hour wheel 38, two notches 36b made in the periphery of the circular body 36a and a radial protuberance 36c separating the two notches 36b and extending beyond the radius of the circular body 36a. Each day, a little before midnight, the finger 36 turns the Maltese cross 34 by a quarter of a turn, which turns the drive pinion 32 of a quarter of a turn, therefore of two teeth, and the pinion d 'drive 32 moves the control ring 22 by a thirty-first turn, therefore by two teeth. Apart from the periods when the finger 36 drives the Maltese cross 34 by its radial protuberance 36c and its two notches 36b, the Maltese cross 34 is prevented from rotating by the periphery of the circular body 36a of the finger 36, as is known in itself, and the control ring 22 therefore remains stationary.

A drive pinion of the units 40, with eight teeth, meshes with the internal teeth 24 of the control ring 22 but only on the first level (teeth 26). This pinion 40 is the first element of a drive train of the units 42 which ends in a pinion 44 with eight teeth which meshes with an external toothing 46 of the display element of the units 14 (cf. FIG. 1b). . Thus, this pinion 40 and therefore the display element of the units 14 is driven by the control ring 22, except during the passage from the 31st of one month to the 1st of the following month when the pinion 40, opposite of the empty space 28 of the first level, remains motionless.

A tens drive pinion 48, eight teeth, meshes with the internal teeth 24 of the control ring 22 but only on the second level (teeth 30a, 30b). This pinion 48 is the first element of a tens drive train 50 which ends with a wheel 52 integral with the tens display element 16 (cf. FIG. 1b). This pinion 48 and therefore the tens display element 16 is driven by the control ring 22 only when changing from 9 to 10, from 19 to 20, from 29 to 30 and from 31 to 1 <er>. On other days, in fact, it is opposite the empty space 29 of the second level and therefore remains motionless.

As illustrated in Figures 4a to 4c, the finger 36 can perform a limited angular movement relative to the twenty-four hour wheel 38, and an acceleration device is provided to accelerate the movement of the control ring 22 and therefore display elements 14, 16. The relative movement between the twenty-four hour wheel 38 and the finger 36 is limited by a pin 80 carried by the circular body 36a of the finger 36 and engaged in an opening 82 made in the twenty-four hour wheel 38. The acceleration device comprises an acceleration pinion 84 meshing with the twenty-four hour wheel 38 to be driven by it and an acceleration cam 86 integral with the acceleration pinion 84 and arranged to cooperate with the pin 80. The gear ratio between the twenty-four hour wheel 38 and the accelerating pinion 84 is such that the accelerating pinion 84 rotates faster, or even much faster, than the accelerator pinion. twenty-four hour wheel 3 8. In an exemplary embodiment, the twenty-four hour wheel 38 has seventy-eight teeth and the acceleration pinion 84 has thirteen teeth, ie a speed ratio of six between the two wheels 38, 84.

The periphery of the acceleration cam 86 comprises two circular arc portions 86a, 86b concentric and of different radii connected by two shoulders 86c, 86d diametrically opposed.

The acceleration device operates as follows. The rotation of the finger 36 is divided into three phases forming a cycle: a first phase (the longest of the three) during which the twenty-four hour wheel 38 continuously drives the finger 36 through the wall of the opening 82 which pushes the pin 80 (FIG. 4a) and during which the finger 36 does not drive the Maltese cross 34; a second phase during which the finger 36 is no longer driven by the wall of the opening 82 but by the shoulder 86c of the acceleration cam 86, the contact between the wall of the opening 82 and the pin 80 being broken ; during this second phase, the finger 36 drives the Maltese cross 34 which, by means of the drive pinion 32, drives the control ring 22, these drives being made rapid by the high speed of rotation of the acceleration cam 86 ; and a third phase in which the finger 36 is no longer driven by the acceleration cam 86 and remains stationary while waiting to be caught by the twenty-four hour wheel 38 and the wall of its opening 82 to restart the cycle.

Figure 4b illustrates the transition between the first two phases: at this precise moment, the pin 80, still driven by the twenty-four hour wheel 38, is caught by the acceleration cam 86 which, by virtue of its speed greater than that of the twenty-four hour wheel 38 over the radius of the pin 80, becomes the driving force for the pin 80 and the finger 36. The pin 80 is therefore no longer in contact with the wall of the opening 82 and advances faster than the twenty-four hour wheel 38. FIG. 4c illustrates the end of the drive of the finger 36 by the acceleration cam 86, which corresponds to the end of the movement of the display elements 14, 16 when the drive mechanism of the display elements 14, 16 is free from jumper.

In a non-limiting example (the sizing can be adapted to choose the speed ratio most suited to the application), the total duration of each movement of the control ring 22, therefore of the display elements 14, 16, by the acceleration cam 86 is about fifteen minutes (which corresponds to 3.5 ° angular travel of the twenty-four hour wheel 38). Without the acceleration device, this total duration would be two hours (corresponding to 30 ° of angular travel of the twenty-four hour wheel 38) since the angular travel required for the finger 36 to drive the Maltese cross through its protuberance 36c 34 is about 30 °. The movement is therefore made eight times faster by the acceleration device. Advantageously, the ratio of the speed of the acceleration pinion 84 to the speed of the twenty-four hour wheel 38 may be between 2 and 10, even more advantageously between 4 and 8.

When using jumpers or any other equivalent device to complete a movement once a certain stroke has been reached, it may be sufficient for the acceleration device to drive the display elements 14, 16 up to at this minimum travel, ie up to the tip of the jumpers or even a little more, the remainder of the display travel then being carried out by the exit slope of the jumpers.

Instead of meshing with the twenty-four hour wheel 38, the cog of the movement 10 could mesh with the acceleration pinion 84. The cog of the movement 10 could also mesh simultaneously with the 24 hour wheel 38 and with the accelerator pinion 84.

Compared to known instantaneous, semi-instantaneous or semi-driving type displays, the acceleration device according to the invention makes it possible to significantly reduce energy consumption while allowing great freedom in the choice of kinematics display movement.

Those skilled in the art will understand that the acceleration device according to the invention could be used in a context other than that of a large date and even a date. For example, the acceleration device according to the invention could be used for displaying the phases of the moon, for displaying a time indication or a day / night indication.

Those skilled in the art will understand that the acceleration device according to the invention is particularly well suited to mechanical watch movements, but could also be used for electronic or quartz watch movements, having at least one analog display. requiring the acceleration of its displacement at determined times.

Claims (7)

1. Watch movement comprising at least one display element (14, 16), a rotary drive member (36) arranged to move the at least one display element (14, 16) at determined times, a acceleration cam (86) and a driving device (38, 84) for driving the rotary drive member (36) and the accelerator cam (86), the rotary drive member (36) being arranged to rotate in a cycle divided into three phases: a first phase during which the drive device (38, 84) directly drives the rotary drive member (36) and during which the rotary drive member ( 36) does not move the at least one display element (14, 16); a second phase during which the rotary drive member (36) is no longer driven directly by the drive device (38, 84) but is driven by the acceleration cam (86) and during which the member rotary drive (36) moves the at least one display element (14, 16); and a third phase where the rotary drive member (36) is no longer driven by the acceleration cam (86) and remains stationary while waiting to be driven again directly by the drive device (38, 84). 2. Watch movement according to claim 1, characterized in that the rotary drive member (36) is a finger. 3. Watch movement according to one of the preceding claims, characterized in that the drive device (38, 84) comprises a wheel (38) coaxial with the rotary drive member (36) and a pinion (84) integral with the acceleration cam (86), the pinion (84) being kinematically connected to the wheel (38), and in that the rotary drive member (36) is arranged to be able to perform a limited rotation with respect to to the wheel (38). 4. Watch movement according to the preceding claim, characterized in that the rotary drive member (36) comprises a circular body (36a) mounted around the common axis of the rotary drive member (36) and the wheel (38), two notches (36b) formed in the periphery of the circular body (36a) and a radial protuberance (36c) separating the two notches (36b) and extending beyond the radius of the circular body (36a) . 5. Watch movement according to the preceding claim, characterized in that the relative movement between the wheel (38) and the rotary drive member (36) is limited by a pin (80) carried by the circular body (36a) of the rotary drive member (36) and engaged in an opening (82) made in the wheel (38). 6. Watch movement according to one of claims 3 to 5, characterized in that the ratio of the speed of the pinion (84) to the speed of the wheel (38) is between 2 and 10, advantageously between 4 and 8. 7. Watch movement according to one of the preceding claims, characterized in that the periphery of the acceleration cam (86) comprises two portions in an arc of a circle (86a, 86b) concentric and of different radii connected by two shoulders (86c , 86d) diametrically opposed.