CH715723A1 - Instant jump mechanism of a display mobile. - Google Patents

Abstract

The invention relates to an instantaneous jump clock mechanism of a display mobile making it possible to display information that changes over a determined period, comprising: - a winding mobile (10), arranged to store energy during said period and to release at least part of said energy at the time of the jump, - a rocker (12) arranged to receive the energy transmitted by the winding mobile (10) at the time of the jump and drive the mobile by one step display. The winding mobile (10) comprises, mounted coaxially: - a first input (101) intended to be driven by a clock movement at a speed V1, such that the first input 101 performs one revolution during said period, - a second input (102) intended to be driven by the watch movement at a speed V2, less than V1, generating a phase shift between the first input (101) and the second input (102), - a spring interposed between the first input (101) and the second input (102), armed by the phase shift between the first input (101) and the second input (102), - a drive finger (106) able to be driven by the second input (102). The kinematic connection between the second input (102) and the watch movement is disengaged at the end of said period, said spring exerting on the second input (102) a return force reducing the phase shift between the first input (101) and the second input (102), said second input (102) driving the drive finger.

Description

Technical area

The present invention relates to the field of watchmaking. It relates more particularly to an instantaneous jump mechanism of a display mobile, particularly suitable for being used for a date display.

State of the art

[0002] Information display systems must, by definition, indicate the correct time. While it is usual, for the hour and minute hands, to have hands which advance in a regular manner opposite a scale, such a movement called "dragging" is nowadays less used for a date display. , month or year. This is also the case for digital displays, regardless of the information to be displayed. In this type of display, so-called “jumping” movements are preferred, that is to say the movable element (disc or needle) is stationary during the period of the information to be displayed, and performs a jump. a step at the end of the period, to indicate the next date or the following month, etc ...

[0003] Although quite widespread, this type of mechanism is relatively difficult to master, in particular under certain specific conditions. In fact, for mechanical watch movements, it is necessary to take torque in order to charge a spring and release the latter at the time of the jump. This has the effect of disrupting the course of the movement. For calendars, including full calendars, the end of the month and even more the end of the year, require advancing multiple displays simultaneously. If the available torque is insufficient, it may happen that the movement stops. On the contrary, if the energy supplied by the spring is too great, there is a risk of jumping two steps simultaneously.

[0004] The object of the present invention is to provide an instantaneous jump mechanism for a watch display allowing little energy to be taken from the movement. In addition, the mechanism can allow a controlled jump of the display mobile.

Disclosure of the invention

[0005] More specifically, the invention relates to an instantaneous jump clock mechanism of a display mobile making it possible to display information that changes over a determined period, as defined in the claims.

Brief description of the drawings

[0006] Other details of the invention will emerge more clearly on reading the following description, made with reference to the appended drawing in which: - Figure 1 is an overall view, showing the mechanism according to the invention in an initial position, implemented in a perpetual calendar, - Figures 2 to 10 show, either in top view or in isometric view, the mechanism according to the invention in successive positions that it occupies during its operation, and - Figures 11 and 12 are respectively isometric and sectional views of details of the mechanism according to the invention.

Embodiment of the invention

[0007] The constituent elements of the watch mechanism according to the invention will be described with reference to FIG. 1, with recourse to details visible in FIGS. 11 and 12. The mechanism will be described with reference to an instantaneous jump mechanism of date, that is to say to a mechanism designed to drive a display mobile 8 of information changing over a period of 24 hours, but a person skilled in the art can generalize it to other information changing over a period determined.

[0008] The mechanism according to the invention comprises a winding mobile 10, arranged to store energy during the 24 hours following a jump, and to release at least part of this energy at the time of the jump.

As we will see below, the winding mobile 10 is arranged to transmit the energy released at the time of the jump, to a rocker 12 arranged to drive the display mobile by one step, that is, that is to say the date mobile, not visible in the figures. This latch 12 being of a known type, it will not be described in detail. We will be satisfied to point out that it is pivotally mounted at A, and that it comprises on the one hand, an actuating arm 14 receiving the energy transmitted by the winding mobile 10, and on the other hand a finger transmission 17, driving the display mobile. A spring is arranged to maintain the lever 12 in a waiting position, between two jumps. In the example illustrated, the date mechanism is integrated in a perpetual calendar mechanism and the rocker rests on a months cam by means of a feeler 16.

The winding mobile 10 comprises, mounted coaxially, a first input 101, a second input 102, as well as a spring 104 interposed between the first input 101 and the second input 102, and a suitable drive finger 106 to be driven by the second input 102 to transmit the energy released at the time of the jump to the actuating arm.

More particularly, the first input 101 is intended to be driven by the watch movement at a speed V1, such that the first input 101 performs one revolution in 24 hours, in the example illustrated. The first entry 101 is a toothed wheel, integral with the shaft which ensures its pivoting. It carries a pin 108, protruding from the periphery of its board, the role of which will appear later.

The second input 102 is intended to be driven by the watch movement at a speed V2, less than V1, generating a phase shift between the first input 101 and the second input 102. The second input 102 is a wheel, the plate 1020 of which is thinner than the serge 1022, forming a housing, like a barrel. This wheel is pivotally mounted on the shaft of the first entry 101. The board 1020 of the second entry 102 comprises an opening 1024 forming a circular arc concentric with the second entry 102, with which the pin 108 cooperates. The wheel comprises a set of teeth. which, in a first plane, is complete (bearing the reference 1026), and which, in a second plane is incomplete (bearing the reference 1028). In other words, on a portion corresponding substantially to the arc of the opening 1024, the toothing is truncated over part of its height, defining a wall devoid of toothing 1030. As can be seen in particular in FIG. 11 , this part devoid of teeth extends into a skirt 1032 which protrudes from the plane of the teeth, on the side of the first entry 101. A gap 1034 (see FIG. 12) is thus defined between the teeth of the first 101 and the second entry 102, where the skirt 1032 is not present, and its role will appear later.

The second entry 102 also includes a lug 110 fixed projecting on its board, on the side opposite the first entry 101.

The spring 104 takes place in the housing defined by the hollow of the second inlet 102. The spring 104 is of the spiral type. It is fixed to the center of the second inlet 102, while its outer end hooks onto the pin 108 of the first inlet 101 which passes through the housing to take place in the opening 1024. It is therefore understood that the phase shift between the first entry 101 and second entry 102, generated by the difference between their driving speed, arms the spring 104 during the 24 hours preceding the jump.

Finally, the drive finger 106 is rotatably mounted on the shaft of the first inlet 101. It is in the form of a spiral cam and its right side 1060 can cooperate with the lug 110 of the second inlet 102, while its convex side 1062 can cooperate with the actuating arm 14 of the rocker 12.

To drive the first input 101 and the second input 102, the mechanism comprises a driving wheel 18 comprising, mounted coaxially and integrally, a transmission wheel 180 driven by the movement, a first pinion 181 in kinematic connection with the first input 101, and a second pinion 182 in kinematic connection with the second input 102, in the plane of the partial teeth. The tooth ratios of the first and second pinions with, respectively, the first 101 and the second input 102, are different in order to generate the speed differential between the inputs.

Advantageously, the driving mobile 18 also comprises an anti-recoil cam 184, interposed between the first pinion 181 and the second pinion. As can be seen particularly in FIG. 12, the anti-recoil cam 184 is located in the plane of the skirt 1032, so that, when the cam is in front of a portion without a skirt 1032, it can take place. in the gap 1034 formed between the first 101 and the second 102 entries. The anti-recoil cam 184 includes a protuberance 1840 extending radially beyond the circumference defined by the radius of the circular portion of the cam 184. This protrusion defines at least one edge, substantially straight, defining a stop surface 1842 adapted to cooperate with the skirt 1032.

The mechanism can also include a set of regulating cogs 20, aimed at braking the second input 102 at the time of the jump. This gear train comprises a first mobile 200 in permanent kinematic connection with the complete toothing of the second input 102. It ends in a flywheel 202, with suitable gear wheels between the two.

We will now describe the operation of the mechanism which has just been described.

[0020] Figures 1 and 2 show, from two different viewing angles, the mechanism in its so-called "initial" position, that is to say after a jump has just occurred.

The first input 101 and the second input 102 are in a relative position without phase shift and the spring 104 is in its state of minimum stress. A preload is provided so that the pin 108 is pressed against a first end of the opening 1024 when the second inlet 102 is free, that is to say not subjected to a torque from the driving mobile 18 .

In Figure 2, we see that the first input 101 is engaged, as is always the case, with the first pinion 181 of the driving wheel. The second pinion 182 of the driving wheel 18 is ready to mesh with the second input 102, at the start (depending on the direction of rotation) of the partial teeth 1028 thereof. FIG. 11 shows in detail the interaction between the driving mobile 18 and the winding mobile 10, during this step. It is particularly noted that the stop surface 1842 of the anti-recoil cam 184 is ready to cooperate with the skirt 1032, in order to prevent setting the time back just after the jump, which would be detrimental to the mechanism.

The lug 110 is in contact with the right side 1060 of the drive finger, ready to drive it. The rocker 12 is in its waiting position.

In operation, the watch movement drives the mobile driving 18 by the transmission wheel 180. The first 181 and second 182 pinions drive their respective input, at the speed determined by the gear ratio between the pinion and the input . Figures 3 and 4 show an intermediate position of the mechanism. It can mainly be seen that the second entry 102 is “behind” compared to the first entry 101 and that the pin 108 is moving in the circular opening 1024.

The anti-recoil cam 184 also pivots, without interacting with the winding mobile 10, because either it has its circular part facing the winding mobile 10, or the protuberance moves freely in the gap 1034 between the first entry 101 and the second entry 102.

The regulating gear train 20 is driven continuously.

The lug 110 drives the drive finger 106 by pushing it into contact with the right side 1060. The latch 12 is in its waiting position.

At the end of the period, just before the jump, the mechanism is in the position shown in Figures 5 and 6. The angular offset between the first entry 101 and the second entry 102 has increased and the pin 108 is located on the other side of the circular opening 1024, relative to the position of FIG. 1 (hidden by the latch 12). The second pinion 182 is at the end of the partial teeth 1028 with which it meshes.

The protuberance 1840 of the anti-recoil cam 184 arrives near the skirt 1032, without being in its course. The convex flank 1062 of the drive finger 106 comes into contact with the actuating arm 14 of the lever 12.

When the second input 102 is no longer engaged with the second pinion 182, it is no longer subject to the action of the spring 104, which then drives the second input 102 in the counterclockwise direction, by the center of the spring, to make it catch up with respect to the first entry 101. FIGS. 7 and 8 represent the mechanism during this phase of operation. The second entry 102 then quickly pivots counterclockwise (with reference to FIG. 7) to return the pin 108 to the first end of the circular opening 1024. The drive finger 106 lifts the rocker 12 to the position of Figures 8 and 9, where the actuator arm 14 is at the top of the convex portion. During the lifting of the latch, the display device is driven by the transmission finger 17. The second input 102 has not yet caught up to all its delay.

The skirt 1032 passes opposite the anti-recoil cam 184, without interaction between them.

The regulating gear train 20, still driven, slows the jump of the second input 102 by inertial effect, thus ensuring a regular and controlled movement of the latch 12.

The end of the movement of the second input 102 occurs when the pin 108 is in abutment at the first end of the opening 1024 (Figure 10). The actuating arm 14 then fell after leaving the top of the convex portion 1062, to return to its initial position. When the pin 108 comes into abutment at the first end of the opening 1024, the second pinion 182 is not yet engaged with the incomplete toothing 1028 of the second entry 102 (see FIG. 10).

The anti-recoil cam 184 is then in the position detailed in Figure 11 and described above, in which the stop surface 1842 of the cam can cooperate with the skirt 1032 to prevent setting the time back at this moment, in order to avoid an overhang between 182 and 1028 after an angular rotation corresponding to the wall without teeth 1030.

Thus, at the end of said period, that is to say at the time of the jump, the kinematic connection between the second input 102 and the watch movement is disengaged, thanks to the non-toothed sector of the second input 102. The spring 104 then exerts on the second input 102 a return force reducing the phase shift between the first input 101 and the second input 102, the second input 102 driving the drive finger.

The rotation of the driving wheel 18 then allows the second pinion 182 to mesh again with the second input 102 and to start a new cycle for the period which begins.

The mechanism which has just been described advantageously makes it possible to take very little energy from the movement, and to smooth this removal throughout the winding period.

In fact, under the action of the prestressed spring 104, the first 101 and second inputs 102 exert forces on the driving wheel 18, respectively on the first 181 and second 182 pinions. These efforts are in the same direction and in opposite directions. It follows that, for a given state of prestressing of the spring 104, the torque to be overcome by the mobile 18 is less than the torque required to bring the spring 104 into this state.

[0039] More particularly, noting: - R181: pitch radius of the first pinion 181, - R182: pitch radius of the second pinion 182, - R101: pitch radius of the first entry 101, - R102: pitch radius of the second entry 102 , - M18: moment to be conquered by the mobile 18, - CR: torque of the prestressed spiral spring 104, at equilibrium, neglecting the losses and assuming a pressure angle α common to the two gears, we can highlight this effect with the following rotation:

This mechanism can be adapted to replace trailing systems of existing mechanisms. The optional use of the anti-kickback cam 184 and the corresponding skirt 1032 provides optimum operating safety, while the use of the regulating gear train helps to control the jump and avoid jerking or jumping. too important.

Claims (9)

1. Clock mechanism for instantaneous jump of a display mobile making it possible to display information that changes over a determined period, comprising: - a winding mobile (10), arranged to store energy during said period and to release at least part of said energy at the time of the jump, - a rocker (12) arranged to receive the energy transmitted by the winding mobile (10) at the time of the jump and to drive the display mobile by one step, characterized in that the winding mobile (10) comprises, mounted coaxially: - a first input (101) intended to be driven by a watch movement at a speed V1, such that the first input 101 performs one revolution during said period, - a second input (102) intended to be driven by the watch movement at a speed V2, lower than V1, generating a phase shift between the first input (101) and the second input (102), - a spring (104) interposed between the first input (101) and the second input (102), armed by the phase shift between the first input (101) and the second input (102), - a drive finger (106) capable of being driven by the second input (102), and in that the kinematic connection between the second input (102) and the watch movement is disengaged at the end of said period, said spring (104) exerting on the second input (102) a return force reducing the phase shift between the first input (101) and the second input (102), said second input (102) driving the drive finger. 2. Watch mechanism according to claim 1, characterized in that the second inlet (102) has a portion devoid of teeth. 3. Watch mechanism according to claim 2, characterized in that the second input (102) is a wheel comprising a toothing which, on a first thickness, is complete, and which, on a second thickness is incomplete, defining a wall devoid of toothing. 4. Watch mechanism according to one of the preceding claims, characterized in that the drive finger (106) is rotatably mounted on a shaft of the first input (101), and in that the second input (102) comprises a lug 110 able to cooperate with the finger to drive the latter. 5. Watch mechanism according to one of the preceding claims, characterized in that the second input (102) is pivotally mounted on a shaft of the first input (101), and in that the first input (101) comprises a pin ( 108) taking place in an opening (1024) made in the board of the second inlet (102), said opening (1024) forming a circular arc concentric with the second inlet (102), with which the pin (108) cooperates. 6. Watch mechanism according to claim 5, characterized in that the spring (104) is of the spiral type and is fixed, on the one hand, at the center of the second entry (102), while its outer end is hooked to said pin (108). 7. Watch mechanism according to one of claims 3 to 6, characterized in that it comprises a driving wheel (18) comprises mounted coaxially and integrally: - a transmission wheel intended to be driven by the movement, - a first pinion (181) in kinematic connection with the first input (101), and - a second pinion (182) in kinematic connection with the second input (102), at the level of the incomplete teeth. 8. Watch mechanism according to claim 7, characterized in that the driving wheel (18) further comprises an anti-recoil cam (184), working in a gap (1034) formed between the first input (101) and the second input. (102), said gap (1034) being interrupted by a skirt (1032) extending the toothless wall of the second inlet (102). 9. Watch mechanism according to one of the preceding claims, characterized in that it comprises a train of regulating cogs in permanent kinematic connection with the second input (102).