EP2927756A1 - Clock movement provided with a drive mechanism for an analogue indicator with periodic or intermittent movement - Google Patents

Abstract

The watch movement (24) is equipped with an analogue display device for information whose value varies periodically or intermittently, this analog display device comprising on the one hand an indicator (26) provided with a first toothing (28) and, on the other hand, a periodic or intermittent drive mechanism (30) for this indicator. The drive mechanism is formed by an irreversible transmission system which has an anti-shock function for the indicator. The display device further comprises a jumper (56) for positioning this indicator which generates a positioning force on the first toothing, which is sufficient to accurately position this indicator in a plurality of discrete display positions but largely insufficient for provide a shockproof function for the indicator. Thus, the indicator can be driven with a relatively low torque; which therefore requires less energy and allows to provide a drive mechanism with a lower reduction in the transmission of the engine torque.

Description

Technical area

The present invention relates to the field of watch movements comprising an analog display of information whose value varies periodically or intermittently among a plurality of predefined discrete values, in particular calendar information and / or a function / application. selected from a plurality of possible functions / applications. By value, it is generally understood a number, a calendar information (like the calendar, the day of the week or the month) and also the selection of a function or an application among a plurality of functions or applications, this list is not exhaustive. The invention particularly relates to the drive mechanism of an analog indicator with periodic or intermittent displacement and the impact resistance means of this indicator, as well as the precise positioning of the indicator in each display position of a plurality discrete display positions planned.

Technological background

For training a calendar indicator, in particular a date ring, three types of mechanism are essentially known: a trailing mechanism, a conventional semi-instantaneous mechanism and an instantaneous mechanism.

In a classic variant represented in Figure 1 , the trailing mechanism 2 is provided to drive a date ring 4 provided with an internal toothing 6. This trailing mechanism comprises a Maltese cross 8 and an actuating wheel 12 of the latter. The Maltese cross has six branches 9 and is integral with a coaxial pinion 10 which meshes with the toothing 6 of the date ring. The pinion 10 comprises six teeth. The number of branches of the Maltese cross and the number of teeth of the pinion are given here as a non-limiting example. Thus, such a mechanism is also known with a four-pointed Maltese cross and an eight-toothed pinion. Preferably, the ratio between the number of teeth and the number of branches is an integer. The actuating wheel 12 comprises two drive pins 16, 17 and a locking member 14 which cooperates with the branches 9 to lock the Maltese cross in stable positions between two successive drives performed respectively by the two pins. This operating mobile is rotated for example by a pinion 20. The operation of a Maltese cross system is well known, it will not be described here in more detail.

The dragging mechanism described above is characterized by a gear with little play, or without play, and the absence of jumper. Thus, the drive function and the positioning function of the date ring in its display positions are both performed by the pinion associated with the Maltese cross. In addition, the anti-shock function is performed by the Maltese cross system, the locking member 14 easily performing this function. The manufacture of a watch movement with such a mechanism is expensive because it is necessary to minimize the machining and mounting tolerances (manufacturing tolerances) of this mechanism and the date ring to ensure accurate positioning of this ring in its display positions, for example a precise centering of each date in the window of a dial designed for the watch movement.

The conventional semi-instantaneous drive mechanism comprises a date ring drive wheel generally provided with a finger or two fingers which periodically penetrates into the toothing of the ring to drive it from one end to the other. display position to a following. The gaps between the teeth of this toothing are generally relatively wide, especially to allow each finger to enter and out of the toothing of the ring without risk of blockage; this especially because of manufacturing tolerances and centering of the date ring. Thus, it is clear that the drive wheel can not provide the positioning function of the ring. In addition, it can not provide an anti-shock function because generally there is no meshing between the toothing and the finger, respectively the two fingers on certain angular ranges of the drive wheel.

To ensure the positioning function and shockproof function, there is provided a jumper spring, also called jumper, which is inserted between two successive teeth of the teeth of the ring. We speak here semi-instantaneous system because in a first phase of the transition to a next date, the ring is rotated by a finger of the drive wheel and the tip of the tooth downstream of the jumper raises the jumper up to that the top of the saltire is in support against the top of this tooth. Then, the jumper exerts a tangential force on the rear flank of the concerned tooth to go to take its next rest position. In this second phase, the jumper quickly drives the ring of the dates in rotation to its next display position, the finger of the drive wheel continuing its rotation at a lower speed than the ring and therefore ceasing to exercise a couple of strength on this ring. The space between the teeth is large enough so that the tooth following that pushed by a finger does not abut against this finger inserted in the teeth of the ring. A major drawback of this semi-instantaneous mechanism comes from the fact that the anti-shock function is performed by the jumper, which must therefore press on the date ring with a large force to be able to exert a sufficient locking torque in case of shock. Thus, the drive mechanism must provide at each date of passage a significant engine torque to overcome the positioning torque of the jumper; which requires a lot energy and a mechanism capable of providing such a motor torque at the tooth of the ring date.

There are various embodiments of an instant drive mechanism. In all cases there is provided a positioning jumper also ensuring the shockproof function. This mechanism therefore has the same disadvantages as the semi-instantaneous mechanism described above.

Summary of the invention

The object of the present invention is to solve the problems and disadvantages of the drive mechanisms of an analogue indicator with periodic or intermittent displacement of the prior art, in particular a date ring.

For this purpose, the subject of the present invention is a watch movement equipped with an analogue display device for a piece of information whose value varies periodically or intermittently, this analog display device comprising on the one hand an indicator of this information provided with a first gear and on the other hand, a periodic or intermittent drive mechanism of the indicator. This drive mechanism is formed by an irreversible transmission system comprising a second toothing which meshes with the first toothing. The display device further comprises a locator for positioning the indicator generating a positioning force on the first toothing, this positioning force being sufficient to precisely position this indicator in a plurality of discrete display positions, but insufficient for provide a shockproof function for the indicator. In addition, the tangential clearance between the first and second sets of teeth is large enough so that these first and second sets of teeth do not touch when the indicator is in any display position of the plurality of discrete display positions and the irreversible transmission system is in a predefined corresponding position. This transmission system irreversible has an anti-shock function for the indicator via meshing of the first and second teeth at least when this indicator is in any display position of the plurality of discrete display positions and the irreversible transmission system is in said predefined corresponding position.

By "periodic training" is meant training which occurs only periodically, i.e. training takes place periodically during a limited period of time and no training occurs between the limited time intervals. Similarly, by 'intermittent drive' is understood a discontinuous drive which stops and resumes depending on the control of the intermittent drive mechanism without this drive necessarily intervenes at regular intervals.

Thanks to the characteristics of the watch movement according to the invention, the problem of the trailing mechanism described above, with the Maltese cross system providing drive and positioning of the indicator, and the problem of the conventional semi-instantaneous mechanism or instantaneous, where the positioning of the indicator and the shockproof function are provided by a jumper spring, are both solved. In a particular embodiment of the invention, the drive mechanism defines a mechanism resembling a semi-instantaneous mechanism with one or more drive fingers of the integral indicator (s) of a Maltese cross, this or these finger (s) forming the second toothing mentioned above. Indeed, the positioning jumper is also generally used for driving the indicator in a second phase of the passage of the indicator from a display position to a next display position.

According to the invention, the drive function of the indicator at least in a first phase of the passage of the indicator from a display position to a next display position and the shockproof function are provided by the system. with irreversible transmission, which is capable to exercise a very important blocking force. On the other hand, the positioning function is not ensured by this irreversible transmission system as in the prior art, but by a positioning jumper exerting a sufficient force for this function but much lower than a usual minimum locking force of the transmission. indicator in case of shock.

Thus, on the one hand, it is possible to drive the indicator from one display position to another with a drive torque much lower than the prior art embodiments having a conventional or instantaneous semi-instantaneous mechanism. in which the jumper spring must be able to exert a significant tangential force on the toothing of the indicator in case of impact. On the other hand, the problems of tolerance and mounting of a prior art embodiment with a trailing mechanism without jumper are eliminated.

Other particular features of the invention will be described below in the detailed description of the invention.

Brief description of the drawings

• La Figure 1, déjà décrite, est une vue de dessus d'un mécanisme d'entraînement traînant avec un système à croix de Malte de l'art antérieur;
• La Figure 2A est une vue schématique de dessus d'un premier mode de réalisation d'un mouvement horloger selon l'invention;
• La Figure 2B est un agrandissement partiel de la vue de la Figure 2A montrant l'engrènement entre la denture d'un anneau des quantièmes et un système à croix de Malte du premier mode de réalisation ; et
• Les Figures 3A et 3B montrent une vue partielle, respectivement en perspective et de dessus, d'un deuxième mode de réalisation d'un mouvement horloger selon l'invention.

The invention will be described hereinafter with the aid of annexed drawings, given by way of non-limiting examples, in which:

• The Figure 1 , already described, is a top view of a trailing drive mechanism with a Maltese cross system of the prior art;
• The Figure 2A is a schematic top view of a first embodiment of a watch movement according to the invention;
• The Figure 2B is a partial enlargement of the view of the Figure 2A showing the meshing between the toothing of a date ring and a Maltese cross system of the first embodiment; and
• The Figures 3A and 3B show a partial view, respectively in perspective and from above, of a second embodiment of a watch movement according to the invention.

Detailed description of the invention

With the help of Figures 2A and 2B a first embodiment of a watch movement according to the invention will be described. The watch movement 24 is equipped with an analog date display device, which is a periodic variation information, and various functions F1, F2, etc. which can be selected by a user of a watch equipped with the watch movement. This analog display device comprises a ring 26 provided with a first toothing 28 and a drive mechanism 30. On the ring 26 are printed the various calendars '1' to '31' and the designation of the various possible functions. Each date and each function defines a discrete display position of the ring 26 through in particular a window provided in a dial mounted on the watch movement 24. The drive is periodic for the date and intermittent for the selection of one of the plurality of possible functions.

The drive mechanism 30 is formed by a Maltese cross system defining an irreversible transmission system. It comprises a drive wheel 32 with a Maltese cross 34 surmounted by a pinion 36, the latter having a second toothing 38 which meshes with the first toothing 28. To actuate the drive wheel periodically or intermittently, the driving mechanism further comprises an actuating wheel 40 driven by a pinion 46 which is itself rotated by an electromagnetic motor not shown. The actuating wheel comprises two pins 41 and 42 aligned on a diameter of this actuating wheel and a locking member 44 centered on this axis of rotation. The pins are arranged for to penetrate between the branches of the Maltese cross and to allow the driving of the wheel 32 and thus of the independent date ring. The locking member 44 serves to lock the wheel 32 by its positioning in any curved end of the branches of the Maltese cross.

The Maltese cross system thus defines an irreversible transmission, since the actuating wheel can drive the drive wheel in rotation, but not vice versa. Whatever the angular position of the actuating wheel, a force torque transmitted by the drive wheel to this actuating wheel will cause the rotation of the latter at most over a small angular distance. We also speak of a self-locking drive mechanism, because by design it blocks the transmission of a force torque and thus a rotation in the opposite direction to that which is provided. In the discrete display positions, it is preferably provided that the locking member 44 is substantially aligned with the end of a branch of the Maltese cross (as shown in FIGS. Figures 2A and 2B ), so as to prevent any rotation of this Maltese cross (beyond manufacturing tolerances). Thus, at least when the ring 26 is in any display position of the plurality of its discrete display positions and the Maltese cross system is in the corresponding position defined above, a force torque exerted by the ring on the pinion 36 will not rotate the wheel 40.

According to the invention, the first toothing 28 and the second toothing 38 have between them a tangential clearance, substantially equal to J1 + J2 as represented on FIG. Figure 2B . This tangential clearance is provided sufficiently large so that the first and second sets of teeth do not touch each other when the ring 26 is in any display position of the plurality of discrete display positions mentioned above and the Maltese cross system. is in a corresponding predefined position, preferably as Figures 2A and 2B . Whatever the angular position of the pinion 36, the first and second teeth are always in a situation of meshing. Thus, an untimely jump of the independent date ring is never possible in case of shock. Indeed, even if the ring is subjected to an acceleration due to a shock during its drive by the pinion 36, the tooth 48 will always be in a space 50 between two adjacent teeth 51 and 52 of the toothing 28 once the completed training and the Maltese cross system again in a non-drive position provided for the plurality of discrete display positions. Thus, at least when the Maltese cross system is in a non-drive intended position, the pinion 36 remains stationary if a large force torque is exerted on it by the ring 26. This ring can therefore only move in the game. said tangential when in any display position of the plurality of discrete display positions. The Maltese cross system thus has an anti-shock function for the ring 26 through the meshing of the first and second teeth. The term "anti-shock function" is intended to prevent the mechanism from breaking or being damaged in the event of an impact, but to prevent the indicator from permanently changing its discrete display position under the effect of a shock to which the watch must be able to be subjected without breaking (According to NIHS 91-10, 91-20, 91-30 and other standards).

To precisely position the independent date ring, the display device further comprises a jumper 56 for positioning this ring. The jumper, also called jump spring, is formed of an arm 58, having a positioning tooth 60 at one end and pivoting about an axis at the other end, and a spring 62 which exerts a force on the arm so as to generate a positioning force on the first toothing 28. When the ring deviates from a display position and the jumper from a corresponding stable or rest position, this positioning force has a tangential component acting on the toothing of the ring so as to bring the ring back to its display position in the absence of a discreet display position change, either to bring the ring in a terminal phase in another display position provided during an actuation of the drive device of the ring. By way of example, the spring 62 is a curved elastic blade or rod with a portion in a groove 64 and the other portion bearing against the rear lateral face of the arm 58. According to the invention, the positioning force is sufficient to precisely position the ring 26 in a plurality of discrete display positions but is insufficient to provide a shockproof function for this ring. The positioning force is therefore less than the usual minimum locking force of the ring in the event of an impact, so as to make it possible to drive the ring in rotation with a relatively low torque force and thus to minimize the energy required to move from one display position to another. In a preferred variant, the positioning force is on the one hand greater than a maximum friction force exerted by the watch movement on the ring 26 and on the other hand less than triple this maximum friction force.

By way of non-limiting example, it has been observed that a conventional brass date ring with a diameter of 20 mm requires a torque of approximately 60 μNm to overcome the static friction force on the ring with the movement posed to dish. To ensure a shockproof function with the jumper, as is the case in the movements of the prior art mentioned above, the jumper must in this example be able to exert a torque of blocking force of about 2000 μNm. For an aluminum or plastic ring, especially given the least weight, this shockproof couple will be lower, for example about 800 .mu.m. On the other hand, thanks to the invention, in the case of the steel ring, it is possible in a variant to size the spring 62 so that the jumper 56 exerts a torque between 120 μNm and 180 μNm. With the aluminum or plastic ring, the torque exerted by the jumper 56 will for example be between 80 μNm and 120 μNm. It can thus be seen that the present invention makes it possible to greatly reduce the torque exerted by the jumper on the ring and therefore the necessary motor torque to be transmitted by the drive mechanism 30. In particular, it is possible to reduce the reduction ratio in this drive mechanism.

According to a preferred variant, the tangential clearance between the first and second sets of teeth is greater than or substantially equal to twice the cumulative production tolerances involved in the gear formed by the ring 26 and the Maltese cross wheel 32 at the first level. and second teeth 28 and 38.

In a particular variant, the clearance between the first and second set of teeth is less than the maximum distance over which the jumper spaced apart from a stable rest position, corresponding to a display position, by displacement of the indicator is capable of to return this indicator in this stable rest position by the positioning force that it exerts on the toothing of the indicator. In another variant, it is the half-game plus cumulative manufacturing tolerances involved in the gear, formed by the indicator and the irreversible transmission system at the first and second teeth, which is less than the maximum distance defined. above. In this variant, it is provided that the theoretical position of the second toothing of the irreversible transmission system, for the discrete display positions of the indicator, is substantially centered in the first toothing of the indicator; that is to say that the clearance is substantially evenly distributed on one side and the other of the tooth or teeth of the second toothing inserted into the first toothing of the indicator, as c is the case Figure 2B . It will be noted that the jumper may also have a certain tolerance as to the display positions that it defines by its stable rest positions in the first toothing. This tolerance is advantageously added to the cumulative production tolerances involved in the aforementioned gear to define the game to be provided in the variants presented above. In a preferred variant, the Jumper position can be adjusted after mounting the indicator, so that the discrete display positions are predefined very accurately and the jumper positioning tolerance can be neglected.

To the Figures 3A and 3B is partially shown a second embodiment of a watch movement according to the invention. We will not describe here again the various variants already mentioned which can also be provided in this second embodiment. The latter is characterized by a drive mechanism having a self-locking pin system in place of the Maltese cross system of the first embodiment. In the variant shown, the drive mechanism 64 of a date ring 26A comprises a drive wheel 66 on which are fixed two pins 68 and 69, which define a second toothing in the gear formed by the ring 26A and the wheel 66. This wheel is driven by a pinion 70 associated or coupled to the rotor of an electromagnetic motor. The two pins are aligned on a diameter of the wheel 66. Thus, in the position shown in FIGS. Figures 3A and 3B , which corresponds to the position of the wheel 66 provided in the discrete display positions of the date ring, these two pins provide a total locking of the date ring. Indeed, a force torque applied by the ring on the wheel 66 can not rotate this wheel, which thus forms with its two pins an irreversible transmission system.

Preferably, the two pins are not cylindrical, but have a substantially semicircular section to allow a relatively large clearance between the first toothing 28A and the second toothing formed of these two pins while ensuring a gear that does not do not block. Indeed, it is necessary that during a drive of the date ring, each pin can alternatively out of a gap of the teeth 28A and then enter again into a space of this toothing without butter against the top of a tooth. Others characteristics already described in the context of the first embodiment will not be repeated again here. In particular, a jumper spring, similar to that of the first embodiment, is provided for accurately positioning the date ring in a plurality of discrete display positions.

Finally, it will be noted that other embodiments may be provided by those skilled in the art for producing an irreversible transmission system. The irreversible nature can be considered in the range of force pairs that can occur at the wheel meshing with the indicator, especially with the teeth of the ring date, in case of impact or violent movement. It is therefore sufficient for the irreversible character to be obtained up to a maximum force torque generated by the indicator at this wheel in all the situations that the watch equipped with the watch movement according to the invention may encounter. One particular embodiment relates to an electronic movement comprising an electromagnetic motor provided to activate the drive mechanism of the indicator. In the case of a stepper motor, the stator is arranged to generate a positioning torque applied to the permanent magnet rotor of this motor, which can be increased by a short circuit of the coil, particularly in the case of a motor. a Lavet motor. This positioning torque keeps the rotor in at least one stable rest position (position taken in the absence of power supply). The motor can be configured so that the positioning torque of the rotor transmitted at the wheel meshing with the indicator defines a locking torque that is greater than the maximum force torque that can exert the indicator on this wheel, in particular when 'a shock. Preferably, the reduction of the kinematic chain of the drive mechanism is provided relatively large so that the blocking force is sufficiently high. It will be noted that the locking torque obtained depends not only on the positioning torque and the reduction factor of the kinematic chain, but also friction losses in this driveline.

Claims (6)

A watch movement (24) equipped with an analogue display device for a piece of information whose value varies periodically or intermittently, this analog display device comprising, on the one hand, an indicator (26, 26A) of said information provided with a first toothing (28, 28A) and, secondly, a periodic or intermittent drive mechanism (30, 64) of this indicator, this drive mechanism being formed by an irreversible transmission system comprising a second toothing (38; 68,69) which meshes with said first toothing,
characterized in that the display device further comprises a jumper (56) for positioning said indicator generating a positioning force on said first toothing which is sufficient to accurately position said indicator in a plurality of discrete display positions but insufficient for provide a shockproof function for the indicator; in that the first and second sets of teeth have a tangential clearance (J1 + J2) which is sufficiently large so that these first and second sets of teeth do not touch each other when the indicator is in any of said plurality of display positions. discrete display positions and that the irreversible transmission system is in a predefined corresponding position; and in that said irreversible transmission system has an anti-shock function for the indicator via meshing of the first and second teeth at least when said indicator is in any display position of said plurality of positions of discrete display and the irreversible transmission system is in said predefined corresponding position. Watch movement according to claim 1, characterized in that the irreversible transmission system is a Maltese cross system (32, 40). Watch movement according to claim 1, characterized in that the irreversible transmission system is a self-locking pin system (66,68,69). Clock movement according to any one of the preceding claims, characterized in that said positioning force is greater than a maximum friction force exerted by the watch movement on said indicator, and in that this positioning force is less than three times that of maximum friction force. Clock movement according to any one of the preceding claims, characterized in that said tangential clearance (J1 + J2) between the first and second teeth is greater than or substantially equal to twice the cumulative manufacturing tolerances involved in the gear formed by the indicator and the irreversible transmission system at the first and second teeth. Clock movement according to any one of the preceding claims, characterized in that said indicator is a date ring (26A).

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