CH720894A2 - Clock mechanism comprising a cam - Google Patents

Abstract

The clockwork mechanism comprises a cam wheel set intended to be driven in rotation and a cam follower, the cam wheel set comprising a drive wheel (23) and a cam (25) arranged in a coaxial position on the drive wheel, the cam follower being biased against the cam (25), and the profile of the cam having at least one recess that the cam follower is arranged to be able to cross when the cam wheel set is driven in a first direction, the recess on the other hand obstructing the cam follower when the latter is pressing against the cam (25) and the cam wheel set is driven in the other direction. The cam (25) is arranged to be able to pivot axially relative to the drive wheel (23), the drive wheel (23) and the cam (25) being coupled in rotation by a friction coupling.

Description

[0001] The present invention relates to a timepiece mechanism comprising a cam wheel and a cam follower, the cam wheel being intended to be driven in rotation and comprising a drive wheel and a cam arranged in a coaxial position on the drive wheel, the cam follower being biased against the cam, and the profile of the cam having at least one recess that the cam follower is arranged to be able to cross when the cam wheel is driven in a first direction, the recess on the other hand obstructing the cam follower when the latter is resting against the cam and the cam wheel is driven in the other direction.

PRIOR ART

[0002] Many clock mechanisms are known which conform to the definition given above. For example, patent document CH 666 591 G A3 describes a mechanism indicating the days of the week, the indicator hand of which, instead of always rotating in the same direction opposite a circular graduation, quickly returns to its starting point to begin a new course as soon as it has travelled the entire length of its graduation in an arc of a circle.

[0003] The attached Figure 1A is a slightly adapted version of Figure 1 of document CH 666 591 G A3. This figure is a plan view of the dial side of a calendar watch comprising two retrograde hand displays provided to indicate the date and the day of the week respectively. The display of the day of the week is ensured by the cooperation of a retrograde hand (referenced 12) and an arc-shaped graduation (referenced 12a). It can be seen that the graduation 12a is divided into seven steps corresponding to the seven days of the week. It can also be noted that the calendar watch shown in Figure 1A comprises a winding and time-setting crown (referenced 8). Although the aforementioned document does not indicate how to manually reset the calendar to the date, it is quite certain that such a correction is possible.

[0004] The attached Figure 1B is a slightly adapted version of Figure 2 of the same prior document. Figure 1B schematically illustrates the day of the week indicator mechanism of the calendar watch of Figure 1A. Referring to Figure 1B, there can first be seen a snail-shaped cam 5 which is mounted coaxially on the day star 3 of the calendar mechanism so as to be rotated by the movement of the watch. Figure 1B also shows a pinion 10 which carries the indicator hand 12. The pinion 10 is also connected to return means 13 which are arranged to return the hand 12 in the direction of the first day of the week. The indicator mechanism also comprises a rack 7 arranged to mesh with the pinion 10, so that the rack controls the position of the hand. The rake 7 further carries a finger 6 which is arranged to cooperate with the profile of the snail-shaped cam 5. Furthermore, since the rake 7 is connected to the return means 13 via the pinion 10, the return means 13 also have the effect of lowering the finger 6 against the profile of the snail-shaped cam 5.

[0005] When the cam 5 rotates clockwise, it gradually lifts the finger 6, so that the rack 7 slowly pivots counterclockwise, driving the pinion 10 with which it is engaged. The rack 7 rotates the pinion 10 clockwise, against the torque generated by the return means 13. When the finger 6 reaches the top of the profile of the cam 5, the return means 13 suddenly cause it to fall into the cam recess, so that it finds itself “instantaneously” at the bottom of the profile. The rack 7 tilts integrally with the finger 6, so that the hand 12 returns to its starting point corresponding to Monday. Display mechanisms whose hands behave in this way are called retrograde.

[0006] As we have just seen, the profile of the cam of a retrograde display mechanism normally has at least one step. However, generally speaking, the presence of one or more steps on the profile of a cam can be problematic. In particular, if such a cam is part of an indicator mechanism, and a user, wishing to correct the displayed indication, manually controls the rotation of the cam in reverse, he risks breaking the mechanism. Indeed, if the cam has one or more steps and is rotated backwards, one of the steps risks coming into contact with the cam follower finger, causing part of the mechanism to break. This is in particular the reason why most watches with retrograde displays can only be set forwards.

[0007] The problem which has just been explained concerning watch mechanisms equipped with a cam whose profile has one or more recesses is absolutely not limited to indicator mechanisms with retrograde display. We find for example the same problem with minute repeater watches.

BRIEF DESCRIPTION OF THE INVENTION

[0008] An object of the present invention is to remedy the problem of the prior art which has just been explained. The present invention achieves this and other objects by providing a clock mechanism which is in accordance with the appended claim 1. This mechanism comprises in particular a cam whose profile has at least one step.

[0009] According to the invention, the drive wheel and the cam are permanently coupled by a friction coupling, the friction giving the cam the possibility of angularly shifting relative to the drive wheel. It will be understood that, thanks to this characteristic, when the cam wheel set is driven in said other direction, and the cam offset abuts against the cam follower, the drive pinion has the possibility of continuing to rotate about its axis even when the cam is blocked. An advantage of such a construction is that it allows a correction to be manually controlled, even in said other direction, without any risk of jamming, blocking or deterioration of the various elements of the mechanism.

BRIEF DESCRIPTION OF THE FIGURES

[0010] Other features and advantages of the present invention will become apparent upon reading the following description, given solely as a non-limiting example, and with reference to the appended drawings in which: FIG. 1A is a plan view of the dial side of a calendar watch of the prior art which includes a retrograde display of the date and the day of the week; FIG. 1B is a schematic plan view of the dial side of the day of the week indicator mechanism which equips the calendar watch of FIG. 1A; FIG. 2A is a perspective view of the cam wheel set of a timepiece mechanism according to a particular embodiment of the invention; FIG. 2B is a cross-sectional view of the cam wheel set of FIG. 2A; FIG. 3A is a partial cross-sectional view showing the cam of the cam wheel set of FIGS. 2A and 2B; – Figure 3B a partial perspective view showing the cam carrier of the cam wheel of Figures 2A and 2B.

DETAILED DESCRIPTION OF AN EMBODIMENT

[0011] Figures 2A, 2B, 3A and 3B are different views of the cam wheel of a clock mechanism according to an exemplary embodiment of the invention.

[0012] Referring first to FIGS. 3A and 3B, it can be seen that the cam wheel shown is composed of a cam 25 (illustrated in FIG. 3A) and a cam carrier 21 (illustrated in FIG. 3B). Referring also to FIG. 2A, it can be seen that the cam 25 has a spiral-shaped profile. The shape of the cam is such that by traveling along its profile, in a first direction, from the point of the profile (referenced 18) which is closest to the axis of rotation, one gradually moves away from this axis, until one has reached the point of the profile (referenced 19) which is furthest from the axis. Then, it can be seen that, past point 19, the profile forms a step that connects the most distant point 19 to the closest point 18. A cam that has this kind of spiral shape is called a "snail". Known snails can be linear like the one illustrated in the figures or, alternatively, be stepped.

[0013] Referring more particularly to the cross-section of FIG. 3A, it can be seen that the lower face of the cam 25 has a recess 27, and that two holes 28a, 28b are arranged in the upper face of the cam 25. These two holes open into the recess 27. Finally, as will be seen in more detail later, the recess 27 is sized so as to allow the cam carrier 21 to be inserted therein.

[0014] Referring now to FIG. 3B, it can be seen that the cam carrier 21 firstly comprises a drive pinion 23 and a barrel 24 which is rigidly fixed to the pinion 23 in a coaxial position. The cam carrier 21 also comprises a support element 22 which carries an auxiliary pinion 29 in a coaxial position. Finally, the figures also show a circlip 30 arranged so as to retain the barrel 24 in the support element 22. The latter is mainly formed of a bar which has two bores 31a and 31b close to its ends. These two bores are used to fix the support element 22 under the cam 25. It will be understood that the bores 31a, 31b are in the extension of the two bores 28a, 28b of the cam 25 when the support element 22 and the cam 25 are assembled. It can further be seen that the upper face of the support element 22 has two shoulders 26a and 26b between which the thickness of the bar is reduced. This portion of reduced thickness which is included between the two shoulders 26a, 26b forms a board whose dimensions are adapted to allow it to house the circlip 30.

[0015] Referring more particularly to FIG. 2B, it can be seen that the cam 25 and the support element 22 each have a central hole arranged in the extension of one another. The two central holes are concentric with the axis of rotation of the cam mobile. It can also be seen that a short cylindrical bearing surface, the inside diameter of which is equal to that of the central hole, projects axially from the lower face of the support element 22, so as to form a rim around the central hole. The cylindrical bearing surface is arranged to cooperate with the auxiliary pinion 29. Indeed, the board of the auxiliary pinion 29 has a wide circular opening, and the cylindrical bearing surface is dimensioned so as to be able to be inserted into this opening by driving, so as to secure the auxiliary pinion 29 and the support element 22.

[0016] Still referring to FIG. 2B, it can be seen that the barrel 24 of the pinion 23 is inserted successively through the central hole of the support element 22 and through that of the cam 25. The drive pinion 23 is thus in abutment against the lower face of the auxiliary pinion 29, and the upper end of the barrel 24 emerges from the upper face of the cam 25. The barrel 24 has a first bearing surface which extends upwards from the drive pinion 23 and whose external diameter corresponds to the internal diameter of the central hole of the support element 22. It will be understood on the one hand from the above that the cam mobile is supported by the drive pinion 23, and on the other hand that the cooperation of the barrel 24 with the central hole of the support element 22 makes it possible to ensure the axial positioning of the cam mobile.

[0017] FIG. 3B also shows that the first bearing surface of the barrel 24 is bordered on the upper side by a flat-bottomed groove designed to receive the circlip 30. The latter is formed by a plate cut out of metal or silicon. It can be seen that the central part of the circlip 30 constitutes a sort of circular crown comprising two arcuate sections arranged symmetrically on either side of the barrel 24 and which press against the bottom of the groove in the manner of two jaws. Each of the ends of one of the arcuate sections is separated from one of the ends of the other arcuate section by an open gap, and it can be seen that the circlip 30 also comprises two U-shaped lateral parts which surround the open gaps, each of the U-shaped parts connecting one of the ends of one of the two arcuate sections to one of the ends of the other arcuate section. The U-shaped elastic side parts perform a dual function. To begin with, when the barrel 24 pivots inside the central hole of the support element 22, the elastic side parts abut against the two shoulders 26a, 26b, so that the circlip and the support element 22 are rotationally integral. On the other hand, the elastic side parts also perform a spring function, urging the two arc-shaped sections towards the bottom of the groove of the barrel 24.

[0018] It will be understood that the coupling produced by the circlip 30 between the barrel 24 and the support element 22 is a friction coupling allowing the drive pinion 23 to rotate about its axis even while the cam 25 remains stationary.

[0019] It will further be understood that various modifications and/or improvements obvious to a person skilled in the art may be made to the embodiments which are the subject of the present description without departing from the scope of the present invention defined by the appended claims.

Claims (8)

1. A clockwork mechanism comprising a cam wheel set intended to be driven in rotation and a cam follower, the cam wheel set comprising a drive wheel (23) and a cam (25) arranged in a coaxial position on the drive wheel, the cam follower being biased against the cam (25), and the profile of the cam having at least one recess that the cam follower is arranged to be able to cross when the cam wheel set is driven in a first direction, the recess on the other hand obstructing the cam follower when the latter is resting against the cam (25) and the cam wheel set is driven in the other direction; characterized in that the cam (25) is arranged to be able to pivot axially relative to the drive wheel (23), and in that the drive wheel (23) and the cam (25) are coupled in rotation by a friction coupling. 2. Clock mechanism according to claim 1, characterized in that the cam wheel comprises a support element (22) rigidly fixed to the cam (25), and in that the drive wheel (23) is pivoted on the support element. 3. Clock mechanism according to claim 2, characterized in that the support element (22) is crossed by a hole which is coaxial with the cam mobile, and in that the cam mobile comprises a shaft (24) fixed to the drive wheel (23) in a coaxial position, the shaft (24) being inserted into the hole of the support element (22), and being retained in the hole by a circlip (30). 4. Clock mechanism according to claim 3, characterized in that the support element (22) comprises at least one stop (26a, 26b) arranged so as to prevent the circlip (30) from rotating relative to the cam (25). 5. Clock mechanism according to one of the preceding claims, characterized in that the cam (25) is a snail. 6. Clock mechanism according to one of the preceding claims, characterized in that it is a display mechanism. 7. Clock mechanism according to claim 6, characterized in that it is a retrograde display mechanism. 8. Clock mechanism according to one of claims 1 to 5, characterized in that it is a minute repeater mechanism.