This application claims priority from European Patent Application No 15201933.7 of Dec. 22, 2015, the entire disclosure of which is hereby incorporated herein by reference.
The present invention generally concerns timepiece mechanisms comprising a rotating wheel set, a support element, a member mounted to pivot on the support element and magnetic return means for returning one portion of the pivoting member against a surface of the rotating wheel set.
There are already known timepiece mechanisms comprising magnetic means for coupling two elements, in particular a cam and a follower lever. Thus,
As explained above, the invention therefore concerns timepiece mechanisms wherein the return means do not operate by means of a spring, but via a pair of magnets generating a magnetic return force. The use of such magnetic return means has the particular advantage of avoiding any problems with spring fatigue. Indeed, when a spring is repeatedly subjected to repetitive stresses, there is a risk of cracks forming and causing a reduction in the coefficient of elasticity, or even breaking the spring.
However, timepiece mechanisms comprising magnetic return means also have some drawbacks. Indeed, the permanent magnets must be arranged in proximity to each other. In such conditions, the omnipresence of a magnetic interaction force between the magnets renders the operation of assembling such mechanisms difficult. It also complicates any disassembly, particularly for repair, and adjustment of the mechanisms.
It is an object of the present invention to overcome the drawbacks of the prior art by providing a timepiece mechanism of the type described above and wherein the rotating wheel set and the parts cooperating therewith can easily be assembled upon assembly of the mechanism, and then easily removed upon disassembly for checking, cleaning or repair, and finally reassembled without difficulty. The present invention achieves this object by providing a timepiece mechanism conforming to the annexed claim 1.
According to the invention, the timepiece mechanism comprises a rotating wheel set, a support element, a member mounted to pivot on the support element and return means for returning, in normal operation, one portion of the pivoting member against a surface of the rotating wheel set. These return means comprise a first magnet carried by the pivoting member and a second magnet carried by the support element separately from the pivoting member, the first magnet and the second magnet being arranged to occupy, in normal operation, respectively a first position relative to the pivoting member and a second position relative to the support element, these first and second positions being arranged such that the interaction of the respective magnetic fields of these first and second magnets generates a first magnetic force which returns said portion of the pivoting member towards said surface of the rotating wheel set. The first magnet or the second magnet is associated with means for varying its position relative to the pivoting member, respectively to the support element, such that it can occupy a third position in which the interaction of the respective magnetic fields of the first and second magnets generates a second magnetic force which tends to move said pivoting member portion away from said rotating wheel set surface. The means for varying the position of the first or second magnet are arranged such that the change between the first position, respectively the second position, and the third position is reversible.
According to an advantageous variant of the invention, the second magnet is arranged to be able to cooperate with a tool to turn the magnet on itself and thereby to be driven in rotation between the second and third positions, in a reversible manner. One advantage of this variant is that it allows a watchmaker to vary the magnetic interaction in the magnetic system provided and especially to change the direction of the magnetic force on the pivoting member to momentarily hold the pivoting member away from the rotating wheel set, thereby facilitating the assembly or disassembly of the timepiece mechanism.
Other features and advantages of the invention will appear upon reading the following description, given solely by way of non-limiting example, with reference to the annexed drawings, in which:
Referring more particularly to
Lever 7 of timepiece mechanisms 1 carries two pivoting members 15a and 15b which are pivoted on the lever about two distinct arbors 17a, 17b. Each of the pivoting members takes the form of a first-class lever with arms that extend on either side of the pivot axis. A first arm ends in a beak 19 and is arranged to act as a click. Each pivoting member thus defines a click in this example. Next, the second arm of each pivoting member carries a magnet 21 (hereafter the first magnet). The first magnet is preferably mounted inside a housing 23 provided for this purpose. Hereafter, each of the two pivoting members will be referred to as “click” given the function thereof.
Referring again to the Figures, it can also be seen that lever 7 carries another magnet 25 (hereafter the second magnet) mounted separately from the two pivoting members 15a, 15b. In the example represented, the three magnets 21 and 25 are substantially aligned and situated in a plane perpendicular to the axis of rotation 2 of oscillating weight 3. The second magnet is disposed at a certain distance from the first two magnets 21 on lever 7. It can also be seen that magnets 21 and 25 are disc-shaped and that their polarization direction substantially corresponds to the direction of alignment of the magnets in the plane perpendicular to axis 2.
Timepiece mechanism 1 further comprises a rotating wheel set 27. In the example represented, the rotating wheel set is a ratchet wheel. In a known manner, the ratchet wheel is arranged to be driven by the two clicks 15a and 15b. In the embodiment illustrated in
Referring more particularly to
According to the invention, at least one of the first and second magnets 21, 25 is arranged to allow a watchmaker to change its polarization direction, or preferably its sense of polarization (its polarity along the direction of alignment of the magnets) and thereby vary the magnetic force acting on each of clicks 15a and 15b. In the variant described here, second magnet 25 is arranged to be capable of a 180° rotation with respect to lever 7 on which it is mounted, in a reversible manner, with the aid of a screwdriver. It is thus easy to change the polarity of this second magnet. Thus, starting from the configuration of
It will be noted that second magnet 25, which is partially housed inside a cavity of lever 7, takes the form of a slotted screw head to allow a watchmaker to rotate the magnet using a screwdriver. According to a variant, the second magnet is mounted inside a rotating housing (not represented) which is in turn housed inside a cavity of the lever, this housing presenting the means for varying the angular position of the second magnet. One advantage of this variant is that it allows the second magnet to rotate without subjecting the latter to mechanical stresses. For example, the housing will be mounted to rotate with friction inside a circular hole in the lever. The friction makes it possible to hold the second magnet in a first angular position during normal operation of the timepiece mechanism. This friction also makes it possible to hold the second magnet in a second angular position, corresponding to a non-operating configuration, once a watchmaker has rotated the housing, particularly during assembly or disassembly of the timepiece mechanism.
When second magnet 25 is rotated by 180°, the three magnets 21, 25 are then polarized in the same sense as represented in
The invention has yet another advantage, since the ability to rotate a magnet makes it possible to vary the direction of the axis of magnetisation of the magnet and therefore the interaction with the other magnet of the magnetic system concerned, and especially to vary the intensity of the magnetic force between the two magnets. It is therefore possible to adjust the intensity of the magnetic force acting on the pivoting member. Fine adjustment of the magnetic force may be important for optimising the function, especially the intensity of the return force exerted on the pivoting member. In a first variant, in particular for a click or a jumper spring, the magnet arranged to rotate on of the support element forms a cam, i.e. the magnet is not centred on the axis of rotation thereof. Therefore, varying the angular position of the magnet also moves it closer to or further from the magnet carried by the rotating member. In a second variant, the magnet does not have a cylindrical or square shape, in projection onto a general plane perpendicular to its axis of rotation, but a different shape, for example rectangular or elliptical. As in the first variant, such a configuration makes it possible to vary the intensity of the force exerted in the magnetic system concerned.
Referring again to
It will also be understood that various modifications evident to those skilled in the art may be made to the variant embodiments forming the subject of the present description without departing from the scope of the present invention defined by the annexed claims. In particular, the present invention is not limited to a self-winding mechanism. Indeed, those skilled in the art know of very many other watchmaking applications in which wheels or rings and clicks or jumper springs are implemented. The present invention is capable of being adapted without difficulty to each of these applications. Moreover, clicks and jumper springs are naturally not the only examples of pivoting members capable of being arranged to cooperate with a rotating wheel set. Among examples other than clicks, the following may also be cited: cam control mechanisms, return-to-zero mechanisms using a hammer, engagement coupling mechanisms and lever mechanisms for perpetual calendars.
Number | Date | Country | Kind |
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15201933.7 | Dec 2015 | EP | regional |