CH718986B1 - Watch movement comprising an oscillator suspension device. - Google Patents

Abstract

The invention relates to a watch movement comprising an oscillator (5) provided with an escapement device (9), and a device (13) for suspending the oscillator (5) arranged to allow only two degrees of freedom in rotation in order to authorize the oscillator (5) to change orientation in a predefined volume, the watch movement (3) further comprising a device (19) for oblique transmission of force to the escapement device (9) allowing to change the orientation of the oscillator (5) in the predefined volume with each oscillation of the resonator (5) in order to make the oscillator (5) less sensitive to the force of gravity.

Description

TECHNICAL FIELD OF THE INVENTION

[0001] The present invention relates to a watch movement with low sensitivity to gravity and, more particularly, a watch movement whose movements of the oscillator make it possible to make the oscillator less sensitive to the force of gravity in order to reduce the rate differences between the different horizontal and vertical positions of the watch movement and, incidentally, of the timepiece.

TECHNICAL BACKGROUND OF THE INVENTION

[0002] In order to make a watch movement and in particular its resonator less sensitive to gravity, there already exist tourbillon or carousel mechanisms making it possible to cause the resonator to rotate around itself in order to cancel out the rate deviations in the movements. vertical positions. However, even with these mechanisms, the step deviation is still sensitive to variations in horizontal positions.

SUMMARY OF THE INVENTION

[0003] The aim of the invention is to propose a watch movement with low sensitivity in relation to gravity whatever its position in order to reduce its rate deviation.

[0004] To this end, the invention relates to a watch movement comprising an oscillator comprising a resonator capable of oscillating around a first axis of rotation to serve as a time base for the watch movement and an escapement device selectively applying to the resonator a force from the watch movement in order to maintain and count the oscillations of the resonator, characterized in that the watch movement further comprises an oscillator support system comprising a suspension device arranged to allow only two degrees of freedom in rotation along second and third concurrent axes, said second axis and third axis being different from the first axis, in order to authorize the oscillator to change orientation in a predefined volume, and a device for oblique force transmission to the device exhaust in order to make the oscillator less sensitive to the force of gravity.

[0005] Advantageously according to the invention, it is understood that the oscillator moves in a complex movement capable of making it less sensitive to the consequences of the force of gravity while being permanently guided, that is to say while knowing in advance the movement that it will carry out as a function of the geometries of the suspension device and the oblique force transmission device. We immediately deduce that, whatever the position of the watch movement (typically whatever the horizontal and vertical positions), the oscillator, through its complex movement, makes it possible to reduce the rate deviation of the watch movement.

[0006] Consequently, using the simple and robust suspension device, we avoid using a mechanism of the tourbillon or carousel type that is difficult to manufacture and adjust, while making it possible to obtain an effect of reducing the sensitivity to gravity in all positions of the watch movement, that is to say both horizontal and vertical.

[0007] Furthermore, the transmission device by its transmission of an eccentric and oblique rotary movement, that is to say inclined, makes it possible to selectively impose the complex movement of the oscillator inside the volume predefined by the suspension device.

[0008] The invention may also include one or more of the following optional characteristics, taken alone or in combination.

[0009] The oblique transmission device may comprise a bent shaft, a first end of which is rotatably mounted relative to a fixed part of the watch movement along a fourth axis and receives the force of the watch movement, and a second end of which transmits, according to a predetermined inclination of the bent shaft relative to the fourth axis, the force on the escapement device making it possible to change the orientation of the oscillator in the predefined volume at each oscillation of the resonator.

[0010] The suspension device is preferably of the Cardan type and may comprise an internal cage pivotally mounted along a second longitudinal axis in an external ring, itself pivotally mounted along a third transverse axis, perpendicular or not to the second longitudinal axis, for example relative to a fixed part of the watch movement, the oscillator being mounted in the internal cage.

[0011] The Cardan suspension device advantageously allows you to choose in advance the predefined volume in which the movement of the oscillator, and more generally of the internal cage, will be circumscribed within the internal space of the external ring . It is understood that the more the inclination and the proximity of the second end of the bent shaft are pronounced relative to the fourth axis of rotation of the bent shaft, the less the opening angle of the cone formed by the movement of the first axis of rotation of the resonator will be important.

[0012] Consequently, compared to a Cardan suspension of a marine chronometer, in the invention, it is advantageously the oscillator which is guided (and not the case of the marine chronometer) and moved according to the eccentric movement and inclined of the bent shaft (and not by the force of gravity induced on the marine chronometer case).

[0013] The internal cage may include a lower part receiving a force transmission gear of the oblique transmission device coupled between the bent shaft and an escape wheel of the escape device, an intermediate part receiving the escape device and an upper part receiving the resonator. The internal cage therefore comprises a stepped architecture, the intermediate part of which is preferably connected laterally, by pivoting connections along the second longitudinal axis, to the internal surface of the external ring of the Cardan suspension device.

[0014] The transmission train of the oblique transmission device may comprise a transmission shaft pivotally mounted along a fifth axis (which can be confused with the first axis of rotation of the resonator) in the lower part of the internal cage, connected in such a manner fixed relative to the second end of the bent shaft and provided with a toothed wheel inducing relative movement relative to the lower part of the internal cage during rotation of the bent shaft to transmit the force of the shaft bent to a pinion mounted in the lower part and connected to the escape wheel. It is understood that no gear transmission is used to transmit the force from the bent shaft to the transmission shaft pivotally mounted along the fifth axis but that a simple interlocking connection is used. It is therefore the relative displacement of the bent shaft - transmission shaft assembly relative to the internal cage which makes it possible to transmit the force of the bent shaft - transmission shaft assembly to the exhaust device in order to maintain and count the oscillations of the resonator. Preferably, the connection by embedding is obtained by a tenon - mortise assembly with a polygonal section so that no relative movement is possible between the bent shaft and the shaft of the transmission gear. Finally, as explained above, it is not essential that the fifth axis of the transmission shaft coincides with the first axis of rotation of the resonator for the invention to work. The fifth axis of rotation could therefore be eccentric in relation to the first axis of rotation.

[0015] According to an alternative intended respectively for the second and third embodiments of the invention, the fourth axis of rotation of the first end of the bent shaft can be either vertical and perpendicular to the third transverse axis of the external ring, either horizontal and perpendicular to the third transverse axis of the external ring. This alternative is essentially guided by the choice to make the movement of the oscillator even more complex to make the oscillator even less sensitive to the force of gravity.

[0016] Thus, in the first part of the alternative relating to the second embodiment, the support system can also include a mechanism for rotating the third transverse axis around the fourth vertical axis in order to make the oscillator even less sensitive to the force of gravity. We understand that the rotation mechanism makes it possible to obtain an effect similar to a tourbillon mechanism applied to the Cardan suspension device (and not to a resonator as in a known tourbillon regulating organ).

[0017] Furthermore, in the second part of the alternative relating to the third embodiment, the support system may further comprise a mechanism for pivoting the oscillator around the fourth axis and/or a rotation mechanism of the third transverse axis around a sixth vertical axis perpendicular to the third transverse axis in order to make the oscillator even less sensitive to the force of gravity. We understand that the rotation mechanism makes it possible to obtain an effect similar to a single or double tourbillon mechanism applied to the Cardan suspension device (and not to a resonator as in a known tourbillon regulating organ).

[0018] Finally, the invention relates to a timepiece characterized in that it comprises a watch movement as presented above.

BRIEF DESCRIPTION OF THE DRAWINGS

[0019] Other particularities and advantages of the invention will emerge clearly from the description given below, for information only and in no way limiting, with reference to the appended drawings, in which: – Figure 1 is a schematic view a timepiece according to the invention; – Figure 2 is a perspective view of a first embodiment of a support system according to the invention; – Figure 3 is a sectional view along plane III-III of Figure 2; – Figures 4 and 5 are perspective views of a second embodiment of a support system according to the invention; – Figures 6 and 7 are sectional views along two different vertical planes of the second embodiment of a support system according to the invention; – Figures 8 and 9 are perspective views of a third embodiment of a support system according to the invention; – Figure 10 is a sectional view along the plane XX of Figure 9; – Figures 11 to 14 are perspective views of successive configurations of the first embodiment of a support system according to the invention whose bent shaft has been moved at four different angles around the fourth axis of rotation.

DETAILED DESCRIPTION OF AT LEAST ONE MODE OF CARRYING OUT THE INVENTION

[0020] In the different figures, the identical or similar elements bear the same references, possibly added with an index. The description of their structure and function is therefore not systematically included.

[0021] In everything that follows, the orientations are the orientations of the figures. In particular, the terms 'upper', 'lower', 'left', 'vertical', 'right', 'above', 'below', 'forward' and 'backwards' are generally understood in relation to the meaning of representation of the figures.

[0022] By “timepiece 2” we mean all types of instruments for measuring or counting time such as pendulums, clocks, watches, etc.

[0023] By “watch movement 3” we mean all types of mechanism capable of counting time whether they are powered by mechanical energy (for example a barrel) or electrical energy (for example a battery).

[0024] By “fixed part of the watch movement 3”, we mean all the elements or bodies fixed in relation to the plate or the plate itself.

By “Cardan type suspension device 13” is meant a Cardan suspension mechanism comprising two independent concentric elements such as an internal cage 14 and an external ring 15, respectively movable around two axes A2, A3. The latter can, for example, be perpendicular to each other or not. The object to be suspended, here an oscillator 5, is fixed on the internal element (like the internal cage 14) and the external element (like the internal ring 15) is mounted pivoting directly or indirectly (depending on the embodiments ) on a fixed part of the watch movement 3. It was notably noted that angles between the two axes A2, A3 equal to forty-five degrees, eighty degrees and ninety degrees all made it possible to obtain movements oscillator complexes 5.

[0026] In the present description, to clarify the explanation of the invention, the axes (A1, A2, etc.) are arbitrarily declared as a first axis, a second axis, etc. It is a simple nomenclature to differentiate and name non-identical geometric elements. This nomenclature does not imply a priority of one axis over another and such denominations can easily be interchanged without departing from the scope of this description. This nomenclature does not imply an order either, that is to say that a third axis could be used without a first axis and/or a second axis being necessary for the implementation of the invention.

As illustrated in Figure 1, the invention relates to a watch movement 3 intended to be integrated into a timepiece 2 such as for example a wristwatch. The watch movement 3 preferably comprises an oscillator 5 with a resonator 6 of the balance 7 - balance spring 8 type and an escapement device 9 of the Swiss anchor type 10.

The resonator 6 is able to oscillate around a first axis A1 of rotation to serve as a time base for the watch movement 3. In the examples of Figures 2 to 14, the resonator 6 comprises a balance 7 of the inertia type variable making it possible to correct its moment of inertia, for example, using adjusting screws and a hairspring 8 of the cylindrical type making it possible to obtain a concentric development of the hairspring during oscillations. As explained below, the escapement device 9 applies to the resonator 6 a force from the watch movement 3 in order to maintain and count the oscillations of the resonator 6.

[0029] According to a feature common to all embodiments of the invention, the watch movement 3 further comprises a system 1 for supporting the oscillator 5 comprising a suspension device 13 and an oblique force transmission device 19 . The suspension device 13 is arranged to authorize only two degrees of freedom in rotation along second A2 and third A3 concurrent axes, said second axis A2 and third axis A2 being different from the first axis A1. Such a suspension device 13 is preferably of the Cardan type and comprises an internal cage 14 pivotally mounted along the second longitudinal axis A2 relative to an external ring 15. The outer ring 15 is pivotally mounted along the third transverse axis A3, perpendicular or not to the second longitudinal axis A2, relative to a fixed part of the watch movement 3 such as the plate using two bearings. As visible in Figures 2 to 14, the oscillator 5 is mounted, preferably directly, in the internal cage 14 in order to authorize the oscillator 5 to change orientation in a predefined volume. We therefore understand that the Cardan suspension device 13 advantageously allows in advance to choose the predefined volume in which the movement of the oscillator 5, and more generally of the internal cage 14, will be circumscribed within the internal space of the outer ring 15.

In the examples illustrated in Figures 2 to 14, the internal cage 14 comprises a lower part 16, an intermediate part 17 and an upper part 18. The internal cage 14 therefore comprises a stepped architecture, the intermediate part 17 of which is preferably connected laterally, by pivoting connections along the second longitudinal axis A2, to the internal surface of the external ring 15. The lower 16 and upper 18 parts have similar bowl-shaped geometries, each base of which has a bearing. Note that the upper part 18 being intended to receive the resonator 6, its associated bearing is of the bumper type (receiving groove, counter-pivot stone, cushion and elastic retaining element) while that of the lower part 16 comprises a simple pad. In the example of Figures 2 to 14, the lower parts 16 and upper 18 are attached with an offset of ninety degrees relative to the first axis A1 of rotation on two opposite faces of the intermediate part 17 by screwing. For this, the intermediate part 17 comprises a central board 25 receiving a second bearing of the bumper type (receiving groove, counter-pivot stone, cushion and elastic retaining element) for the other pivoting end of the resonator 6, a bearing lower part of the anchor 10 and being attached to the lower part 16.

The intermediate part 17 further comprises an upper board 26 and a lower cradle 27 on either side of the central board 25. The upper board 26 of substantially annular shape is mounted between the central board 25 and the balance 7 of the resonator 6 using two pillars 29 (better visible in Figure 6) diametrically opposed to the first axis A1 and receiving a bearing upper part of the anchor 10. The lower cradle 27 is only intended to receive a bearing of the simple cushion type to be functionally associated with that of the lower part 16 of the internal cage 14 to pivotally mount a part of the transmission cog 20. Finally, the central board 25 comprises studs 28 whose upper parts are attached to the upper part 18 of the internal cage 14 and whose external faces receive the pivots (not visible) each intended to cooperate with a bumper-type bearing (receiving groove, counter-pivot stone, cushion and elastic retaining element) provided in the external ring 15 of the Cardan suspension device 13.

In the examples illustrated in Figures 2 to 14, the resonator 6 is received in the upper part 18 and pivotally mounted between the bumper bearing of the upper part 18 and the bumper bearing of the central board 25. As visible in Figures 2 to 14, the resonator 6 is mounted in the traditional manner on a pivoting shaft 31. The cylindrical spring 8 is thus, on the one hand, pinned to the upper part 18 laterally in relation to the bumper bearing and, on the other hand, to a ferrule fitted onto the pivoting shaft 31. Coaxially below the shell, the balance 7 is mounted on the shaft 31 which also pivots (best visible in Figure 7). Of course, other types of resonator and/or the same type of resonator with different organs are possible without departing from the scope of the invention such as, for example, a tuning fork resonator or a resonator with a balance 7 and/or a different hairspring 8(s).

[0033] In the examples illustrated in Figures 2 to 14, the exhaust device 9 is received in the intermediate part 17 and is of the Swiss anchor type. The anchor 10 is pivotally mounted between a bearing bearing of the upper board 26 and a bearing bearing of the central board 25. The anchor 10 comprises three parts in one piece or not (better visible in Figures 2, 3 and 6). The first part 10a comprises the arms provided with entry and exit pallets. The second substantially cylindrical part 10b makes it possible to space and secure in rotation the first 10a and third 10c parts. The third part 10c comprises the fork and the dart intended to cooperate with the double plate - pin assembly mounted in the usual manner on the shaft 31 (best visible in Figures 6 and 7). We can see in Figure 2 that the first part 10a is provided in a clearance of the central board 25 allowing the entry and exit lifts to cooperate laterally with the escape wheel 11. The latter is pivotally mounted using a shaft 12 mounted between a bush bearing of the lower part 16 and a bush bearing of the central board 25 (best visible in Figure 6).

Of course, other types of exhaust device 9 and/or the same type of exhaust device 9 with different members are possible without departing from the scope of the invention such as, for example, a device 9 exhaust of the trigger or cylinder type, or an escape device 9 with a different wheel 11 and/or anchor 10.

In the examples illustrated in Figures 2 to 14, the transmission gear 20 of the oblique transmission device 19 is received in the lower part 16. the transmission cog 20 comprises two shafts 12, 22 intended to transmit the force to the exhaust device 9. The shaft 22 is pivotally mounted along a fifth axis A5 between a cushion bearing of the lower part 16 and a cushion bearing of the lower cradle 26 (best visible in Figures 3 and 7) and comprises a toothed wheel 23. We further note that the shaft 22 has an end 22a which passes through the bush bearing of the lower part 16 in order to be able to cooperate with the end 21b of the bent shaft 21 as explained below. The shaft 12 is pivotally mounted along an axis substantially parallel to the fifth axis A5 between a bush bearing of the lower part 16 and a bush bearing of the central board 25 (best visible in Figures 3 and 6) and comprises, at one end, a pinion 24 intended to be coupled to the toothed wheel 23 and, at the other end, the escape wheel 11.

Advantageously according to the invention, the device 19 for oblique force transmission preferably comprises a bent shaft 21. Thus, a first end 21a of the bent shaft 21 is rotatably mounted relative to a fixed part of the watch movement 3 along a fourth axis A4 and receives the force of the watch movement 3 such as for example the force transmitted by a cog coupled to d 'a source of mechanical energy such as a barrel mainspring. A second end 21b transmits, according to a predetermined inclination α along an axis B of the shaft 21 bent with respect to the fourth axis A4, the force to the exhaust device 9 making it possible to change the orientation of the oscillator 5 in the volume predefined at each oscillation of the resonator 6 in order to make the oscillator 5 less sensitive to the force of gravity.

Advantageously according to the invention, it is understood that the oscillator 5 moves in a complex movement capable of making it less sensitive to the consequences of the force of gravity while being permanently guided, that is to say all knowing in advance the movement that it will carry out depending on the geometries of the Cardan suspension device 13 and the bent shaft 21. We immediately deduce that, whatever the position of the watch movement 3 (typically whatever the horizontal and vertical positions), the oscillator 5, through its complex movement, makes it possible to reduce the deviation of the watch movement 3. Preferably, the predetermined inclination α along an axis B of the shaft 21 bent relative to the fourth axis A4 is substantially equal to forty-five degrees to maximize the amplitude of the complex movement. Of course, depending on the desired effect, the predetermined inclination α along an axis B of the shaft 21 bent relative to the fourth axis A4 can be chosen between a value greater than zero degrees and less than ninety degrees.

[0038] Furthermore, the transmission device 19 by its transmission of an eccentric and inclined rotary movement by the bent shaft 21 makes it possible to selectively impose the complex movement of the oscillator 5, and more generally of the internal cage 14 , inside the volume predefined by the Cardan suspension device 13. We understand in fact that the more the inclination along an axis B and the proximity of the second end 21 b of the bent shaft 21 are pronounced relative to the fourth axis A4 of rotation of the bent shaft 21, the less the angle d The opening of the cone formed by the movement of the first axis A1 of rotation of the resonator 6 will be significant.

Consequently, compared to a Cardan suspension of a marine chronometer, in the invention, it is advantageously the oscillator 5 which is guided (and not the case of the marine chronometer) and moved according to the movement eccentric and inclined of the bent shaft 21 (and not by the force of gravity induced on the case of the marine chronometer).

[0040] As visible in Figures 3, 5 and 10 in particular, the transmission shaft 22 is connected, via its end 22a, in a fixed manner relative to the second end 21b of the bent shaft 21 inducing a relative movement of the toothed wheel 23 relative to the lower part 16 of the internal cage 14 during the rotation of the bent shaft 21 along the fourth axis A4. The force of the bent shaft 21 is therefore then transmitted to the pinion 24 then to the exhaust wheel 11. It is understood that no gear transmission is used to transmit the force from the bent shaft 21 to the transmission shaft 22 but that a simple interlocking connection is used. It is therefore the relative movement of the bent shaft 21 - transmission shaft 22 assembly which makes it possible to transmit the force of the bent shaft 21 - transmission shaft 22 assembly to the exhaust device 9 in order to maintain and count the oscillations of the resonator 6. In the examples illustrated in Figures 2 to 14, the connection by embedding is obtained by a tenon - mortise assembly with a square polygonal section so that no relative movement is possible between the bent shaft 21 and the shaft 22 transmission. As already explained above, it is not essential that the fifth axis A5 of the transmission shaft 22 coincides with the first axis A1 of rotation of the resonator 6 for the invention to work, although this is the case in the examples illustrated in Figures 2 to 14.

[0041] Three embodiments are presented in Figures 2 to 14. The three embodiments differ mainly by the orientation of the fourth axis A4 or by the functionalities provided compared to the first, simplest embodiment. The first embodiment is presented in Figures 2 to 3 and 11 to 14. It can be seen that, in the first embodiment, the fourth axis A4 is substantially vertical, that is to say perpendicular to the third transverse axis A3 of the external ring 15. By comparison between Figures 11 and 13 and, 13 and 14, between which an angle of one hundred and eighty degrees and ninety degrees has been imposed on the shaft 21 bent with respect to the fourth vertical axis A4, we see sees that the external ring 15 pivots in a back-and-forth movement relative to the third axis A3 inducing a pitch component to the oscillator 5. In addition, by comparison between Figures 12 and 13, between which a angle of forty-five degrees was imposed on the shaft 21 bent relative to the fourth vertical axis A4, we see that the internal cage 14 pivots in a complex movement relative to the second A2 and third axis A3 respectively inducing components roll and pitch to oscillator 5.

[0042] Advantageously according to the first embodiment of the invention, it is understood that the oscillator 5 moves in a complex movement capable of making it less sensitive to the consequences of the force of gravity by its transmission of an eccentric rotary movement and inclined by the bent shaft 21 while being permanently guided, that is to say while knowing in advance the movement that it will carry out depending on the geometries of the Cardan suspension device 13. We immediately deduce that, whatever the position of the watch movement 3 (typically whatever the horizontal and vertical positions), the oscillator 5, through its complex movement, makes it possible to reduce the rate deviation of the watch movement 3.

[0043] The second embodiment is presented in Figures 4 to 7. It can be seen that, like the first embodiment, in the second embodiment, the fourth axis A4 is substantially vertical, that is to say perpendicular to the third transverse axis A3 of the external ring 15. However, compared to the first embodiment, the support system 1 of the second embodiment further comprises a mechanism 32 for rotating the third transverse axis A3 around the fourth vertical axis A4 in order to make the oscillator 5 even less sensitive to the force of gravity. It is understood that the rotation mechanism 32 makes it possible to obtain an effect similar to a tourbillon mechanism applied to the Cardan suspension device 13 (and not to a resonator as in a known tourbillon regulating member).

[0044] For this purpose, the rotation mechanism 32 mainly comprises a supporting structure 33 surrounding at least partially the Cardan suspension device 13 and intended to receive for example using bumper bearings (receiving groove, stone against -pivot, pad and elastic retaining element), the pivots of the external ring 15. We therefore understand that the rotation mechanism 32 makes it possible to induce a yaw component to the oscillator 5 in the second embodiment compared to the first embodiment in order to make the oscillator 5 even less sensitive to the force of gravity. .

[0045] In the particular example of the second embodiment in which the supporting structure 33 and the bent shaft 21 are both rotated around the fourth axis A4, the support system 1 comprises a train epicyclic 34 intended to facilitate the integration (compactness, robustness) of mechanical actions and transmit a force to the supporting structure 33 and to the bent shaft 21 at the same time according to a ratio of predetermined speeds and directions. In Figure 6 for example, we can see a satellite carrier 34d integral with a fixed part of the watch movement 3 and supporting three toothed satellites 34b (only two visible). The satellites 34b are coupled between an exterior sun gear 34a connected to an energy source of the watch movement 3 and an interior sun gear 34c secured to the first end 31a of the bent shaft 21. In addition, to facilitate the relative movements between the planetary gears 34a, 34c and the planetary carrier 34d, a double ball bearing is preferably used. We therefore understand that the rotation speed of the bent shaft 21 will be greater than that of the supporting structure 33 and in the opposite direction.

The complex movement obtained is the result of the distinct rotation speeds between the bent shaft 21 and the supporting structure 33. For example, the bent shaft 21 can rotate counterclockwise in twenty seconds while the supporting structure 33 can rotate clockwise in sixty seconds. . In this way, the rotation of the supporting structure 33 could visualize the difference of one minute. In addition, the balance 7 could make three complete revolutions of the bent shaft 21 to again find an identical position. The duration of a complete cycle of the balance 7 thus forms a period of the complex movement. The choice of rotation in opposite directions between the bent shaft 21 and the supporting structure 33 is preferred, but is not obligatory.

The third embodiment is presented in Figures 8 to 10. It can be seen that, unlike the first and second embodiments, in the third embodiment, the fourth axis A4 is substantially horizontal and perpendicular to the third axis A3 transverse of the external ring 15. In the manner of the second embodiment, the support system 1 of the third embodiment further comprises a mechanism 35 for rotating the third transverse axis A3 around a sixth vertical axis A6 in order to make the oscillator 5 even less sensitive to the force of gravity. It is understood that the rotation mechanism 35 makes it possible to obtain an effect similar to a whirlwind mechanism applied to the Cardan suspension device 13.

[0048] For this purpose, the rotation mechanism 35 mainly comprises a supporting structure 36 surrounding the Cardan suspension device 13 and intended to receive for example using bumper bearings (receiving groove, counter-pivot stone, pad and elastic retaining element), the pivots of the external ring 15. We therefore understand that the rotation mechanism 35 makes it possible to induce a yaw component over three hundred and sixty degrees (complete revolution) to the oscillator 5 in the third embodiment compared to the first embodiment in order to make it even less sensitive oscillator 5 to the force of gravity.

[0049] Furthermore, the third embodiment can provide, in addition to or in substitution for the rotation mechanism 35, a mechanism 37 for pivoting the oscillator 5 around the fourth axis A4 in order to make the oscillator 5 even less sensitive. to the force of gravity. We therefore understand that the rotation mechanism 35 makes it possible to induce an additional pitch component over three hundred and sixty degrees (complete revolution) to the oscillator 5 in the third embodiment compared to the first embodiment in order to make it even less oscillator 5 sensitive to the force of gravity. Thus, in combination, the mechanisms 35 and 37 add a movement comparable to a double whirlwind along perpendicular axes.

[0050] In the particular example of the third embodiment in which the mechanisms 35 and 37, the same supporting structure 36 is used for the two mechanisms 35 and 37 in order to facilitate the integration (compactness, robustness) of the mechanical actions and transmit a force to the supporting structure 36 and to the bent shaft 21 at the same time according to a predetermined ratio of speeds and directions. In Figure 10 for example, we can see an annular cage 36a receiving the pivots of the external ring 15 and, perpendicularly, the first end 21a of the bent shaft 21. In order to allow the rotation of the annular cage 36a around the fourth axis A4, a shaft 36e is used. It is substantially opposite the first end 21a of the shaft 21 bent relative to the third axis A3.

[0051] The first end 21a of the shaft 21 and the shaft 36e extends into bumper bearings (receiving groove, counter-pivot stone, cushion and elastic retaining element) mounted in an annular support 36b whose peripheral toothing is connected to an energy source of the watch movement 3. Under the support and coaxially, a toothed crown 36d is present and connected to a fixed part of the watch movement 3. Finally, a reference 36c and a double reference (not visible ) are respectively secured to the shaft 36e and the first end 21a and both coupled to the toothed crown 36d.

We therefore understand, by the drive of the support 36b which drives the oscillator 5 over three hundred and sixty degrees around the sixth axis A6, that the speed of rotation of the bent shaft 21 will be greater than that of the support 36b by the relative movement of the double return against the toothed crown 36d according to a movement explained in the first embodiment and that the rotation speed of the shaft 36e will be greater than that support 36b by the relative movement of the return 36c against the toothed crown 36d in driving oscillator 5 around the fourth axis A4 over three hundred and sixty degrees. It is also immediate that the additional return of the bent shaft 21 relative to that 36c of the shaft 36e induces opposite directions of rotation between them and, if desired, different speeds of rotation.

[0053] The invention is not limited to the embodiments and variants presented and other embodiments and variants will be clearly apparent to those skilled in the art. Thus, the embodiments and variants can be combined with each other without departing from the scope of the invention.

[0054] Thus, the suspension device 13 cannot be limited to a Cardan suspension mechanism. It could instead be of the type with a flexible element such as a bellows or with elastic blades or of the type with a ball-and-finger connection to allow the same complex movements to be offered to the oscillator 5. In addition, the transmission device 19 oblique cannot be limited to a bent shaft 21. It could instead be of the conical return type to allow inclined transmission of force to the exhaust device 9.

Claims (14)

1. Watch movement (3) comprising an oscillator (5) comprising a resonator (6) capable of oscillating around a first axis (A1) of rotation to serve as a time base for the watch movement (3) and a device (9 ) exhaust selectively applying to the resonator (6) a force from the watch movement (3) in order to maintain and count the oscillations of the resonator (6), characterized in that the watch movement (3) further comprises a system (1) support of the oscillator (5) comprising a suspension device (13) arranged to authorize only two degrees of freedom in rotation along second (A2) and third (A3) concurrent axes, said second axis (A2) and third axis (A3) being different from the first axis (A1), in order to authorize the oscillator (5) to change orientation in a predefined volume, and a device (19) for oblique force transmission to the device (9) of exhaust allowing the orientation of the oscillator (5) to be changed in the predefined volume at each oscillation of the resonator (6) in order to make the oscillator (5) less sensitive to the force of gravity. 2. Watch movement (3) according to the preceding claim, in which the oblique transmission device (19) comprises a bent shaft (21) of which a first end (21a) is rotatably mounted relative to a fixed part of the watch movement (3). ) along a fourth axis (A4) and receives the force of the watch movement (3), and of which a second end (21 b) transmits, according to a predetermined inclination (a) of the shaft (21) bent relative to the fourth axis (A4), the force on the exhaust device (9) making it possible to change the orientation of the oscillator (5) in the predefined volume at each oscillation of the resonator (6). 3. Watch movement (3) according to claim 1 or 2, in which the suspension device (13) is of the Cardan type and comprises an internal cage (14) pivotally mounted along the second axis (A2) in a ring (15) external, itself pivotally mounted along the third axis (A3), perpendicular to the second axis (A2), relative to a fixed part of the watch movement (3), the oscillator (5) being mounted in the cage (14) internal. 4. Watch movement (3) according to claim 1 or 2, in which the suspension device (13) is of the Cardan type and comprises an internal cage (14) pivotally mounted along the second axis (A2) in a ring (15) external, itself pivotally mounted along the third axis (A3), not perpendicular to the second axis (A2), relative to a fixed part of the watch movement (3), the oscillator (5) being mounted in the cage (14 ) internal. 5. Watch movement (3) according to claim 3 or 4, in which the internal cage (14) comprises a lower part (16) receiving a cog (20) for transmitting force from the oblique transmission device (19) coupled between the bent shaft (21) and an exhaust wheel (11) of the exhaust device (9), an intermediate part (17) receiving the exhaust device (9) and an upper part (18) receiving the resonator ( 6). 6. Watch movement (3) according to the preceding claim, in which the transmission train (20) of the oblique transmission device (19) comprises a transmission shaft (22) pivotally mounted along a fifth axis (A5) in the part ( 16) lower of the internal cage (14), connected in a fixed manner relative to the second end (21b) of the bent shaft (21) and provided with a toothed wheel (23) inducing a relative movement relative to the lower part (16) of the internal cage (14) during rotation of the bent shaft (21) to transmit the force of the bent shaft (21) to a pinion (24) mounted in the lower part (16) and connected to the exhaust wheel (11). 7. Watch movement (3) according to any one of claims 2 to 6, in which the fourth axis (A4) of rotation of the first end (21a) of the bent shaft (21) is vertical and perpendicular to the third axis (A3) transverse of the external ring (15). 8. Watch movement (3) according to the preceding claim, in which the support system (1) further comprises a mechanism (32) for rotating the third transverse axis (A3) around the fourth vertical axis (A4) in order to further make the oscillator (5) is less sensitive to the force of gravity. 9. Watch movement (3) according to any one of claims 2 to 6, in which the fourth axis (A4) of rotation of the first end (21a) of the bent shaft (21) is horizontal and perpendicular to the third axis (A3) transverse of the external ring (15). 10. Watch movement (3) according to the preceding claim, in which the support system (1) further comprises a mechanism (37) for pivoting the oscillator (5) around the fourth horizontal axis (A4) in order to still make the oscillator (5) is less sensitive to the force of gravity. 11. Watch movement (3) according to claim 9 or 10, in which the support system (1) further comprises a mechanism (35) for rotating the third transverse axis (A3) around a sixth vertical axis (A6). perpendicular to the third transverse axis (A3) in order to make the oscillator (5) even less sensitive to the force of gravity. 12. Watch movement (3) according to any one of the preceding claims, wherein the escapement device (9) is of the Swiss anchor type. 13. Watch movement (3) according to any one of the preceding claims, wherein the resonator (6) is of the balance-spring type. 14. Timepiece (2) characterized in that it comprises a watch movement (3) according to one of the preceding claims.