CH719658A2 - Mechanical watch movement. - Google Patents

Abstract

The invention relates to a watch movement (10) comprising a barrel (14), a regulating member, an escapement (15) comprising an escape wheel and a transmission member for transmitting the oscillations of the regulating member to the wheel. exhaust so that the rotation of the escape wheel takes place according to the oscillations of the regulating organ. The watch movement further comprises a kinematic link (19) connecting the barrel (14) to the escape wheel. The kinematic link has less than three mobiles (10). The invention also relates to a timepiece comprising such a movement.

Description

Technical area

The present invention relates to a simplified mechanical watch movement comprising a limited number of gears.

State of the art

[0002] Conventional mechanical watch movements without complications have an architecture including in particular a finishing train connecting the barrel to the escape pinion of the movement. The finishing gear has a negative impact on the overall efficiency of the movement. Furthermore, the architecture of the basic movement of conventional movements is dictated in particular by the finishing gear.

[0003] An aim of the present invention is therefore to propose a simplified mechanical watch movement in order to increase the overall efficiency of the movement.

Another aim of the present invention is to propose a new architecture with possibilities for unique identification of the product.

Another aim of the present invention is to propose a mechanical watch movement comprising a low frequency regulating member.

Brief summary of the invention

[0006] These goals are achieved by a watch movement comprising a barrel, a regulating member, an escapement comprising an escape wheel and a transmission member for transmitting the oscillations of the regulating member to the escape wheel so that the rotation of the escape wheel takes place according to the oscillations of the regulating organ. The watch movement also includes a kinematic link connecting the barrel to the escape wheel. The watch movement is characterized in that the kinematic link has fewer than three mobiles.

[0007] According to one embodiment, the kinematic connection comprises no less and no more than two mobiles. One of the two mobiles is engaged with the barrel while the other of the two mobiles is engaged with the pinion of the escape wheel.

[0008] According to one embodiment, the kinematic connection comprises a single mobile in engagement with the barrel and the pinion of the escape wheel.

[0009] According to one embodiment, the escapement and the regulating member are configured so that the escapement wheel can perform one complete rotation per minute.

[0010] According to one embodiment, the escape wheel includes a seconds indicator.

[0011] According to one embodiment, the gear ratio between the single mobile and the pinion of the escape wheel as well as the speed of rotation of the escape wheel are chosen so that the single mobile can rotate 360° per hour.

[0012] According to one embodiment, the single mobile includes a minute indicator.

[0013] According to one embodiment, the gear ratios between the barrel and the escape wheel as well as the rotation speed of the escape wheel are chosen so that the barrel can rotate 360 ° in N x12h, N preferably being an integer greater than or equal to 1.

[0014] According to one embodiment, the barrel includes an hour indicator.

[0015] According to one embodiment, the regulating member comprises two oscillators.

Another aspect of the invention relates to a timepiece comprising the watch movement according to the invention.

Brief description of the figures

[0017] Examples of implementation of the invention are described in the description illustrated by the appended figures in which: – Figure 1 is a schematic top view of a simplified watch movement according to one embodiment of the invention; – Figure 2 illustrates a perspective view of an oscillator comprising two balance springs driven together by a desmodromic gear train according to one embodiment of the invention; – Figure 3 illustrates a top view of Figure 2; – Figure 4 illustrates a view similar to Figure 3 without the representation of the hairsprings; – Figure 5 illustrates a side view of Figure 2, – Figure 6 illustrates a perspective view of an oscillator according to another embodiment of the invention; – Figure 7 illustrates a top view of Figure 6; – Figure 8 illustrates a side view of Figure 6; – Figure 9 illustrates a perspective view of the regulating member comprising two sprung balances driven together by a desmodromic gear train according to another embodiment of the invention, – Figure 10 illustrates a side view of Figure 9, – Figure 11 is a schematic top view of a regulating member according to one embodiment, – Figure 12 is a schematic top view of a regulating member according to another embodiment, – Figure 13 is a view schematic top view of a regulating member according to another embodiment, - Figure 14 is a schematic top view of a regulating member according to another embodiment, - Figure 15 is a schematic top view of a regulating member according to another embodiment, – Figure 16 is a schematic top view of a regulating member according to another embodiment, – Figure 17 is a schematic top view of a regulating member according to another form embodiment, – Figure 18 is a schematic top view of a regulating member according to another embodiment, – Figure 19 is a schematic top view of a regulating member according to another embodiment, – Figure 20 is a schematic top view of a regulating member according to another embodiment, - Figure 21 is a schematic top view of a regulating member according to another embodiment, - Figure 22 is a schematic view of above of a regulating member according to another embodiment, – Figure 23 is a schematic top view of a regulating member according to another embodiment, – Figure 24 is a schematic top view of a regulating member according to another embodiment, - Figure 25a illustrates a top view of an exhaust of the regulating member of Figure 12, - Figure 25b illustrates a top view of an exhaust, according to another embodiment , of the regulating member of Figure 12, – Figure 25c illustrates a top view of an exhaust, according to another embodiment, of the regulating member of Figure 12, – Figure 25d illustrates a view at the top level of the point of contact between a pallet of one of the anchors of Figure 25c and a tooth of the escape wheel, – Figure 26 illustrates a top view of an escapement of the regulating member of Figure 17, – Figure 27 is a schematic top view of the oscillator according to another embodiment, – Figure 28 is a schematic top view of the oscillator illustrating an overlapping zone between two pendulums according to another embodiment, – Figure 29 is a schematic top view of the oscillator illustrating a zone of intersection between two pendulums according to another embodiment, and – Figure 30 is a schematic view of the oscillator illustrating two zones of intersection between three balancers according to another embodiment.

Examples of embodiments of the invention

[0018] In the present application, the term “oscillator” means a resonator comprising, on the one hand, several balances and, on the other hand, a cog arranged to engage with the balances so as to make these balances dependent between them. Furthermore, in the present application the term “regulating member” means an assembly comprising the oscillator and a counting member, in particular an escapement.

[0019] With reference to Figure 1, the watch movement 10 has a simplified construction thanks to a low-frequency regulating member with a double sprung balance 22a, 22b, which will be described later, configured to oscillate at a frequency lower than 1.5 Hz. According to the inertia of the balances retained, the power reserve can be considerably increased, particularly if achieving high chronometric performance is not a priority.

The simplified watch movement comprises a plate 12 on which a barrel 14 is mounted, an escapement 15 comprising an escape wheel and a kinematic link 19 connecting the barrel 14 to the pinion of the escape wheel. The kinematic link 19 has fewer than three mobiles.

[0021] According to an advantageous embodiment, this kinematic connection only comprises a mobile 19 engaged on the one hand with the ratchet of the barrel 14 and, on the other hand, with the pinion of the escape wheel. The mobile 19 therefore replaces the center wheel, the middle wheel and the second wheel of a traditional movement.

[0022] According to a variant of execution not illustrated, the kinematic connection comprises no less and no more than two mobiles meshing together. One of the two mobiles is engaged with the barrel ratchet while the other of the two mobiles is engaged with the pinion of the escape wheel.

[0023] The simplified watch movement has the advantage of providing a new architecture with possibilities for identifying the unique product due to the fact that the geometric constraints, for example the center distances, are very different from traditional movements. Furthermore, the simplification of the movement makes it possible to increase the overall efficiency by reducing the number of gears.

[0024] Under certain conditions linked to gear ratios and the escapement, it is possible to display the second directly on the escapement wheel. In this case, the gear ratios between the barrel 14, the mobile 19 and the pinion of the escape wheel 16 are chosen so that the latter can perform one complete rotation per minute. A seconds indicator member 50 can be mounted on the axis of the escape wheel.

Likewise, under certain conditions linked to gear ratios, the mobile 19 can directly display the minutes. The gear ratio between the barrel and the mobile 19 is therefore chosen so that the latter can perform one complete rotation per hour. A minute indicator member 52 can for example be mounted on the axis of the mobile 19.

Finally, under certain conditions linked to gear ratios, barrel 14 can display the time. For example, an hour indicator member 54 can be mounted on the shaft of the barrel 14.

As mentioned previously, the production of a simplified watch movement is only possible by the use of a low frequency regulating member. In order to maintain an acceptable quality factor, the inertia of the balance must be increased compared to a mechanical movement equipped with a higher frequency oscillator. This increase in inertia has the main disadvantage of increasing sensitivity to angular accelerations. In order to counter this sensitivity to accelerations, the oscillator of the regulating member comprises at least two balances coupled in phase opposition according to different embodiments, that is to say that a hairspring is associated with each of the two balancers so that one of the hairsprings is in a contraction phase while the other of the hairsprings is in an expansion phase. According to a variant, the phase opposition can be achieved by mounting on one of the balances of the oscillator two hairsprings wound in the opposite direction so that one of the two hairsprings is in a contraction phase when the other of the two spirals is in a phase of expansion.

[0028] According to an advantageous embodiment, illustrated by Figures 2 to 5, the oscillator 22 comprises a first and a second sprung balance 22a, 22b arranged in the same plane. Each balance spring 22a, 22b comprises a flywheel 24a, 24b, a balance spring 32a, 32b and a balance shaft 34a, 34b. The flywheel includes serge segments 28a, 28b and balance arms 26a, 26b connecting the serge segments to the balance shaft. One end of each hairspring 32a, 32b is connected to the respective balance axis by means for example of a ferrule 36a, 36b (figure 5) driven onto the axis while the other end is connected for example to a pin mounted on a pin support itself secured to a bridge or fixed cock (not illustrated) in relation to the plate 12 of the watch movement 10.

The oscillator may include an elastic member other than a conventional flat spiral spring, for example a cylindrical balance spring, a hemispherical or spherical balance spring or even a conical balance spring. The hairspring can also have several turns according to a variant. The oscillator can also include an elastic member not resembling a hairspring to fulfill the function of returning the balance.

The first and second sprung balances 22a, 22b of the oscillator 22 are connected by a gear train 40 in order to drive these sprung balances by a desmodromic connection so that the flywheel 24a of the one of the two sprung balances 22a, 22b can oscillate in opposition to phase relative to the flywheel 24b of the other of the two sprung balances. In other words, the balance spring 32a of one of the two balance springs 22a, 22b is in an expansion phase while the balance spring 32b of the other of the two balance springs 22a, 22b is in a phase of expansion. contraction, which has the effect of driving the respective flywheels 24a, 24b in an opposite direction. This particular arrangement of the two hairsprings 32a, 32b makes it possible to cancel or, at least, reduce the sensitivity of the oscillator 22 to angular accelerations.

[0031] As can be seen in particular in Figures 4 and 5, the gear train 40, ensuring the desmodromic connection between the two sprung balances 22a, 22b, comprises a first mobile 42 secured to the balance axis 34a of the balance of one of the two sprung balances 22a, 22b, a second mobile 44 secured to the balance axis 34b of the balance of the other of the two sprung balances 22a, 22b and two intermediate mobiles 46, 48 in taken with respectively the first and second mobiles 42, 44. The ratios and the number of gears have been determined so that the first and second flywheels 24a, 24b of the respective sprung balances 22a, 22b can oscillate in phase opposition .

With particular reference to Figure 2, the flywheel 24a, 24b of each sprung balance 22a, 22b comprises four arms 26a, 26b separated by an angle of 90° relative to each other. Each arm 26a, 26b extends from the respective balance axis 34a, 34b, in a radial direction, to a distal part 28a, 28b. Furthermore, the thickness of each arm 26a, 26b increases from the balance axis to the corresponding distal part.

[0033] The distal parts of the first and second flywheels 24a, 24b each form four disjoint serge segments 28a, 28b along respectively a first and a second circle 25a, 25b as shown in Figure 4. Each of the four disjoint serge segments 28a, 28b of each balance 24a, 24b extends along an arc of a circle comprised for example between 20° and 50° and preferably along an arc of a circle comprised between 30 ° and 40°.

[0034] According to other execution variants, the flywheel of each sprung balance may have only two or three arms. In this case, the serge segment associated with each arm will be larger so that the inertia of each balance remains constant. For example, each discontinuous serge segment of the flywheel can extend along an arc of a circle greater than 45° in the case where each balance wheel has three arms, or even greater than 60° in the case where each balance wheel has only two arms.

[0035] A flyweight 30a, 30b in the form of screws is screwed into each serge segment 28a, 28b, for example in a radial direction, in order to be able to modify the inertia of the flywheel 24a, 24b of each balance wheel. hairspring to adjust their oscillation frequency.

[0036] The center distance between the two balance axes 34a, 34b respectively of the first and second sprung balances 22a, 22b is reduced so as to limit the differences in the influence of the acceleration between the first and second flywheels. 24a, 24b. According to this configuration, the first and second circles 25a, 25b, along which the disjoint serge segments 28a, 28b are arranged respectively of the first and second balance 24a, 24b, intersect. This configuration also has the advantage of reducing the bulk of the balances (surface). According to one embodiment, the dimensions of the two flywheels are substantially identical. These two flywheels define two discs with an overlapping zone 29a resembling a symmetrical lens as illustrated in Figure 28. According to another embodiment illustrated in Figure 29, the diameter D1 of one of the flywheels flywheels 24a, 24b is less than the diameter D2 of the other flywheel. The first diameter D1 represents for example less than 80% of the second diameter D2. In this case, the overlapping zone 29b resembles an asymmetrical lens.

[0037] When the regulating member 20 is in operation, the oscillations of the flywheels 24a, 24b of the sprung balances 22a, 22b are synchronized in phase opposition so that the serge segments 28a of the flywheel inertia 24a of one of the two sprung balances 22a, 22b never comes into contact with the serge segments 28b of the flywheel 24b of the other of the two sprung balances 22a, 22b.

[0038] According to another embodiment illustrated in Figures 6 to 8, the oscillator 22 comprises a first and a second sprung balance 22a, 22b mounted coaxially. The first and second sprung balances 22a, 22b are interconnected by a gear train 40 so that the flywheel 24a of one of the two sprung balances 22a, 22b can oscillate in phase opposition to the flywheel. of inertia 24b of the other of the two sprung balances to cancel or, at least, reduce the sensitivity of the oscillator 22 to angular accelerations. According to another embodiment not shown, the first and second sprung balance are arranged so that their respective flywheel oscillates in two parallel planes with their respective axis parallel to each other.

[0039] According to Figure 8, the gear train 40 comprises a first mobile 42 secured to the balance axis 34a of the first sprung balance 22a, a second mobile 44 secured to the balance axis 34b of the second balance-spring hairspring 22b as well as an intermediate gear train. The intermediate cog comprises a third mobile 45 engaged with the first mobile 42, a fourth mobile 46 engaged with the second mobile 44, a fifth mobile 47 engaged with the fourth mobile 45 as well as a lower mobile 48 and an upper mobile 49 mounted coaxially so that the lower and upper mobiles 48, 49 engage respectively with the fifth mobile 47 and the third mobile 45.

[0040] Just like the first embodiment, the flywheel 24a, 24b of each sprung balance 22a, 22b comprises four arms 26a, 26b separated by an angle of 90° relative to each other and comprising the same characteristics of the arms of the two sprung balances of the regulating organ illustrated in particular in Figure 2. The number of arms can be different from four. Each flywheel 24a, 24b can for example comprise only two or three arms as mentioned above.

[0041] According to another embodiment illustrated by Figures 9 and 10, the oscillator 22 comprises a first and a second sprung balance 22a, 22b mounted so that their respective balance axes are concurrent. For example, the first and second axes form an angle between them substantially equal to 45° according to Figure 10 although this angle can vary significantly depending on execution variants, for example between 30° and 60°. According to a variant embodiment, illustrated in Figure 30, the oscillator comprises three balance wheels each comprising a flywheel 24a, 24b, 24c, each defining a disk. The balance wheels are arranged so that a first and a second disk a third disk according to a first and a second intersection zone 29a which are rectilinear.

[0042] The advantage of this embodiment lies in particular on the simplified gear train so that the flywheels 24a, 24b respectively of the first and second sprung balances 22a, 22b can oscillate in opposition to phase since this train gear comprises only two mobiles 42, 44 with appropriate teeth, conical for example, in direct engagement.

[0043] Just like the first and second embodiments, the flywheel 24a, 24b of each sprung balance comprises four arms 26a, 26b separated by an angle of 90° from each other and having the same characteristics of the arms of the two sprung balances of the regulating member illustrated in particular in Figure 2. Each balance 24a, 24b can comprise only two or three arms according to a variant of execution as already specified previously.

[0044] Just as for the first embodiment, when the oscillator 22 is in operation, the oscillations of the flywheel 24a of one of the two sprung balances 22a, 22b are synchronized in phase opposition with respect to the oscillations of the flywheel 24b of the other of the two sprung balances 22a, 22b so that the serge segments 28a, 28b of the respective flywheels 24a, 24b never come into contact.

The regulating member 20 according to the invention can be implemented according to different configurations of the oscillator and the exhaust according to schematic figures 11 to 24 in order to transmit the oscillation frequency of the regulating member 20 to the kinematic connection 19 connecting the barrel 14 to the pinion of the escape wheel 16, preferably via a single mobile 19 according to the schematic representation of Figure 1. The escapement may include one or more anchors, for example Swiss anchor type. Alternatively, the escapement may comprise any other device acting between the oscillator and an escape wheel, for example a detent or coaxial escapement. The term “anchor” is therefore to be taken in the present application in the broad sense, designating any organ intended to cooperate between the regulating organ and the exhaust mobile(s).

[0046] According to the embodiment of Figure 11, the regulating member 20 comprises an oscillator 22 comprising two sprung balances 22a, 22b, for example the oscillator 22 illustrated in Figure 2. The first and second flywheels inertia 24a, 24b are arranged to oscillate in phase opposition. The escapement includes a single escapement anchor 17, for example a Swiss anchor.

The anchor 17 comprises an entry vane 170 and an exit vane 172 arranged to cooperate with the escape wheel 16 in a conventional manner in order to transmit the oscillations of the flywheel 24a of a single balance wheel. spiral 22a from the regulating member 20 to the escape wheel 16 so that the rotation of the escape wheel 16 takes place according to the oscillations of the flywheel 24a. For this purpose, the anchor 17 comprises a fork 179 arranged to cooperate with a plate pin of the balance axis.

The flywheel 24a of one of the sprung balances is connected to the flywheel 24b of the other of the sprung balances by a gear train with an even number of references 42, 44, 46 , 48 so as to reverse the direction of rotation of the balances.

[0049] Each sprung balance 22a, 22b comprises a sprung 32a, 32b wound in the same direction so that during the movement, the sprung of one of the sprung balances is in a phase contraction while the spring of the other balance spring is in an expansion phase, that is to say in phase opposition.

[0050] According to Figure 12 and with reference to the different embodiments illustrated by Figures 25a-25d, the regulating member 20 has an architecture comparable to that of Figure 11, with the difference that the first and second sprung balances 22a, 22b cooperate respectively with a first and a second anchor 17a, 17b, which cooperate with the same escape wheel 16.

[0051] In particular, with particular reference to Figure 25a, the first anchor 17a comprises an entry pallet 170a, and an outlet pallet 172a arranged to cooperate with the teeth of the escape wheel 16 while the second anchor exhaust 17b comprises an inlet vane 170b and an outlet vane 172b arranged to cooperate with the teeth of the escape wheel 16 alternating with the first escape anchor 17a. The first and second escape anchor 17a, 17b are arranged so that the entry and exit pallets of each anchor can cooperate with different teeth.

[0052] According to this arrangement, the exit pallet 172a of the first anchor 17a is arranged opposite the entry pallet 170b of the second anchor 17b while the entry pallet 170a of the first anchor and the exit pallet 172b of the second anchor 17b are spaced apart from each other in order to cooperate with teeth of the escape wheel 16 which are separated by an angle less than 180° passing through the center of the wheel 16. escape wheel 16 has for this purpose at least 20 teeth while a fork 179a, 179b of each anchor is arranged to cooperate with the plate pin 35a of the plate 35 of the axis of the corresponding sprung balance 22a, 22b. The escape wheel with less than 20 teeth, for example 15 teeth, can also be used under certain conditions.

[0053] Due to the opposite directions of rotation of the flywheels 24a, 24b (Figure 12) as described above, the anchors 17a, 17b work symmetrically. Figure 25a shows a tooth of the escape wheel 16 on the rest plane 176 of the entry pallet 170a of the first anchor 17a and another tooth of the escape wheel 16 on the rest plane 176 of the output pallet 172b of the second anchor 17b. The angle α defined by the points of contact between the respective rest planes 176 of the entry pallet 170a and the exit pallet 172b respectively of the first and second anchor 17a, 17b with respectively a first and a second tooth of the escape wheel 16 and through the center of the escape wheel 16 is less than 180° and is preferably located between 130° and 160°. The operating principle of the escapement 15 in Figure 25a requires that the adjustments be made so that the operating phases of the anchors are carried out simultaneously.

[0054] According to the embodiment illustrated in Figure 25b, the impulse plane of the output vane 172a of the first anchor 17a and the impulse plane of the outlet vane 172b of the second anchor 17b are removed from so that the distal part of the outlet pallets 172a, 172b of the first and second anchor 17a, 17b forms an angle of approximately 90° with the resting plane 176 of the pallet.

[0055] This specific shape of the distal part of the aforementioned pallets has the advantage of avoiding the constraint imposed by the operating phases of the first and second anchors which must be carried out simultaneously according to the embodiment illustrated in the figure 25a. This makes it possible to simplify the adjustment of the exhaust 15. The pallets are however sized so that the pulling function is fulfilled.

[0056] The dimensions of the pallets are such that the teeth of the escape wheel rest well on the resting planes of the truncated pallets so as to ensure locking of the anchor in a conventional manner and that the release phase on this pallet is not longer than on the non-truncated pallet of the other anchor in order to avoid a loss of energy during the impulse. This embodiment has the advantage of facilitating the self-starting of the exhaust 15.

[0057] According to the embodiment illustrated in Figure 25c, the exhaust uses the operating principle described in EP2923242A1, the content of which is incorporated by reference in the present application, so as to avoid hyperstatism of the exhaust 15 according to Figure 25a and the residual adjustment sensitivity of the exhaust according to Figure 25b. In this case, to obtain proper functioning of the exhaust, the tooth resting on the inlet or outlet pallets must be positioned very precisely in relation to the end of the resting plane of the pallets so that the exhaust release and impulse phases take place correctly.

[0058] Given the manufacturing tolerances, a conventional anchor escapement generally requires a final adjustment of the positions of the inlet and outlet vanes. This adjustment is generally long and delicate because it can strongly influence the performance of the exhaust.

[0059] The escapement 15 according to Figure 25c is similar to the escapement of Figure 25a due to the arrangement of a first and a second anchor 17a, 17b arranged to cooperate with an escape wheel 16. The escape wheel nevertheless differs in the profile of its teeth.

[0060] In this case, each tooth of the escape wheel 16 comprises a driving plane 182 (FIG. 25d) oriented so that the contact between the input pallet 170a, 170b and the outlet pallet 172a, 172b of each anchor 17a, 17b and the escape wheel via the driving plane 182 creates a torque which tends to reduce the angle between the anchor and the reference axis V1, V2 connecting the axes of the anchor and the balance for each of the first and second anchors 17a, 17b. In other words, the present implementation provides a driving plan which means that the anchor will naturally arrive in an equilibrium position, because the driving plan is arranged to create a torque creating a movement towards the position of balance.

[0061] According to a variant of execution not shown, the driving plan can be located on one of the pallets of the first and second anchor while the escape wheel has conventional teeth.

The regulating member 20 according to the embodiment of Figure 13 has an architecture comparable to that of Figure 12, with the difference that one of the balances does not include a hairspring. This balance includes a flywheel 24 secured to the first mobile 42. This engages with a gear train comprising two intermediate mobiles 46, 48 and the second mobile 44 secured to the sprung balance 22b. The flywheel 24a is thus driven by a desmodromic connection to oscillate according to the oscillations of the sprung balance 22b but in the opposite direction. The sprung balance 22b may include only one spiral or, according to a variant not shown but similar to Figure 14, a pair of spirals wound in opposite directions to obtain phase opposition.

[0063] According to the embodiment of Figure 14, only one of the balances of the oscillator 22 is arranged to cooperate with the escape wheel 16. This balance does not have a hairspring and its flywheel 24a is integral with the first mobile 42. Like the adjustment member of Figure 13, the first mobile 42 is engaged with a gear train comprising two intermediate mobile wheels 46, 48 and the second mobile 44 secured to the sprung balance 22b. The flywheel 24a is thus driven by a desmodromic connection to oscillate according to the oscillations of the sprung balance 22b but in the opposite direction. The sprung balance 22b comprises, for its part, a single hairspring or preferably two hairsprings 32a, 32b mounted coaxially and wound in opposite directions to obtain phase opposition.

[0064] According to the embodiment of Figure 15, the oscillator 22 of the regulating member 20 comprises three balances, namely two balance springs 22a, 22b as well as a balance without a balance spring. This comprises a flywheel 24c secured to a mobile 43 of the gear train and is arranged to cooperate with the escape wheel 16 via an anchor 17. The two sprung balances 22a, 22b are arranged at the end of the CC kinematic chain of the desmodromic connection of the oscillator 22 on either side of the balance without a hairspring. In the example illustrated, the flywheels 24a, 24b rotate in the same direction thanks to the odd number of mobiles 43, 46, 47, 48, 49 of the gear train connecting the two sprung balances 24a, 24b. The hairspring 32a of the hairspring balance 22a is therefore wound in the opposite direction relative to the hairspring 32b of the hairspring balance 22b to obtain phase opposition. Generally speaking, the respective oscillations of two rockers following each other in the CC kinematic chain of a regulating member comprising at least three rockers are in phase opposition.

[0065] According to the embodiment of Figure 16, the oscillator 22 also comprises three balances of the regulating member 20, namely a central sprung balance 22c arranged to cooperate with the escape wheel 16 and two balances without balance spring and which are arranged on either side of the central balance spring. This comprises two spirals 32a, 34 mounted coaxially and wound in opposite directions to obtain phase opposition. According to a variant not illustrated, the central sprung balance may have only one spiral. The oscillations of the flywheels 24a, 24b located on either side of the central sprung balance 22c occur according to the oscillations of the latter by the gear train.

[0066] According to the embodiment of Figure 17 and with reference to Figure 26, the first and second balance springs 22a, 22a of the regulating member 20 cooperate respectively with a first and a second escapement half-anchor 18a, 18b which cooperate with the same escape wheel 16. In this case, the first half-anchor 18a comprises an entry pallet 180a while the second half-anchor 18b comprises an outlet pallet 180b. The operation of the escapement 15 is thus decoupled by producing two half-anchors each working with the plate pin of a balance shaft. In this case, the pulses are distributed between the first and second hairspring balances 22a, 22b of the oscillator 22. The hairsprings 32a, 32b of the respective hairspring balances 22a, 22a are wound in the same direction in order to obtain opposition phase. According to a variant not shown, one of the balances does not have a hairspring while the other balance has a pair of hairsprings mounted in opposite phase.

[0067] According to the embodiments of Figures 18 and 19, the regulating member 20 has an architecture comparable to that of Figure 17 with the difference that the first and second sprung balances 22a, 22b cooperate respectively with a first and a second escape wheel 16a, 16b via a first and a second anchor 17a, 17b according to the regulating member 20 of Figure 18 or via a first and a second half-anchor 18a, 18b according to the organ of Figure 19. The balance springs 32a, 32b of the respective balance springs 22a, 22a are also wound in the same direction in order to obtain phase opposition. According to a variant not shown, one of the balances does not have a hairspring while the other balance has a pair of hairsprings mounted in opposite phase.

[0068] According to the embodiment of Figure 20, the oscillator 22 of the regulating member 20 comprises a balance spring 22a and a balance wheel without a balance spring. The regulating member comprises an escapement comprising, on the one hand, a first and a second escapement wheel 16a, 16b arranged to be driven in an opposite direction between them, and on the other hand, an anchor 17 arranged to cooperate with one of the balance wheels, for example the one without a hairspring, and with the two escape wheels. The sprung balance 22a preferably comprises two balance springs mounted in opposition to phase. In a variant not shown, each balance wheel has a hairspring.

[0069] Two other embodiments of the regulating member are illustrated in Figures 21 and 22. The first and second balance wheels of the oscillator 22 are mounted in phase opposition and do not have a hairspring. These balances therefore only include a flywheel 24a, 24b. The hairspring 32 is mounted on a mobile 48 of the gear train of the oscillator 22. Centering the hairspring in the gear train has the advantage of reducing the return effects compared to a hairspring at one of the ends of the gear train. the oscillator chain. The flywheels 24a, 24b are then preferably free of spirals. According to this embodiment, the inertia of the mobile 48 is at least five times, preferably at least ten times, or even at least twenty times lower than the inertia of any of the balances.

[0070] With reference to Figure 22, the gear train is arranged to impart a back and forth movement to the mobile 48, which cooperates with the anchor 17 by means, for example, of a pin (not shown). in solidarity with mobile 48.

[0071] The mobile 48 can be larger or smaller than the mobiles 42, 44 secured respectively to the first and second balances 24a, 24b, so as to increase the sizing range of the balance-spring couplings and the amplitudes (the amplitude of the hairspring can be adapted to the ideal operation of the escapement while the amplitude of the balances can be adapted to their inertia). According to the regulating member of Figure 22, the pitch diameter of the mobile 48 is greater than the pitch diameter of the respective mobiles 42, 44 of the first and second balances 24a, 24b.

[0072] Another example of a regulating member is schematically illustrated in Figure 23. This regulating member is similar to the regulating member of Figure 22 with the difference that the balance spring 32 is mounted on a mobile 48 of the gear train whose pitch diameter is less than the pitch diameter of the respective mobiles 42, 44 of the first and second balances 24a, 24b.

[0073] According to another embodiment schematically illustrated in Figure 24, the regulating member comprises two sprung balances 22a, 22b mounted in opposition to phase while the mobile 48 of the gear train is arranged to cooperate with the anchor 17 by means for example of a pin (not shown) secured to the mobile 48. This is moved back and forth when the regulating member moves in order to regulate the rotation of the wheel. escapement 16 and to maintain the oscillations of the first and second balance springs.

[0074] According to the embodiments illustrated in Figures 12, 13 and 21, the escape wheel 16 can be replaced by two coaxial escape wheels which can be integral or movable between them, in particular for taking up play and /or to optimize contact with the pallets.

[0075] According to another embodiment schematically illustrated in Figure 27, the oscillator of the regulating member comprises four flywheels 24a, 24b, 24c, 24d. Each flywheel 24a, 24b, 24c, 24d is similar to the flywheels of the regulating member according to the embodiment illustrated in particular in Figures 2 to 4. The distal parts of each flywheel together form several disjoint serge segments, for example three or four segments, along respectively a first, a second, a third and a fourth circle. The center distance between the four balance axes is reduced so that each circle intersects another circle among the four circles. The four flywheels 24a, 24b 24c, 24d are connected together by a gear train (not shown) adapted so that two flywheels 24a, 24c oscillate in the same phase and in phase opposition to each other. to the two other oscillators 24b, 24d. The four flywheels 24a, 24b, 24c, 24d are preferably arranged to oscillate in the same plane.

[0076] The regulating member according to the invention makes it possible to intervene between the balance, the spring and the escape wheel, which are directly linked together in a conventional regulating member, several mobiles of a gear train. The dimensioning of each mobile determines their respective couplings. This dimensioning allows the implementation of new adjustment methods between: – the return torque of at least one spiral spring and the inertia of the balance wheels while maintaining unchanged the power necessary for maintaining the oscillations of the oscillator, – the power necessary for maintaining the oscillator and the power delivered by the at least one exhaust mobile.

[0077] These adjustment methods may in particular have the advantage of making it possible to overcome: – variations in the production of components in series (distribution of couples of hairsprings or balance inertias in production batches), – variations of torque provided by the driving member of a movement equipped with such a regulating member, – variations generated by the consumption of additional functions of mechanisms in a movement equipped with such a regulating member (the same basic movement being able to power several calibers whose additional functions vary, but for which the same regulating organ would be used, its power being adapted according to the consumption of these additional functions).

[0078] The adjustment according to these methods can be complementary to various other conventional adjustments, in particular an adjustment by screw or by eccentrics mounted on balances or an adjustment by the racket.

[0079] It is possible, by modifying the geometric properties (pitch diameter and/or inertia) of mobiles of the gear train, in particular of at least one of the mobiles 42, 43, 44, 45, 46, 47, 48, 49 of the gear train 40, to modify the pairing between the return torque of the at least one spiral spring and the inertia of the balance wheels while maintaining unchanged the power necessary for maintaining the oscillations of the oscillator.

[0080] The method therefore comprises the following steps: – determine the inertia of all the balances of the oscillator, – determine the restoring torque of the elastic member of the oscillator, – compare these values to the theoretical values giving the targeted performance and determining the modification to be made to achieve this, whether it is a mobile with greater/lower inertia or a mobile with a larger/smaller nominal diameter, – replace the initial mobile(s) with mobiles determined in the previous step – optionally, measure the chronometric performance of the regulating organ, and – optionally start again if the pairing still needs to be improved/refined.

[0081] Although the inertia of the wheels of the gear train is very much lower than that of the balance wheels (the wheels do not have sufficient inertia to allow them to maintain oscillations, that is to say they do not can be assimilated to balance wheels), a variation of this can however modulate in small proportions the relationship between the inertia of the balance spring and the return torque of the balance spring and modify the period of the oscillations, and therefore the progress of the balance. watch movement equipped with such a regulating organ.

[0082] The modification of the inertia of a mobile of the gear train can be carried out in different ways, in particular by 1) a change of material to target different densities and therefore different inertias at equal dimensions, by 2 ) a change in thickness, therefore different inertias at equal pitch diameter (or contour profile), or by 3) a change in effective mass at equal external dimensions, using perforated mobiles.

[0083] By modifying the pitch diameter of one of the mobiles, in particular a mobile carrying a hairspring, the relationship between the inertia and the return torque of the hairspring is modified. Changing the pitch diameter in gearing generally assumes, for the same module, a change in the number of teeth. However, there are other means of fine modulation such as offsets, which consist of modifying the original diameter for an equal number of teeth and thus the relationship between mobiles meshing together.

[0084] The energy available to the escape wheel may vary upstream (in particular due to the moment developed by the barrel spring which may vary in production, but also in more specific cases such as additional openings on mobiles - skeletons, or in the case of driving additional modules with different consumptions), it is also possible to modify these pairings to adapt the characteristics of the regulating member to the quantity of energy available to the escape wheel.

[0085] This involves the following steps: – determining the torque supplied by the driving source to one or more escapement wheels, – determining the effective inertia of the balances fitted to the regulating member, – determining the return torque of the elastic member equipping the regulating member, – compare these values to the theoretical values giving the targeted performances and determine the modification to be made to achieve this, a modification of the inertia of a mobile being able to be accompanied by a modification of the nominal diameter of the same mobile or another mobile of the gear train, this in order to maintain the balance-spring balance, – replace the initial mobile(s) with mobiles determined in the previous step – optionally measure the chronometric performance of the regulating body, and – optionally start again if the pairing still needs to be improved/refined.

[0086] In order to optimize the adjustment process described above, it may be useful to carry out statistical determinations (if it is only a matter of adjusting to series distributions) or determinations of needs (if it is This is to compensate for variations in consumption of additional functions) in order to distribute the pairing mobiles by classes, and to size these classes (gaps) according to the aforementioned needs.

[0087] Finally, if it is a question of involving mobiles of different original diameters, it is obvious that the positioning of the mobiles in their support (exhaust holder, cock plate or other), the guiding means (bearing , ball bearings, etc.) must be configured so that their relative spacing can be adapted to the variations in center distance resulting from the pairing. These means for adjusting the center distances are well known from the state of the art, as disclosed for example in CH131854.

[0088] The guide means can in particular be mounted on intermediate supports allowing this adjustment, but other means are also possible beyond the scope of the invention.

Reference list

[0089] Watch movement 10 Plate 12 Barrel 14 Escapement 15 Escape wheel 16, 16a, 16b Transmission member Escape anchor 17; 17a, 17b Inlet and outlet pallets 170, 172; 170a, 172a; 170b, 172b Impulse plane 174 Rest plane 176 Distal portion 178 Driving plane 182 Fork 179 First escape half-anchor 18a Inlet pallet 180a Second escape half-anchor 18b Exit pallet 180b Kinematic connection 19 between the barrel and the escape wheel Less than three mobiles Single mobile Regulating body 20 Oscillator 22 Spiral balance 22a, 22b Flywheel 24a, 24b, 24c, 24d First and second circles 25a, 25b Balance arms 26a, 26b Segments of serge 28a, 28b Intersection zone 29a, 29b Weights 30a, 30b Spiral 32, 32a, 32b Balance shaft 34a, 34b Single plate 35 Plate pin 35a Ferrule 36a, 36b Gear train 40 connecting the first and second oscillators First mobile 42 (integral to one of the balance axes) Second mobile 44 (integral to the other of the balance axes) Intermediate mobiles 45, 46, 47, 48, 49 CC kinematic chain Seconds indicator 50 Minutes indicator 52 Hour indicator 54

Claims (11)

1. Watch movement (10) comprising a barrel (14), a regulating member (20), an escapement (15) comprising an escape wheel (16) and a transmission member (17; 17a, 17b; 18a, 18b ) to transmit the oscillations of the regulating member (20) to the escape wheel (16) so that the rotation of the escape wheel (16) takes place according to the oscillations of the regulating member (20) thus that a kinematic connection (19) connecting the barrel (14) to the escape wheel (16), characterized in that said kinematic connection comprises less than three mobiles. 2. Watch movement (10) according to claim 1, characterized in that said kinematic connection comprises no less and no more than two mobiles, one of the two mobiles being in engagement with the barrel (14), the other of the two mobiles being engaged with the pinion of the escape wheel (16a). 3. Watch movement (10) according to claim 1, characterized in that said kinematic connection comprises a single mobile (19) engaged with the barrel (14) and the pinion of the escape wheel (16a). 4. Watch movement (10) according to one of the preceding claims, characterized in that the escapement (15) and the regulating member (20) are configured so that said escapement wheel (16) can perform one complete rotation per minute. 5. Watch movement (10) according to the preceding claim, characterized in that said escape wheel includes a seconds indicator. 6. Watch movement (10) according to claim 3 or 4 characterized in that the gear ratio between said single mobile (19) and the pinion of the escape wheel (16a) as well as the rotation speed of the wheel exhaust (16) are chosen so that the single mobile (19) can rotate 360° per hour. 7. Watch movement (10) according to the preceding claim, characterized in that the single mobile comprises a minute indicator. 8. Watch movement (10) according to one of the preceding claims, characterized in that the gear ratios between the barrel (14) and the escape wheel (16a) as well as the rotation speed of the escape wheel escapement (16) are chosen so that said barrel can rotate 360° in N x12h, N preferably being an integer greater than or equal to 1. 9. Watch movement (10) according to the preceding claim, characterized in that the barrel (14) includes an hour indicator. 10. Watch movement according to one of the preceding claims, characterized in that the regulating member (20) comprises two oscillators (22a, 22b). 11. Timepiece comprising the movement according to one of the preceding claims.