CH710278B1 - Regulating organ for a mechanical watch movement. - Google Patents

Abstract

The invention relates to a regulating member (1) for a mechanical watch movement comprising an escape wheel (5), a vibrating oscillator (3) provided with at least two arms (31', 32'), and an anchor part (4) and two members (40) arranged so as to cooperate alternately with the teeth of said escape wheel (5), so as to maintain periodic oscillations of the vibrating oscillator (3) and to advance the escape wheel (5) at each alternation of oscillations, and in which the arms (31', 32') and the anchor part (4) are formed in a single piece. The invention also relates to a method for adjusting the oscillation frequency of such a regulating member and to a watch movement comprising such a regulating member.

Description

Technical area

[0001] The present invention relates to a regulating member for a mechanical watch movement comprising a vibrating oscillator including a tuning fork type vibrating blade and an anchor intended to cooperate with an escape wheel. The present invention also relates to a watch movement comprising such a regulating member. This regulating member is intended to replace a conventional regulating member comprising a sprung balance.

State of the art

[0002] In a watch movement, the function of the escapement is to transmit the energy received by the gear train, itself driven by the mainspring, to the regulating member constituted by the balance-spring assembly. This escapement generally includes an independent anchor oscillating around an axis pivoted in the plate. The mechanical connection between the anchor and the regulating member, constituted by the plate carrying the pin which abuts against each of the horns of the anchor, is relatively complicated. In addition, the balance-spring assembly requires delicate adjustment.

[0003] Document CH 1685665 describes an escapement device comprising an anchor secured to a vibrating member where the anchor is arranged in such a way that it oscillates perpendicular to the plane of the escape wheel. The anchor is fixed by embedding or welding, at the end of a vibrating blade embedded by its end in a rigid support. A tuning fork or resonator derived from the tuning fork can be used instead of the vibrating blade, with one of the branches carrying the anchor and the other branch oscillating freely and synchronizing the first branch.

[0004] Document CH442153 describes an escapement comprising a tuning fork, playing the role of a primary oscillator, and a vibrating blade, playing the role of a secondary oscillator, at the end of which is fixed an anchor provided with two lifts diametrically opposed to the center of the escape wheel. Under the effect of the impact of a tooth of the escape wheel against one of the lifts, the oscillating blade oscillates, the amplitude of its oscillation allowing the anchor to lightly strike the end of one of the branches of the tuning fork which in turn oscillates at its own frequency.

Brief summary of the invention

[0005] The present invention relates to a regulating member for a mechanical watch movement comprising an escape wheel, said regulating member comprising a vibrating oscillator provided with at least two arms, an anchor part and two members arranged so as to cooperate in a manner alternated with the teeth of said escape wheel, so as to maintain periodic oscillations of the vibrating oscillator and to advance the escape wheel by one tooth at each alternation of the oscillations, in which the arms and the anchor part are formed in a single piece, and in which the vibrating arms and the anchor part are generally arranged in the same reference plane as the escape wheel.

[0006] The regulating member can be made from a single silicon wafer by a microfabrication process.

[0007] This solution has the particular advantage over the prior art of having a small footprint and of requiring a lower number of parts than that normally required in a conventional assortment or in a tuning fork type regulating member.

[0008] In addition, the high oscillation frequency of this solution allows for better stability and precision of the operation of the oscillating member when worn, and allows a greater quality factor Q, while reducing the requirements adjustment.

[0009] The invention also relates to a method for adjusting the oscillation frequency of such a regulating member and to a watch movement comprising such a regulating member.

Brief description of the figures

[0010] Examples of implementation of the invention are indicated in the description illustrated by the appended figures in which: Figure 1 represents a top view of a regulating member, according to one embodiment; Figure 2 shows a top view of the regulating member in cooperation with an escape wheel, according to one embodiment; Figures 3a to 3d illustrate the oscillation of the regulating member of Figure 1 according to a first fundamental oscillation mode (Figure 3a), a second mode (3b), a third mode (Figure 3c) and a fourth mode (Figure 3c). Figure 3d), according to one embodiment; Figure 4 shows a perspective view of the regulating member comprising weights, according to one embodiment; Figure 5 illustrates a side view of the regulating member comprising weights, according to another embodiment; Figure 6 shows the regulating member comprising stops, according to one embodiment; Figure 7 shows a perspective view of the regulating member, comprising a second oscillator, according to another embodiment; Figure 8 shows a perspective view of the regulating member, according to yet another embodiment; Figure 9 shows a detailed view of the teeth of the escape wheel, according to one embodiment; Figure 10 illustrates the regulating member comprising an on/off mechanism, according to one embodiment; Figure 11 shows a variant of the regulating member comprising a second oscillator; Figure 12 shows another variant of the regulating member comprising a plurality of detachable elements; and Figure 13 represents a top view of the regulating member, according to another exemplary variant.

Example(s) of embodiment of the invention

[0011] According to the invention, the regulating member is a vibrating oscillator, comprising at least two vibrating arms, which is coupled with an anchor part in one piece. In particular, each arm of the regulating member carries a member, such as a lifter, adapted to cooperate with the teeth of an escape wheel. The escape wheel can then be advantageously placed between the arms of the regulating member.

[0012] Figures 1 and 2 represent a top view of a regulating member 1 according to a preferred embodiment of the invention. Here, the regulating member 1 comprises a vibrating oscillator 3 including a vibrating blade 31 and a mass element 32. In this embodiment, the regulating member 1 also comprises a base 2 intended to be mounted on a plate or any other part fixed of a watch movement and on which the vibrating blade 31 is fixed in the vicinity of its nodal point, via a foot 9. In the example illustrated in Figures 1 and 2, the vibrating blade 31 comprises two arms of blade 31' forming a tuning fork, each of the blade arms 31' having a distal end 36. The mass element 32 also comprises two mass arms 32', each extending from the distal end 36 of a blade arms 31'. Advantageously, the frequency of the regulating member 1 can be controlled by varying the size of the vibrating blade 31 and/or the size of the mass element 32.

The anchor part 4 of the regulating member 1 comprises in this embodiment two anchor arms 4', each of the anchor arms 4' extending from the mass arm 32' near the distal end 36 of one of the blade arms 31'. Each of the anchor arms 4' comprises a member, here in the form of a lift 40, adapted to cooperate with the teeth 50 of an escape wheel 5. Preferably, the base 2, the blade arms 31', the mass arms 32' and the anchor arms 4 generally extend in the same reference plane, in an arc relative to a center 12. Drillings 20 can be made in the base 2 so as to fix the base 2 to the plate by screwing 21. The base 2 can however be fixed by any other appropriate means.

[0014] For the remainder of the description, we will adopt, without limitation, transverse “x” and longitudinal “y” orientations, defining the reference plane in which the regulating member 1 extends, as well as an axis “z”. “ perpendicular to the longitudinal and transverse orientations. In Figure 1, the transverse “x” and longitudinal “y” orientations are represented in the page plane and the z axis extends out of the page.

The regulating member 1 is intended to cooperate with the escape wheel 5 (shown in Figure 2) of the watch movement. Preferably, the escape wheel 5 is housed in an interior space 11 delimited by the blade arms 31', the mass arms 32' and the anchor arms 4'. The escape wheel 5 is pivotally mounted around the center 12 so that a toothing 50 of the escape wheel 5 comes into cooperation with the lifts 40. In this configuration, the blade arms 31', the arms masses 32' and the anchor arms 4' are in the same reference plane as the escape wheel 5 and are generally concentric with the pivot axis of the escape wheel 5.

The blade arms 31 are capable of oscillating in the manner of a tuning fork from their end fixed to the base 2. When they oscillate, the blade arms 31' drive the mass arms 32' and the 4' anchor arm also swinging. In particular, the blade arms 31', the mass arms 32' and the anchor arms 4' are capable of oscillating according to a first fundamental oscillation mode, as illustrated in Figure 3a (the movements shown in Figures 3a to 3d are not to scale). In the first oscillation mode, the two blade arms 31', the mass arms 32' and the anchor arms 4' oscillate in the reference plane asymmetrically. In other words, the blade arms 31', the mass arms 32' and the anchor arms 4' move together, in a back and forth movement in the same direction in the reference plane. In Figure 3a, the movement of the blade arms 31', mass arms 32' and anchor arm 4' is indicated by the arrows and their movement is compared to their position at rest by the contour lines.

[0017] When the regulating member 1 cooperates with the escape wheel 5 and oscillates in the first oscillation mode, the anchor arms 4' oscillate and the lifts 40 alternately receive impulses from the teeth of the wheel exhaust 5, so as to alternately lock and release the escape wheel 5 and to maintain the periodic oscillations of the vibrating oscillator 3. The regulating member 1 therefore allows the successive escape of two teeth 50 in such a way that the escape wheel 5 advances by one tooth in a back-and-forth movement of the anchor arms 4'.

[0018] In such a configuration, the oscillating arms formed here by the blade arms 31' and the mass arms 32', play the role of a regulating member, and the anchor arms 4' with the lifts 40 and the wheel 5 plays the role of an escapement member, in a conventional watch movement.

[0019] In one embodiment, the regulating member 1 comprising the vibrating blade 31, the mass element 32 and the anchor 4 is manufactured in a single piece. For example, the regulating member 1 can be made of the same material, such as silicon, quartz, ceramic, a crystalline or amorphous metal, or any other material suitable for precision machining. The regulating member 1 can be manufactured by a microfabrication process on a single silicon wafer (monocrystalline, polycrystalline or amorphous). The escape wheel 5 can also be made from the same material as the oscillating member, possibly on the same wafer.

[0020] The frequency of the first oscillation mode of the regulating member 1 as well as the duration over time of the oscillation (or rate of damping of the oscillation) can be modified by changing the moment of inertia of the rigid arms 32. A higher moment of inertia of the rigid arms 32 results in a lower oscillation frequency of the regulating member 1 and a longer oscillation duration (less rapid damping of oscillations).

[0021] In a variant, the mass arms 32' are arranged so that the center of gravity of the assembly formed by a blade arm 31' and a mass arm 32' is located substantially at the distal end 36 of the blade arm 31', that is to say at the junction between the blade arm 31' and the mass arm 32'.

[0022] Figure 4 shows a perspective view of the regulating member 1, according to an embodiment in which at least one of the two mass arms 32' comprises a flyweight 34. The flyweight 34 makes it possible to modify the moment of 'inertia of the mass arm 32' without significantly increasing the bulk of the regulating member 1. The flyweight 34 is advantageously manufactured from a material having a density greater than that used for the rest of the regulating member 1 (and therefore the arms masses 32'). For example, the weight 34 can be made of gold or any other dense metal or alloy. The weight 34 can be machined by a conventional method and assembled, by gluing, screwing or pinning. Figure 5 illustrates a side view of the regulating member 1, according to a variant in which the flyweight 34 is manufactured by adding material, for example by growth of material, to the surface of at least one of the mass arms 32'. In Figure 5, the weight 34 appears as a covering over the mass arm 32'. The growth of material can be carried out over the entire surface or a portion of the surface of the mass arms 32'. The added material may include gold, a gold alloy or any other material making it possible to increase the density of the mass arm 32'. The addition of material can also be carried out in the thickness of at least one of the two mass arms 32'. Alternatively, the addition of material can be carried out with the same material as that forming the mass arms 32' (and the rest of the regulating member 1).

[0023] More generally, the frequency of oscillation of the regulating member can be adjusted by modifying the inertia of the mass arms 32' and/or the weights 34. In particular, the frequency can be increased by ablation of material on at least one of the mass arms and/or at least one weight. The ablation of material can be carried out by laser machining, by breaking detachable elements (as described in document CH702708) or by any other appropriate method. If detachable elements are used, they can be produced during the same operation as the manufacturing operation of the regulating member. Figure 12 illustrates the regulating member 1 according to a variant in which the mass arms 32' carry a plurality of detachable elements 37 at each of their ends. Each of the detachable elements 37 can be removed from the arm 32' by breaking at a reduced section 37' of the detachable element 37. On the other hand, the frequency of the regulating member can be reduced by increasing the length of the vibrating arms 31', 32' of the regulating member.

[0024] In Figure 12, the elements 37 all have the same size and the same mass. According to a variant, to obtain finer adjustment with a larger range, detachable elements with different masses are used. For example, the detachable elements can be dimensioned in five different masses in order to correspond, respectively, to a correction of: 1 s/d, 2 s/d, 4 s/d, 8 s/d, and 16 s /j. In this way, it is possible to correct from 1 to 31 s/d by detaching a combination of appropriate elements.

The regulating member 1 can also oscillate according to other oscillation modes (harmonics) than the first oscillation mode described above. For example, Figure 3b illustrates the regulating member 1 oscillating in a second oscillation mode, in which the two blade arms 31', the mass arms 32' and the anchor arms 4' oscillate in the reference plane (in the transverse “x” and longitudinal “y” orientations) symmetrically. In the second oscillation mode, the two blade arms 31', the mass arms 32' and the anchor arms 4' move together, successively towards the center 12 and away from the center 12. It will be understood that this mode of oscillation is not favorable to the anchor function of the regulating member 1 since the lifts 40 tighten towards the escape wheel 5 and move away from it successively, not allowing the regulation of the pivoting of the escape wheel 5.

[0026] A third and fourth mode of oscillation are illustrated respectively in Figures 3c and 3d, in which the two blade arms 31 ', the mass arms 32' and the anchor arms 4' oscillate outside the reference plane ( along the “z” axis). In the third oscillation mode (figure 3c), the two blade arms 31', the mass arms 32' and the anchor arms 4' oscillate asymmetrically so that one of the lifts 40 rises according to the “z” axis and the other lift 40 descends along the “z” axis. In the fourth oscillation mode (figure 3d), the two blade arms 31', the mass arms 32' and the anchor arms 4' oscillate symmetrically so that the two lifts 40 rise and fall together, according to the “z” axis.

The oscillation frequency of the different oscillation modes depends on the geometry of the organ 1 and, as discussed above, can be adjusted by modifying the moment of inertia of the mass element 32 (c 'that is to say mass arms 32'). The periodic oscillations corresponding to the first oscillation mode where the vibrating oscillator 3 oscillates in the reference plane can have a frequency ranging from approximately 60 Hz to 5,000 Hz, but preferably are between 60 Hz to 200 Hz. embodiment, the moment of inertia of the mass element 32 is modified so that the oscillation frequency of the first oscillation mode is approximately 100 Hz, the oscillation frequency of the second oscillation mode is of about 128 Hz, and the oscillation frequency of the third and fourth oscillation mode is about 183.5 Hz and 205.8 Hz, respectively. At a frequency of 100 Hz, the time of a rest phase of regulating organ 1 is approximately 1 ms, and the time of a pulse phase is a little more than 1 ms. The regulating member 1 is therefore very little disturbed by friction or shock during contact between the lifts 40 with the teeth 50 of the escape wheel 5.

[0028] In one embodiment illustrated in Figure 10, the regulating member 1 comprises an on/off mechanism 60 comprising a lever 61 actuated by the pull tab 62 of a time setting mechanism and configured to stop and keep the regulating member 1 stopped, by stopping the vibrating arms 31', 32' of the regulating member 1 in an unbalanced position, corresponding to one of the two extreme positions of the vibrating oscillator 3 in operating mode normal (or even an eccentric position relative to the escape wheel 5) so as to ensure a self-starting function of a watch movement. Preferably, the regulating member 1 is started in the first oscillation mode. Vibration of the regulating member in any of the second, third and fourth oscillation modes can be prevented by blocking the vibration of these modes by stops or by other means. For example, Figure 6 shows the regulating member 1 comprising stops 6, according to an embodiment in which each of the stops 6 is formed integrally with one of the mass arms 32' in the reference plane so as to come abutting against each other when the regulating member 1 oscillates symmetrically. The stops 6 therefore prevent the regulating member 1 from oscillating according to the second oscillation mode. Similarly, stops (not shown) can also be configured so as to prevent the movement of the regulating member 1 along the “z” axis, or even along the “x”, “y” and “z” axes. in case of shock.

[0029] According to yet another embodiment, the regulating member 1 comprises a mechanism for adjusting the reference point. In the example of Figures 1 and 2, the adjustment mechanism takes the form of an adjustment fork 8 secured to the base 2 and arranged to cooperate without play with an adjustment eccentric 80 (see Figure 2) pivoting in the plate (or any other fixed part of the movement). The adjustment eccentric 80 is configured to move in the reference plane so as to drive, via the adjustment fork 8, the adjusting member 1 in rotation around a pivot point shown by the number 22 in Figures 1, 2 and 8. Depending on the direction of movement of the adjusting eccentric 80, the regulating member 1 can be rotated clockwise or counterclockwise so as to adjust the penetration of the lifts 40 relative to to the teeth 50 of the escape wheel 5. The adjustment amplitude can, for example, be of the order of approximately ±120 µm. The adjustment fork 8 can be sufficiently flexible so as to absorb possible play between the adjustment fork 8 and the adjustment eccentric 80, and thus ensure immediate driving of the regulating member 1 in both directions of rotation.

[0030] In another variant of the embodiment, the base 2 comprises stops making it possible to limit the transverse movement in the reference plane (see elements 6' in the variant of Figure 8). Such stops can be oriented on an axis perpendicular to the plane of the escape wheel

[0031] The oscillation of the regulating member 1 can be disrupted by the impulse of the teeth 50 of the escape wheel on the lifts 40. In one embodiment illustrated in Figure 7, the regulating member 1 comprises a second oscillator 7 arranged to oscillate freely, that is to say, without being disturbed by the lifts 40. The second oscillator 7 can be coupled to the oscillation of the regulating member 1 by sympathetic resonance. The second oscillator 7 thus makes it possible to reduce the disturbances due to impacts of the teeth 50 on the lifts 40.

[0032] The transmission and coupling of vibrations between the regulating member 1 which cooperates with the escape wheel 5, and the second oscillator 7 can be done via support materials (mechanical resonance), an ambient fluid (acoustic resonance) or by magnetic coupling. In the case of coupling via an ambient fluid, the surface of the regulating member 1 can be modified (for example by nano structuring) so as to increase the pressure of the displaced waves and thus promote the quality synchronization. Alternatively, or in combination, the geometry of the regulating member 1 can be modified. In the case of magnetic coupling, the second free oscillator 7 can be mounted under a controlled atmosphere, for example in a magnetically permeable capsule (not shown), so as to improve the quality factor of the regulating member 1. Generally speaking, the second oscillator 7 contributes to improving the quality factor of the regulating member 1.

[0033] A variant of such a double oscillator is also illustrated in Figure 11. Here the second regulating member 7 comprises a second vibrating blade 71 also divided into two arms 71' and a second mass element 72 also divided into two mass arm 72' so as to give a balanced configuration almost in the shape of an “H” to the regulating member 1.

[0034] It goes without saying that the present invention is not limited to the embodiment which has just been described and that various simple modifications and variants can be envisaged by those skilled in the art without departing from the scope of the present invention. .

[0035] Figure 8 represents the regulating member 1 according to another embodiment in which the base 2 is arranged in the interior space 11 of the member 1, but in a lower plane below the wheel exhaust 5. The configuration of the regulating member 1 of Figure 8 is more compact. In this configuration, the base 2 may include stops 6' which prevent transverse movements of the anchor arms 4' in the reference plane.

Figures 9a and 9b show a detailed view of the teeth 50 of the escape wheel 5, according to one embodiment. Each of the teeth 50 of the escape wheel 5 comprises an inclined impulse plane 51 and a rest plane 52. Each of the lifts 40 also includes an inclined rest plane 41 but does not include an impulse plane, the top 42 of the lift 40 having rather a point shape. The configuration of the teeth 50 of the escape wheel 5 and the lifts 40 in this embodiment allows the lifts 40 to receive the impulses from the teeth 50, and to maintain the oscillations of the vibrating oscillator 3 while advancing the escape wheel 5 in one direction or the other. In other words, the regulating member 1 can operate regardless of the direction of rotation of the escape wheel 5. Figure 9a shows a lift 40 engaged with the impulse plane 51 of a tooth 50 during phase d impulse, while Figure 9b shows a lift 40 engaged with the rest plane 52 of a tooth 50 during the rest phase.

[0037] In order to limit possible rebounds of the lifts 40 during the impulse on the teeth 50 of the escape wheel 5, the latter can be provided with elastic arms 53 (figure 2) so as to absorb the shocks of the lifts 40 on teeth 50.

The regulating member 1 may comprise thermal compensation means including compensating coatings, materials with zero thermo-elastic coefficient, and other means similar to those used on balance wheels, for example bimetallic structures, or others. For example, if the regulating member 1 is made of silicon, it may include a coating of silicon dioxide deposited on at least part of its surface. Alternatively, the thermal compensation means of a silicon regulating member 1 may be one of the means described in the applicant's document CH699780.

The geometry of the regulating member 1 and in particular of these arms can be modified in different ways. For example, according to a variant, each vibrating blade, each mass element and/or each anchor arm can be assimilated together as a single element or vibrating arm of the regulating member. According to another exemplary variant illustrated in Figure 13, the blade arms 31' have a different shape with an intermediate section curved in the other direction, which makes it possible to stiffen the blades (the lifts of the anchor part are not visible in this figure).

[0040] Furthermore, the organs of the anchor part adapted to cooperate with the teeth of the escape wheel (the anchor arms 4, 4') can take different shapes, just like the teeth of the escape wheel .

[0041] The regulating member and the escapement of the present invention also have a unique aesthetic and they can advantageously be incorporated into a watch movement of a watch in a way making it possible to make them visible to the wearer of the watch. For example, the regulating member and the exhaust can be mounted above or below the movement motor member. To also give an indication of the seconds, the escape wheel can be adapted so that it rotates at a speed of one revolution per minute.

Reference numbers used in the figures

[0042] 1 regulating member 11 interior space 12 center 2 base 21 screw 22 pivot point 3 vibrating oscillator 31 vibrating blade 31' blade arm 32 mass element 32' mass arm 34 flyweight 35 flyweight 36 distal end of a blade arm 37 detachable element 37' reduced section of detachable element 4 anchor part 4' anchor arm 40 lift 41 rest plane of the lift 42 top of the tooth 5 escape wheel 50 tooth of the escape wheel 51 plane of impulse of the tooth 52 rest plane of the tooth 53 arm of the escape wheel 6 stop 6' stop 60 start/stop mechanism 61 lever 62 pull 7 second oscillator 71 second vibrating blade 71' second blade arm 72 second mass element 72' second mass arm 8 adjustment fork 80 adjustment eccentric 9 foot

Claims (23)

1. Regulating member (1) for a mechanical watch movement comprising an escape wheel (5), said regulating member comprising a vibrating oscillator (3) provided with at least two arms, an anchor part (4, 4') and two members arranged so as to cooperate alternately with the teeth of said escape wheel (5), so as to maintain periodic oscillations of the vibrating oscillator (3) and to advance the escape wheel (5) at each alternation of oscillations, in which the arms and the anchor part (4, 4') are formed in a single piece, and in which the vibrating arms and the anchor part (4, 4') are generally arranged in the same plane reference as the escape wheel. 2. Regulating member (1) according to claim 1, wherein the at least two arms of the vibrating oscillator (3) and the anchor part (4, 4') are arranged generally concentrically with a center (12) of the regulating member (1) coinciding with the pivot axis of the escape wheel (5). 3. Regulating member (1) according to claim 1 or 2, further comprising one or more stops (6) adapted to prevent the vibrating oscillator (3) from oscillating outside the reference plane. 4. Regulating member (1) according to one of the preceding claims, wherein said periodic oscillations correspond to a first oscillation mode where the vibrating oscillator (3) oscillates in the reference plane, so that the members of the anchor part (4) move in the same direction to successively engage with the teeth (50) of the escape wheel (5). 5. Regulating member (1) according to claim 4 in which the anchor part (4, 4') comprises two anchor arms (4'), each of the anchor arms (4') comprises a lift (40), and in which, when the anchor arms (4') oscillate, the lifts (40) alternately receive impulses from the teeth (50) of the escape wheel (5). 6. Regulating member (1) according to claim 4 or 5, wherein said periodic oscillations of the first oscillation mode have a frequency ranging from approximately 60 Hz to 5,000 Hz, preferably between 60 Hz to 200 Hz. 7. Regulating member (1) according to one of claims 4 to 6, further comprising one or more stops adapted to prevent the vibrating oscillator (3) from oscillating in a mode of oscillation other than the first mode of oscillation oscillation. 8. Regulating member (1) according to one of the preceding claims, characterized in that each of said at least two arms of the vibrating oscillator (3) includes an arm (31') of a vibrating blade (31) and a arm (32') of a mass element (32), and in that the anchor part (4) comprises two anchor arms (4'). 9. Regulating member (1) according to claim 8, wherein each arm (31') of the vibrating blade (31) has a distal end (36); and wherein each arm (32') of the mass element (32) extends from the distal end (36) of the corresponding arm (31') of the vibrating blade (31). 10. Regulating member (1) according to claim 9, in which each of the anchor arms (4') extends from one of the arms (32') of the mass element adjacent to the distal end (36) of the arm (31') of the corresponding vibrating blade (31). 11. Regulating member (1) according to one of claims 8 to 10, in which the vibrating blade (31) is fixed near its nodal point to a base (2) intended to be mounted on a fixed part of the watch movement . 12. Regulating member (1) according to claim 11, in which the base (2) extends in an arc relative to the center (12). 13. Regulating member (1) according to one of the preceding claims, wherein the entire member is made from a single silicon wafer. 14. Regulating member (1) according to one of claims 1 to 12, in which the vibrating oscillator (3) comprises at least one flyweight (34) secured to each arm so as to modify the moment of inertia of the regulating member. 15. Regulating member (1) according to claim 14, in which the at least one flyweight (34) is made of a material having a density greater than that in which the arms are formed. 16. Regulating member (1) according to one of the preceding claims, further comprising an on/off mechanism configured to stop and maintain the regulating member (1) in an unbalanced position and to ensure an auto function. -starting of the regulating organ (1). 17. Regulating member (1) according to one of the preceding claims, further comprising a mechanism for adjusting the reference point (8, 80) making it possible to adjust the penetration of the members relative to the teeth (50) of the gear wheel. exhaust (5). 18. Regulating member (1) according to claim 17, in which the reference point adjustment mechanism comprises an adjustment fork (8) arranged to cooperate without play with an adjustment eccentric (80) so as to drive the adjusting member (1) in rotation around a point of adjustment pivoting (22). 19. Regulating member (1) according to one of the preceding claims, further comprising a second oscillator (7) coupled to the oscillation of the vibrating oscillator (3) by sympathetic resonance. 20. Regulating member (1) according to one of the preceding claims, wherein the regulating member is made of silicon and comprises thermocompensation means. 21. Method for adjusting the oscillation frequency of a regulating member (1) according to one of claims 14 to 20, the method comprising modifying the inertia of the mass arms (32') and/or the flyweights (34) where the frequency is increased by ablation of material on at least one of the mass arms and/or at least one flyweight. 22. Watch movement comprising a regulating member (1) according to one of claims 1 to 20. 23. Watch movement according to claim 22, in which the regulating member is mounted above or below a movement motor member.