CH712195B1 - Balance wheel with adjustable auxiliary thermal compensation weights. - Google Patents

Abstract

The invention relates to a balance wheel, with adjustable auxiliary thermal compensation weights (13) making it possible to provide adjustment of the thermal compensation of the balance wheel.

Description

Description

FIELD OF THE INVENTION The invention relates to adjustable auxiliary thermal compensation weights and in particular such weights mounted on a balance of a balance-spring balance spring.

Background of the invention [0002] It is explained in document EP 1 422 436, incorporated by reference into the present application, how to form a compensating hairspring comprising a silicon core coated with silicon dioxide and cooperating with a balance wheel 'predetermined inertia to thermally compensate all of said resonator.

Manufacturing such a compensating hairspring brings many advantages but retains the disadvantage common to all manufacturing. Indeed, the step of engraving hairsprings in a silicon wafer offers a very small but not negligible geometric dispersion, being a compensating hairspring to offer a similar step for each type of movement.

SUMMARY OF THE INVENTION The object of the present invention is to overcome all or part of the drawbacks mentioned above by proposing a balance wheel offering a thermal compensation adjustment making it possible to correct the manufacturing dispersions of the elements of a balance-spring balance spring. .

To this end, the invention relates to a balance comprising a twill connected to a hub using at least one arm, characterized in that the balance comprises adjustable auxiliary thermal compensation weights making it possible to make vary the inertia of the balance as a function of the temperature.

It is therefore understood that the adjustable auxiliary thermal compensation weights are adaptable to a balance of an already developed timepiece movement and make it possible to individually compensate for the dispersion specific to each movement in order to make, for example, a balance-spring balance spring even less sensitive. temperature variations only with a compensating hairspring alone. Therefore, the adjustable auxiliary thermal compensation shoes do not do all of the compensation but provide a means to fine tune the basic setting.

[0007] In accordance with other advantageous variants of the invention:

- the adjustable auxiliary thermal compensation weights are mounted on the pendulum rim;

- the adjustable auxiliary thermal compensation weights are mounted on the external diameter of the pendulum serge, on the internal diameter of the pendulum serge or comprise at least one assembly formed by a first counterweight mounted on the internal diameter of the pendulum serge and a second flyweight mounted on the external diameter of the pendulum serge;

- the adjustable auxiliary thermal compensation weights include an adjustable positioning device in order to adapt the influence of the adjustable auxiliary thermal compensation weights;

- the adjustable positioning device comprises mechanical means making it possible to choose the distance from the free end of the weights relative to the twill;

- the adjustable auxiliary thermal compensation weights include at least one material whose coefficient of expansion is greater than 10.10 ^-6 K ^-1 so that the adjustable auxiliary thermal compensation weights vary the balance inertia as a function of the temperature;

- the adjustable auxiliary thermal compensation weights have a first part comprising the adjustable positioning device making it possible to choose the distance of the free end of the weights from the rim and a second part mounted in the first part and comprising at least one material whose coefficient of expansion is greater than 10.10 ^-6 K ^-1 so that the adjustable auxiliary thermal compensation weights cause the inertia of the balance to vary as a function of the temperature;

- Said at least one material whose coefficient of expansion is greater than 10.10 ^-6 K ^-1 comprises silver, magnesium, lead, thallium, nickel, copper, zinc, gold, aluminum, indium or vulcanite.

In addition, the invention relates to a resonator comprising a compensating hairspring, characterized in that the compensating hairspring is coupled to a balance wheel according to one of the preceding variants.

Summary description of the drawings [0009] Other particularities and advantages will emerge clearly from the description which is given below, for information and in no way limitative, with reference to the attached drawings, in which:

fig. 1 is a partial representation of a watch movement resonator equipped with a pendulum according to the invention;

fig. 2 to 4 are representations of three embodiments of pendulums according to the invention, comprising adjustable auxiliary thermal compensation weights;

fig. 5 and 6 are representations of two alternatives of the third embodiment of pendulums according to the invention, comprising adjustable auxiliary thermal compensation weights;

fig. 7 is a representation of a variant of an adjustable auxiliary thermal compensation shoe, which includes a pendulum according to the invention.

Detailed description of the preferred embodiments As shown in FIG. 1, a resonator 1, comprising a compensating hairspring 3 of the silicon type coated with silicon dioxide and cooperating with a balance 5 of predetermined inertia, offers a step with thermal compensation unprecedented in the field of mechanical watchmaking.

However, the vagaries of manufacturing and the fact that the compensating hairspring is not necessarily of the silicon type coated with silicon dioxide have pushed the Applicant to seek corrective solutions. It thus appeared that a need exists for an adjustable auxiliary thermal compensation system making it possible to adjust the thermal coefficient of a resonator over a range of ± 0.5 sj ^_1 . ^o_1 which can be adapted to existing watch movements.

The invention therefore proposes to modify a usual pendulum such as, for example, comprising an uncut twill connected to a hub using at least one arm. According to the invention, the balance comprises, advantageously, adjustable auxiliary thermal compensation weights making it possible to offer an adjustment of the thermal compensation of the balance. Preferably according to the invention, it appeared simpler to integrate the adjustable auxiliary thermal compensation weights on the balance stick.

It is therefore understood that the adjustable auxiliary thermal compensation weights can individually correct the thermal coefficient of each movement in order to make, for example, a balance-spring balance spring even less sensitive to temperature variations than with a compensating balance spring alone . Consequently, the adjustable auxiliary thermal compensation weights do not make all of the compensation but provide a means to refine the basic adjustment after manufacture or after-sales.

According to a first embodiment illustrated in FIG. 2, a balance 15 can be seen comprising a serge 14 provided with regulating screws 16 and connected to a hub 11 by means of four arms 12. The balance 15 advantageously comprises, according to the invention, two adjustable auxiliary thermal compensation weights 13 mounted on the outer diameter of the serge 14 of the balance 15 allowing adjustment of the thermal compensation of the balance 15.

We understand that the goal is to offer a possibility to adjust the variation of the inertia of the balance 15 in a predetermined manner as a function of temperature variations in order to correct the manufacturing dispersions of the elements of a resonator 1 balance- hairspring.

In the first embodiment illustrated in FIG. 2, the adjustable auxiliary thermal compensation weights 13 are mounted symmetrically on the external diameter of the serge 14 relative to the hub 11.

To do this, the adjustable auxiliary thermal compensation weights 13 include an adjustable positioning device 19 in order to adapt the influence of the adjustable auxiliary thermal compensation weights 13. In the example of FIG. 2, the adjustable positioning device 19 comprises mechanical means formed by sets of threaded holes in the serge 14 - threads on the counterweights 13 making it possible to choose the distance from the free end of the counterweights 13 relative to the serge 14. It is understood therefore that, in the example of FIG. 2, the counterweights 13 function substantially like the regulating screws 16.

According to the first embodiment illustrated in FIG. 2, the adjustable auxiliary thermal compensation weights 13 comprise one (or more) material (s) whose coefficient of expansion is greater than 10.10 ^-6 K ^-1 so that the adjustable auxiliary thermal compensation weights 13 cause the inertia of the pendulum 15 as a function of temperature.

Said at least one material whose coefficient of expansion is greater than 10.10 ^-6 K ^-1 may thus include silver, magnesium, lead, thallium, nickel, copper, zinc, l ', aluminum, indium or vulcanite.

It is therefore understood that by adjusting the penetration of the adjustable auxiliary thermal compensation weights 13 in the rim 14, it is possible to choose a predetermined correction of the inertia of the balance 15 as a function of temperature variations.

Of course, the present invention is not limited to the example illustrated but is capable of various variants and modifications which will appear to those skilled in the art. In particular, the pendulum 15 can also be of different geometry such as, for example, with more or less arms 12, with a cut serge 14, with a serge 14 with two concentric integral rings or with a serge 14 formed of several curved lobes . The balance 15 can also include a larger number of adjustable auxiliary thermal compensation weights 13. Similarly, the weights 13 could also be of different geometry and / or comprise one (or more) different material (s) and / or an adjustable positioning device 19 different according to the desired range of adjustment of the thermal coefficient. As an example, a variant of the counterweight 61 of adjustable auxiliary thermal compensation is presented in FIG. 7. The flyweight 61 comprises a first part 63 for fixing to the serge 14 of the balance 15 and a second part 65 for adjusting thermal compensation. It is therefore understood that the first part 63 does not have to be formed from a material whose coefficient of expansion which is greater than 10.10 ^-6 K ^-1 . Indeed, the second part 65 may be the only part to be formed from a material whose coefficient of expansion which is greater than 10.1 CT ⁶ K ^-1 .

Thus, according to the example of FIG. 7, the first fixing part 63 comprises a tubular body provided with a thread 62 and a flange 64. The thread 62 is intended to cooperate with a corresponding thread formed in the serge 14 of the pendulum 15. It is understood that the thread 62 forms an adjustable positioning device like that 19 explained above, and makes it possible, through the first part 63, to choose the distance from the free end of the weights 61 relative to the serge 14.

In addition, according to the example of FIG. 7, the second thermal compensation part 65 comprises a rod 67 received in the tubular body of the first part. Preferably, the rod 67 comprises a thread 66 intended to cooperate with the end 68 of the first part 63 in order to adjust the insertion of the rod 67 into the tubular body of the first part 63. However, alternatively, the rod 67 could more simply to be fitted into the first part 63. At the end of the rod 67 opposite to that receiving, preferably, the thread 62, the second part 65 comprises a block 69 intended to maximize the compensation effect of the counterweight 61.

[0025] Consequently, the variant of flyweight 61 of adjustable auxiliary thermal compensation presented in FIG. 7 can be adjusted at the level of the insertion of the first part 63 in the rim 14 and, preferably, by the insertion of the second part 65 in the first part 63 in order to precisely choose the distance from the block 69 of the counterweights 61 by relative to the serge 14. Of course, if the second part 65 is fitted into the first part 63, the adjustment will only be made by driving the first part 63 into the serge 14.

According to a second embodiment illustrated in FIG. 3, a balance 25 can be seen comprising a serge 24 provided with regulating screws 26 and connected to a hub 21 by means of four arms 22. The balance 25 advantageously comprises, according to the invention, two adjustable auxiliary thermal compensation weights 23 mounted on the internal diameter of the serge 24 of the balance 25 allowing adjustment of the thermal compensation of the balance 25. It is noted that this second embodiment offers the advantage of not requiring additional space as for the first embodiment.

We understand that the goal is to offer a possibility of adjusting the variation of the inertia of the balance 25 in a predetermined manner as a function of temperature variations in order to correct the manufacturing dispersions of the elements of a resonator 1 balance- hairspring.

In the second embodiment illustrated in FIG. 3, the adjustable auxiliary thermal compensation weights 23 are mounted symmetrically on the internal diameter of the serge 24 relative to the hub 21.

To do this, the adjustable auxiliary thermal compensation weights 23 include an adjustable positioning device 29 in order to adapt the influence of the adjustable auxiliary thermal compensation weights 23. In the example of FIG. 3, the adjustable positioning device 29 comprises mechanical means formed by sets of threaded holes in the serge 24 - threads on the counterweights 23 making it possible to choose the distance from the free end of the counterweights 23 relative to the serge 24. It is understood therefore that, in the example of FIG. 3, the counterweights 23 operate substantially in reverse to the regulating screws 26.

According to the second embodiment illustrated in FIG. 3, the adjustable auxiliary thermal compensation weights 23 comprise one (or more) material (s) whose coefficient of expansion is greater than 10.10 ^-6 K ^-1 so that the adjustable auxiliary thermal compensation weights 23 cause the inertia of the pendulum 25 as a function of temperature.

Said at least one material whose coefficient of expansion is greater than 10.10 ^-6 K ^-1 can thus include silver, magnesium, lead, thallium, nickel, copper, zinc, l ', aluminum, indium or vulcanite.

It is therefore understood that by adjusting the penetration of the adjustable auxiliary thermal compensation weights 23 in the rim 24, it is possible to choose a predetermined correction of the inertia of the balance wheel 25 as a function of temperature variations.

Of course, the present invention is not limited to the illustrated example but is susceptible to various variants and modifications which will appear to those skilled in the art. In particular, the pendulum 25 can also be of different geometry such as, for example, with more or less arms 22, with a cut serge 24, with a serge 24 with two concentric integral rings or with a serge 24 formed of several curved lobes . The balance 25 can also include a larger number of adjustable auxiliary thermal compensation weights 23. Similarly, the counterweights 23 could also be of different geometry and / or comprise one (or more) different material (s) and / or an adjustable positioning device 29 different according to the desired range of adjustment of the thermal coefficient. By way of example, one or more weights 23 could be modified according to the variant presented in FIG. 7.

According to a third embodiment illustrated in FIG. 4, a balance 35 can be seen comprising a serge 34 provided with adjusting screws 36 and connected to a hub 31 by means of four arms 32. The balance 35 advantageously comprises, according to the invention, two adjustable auxiliary thermal compensation weights which comprise at least one assembly 37 formed by a first counterweight 33 mounted on the internal diameter of the serge 34 of the pendulum 35 and a second counterweight 38 mounted on the external diameter of the serge 34 of the pendulum 35. It is noted that this third mode of embodiment allows the same inertia to be maintained at ambient temperature by allowing compensation by the combined displacement of the first and second flyweights 33, 38 towards the serge 34 or, on the contrary, by deviating from the serge 34.

We understand that the goal is to offer a possibility to adjust the variation of the inertia of the balance 35 in a predetermined manner as a function of temperature variations in order to correct the manufacturing dispersions of the elements of a resonator 1 balance- hairspring.

In the third embodiment illustrated in FIG. 4, the adjustable auxiliary thermal compensation weights 33, 38 are mounted symmetrically on each side of the serge 34.

To do this, the adjustable auxiliary thermal compensation weights 33, 38 include an adjustable positioning device 39 in order to adapt the influence of the adjustable auxiliary thermal compensation weights 33, 38. In the example of FIG. 4, the adjustable positioning device 39 comprises mechanical means formed by sets of threaded holes in the serge 34 - threads on the weights 33, 38 making it possible to choose the distance from the free end of the weights 33, 38 relative to the serge 34. It is therefore understood that, in the example of FIG. 4, the counterweights 33, 38 operate substantially in opposite directions so as not to interfere with the inertia at ambient temperature.

As such, advantageously according to the invention, it is understood in a variant of the third embodiment, that an alternative adjustable positioning device could be implemented to move the said at least one assembly 37 at the same time in order to jointly move the two weights 33, 38 towards the serge 34 or, on the contrary, by moving away from the serge 34. Such an alternative adjustable positioning device could consist of a single double screw making it possible to move the weights simultaneously apart or closer together 33, 38.

According to the third embodiment illustrated in FIG. 4, the adjustable auxiliary thermal compensation weights 33, 38 comprise one (or more) material (s) whose coefficient of expansion is greater than 10.10 ^-6 K ^-1 so that the adjustable auxiliary thermal compensation weights 33, 38 can vary the inertia of the pendulum 35 as a function of the temperature.

Said at least one material whose coefficient of expansion is greater than 10.10 ^-6 K ^-1 may thus include silver, magnesium, lead, thallium, nickel, copper, zinc, l ', aluminum, indium or vulcanite.

It is therefore understood that by adjusting the penetration of the adjustable auxiliary thermal compensation weights 33, 38 in the rim 34, it is possible to choose a predetermined correction of the inertia of the balance wheel 35 as a function of temperature variations.

Of course, the present invention is not limited to the illustrated example but is susceptible to various variants and modifications which will appear to those skilled in the art. In particular, the pendulum 35 can also be of different geometry such as, for example, with more or less arms 32, with a cut serge 34, with a serge 34 with two concentric integral rings or with a serge 34 formed of several curved lobes . Similarly, the counterweights 33, 38 could also be of different geometry and / or comprise one (or more) different material (s) and / or an adjustable positioning device 39 different according to the desired range of adjustment of the coefficient thermal. By way of example, one or more weights 33, 38 could be modified according to the variant presented in FIG. 7.

According to first and second alternatives, the balance 35 could include a larger number of assembly 37 of counterweights 33, 38 of adjustable auxiliary thermal compensation.

According to the first alternative illustrated in FIG. 5, a balance 45 can be seen comprising a clamp 34 provided with adjusting screws 36 and connected to a hub 31 by means of four arms 32. The balance 45 advantageously comprises two assemblies 37,, 37 ₂ formed respectively by a first counterweight 33,, 33 ₂ mounted on the internal diameter of the serge 34 of the pendulum 45 and a second counterweight 38,, 38 ₂ mounted on the external diameter of the serge 34 of the pendulum 45. It can be seen that the two assemblies 37 ,, 37 ₂ are mounted symmetrically on the serge 34 relative to the hub 31.

Note that this first alternative of the third embodiment makes it possible to better balance the pendulum 45 relative to the pendulum 35 of FIG. 4 while maintaining the same inertia at room temperature and allowing compensation by the combined movement of the first and second flyweights 33 ,, 33 ₂ , 38 ,, 38 ₂ towards the rim 34 or, on the contrary, by deviating from the serge 34.

It is understood that the aim is to offer a possibility, with the same advantages as those explained for FIG. 4, to adjust the variation of the inertia of the balance 45 in a predetermined manner as a function of the temperature variations in order to correct the manufacturing dispersions of the elements of a balance-spring 1 balance spring. Thus, by adjusting the penetration of the adjustable auxiliary thermal compensation weights 33,, 33 ₂ , 38,, 38 ₂ in the rim 34, it is possible to choose a predetermined correction of the inertia of the balance wheel 45 as a function of temperature variations .

Of course, the present invention is not limited to the example illustrated but is capable of various variants and modifications which will appear to those skilled in the art. In particular, the pendulum 45 can also be of different geometry such as, for example, with more or less arms 32, with a cut serge 34, with a serge 34 with two concentric integral rings or with a serge 34 formed of several curved lobes . Similarly, the counterweights 33,, 33 ₂ , 38,, 38 ₂ could also be of different geometry and / or comprise one (or more) different material (s) and / or an adjustable positioning device 39, , 39 ₂ different depending on the desired range of adjustment of the thermal coefficient. For example, one or more weights 33 ,, 33 ₂ , 38 ,, 38 ₂ could be modified according to the variant presented in FIG. 7.

According to the second alternative illustrated in FIG. 6, a balance 55 can be seen comprising a serge 34 provided with regulating screws 36 and connected to a hub 31 by means of four arms 32. The balance 55 advantageously comprises four assemblies 37 ,, 37 ₂ , 37 ₃ , 37 ₄ formed respectively by a first counterweight 33 ,, 33 ₂ , 33 _s , 33 ₄ mounted on the internal diameter of the serge 34 of the pendulum 55 and a second counterweight 38 ,, 38 ₂ , 38 ₃ , 38 ₄ mounted on the outer diameter of the serge 34 of the pendulum 55. It can be seen that the four assemblies 37 ,, 37 ₂ , 37 ₃ , 37 ₄ are mounted symmetrically on the serge 34 relative to the hub 31.

Note that this second alternative of the third embodiment makes it possible to thermally influence the pendulum 55 relative to the pendulum 45 of FIG. 5 while maintaining the same inertia at ambient temperature and allowing compensation by the combined displacement of the first and second flyweights 33 ,, 33 ₂ , 33 ₃ , 33 ₄ ,

38 ,, 38 ₂ , 38 ₃ , 38 ₄ towards serge 34 or, on the contrary, by deviating from serge 34.

It is understood that the aim is to offer a possibility, with the same advantages as those explained for FIGS. 4 and 5, to adjust the variation of the inertia of the balance 55 in a predetermined manner as a function of the temperature variations in order to correct the manufacturing dispersions of the elements of a balance-spring 1 balance spring. Thus, by adjusting the penetration of the adjustable auxiliary thermal compensation weights 33 ,, 33 ₂ , 33 ₃ , 33 ₄ , 38 ,, 38 ₂ , 38 ₃ , 38 ₄ in the serge 34, it is possible to choose a predetermined correction of the inertia of the pendulum 55 as a function of temperature variations.

Of course, the present invention is not limited to the illustrated example but is susceptible to various variants and modifications which will appear to those skilled in the art. In particular, the pendulum 55 can also be of different geometry such as, for example, with more or less arms 32, with a cut serge 34, with a serge 55 with two concentric integral rings or with a serge 34 formed of several curved lobes .

Similarly, the weights 33 ,, 33 ₂ , 33 ₃ , 33 ₄ , 38 ,, 38 ₂ , 38 ₃ , 38 ₄ could also be of different geometry and / or include one (or more) material (x ) different and / or an adjustable positioning device 39 ,, 39 ₂ , 39 ₃ , 39 ₄ different depending on the desired range of adjustment of the thermal coefficient. For example, one or more weights 33 ,, 33 ₂ , 33 ₃ , 33 ₄ , 38 ,, 38 ₂ , 38 ₃ , 38 ₄ could be modified according to the variant presented in FIG. 7.

Claims (11)

Claims 1. Balance wheel (5, 15, 25, 35, 45, 55) comprising a serge (14, 24, 34) connected to a hub (11,21,31) using at least one arm (12, 22, 32), characterized in that the balance (5, 15, 25, 35, 45, 55) has weights (13, 23, 33, 38, 33 ,, 38 ,, 33 ₂ , 38 ₂ , 33 ₃ , 38 ₃ , 33 ₄ , 38 ₄ ) adjustable auxiliary thermal compensation making it possible to vary the inertia of the balance (5, 15, 25, 35, 45, 55) as a function of the temperature. 2. Balance wheel (5,15, 25, 35, 45, 55) according to the preceding claim, characterized in that the weights (13, 23, 33, 38, 33,, 38 ₄ , 33 ₂ , 38 ₂ , 33 ₃ , 38 ₃ , 33 ₄ , 38 ₄ ) of adjustable auxiliary thermal compensation are mounted on the clamp (14, 24, 34) of the balance (5, 15, 25, 35, 45, 55). 3. Balance wheel (5,15, 25, 35, 45, 55) according to the preceding claim, characterized in that the weights (13, 23, 33, 38, 33,, 38 ₄ , 33 ₂ , 38 ₂ , 33 ₃ , 38 ₃ , 33 ₄ , 88 ₄ ) of adjustable auxiliary thermal compensation are mounted on the external diameter of the serge (14, 24, 34) of the balance (5, 15, 25, 35, 45, 55). 4. balance (5, 15, 25, 35, 45, 55) according to claim 2, characterized in that the weights (13, 23, 33, 38, 33 ,, 38 ,, 33 ₂ , 38 ₂ , 33 ₃ , 38 ₃ , 33 ₄ , 38 ₄ ) adjustable auxiliary thermal compensation are mounted on the internal diameter of the serge (14, 24, 34) of the balance (5, 15, 25 , 35, 45, 55). 5. Balance wheel (5, 15, 25, 35, 45, 55) according to claim 2, characterized in that the weights (13, 23, 33, 38, 33 ,, 38 ,, 33 ₂ , 38 ₂ , 33 ₃ , 38 ₃ , 33 ₄ , 38 ₄ ) of adjustable auxiliary thermal compensation comprise at least one assembly formed by a first counterweight mounted on the internal diameter of the serge (14, 24, 34 ) of the balance (5, 15, 25, 35, 45, 55) and a second counterweight mounted on the external diameter of the serge (14, 24, 34) of the balance (5, 15, 25, 35, 45, 55) . 6. Balance wheel (5, 15, 25, 35, 45, 55) according to one of the preceding claims, characterized in that the weights (13, 23, 33, 38, 33 ,, 38 ,, 33 ₂ , 38 ₂ , 33 ₃ , 38 ₃ , 33 ₄ , 38 ₄ ) adjustable auxiliary thermal compensation include an adjustable positioning device (19, 29, 39, 39 ,, 39 ₂ , 39 ₃ , 39 ₄ ) in order to adapt the influence weights (13, 23, 33, 38, 33,, 38 ₄ , 33 ₂ , 38 ₂ , 33 _s , 38 ₃ , 33 ₄ , 38 ₄ ) adjustable auxiliary thermal compensation. 7. pendulum (5, 15, 25, 35, 45, 55) according to the preceding claim, characterized in that the adjustable positioning device (19, 29, 39, 39 ₄ , 39 ₂ , 39 ₃ , 39 ₄ ) comprises mechanical means for choosing the distance from the free end of the counterweights (13, 23, 33, 38, 33 ₄ , 38 ₄ , 33 ₂ , 38 ₂ , 33 ₃ , 38 ₃ , 33 ₄ , 38 ₄ ) relative serge (14, 24, 34). 8. Balance wheel (5, 15, 25, 35, 45, 55) according to one of the preceding claims, characterized in that the weights (13, 23, 33, 38, 33 ,, 38 ,, 33 ₂ , 38 ₂ , 33 ₃ , 38 ₃ , 33 ₄ , 38 ₄ ) adjustable auxiliary thermal compensation includes at least one material whose expansion coefficient a is greater than 10.10 ^-6 K ^-1 so that the weights (13, 23, 33, 38 , 33 ,, 38 ,, 33 ₂ , 38 ₂ , 33 ₃ , 38 ₃ , 33 ₄ , 38 ₄ ) adjustable auxiliary thermal compensation causes the balance wheel inertia to vary (5, 15, 25, 35, 45, 55) depending on the temperature. 9. Balance wheel (5, 15, 25, 35, 45, 55) according to claim 6, characterized in that the weights (13, 23, 33, 38, 33 ,, 38 ,, 33 ₂ , 38 ₂ , 33 ₃ , 38 ₃ , 33 ₄ , 38 ₄ ) of adjustable auxiliary thermal compensation comprise a first part (63) comprising the adjustable positioning device (19, 29, 39, 39 ,, 39 ₂ , 39 ₃ , 39 ₄ ) allowing to choose the distance from the free end of the weights (13, 23, 33, 38, 33 ,, 38 ,, 33 ₂ , 38 ₂ , 33 ₃ , 38 ₃ , 33 ₄ , 38 ₄ ) relative to the serge (14, 24, 34) and a second part (65) mounted in the first part (63) and comprising at least one material whose coefficient of expansion is greater than 10.10 ^-6 K ^-1 so that the weights (13, 23, 33, 38 , 33 ,, 38 ,, 33 ₂ , 38 ₂ , 33 ₃ , 38 ₃ , 33 ₄ , 38 ₄ ) adjustable auxiliary thermal compensation causes the balance wheel inertia to vary (5, 15, 25, 35, 45, 55) depending on the temperature. 10. Balance (5, 15, 25, 35, 45, 55) according to claim 8 or 9, characterized in that said at least one material whose coefficient of expansion is greater than 10.10 ^-6 K ^-1 includes silver , magnesium, lead, thallium, nickel, copper, zinc, gold, aluminum, indium or vulcanite. 11. Resonator (1) comprising a compensating hairspring (3), characterized in that the compensating hairspring (3) is coupled to a balance (5, 15, 25, 35, 45, 55) according to one of claims 1 to 10.