CH715531A2 - Regulating organ for watch. - Google Patents

Abstract

The invention relates to a regulating member (30) for a watch comprising a fixed structure extending substantially perpendicular to an axial direction, this regulating member (30) comprising a regulating member with a balance (1) arranged to pivot around a pendulum axis (D1), this pendulum (1) is pivoted by magnetic pivots, or directly in the fixed structure which carries magnets (3) arranged to give an oblique or perpendicular orientation to the pendulum axis (D1) relative to the axial direction, or else in a cage (11), arranged to pivot around a cage axis (DC), and which comprises a device for canceling the step deviation in the vertical positions (10) , constituted by a whirlwind or a carousel, which comprises the regulating member (30), and the cage (11) carrying magnets (3) defining the balance axis (D1) perpendicular or oblique with respect to the axis of cage (DC). The invention also relates to a method for optimizing the chronometric properties of a mechanical watch.

Description

Field of the invention

The invention relates to a regulating member for a watch comprising a fixed structure extending substantially perpendicular to an axial direction, said regulating member comprising a regulating member with a balance arranged to pivot about a balance axis.

The invention also relates to a watch comprising such a regulating member.

The invention relates to the field of regulating bodies for watches.

Invention background

The search for the best chronometric performances is a constant concern of the big watchmaking houses. It is essentially a question of guaranteeing a constancy of the walk, whatever the geometrical position of a watch in space and compared to the gravity field.

The invention of the tourbillon by Abraham-Louis Breguet in 1901, and its improvements, as well as the invention of carousels, in particular developed by Bonniksen at the dawn of the 20th century, have made great progress.

These mechanisms have been constantly improved, such as inclined vortices, which always include a conventional pivoting of the balance axis.

And reducing the last few seconds per day of walking distance remains a very difficult goal to achieve.

Summary of the invention

The invention aims to further improve the chronometric properties of the regulating organs, in particular but not limited to whirlwinds or carousels, by adopting specific geometries of the pivot axes of the various mobiles, in combination with the adoption magnetic pivoting means, at least at the level of the inertial mass of the resonator, in particular a pendulum.

Thus, the invention relates to a regulating member for a watch, according to claim 1.

The invention also relates to a watch comprising such a regulating member.

Brief description of the drawings

Other characteristics and advantages of the invention will appear on reading the detailed description which follows, with reference to the accompanying drawings, where: Figure 1 shows, schematically, a watch 1000, which has a fixed structure, which extends substantially in a plane and perpendicular to an axial direction; a member comprises a pendulum pivoting about a pendulum axis parallel to the axial direction; FIG. 2 is a flow diagram, which presents the chronometric properties typical of a resonator with magnetic pivoting of the balance, as a function of time on the abscissa, with the walking distance on the ordinate, in seconds per day; the normalized positions VB, VH, VD, VG, HH and HB are indicated in FIG. 1, with reference to a trihedron XYZ whose axis Z corresponds to the field of gravity; Figure 3 shows, schematically and in section, the regulating member of the mechanism of Figures 1 and 2; FIG. 4 represents, diagrammatically, similar to FIG. 1, a mechanism comprising a conventional tourbillon, the cage axis of which is, like the balance axis, parallel to the axial direction; Figure 5 is a walking diagram, similar to Figure 2, specific to the mechanism of Figure 4, simplified with a walking curve V which is the average of the steps measured in the vertical positions; Figure 6 shows, similarly to Figure 3, the regulating member of the mechanism of Figures 4 and 5; Figure 7 shows, schematically, similar to Figure 1, a mechanism comprising a first variant of the invention, with a vortex whose cage axis is perpendicular to the axial direction and whose pendulum axis is parallel to the axial direction; Figure 8 is a walking diagram, similar to Figure 2, specific to the mechanism of Figure 7, simplified with a walking curve M which is the average of the steps measured in the vertical positions; Figure 9 shows, similarly to Figure 3, the regulating member of the mechanism of Figures 7 and 8; FIG. 10 represents, diagrammatically, similar to FIG. 1, a mechanism comprising a second variant of the invention, with a vortex whose cage axis is parallel to the axial direction and whose pendulum axis is perpendicular to the axial direction; Figure 11 is a walking diagram, similar to Figure 2, specific to the mechanism of Figure 10, simplified with a walking curve V which is the average of the steps measured in the vertical positions; Figure 12 is a view similar to Figure 10 showing the watch in a vertical position; Figure 13 shows, similarly to Figure 3, the regulating member of the mechanism of Figures 10 to 12; FIG. 14 represents, diagrammatically, similar to FIG. 1, a mechanism comprising another variant of the invention, with a pendulum whose pendulum axis is oblique with respect to the axial direction; Figure 15 shows, similarly to Figure 3, the regulating member of the mechanism of Figures 14; Figure 16 is a flow diagram, similar to that of Figure 2, in the case of a conventional watch with regulating member with mechanical pivots; Figure 17 is a block diagram showing a watch comprising such a regulating member.

Detailed description of preferred embodiments

Figure 1 shows, very schematically, a watch 1000, which has a fixed structure 100, typically composed of a plate and bridges.

This fixed structure 100 conventionally extends substantially along a plane intended to tangent the wrist of a user for a wristwatch, or to tangent the body or a garment of the user in the case of a watch. poached. This fixed structure 100 extends substantially perpendicular to an axial direction D0. In most watches, this axial direction D0 is that of the axes of the displays such as needles or discs, and it is also the direction of most of the mobiles contained in a watch movement.

Figure 1 shows only a part of the regulating member, in this case an inertial mass, here a balance 1, which is returned to a rest position by elastic return means not shown, such as '' a spiral spring or flexible blades. This pendulum 1 pivots around a pendulum axis D1, which here is parallel, or substantially parallel, to the axial direction D0. By "substantially parallel" here is meant that the axial direction D0 and the direction of the balance axis D1, related to the same point, are included in a cone of total angle at the vertex less than 10 °.

The magnetic pivots, presented in 2011 by Montres Breguet SA, constituted a watchmaking revolution, which makes an essential contribution to chronometry.

Figure 2 shows the typical timing properties of a resonator with magnetic pivoting of the balance. The normalized positions VB, VH, VD, VG, HH and HB are indicated in FIG. 1, with reference to a trihedron XYZ whose axis Z corresponds to the field of gravity. This figure 2 shows relatively small gait differences between the different chronometric positions, with a maximum amplitude of approximately 7 seconds per day, and with a small drift during the disarming time of the barrel, of the order of 3 seconds per day. (included in the previous 7 seconds per day). These values represent significant progress compared to a traditional pivot resonator. We can see that the greatest gait deviations logically correspond to the measurements made according to the direction of the gravity field, HH and HB. The other running values are very close to each other, and converge towards a low common value, between 1 second per day and two seconds per day, towards the end of disarming the barrel.

Figure 3 shows the main elements of the architecture of this regulating organ mechanism 30, with the shaft 2 of the pendulum 1 pivoted in cooperation with magnets 3 and 5 housed at the level of solid elements 4 and 6 of the structure 100. The balance 1 conventionally comprises a clamp 9, supporting micrometric adjustment members not shown. The pendulum 1 comprises plates arranged to cooperate with the fork and the stinger of a retainer 7, in particular an anchor, pivotally mounted around an anchor axis DA; this anchor conventionally cooperates with an exhaust mobile 8, here an escape wheel, pivotally mounted around an exhaust axis DE.

Regarding the chronometric properties, the vertical positions can be adjusted precisely, by adjusting the unbalance of the balance, in particular by the adjustment screws on the clamp. The steps in these positions are therefore grouped in a relatively limited interval (± 2 seconds / day, even ± 1 second / day).

The positions "horizontal high HH" and "horizontal low HB" are practically not adjustable. In fact, in one of these positions, the weight of the balance adds to the axial magnetic force while in the other position, the weight subtracts from the axial magnetic force. This results in a slight difference in gait between these two positions.

In summary, the time balance is therefore as follows: grouped vertical steps, and the positions HH and HB are discarded.

These findings are observed statistically on the chronometric records in production.

Another solution, in the tradition of the Breguet Manufacture, is to use a tourbillon. This case is explained below and differentiated into three main variants according to the respective orientations of the different axes of the different mobiles, and which are illustrated in FIGS. 4 to 13, which are arranged each time similar to this first example above. a simple pendulum on magnetic pivot. In particular, the chronometric properties illustrated in FIG. 2 are taken up and modified / adapted in the cases described below.

5 shows the typical timing properties of a resonator with magnetic pivoting of the balance 1 placed in a tourbillon 10 according to a conventional architecture, visible in Figure 4, so that the balance axis D1 is parallel to the axial direction D0, to which the DC axis of the cage 11 of the tourbillon 10 is also parallel, as visible in FIG. 6. The shaft 2 of the pendulum 1 cooperates with magnets 3 and 5 which are this time housed in hubs 12 and 13 of the cage 11, which hubs are pivoted at the level of pivots 14 and 15 in the structure 100. The cage 11 carries the retainer 7 and the exhaust mobile 8, the latter cooperates by meshing with a fixed wheel 16.

The vortex 10, by its rotation, averages the vertical positions.

By analyzing the chronometric properties of the balance alone, according to Figure 2, it is possible to deduce the chronometric properties of this same balance in a tourbillon whose rotation is coaxial, or parallel, to the rotation of the balance according to Figure 4 The vertical positions are averaged, according to the curve V in FIG. 5. The walking distance between HH and HB remains. This conventionally mounted tourbillon 10 only slightly improves the chronometric balance of this system.

The invention therefore endeavors to develop more judicious configurations, so that the tourbillon, by its rotation, averages the HH, HB positions as well as two other vertical positions. Figures 7 to 13 illustrate two advantageous variants of the invention.

FIGS. 7 to 9 relate to a first variant, comprising a balance 1 on magnetic pivots, with a vortex 10, the cage axis DC of which is substantially in the plane of watch 1000, therefore perpendicular to the axial direction D0, and where the pendulum axis D1 is out of the plane of the watch, in particular but not limited to parallel to the axial direction D0.

FIG. 8 shows the chronometric properties typical of a resonator with magnetic pivoting of the balance placed in a tourbillon according to this modified architecture: cage axis DC in the plane of the watch, balance axis outside the plane of the watch. Figure 9 shows the main elements of the architecture of this mechanism. We see that the escapement mobile 8 meshes with a fixed wheel 17 which has changed orientation compared to that of FIG. 6, since this fixed wheel 16 now extends in the thickness of the watch, and no longer flat. The vortex 10, by its rotation, averages the positions HH, HB and two other vertical positions.

By analyzing the chronometric properties of the balance 1 alone, according to FIG. 2, one can also deduce the chronometric properties of this same balance 1 in the tourbillon 10 according to FIGS. 7 and 9. The deviation values remain the same for two positions VB and VH. On the other hand, two vertical positions VD and VG and the two horizontal positions HH and HB are averaged, according to the curve M in FIG. 8. The distance of travel between HH and HB is eliminated by averaging the positions covered by the vortex. This particular tourbillon 10 therefore improves the chronometric balance of this system. The vertical size of this device is moderate.

Figures 10 to 13 relate to a second variant, comprising a balance 1 on magnetic pivots, with a tourbillon 10 whose DC axis of the cage is substantially out of the plane of the watch, and the balance axis D1 in the plane of the watch.

FIG. 11 shows the chronometric properties typical of an oscillator with magnetic pivoting of the balance 1 placed in a tourbillon 10 according to this modified architecture: cage axis DC outside the plane of the watch, axis of the balance D1 in the plane of the watch. The pendulum axis no longer being outside the plane of the watch in a conventional manner, the chronometric positions are no longer equivalent with the three previous cases.

In this very advantageous construction, the HH and HB positions correspond to an averaging of the positions where the pendulum axis is horizontal. When the watch is vertical, as indicated in FIG. 12, the tourbillon 10 averages the positions where the balance 1 is coaxial with the terrestrial gravity field (equivalent HH and HB of FIG. 2) as well as two positions where the gravity is perpendicular to Earth's gravity.

This tourbillon very clearly improves the chronometric balance of this system. Depending on its size, its vertical size can be significant, which then reserves the use for thick watches, typically large complications. However, the improvement in chronometric properties is such that the invention makes it possible to reduce the diameters of the balance and the cage, in order to restrict the total size, and make the vertical size of such a tourbillon compatible with any haute horlogerie watch.

This favorable configuration of a balance axis D1 in the plane prompts consideration of other variants without a vortex, more economical, by positioning the balance axis D1 inclined relative to the axial direction D0. Figures 14 and 15 illustrate such a mechanism without a vortex, where the balance 1 is simply inclined at an angle a. Indeed, a simple solution to the problem linked to the HH and HB positions is to artificially remove these positions by tilting the pendulum, for example at an angle between 20 ° and 70 °, more particularly between 30 ° and 60 °, more particularly between 40 ° and 50 °. However, in this very economical solution there remains a position of the watch where the pendulum is coaxial with gravity.

Figure 15 is a particular example of geometry.

It is understood that the exhaust line may include one or more square or oblique references. This also makes the whole mechanism very compact.

Different return configurations, at 90 ° or at any angle, can be used: between the anchor and the balance plate; and / or between the anchor and the escape wheel; and / or between the escape wheel and the fixed second wheel.

Thus, the invention relates to a regulating member 30 for a watch 1000 comprising a fixed structure 100 extending substantially perpendicularly to an axial direction D0. This regulating member 30 comprises a regulating member with a pendulum 1 arranged to pivot around a pendulum axis D1.

According to the invention, this pendulum 1 is pivoted by magnetic pivots, or directly in said fixed structure 100 which carries magnets 3, 5, which are arranged to give the pendulum axis D1 an oblique orientation or perpendicular to the axial direction D0, or else in a cage 11, arranged to pivot around a cage axis DC, and which comprises a device for canceling the step deviation in the vertical positions 10, constituted by a whirlwind or a carousel, which comprises the regulating member 30, and the cage 11 carrying magnets 3, 5, defining the balance axis D1 perpendicular or oblique with respect to the axis of cage DC.

In the first variant of Figures 7 to 9, the pendulum 1 is pivoted by such magnetic pivots in such a cage 11, the cage axis DC is perpendicular or substantially perpendicular to the axial direction D0. More particularly, this axis of cage DC is perpendicular to the axial direction D0.

In the second variant of Figures 10 to 13, the pendulum 1 is pivoted by such magnetic pivots in such a cage 11, the cage axis DC is parallel or substantially parallel to the axial direction D0. More particularly, the cage axis DC is parallel to the axial direction D0.

More particularly, in the first or second variant, the cage axis DC is perpendicular or oblique to the balance axis D1. More particularly still, in the first or the second variant, the cage axis DC is perpendicular to the balance axis D1.

More particularly, in the first or second variant, the balance 1 is arranged to cooperate indirectly, through a stopper 7, with an exhaust mobile 8 which meshes with a fixed wheel 16.

More particularly, in the first variant, the axis of said fixed wheel 16 is perpendicular to the axial direction D0.

More particularly, in the second variant, the axis of said fixed wheel 16 is parallel to the axial direction D0.

In the variant of Figures 14 and 15, the pendulum 1 is pivoted by magnetic pivots directly in the fixed structure 100 which carries magnets 3, 5 arranged to give an oblique orientation to the pendulum axis D1 relative to the axial direction D0, but not perpendicular to this axial direction D0. More particularly, the pendulum 1 is arranged to cooperate indirectly, through a retainer 7, with an exhaust mobile 8 which is arranged to be driven, directly or through a gear train, by means of storage of energy. More particularly, as visible in FIG. 15, the pendulum 1 is arranged to cooperate obliquely with the retainer 7.

The invention also relates to a watch 1000 comprising a fixed structure 100 extending substantially perpendicularly to an axial direction D0, and such a regulating member 30, and comprising energy storage means arranged to drive, directly or at through a gear train, the cage 11 when the regulating member 30 comprises a tourbillon or a carousel, or else the exhaust mobile 8 when the regulating member 30 does not include a tourbillon or carrousel.

The invention also relates to a method for optimizing the chronometric properties of a mechanical watch 1000 comprising a fixed structure 100 extending substantially perpendicularly to an axial direction D0, and comprising a regulating member 30 comprising a regulating member with a balance 1 arranged to pivot around a balance axis D1, according to which method: target walking values are defined according to at least each of the six standard chronometric positions; the chronometric properties of the watch 1000 are measured at least according to the six standardized positions; the regulating member 30 is modified to give the pendulum axis D1 an oblique or perpendicular orientation relative to the axial direction D0, a new measurement is made of the chronometric properties of the watch 1000 at least according to the six standardized positions, and the measured running values are compared with the target values; the modification of the regulating member 30 is stopped as soon as the measured walking values are lower than the target values.

More particularly, when after the new measurement the measured walking values are greater than the target values, the regulating member 30 is further modified, by replacing the pivots of the balance 1 with magnetic pivots, and / or by inserting the balance 1 in a cage 11 arranged to pivot around a DC axis of the cage, and which comprises a device for canceling the step deviation in the vertical positions 10, constituted by a whirlwind or a carousel, which is incorporated into the regulating body 30.

More particularly still, when the regulating member 30 is modified by inserting the pendulum 1 into a cage 11, the cage 11 is fitted with magnets 3, 5, constituting magnetic pivots and defining the perpendicular pendulum axis D1 or oblique to the DC cage axis.

More particularly, when the regulating member 30 is modified by replacing the pendulum pivots 1 with magnetic pivots, a modification of the exhaust line is also carried out by incorporating one or more square or oblique references , between the anchor and the balance plate and / or between the anchor and the escape wheel and / or between the escape wheel and the fixed second wheel.

It should be noted that, if the inclination of the axis of the balance D1 relative to the axial direction D0 is favorable for improving the chronometric properties of a watch, the best result is achieved with magnetic pivots , whose power diagrams show a much better grouping in the vertical positions than with conventional pivots, a much less variation (waves of the walking curves) during the power reserve duration than with conventional pivots, and a low drifts during the power reserve while the steps drift appreciably after 24 h when using conventional pivots. The comparison of Figures 2, 5, 8, 11 and 16 clearly shows these advantages.

To simplify, the main effect of the magnetic pivots is to group the walking curves in the vertical positions, with substantially linear walking curves and with a small drift, and, when this arrangement is cumulated with an oblique orientation of the pendulum axis, the running curves in all positions are both substantially close to each other, with linear gaits, and curves corresponding to the vertical positions almost combined.

In sum, in the very favorable case of the use of a tourbillon with a new arrangement of the axes of the mobiles, combined with the use of magnetic bearings, the rotation of the average cage at least partially the positions or the Earth's gravity is coaxial with the pendulum axis (magnetic).

The timing of the regulating member is better in all positions of the watch.

Claims (17)

1. Regulating member (30) for a watch (1000) comprising a fixed structure (100) extending substantially perpendicular to an axial direction (D0), said regulating member (30) comprising a regulating member with a balance (1) arranged for pivoting around a pendulum axis (D1), characterized in that said pendulum (1) is pivoted by magnetic pivots, or else directly in said fixed structure (100) which carries magnets (3, 5) arranged for give said pendulum axis (D1) an oblique or perpendicular orientation relative to said axial direction (D0), or else in a cage (11), arranged to pivot around a cage axis (DC), and which comprises a device for canceling a step deviation in vertical positions (10), constituted by a whirlwind or a carousel, which comprises said regulating member (30), and said cage (11) carrying magnets (3, 5) defining said pendulum axis (D1) perpendicular or oblique to said cage axis (DC). 2. Regulating member (30) according to claim 1, characterized in that said balance (1) is pivoted by said magnetic pivots in a said cage (11), of which said cage axis (DC) is parallel or substantially parallel to said axial direction (D0). 3. Regulating member (30) according to claim 2, characterized in that said cage axis (DC) is parallel to said axial direction (D0). 4. Regulating member (30) according to claim 1, characterized in that said pendulum (1) is pivoted by said magnetic pivots in a said cage (11), of which said cage axis (DC) is perpendicular or substantially perpendicular or oblique to said axial direction (D0). 5. Regulating member (30) according to claim 4, characterized in that said cage axis (DC) is perpendicular to said axial direction (D0). 6. Regulating member (30) according to one of claims 2 to 5, characterized in that said cage axis (DC) is perpendicular or oblique with respect to said balance axis (D1). 7. Regulating member (30) according to one of claims 2 to 6, characterized in that said balance (1) is arranged to cooperate indirectly, through a stopper (7), with an exhaust mobile (8 ) which meshes with a fixed wheel (16). 8. Regulating member (30) according to claim 7 and claim 2 or 3, characterized in that the axis of said fixed wheel (16) is parallel to said axial direction (D0). 9. Regulating member (30) according to claim 7 and claim 4 or 5, characterized in that the axis of said fixed wheel (16) is perpendicular to said axial direction (D0). 10. Regulating member (30) according to claim 1, characterized in that said pendulum (1) is pivoted by said magnetic pivots directly in said fixed structure (100) which carries magnets (3, 5) arranged to give an orientation oblique to said pendulum axis (D1) relative to said axial direction (D0), but not perpendicular to said axial direction (D0). 11. Regulating member (30) according to claim 10, characterized in that said balance (1) is arranged to cooperate indirectly, through a retainer (7), with an exhaust mobile (8) which is arranged to be driven, directly or through a cog, by energy storage means. 12. Regulating member (30) according to claim 11, characterized in that said balance (1) is arranged to cooperate obliquely with said retainer (7). 13. Watch (1000) comprising a fixed structure (100) extending substantially perpendicular to an axial direction (D0), and a regulating member (30) according to one of claims 1 to 12, and comprising storage means for energy arranged to drive, directly or through a gear train, said cage (11) when said regulating member (30) is according to one of claims 2 to 9, or else said exhaust mobile (8) when said regulating member (30) is according to claim 11 or 12. 14. Method for optimizing the chronometric properties of a mechanical watch (1000) comprising a fixed structure (100) extending substantially perpendicular to an axial direction (D0), and comprising a regulating member (30) comprising a regulating member with a pendulum (1) arranged to pivot about a pendulum axis (D1), characterized in that: - target walking values are defined according to at least each of the six standard chronometric positions; - The chronometric properties of said watch (1000) are measured at least according to the six standardized positions; - said regulating member (30) is modified to give said pendulum axis (D1) an oblique or perpendicular orientation relative to said axial direction (D0), A new measurement of the chronometric properties of said watch (1000) is carried out at least according to the six normalized positions, and the measured running values are compared with said target values; - The modification of said regulating member (30) is stopped as soon as said measured walking values are lower than said target values. 15. The method of claim 14, characterized in that, after said new measurement said measured walking values are greater than said target values, said regulating member (30) is further modified, by replacing the pivots of said balance wheel (1) by magnetic pivots, and / or by insertion of said balance (1) in a cage (11) arranged to pivot about a cage axis (DC), and which comprises a device for canceling the step deviation in the vertical positions (10), constituted by a whirlpool or a carousel, which is incorporated into said regulating member (30). 16. Method according to claim 15, characterized in that, when said regulating member (30) is modified by inserting said pendulum (1) in a cage (11), said cage (11) is fitted with magnets (3, 5 ) constituting magnetic pivots and defining said balance axis (D1) perpendicular or oblique with respect to said cage axis (DC). 17. The method of claim 15, characterized in that, when said regulating member (30) is modified by replacing the pivots of said balance (1) with magnetic pivots, a modification of the exhaust line is also carried out by incorporating d one or more square or oblique references, between the anchor and the balance plate and / or between the anchor and the escapement wheel and / or between the escapement wheel and the fixed second wheel.