CH715024A2 - Mechanical clock oscillator. - Google Patents

Abstract

The invention relates to a mechanical oscillator (100) with inertial element (4) oscillating around a virtual pivot axis (D) of fixed position with respect to a fixed base (2) to which it is suspended by several flexible links ( 5), each comprising a deformable compass (7A, 7B, 7C) comprising elastic blades (6) forming a first branch (8) fixed to a base (2) and a second branch (9) fixed to said inertial element (4) contiguous at a cusp edge (11) defining an apex of said deformable compass (7A, 7B, 7C), wherein in an unstressed state of said oscillator (100), the projection of said vertex is of a first side of said pivot axis (D), opposite a second side which project the ends (82; 94) of the first (8) and second (9) branches.

Description

Description Field of the Invention The invention relates to a mechanical watch oscillator, comprising at least one base arranged to be fixed to a plate or a bridge of a watch movement, and at least one inertial element arranged for oscillating about a virtual pivot axis of fixed position relative to said at least one base or of fixed position relative to said bases when said oscillator comprises several thereof, in a pivot plane perpendicular to said virtual pivot axis, each said inertial element being suspended from at least one said base by several flexible connections each comprising at least one elastic blade, and said flexible connections together defining said virtual pivot axis.

The invention also relates to a clockwork movement, comprising at least one such mechanical oscillator, and comprising a plate or a bridge for fixing each said base, which each said oscillator comprises.

The invention also relates to a watch comprising at least one such clockwork movement, and / or comprising at least one such mechanical oscillator.

The invention relates to the field of high precision timepieces, very insensitive to external physical parameters, comprising oscillators with elastic blades, high quality factor, and retaining high qualities of isochronism in all worn positions.

BACKGROUND OF THE INVENTION The most recent works on watch oscillators have presented different types of flexible links, for pivoting and recalling pendulums.

Without going into detail, it will be noted that two conditions must absolutely be met to allow the use of these oscillators in watches:

- the gait should depend as little as possible on the amplitude of oscillation, even if it is possible to compensate for the delay in the exhaust;

- the step must be independent of the orientation of the watch in the gravity field.

Various disclosures consider ensuring these two essential characteristics, but the simulations and the practical tests demonstrate, in fact, deficiencies, in particular in certain positions of the range, where the expected results cannot be ensured.

Current disclosures generally have a defect which limits their industrial application, and which consists in the low value of possible oscillation amplitude, typically up to 10 ° or 15 ° only. This limit can be explained either because it is impossible to go higher due to the constraints in the blades making up the flexible connections, or because at least one of the two conditions set out above, (step independent of the amplitude, and walking independent of the orientation of the watch in the gravity field) is no longer satisfied.

Patent application EP 3 299 905 in the name of CSEM offers a solution which makes it possible to go to higher amplitudes, typically 30 °, which is real progress. However, walking is not yet independent of the orientation of the watch in the gravity field, in particular in the positions X +, X-, Y +, Y-, in which the walking characteristics as a function of the amplitude are similar to each other, but very far from the walking characteristic as a function of the amplitude, which corresponds to the horizontal position, perpendicular to the gravity field, which characteristic is excellent.

Claims (29)

Summary of the invention The invention proposes to develop a mechanical oscillator with flexible links suitable for a high amplitude, and typically up to 25 ° at least, and which has in the vertical positions of the carried walking characteristics as a function of the amplitude equivalent to that measured in the horizontal position. To this end, the invention relates to a mechanical clockwork oscillator according to claim 1. The invention also relates to a timepiece movement according to claim 28. The invention also relates to a watch according to claim 29. Brief description of the drawings [0014] Other characteristics and advantages of the invention will appear on reading the detailed description which follows, with reference to the accompanying drawings, where: fig. 1 shows, schematically, and in perspective view from above, an oscillator according to the invention, in a particular and non-limiting embodiment where an inertia element! single is suspended from bases CH 715 024 A2 fixed to the structure of a movement by three flexible links of similar characteristics, together defining the virtual pivot axis of the inertial element, and superimposed in different levels parallel to a pivot plane of the inertial element , perpendicular to the virtual pivot axis; fig. 2 shows, schematically, and in top view, the oscillator of FIG. 1; fig. 3 is a section along a plane AA, passing through the pivot axis, of such an oscillator according to FIG. 1 or 2, the section plane passing through two elastic blades which together constitute a deformable compass, which comprises one of the flexible connections of this oscillator, in a particular variant where the arms of the compass constituted by these two elastic blades which are in two levels superimposed, parallel to the pivot plane, have useful lengths, between their embedding and a virtual compass top at a cusp edge, which are equal. In this variant, the inertial element extends on either side of the set of elastic blades; fig. 4 illustrates, similarly to FIG. 3, another variant, where the useful lengths are different, the projections of blades on the pivoting plane are identical only on one part, which comprises the top of the compass, and extends on either side of the virtual pivot axis defined by flexible links; fig. 5 is a block diagram which represents a watch comprising a clockwork movement, which comprises such a mechanical oscillator, and a plate or a bridge for fixing each said base, which this oscillator comprises; fig. 6 illustrates, similarly to FIG. 3, another variant, where the same flexible connection comprises a superposition of six elastic blades, here constituting three deformable compasses; fig. 7 illustrates, similarly to FIG. 2, a detail of another variant, where the elastic blades which constitute the flexible connections are not straight, but only symmetrical with respect to a compass axis passing through the compass top and the virtual pivot axis, in projection on the pivot plane; fig. 8 is a section through the plane AA, passing through the pivot axis, of such an oscillator according to FIG. 1 or 2, showing the superposition of the three levels of flexible connections, each extending over two parallel levels; fig. 9 is a walking diagram, with walking in seconds per day on the ordinate, as a function of the amplitude in degrees on the abscissa, the upper curve corresponds to walking in the horizontal plane, and the lower curve, very close to the previous one , which results from the superposition of the walking curves in a vertical plane, for four different orientations in gravity X +, X-, Y +, Y-; fig. 10 is a section which illustrates, similarly to FIG. 3, and in the plane of the upper flexible connection, another variant, where the inertial element does not extend on either side of the set of elastic blades, but only of the upper elastic blade; fig. 11 is a section through the variant of FIG. 10, by the same plane, and in which the three flexible connections are visible; fig. 12 is a section of the variant of FIG. 10, in the plane of the intermediate flexible connection. Detailed description of the preferred embodiments The difficulty of the problem set out above is to determine a geometry of the flexible connections of the oscillator, which makes it possible to obtain a solution which satisfies the two operating conditions independent of the amplitude , and walking independently of the orientation of the watch in the gravity field, while having an amplitude allowing industrial exploitation, typically more than 25 °, and preferably from 30 ° to 40 ° approximately, or even more. The invention relates to a mechanical clock oscillator 100, which comprises at least one base 2 arranged to be fixed to a plate 3 or a bridge of a clockwork movement 200. This oscillator 100 comprises at least one element inertial 4, which is arranged to oscillate around a virtual pivot axis D of fixed position relative to this base 2 if it is unique, or relative to these bases 2 when the oscillator 100 comprises several, in a plane pivot P perpendicular to the virtual pivot axis D. Each inertial element 4 is suspended from at least one such base 2 by several flexible connections 5 each comprising at least one elastic blade 6. And these flexible connections 5 together define the virtual pivot axis D, in their particular geometric arrangement , in projection on the pivot plane P of the inertial element 4. First of all, the present invention endeavors to avoid any configuration where the inertial mass of the oscillator, typically a pendulum, comprises rigid arms extending from the twill to an internal diameter of the support of elastic blades 6 constituting flexible connections 5. For this purpose, the invention favors the configuration where elastic blades 6 are fixed to the twill of the inertial element 4 on the one hand, and to the frame (plate or bridge of the movement ) else CH 715 024 A2 starts at a fixed base 2, at their end located on the outside diameter, that is to say the one most distant from the virtual pivot axis D defined by the flexible connections 5. Then, the invention favors a crossing of the blades, of course in projection on the pivot plane P because these elastic blades 6 are arranged in different and parallel levels, at the level of the pivot axis D. Naturally this configuration according to the invention requires stacking on more levels than the prior art, but can also accommodate reduced blade dimensions, which does little alter the overall size, which is preferably included in the size of the inertial element 4 itself. According to the invention, at least one such flexible connection 5 comprises at least one deformable compass 7. This term compass is chosen to describe in a simple way a component which is preferably in one piece, and which comprises, on either side of a compass top, deformable branches, which are fixed to different components of the oscillator; such a deformable compass is not articulated, it is in fact analogous to a dowsing rod. For the sake of simplification, the invention is illustrated with a single branch on each side of the top of the compass, but it is entirely possible to equip the deformable compass with a plurality of branches, at least on one side of its vertex, the number of branches on each side of the vertex may be different. More particularly, this deformable compass 7 comprises such an elastic blade 6 forming a first branch 8, which is arranged to be, at a first outer end 82, fixed to such a base 2, or which integral with said base 2, in particular in a monobloc version. This first branch 8 is angularly mobile, in projection on the pivot plane P, relative to another elastic blade 6 which forms a second branch 9 of the deformable compass 7. This second branch 9 is, at a second external end 94, arranged to be fixed to the inertial element 4, or is integral with the inertial element 4. The first branch 8 and the second branch 9 of each compass deformable 7 are contiguous at a cusp edge 11, which defines a virtual vertex 10 of the deformable compass 7. It is understood that the branches of this compass are deformed during oscillation. Typically particular branches, which are straight in the rest position of the oscillator take a shape substantially in an arc of a circle of variable radius during the oscillation, during which the top 10 of the deformable compass 7 is movable relative to the axis virtual pivot point D, from which it is furthest in the rest position of the oscillator 100. According to the invention, the projection on the pivot plane P of the virtual vertex 10 is on a first side of the virtual pivot axis D, opposite a second side where the first end 82 and the second are projected end 94. In sum, the geometric field swept by the elastic blades 6 during the oscillation intersects the virtual pivot axis D. More particularly, the angle formed by the projection, on the pivot plane P, of the virtual vertex 10, of the virtual pivot axis D, and of the first end 82 and / or of the second end 94, is between 160 ° and 200 °. More particularly, as visible on the executions of FIGS. 1 to 3, the projections on the pivot plane P of the first end 82 and the second end 94 are combined. More particularly still, in an unstressed rest state of the oscillator 100, the first branch 8 and the second branch 9 are symmetrical, in projection on the pivot plane P, relative to a straight line forming an axis of compass D7 joining the virtual pivot axis D and the projection of the virtual vertex 10. This projection of the virtual vertex 10 is located on a first side of the virtual pivot axis D, opposite to a second side where the first is projected end 82 and the second end 94. Each deformable compass 7 thus forms, during the operation of the oscillator 100, a vee, the branches of which are attached externally to the base and to the inertial element, and whose tip (the summit) is free. Preferably, in the rest position of the oscillator, the vee is closed, and the first branch 8 and the second branch 9 are superimposed. Preferably, the R / L ratio between on the one hand the eccentricity R of the vertex 10 relative to the virtual pivot axis D, in projection on the pivot plane P, and on the other hand the most short length L between the vertex 10 and the first end 82 or the second end 94, in projection on the pivot plane P, is between 0.12 and 0.18, or between 0.47 and 0.53. More particularly, the lengths L between the apex 10 and the first end 82 on the one hand, and the second end 94 on the other hand, in projection on the pivot plane P, are equal, as visible in FIG. 3. In particular, all the D7 compass axes of all deformable compasses 7, which have the same flexible connection 5, are combined in projection on the pivot plane P. In particular, all the compass axes D7 of all the deformable compasses 7 that comprise the flexible links 5 intersect, in projection on the pivot plane P, on the virtual pivot axis D. More particularly still, all the flexible connections 5 are identical. In particular, all the D7 compass axes of all the deformable compasses 7, which comprise the flexible links 5, are uniformly distributed angularly around the virtual pivot axis D. In a particular embodiment, at least one deformable compass 7 has elastic blades 6 straight. More particularly, all the elastic blades 6 are straight. CH 715 024 A2 Preferably, but not limited to, at least one deformable compass 7 comprises the first branch 8 in a first level P1 parallel to the pivot plane P, and the second branch 9 in a second level P2 parallel to the plane P and separate from the first level P1. It is possible to arrange this oscillator with left blades, however the complexity and the dimensions are increased, without an advantage being clearly visible. More particularly, each deformable compass 7 comprises the first branch 8 in a first level P1 parallel to the pivot plane P, and said second branch 9 in a second level P2 parallel to the pivot plane P and distinct from the first level P1. Advantageously, at least one deformable compass 7 comprises a first branch 8 and a second branch 9, the projections on the pivot plane P, in the unstressed rest state of the oscillator, are superimposed one to the other. More particularly, the projections of the first branch 8 and the second branch 9, on the pivot plane P, in the unstressed rest state of the oscillator 100, are identical to each other. In particular, and as shown in Figs. 3 and 8, at least one inertial element 4 extends, in the direction of the virtual pivot axis D, on either side of all of the flexible connections 5 by which it is suspended from the base 2 or at the bases 2, between an upper plane PS and a lower plane PI. More particularly, each inertial element 4 extends, in the direction of the virtual pivot axis D, on either side of all of the flexible connections 5 by which it is suspended from the base 2 or the bases 2. Advantageously at least one inertial element 4 does not have an axial bearing, and does not have a radial arm, relative to the virtual pivot axis D, other than the flexible connections 5 by which it is suspended from the base 2 or to the bases 2. More particularly, each inertial element 4 does not have an axial bearing, and does not have a radial arm, relative to the virtual pivot axis D, other than the flexible connections 5 by which it is suspended from the base 2 or base 2. In a particular embodiment, at least one deformable compass 7 comprises at least one intermediate flyweight, more rigid than the first branch 8 and the second branch 9, on the first branch 8 and / or on the second branch 9 and / or on the cusp edge 11. However, a weighting at the cusp edge 11 seems superfluous, the variant illustrated by the figures is limited to ensuring the mechanical junction between the first branch 8 and the second branch 9. In the advantageous embodiment of FIGS. 1,2 and 9, the oscillator 100 comprises, on the same level in the direction of the virtual pivot axis D, three identical flexible connections 5 and at 120 ° from one another. In this configuration, the ratio R / L between on the one hand the eccentricity R of the vertex 10 relative to the virtual pivot axis D, in projection on the pivot plane P, and on the other hand the shortest length L between the vertex 10 and the first end 82 or the second end 94, in projection on the pivot plane P, is between 0.12 and 0.18, or between 0.47 and 0.53. The elastic blades 6 are made of silicon and / or silicon dioxide, and each have a length of 1.00 mm, a height of 0.15 mm, a thickness of 25.8 micrometers and a value λ = R / L of -0.496. The figures illustrate different variants comprising three flexible connections thus superimposed, arranged at 120 ° in projection on the plane P: upper compass 7A with first upper branch 8A and second upper branch 9A, intermediate compass 7B with first intermediate branch 8B and second intermediate branch 9B, lower compass 7C with first lower branch 8C and second lower branch 9C. In particular, the oscillator 100 comprises, on the same level in the direction of the virtual pivot axis D, an odd number of flexible connections 5, preferably identical, to facilitate self-starting of the 'oscillator. In general, the dimensions suitable for such elastic blades 6 for watch oscillators are: length from 0.50 to 4.00 mm, a height from 0.10 to 0.50 mm, a thickness of 10 to 40 micrometers, and R / L between 0.10 and 0.20 or between 0.45 and 0.55, and more particularly between 0.12 and 0.18, or between 0.47 and 0.53. FIG. 4 illustrates a particular case where the useful lengths of the elastic blades 6 are different, the blade projections on the pivot plane P are only identical on one part, which comprises the top 10 of the compass, and extends from both sides 'other of the virtual pivot axis D defined by the flexible connections 5. One can also imagine non-symmetrical branches, for example of different thicknesses, different shapes, or other. [0045] FIG. 9 illustrates another variant where the elastic blades which constitute the flexible connections are not straight, but only symmetrical with respect to a compass axis passing through the compass top and the virtual pivot axis, in projection on the pivot plane . There is no limitation of shape, the blades could be in treble clef, or another shape allowing to develop their length, such as a hairspring, or other. Each said flexible connection 5 can be produced in silicon and / or silicon dioxide, or in at least partially amorphous material, or in DLC, or in quartz, or in similar materials. The invention also relates to a timepiece movement 200, comprising at least one such mechanical oscillator 100, and comprising a plate 3 or a bridge for fixing each base 2, which each oscillator 100 comprises. The invention also relates to a watch 300 comprising at least one such clockwork movement 200, and / or comprising at least one such mechanical oscillator 100. CH 715 024 A2 We can of course vary: - the number of flexible connections; - the number of pairs of elastic blades per flexible connection; - the angle between the elastic blades of the flexible connections, - the R / L ratio; - Weighting by adding at least one rigid part on the elastic blades. claims 1. Mechanical clock oscillator (100), comprising at least one base (2) arranged to be fixed to a plate (3) or a bridge of a clock movement (200), and at least one inertial element ( 4) arranged to oscillate about a virtual pivot axis (D) of fixed position relative to said at least one base (2) or of fixed position relative to said bases (2) when said oscillator (100) comprises several , in a pivot plane (P) perpendicular to said virtual pivot axis (D), each said inertial element (4) being suspended from at least one said base (2) by several flexible connections (5) each comprising at least one blade elastic (6) and said flexible connections (5) together defining said virtual pivot axis (D), characterized in that at least one said flexible connection (5) comprises at least one deformable compass (7) comprising a said elastic blade (6) forming a first branch (8) arranged to be re, at a first end (82), fixed to a said base (2) or integral with a said base (2), angularly movable, in projection on said pivot plane (P), relative to another said blade elastic (6) forming a second branch (9) of said deformable compass (7) which is, at a second end (94), arranged to be fixed to said inertial element (4), or integral with said inertial element (4), said first branch (8) and said second branch (9) being contiguous at a cusp edge (11) defining a virtual vertex (10) of said deformable compass (7), and characterized in that in a non-resting state constrained by said oscillator (IOO), the projection onto said pivot plane (P) of said virtual vertex (10) is on a first side of said virtual pivot axis (D), opposite to a second side where said first end projects ( 82) and said second end (94). 2. Mechanical oscillator (100) according to claim 1, characterized in that, in said unconstrained state of rest of said oscillator (IOO), the angle formed by the projection, on said pivot plane (P), of said virtual vertex (10), said virtual pivot axis (D), and said first end (82) and / or said second end (94) is between 160 ° and 200 °. 3. Mechanical oscillator (100) according to claim 1 or 2, characterized in that, in said unconstrained state of rest of said oscillator (IOO), the projections on said pivot plane (P) of said first end (82) and of said second end (94) are combined. 4. Mechanical oscillator (100) according to one of claims 1 to 3, characterized in that said first branch (8) and said second branch (9) are symmetrical, in projection on said pivot plane (P), relative to a straight line forming a compass axis (D7) joining said virtual pivot axis (D) and the projection of said virtual vertex (10). 5. Mechanical oscillator (100) according to one of claims 1 to 4, characterized in that the R / L ratio between on the one hand the eccentricity R of said vertex (10) relative to said virtual pivot axis (D) , in projection on said pivot plane (P), and on the other hand the shortest length L between said vertex (10) and said first end (82) or said second end (94), in projection on said pivot plane (P), is between 0.12 and 0.18, or between 0.47 and 0.53. 6. Mechanical oscillator (100) according to claim 4 and according to any one of claims 1 to 5, characterized in that all of said compass axes (D7) of all said deformable compasses (7), which has the same connection flexible (5), coincide in projection on said pivot plane (P). 7. Mechanical oscillator (100) according to claim 4 and according to any one of claims 1 to 6, characterized in that all of said compass axes (D7) of all of said deformable compasses (7) that comprise said flexible connections (5 ) intersect, in projection on said pivot plane (P), on said virtual pivot axis (D). 8. Mechanical oscillator (100) according to one of claims! to 7, characterized in that all of said flexible connections (5) are identical. 9. Mechanical oscillator (100) according to claim 4 and according to any one of claims 1 to 8, characterized in that all of said compass axes (D7) of all of said deformable compasses (7) that comprise said flexible connections (5 ) are uniformly distributed angularly around said virtual pivot axis (D). 10. Mechanical oscillator (100) according to any one of claims 1 to 9, characterized in that at least one said deformable compass (7) comprises said elastic blades (6) which are straight in said state of unconstrained rest of said oscillator ^ 00). 11. Mechanical oscillator (100) according to claim 10, characterized in that all of said elastic blades (6) are straight. CH 715 024 A2 12. Mechanical oscillator (100) according to one of claims 1 to 11, characterized in that at least one said deformable compass (7) comprises said first branch (8) in a first level (P1) parallel to said pivot plane (P), and said second branch (9) in a second level (P2) parallel to said pivot plane (P) and distinct from said first level (P1). 13. Mechanical oscillator (100) according to claim 12, characterized in that each said deformable compass (7) comprises said first branch (8) in a first level (P1) parallel to said pivot plane (P), and said second branch (9) in a second level (P2) parallel to said pivot plane (P) and distinct from said first level (P1). 14. Mechanical oscillator (100) according to one of claims 1 to 13, characterized in that at least one said deformable compass (7) comprises said first branch (8) and said second branch (9) whose projections on said pivot plane (P), in said unstressed rest state of said oscillator (IOO), are superimposed on each other. 15. Mechanical oscillator (100) according to claim 14, characterized in that said projections of said first branch (8) and said second branch (9) of each deformable compass (7), on said pivot plane (P), in said unstressed rest state of said oscillator (IOO), are identical to each other. 16. Mechanical oscillator (100) according to claim 14 or 15, characterized in that each said deformable compass (7) comprises said first branch (8) and said second branch (9) whose projections on said pivot plane (P) , in said unstressed rest state of said oscillator (IOO), are superimposed or identical to each other. 17. Mechanical oscillator (100) according to one of claims 1 to 16, characterized in that at least one said deformable compass (7) comprises said first branch (8) which is more rigid than said second branch (9), and less rigid than said inertial element (4) fixed at its second end (74). 18. Mechanical oscillator (100) according to claim 17, characterized in that each said deformable compass (7) comprises said first branch (8) which is more rigid than said second branch (9), and less rigid than said inertial element ( 4) fixed at its second end (74). 19. Mechanical oscillator (100) according to one of claims 1 to 16, characterized in that at least one said deformable compass (7) comprises said first branch (8) which is as rigid as said second branch (9) and has the same elastic characteristics, and which is less rigid than said inertial element (4) fixed at its second end (74). 20. Mechanical oscillator (100) according to claim 19, characterized in that each said deformable compass (7) comprises said first branch (8) which is as rigid as said second branch (9) and has the same elastic characteristics, and which is less rigid than said inertial element (4) fixed at its second end (74). 21. Mechanical oscillator (100) according to one of claims 1 to 20, characterized in that at least one said inertial element (4) extends, in the direction of said virtual pivot axis (D), from both other of all of said flexible connections (5) by which it is suspended from said base (2) or said bases (2). 22. Mechanical oscillator (100) according to one of claims 1 to 21, characterized in that each said inertial element (4) extends, in the direction of said virtual pivot axis (D), on both sides of all of said flexible connections (5) by which it is suspended from said base (2) or said bases (2). 23. Mechanical oscillator (100) according to one of claims 1 to 22, characterized in that at least one said inertial element (4) is devoid of axial bearing, and is devoid of radial arm, relative to said pivot axis virtual (D), other than said flexible connections (5) by which it is suspended from said base (2) or said bases (2). 24. Mechanical oscillator (100) according to one of claims 1 to 23, characterized in that each said inertial element) (4) is devoid of axial bearing, and is devoid of radial arm, with respect to said virtual pivot axis ( D), other than said flexible connections (5) by which it is suspended from said base (2) or said bases (2). 25. Mechanical oscillator (100) according to one of claims 1 to 24, characterized in that at least one said deformable compass (7) comprises at least one intermediate flyweight, more rigid than said first branch (8) and said second branch (9), on said first branch (8) and / or on said second branch (9) and / or on said cusp edge (11). 26. Mechanical oscillator (100) according to one of claims 1 to 25, characterized in that said oscillator (100) comprises, on the same level in the direction of said virtual pivot axis (D), three said flexible connections (5 ) identical and 120 ° from each other. 27. Mechanical oscillator (100) according to one of claims 1 to 26, characterized in that each said flexible connection (5) is made of silicon and / or silicon dioxide, or of at least partially amorphous material, or of DLC, or quartz. 28. Clock movement (200), comprising at least one mechanical oscillator (100) according to one of claims 1 to 26, and comprising a plate (3) or a bridge for fixing each said base (2), that each said oscillator (100) comprises. CH 715 024 A2 29. Watch (300) comprising at least one clockwork movement (200) according to claim 27, and / or comprising at least one mechanical oscillator (100) according to one of claims 1 to 26. CH 715 024 A2 CH 715 024 A2