CH717822A2 - Clockwork micro-generator rotor. - Google Patents

Abstract

The invention relates to a rotor (100) of a micro-generator (1000), comprising an alternation of magnets (110) of alternating polarities arranged to successively face the front end (211) of a coil (210) of stator (200) to induce an alternating voltage at the terminals of the coil (210) during the relative rotation of the rotor (100) with respect to the stator (200), these magnets (110) are separated two by two by channels devoid of magnetization, which channels each extend on either side of a radial plane (PR) passing through the generatrix axis (D), and the magnetic fields emitted by these magnets (110) in the direction of said axis (D) are concentrated in a prismatic volume of annular section. The invention relates to a microgenerator comprising such a rotor and to a watch comprising such a microgenerator.

Description

Field of the invention

The invention relates to a micro-generator rotor, arranged to cooperate with at least one stator coil that includes at least one stator that includes said micro-generator, said rotor being arranged to pivot around a parallel generator axis and eccentric with respect to the axis of said coil, said rotor comprising, on at least one face arranged to face a front end of said coil, magnets of an even number, which have alternating polarities facing a said stator facing this said rotor from which it is separated by an air gap, and which are arranged to successively face said front end of a said coil to induce an alternating voltage at the terminals of said coil during the relative rotation of said rotor by report to said stator.

The invention relates to a micro-generator comprising at least one such rotor.

The invention also relates to a timepiece, in particular a watch, comprising at least one such micro-generator or at least one such rotor.

Background of the invention

[0004] The production of multipolar micro-generators used in the watchmaking field (movement) uses toroidal magnets with sectorial magnetization, or discrete cylindrical magnets.

[0005] The production of toroidal magnets in the required dimensions is complex and the sectorial magnetization can lead to losses. In particular, the production of edges with a sharp angle or a very small radius is difficult, and often results in scratches leading to the scrapping of the component.

[0006] In the case of the use of discrete magnets, the intensity of the magnetic coupling depends in particular on the volume of the magnets.

Summary of the invention

The invention proposes to produce micro-generator rotors that are both efficient, compact, and whose manufacture can be controlled.

To this end, the invention relates to a micro-generator rotor according to claim 1.

The invention relates to a micro-generator comprising at least one such rotor.

The invention also relates to a timepiece, in particular a watch, comprising at least one such micro-generator or at least one such rotor.

[0011] The use of discrete magnets of elliptical or trapezoidal shape makes it possible to optimize the volume of the magnet while maintaining reduced dimensions.

For economic reasons, the use of sintered discrete magnets is advantageous, and the geometries proposed by the invention allow a good compromise between performance and production cost.

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 appended drawings, where: FIG. 1 represents, schematically, partially, and in perspective, a micro-generator comprising two rotors according to the invention, coaxial and cooperating with a stator carrying two coils; these rotors carry elliptical magnets, which are separated by radial channels devoid of magnetization; FIG. 2 represents, in a manner similar to FIG. 1, a rotor assembly of another micro-generator similar to that of FIG. 1, and where each rotor carries magnets each inscribed in a ring and comprising rounded areas between two faces cylindrical, and two substantially straight and radial faces, between which extend radial channels devoid of magnetization; Fig. 3 is a cross-sectional view, passing through the generator axis, of the micro-generator of Fig. 1, where a rotor shaft has a cutout for cooperation with a drive board of a drive mechanism external, this board, visible in the right part of Figure 3, not being shown in Figure 1 to show the magnets, the coils and the cut shaft; FIG. 4 represents, similarly to FIG. 3, the rotor assembly of the micro-generator of FIG. 1, with its elliptical magnets on the rotors; FIG. 5 represents, schematically and in perspective, one of the rotors of the micro-generator of FIG. 3; Figure 6 is a plan view of the rotor of Figure 5; Figure 7 is a plan view of another rotor, similar to the rotor of Figure 5, and whose magnets are annular sectors; FIG. 8 is a plan view illustrating the sections of three types of magnets that can be used for rotors: circular, elliptical, in an annular sector with large junction radii between the flat and cylindrical faces; FIG. 9 represents, schematically and in perspective, one of the rotors of the micro-generator of FIG. 1, with elliptical lovers; Figure 10 is a sectional view, passing through the generatrix axis, of the rotor of Figure 9; Figure 11 is a plan view of the rotor of Figure 9, showing the alternation of polarities; FIG. 12 is a plan view illustrating three variants of the rotor of FIG. 9, according to the orientation of the major axis of the ellipse with respect to a perpendicular to the radial passing through the center of gravity of the magnet: 0°, 20°, 40°; Figure 13 is a top view of the micro-generator of Figure 1, shown in its complete configuration, with the two coils arranged at 120°, and the drive board of Figure 3.

Detailed Description of Preferred Embodiments

The invention relates to a rotor 100 of micro-generator 1000, which is arranged to cooperate with at least one stator coil 210, which comprises at least one stator 200 which comprises the micro-generator 1000.

This rotor 100 being arranged to pivot about a generatrix axis D, which is parallel and eccentric with respect to the axis of the coil 210. The rotor 100 comprises, on at least one face 101 arranged to face at a front end 211 of a coil 210, magnets 110 in an even number, which have alternating polarities facing such a stator 200 facing this rotor 100 from which it is separated by an air gap 300. These magnets 110 are arranged to successively face the front end 211 of a coil 210 to induce an alternating voltage across the terminals of the coil 210 during the relative rotation of the rotor 100 with respect to the stator 200.

According to the invention, the magnets 110 are separated two by two by channels 120 devoid of magnetization, which channels 120 each extend on either side of a radial plane PR passing through the axis of generatrix D. And the magnetic fields emitted by the magnets 110 along the direction of the axis of generatrix D are concentrated in a prismatic volume of annular section.

More particularly, the rotor 100 comprises magnets 110 which are angular sectors of annular prisms of revolution around the generatrix axis D.

More particularly, on at least one face 101, all the magnets 110 that comprise the rotor 100, on the side of the air gap 300 at the same distance from the generatrix axis D, are angular sectors of annular prisms of revolution around the generatrix axis D.

More particularly, the rotor 100 comprises magnets 110 of elliptical section with an eccentricity different from 1. More particularly, on at least one face 101, all the magnets 110 that the rotor 100 comprises on the side of the the same distance from the generatrix axis D are magnets 110 of elliptical section.

Alternatively, all the magnets 110 of elliptical section have their major axis perpendicular to the radial coming from the generatrix axis D and passing through the intersection of the major axis and their minor axis.

In another variant, all the magnets 110 of elliptical section have their major axis inclined with respect to the radial coming from the generatrix axis D and passing through the intersection of the major axis and their minor axis.

More particularly, all the magnets 110 that the rotor 100 has on at least one of two parallel faces that the rotor 100 has are identical.

More particularly, the rotor 100 comprises at least one circular flange 102, with a thickness between 0.1 mm and 0.3 mm, with an outer radius Rflasque between 1.5 mm and 5 mm, carried by at least one shaft of lower radius Rarbor or equal to 1.5 mm, and of total length between 0.5 mm and 3 mm.

More particularly, the rotor 100 comprises a plurality of such circular flanges 102, carried by a common shaft or by concentric shafts, at the rate of one shaft per flange, each shaft having a total radius Rarbre less than or equal to 1.5 mm .

More particularly, the total length of the common shaft, or of all the concentric shafts, is between 0.5 and 3 mm.

More particularly, the concentric shafts are free to rotate relative to each other.

[0027] More specifically, the common shaft, or one of the concentric shafts, depending on the configuration selected, comprises a cutting 191, which is arranged to allow coupling to an external accelerator cog via a drive plate 190 passing between two adjacent flanges 102. More particularly, this drive board 190 occupies an angular sector Splanche in the air gap between the neighboring flanges 102, centered on their axis of rotation. This angular sector Splanche is limited by the size of the coils 210, when the coils 210 and this drive board 190 are located at the same plane perpendicular to the generatrix axis D, as visible in Figure 13 where the micro-generator 1000 comprises two coils 210, arranged, in a non-limiting manner, at an angle at the top of approximately 120° with respect to the axis of the generator D.

More particularly, at least one face 101 of a circular flange 102 carries at least one pair of magnets 110, of any shape and identical to each other, of thickness between 0.1 mm and 1 mm and arranged angularly on the flange 102, and whose radial positioning Raimant on the flange 102 of the center of gravity (or of the geometric center) of the magnets 110 is arbitrary and included between the radii Rshaft and Rflask, the maximum external dimensions of the magnets 110 being included between the radii Rshaft and Flask.

The invention also relates to a micro-generator 1000, which comprises, coaxial with a generator axis D, at least one such rotor 100, comprising on each face magnets 110 in an even number, and at least one stator 200 comprising at least one coil 210 with an axis parallel and eccentric with respect to the generatrix axis D.

More particularly, a stator 200 comprises at least one coil 210 with an axis parallel to the generatrix axis D which is the axis of rotation of the rotor, and with an outer radius Rbobine of between 0.5 mm and 4 mm; more particularly, this coil 210 is made with insulated and heat-adhesive copper wire with a diameter less than or equal to 50 micrometers.

More particularly, the coil 210 has an Ecoil thickness allowing its insertion between two flanges 102 adjacent to the rotor 100, at a distance from each of them.

More particularly, the inner radius Rbobineint of the coil windings 210 is between 0.2 mm and 2 mm.

More specifically, a stator 200 comprises a single support, which is arranged to hold each coil 210 in the same plane perpendicular to the generatrix axis D, in the air gap between two adjacent flanges of the rotor 100. More particularly, this support which is arranged to allow them to be positioned angularly on a sector Ssupport equal to the complement to 360° of the angle Splanche in order to leave enough room for the drive board 190 in the air gap.

More specifically, the support is arranged to allow radial positioning of the center of each coil 210 relative to the generatrix axis D on a radius Rsupport between + 2 mm and - 2 mm relative to a radius Raimant traveled by the center of gravity of the magnets 110.

More particularly, the magnetic fields emitted by the magnets 110 along the direction of the generatrix axis D are concentrated in a prismatic volume of annular section whose smallest diameter and largest diameter are defined by the minimum radial footprints and maximum of the coils 210 that the stator 200 has.

More specifically, each coil 210 is arranged to cooperate, on either side in a direction parallel to the generatrix axis D, with two rotors 100 indexed relative to each other, and whose contours of the magnets 110 that they comprise are superimposed in projection on a plane perpendicular to the generatrix axis D.

In a particular embodiment, the micro-generator 1000 comprises a single coil 210.

In another particular embodiment, and as shown in the figures, the micro-generator 1000 comprises at least two coils 210 per level.

More particularly, at least one rotor 100 is driven in rotation by an energy storage barrel.

[0040] More particularly, at least one rotor 100 is driven in rotation by a wheel set of a mechanical clockwork movement.

[0041] More particularly, at least one rotor 100 is driven in rotation by the inertial mass of a mechanical resonator 500. synchronous one rotor 100.

[0042] More specifically, at least one rotor 100 is driven in rotation by an escape wheel set 610 that includes an escapement mechanism 600 cooperating with a mechanical resonator 500, or by a wheel set driven by the escape wheel set 610 at the through a 620 cog.

More particularly, the rotors 100 that the micro-generator 1000 includes are rotationally synchronous.

More particularly, the rotors 100 that the micro-generator 1000 includes are mechanically linked.

[0045] More specifically, each coil 210 comprises a winding on a prismatic structure whose section is, or else an annular sector, the smallest diameter and the largest diameter of which are defined by the minimum and maximum radial grips of the coils 210 that the stator 200, or else is a trapezium whose two parallel faces are perpendicular to a radial coming from the generatrix axis D at radii substantially equal to the radial values of the minimum and maximum radial grips of the coils 210 that the stator 200 comprises.

More specifically, the micro-generator 1000 is a timepiece micro-generator arranged to be integrated into a watch.

The invention also relates to a timepiece, in particular a watch 2000 comprising at least one such micro-generator 1000, and/or at least one such rotor 100.

Claims (33)

1. Rotor (100) of micro-generator (1000), arranged to cooperate with at least one stator coil (210) that comprises at least one stator (200) that comprises said micro-generator (1000), said rotor (100) being arranged to pivot about a generatrix axis (D) parallel and eccentric with respect to the axis of said coil (210), said rotor (100) comprising, on at least one face (101) arranged to face a front end (211) of a said coil (210), magnets (110) in an even number, which have alternating polarities facing a said stator (200) facing this said rotor (100) from which it is separated by an air gap (300), and which are arranged to successively face said front end (211) of a said coil (210) to induce an alternating voltage across the terminals of said coil (210) during the relative rotation of said rotor (100) relative to said stator (200), characterized in that said magnets (110) are separated two by two by channels (120) d devoid of magnetization, which channels (120) each extend on either side of a radial plane (PR) passing through said generatrix axis (D), and in that the magnetic fields emitted by said magnets ( 110) along the direction of said generatrix axis (D) are concentrated in a prismatic volume of annular section. 2. Rotor (100) according to claim 1, characterized in that said rotor (100) comprises said magnets (110) which are angular sectors of annular prisms of revolution around said generatrix axis (D). 3. Rotor (100) according to claim 2, characterized in that, on at least one said face (101), all said magnets (110) that said rotor (100) includes on the side of said gap (300) at the same distance from said generatrix axis (D) are said angular sectors of annular prisms of revolution around said generatrix axis (D). 4. Rotor (100) according to claim 1, characterized in that said rotor (100) comprises said magnets (110) of elliptical section with an eccentricity different from 1. 5. Rotor (100) according to claim 4, characterized in that, on at least one said face (101), all said magnets (110) that said rotor (100) comprises on the side of said gap (300) at the same distance from said generatrix axis (D) are said magnets (110) of elliptical section. 6. Rotor (100) according to claim 4 or 5, characterized in that all said magnets (110) of elliptical section have their major axis perpendicular to the radial from said generatrix axis (D) and passing through the intersection of said major axis and their minor axis. 7. Rotor (100) according to claim 4 or 5, characterized in that all said magnets (110) of elliptical section have their major axis inclined relative to the radial coming from said generatrix axis (D) and passing through the crossing said major axis and their minor axis. 8. Rotor (100) according to one of claims 1 to 7, characterized in that all said magnets (110) that said rotor (100) has on at least one of two parallel faces that said rotor (100) has are identical. 9. Rotor (100) according to one of claims 1 to 8, characterized in that said rotor (100) comprises at least one flange (102) circular, of thickness between 0.1 mm and 0.3mm, of outer radius Rflasque between 1.5 mm and 5 mm, carried by at least one shaft of radius Rshaft less than or equal to 1.5 mm, and of total length between 0.5 mm and 3 mm. 10. Rotor (100) according to claim 9, characterized in that said rotor (100) comprises a plurality of said circular flanges (102), carried on a common shaft or by concentric shafts, at the rate of one shaft per flange, each said shaft having a total radius Rshaft less than or equal to 1.5 mm. 11. Rotor (100) according to claim 10, characterized in that the total length of said common shaft or of all of said concentric shafts is between 0.5 mm and 3 mm. 12. Rotor (100) according to claim 10 or 11, characterized in that said concentric shafts are free to rotate relative to each other. 13. Rotor (100) according to one of claims 10 to 12, characterized in that said common shaft or one of said concentric shafts comprises a cutting arranged to allow coupling to an external accelerator cog via a drive plate (190) passing between two said flanges (102). 14. Rotor (100) according to one of claims 9 to 13, characterized in that at least one said face (101) of said circular flange (102) carries at least one pair of said magnets (110), any shape and identical to each other, with a thickness between 0.1 mm and 1 mm and arranged angularly on said flange (102), and whose radial positioning Raimant on said flange (102) of the center of gravity or the geometric center of said magnets (110 ) is arbitrary and included between said radii Rshaft and Rflask, the maximum external dimensions of said magnets (110) being between said radii Rshaft and Rflask. 15. Micro-generator (1000), comprising, coaxial with a generator axis (D), at least one rotor (100) according to one of claims 1 to 14, comprising on each face magnets (110) in even number, and at least one stator (200) comprising at least one coil (210) with an axis parallel and eccentric with respect to said generatrix axis (D). 16. Micro-generator (1000) according to claim 15, characterized in that said stator (200) comprises at least one said coil (210) with an axis parallel to said generator axis (D) which is the axis of rotation of the rotor, and with an external radius Rcoil between 0.5 mm and 4 mm, made with insulated and heat-adhesive copper wire with a diameter less than or equal to 50 micrometers. 17. Micro-generator (1000) according to claim 15, comprising a rotor (100) according to claim 10 or a claim dependent on claim 10, characterized in that said coil (210) has an Ecoil thickness allowing its insertion between two flanges (102) adjacent to said rotor (100), at a distance from each of them. 18. Micro-generator (1000) according to claim 16 or 17, characterized in that the inner radius Rbobineint of the windings of said coil (210) is between 0.2mm and 2mm. 19. Micro-generator (1000) according to one of claims 15 to 18, comprising a rotor (100) according to claim 13 or a claim dependent on claim 13, characterized in that a said stator (200) comprises a single support holding each said coil (210) in the same plane perpendicular to said generatrix axis (D), in the air gap between two said neighboring flanges of said rotor (100). 20. Micro-generator (1000) according to claim 18, characterized in that said support is arranged to allow radial positioning of the center of each said coil (210) relative to said generator axis (D) on a radius Rsupport between + 2 mm and - 2 mm with respect to a Raimant radius traversed by the center of gravity of said magnets (110). 21. Micro-generator (1000) according to one of claims 15 to 20, characterized in that the magnetic fields emitted by said magnets (110) in the direction of said generator axis (D) are concentrated in a said prismatic volume of annular section whose smallest diameter and largest diameter are defined by the minimum and maximum radial footprints of said coils (210) that comprises said stator (200). 22. Micro-generator (1000) according to one of claims 15 to 20, characterized in that each said coil (210) is arranged to cooperate, on either side in a direction parallel to said generator axis (D) , with two said rotors (100) indexed relative to each other, and whose contours of said magnets (110) that they comprise are superimposed in projection on a plane perpendicular to said generatrix axis (D). 23. Micro-generator (1000) according to one of claims 15 to 22, characterized in that it comprises a said coil (210) single. 24. Micro-generator (1000) according to one of claims 15 to 23, characterized in that at least one said rotor (100) is driven in rotation by an energy storage barrel. 25. Micro-generator (1000) according to one of claims 15 to 23, characterized in that at least one said rotor (100) is driven in rotation by a wheel set of a mechanical clockwork movement. 26. Micro-generator (1000) according to claim 25, characterized in that at least one said rotor (100) is rotated by the inertial mass of a mechanical resonator (500). 27. Micro-generator (1000) according to claim 26, characterized in that said mechanical resonator (500) is a balance-spring, one balance (510) of which is arranged to synchronously drive said rotor (100). 28. Micro-generator (1000) according to claim 25, characterized in that at least one said rotor (100) is driven in rotation by an escape wheel set (610) which comprises an escape mechanism (600) cooperating with a mechanical resonator (500), or by a mobile driven by said escapement mobile (610) through a gear train (620). 29. Micro-generator (1000) according to one of claims 15 to 28, characterized in that said rotors (100) which it comprises are synchronous in rotation. 30. Micro-generator (1000) according to claim 29, characterized in that said rotors (100) which it comprises are mechanically linked. 31. Micro-generator (1000) according to one of claims 15 to 30, characterized in that each said coil (210) comprises a winding on a prismatic structure whose section is an annular sector whose smallest diameter and largest large diameter are defined by the minimum and maximum radial footprints of said coils (210) that said stator (200) comprises, where is a trapezium whose two parallel faces are perpendicular to a radial coming from said generatrix axis (D) at substantially equal radii to the radial values of said minimum and maximum radial footprints of said coils (210) that said stator (200) comprises. 32. Micro-generator (1000) according to one of claims 15 to 30, characterized in that said micro-generator (1000) is a timepiece micro-generator arranged to be integrated into a watch. 33. Watch (2000) comprising at least one micro-generator (1000) according to one of claims 15 to 32.