CH717735A2 - Mechanism, for example watch mechanism, provided with a magnetic gear. - Google Patents

Abstract

The invention relates to a mechanism, for example a watch mechanism, comprising a magnetic gear (3) formed by a first wheel (4) and a second wheel (6), the first wheel being provided with first alternating magnetic poles forming a magnetic toothing (9) and the second wheel being provided with a toothing (7) of ferromagnetic material which has a magnetic coupling with the magnetic toothing so that, when one of the first and second wheels is driven in rotation, this wheel (4) rolls, via the magnetic coupling, on a geometric circle centered on the other wheel (6) and linked to this other wheel. The magnetic gear further comprises a ferromagnetic element (12) arranged relative to the first wheel so as to compensate for at least a major part of a torque of parasitic magnetic force which this first wheel undergoes and resulting from said magnetic coupling, this torque of parasitic magnetic force having a periodic intensity variation depending on the angular position of the first wheel.

Description

Technical field of the invention

The invention relates to the field of magnetic gears formed of a first wheel and a second wheel in magnetic mesh relationship, the first wheel being provided with first magnetic poles arranged circularly and defining a first magnetic toothing, the second wheel being provided with teeth made of ferromagnetic material or with second magnetic poles, these teeth or second magnetic poles being arranged circularly and defining a second magnetic toothing.

[0002] In particular, the invention relates to a timepiece mechanism incorporating a magnetic gear.

Technology background

[0003] Figure 1 shows a magnetic gear 2 comprising a small wheel 4 provided with six bipolar magnets 8 having a radial and alternating magnetization, these six magnets being arranged regularly around a central part of the small wheel so as to define a magnetic toothing 9 having six magnetic teeth, and a large wheel 6 located in a general plane in which the small wheel also extends and comprising a ferromagnetic rim with a peripheral toothing 7. The wheel 4 has a central axis 32 defining an axis of rotation of this small wheel and the wheel 6 has a central axis 34. In a general case where the large wheel also rotates, the central axis 34 defines an axis of rotation of this large wheel. In a particular case, the large wheel is arranged fixedly on a support (plate or bridge of a watch movement) and the small wheel is arranged so as to turn on the periphery of the large wheel when this small wheel is driven in rotation by a motor device.

[0004] Figure 2 gives a curve 10 of a couple of parasitic magnetic force which is exerted on the small wheel 4 when it turns and "rolls" on a geometric circle linked to the large wheel 6 and centered on the central axis 34 of the latter. This pair of parasitic magnetic force presents a periodic intensity variation as a function of the angular position α of the small wheel 4. The angle α is measured from a reference half-axis 30 starting from the axis of rotation 32 of the small wheel and intercepting the central axis / the axis of rotation of the large wheel 6. By definition, the semi-axis of reference 30 is perpendicular to the axis of rotation of the small wheel 4. As shown in Figure 2 , the period of the sinusoidal curve 10 corresponds to the angle at the center between two successive bipolar magnets and therefore to the angle traveled by the small wheel for the magnetic gear 2 to take a step, that is to say that the small wheel 4 rotates so as to pass from a bipolar magnet (defining a magnetic tooth or, by analogy to a conventional mechanical gear, corresponding to a hollow between two magnetic teeth) aligned on the reference semi-axis 30 to a magnet next bipolar (defining a next magnetic tooth or u n following hollow between two magnetic teeth) which in turn aligns itself with this reference semi-axis and that, at the same time, the large wheel 6 rotates (or the axis of rotation of the small wheel rotates around the central axis 34 of the large wheel) so as to pass from one tooth aligned on the reference semi-axis to a following tooth which in turn is aligned on this reference semi-axis. It will be noted that the large wheel also experiences a corresponding parasitic magnetic force torque. For reasons related to the clarity of the drawing, the angle of rotation / the angular position represented in Figure 1 by an arrow is measured from a semi-axis complementary to the reference semi-axis 30 (these two half-axis axes together forming a geometric axis) and therefore corresponds to α-180°. Point A in FIG. 2 corresponds to an angle α equal to zero or to an integer multiple of 360°/N, with N equal to the number of bipolar magnets 8 and therefore to the number of magnetic teeth of the magnetic toothing 9. L The angle 360°/N thus corresponds to an angular period or an angular pitch of the magnetic toothing 9.

The angular positions of the magnetic gear 2 at points A and E, on the graph of Figure 2, correspond to positions of stable equilibrium for this magnetic gear, while the angular position of this magnetic gear at point C corresponds to an unstable equilibrium position. Points B and D, on the graph of FIG. 2, correspond to the two maximum intensities (respectively positive and negative) and therefore to the amplitude of the couple of parasitic magnetic force. It will be noted that the parasitic magnetic force torque occurs in the absence of transmission of a force torque between the two wheels, this parasitic magnetic force torque tending to bring a bipolar magnet 8 in front of a tooth made of ferromagnetic material of the wheel 6 and therefore to align on the reference semi-axle 30 a magnetic pole of the wheel 4 and a ferromagnetic tooth of the wheel 6 (situation at points A and E of the curve 10), the angular positions of the two wheels corresponding then at a minimum potential energy for the magnetic gear.

[0006] The parasitic magnetic force torque (also called hereafter 'parasitic magnetic torque') can be significant, possibly as great (or even greater) than the magnetic force torque that can be transmitted between the two wheels of the magnetic gear. To overcome this disturbing torque, a motor device driving one of the two wheels must be able to supply a force torque much greater than the magnetic force torque transmitted in the magnetic gear to prevent it from blocking, which unnecessarily increases its energy consumption. In addition, because of its sinusoidal variation, the disturbing torque introduces a relatively large variation in the magnetic force torque transmitted in the magnetic gear. Indeed, when the small wheel 4 is driven in a positive direction of rotation, the disturbing torque brakes this small wheel during a first angular half-period of the magnetic toothing 9, from each position of alignment of a bipolar magnet 8 on the reference half-axis 30, and drives this small wheel during the second angular half-period following this first angular half-period (see FIG. 2). The same goes for the large wheel 6 over each magnetic period of its magnetic toothing 7, with an inversion of the mathematical sign.

Summary of the invention

The object of the invention is to overcome the problem of the parasitic magnetic force torque in a magnetic gear, by eliminating at least a major part of this disturbing torque.

To this end, the present invention relates to a mechanism comprising a magnetic gear formed of a first wheel and a second wheel, the first wheel being provided with N first alternating magnetic poles which are arranged circularly and define a first toothing magnetic, the second wheel being provided with teeth made of ferromagnetic material or with second alternating magnetic poles and arranged circularly, these teeth or these second magnetic poles defining a second magnetic toothing which has a magnetic coupling with the first magnetic toothing so that, when one of the first and second wheels is driven in rotation, this wheel rolls, via the magnetic coupling, on a geometric circle centered on the other wheel and linked to this other wheel. According to the invention, the mechanism further comprises a ferromagnetic element or a set of ferromagnetic elements arranged relative to the first wheel so as to compensate for at least a major part of a parasitic magnetic torque that this first wheel undergoes and resulting from said coupling magnetic, this parasitic magnetic torque having a periodic intensity variation as a function of the angular position of the first wheel relative to a reference half-axis starting from the central axis of the first wheel and intercepting the central axis of the second wheel.

[0009] It will be noted that the rolling of one of the two wheels on a geometric circle centered on the other wheel and linked to this other wheel takes place without mechanical contact, said geometric circle having a radius which depends on the angular pitches of each of the two wheels and the distance between the respective central axes of these two wheels. By 'magnetic torque' is meant a torque of magnetic force.

[0010] According to a main embodiment, the ferromagnetic element or the set of ferromagnetic elements is arranged so as to generate a compensating magnetic torque which also has a periodic intensity variation as a function of the angular position of the first wheel relative to the reference half-axis, the compensation magnetic torque and the parasitic magnetic torque having a phase shift of substantially 180°.

According to an advantageous variant, the ferromagnetic element or the set of ferromagnetic elements has a plane of symmetry comprising the reference semi-axis and the central axis of the first wheel.

[0012]According to an advantageous variant, the ferromagnetic element or the set of ferromagnetic elements is arranged so as to generate globally on the first wheel a compensation magnetic attraction force which is aligned on the reference semi-axis with a direction opposite to that of an overall magnetic attraction force exerted by the second wheel on the first wheel.

Brief description of figures

The invention will be described below in detail using the accompanying drawings, given by way of non-limiting examples, in which: Figure 1, already described, shows a magnetic gear according to the prior art. Figure 2, already described, graphically represents a parasitic magnetic torque occurring in the magnetic gear of Figure 1. Figure 3 shows a first embodiment of a mechanism incorporating a magnetic gear according to the invention (only the magnetic gear being shown). Figure 4 graphically represents a compensating magnetic torque, generated by an additional ferromagnetic element, intervening in the magnetic gear of Figure 3. Figure 5 graphically represents residual parasitic magnetic torque in the magnetic gear of Figure 3. Figure 6 shows a first variant of the first embodiment according to the invention. Figure 7 shows a second variant of the first embodiment according to the invention. Figure 8 shows a second embodiment of a mechanism incorporating a magnetic gear according to the invention (only the magnetic gear being shown).

Detailed description of the invention

With reference to Figures 3 to 7, a first embodiment of a magnetic gear according to the invention will be described below.

[0015] In a first variant, shown in FIGS. 3 to 5, the magnetic gear 3 is formed of a first wheel 4 and a second wheel 6 already described with reference to Figure 1. In general, the first wheel is provided with N alternating first magnetic poles which are arranged circularly and define a first magnetic toothing. In the variant considered, the first wheel 4 comprises six bipolar magnets having radial magnetization, the six outer magnetic poles forming a first magnetic toothing 9. As the magnetic poles are arranged in a circular manner with alternating polarization, their number is an even number. . In general, the second wheel is provided with teeth made of ferromagnetic material or with second magnetic poles alternated and arranged circularly, these teeth or these second magnetic poles defining a second magnetic toothing which has a magnetic coupling with the first magnetic toothing so that, when one of the first and second wheels is driven in rotation, this wheel rolls, via the magnetic coupling, on a geometric circle centered on the other wheel and linked to this other wheel. In the variant considered, the second wheel 6 comprises a rim of ferromagnetic material defining at its outer periphery teeth which form a second magnetic toothing 7. The two wheels 4 and 6 extend in the same general plane and are arranged so that their magnetic teeth do not touch. The parasitic magnetic torque occurring between the two wheels 4 and 6 has already been presented previously with reference to Figure 2.

To compensate for the aforementioned parasitic magnetic torque, the magnetic gear 3 further comprises a ferromagnetic element 12 arranged relative to the first wheel 4 so as to compensate and therefore cancel at least a major part of this parasitic magnetic torque (curve 10 in Fig.2) that this first wheel undergoes and resulting from the magnetic coupling between the two wheels 4 and 6.

The ferromagnetic element 12 is preferably arranged in the general plane of the two wheels of the magnetic gear 3. This ferromagnetic element comprises two end parts 13 and 14 which extend in the direction of the first toothing 9 of the wheel 4, the first end part 14 being located at an angular position equal to 90° while the second end part is located at an angular position equal to 270°. In general, each of the end parts is positioned at an angle, relative to the reference semi-axis (30), the value of which is equal to (M-1/2)-360°/N with M being a number integer greater than '1' and less than N. It will be noted that, in a more complex variant, other projecting parts, in addition to the two end parts, can be provided, each being positioned at a different angle among the plurality of angles defined by the value M between '1' and N in the above mathematical formula. An intermediate part 12A connects the two end parts. This intermediate part has the shape of a semi-circle which extends in the general plane of the wheel 4, on the side opposite the wheel 6. It will be noted that this intermediate part generates a weak magnetic torque on the wheel 4, much lower than the parasitic magnetic torque generated by wheel 6 and to the compensation magnetic torque generated globally by ferromagnetic element 12 and mainly by the two end parts 13 and 14 which are arranged re-entrant in the direction of toothing 9 of wheel 4, relatively to the circle defined by the intermediate part, and therefore have a radial orientation.

The ferromagnetic element 12 is arranged so as to generate a compensating magnetic torque 18, represented by a curve in Figure 4, having a periodic intensity variation, of the same period as the periodic intensity variation of the torque parasitic magnetic torque, as a function of the angular position α of wheel 4 relative to reference semi-axis 30. Advantageously, the compensation magnetic torque and the parasitic magnetic torque exhibit a phase shift of substantially 180°. Preferably, the ferromagnetic element 12 is configured so that the maximum intensity (amplitude) of the compensating magnetic torque is substantially equal to that of the parasitic magnetic torque. In Figure 5 is shown a possible residual magnetic torque exerted on the wheel 4. In addition, the ferromagnetic element 12, in particular its two end parts, has a plane of symmetry 36 comprising the reference semi-axis 30 and the central axis 32 (axis of rotation) of the first wheel 4. This feature is advantageous to prevent the ferromagnetic element from generating a magnetic attraction force on the wheel 4 having an orientation perpendicular to the reference semi-axis 30. Such a magnetic attraction force would be perpendicular to the radial magnetic attraction force generally exerted by wheel 6 on wheel 4, so that such a perpendicular magnetic attraction force would generate a friction force of the pivots of this wheel 4 in associated bearings (not shown) which define the axis of rotation 32.

[0019] According to an improvement of the first variant, provision is made to configure the ferromagnetic element so as to generate globally on the first wheel 4 a compensation magnetic attraction force which is aligned on the reference semi-axis 30 with a direction opposite to that of a radial magnetic attraction force exerted overall by the second wheel 6 on the first wheel 4. It will be noted that the first variant already has a small compensating magnetic attraction force resulting from the intermediate part in semi-circle, but this intermediate part mainly serves to form a magnetic circuit of low magnetic reluctance between the two end parts 13 and 14 and its magnetic attraction force on the first wheel is much less than the magnetic attraction force radial force exerted by the second wheel on this first wheel, these two forces of attraction not being of the same order of magnitude. Specific embodiments, corresponding to the planned improvement, are the subject of a second variant and a third variant shown respectively in Figures 6 and 7.

[0020] In the second variant of FIG. 6, the magnetic gear 3A comprises a ferromagnetic element 16 provided, in addition to the two end parts 13 and 14 already described, with a compensation part 15 projecting in the direction of the first toothing 9 from the intermediate part 16A, this compensating part being positioned at an angle of 180° relative to the reference semi-axis 30, and serving to form the major part of the compensating magnetic attraction force. It will be noted that the compensation part 15 has the disadvantage of increasing an overall parasitic magnetic torque exerted on the wheel 4. However, the ferromagnetic element 16 can be configured so that the two end parts 13 and 14 compensate the major part or, preferably, substantially entirely the two magnetic torques generated respectively by the wheel 6 and the compensation part 15 on the wheel 4. In an advantageous variant, the additional magnetic torque generated by the compensation part can be reduced by enlarging that -ci (while increasing if necessary the distance to the first magnetic toothing) so that its free end has an arcuate profile, centered on the axis of rotation 32 of the first wheel, at a minimum distance from the first magnetic toothing 9 and extends substantially over an angular period of this first magnetic toothing, possibly a little less. A person skilled in the art will know how to optimize the profile and the angular extent of the free end of the compensation part in order to reduce the additional magnetic torque as much as possible.

[0021] In the third variant of FIG. 7, the magnetic gear 3B comprises a ferromagnetic element 22 whose intermediate part 22A is configured so that it approaches the first magnetic toothing 9 of the first wheel 4 in the direction of the angular position equal to 180°, measured from the reference half-axis 30, thus presenting a minimum distance with this first magnetic toothing at the angular position 180°. This third variant has the advantage of making it possible to obtain a relatively large compensation magnetic attraction force, in particular substantially equal to the radial magnetic attraction force exerted overall by the second wheel 6 on the first wheel 4, without generate a significant magnetic torque on the latter. Indeed, the magnetic torque generated by the intermediate part 22A is significantly lower than that generated by the intermediate part 16A of the second variant as shown in Figure 6. To further reduce this additional magnetic torque which applies to the first wheel , those skilled in the art will know how to optimize the shape of the intermediate part 22A, in particular its middle part.

With reference to Figure 8, a preferred variant of a second embodiment of a 3C magnetic gear according to the invention will be described, which is characterized by the arrangement of a set of separate ferromagnetic elements for compensate at least a major part of the parasitic magnetic torque (curve 10, FIG. 2) to which the first wheel 4 is subjected, which results from the magnetic coupling to the second wheel 6, in particular to the second magnetic toothing 7. The set of ferromagnetic elements comprises at least two elements 24 and 26 each positioned at a different angle, relative to the reference semi-axis 30, the value of which is equal to (M-1/2)-360°/N where M is an integer greater than '1' and less than N.

As for the first embodiment, it is provided in a general variant that the set of ferromagnetic elements is arranged so as to generate a compensating magnetic torque 18 (see Fig.4) which also has a variation of periodic intensity as a function of the angular position of the first wheel relative to the reference semi-axis 30, the compensating magnetic torque having the same angular period as the parasitic magnetic torque and exhibiting with the latter a phase shift of substantially 180°.

In a first advantageous variant, the set of ferromagnetic elements is arranged for the most part on a side opposite to the second wheel 6 relative to a geometric plane 38 comprising the central axis 32 of the first wheel and perpendicular to the reference semi-axis 30. Thus, the set of ferromagnetic elements is arranged so as to globally generate on the first wheel 4 a compensation magnetic attraction force which is aligned on the reference semi-axis 30 with a direction opposed to that of a radial magnetic attraction force exerted generally by the second wheel on the first wheel. In the preferred variant which is shown in FIG. 8, the set of ferromagnetic elements, consisting of the two elements 24 and 26, is arranged entirely on one side of the geometric plane 38 which is opposite to the second wheel 6.

In a second advantageous variant, the set of ferromagnetic elements has a plane of symmetry 36 comprising the reference semi-axis 30 and the central axis 32 of the first wheel. The preferred variant represented in FIG. 8 also enters into this second advantageous variant. The advantage resulting from such an arrangement has already been described.

Claims (10)

1. Mechanism comprising a magnetic gear (3) formed of a first wheel (4) and a second wheel (6), the first wheel being provided with N alternating first magnetic poles which are arranged circularly and define a first magnetic toothing (9), the second wheel being provided with teeth made of ferromagnetic material or second alternating magnetic poles arranged circularly, these teeth or these second magnetic poles defining a second magnetic toothing (7) which has a magnetic coupling with the first magnetic toothing of so that, when one of the first and second wheels is driven in rotation, this wheel (4) rolls, via the magnetic coupling, on a geometric circle centered on the other wheel (6) and linked to this other wheel; characterized in that the mechanism further comprises a ferromagnetic element (12; 12A; 16) or a set of ferromagnetic elements (24, 26) arranged relative to the first wheel so as to compensate at least a major part of a torque parasitic magnetic torque (10) which this first wheel undergoes and resulting from said magnetic coupling, this parasitic magnetic torque having a periodic intensity variation as a function of the angular position (α) of the first wheel relative to a reference semi-axis (30 ) starting from the central axis (32) of the first wheel and intercepting the central axis (34) of the second wheel. 2. Mechanism according to claim 1, characterized in that said ferromagnetic element or the set of ferromagnetic elements is arranged so as to generate a compensating magnetic torque (18) which also has a periodic intensity variation as a function of the angular position of the first wheel relative to said reference half-axis (30), the compensation magnetic torque and the parasitic magnetic torque having a phase shift of substantially 180°. 3. Mechanism according to claim 1 or 2, characterized in that said ferromagnetic element or the set of ferromagnetic elements has a plane of symmetry (36) comprising the reference semi-axis (30) and the central axis (32 ) of the first wheel. 4. Mechanism according to any one of the preceding claims, characterized in that said ferromagnetic element or the set of ferromagnetic elements is arranged so as to generate globally on the first wheel a compensating magnetic attraction force which is aligned on the half - reference axis (30) with a direction opposite to that of a radial magnetic force of attraction exerted globally by the second wheel on the first wheel. 5. Mechanism according to any one of the preceding claims, characterized in that the ferromagnetic element (12, 16, 22) comprises two end portions (13, 14) which extend in the direction of the first toothing (9), each positioned at an angle, relative to the reference semi-axis (30), the value of which is equal to (M-1/2)-360°/N with M being an integer greater than '1' and less than N , and an intermediate part (12A, 16A, 22A) connecting the two end parts. 6. Mechanism according to claim 5 dependent on claim 4, characterized in that the ferromagnetic element (16) further comprises a compensation part (15) projecting in the direction of the first toothing (9) from the intermediate part ( 16A), this compensating part being positioned at an angle, relative to the reference semi-axis (30), the value of which is equal to 180° and serving to form the major part of the compensating magnetic attraction force. 7. Mechanism according to claim 5 dependent on claim 4, characterized in that the intermediate part (22A) of the ferromagnetic element (22) is configured so that this intermediate part approaches the first magnetic toothing (9) in direction of the angular position equal to 180°, measured from the reference semi-axis (30), thus presenting a minimum distance with this first magnetic toothing at the angular position 180°. 8. Mechanism according to any one of claims 1 to 4, characterized in that said set of ferromagnetic elements comprises two elements (24, 26) each positioned at an angle, relative to the reference semi-axis (30), whose value is equal to (M-1/2)-360°/N with M being an integer greater than '1' and less than N. 9. Mechanism according to claim 4 or claim 8 dependent on claim 4, characterized in that the set of ferromagnetic elements (24, 26) is arranged mainly or, preferably, entirely on a side opposite to the second wheel (6) relative to a geometric plane (38) comprising the central axis (32) of the first wheel and perpendicular to the reference semi-axis (30). 10. Mechanism according to any one of the preceding claims, characterized in that this mechanism is a timepiece mechanism.