RU2624713C1 - Magnetic or electrostatic resonator - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: clock resonator (6) comprising a movable component (7) having a ring-like shape extending around the axis and configured to oscillate about the axis (A), and a drive element (8), on which the torque acts inside the clock mechanism (10). This resonator is an annular magnetic or electrostatic resonator (6), the mobile component (7) of which is periodically excited by the action caused by the movement of the said drive element (8). The drive element (8) is designed to exert a non-contact force on the movable component (7). The mobile component (7) includes the first number of the first polar elements (76) magnetized or electrically charged with the first angular pitch, and the drive element (8) includes the second number of the second pole elements (86) magnetized or electrically charged with the second angular step and arranged such that the movable component (7) together with the drive element (8) form a mechanism that reduces or increases the speed.

EFFECT: improveming the resonator.

21 cl, 22 dwg

Description

FIELD OF THE INVENTION

The invention relates to a clock resonator containing a movable component having the shape of a ring extending around an axis, and configured to oscillate around an axis, and a drive element that is acted upon by a torque within the clock mechanism.

The invention also relates to a clock mechanism that is attached to a plate: energy storage means configured to supply said torque to a gear transmission to drive a mechanism including such an annular resonator with a movable component attached by means of flexible strips to said a plate, and a drive element driven by said gear train, said drive element controlling the display means of said mechanism ma.

The invention also relates to a watch including one such mechanism.

The invention relates to the field of regulation of mechanical watches, in particular mechanical watches or pocket watches.

State of the art

Many contacts in the control element reduce the quality indicator and efficiency. Moreover, it is difficult to match the different frequencies of the resonator components.

French patent No. 2132162 to HORSTMANN MAGNETICS describes a magnetic drive mechanism and an anchor mechanism for rotors in which the coupling between the mechanically oscillating element and the rotor is purely magnetic without mechanical interaction. The rotor contains a disk made of ferromagnetic material, along the entire perimeter of which there is an even number of evenly distributed spokes or levers having such a shape that the outer ends of each pair of adjacent levers or spokes are displaced in the axial direction relative to the plane of symmetry perpendicular to the axis of rotation of the rotor. The mechanism comprises an oscillating element, such as a rotor, the axis of rotation of which is parallel to the direction of oscillation of the oscillating element, and an annular magnetic element located on the oscillating element and at least partially surrounding the perimeter of the rotor, said rotor being magnetically coupled to the poles of the magnetic element, so that the drive torque moments oriented in the same direction as the rotation act on the rotor in a large number of places around the perimeter of the rotor during vibrations by an oscillating element m.

Belgian patent application No. 530509A on behalf of PHILIPS describes a device for stabilizing the speed of a motor, the motor being at least partially driven by a mechanical resonance system operating at a frequency close to its resonant frequency. The resistance torque of the mentioned system, which increases sharply at resonance, has a stabilizing effect on the angular speed of the motor.

Disclosure of invention

The invention proposes to create mechanisms that demonstrate greater efficiency than conventional resonators.

To this end, the invention relates to a clock resonator comprising a movable component having the shape of a ring extending around an axis and configured to oscillate, and a drive element that is subjected to a torque within the clock mechanism, characterized in that said resonator is essentially annular a magnetic or electrostatic resonator in which the movable component is periodically excited by an action caused by the movement of said drive element, said the th drive element is designed so as to contactlessly exert a force on said movable component, said movable component being flexible and deformable at least in a plane that is perpendicular to said axis and in which it oscillates, and said movable component comprises a first region magnetized or electrically charged with a first angular pitch, and said drive element comprises a second region magnetized or electrically charged with a second angular pitch, excellent t of the first angular step, and arranged so as to attract or repel interact with said first region, so that said movable component together with said drive element form a mechanism that decreases or increases speed, while the speed of said drive element determines the propagation velocity of the deformation wave of the material said movable component along its entire length, and can determine a standing wave of oscillations of said movable component between repeating shapes corresponding to standing modes.

The invention also relates to a clock mechanism including attached to a plate: energy storage means configured to supply said torque to a gear transmission to actuate a mechanism including such an annular resonator with said movable component attached by means of flexible strips to said a plate, and said drive element driven by said gear train, said drive element controlling the display means mentioned mechanism.

The invention also relates to watches including such a mechanism, characterized in that the said watches are wrist or pocket watches.

Brief Description of the Drawings

Other features and advantages of the invention will become apparent upon reading the following detailed description with reference to the accompanying drawings.

In FIG. 1 and 2 are schematic plan views of a ring resonator according to the invention with a movable component in the form of a ring, which is driven by a drive element in the form of a wheel, with FIG. 1 shows the position when the first pole elements contained in the annular movable component and the second pole elements contained in the drive element are combined at the 12 o'clock and 6 o'clock positions, and when the first pole elements and at the 3 o'clock and 9 o'clock positions the second pole elements are not aligned. In FIG. 2 shows a state in which, after a slight angular rotation of the drive alignment element, become opposite.

In FIG. 3 shows a similar embodiment in which the pole elements are made of magnets and, as shown in FIG. 4, if the pole elements are aligned, they repel each other, and, as shown in FIG. 5, if the pole elements are not aligned, they attract each other.

In FIG. 6-8 show a diagram of the interaction forces between the movable component and the drive element as a function of the angle of the drive element corresponding to FIG. 6, 12 hours in FIG. 7 and 9 in FIG. 8.

FIG. 9-11 are similar to FIG. 6-8, while some of the pole elements are removed from the movable component, the remaining groups of pole elements are located at certain intervals around the circumference.

FIG. 12-14 are also similar to FIGS. 6-8 and save only four pairs of the first pole elements on the movable component at an angle of 90 ° to each other.

In FIG. 15 and 16 show a first embodiment of the invention, which consists in driving a partial ring-shaped movable component in accordance with FIG. 12. In FIG. 16 shows a separate resonant mode. In FIG. 15A shows an embodiment of FIG. 15, comprising means for limiting loss of synchronization in the form of mechanical limiters.

In FIG. 17 and 18 show the second option, which consists in the excitation of the movable component in the form of a complete ring. In FIG. 18 shows a separate resonant mode.

The third embodiment shown in FIG. 19, consists in arranging the drive element and the movable component one above the other, while the vibrations are performed in three dimensions, as shown in FIG. twenty.

In FIG. 21 is a block diagram showing a clock comprising a clock mechanism into which a mechanism according to the invention is included.

The implementation of the invention

Throughout what follows, the term “ring” means a three-dimensional figure similar to a torus passing around an axis and closing on itself. This "ring" essentially represents the surface of rotation around the axis, but not necessarily the accuracy of rotation around the axis.

The invention can be implemented using magnetic and / or electrostatic fields. It is shown in more detail in the magnetic version.

The invention relates to a clock resonator 6 containing a movable component 7, configured to oscillate around axis A, and a drive element 8, which is acted upon by a torque inside the clock mechanism 10.

According to the invention, this resonator is essentially a magnetic or electrostatic resonator 6, the movable component 7 of which is periodically excited by the action caused by the movement of the drive element 8; moreover, said drive element 8 is configured so as to contactlessly exert a force on the movable component 7.

The movable component 7 is flexible and deformable at least in a plane perpendicular to the axis A, while the movable component 7 contains a first region magnetized or electrically charged with a first angular pitch, and the drive element 8 contains a second region magnetized or electrically charged with a second angular a step different from said first angular step, and arranged so as to attract or repel interact with said first region, so that the movable component 7 together with drive component 8 form a mechanism that reduces or increases speed.

An interaction can occur between a magnetized or respectively electrically charged element and a conductive or respectively dielectric track.

More specifically, in the non-limiting example shown in the drawings, the movable component 7 includes a first number of first pole elements 76 magnetized or electrically charged with a first angular pitch, and the drive element 8 includes a second number of second pole elements 86 magnetized or electrically charged with a second angular pitch, which is different from the first angular pitch. These second pole elements 86 are arranged so as to interact by attraction or repulsion with the first pole elements 76, so that the movable component 7 together with the drive element 8 form a mechanism that reduces or increases speed.

More specifically, the first quantity is different from the second quantity.

More specifically, the first quantity is different from the second quantity per unit.

In particular, the speed of the drive element 8 determines the speed of propagation of the deformation wave of the material of the movable component 7 over its entire length.

In another implementation of the invention, the speed of the drive element 8 determines a standing wave of oscillation of the movable component 7 between the repeating shapes corresponding to the standing modes.

Preferably, the movement of the drive element 8 includes at least one pivotal movement.

More specifically, as not limitingly shown in the drawings, the movement of the drive element 8 is a rotation about axis A.

In a separate embodiment, as can be seen from FIG. 15 and 17, the movable component 7 is attached to the plate 5 contained in the clock mechanism 10, through several flexible strips 9.

In a first embodiment, these flexible strips 9 are more flexible than the movable component 7, and are designed to hold the movable component 7 substantially centered on axis A and to limit the oscillatory movements of the movable component 7 in the same plane P perpendicular to said axis A, with limited displacements of the center of inertia of the movable component 7, comprising less than one tenth of the smallest external dimension of the movable component 7 in the plane P.

In a second embodiment, these flexible strips 9 are more rigid than the movable component 7, and are designed to hold the movable component 7 substantially centered on axis A and to limit the movement of the movable component 7 in the same plane P perpendicular to said axis A, c limited displacements of the center of inertia of the movable component 7, comprising less than one tenth of the smallest external dimension of the movable component 7 in the plane P.

More specifically, the movable component 7 is continuously or periodically weighted around the perimeter.

In particular, the movable component 7 is weighted by several inertial bodies.

In particular, the movable component 7 has varying sections and / or thickness along the perimeter.

Advantageously, the movable component 7 is made of a material subject to mechanical microprocessing, or silicon, and has a rectangular section in each plane passing through said axis A.

Advantageously, the movable component 7 is made integrally with several flexible strips 9 for connection with the plate 5 contained in the clock mechanism 10.

Advantageously, the movable component 7 is integrally formed with several flexible strips 9 and with a plate 5.

In a separate embodiment, in an unstressed free position, the movable component 7 has a polygonal or multiple-lobe shape in a plane P perpendicular to axis A.

In the particular embodiment shown in FIG. 1-19, the movable component 7 is a ring coaxial with the drive element 8.

In a separate embodiment, as shown in FIG. 20, the movable component 7 is solid and at least partially deformable in the direction of axis A.

The invention also relates to a clock mechanism 10, including energy storage means 3 attached to the plate 5, namely, a cylinder configured to supply torque to a gear 2 to drive a mechanism 1 including such an annular resonator 6 with such a movable component 7, attached by means of flexible strips 9 to the plate 5, and a drive element 8, namely an anchor wheel driven by a gear 2, and the drive element 8 preferably controls the means 4 displays of said clockwork 10.

The invention also relates to a watch 100 including such a clock mechanism 10. The watch 100 is preferably a pocket watch or a wrist watch.

More specifically, the figures show preferred embodiments.

The movable component 7 includes first pole elements 76, and the drive element 8 includes second pole elements 86. The number of pole elements on each structure is selected so that for a given angle of the drive element 8, the pole elements for 12 hours and for 6 hours of the movable component 7 and the drive element 8 were facing each other, and the pole elements for 3 hours and 9 hours were not facing each other. When the drive element 8 is rotated by a small angle θ, the alignment should become opposite.

In FIG. 1 at 12 o’clock and at 6 o’clock the first pole elements 76 and the second pole elements 86 are combined. At 3 hours and 9 hours, the first pole elements 76 and the second pole elements 86 are not aligned. In FIG. 2, when the drive element 8 is rotated by a small angle θ, the locations become opposite.

In FIG. The 3 pole elements are made of magnets: the drive element 8 is radially offset outward, and the movable component 7 is radially offset to the axis A. As shown in FIG. 4, when the pole elements are aligned, they repel each other. As shown in FIG. 5, when the pole elements are not aligned, they attract each other.

Thus, it is possible to plot the interaction forces as a function of the angle of the drive element 8 corresponding to FIG. 6, between the movable component 7 and the drive element 8 for 12 hours in FIG. 7 and at 9 o’clock in FIG. 8.

In FIG. 9-11, similarly to FIG. 6-8, it is shown that by removing the pole elements from the movable component 7, it is possible to choose where it is desirable to arrange the interaction forces between the two elements. In FIG. 12-14, only four pairs of first pole elements 76 are stored on the movable component 7 at an angle of 90 ° to each other.

In FIG. 15 and 16 show a first embodiment of the invention, which consists in using the principle described above to excite the movable component 7 in the form of a partial ring, so that it resonates in the so-called “glass” mode: the drive element 8 is synchronized with the vibrations of the movable component 7. Between the drive element 8 and the movable element 7 there is no mechanical interaction.

In FIG. 15 shows a diagram of a mechanism in which the ring-shaped component 7 is excited only at the 12 o’clock position, at 3 o’clock, at 6 o’clock and at 9 o’clock. In FIG. Figure 16 shows its resonance mode in the form of variable eccentric ellipses with permutation of the axes.

In FIG. 15A shows an embodiment of FIG. 15, comprising means for limiting loss of synchronization in the form of mechanical limiters. At the second level, parallel to the level of the pole elements 86 of the drive element 8, the gear 40 is integral with the drive element 8, and the movable component 7 contains stops in the form of pins 41. During normal operation, these pins 41 oscillate with the movable component 7 without touching gear wheel 40. In case of loss of synchronization, the drive element 8 drive tends to move and rotate too fast, but then the pins 41 collide with the gear wheel 40, which prevents acceleration.

In FIG. 17 and 18 show a second embodiment, which consists in using the principle described above, while the movable component 7 has the shape of a full ring for exciting in the so-called "hoop" mode. In FIG. 17 shows a diagram of a mechanism in which an annular component 7 is excited around its entire circumference. In FIG. 18 shows its separate resonant mode.

The third embodiment shown in FIG. 19, consists in arranging the drive element 8 and the movable component 7 on top of each other so that the movable component 7 oscillates in three dimensions, at least partially in the direction of the axis A, in height, in accordance with the same principle as in the first embodiment. Thus, the disk is in the form of a potato chip, as seen in FIG. twenty.

The fourth option (not shown) is a version of the second option outside the plane, very close to the third option.

Another option, which is not shown, includes a drive element 8, which instead of individual magnets includes a track that interacts with the magnets on the vibrating movable component 7 in the same way as in the case of magnet-magnet interaction.

The invention allows to eliminate contacts in the regulatory element, which leads to an increase in the quality indicator and increase in efficiency. Moreover, the drive element 8, preferably in the form of an anchor wheel, rotates at a low frequency, and the movable component 7, preferably a ring, resonates at a high frequency.

The embodiment shown in FIG. 15, with the movable component 7 in the form of an incomplete ring, reduced to certain angular ranges, allows you to get vibration in the "glass" mode.

Claims (22)

1. A clock resonator (6) containing a movable component (7) having the shape of a ring extending around an axis and configured to oscillate around axis (A), and a drive element (8) subjected to a torque inside the clock mechanism ( 10), characterized in that it is essentially a ring magnetic or electrostatic resonator (6), while the movable component (7) is periodically excited under the action caused by the movement of the drive element (8), and the drive element (8) is made with in the ability to contactlessly exert force on the movable component (7), while the movable component (7) is flexible and deformable in the plane (P), which is perpendicular to the aforementioned axis (A) and in which it has the ability to oscillate, and the movable component (7) comprises a first region magnetized or electrically charged with a first angular pitch, and the drive element (8) contains a second region magnetized or electrically charged with a second angular pitch different from the first angular pitch, and configured to interaction with attraction or repulsion with the aforementioned first region, so that the movable component (7) together with the drive element (8) form a mechanism that reduces or increases the speed, while the speed of the drive element (8) determines the propagation velocity of the deformation wave of the material of the moving component ( 7) over its entire length and can determine the standing wave of oscillations of the moving component (7) between the repeating forms corresponding to the standing modes. 2. A clock resonator (6) according to claim 1, characterized in that the movable component (7) includes a first number of first pole elements (76) magnetized or electrically charged with a first angular step, and the drive element (8) contains a second the number of second pole elements (86), magnetized or electrically charged with a second angular step and configured to interact with attraction or repulsion with the first pole elements (76), so that the movable component (7) together with the drive element (8) form a mechanism Reducing or increasing velocity. 3. The clock resonator (6) according to claim 2, characterized in that said amount differs from said second quantity. 4. The clock resonator (6) according to claim 3, characterized in that said amount differs from said second quantity by one. 5. Clock resonator (6) according to claim 1, characterized in that the speed of the drive element (8) determines a standing wave of oscillations of the moving component (7) between the repeating forms corresponding to the standing modes. 6. Clock resonator (6) according to claim 1, characterized in that the movement of the drive element (8) includes at least one pivotal movement. 7. Clock resonator (6) according to claim 6, characterized in that the said movement of the drive element (8) is a rotary movement around the said axis (A). 8. Clock resonator (6) according to claim 1, characterized in that the movable component (7) is attached to the plate (5) contained in the clock mechanism (10) by means of several flexible bands (9), which are more flexible than the movable component (7), and are designed to hold the movable component (7) essentially centered on the axis (A) and to limit the movements of the movable component (7) in the same plane (P) perpendicular to said axis (A), c limited displacements of the center of inertia of the moving component (7), comprising less than one des one of the smallest size outer movable component (7) in said plane (P). 9. Clock resonator (6) according to claim 1, characterized in that the movable component (7) is attached to the plate (5) contained in the clock mechanism (10) by means of several flexible bands (9), which are more rigid than the movable component (7), and are designed to hold the movable component (7) essentially centered on the axis (A) and to limit the movements of the movable component (7) in the same plane (P) perpendicular to said axis (A), c limited displacements of the center of inertia of the moving component (7), comprising less than one yatoy from smallest external size of the movable component (7) in said plane (P). 10. The clock resonator (6) according to claim 1, characterized in that the movable component (7) is continuously or periodically weighted along the perimeter. 11. Clock resonator (6) according to claim 10, characterized in that the movable component (7) is weighted by several inertial bodies. 12. The clock resonator (6) according to claim 1, characterized in that the movable component (7) has varying sections and / or thickness along the perimeter. 13. Clock resonator (6) according to claim 1, characterized in that the movable component (7) is made of a material subject to mechanical microprocessing, or silicon, and has a rectangular cross-section in each plane passing through said axis (A). 14. Clock resonator (6) according to claim 13, characterized in that the movable component (7) is made as a unit with several flexible strips (9) for connection with the plate (5) contained in the clock mechanism (10). 15. The clock resonator (6) according to claim 14, characterized in that the movable component (7) is made as a unit with several flexible bands (9) and with a plate (5). 16. The clock resonator (6) according to claim 1, characterized in that in the unrestricted free state the movable component (7) has a polygonal or multi-lobed shape in the plane (P) perpendicular to said axis (A). 17. Clock resonator (6) according to claim 2, characterized in that the drive element (8) includes at the second level parallel to the level of the second pole elements (86), a gear wheel (40), made as a single unit with the drive element (8), while the movable component (7) includes limiters in the form of pins (41), which during normal operation are made to oscillate with the movable component (7) without touching the gear (40), and engagement with said gear wheel (40) in case of loss of synchronization to prevent acceleration. 18. Clock resonator (6) according to claim 1, characterized in that the movable component (7) is a ring coaxial with the drive element (8). 19. Clock resonator (6) according to claim 1, characterized in that said drive element (8) is an anchor wheel. 20. Clock mechanism (10), including energy storage means (3) attached to the plate (5), configured to supply said torque to the gear transmission (2) to drive the mechanism (1), which includes an annular a resonator (6) according to claim 1, with said movable component (7) attached by means of flexible strips (9) to said plate (5) and said drive element (8) driven by said gear train (2), element (8) is configured to control means (4) mapping the aforementioned mechanism (10). 21. Watches (100), including a clock mechanism (10) according to claim 20, characterized in that the watch is a wrist or pocket watch.

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