This application claims priority to European Patent Application No. 19205242.1 filed on Oct. 25, 2019, the entire disclosure of which is hereby incorporated herein by reference.
The present invention relates to a flexible guide for a rotary resonator mechanism. The invention also pertains to a set of superimposed flexible guides for a rotary resonator mechanism. The invention also pertains to a horological movement provided with such a flexible guide or with such a set of superimposed flexible guides.
Most of today's mechanical watches are provided with a balance-spring and a Swiss lever escapement mechanism. The balance-spring constitutes the time base of the watch. It is also called a resonator.
The escapement, in turn, fulfils two main functions:
The Swiss lever escapement mechanism has a low energy efficiency (around 30%). This low efficiency results from the fact that the movements of the escapement are jerky, that there are drops or lost paths to accommodate machining errors, and also from the fact that several components transmit their movement to each other via inclined planes which rub against each other.
To constitute a mechanical resonator, an inertial element, a guide and an elastic return element are needed. Traditionally, a spiral spring acts as an elastic return element for the inertial element that a balance constitutes. This balance is guided in rotation by pivots which rotate in plain ruby bearings. This gives rise to friction, and therefore to energy losses and operating disturbances, which depend on the positions, and which one seeks to eliminate.
There are also rotary resonators pivoting about an axis of rotation and subjected to a motor torque, which perform a continuous rotary movement around an axis.
Application EP 17194636.1 describes such a resonator mechanism including a plurality of inertial elements movable relative to the central moving body of the resonator, and returned towards its axis of rotation by elastic return means. When rotating, the resonator deploys in a plane perpendicular to the axis of rotation of the resonator.
Another application EP17183211.6 shows a rotary resonator including at least one inertial element arranged to pivot relative to the central moving body about a secondary axis perpendicular to the axis of the central moving body. While rotating, the resonator deploys in a plane containing the axis of rotation of the resonator.
In these applications, there are in particular embodiments of rotary resonators including flexible strip guides as elastic return means of the inertial element(s). The flexible virtual pivot guides allow to significantly improve the performance of timepiece resonators. The simplest are crossed-strip pivots, composed of two guide devices with straight strips which cross each other, generally perpendicularly. But there are also RCC (Remote Centre Compliance) type uncrossed-strip pivots, for which the centre of rotation is outside the structure of the pivot, and which have straight strips that do not cross each other.
It is possible to optimise a three-dimensional strip guide for a resonator, in an attempt to make it isochronous with an operation independent of its orientation in the gravity field. In the case of rotary resonators described in the state of the art, it is sought to obtain an elastic return moment of the flexible guide, which has a sinusoidal shape. For some cases of rotary resonators described in the state of the art, the return moment allowing a perfect isochronism to be achieved obeys the following law:
M=−k sin(2θ), where θ is the guide deformation angle and k a spring constant. Thus, the return moment increases up to an angle of deformation of the guide, for example of 45°, then it decreases to another angle, for example 90°.
However, the flexible guide rotary resonators described in the state of the art do not meet this requirement, so that they do not achieve sufficient isochronism to be efficient.
A purpose of the invention is, consequently, to provide a flexible guide for a rotary resonator mechanism, which avoids the aforementioned problems.
To this end, the invention relates to a flexible guide for a rotary resonator mechanism, in particular of a horological movement, the guide comprising a first support, an element movable relative to the first support, a first pair of flexible strips connecting the first support to the movable element, so that the movable element can displace relative to the first support by bending the strips in a circular movement about a centre of rotation, the flexible guide being arranged substantially in a plane.
The flexible guide is remarkable in that it comprises prestressing means, the prestressing means being configured to apply a force for buckling the flexible strips by bringing the first support closer to the movable element, so that the flexible guide comprises two stable positions of the element movable relative to the first support for which the return moment is zero, the two stable positions having a predetermined angle of rotation therebetween.
Thanks to the invention, a flexible strip guide which can move between two stable positions, and whose behaviour is close to an ideal guide for a rotary resonator is obtained. Such a flexible guide guarantees an isochronism and an operation independent of the gravity field. Indeed, the buckling force of the strips allows to transform the linear return moment of a flexible guide without constraint into a bistable return moment, the return moment having a substantially sinusoidal shape, between the two stable angular positions of the movable element.
According to an advantageous embodiment, the return moment of the flexible guide has a substantially sinusoidal shape between the two stable angular positions.
According to an advantageous embodiment, the movable element has an axial symmetry and a centre of rotation, the flexible strips being directed towards the centre of rotation.
According to an advantageous embodiment, the prestressing means comprise a spring connecting the movable element and the first support.
According to an advantageous embodiment, the flexible guide comprises a second support and a second pair of flexible strips connecting the second support to the movable element, the second support and the second pair of strips being arranged by symmetry of the first support and the first pair of flexible strips relative to the movable element, the two pairs of flexible strips connecting on either side the first and the second support to the movable element at its centre of rotation.
According to an advantageous embodiment, the prestressing means include a holding component comprising two arms, each arm being fixed to a support, so as to apply the buckling force on one support towards the other support.
According to an advantageous embodiment, the holding component comprises elastic structures arranged on the arms to be in contact with each support.
According to an advantageous embodiment, the movable element is partly deformable at the centre of rotation.
According to an advantageous embodiment, each arm of the holding component comprises a deformable portion.
The invention also pertains to a set of superimposed flexible guides comprising at least two flexible guides according to the invention, the supports of the second flexible guide being fixed to the movable element of the first flexible guide.
According to an advantageous embodiment, the set comprises a third flexible guide superimposed on the second flexible guide, the supports of the third flexible guide being fixed to the movable element of the second flexible guide.
The invention also pertains to a rotary resonator mechanism of a horological movement, the mechanism including a central moving body arranged to pivot about a central axis and at least two inertial elements arranged to pivot relative to the central moving body about a secondary axis. The mechanism comprises two flexible guides, each flexible guide connecting an inertial element to the central moving body.
The invention also pertains to a rotary resonator mechanism of a horological movement, the mechanism including a central moving body arranged to pivot about a central axis and at least two inertial elements arranged to pivot relative to the central moving body about a secondary axis. The mechanism comprises two sets of superimposed flexible guides, each set connecting an inertial element to the central moving body.
Other features and advantages of the present invention will become apparent upon reading several embodiments given only by way of non-limiting examples, with reference to the appended drawings wherein:
According to the invention, the flexible guide 1 comprises prestressing means 7 configured to apply a force for buckling the flexible strips 4, 5 by bringing the movable element 3 closer to the support 2. To this end, the prestressing means 7 comprise, for example, a spring fixed on the one hand to the support 2 and on the other hand to the movable element 3. Preferably, the spring is substantially fixed at the centre of mass of the movable element 3.
The spring exerts a tensile force which brings the movable element 3 closer to the support 2. Thus, a buckling force constrains the strips to bend to put the movable element 3 in a stable position for which the return moment is zero. In
There is a second stable position, not shown in
In an application to a rotary resonator mechanism, such as those described in the applications mentioned in the preamble, two flexible guides are used to replace those described in these applications. The supports are fixed to the central element, while the movable elements are each fixed to an inertial element.
The movable element 13 comprises a longitudinal part 22 and a U-shaped structure 23, 24 at each end of the longitudinal part 22. Each end is connected to the base centre of the U of the structure 23, 24. Thus, the movable element 13 has an axial symmetry along its longitudinal part 22. The middle of the longitudinal part forms the centre of rotation 18 of the movable element 14.
Without prestressing means, as shown in
The movable element 22 is configured to be able to rotate around the centre of rotation 18 thanks to the flexibility of the strips 14, 15, 16, 17. The centre of rotation 18 is arranged substantially at its centre of mass. Depending on the actuation of the guide 10, the movable element 13 rotates in the plane of the flexible guide 10. Without prestress, the elastic return moment is linear depending on the angle of rotation relative to the equilibrium position of the mechanism. In addition, in this case there is only one stable position corresponding to the rest position of the movable element. The movable element is directed along the first axis of symmetry X, as shown in
According to the invention, the flexible guide 10 comprises prestressing means 27 configured to apply a force F for buckling the flexible strips 14, 15, 16, 17 by bringing each support 11, 12 closer to the movable element 13. To this end, the flexible guide 10 is provided with a component for holding said supports 11, 12, the holding component forming said prestressing means 27. The holding component has a U-shaped body 25 whose two arms 26, 28, which are substantially parallel, each rests on one of the supports 11, 12. The distance between the two arms is less than the distance between the two supports 11, 12 without prestress. Thus, the arms 26, 28 press on the supports 11, 12 by applying the force F, which allows the flexible strips 14, 15, 16, 17 to be buckled to bring each support 11, 12 closer to the movable element 13. The buckling force F is directed along the second axis of symmetry Y of the flexible guide 10. Thus, the flexible strips 14, 15, 16, 17 of the two pairs are substantially curved. In response, the movable element 13 displaces in rotation at a determined angle α to reach a first stable position. The angle α is defined relative to the first axis of symmetry X, the first stable position being directed upwards in
The movable element 13 can pass from one stable position to another according to the movement followed by the flexible guide 10. In particular in a rotary resonator mechanism, where the flexible guide 10 follows a rotational movement about a main axis of the mechanism. The movable element 13 is positioned in a position depending on the centrifugal force it undergoes. Thanks to such a flexible guide 10, the rotational speed of the resonator remains substantially constant, even if the driving force applied to the resonator mechanism varies.
In a first variant of the second embodiment of the flexible guide 30, shown in
The absorbers 38, 39 are disposed at the ends of the walls to be in contact with the supports 11, 12 of the flexible guide 30. Thus, these absorbers 38, 39 allow to improve the curvature of the elastic return moment between the stable positions, in order to give them a shape even closer to a sinusoidal function.
In
A third variant, shown in
The invention also relates to a set 60 of superimposed flexible guides. In
To apply a constraint on the upper flexible guide 62, 63, the distance between the two U-shaped structures of the movable element 64, 65 of the lower moving body is less than the distance between the two supports 67, 68, 69, 71 of the upper guide 62, 63 without prestress. Thus, the supports 67, 68, 69, 71 of the upper flexible guide 62, 63 are maintained compressed between the two U-shaped structures of the movable element 64, 65 of the lower guide 61, 62. The buckling force of the flexible strips is obtained by this interlocking of the supports 67, 68, 69, 71.
For each flexible guide 61, 62, 63, the angle of displacement between the two stable positions is equal to 2α, α being the angle formed by the position of the movable element with prestress relative to the position of the movable element without prestress. 2α is for example comprised between 20 and 40°, preferably substantially equal to 30°. Thus, by superimposing three devices, a global angle of 90° is obtained. With such a global angle, the result is a flexible guide that is ideal for use in a resonator timepiece mechanism.
In the rest position, the upper flexible guide is oriented in a direction forming an angle corresponding to the angle formed between the two stable positions of the movable element. Thus the second axis of symmetry of the upper flexible guide forms an angle with the second axis of symmetry of the upper flexible guide, for example of 30°.
The invention also pertains to a rotary resonator timepiece mechanism, not shown in the figures.
In a first variant, the resonator mechanism is provided with a flexible guide according to the first or the second embodiment.
In a second variant, the resonator mechanism is provided with a set of superimposed flexible guides according to the invention.
The flexible guide or the set of superimposed flexible guides has the function of allowing the movable masses of the resonator mechanism to move away from the centre of rotation, when the rotational force of the mechanism is stronger, or to move closer thereto, when the rotational force of the mechanism is lower. Thus, a substantially constant rotational speed is maintained, regardless of the tension of the barrel spring.
In the examples of the rotary resonator mechanism of the applications mentioned in the preamble, the flexible guides described therein are replaced by a flexible guide according to the invention or a set of superimposed flexible guides according to the invention. For this purpose, the holding component of the lower guide is fixed to the axis, while a support of the upper guide is fixed to the movable mass of the resonator. By symmetry, a second assembly is assembled in the same way to allow the other movable mass of the resonator to move relative to the centre of rotation of the resonator.
Naturally, the invention is not limited to the embodiments described with reference to the figures and variants could be considered without departing from the scope of the invention.
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