CH707787A1 - regulating member for wristwatch and method of assembling a regulatory body for wristwatch. - Google Patents

Abstract

A regulating organ for a wristwatch, comprising: a generator comprising a rotor (2) provided with permanent magnets and a stator provided with a plurality of coils (10); an electronic circuit (8) mounted on a first circuit, powered by the generator (M) and for adjusting the speed of rotation of the rotor (2); the coils (10) of the generator are connected by a second circuit; and: constitute two distinct modules separated geographically from one another and electrically connected to each other.

Description

Technical area

The present invention relates to a regulator member for a wristwatch, in particular an electronic regulator member for a mechanical wristwatch.

State of the art

[0002] Mechanical wristwatches are usually regulated by means of an assortment comprising a hairspring and a pendulum. The accuracy that can be achieved using a regulating organ of this type is, however, limited.

[0003] Electronic watches are usually regulated by means of a quartz oscillator. The accuracy that can be achieved is greater than that of mechanical movements, but these watches usually require a battery that needs to be replaced periodically.

In order to overcome these disadvantages, it is also known in the state of the art of watches comprising a mechanical movement controlled by an electronic circuit with a quartz oscillator. The energy required for the electronic circuit is provided by a motion-driven generator.

Thus, CH-A-597 636 (S.A. Ebauches) proposes a mechanical movement with a mainspring and a generator. The spring actuates, by means of a gear train, a time indicator and the generator that delivers an alternating voltage. The generator supplies a rectifier that charges a storage capacity to power a crystal oscillator and an electronic control circuit. The electronic control circuit comprises a comparison logic circuit and an energy dissipation circuit connected to the output of the comparison logic circuit, the power absorption of which can be controlled by the comparison logic circuit. An input of the comparison logic circuit is connected to the reference circuit and another input of the comparison logic circuit is connected to the generator. The comparison logic circuit controls, according to the result of this comparison, the power absorption by the energy dissipation circuit and regulates in this way, through the control of the energy absorption of the control circuit, the operation of the generator and the time indicator.

In such a watch, the advantages of a mechanical watch, that is to say the absence of batteries, are combined with the precision of a quartz watch.

[0007] EP 905 589 describes a braking circuit for a watchmaking microgenerator, comprising a counter and a braking circuit which brakes as soon as the value accumulated in the counter exceeds a threshold.

[0008] EP 816 955, the content of which is incorporated by reference, describes an improvement to the electronic control circuits of watchmakers, in which the voltage rectifier comprises transistors controlled by comparators to replace the diodes after the start of the circuit.

[0009] WO 0 063 749, the content of which is incorporated by reference, describes a watch movement with a microgenerator. In order to avoid the accumulation of electric charges, the wheels and pinions of the gear train are electrically connected to the ground (that is to say to the plate) and made of a non-magnetic material.

EP 0 851 322 discloses a watch movement generator comprising a stator with three coils electrically connected and a rotor provided with magnetized regions. The coils are arranged asymmetrically around the axis of the rotor, to allow the rotor to slide between the coils during assembly. This asymmetrical arrangement, however, causes a slight loss of the efficiency of the generator.

The above regulators and allow to replace the balance-spiral bodies that equip the majority of mechanical watches, offering higher accuracy. Ideally, it would be desirable to modify an existing mechanical movement by replacing the conventional regulating member with one of these new regulating members. However, although the dimensions of the generator are generally compatible with those of existing balances, it is not possible to easily place the printed circuit which carries the coils and the control electronics. Therefore, it is generally necessary to completely change the design of the mechanical movement to place the regulating member.

On the other hand, the mounting of this regulating organ is generally difficult. The rotor must be assembled at the same time as the rest of the gear with which it meshes; then, the stator coils must be mounted facing the rotor. EP 0 851 322 certainly provides a simplification of the assembly, allowing to slide a printed circuit carrying the stator coils and the control electronics around the axis of the rotor already mounted. This simplification is however at the cost of a loss of energy efficiency. On the other hand, the assembly of the printed circuit around the rotor, in a movement almost completely assembled, is particularly delicate. It is also necessary to provide sufficient space near the stator coils for the portion of the printed circuit dedicated to quartz and the other elements of the control electronics; this place is often unavailable near the rotor.

Brief summary of the invention

An object of the present invention is therefore to provide an electronic controller for a wristwatch free of these limitations.

According to the invention, these objects are attained in particular by means of a regulating member for a wristwatch, comprising: a generator comprising a rotor provided with permanent magnets and a stator provided with a plurality of coils; a first electronic circuit powered by the generator and for adjusting the speed of rotation of the rotor; a second circuit for electronically connecting said coils of the generator; the first circuit and the second circuit constituting two distinct modules separated geographically from one another and electrically connected to each other.

This solution makes it possible to separate the circuit connecting the coils of the generator of the electronic circuit; both circuits are electrically connected to one another by means of conductive tracks.

Thus, it is possible to realize the electronic speed control circuit and the connection circuit of the generator coils in the form of two separate modules, that is to say of two elements that can be manufactured, stored, mounted, tested and / or marketed independently of one another, and which can be easily moved relative to each other.

The second circuit allows for example to connect the electrical coils together, and / or to mount them on a support with conductive tracks for connecting these coils to other components. The second circuit may comprise a printed circuit.

The first circuit may comprise a printed circuit and various electronic components on this printed circuit.

This solution allows to deport the electronic circuit in another place on the movement. It is also possible to replace only the generator, or only the electronic circuit, if only one of these two modules is defective. This modular construction also makes it possible to use a given generator with different electronic circuits, or the same electronic circuit with different generators.

The conductive tracks connecting the printed circuit which carries the coils with the printed circuit which carries the electronic control circuit may be placed on a printed circuit, for example a flexible printed circuit. It is also possible to connect the printed circuit which carries the coils with the printed circuit which carries the electronic control circuit by means of cables, for example of flat cables. This connection can be removable.

The rotor is advantageously removable, so as to slide its axis between the stator coils. In one embodiment, the rotor comprises two rotor plates on either side of the stator and connected by the axis of the rotor which passes between the coils. At least one of the rotor platens may be in a disassembled condition when the rotor is assembled, and then mounted laterally on the shaft. In this way, it is not necessary to provide a space between the adjacent coils greater than the diameter of the rotor axis; the coils can even be contiguous.

Brief description of the figures

Examples of implementation of the invention are indicated in the description illustrated by the appended figures in which: <tb> Fig. 1 <SEP> illustrates an exploded view of the generator according to the invention. <tb> Fig. 2 <SEP> illustrates a perspective view of the assembled generator according to the invention. <tb> Fig. 3 <SEP> illustrates a perspective view of the electronic control circuit according to the invention. <tb> Fig. 4 <SEP> illustrates a perspective view of a watch movement with a generator and an electronic control circuit according to the invention.

Example (s) of embodiment of the invention

A controller for wristwatch according to the present invention comprises a generator M and a first circuit 8, generally mounted on a first printed circuit 80, powered by the generator M and for adjusting the generator.

An example of a generator according to the invention is shown exploded in Figure 1 and assembled in Figure 2. The illustrated generator comprises a stator 1 and a rotor 2. The stator comprises a plurality of coils 10, six in this example, angularly spaced from each other and electronically connected via a second circuit 11. This second circuit 11 is preferably also a printed circuit, for example a flexible printed circuit, comprising conductive tracks 110 for connecting the coils together and to a third printed circuit 6 described below. Alternatively, the coils 10 may be electronically bonded in a modular manner but without the need for a plate of a printed circuit.

The coils 10 are preferably regularly spaced angularly about the axis 20. The distance between two adjacent coils is less than the diameter of the rotor axis; advantageously, the coils are contiguous to increase the magnetic coupling between the coils 10 of the stator and the permanent magnets of the rotor.

A chassis 3 in injected synthetic material is used to fix the printed circuit 11 on the plate or on a bridge of the watch movement, by means of screws passing in the earpieces 30. The printed circuit 11 is driven or glued in the frame 3. Other mechanical fastening modes are also possible (for example by clipping).

The rotor 2 comprises a first rotor plate 22a and a second rotor plate 22b. The two rotor plates are intended to rotate on either side of the stator. They are interconnected and rotated by a rotor axis 20 which passes into the gap between the coils 10 and which is driven by means of a pinion not shown by the work train of which it adjusts the running.

Each rotor plate 22a, 22b is provided with permanent magnets 21a, respectively 21b generating a rotating magnetic field which induces an alternating current in the coils 10 when the rotor rotates. The permanent magnets 21a, 21b may be constituted by discrete magnets or by a magnetized ring. In a variant, the rotor plates 22a, 22b are magnetized and therefore directly constitute the permanent magnets.

At least one of the two rotor plates 22a and / or 22b is removable to allow the insertion of the rotor axis 20 in the gap in the center of all the coils 10 of the stator. In the example of Figure 1, the lower rotor plate 22b is removable. It is also possible to provide a removable upper rotor plate 22a, or the two removable rotor plates.

The lower rotor plate 22b has an opening 220b which allows to insert the rotor axis 20. The rotor plate 22b is held along the axis 20 between a bearing of this axis and a ring 23b which can be chased or clipped on this axis. In variants, the rotor plate 22b can be driven on the axis of the rotor 20 without the need to use the ring 23b.

The surface of the printed circuit of the second circuit 11 carrying the coils 10 of the stator 1, as well as the dimensions of the frame 3, are preferably substantially of the same dimension as the rotor 2. In particular, the circuit 11 does not include Preferably, no other electronic component except the coils 10. Thus, it is possible to place this generator in place of the sprung-balance member of a number of existing mechanical movements.

The speed of rotation of the rotor is regulated by the first electronic circuit 8 which is preferably also mounted on a printed circuit 80 as illustrated in FIG. 3. It is electrically powered by the currents induced in the coils 10 by the rotating magnetic field generated by the rotation of the permanent magnets 21a, 21b. The electronic circuit 8 may be, for example, in accordance with the circuit described in EP 816 955 and comprises an asic electronic circuit 82 for comparing the frequency of the signal induced in the coils 10 with a frequency delivered by a quartz oscillator 81. The elements 83 are capabilities used for multiplication and voltage straightening.

The first circuit 8 is electrically connected to the second circuit 11 carrying the stator by electrically conductive tracks 60. In the illustrated example, these tracks are constituted on a third circuit 6 in the form of a flexible printed circuit 60. third printed circuit 60 may be independent, or constitute a portion of the printed circuit of the second circuit 11, as illustrated. It is also conceivable to provide a third printed circuit 60 constituting a portion of the first printed circuit 80. According to variants, the conductive tracks 60 may be replaced by any other suitable electrical connection forms.

In the example shown, the electrical connection between the third flexible printed circuit 60 and the first printed circuit 80 is non-permanent and provided by a removable connector, for example at least one electrically conductive screw 61, but another type of detachable connector (eg caliper, or clipping) can also be used. Each of the two circuits 8 and 11 may also comprise a ground plane both connected to the plate 50 or to a bridge of the movement 5, to provide an electrical connection via this mass between these circuits. Fig. 4 schematically illustrates an assembled movement according to the invention. Only certain components are illustrated including the regulating member 2, 6, 8 and the barrel 7. Other components, including the wheel, etc., are not illustrated to simplify the figure.

With the regulating member of the present invention the generator M is modular and can be assembled outside the watch movement 5. Subsequently, the frame 3 is fixed to the plate or to a bridge, for example by means of screws in the atria 30, andthe second circuit 11 is then connected to the third circuit 6 by the removable connector.

A rotor portion 2a with a rotor plate 22a, the magnets 21a and the axis 20 is then slid into the gap in the center of the coils 10 of the stator; the second rotor plate 21b, 22b is then slid on the axis 20 on the other side of the stator 1, then maintained by the ring 23b driven or held on the axis 20. In a variant, the ring can be removed and the rotor plate can be driven directly on the axis.

Alternatively, it is possible to mount a part of the rotor, for example the elements 21a, 22a and the axis 20, before mounting the stator threaded around this axis. The second rotor plate is then fixed on the other side of the stator.

The first printed circuit 80 is then fixed on the plate or on a bridge of the movement 5, and then electrically connected to the third printed circuit 6 by means of a connector, for example at least one screw providing an electrical connection between at least one track 60 of the third printed circuit and a track of the first printed circuit 80. It is also possible to place this first printed circuit and to connect it electrically before mounting the rotor. It is also possible to place this first printed circuit before mounting the second circuit board.

Reference numbers used in the figures

[0039] <Tb> M <September> Generator <Tb> 1 <September> Stator <tb> 10 <SEP> Stator Coils <tb> 11 <SEP> Second printed circuit for stator <tb> 110 <SEP> Electrically conductive tracks out of 11 <Tb> 2 <September> Rotor <tb> 2a <SEP> Upper part of the rotor <tb> 2b <SEP> Lower part of the rotor <tb> 20 <SEP> Rotor shaft <tb> 200b <SEP> Second span on the rotor axis <tb> 21a <SEP> First permanent magnets <tb> 21b <SEP> Second permanent magnets <tb> 22a <SEP> First rotor plate <tb> 22b <SEP> Second rotor plate <tb> 220b <SEP> Opening in the second rotor plate <tb> 23a <SEP> First ring <tb> 23b <SEP> Second ring <Tb> 3 <September> Chassis <tb> 30 <SEP> Chassis mounting loops <Tb> 5 <September> Movement <Tb> 50 <September> Platinum <tb> 6 <SEP> Third flexible printed circuit <tb> 60 <SEP> Electrically conductive tracks out of 6 <Tb> 7 <September> Barrel <tb> 8 <SEP> Electronic circuit <tb> 80 <SEP> First printed circuit for 8 <Tb> 81 <September> Quartz <Tb> 82 <September> Asia <Tb> 83 <September> Capacitors

Claims (22)

1. Regulator body for a wristwatch, comprising: a generator (M) comprising a rotor (2) provided with permanent magnets (21a, 21b) and a stator (1) provided with a plurality of coils (10); a first electronic circuit (8), powered by the generator (M) and for adjusting the speed of rotation of the rotor (2); characterized by a second circuit (11) for electronically connecting said coils (10) of the generator (M); the first circuit and the second circuit constitute two distinct modules separated geographically from one another and electrically connected to each other. 2. Control element according to claim 1, wherein the first electronic circuit (8) is mounted on a first printed circuit (80) and the second circuit (11) is mounted on a second printed circuit. 3. Control member according to one of claims 1 to 2, wherein the first circuit (8) and the second circuit (11) are electrically connected to one another removably. 4. Control element according to one of claims 1 to 3, wherein the first circuit (8) and the second circuit (11) are electrically connected to each other by means of conductive tracks (60). The controller according to claim 4, wherein said conductive tracks (60) are mounted on a third flexible printed circuit (6). 6. Control member according to one of claims 1 to 5, wherein the rotor comprises an axis (20) and two rotor plates (22a, 22b) provided with said permanent magnets (21a, 21b), at least one of said rotor plates (22b) being removable for mounting or dismounting the rotor. 7. Regulating body according to claim 6, comprising at least one removable ring (23a, 23b) for axially fixing at least one rotor plate (22a, 22b) on said axis (20). 8. Control member according to claim 7, said axis having a bearing surface (200b), one of said rotor plates (21b) being positioned axially between said bearing surface (200b) and said removable ring (23b). 9. Control member according to one of claims 6 to 8, said coils (10) being regularly spaced angularly about said axis (20). 10. Control member according to claim 9, the distance between two adjacent coils being less than the diameter of the axis of the rotor (20). 11. Control member according to one of claims 2 to 10, comprising a frame (3) for the removable attachment of the second printed circuit (11) on a plate or a motion bridge. 12. Control member according to one of claims 4 to 11, the second printed circuit (11) and the third printed circuit (6) constituting a single piece. 13. Control member according to one of claims 4 to 12, the first printed circuit (80) and the third printed circuit (6) being electrically connected to one another removably by means of a connector (61). ). 14. Regulating body according to claim 13, said connector being constituted by a screw (61 for fixing the third printed circuit (6) or by a clipping system or by plugging. 15. Regulating body according to one of claims 5 to 14, the first printed circuit (80) and the second printed circuit (11) each comprising a ground plane and electrical connection means of said ground plane to a platinum (50). ) or a movement bridge (5). 16. A method of assembling a regulating member for a wristwatch, comprising: mounting the rotor (2) and the stator (1) of a generator (M), the stator having a plurality of coils (10) mounted on a second circuit (11); mounting a first circuit (80) with an electronic speed adjusting circuit (8) of the rotor (2); electrical connection of the first printed circuit (80) and the second circuit (11). 17. The method of claim 16, wherein the first electronic circuit (8) is mounted on a first printed circuit (80) and the second circuit (11) is mounted on a second printed circuit. 18. Method according to one of claims 16 or 17, the electrical connection of the first circuit (80) and the second circuit (11) involving a third flexible printed circuit (6). 19. Method according to one of claims 16 or 17, the electrical connection of the first circuit (80) and the circuit (11) involving an electrically conductive screw (61) or a clipping system or plugging. 20. Method according to one of claims 16 to 19, said rotor comprising two rotor plates (22a, 22b) each provided with permanent magnets (21a, 21b) and connected to each other by a rotor axis ( 20), the mounting of the rotor and the stator comprising mounting said rotor shaft (20) and a first rotor plate (22a), mounting the stator (1), and then mounting the second rotor plate (22b) on said rotor axis (20). 21. Method according to one of claims 16 to 20, said rotor comprising two rotor plates (22a, 22b) each provided with permanent magnets (21a, 21b) and connected to each other by a rotor axis ( 20), the mounting of the rotor and the stator comprising mounting the stator (1), mounting the rotor shaft (20) and a first rotor plate (22a), mounting the stator (1), and mounting the second rotor plate (22b) on said rotor axis (20) on the side of said stator (1) opposite to the first rotor plate (22a). 22. Method according to one of claims 20 or 21, the mounting of the second rotor plate (22b) on the axis of the rotor (20) comprising the insertion of the rotor shaft (20) into an opening (220b) through the second rotor plate, then maintaining the second rotor plate (22b) on the axis of the rotor (20) by means of a ring (23b) or by driving or gluing directly from the plate.