A horological movement equipped with a mechanical balance resonator and an electromagnetic regulator provided with a coil integrated into the balance.
This application is based on and claims priority under 35USC 119 from European Patent Application No. 19166996.9 filed Apr. 3, 2019, which is incorporated herein by reference in its entirety.
The invention relates to the field of watchmaking. More specifically, it relates to a horological movement intended to equip a watch and comprising:
The operation of a horological movement, and its ability to tell the time with precision, depends on the precision of its mechanical resonator, that is to say on the precision—and the constancy—of its frequency of oscillation.
However, it is known that various factors can affect the oscillation frequency of a mechanical resonator:
To limit the variations in the oscillation frequency of the mechanical resonator, it is known to equip the movement with an electromagnetic regulator which takes part of the mechanical energy from the balance, converts it into electricity, and induces on the balance an electromotive or counter-electromotive force depending on whether it is necessary to increase its oscillation frequency or, on the contrary, to decrease it to maintain it within a range allowing to guarantee the precision of the movement.
The problem of regulating the oscillation frequency of a mechanical resonator is well detailed in the Swiss patent application CH 713 306, which moreover proposes, in order to solve it, a regulating device provided with a measuring device arranged to determine whether the mechanical resonator is affected by a gain or a loss, and with a regulating impulse application device arranged to be able to selectively apply to the mechanical resonator a first braking impulse or, respectively, a second braking impulse.
Concretely, the regulation system comprises:
If the solution proposed by the Swiss patent CH 713 306 effectively solves the problem of regulating the mechanical resonator, it poses several new problems:
A purpose of the invention is to provide a solution to these problems.
First, to achieve this purpose, a horological movement is proposed, comprising:
This movement has a size similar to a conventional mechanical movement, while solving the problem of magnetic coupling (in particular thanks to the immobility of the permanent magnets).
Various additional features can be provided, alone or in combination.
Thus, for example, the cavity is blind on the side of at least one of the faces of the balance.
The regulator may comprise a pair of coils. These coils are preferably diametrically opposite but, in some configurations, they can be angularly offset by 120° for example.
The electromagnetic regulator preferably comprises capacitors coupled to the electronic circuit.
A cover is advantageously mounted on the balance to close the cavity.
The (or each) permanent magnet is preferably made of a neodymium-iron-boron alloy.
According to various embodiments, the electromagnetic regulator comprises:
Second, a watch equipped with a movement as presented above is proposed.
Other objects and advantages of the invention will appear in light of the description of an embodiment, made below with reference to the appended drawings wherein:
The watch 1 comprises a horological movement 6 designed to indicate at least the hours and the minutes. The movement 6 is of the mechanical type (that is to say that the energy is supplied by a barrel spring); its winding can be manual (that is to say that the coiling of the barrel spring is performed manually by means of a winding-mechanism) or automatic (that is to say that the coiling of the barrel spring results from the rotation of an oscillating mass).
The movement 6 comprises:
The watch 1 further includes a crystal and a back (not shown), fixed to the middle part 2 on the side, respectively, of a front face 9 (where the information intended for the wearer are displayed) and of a rear face 10 (against the wearers wrist).
Most of the components of the movement 6 are on the side of the plate 7 turned to the rear face 10 of the middle part 2 (in other words, the plate 7 is mounted upside down in the middle part 2). Consequently, in what follows, the term “upper” designates a direction oriented towards the rear face 10 of the middle part 2, while the term “lower” designates a direction oriented towards its front face 9.
Conventionally, the mechanical resonator 8 comprises, first, an oscillating balance 11 rotatably mounted relative to the plate 7 about an axis 12. More specifically, the balance 11 is mounted between the plate 7 and a balance bridge 13 fixed thereon. The plate 7 incorporates a lower bearing 14 wherein a lower end of the axis 12 is fitted. The balance bridge 13 incorporates an upper bearing 15 wherein an upper end of the axis 12 is fitted.
The balance 11 performs a flywheel function. It has an upper face 16 and a lower face 17 which jointly delimit at least one inner cavity 18. The balance 11 can be made of brass. However, it is preferably made of a material which does not conduct electricity, for example of ceramic, quartz, silicon or of a polymer to prevent eddy current loss.
According to a preferred embodiment illustrated in the drawings, and in particular in
As illustrated in particular in
Second, the mechanical resonator 8 comprises a spiral spring 22 coupled to the balance 11. The spiral spring 22 is for example made of silicon, quartz, diamond or any other non-magnetic material known to the person skilled in the art. The spiral spring 22 has a first end 23 fixed relative to the plate 7, and a second end secured to the balance 11. More specifically, the first end 23, outside the spiral spring 22, is trapped in a stud holder 24 secured to the upper bearing 15. The second end, inside the spring, is secured to the axis 12 of rotation of the balance 11.
The mechanical resonator 8 is intended, by the alternating rotation of the balance 11 accompanied (and constrained) by the compression-detent cycles of the spiral spring 22, to make the rotation of a train for transmitting a motor torque (produced by a barrel spring which is not shown) to display organs (typically hands) sequential and regular.
The coupling of the mechanical resonator 8 to the transmission train is ensured by an escapement mechanism 25 which comprises:
While mechanical movements are highly appreciated by watchmaking enthusiasts for their authenticity, however they remain less precise than quartz movements, due to the potential variations in the rate of mechanical resonators.
The rate of the mechanical resonator 8 can in particular be affected by the coiling level of the barrel spring, the ambient temperature or else the spatial orientation of the watch 1.
While remaining mechanical, that is to say drawing its motive energy from a spring, the movement 6 is made more precise being equipped with a regulator 29 of the electromagnetic type which corrects any variations in the rate of the mechanical resonator 8.
More specifically, the electromagnetic regulator 29 is coupled to the mechanical resonator 8 to regulate the frequency of the oscillations of the balance 11. This electromagnetic regulator 29 comprises:
As illustrated in particular in
The magnet 30 (or the magnets 30) generate(s) a permanent (that is to say the value of which is invariable in time) and stationary (that is to say the value of which is invariable at each point in space, using the plate 7 as a reference). This magnetic field is partially illustrated in dashed lines in
The magnet 30 (or each magnet 30) is advantageously made of a neodymium-iron-boron alloy, which provides the advantage of generating a strong magnetic field while being of contained volume (and mass).
The magnet 30 (or each magnet 30) is preferably at least partly (and preferably totally, even totally) housed in a hollow 34 formed in the plate 7 (or in the balance bridge 13).
The electromagnetic regulator 29 preferably comprises at least one pair of magnets 30 fixedly mounted relative to the plate 7. These magnets 30 can be mounted side by side on the plate 7, or on the balance bridge 13.
According to a particular embodiment, the movement 6 comprises at least two magnets 30 opposite each other, namely:
According to a particular embodiment illustrated in particular in
In this case, the upper magnets 30 are advantageously positioned in line with the lower magnets 30. The opposite faces of the upper magnets 30 and of the lower magnets 30 are advantageously of the same polarity, so as to obtain a good local concentration of the magnetic field, and field lines oriented perpendicular to the plane swept by the balance 11.
Thanks to the use of neodymium-iron-boron alloy, the magnets 30, while generating a strong magnetic field, have a limited volume which allows their discrete integration in the plate 7 and/or in the balance bridge 13. In fact, it is even possible to make them invisible to the naked eye. It is also possible to mask them by means of one or more chip(s) 35 which may each, furthermore, play the role of a pole piece to concentrate the magnetic field generated by the magnets.
The magnets 30 can be arranged in various configurations, in addition to those which have just been described. Thus, it may be advantageous to arrange the magnets 30 according to a configuration, illustrated in
According to a preferred embodiment illustrated in
The passage of the (or each) coil 31 in the magnetic field generated by the magnet(s) 30 induces therein a current which powers the electronic circuit 33 and the quartz resonator 32. By reverse piezoelectric effect, the quartz resonator 32 vibrates at a predetermined fixed frequency and provides a clock rate to the electronic circuit 33. The electronic circuit 33 is programmed to measure the frequency of the oscillations of the balance 11 (which result in electrical impulses) and to compare them with a predetermined reference frequency, derived from the clock rate provided by the quartz.
As soon as the oscillation frequency of the balance 11 is decreed different from the reference frequency, the electronic circuit 33 imposes on the terminals of the coils 31 a voltage producing a counter-electromotive force which either increases the rotation frequency of the balance 11 (when this frequency is decreed lower than the reference frequency), or decreases it (when this frequency is decreed higher than the reference frequency), according to the instant at which this voltage is applied.
It will be noted that it is preferable that the distance between the quartz resonator 32 and the circuit 33 is small, so as to minimise any interference.
A magnetic regulation method of the oscillation frequency of the mechanical resonator 8 is proposed in patent application CH 713 306.
According to an embodiment illustrated in
It is the passage of one of the coils 31 in line with one of the magnets 30 (or with a pair of magnets 30) at the equilibrium point of the balance 11 (corresponding to the maximum speed thereof during the running of the movement 6) which, by electromagnetic induction, generates a current in the circuit 33. The passage of the other coil 31 in line with one of the magnets 30 (or a pair of magnets 30) is detected by the circuit 33 to ensure the regulation.
As illustrated in the drawings, various configurations of the balance 11 are possible:
Although two coils 31 are preferable, the electromagnetic regulator 29 may comprise only one coil 31 (
The combinations are possible:
As illustrated in the drawings, the regulator 29 advantageously comprises capacitors 36 coupled to the circuit 33 and whose function is double: straightening the voltage across the terminals of the circuit 33; providing a gain on this voltage by increasing the value.
In the example illustrated in particular in
It may be necessary to poise the masses on the balance 11. To this end, it can be pierced with hollows or holes, distributed so as to compensate for the disequilibrium induced by the embedded components (in particular the coils 31, the crystal resonator 32, the circuit 33 and the capacitors 36). Alternatively, or in combination, inertia-blocks 38, the number and/or position of which can be adjustable, can be mounted on the balance 11 (typically on the felloe 20).
The architecture which has just been described (in all its possible configurations) has several advantages.
Firstly, the electromagnetic regulator 29 is completely hidden, and invisible to the wearer of the watch 1, for the benefit of its aesthetics. This results from the fact that the movable components of the regulator 29 (coils 31, quartz resonator 32, circuit 33, capacitors 36) are included in the inner cavity 18 of the balance 11. These movable components are hidden from the sight of the wearer either by the blind face of the balance 11 (here the lower face 17), or by the cover 37. As for the magnets 30, they are also invisible (or at the very least discreet) by being masked either by the mass of the plate 7, or by the mass of the balance bridge 13, or by a chip 35.
Secondly, the inclusion of the space-saving magnet 30 (or magnets 30) in the plate 7 and/or in the balance bridge 13 does not require any particular modification of their shape, and particularly does not require to be thickened.
Thirdly, the inclusion of the coil(s) 31, the quartz resonator 32 and the electronic circuit 33 in the balance 11 (and more specifically in the felloe 20) does not generate any additional thickness. It may be necessary to widen the felloe 20 or the arms 21 where appropriate, but this widening does not affect the overall size of the balance 11.
Fourthly, since the magnets 30 are fixed, the magnetic field generated is permanent and stationary, without being affected by undesirable variations. As the coils 31 are in turn passive when they are outside the magnetic field generated by the magnets 30, the frequency of rotation of the balance 11 is not affected by the possible presence of metal parts in its immediate environment.
Number | Date | Country | Kind |
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19166996.9 | Apr 2019 | EP | regional |