This application claims priority from European Patent application 16158884.3 of Mar. 7, 2016, the entire disclosure of which is hereby incorporated herein by reference.
The invention relates to a bimetallic device sensitive to temperature variations and particularly to such a device comprising two materials, for which the difference between the expansion coefficients allows a variation in curvature according to the temperature change.
Bimetallic devices are known for manufacturing compensating balance wheels with a cut-out rim that is formed by two half-rings, each made up of a first steel layer soldered on a second brass layer. Thus formed, the rim opens when the temperature drops and closes when the temperature rises in order to compensate for the effect of the temperature on the flexibility of a balance spring.
The object of the present invention is to overcome all or part of the disadvantages of the known devices by proposing an alternative bimetallic device to those described above.
To this end, the invention relates to a bimetallic device comprising at least one first silicon-based layer and at least one second metal-based layer, characterised in that said at least one first and at least one second layers are arranged to attach to each other so that the curvature of the bimetallic device varies according to the temperature.
It is thus understood that the difference in the expansion coefficient of the bimetallic device is between approximately 10 and 30 10−6 K−1 depending on the materials used. This difference, which is much higher than that of the steel-brass pairing of approximately 6 10−6 K−1, allows the bimetallic device to have higher temperature sensitivity.
Furthermore, it is possible to work the silicon-based and metal-based materials into a wide variety of shapes and with high manufacturing precision. By way of an example, dry etching the silicon-based material and electroforming the metal-based material on the silicon-based material provides manufacturing precision of approximately one micron.
According to further advantageous variants of the invention:
said at least one first silicon-based layer comprises monocrystalline silicon, doped monocrystalline silicon, polycrystalline silicon, doped polycrystalline silicon, porous silicon, silicon oxide, quartz, silica, silicon nitride or silicon carbide;
said at least one second metal-based layer comprises silver, magnesium, lead, thallium, nickel, copper, zinc, gold, aluminium or indium or vulcanite;
under the ambient temperature and pressure conditions the bimetallic device forms a curved strip;
said at least one first and at least one second layers are attached to each other by nesting and/or by using a bonding material and/or said at least one second layer is electroformed on said at least one first layer;
the bimetallic device comprises a fixing base integral with one of said at least one first and at least one second layers that allows the bimetallic device to be mounted on a part;
the bimetallic device comprises a block integral with the end of one of said at least one first and at least one second layers that allows the influence of the bimetallic device to be enhanced;
the bimetallic device comprises adjustable stop means that allow the minimum and/or maximum curvature variations of the bimetallic device to be limited;
the bimetallic device comprises a plurality of first layers arranged to attach to a single second layer, or conversely, a plurality of second layers arranged to attach to a single first layer.
According to a first embodiment, the invention relates to a compensating balance wheel comprising at least one bimetallic device according to any of the preceding variants.
Consequently, the bimetallic device according to the invention particularly can be advantageously used to provide a resonator with main or auxiliary thermal compensation via the balance wheel.
According to a first alternative, the compensating balance wheel comprises a cut-out rim that is formed by two bimetallic devices, each connected by at least one arm to a central opening in order to modify the inertia of the balance wheel according to the temperature.
According to a second alternative, the compensating balance wheel comprises a one-piece rim that is connected by at least one arm to a central opening and said at least one bimetallic device is mounted on the rim in order to modify the inertia of the balance wheel according to the temperature.
According to a third alternative, the compensating balance wheel comprises a one-piece rim that is connected by at least one arm to a central opening and said at least one bimetallic device is mounted on said at least one arm in order to modify the inertia of the balance wheel according to the temperature.
According to a second embodiment, the invention relates to a compensating index comprising at least one bimetallic device according to any of the preceding variants.
Consequently, the bimetallic device according to the invention particularly can be advantageously used to provide a resonator with high-precision auxiliary thermal compensation through the indexing.
According to a first alternative, the compensating index thus can comprise a gap that is arranged to receive a hairspring and is connected to said at least one bimetallic device in order to modify the position of the gap according to the temperature.
According to a second alternative, the compensating index can comprise a gap that is arranged to receive a hairspring, the size of the gap being controlled by said at least one bimetallic device in order to modify the gap according to the temperature.
According to a third embodiment, the invention relates to a temperature sensor comprising at least one bimetallic device according to any of the preceding variants.
Consequently, the bimetallic device according to the invention particularly can be advantageously used for high-precision temperature measurement.
The temperature sensor thus can comprise a pointer and a flexible device for tracking the movement of said at least one bimetallic device in order to modify the position of the pointer according to the temperature.
Finally, according to a fourth embodiment, the invention relates to a compensating balance spring comprising at least one bimetallic device according to any of the preceding variants.
Consequently, the bimetallic device according to the invention particularly can be advantageously used to provide a resonator with high-precision auxiliary thermal compensation through the pinning point.
The compensating balance spring thus can comprise an overcoil connected to said at least one bimetallic device that is arranged to be fixed to a beam in order to modify the active length of the compensating balance spring according to the temperature.
Further features and advantages will become apparent from the following description, which is provided by way of a non-limiting example, with reference to the accompanying drawings, in which:
The invention relates to a bimetallic device sensitive to temperature variations. The invention has been developed for horological applications for auxiliary thermal compensation or for mechanical temperature measurement. However, the bimetallic device cannot be limited to applications in the horological field.
The bimetallic device according to the invention comprises at least one first silicon-based layer and at least one second metal-based layer.
Said at least one first silicon-based layer can comprise monocrystalline silicon, doped monocrystalline silicon, polycrystalline silicon, doped polycrystalline silicon, porous silicon, silicon oxide, quartz, silica, silicon nitride or silicon carbide. Of course, when the silicon-based material is in a crystalline phase, any crystalline orientation can be used.
Furthermore, said at least one second metal-based layer can comprise silver and/or magnesium and/or lead and/or thallium and/or nickel and/or copper and/or zinc and/or gold and/or aluminium and/or indium and/or vulcanite.
According to the invention, said at least one first and at least one second layers are arranged to attach to each other so that the curvature of the bimetallic device varies according to the temperature. Indeed, the strip that is formed by said at least one first and at least one second layer curves with the increase in temperature on the side where the expansion coefficient is the weakest.
Furthermore, this particularly means that the bimetallic device can comprise a plurality of first layers arranged to attach to a single second layer or, alternatively, that a plurality of second layers are arranged to attach to a single first layer.
Thus, for the horological applications, the aim is to find a difference in the expansion coefficient of the bimetallic device of between approximately 10 and 30 10−6 K−1 and to find low sensitivity to the magnetic fields. In a preferred manner, the monocrystalline silicon—nickel/phosphorus alloy pairing is used.
Therefore, the monocrystalline silicon comprises a linear expansion coefficient α at 25° C. of approximately 2.5 10−6 K−1, whereas the metals or metallic alloys generally comprise linear expansion coefficients α at 25° C. that are substantially between 13 and 32 10−6 K−1. It is thus understood that the difference in expansion coefficient of the bimetallic device allows high temperature sensitivity.
According to the invention, under the ambient temperature and pressure conditions (ATPC) that correspond to a temperature of 25° C. and to a pressure of 100 kPa, the bimetallic device preferably forms a curved strip.
A first example of a bimetallic device 1 is shown in
As shown in
Of course, in a further or alternative manner, said at least one first and at least one second layers can be attached to each other by using a bonding material or by electroforming.
More specifically, in a further or alternative manner, the strip 7 can be rigidly connected by bonding or brazing said first 3 and second 5 layers or the second layer 5 can be electroformed on the first layer 3.
As shown in
According to the variants shown in
Alternatively,
According to a third variant shown in
Alternatively, the block 6 can be an inertia block fixed on the end of one of said at least one first and at least one second layers 3, 5 in the same way as the first and second adjustable stop means 15, 17. The inertia block thus can be formed from a third material, which is denser, for example, than said at least one first and at least one second layers 3, 5.
A first embodiment of the invention relates to a compensating balance wheel comprising at least one bimetallic device according to any of the preceding variants. It is thus understood that the bimetallic device according to the invention particularly can be advantageously used to provide a resonator, which may or may not comprise a compensating balance spring, with auxiliary or main thermal compensation at the balance wheel.
According to a first alternative shown in
It is thus understood that the bimetallic devices 25, 27 according to the invention are advantageously used to provide a resonator, which may or may not comprise a compensating balance spring, with auxiliary or main thermal compensation at the balance wheel. It is also understood that, depending on the thermal compensation to be provided, the materials and the geometries that are used for the bimetallic device 25, 27 and, possibly, for the block/inertia block 6 and/or the fixing base 9 and/or the stop means 11, 13, 15, 17 will be selected in order to adjust the working of the timekeeping movement as precisely as possible. It is also possible for the position of the bimetallic device 25, 27 to be adjusted, i.e. its fixing position relative to the opening 24, as well as the angle that it forms relative to the arm 22, in order to optimise its use.
Of course, a plurality of bimetallic devices 25, 27 can be distributed over the same section of the cut-out rim 23 or at said at least one arm 22. It is also possible, in a manner similar to the example of
According to a second alternative shown in
Depending on the choice of materials for the first and second layers, it is possible to determine whether to fix the bimetallic device to the internal diameter of the rim, as shown in
In the example of
It is also possible, as shown in
It is thus understood that the bimetallic devices 45, 55 according to the invention are advantageously used to provide a resonator comprising a compensating balance spring with auxiliary thermal compensation at the balance wheel. It is particularly understood that, depending on the auxiliary compensation to be provided, the materials and the geometries that are used for the bimetallic device 45, 55 and, possibly, for the block/inertia block 6 and/or the fixing base 9 and/or the stop means 11, 13, 15, 17 will be selected in order to adjust the working of the timekeeping movement as precisely as possible. It is also possible to adjust the position of the bimetallic device 45, 55 on the rim 33 in order to optimise its influence.
In the example of
It is also possible, in a manner similar to the example of
It is thus understood that the bimetallic devices 35 according to the invention are advantageously used to provide a resonator comprising a compensating balance spring with auxiliary thermal compensation at the balance wheel. It is particularly understood that, depending on the auxiliary compensation to be provided, the materials and the geometries that are used for the bimetallic device 35 and, possibly, for the block/inertia block 6 and/or the fixing base 9 and/or the stop means 11, 13, 15, 17 will be selected in order to adjust the working of the timekeeping movement as precisely as possible. It is also possible to adjust the position of the bimetallic device 35 on the rim 33 in order to optimise its influence.
According to a third alternative shown in
In the alternative of
It is also possible, in a manner similar to the example of
It is thus understood that the bimetallic devices 65 according to the invention are advantageously used to provide a resonator comprising a compensating balance spring with auxiliary thermal compensation at the balance wheel. It is particularly understood that, depending on the auxiliary compensation to be provided, the materials and the geometries that are used for the bimetallic device 65 and, possibly, for the block 6 and/or the fixing base 9 and/or the stop means 11, 13, 15, 17 will be selected in order to adjust the working of the timekeeping movement as precisely as possible. It is also possible to adjust the position of the bimetallic device 65 on each arm 62, i.e. its fixing position between the opening 64 and the rim 63, as well as the positioning relative to the length of the arm 62, i.e. the angle between the start of the bimetallic device 65 and the length of the arm 62, or the direction of the curvature of the bimetallic device (substantially parallel to the curvature of the rim 63 or opposite the curvature), in order to optimise its influence.
According to a second embodiment, the invention relates to a compensating index 71, 91 comprising at least one bimetallic device 75, 95 according to any of the preceding variants.
Consequently, the bimetallic device 75, 95 according to the invention advantageously can be used to provide a resonator with high-precision auxiliary thermal compensation through the indexing.
Indeed, the index is used to modify the daily working of the timepiece, by extending or shortening the active length of the balance spring of a balance wheel-balance spring resonator. The index is normally adjusted with low friction on the top balance-endpiece. The daily working of the timepiece is modified by turning the index. In order to simplify the adjustment, graduations are generally marked on the balance-cock that allow the effect of the alteration to be approximately assessed.
According to a first alternative shown in
More specifically, the bimetallic device 75 comprises a concentrically extending U-shaped strip that is formed by a single first layer and a single second layer. The bimetallic device 75 is mounted between the arm 72 supporting two pins 76 or, alternatively, an index key, forming the gap i, and a fixing ring 77 at the top balance-endpiece. As shown in
It is thus understood that the arm 72 and/or the pins 76 and/or a section of the strip of the bimetallic device 75 and/or the opening 74 and/or the fixing ring 77 can be integral.
Of course, a plurality of bimetallic devices 75 can be distributed between the arm 72 and the fixing ring 77, i.e. one between the opening 74 and the start of the pins 76 and one between the opening 74 and the fixing ring 77, for example. It is also possible, in a manner similar to the example of
It is thus understood that the bimetallic devices 75 according to the invention are advantageously used to provide a resonator comprising a compensating balance spring with auxiliary thermal compensation at the index. It is particularly understood that, depending on the auxiliary compensation to be provided, the materials and the geometries that are used for the bimetallic device 75 and, possibly, for the block/index block 6 and/or the fixing base 9 and/or the stop means 11, 13, 15, 17 will be selected in order to adjust the working of the timekeeping movement as precisely as possible. It is also possible to adjust the position of the bimetallic device 75 in order to optimise its influence.
According to a second alternative shown in
More specifically, the bimetallic device 95 comprises a U-shaped strip that is formed by a single first layer and a single second layer. The bimetallic device 95 is mounted on the arm 92 at one 93 of its ends and comprises a first pin 96 on its other end. A second pin 96 is mounted on the arm 92 opposite the first pin in order to form the gap i and an index tip 97 is mounted opposite the arm 92 relative to the opening in order to allow the index 91 to be adjusted.
It is thus understood that the arm 92 and/or the pins 96 and/or a section of the strip of the bimetallic device 95 and/or the opening 94 and/or the index tip 97 can be integral.
Of course, a plurality of bimetallic devices 95 can be distributed between the arm 92 and the index tip 97, i.e. by including a second device between the opening 94 and the start of the pins 96, for example. It is also possible, in a manner similar to the example of
It is thus understood that the bimetallic devices 95 according to the invention are advantageously used to provide a resonator comprising a compensating balance spring with auxiliary thermal compensation at the index. It is particularly understood that, depending on the auxiliary compensation to be provided, the materials and the geometries that are used for the bimetallic device 95 and, possibly, for the block/index block 6 and/or the fixing base 9 and/or the stop means 11, 13, 15, 17 will be selected in order to adjust the working of the timekeeping movement as precisely as possible. It is also possible to adjust the position of the bimetallic device 95 in order to optimise its influence.
It also can be contemplated that a bimetallic device of the type shown in
According to a third embodiment shown in
Consequently, the bimetallic device 85 according to the invention advantageously can be used for high-precision temperature measurement.
In the example of
More specifically, the bimetallic device 85 comprises a strip, which is formed by a single first layer and a single second layer and which is mounted in order to be in permanent contact with a feeler 80 of the flexible device 87 for tracking movement. As shown in
Of course, a plurality of bimetallic devices 85 can be used to indicate an average temperature value via a differential. It is also possible, in a manner similar to the example of
It is thus understood that the bimetallic devices 85 according to the invention are advantageously used to provide temperature measurement precision. It is particularly understood that, depending on the measurement precision to be provided, the materials and the geometries that are used for the bimetallic device 85 and, possibly, for the block 6 and/or the fixing base 9 and/or the stop means 11, 13, 15, 17 will be selected in order to adjust the operation of the temperature sensor as precisely as possible. It is also possible to adjust the position of the bimetallic device 85 in order to optimise its use.
Of course, the present invention is not limited to the example shown, but is susceptible to various variants and modifications that will become apparent to persons skilled in the art. In particular, increasing numbers of the components that are made for a time-keeping part are silicon-based. For this reason, any silicon-based component can be modified during manufacturing to integrate a bimetallic device according to the invention such as, for example, the balance spring or the escapement.
Thus, by way of an example, according to a fourth embodiment, the invention relates to a compensating balance spring comprising at least one bimetallic device. Indeed, the bimetallic device according to the invention particularly can be advantageously used to provide a resonator with high-precision auxiliary thermal compensation at the pinning point.
More specifically, the compensating balance spring thus can comprise an overcoil that is connected, as one-piece or not as one-piece, to said at least one bimetallic device that is arranged to be fixed to a beam in order to modify the active length of the compensating balance spring according to the temperature.
Number | Date | Country | Kind |
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16158884.3 | Mar 2016 | EP | regional |