瑞士专利CH712552A2 Clock axis.

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专利摘要:
The invention relates to a horological axis (1), in particular a balance shaft (1), comprising a first functional portion (2a; 2b) including at least one portion (221aa; 221b) of a tigeron (22a; 22b) and or at least one portion (211aa; 211b) of a pivot (21a; 21b), the first functional portion being ceramic and a first outer diameter (D1) of the first functional portion being less than 0.5 mm, or even less than 0.4 mm, or even less than 0.2 mm, or even less than 0.1 mm
公开号:CH712552A2
申请号:CH00766/17
申请日:2017-06-13
公开日:2017-12-15
发明作者:Linck Vannina
申请人:Rolex Sa；
IPC主号:

专利说明:

Description: [0001] The invention relates to a horological axis, in particular a balance shaft. The invention also relates to an oscillator or a watch movement or a timepiece comprising such an axis.
The balance shaft is an essential component of the watchmaking regulating member. The balance shaft comprises at each end a tigeron extending by a pivot. The balance shaft carries the spiral spring and oscillates on its pivots in bearings. During shocks, the tigers and pivots of the axis constituting areas of least mechanical resistance are provided to take up the efforts involved. Nevertheless, in some cases, especially during high intensity shocks, the pivots can be matched against each other. their respective bearing because of their small size, especially their small diameter.
The axis must therefore: • to have a high elastic limit not to deform plastically during major shocks, • to be tough not to break during major shocks, and • to be hard , mainly at the level of the pivots, so as not to wear or be marked during the current shocks, and in order to optimize the quality factor and the isochronism of the timepiece that it equips, the axis being constantly in motion.
[0004] The watch axes are traditionally cut in a 20AP steel, and then quenched. The pivots are then rolled to obtain the desired surface condition and surface hardness. The hardness typically reaches at least 700HV. The 20AP steel shafts or made of other metallic materials, whether they have been hardened or not, require this rolling operation at the pivots to ensure the manufacturing accuracy, the resistance over time, with respect to but also with respect to shocks, as well as to ensure the optimal functioning of the movement by controlling the tribological parameters. This operation, which consists of steps of polishing and surface hardening of the surface of the pivot, is complex and delicate, and requires a great know-how which is strongly related to the control of the process by the person skilled in the art who 'applied. In addition, 20AP steel contains lead (0.2% by weight) and will soon have to be replaced by another lead-free steel such as FinemacTM (or 20C1A). The manufacturing of these axes is identical: they are turned from bar before tempering, then heat-treated and tempered to increase the hardness. A relaxation annealing ensures a release of internal stresses and prevents these axes from breaking like glass during shocks. This steel has the main lack of hardness at the pivots and therefore also require a rolling operation to achieve the final properties required. These axes 20AP steel or Finemac are also ferromagnetic and can induce gait disturbances if the movements they are equipped with are subject to magnetic fields, residual magnetization.
Alternatives to these axes 20AP steel or Finemac exist, with austenitic steel pins or austenitic alloys based on cobalt or nickel hardened by carbon or nitrogen ion implantation. They are also rolled to improve their properties. According to the patent application EP 2 757 423, axes have been made in a 316L type austenitic stainless steel, in order to minimize sensitivity to magnetic fields, but the resistances obtained, as well as the hardnesses, are below characteristics required to ensure wear resistance. The solution of affixing a DLC (Diamond Like Carbon) type coating has been considered, but significant delamination risks have been identified. Similarly, nitriding or carburizing surface treatment to form nitrides or chromium carbides would have the intended effect in terms of hardening of the surface, but would result in a loss of corrosion resistance detrimental to the quality of the components and the product. The patent application EP 2 757 423 discloses a solution for hardening an austenitic steel or an alloy of austenitic cobalt or of an austenitic nickel alloy by means of a thermochemical treatment, aimed at integrating into the interstitial sites of the crystalline lattice of the alloy of carbon or nitrogen atoms to reinforce the material before proceeding to the rolling of the pivot, while limiting the risk of corrosion of the axis. The hardnesses thus reached are close to 1000 HV, which theoretically positions this type of parts to a better level than the 20AP steel parts.
Such axes, however, also require a rolling at the pivots to reach the final dimension, in particular to obtain a surface condition to obtain adequate performance in terms of chronometry. Such a solution is therefore not optimal insofar as it requires at least two axis processing steps: a superficial hardening step followed by a second rolling step.
An alternative described in the patent application EP 2 757 424 and to overcome the rolling is to constitute all or part of the axis, but in any case or pivots, metal material hardened by hard ceramic particles (metal matrix composite or MMC). It is a material partially composed of particles of hardness greater than or equal to 1000 HV, of size between 0.1 and 5 microns. The exemplary materials comprise 92% of the tungsten carbide (WC) particles embedded in a nickel matrix, which are mixed before being injected into a mold in the shape of the axis. After injection, the blank thus obtained is sintered and the axis is polished, especially at the pivots, using a diamond paste. A metal matrix composite axis with 92% WC and 8% nickel has a tenacity of 8 MPa.rn1'2 and a hardness greater than 1300 HV. In view of the typical dimensions of the pivots, of the order of 60 microns, and the importance of the concentricity and the surface condition, the use of composites comprising particles which are likely to become detached carries a risk . In fact, there is only a slight decline in the horological dimensions of the wear behavior of this type of material. It is to be feared that the detachment of the reinforcing particles does not pre-terminate the geometric integrity of the pivot or pivots.
The object of the invention is to provide a watch axis to overcome the drawbacks mentioned above and improve the watch axes known from the prior art. In particular, the invention proposes a hard and tenacious watch axis and whose manufacturing process is simplified.
For this purpose, a horological axis according to the invention is defined by claim 1.
Different embodiments of the watch axis according to the invention are defined by claims 2 to 9.
An axis-guide assembly according to the invention is defined by claim 10.
Different embodiments of the assembly according to the invention are defined by claims 11 and 12.
An oscillator according to the invention is defined by claim 13.
A watch movement according to the invention is defined by claim 14.
A timepiece according to the invention is defined by claim 15.
The appended figures represent, by way of example, three embodiments of a watch axis according to the invention, various embodiments of systems according to the invention and an embodiment of a timepiece according to the invention.
Fig. 1 is a view of a first embodiment of a timepiece according to the invention, comprising a first embodiment of an axis according to the invention.
Fig. 2 is a view of a first variant of a first embodiment of an axis-guide assembly according to the invention.
Fig. 3 is a view of a second variant of the first embodiment of the axis-guide assembly according to the invention.
Fig. 4 is a view of a second embodiment of the axis-guide assembly according to the invention.
Fig. 5 is a view of a second embodiment of the axis according to the invention.
Fig. 6 is a graph of the quality factor variations of a balance-balance oscillator in different watch positions, the oscillator being equipped with a conventional damping bearing.
Fig. 7 is a graph of the quality factor variations of a balance-balance oscillator in different watch positions, the oscillator being equipped with a ball bearing.
Fig. 8 is a view of a third embodiment of the axis according to the invention.
Fig. 9 is a sectional view along the plane A-A of FIG. 8 of the third embodiment of the axis according to the invention.
An embodiment of a timepiece 120 is described below with reference to FIG. 1. The timepiece is for example a watch, in particular a wristwatch. The timepiece comprises a watch movement 110, in particular a mechanical movement. The watch movement comprises an oscillator 100, in particular a balance oscillator 8 - spiral. The pendulum is for example driven on a balance axis 1.
The balance shaft 1 comprises a first functional portion 2a; 2b including: - at least one portion 221a; 221 b of a tigeron 22a; 22b, and / or - at least one portion 211a; 211b of a pivot 21a; 21b.
The first functional portion is ceramic and the first functional portion has a first outer diameter D1, for example a first outer maximum diameter, less than 0.5 mm, or even less than 0.4 mm, or even less than 0.2 mm, or even less than 0.1 mm.
In the first embodiment shown in FIG. 1, the axis 1 comprises a first pivot 21a, a first taper 22a, a portion 33 for receiving a plate 9, a plate 34 for receiving the balance 8, a portion 32 for receiving the balance 8, a portion 31 of receiving a shell of the spiral (not shown), a second pivot 21b and a second bolster 22b. Advantageously, the tigeron portion has a dimension greater than 0.1 mm, or even greater than 0.2 mm, or even greater than 0.25 mm in at least one direction, or even in all directions. Advantageously, the pivot portion has a dimension greater than 0.04 mm, or even greater than 0.05 mm, or even greater than 0.1 mm in at least one direction, or even in all directions. Preferably, the first portion of tigeron comprises a longitudinal section of the tigeron (or at least the outer surface of a section of the tigeron) over a length of at least 0.2 mm. Preferably, the first pivot portion comprises a longitudinal portion of the pivot (or at least the outer surface of a portion of the pivot) over a length of at least 0.1 mm.
In the first embodiment shown in FIG. 1, the axis 1 comprises two first functional portions 2a and 2b each including: - at least one portion 221a; 221b of a tigeron 22a; 22b, and / or - at least one portion 211a; 211 b of a pivot 21 a; 21 b.
In the first embodiment shown in FIG. 1, the first two functional portions are ceramic and each of the first two functional portions has a first outer diameter D1, for example a first maximum outside diameter, less than 0.5 mm, or even less than 0.4 mm, or even less than 0.2 mm, or less than 0.1 mm.
The first functional portion may provide various functions such as in particular: a guiding function, in particular pivoting and / or translational function, that is to say that the portion has a contact surface with another component; in particular a guide, to ensure the pivoting and / or the translation and that there is a contact and a relative movement between the portion and this other component, and / or - a function of reception, that is to say that the portion has a contact surface with another component to ensure the positioning and / or maintenance of the other component on the portion, and / or - a meshing function, that is to say that the portion has a tooth-shaped contact surface with another component to ensure meshing between the portion and this other component, and / or - a function of transmission of efforts or recovery of efforts, that is to say say that the portion is mechanically solicited.
In the first embodiment shown in FIG. 1, the first and second pivots 21a, 21b provide a pivoting function and a force recovery function in the event of impact or, more generally, in case of acceleration experienced by the timepiece equipped with the axis. The first and second tiberns 22a and 22b provide a force recovery function in case of impact or, more generally, in case of acceleration experienced by the timepiece equipped with the axis.
The axis may also have a second functional portion 3, in particular: a second functional receiving portion 31, 32, 33; 34 of a clock component, in particular of the balance 8, of the plate 9, of the spiral spring ferrule, or even of a toothed wheel or of another axis 6 in another embodiment which will be described below, or a second pivoting portion of a clock component, such as a wheel, on the axis in another embodiment, so as to allow this clockwork component to pivot with respect to the axis, or a second meshing portion, in particular a toothing, in another embodiment.
In the first embodiment shown in FIG. 1, the portions 31, 32 and 33 each provide a reception function.
Advantageously, the second functional portion has a second outer diameter D2, for example a second maximum outside diameter, less than 2 mm, or even less than 1 mm, or even less than 0.5 mm. Preferably, the second functional portion is ceramic.
Advantageously, the ratio of the dimension of the first diameter to the dimension of the second diameter is less than 0.9, or even less than 0.8, or even less than 0.6, or even less than 0.5, or even less than 0.4.
The fact that the first functional portion and / or the second functional portion is ceramic means that this functional portion is integrally ceramic. Preferably, the production of the functional portion of a material composed of ceramic grains bonded together by a non-ceramic matrix, such as a metal matrix, is excluded. By "ceramic" is meant a homogeneous or substantially homogeneous material, including at the microscopic level. Preferably, the ceramic is homogeneous in at least one direction, or even in all directions, over a distance greater than 6 pm, or even greater than 10 pm, or even greater than 20 pm. More preferably, the ceramic has no non-ceramic material in at least one direction, or even in all directions, over a distance greater than 6 pm, or even greater than 10 pm, or even greater than 20 pm.
Advantageously, the first functional portion has dimensions greater than 20 μm or 40 μm or 50 μm in at least one direction or in three directions perpendicular to each other and / or the first functional portion has a diameter equal to that of the axis at any point of this first functional portion and / or the first functional portion is between two planes perpendicular to the geometric axis of the axis.
Advantageously, the second functional portion has dimensions greater than 20 pm or 40 pm or 50 pm in at least one direction or in three directions perpendicular to each other and / or the second functional portion has a diameter equal to that of the axis at any point of this second functional portion and / or the second functional portion is between two planes perpendicular to the geometric axis of the axis.
Advantageously, the ceramic is predominantly or mainly (in mass or in mole) composed of: - zirconium oxide, and / or - alumina.
Thus, zirconium oxide and / or alumina may be the predominant elements in ceramics. Nevertheless, the proportion by weight or mole of zirconium oxide and / or alumina may be less than 50%.
Optionally, the ceramic comprises, in addition to zirconium oxide and / or alumina, one or more of the following elements: carbon nanotubes, graphene, fullerenes, yttrium oxide, cerium oxide, - zirconium carbide, - silicon carbide, - titanium carbide, - zirconium boride, - boron nitride, - titanium nitride and - silicon nitride.
Alternatively, the ceramic may be predominantly or mainly (in mass or in mole) composed of silicon nitride.
Thus, silicon nitride may be the predominant element in the ceramic. Nevertheless, the proportion by weight or mole of silicon nitride may be less than 50%.
Optionally, the ceramic comprises, in addition to the silicon nitride, one or more of the following elements: carbon nanotubes, graphene, fullerenes, zirconium oxide, aluminum oxide, yttrium oxide , - cerium oxide, - zirconium carbide, - silicon carbide, - titanium carbide, - zirconium boride, - boron nitride and - titanium nitride.
For example, the ceramic may be one of the ceramics of the table below:
It may be envisaged to make an axis from an extruded ceramic wire, using different diamond grinding wheels. At the end of these steps, the parts can be geometrically compliant and of sufficient hardness to do without post-processing.
Alternatively, the injection or pressing of a preform which only the ends would be ground optimizes the process, including a gain in manufacturing cycle time.
Alternatively, other manufacturing techniques can further improve the properties of the parts obtained, such as cold isostatic pressing (CIP), reducing the number of defects present in the material before it is machined. . This increases in particular its tenacity.
Because of the intrinsic properties of the aforementioned ceramics, extremely hard, the pivots are not marked during shocks and the performance is maintained over time. Advantageously, in case of significant impact, these pivots will not deform, a contrario steel pivots that can bend and thus affect the chronometry of the timepiece. Thus, ceramics as presented above allow to maintain the geometric integrity of the pivots in time.
The ceramics also offer the additional advantage of being non-magnetic, and not to influence the progress of the timepiece when it is subjected to a magnetic field, in particular a magnetic field greater than 32 kA / m. (400G).
Advantageously, the entire axis is made of ceramic. However, it is conceivable to limit the ceramic portion to the first functional portion which includes at least one pivot and / or at least one tigeron.
Advantageously, the first portion has a surface of revolution, in particular a cylindrical surface or a conical surface or a frustoconical surface or a curved generating surface. The tiger and the pivot may be confused or at least not be delimited by a straight border as a scope. For example, the tigeron and the pivot may be separated by a frustoconical surface or a curved generating surface.
Two variants of a first embodiment of an assembly 41 comprising an axis 1 as described above and at least one guide 51, in particular a bearing 51, the axis being intended to rotate or to rotate in the at least one bearing are respectively shown in FIGS. 2 and 3.
The guide may be in the form of a conventional damping bearing. Thus, in the first embodiment, the at least one bearing 51 comprises a pivoting stone 511 designed to cooperate with a cylindrical or frustoconical section of a pivot 21 'and a backstop 512 intended to cooperate with one end. 212 'of the pivot. The stones thus cooperate with the pivot 21 'to pivot and receive, or define axially, the axis in the guide.
In the first variant of the first embodiment of the assembly, the axis 1 comprises a pivot 21 'having a convex or convex end 212'.
In the second variant of the first embodiment of the assembly, the axis 1 comprises a pivot 21 "having an end 212" hollow or concave.
The fact of having ceramic axes, both hard and tenacious material, provides geometries that can optimize and sustain the contact at the pivot and the bearing in which it pivots, particularly at the level of pivot ends. This would be difficult to envisage with conventional alloys such as rolled 20AP steel where the risk of loss of wearing performance would be greater, particularly because of excessive contact pressures.
A second embodiment of an assembly 42 comprising an axis 1 as described above and at least one guide, in particular a bearing 52, the axis being intended to rotate or to pivot in the at least one guide, is shown in FIG. 4. In this second embodiment, the at least one guide 52 comprises a raceway 521 and balls 522, the balls cooperating by contact on a pivot 21 * with a conical end 212 * to guide the axis in the guidance. Of course, the end of the pivot 21 * could alternatively have a frustoconical surface. The balls thus roll on both the raceway and the pivot.
Figs. 6 and 7 illustrate the advantages of a ball bearing intended to cooperate with a balance-type oscillator. Indeed, we see in figs. 6 and 7, respectively obtained by measuring in different clock positions an oscillator cooperating with a conventional damping bearing and by measuring in different clock positions an oscillator cooperating with a ball bearing, that the operation of the oscillator oscillator cooperating with a ball bearing has quality factor deviations between the different clock positions lower than those induced by the operation of the oscillator cooperating with a conventional damping bearing.
However, it is essential, for the smooth operation of the pivoting and the reduction of gait deviations in position, that the geometry of the pivots is perennial in time, regardless of the constraints and shocks to the watch, this for all the geometries of pivots. This is even more critical in some cases: indeed, if a pivot associated with a ball bearing matures or plastic deforms following shocks, much of the advantage of the solution is lost.
Thus, the use of ceramics for the manufacture of the balls and the pivot makes it possible to optimize the use of a ball bearing and to significantly reduce the differences in quality factor between the different watch positions that occupies the timepiece.
A second embodiment of a watch axis 1 'according to the invention is described below with reference to FIG. 5.

权利要求:
Claims (15)
[1]
This axis 1 'is provided to be attached to a pivot axis 6, in particular a pivot axis made of a separate material, in particular a free-cutting steel. Thus, the first functional portion may comprise a pivot 2a, but the second functional portion may for example be in the form of a portion 35 intended to be fixed, in particular by driving or welding, within a bore 36 formed on the body of the axis 6 of pivoting. The invention has been described previously applied to a balance shaft. However, this invention can obviously be applied to any other watch axis, for example a pivot axis of a watchmaker such as a mobile taking part in the finishing line of a watch movement, in particular a center mobile, or a mobile of medium, or a mobile of small average, or a mobile of seconds. A horological axis according to the invention can also be implemented in the context of an optimization of a watch escapement and thus allow the pivoting of an anchor wheel or a blocker or an anchor taking part in the escape. Of course, this invention can be applied to any watch mobile taking part in an additional hor-logère function, such as a calendar or a chronograph. In an alternative embodiment, shown in FIGS. 8 and 9, the first functional portion can provide a translation function. The watch axis is here in the form of a pin 1 "comprising a first functional portion 2a which is in the form of a rod 22a.The latter cooperates with a groove 53 formed within a watch component, for example, a hammer 91 of a chronograph, so as to guide in translation said component, in particular to guide in translation said component in the longitudinal direction of said groove The pin 1 "has a second functional portion which is in the form of a tigeron 45 intended to be driven within a bore 46 of a blank 81 clock. In this embodiment, the first and second functional portions are delimited by a bearing surface 450, in particular a plate 450. Once shaped, the ceramic parts do not require heat treatment or rolling to obtain high wear resistance performance. claims
1. Watch axis (1; 1 '; 1 "), in particular balance shaft (1), comprising a first functional portion (2a; 2b) including at least one portion (221a; 221b) of a tigeron (22a; 22b) and / or at least one portion (211a; 211b) of a pivot (21a; 21b; 21 '; 21 "; 21 *), the first functional portion being integrally ceramic and a first outer diameter (D1) of the first functional portion being less than 0.5 mm, or even less than 0.4 mm, or even less than 0.2 mm, or even less than 0.1 mm.
[2]
2. Axis according to the preceding claim, characterized in that the ceramic is mainly composed of: - zirconium oxide, or - alumina, or - a combination of these two oxides, optionally added one or several of the following elements: - carbon nanotubes, - graphene, - fullerenes, - yttrium oxide, - cerium oxide, - zirconium carbide, - silicon carbide, - titanium carbide, - zirconium boride, - nitride boron, - titanium nitride, and - silicon nitride.
[3]
3. Axis according to claim 1, characterized in that the ceramic is predominantly composed of silicon nitride, optionally added with one or more of the following elements: carbon nanotubes, graphene, fullerenes, zirconium oxide , - aluminum oxide, - yttrium oxide, - cerium oxide, - zirconium carbide, - silicon carbide, - titanium carbide, - zirconium boride, - boron nitride and - titanium nitride.
[4]
4. Axis according to one of the preceding claims, characterized in that the first portion has a surface of revolution, in particular a cylindrical surface or a conical surface or a frustoconical surface or a curved generating surface.
[5]
5. Axis according to one of the preceding claims, characterized in that the axis or the first functional portion has a convex end (212 ') or concave (212 ") or conical (212 *) or frustoconical.
[6]
6. Axis according to one of the preceding claims, characterized in that it has a second functional portion (3), in particular: a second functional receiving portion (31, 32, 33, 34, 35, 45) of a watch component, in particular a balance wheel, a plate, a spiral spring shell, a toothed wheel, another axis (6), a blank (81) or - a second pivoting portion of a clock component on the axis or - a second meshing portion, in particular a toothing.
[7]
7. Axis according to the preceding claim, characterized in that the second functional portion has a second outer diameter (D2) of less than 2 mm, or even less than 1 mm, or even less than 0.5 mm.
[8]
8. Axis according to the preceding claim, characterized in that the ratio of the dimension of the first diameter to the dimension of the second diameter is less than 0.9, or even less than 0.8, or even less than 0.6, or even less than 0.5, or even less than 0.4. .
[9]
9. Axis according to one of the preceding claims, characterized in that the axis is made integrally ceramic.
[10]
10. Assembly (41; 42) comprising an axis (1) according to one of the preceding claims and at least one guide (51; 52; 53), in particular a bearing (51; 52) or a groove (53), axis being intended to: - rotate or pivot in the at least one guide; and / or translate in the at least one guidance.
[11]
11. Assembly (41) according to the preceding claim, characterized in that the at least one guide (51) comprises a pivoting stone (511) and a stone of support (512), the stones cooperating with the pivot to guide the axis in the guidance.
[12]
12. Assembly (42) according to claim 10, characterized in that the at least one guide (52) comprises a raceway (521) and balls (522), the balls cooperating by contact on the pivot (21 * ) to guide the axis in the guidance.
[13]
13. Oscillator (100) of the sprung balance type comprising an axis (1; 1 ') according to one of claims 1 to 9 and / or an assembly according to one of claims 10 to 12.
[14]
14. Clock movement (110) comprising an oscillator (100) according to the preceding claim and / or an assembly according to one of claims 10 to 12 and / or an axis (1; 1 '; 1 ") according to one of Claims 1 to 9.
[15]
15. Timepiece (120) comprising a watch movement (110) according to the preceding claim and / or an oscillator (100) according to claim 13 and / or an assembly according to one of claims 10 to 12 and / or a axis (1; 1 '; 1 ") according to one of claims 1 to 9.

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同族专利:

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EP3584640A1|2019-12-25|

EP3258325A1|2017-12-20|

EP3258325B1|2019-10-30|

US20170357213A1|2017-12-14|

JP2018028529A|2018-02-22|

CN107490950B|2021-05-07|

CH712552B1|2021-12-15|

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EP3594757B1|2018-07-10|2021-05-26|Blancpain SA|Timepiece component with ceramic non-magnetic arboured portion|

JP2020027064A|2018-08-14|2020-02-20|セイコーエプソン株式会社|Timepiece component, movement, and timepiece|

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法律状态:

优先权:

申请号 | 申请日 | 专利标题

EP16174244.0A|EP3258325B1|2016-06-13|2016-06-13|Timepiece arbor|

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