CH718278A2 - Assembly comprising a rotating mobile in non-magnetic material and a bearing fitted with a cone. - Google Patents

Abstract

The invention relates to an assembly (10), in particular for a timepiece, comprising a rotating wheel set and a bearing, such as a stone (20), the rotating wheel set being provided with at least one pivot (17) comprising at least partly a non-magnetic material, preferably entirely, the bearing comprising a face (6) provided with a hole (8) formed in the body of the bearing and with a functional geometry at the entrance of the hole (8), characterized in that the functional geometry has the shape of a cone (12), and in that the non-magnetic material of the pivot (17) comprises an alloy to be chosen from materials based on copper, materials based on palladium or materials with aluminum base.

Description

Field of the invention

The invention relates to an assembly comprising a rotating wheel set provided with a pivot made of non-magnetic material and a bearing provided with a cone, in particular for a timepiece.

The invention also relates to a timepiece comprising such an assembly.

Background of the invention

[0003] In the state of the watchmaking technique, rotating mobiles, such as pendulums, generally comprise two pivots whose ends are inserted into stones in order to be able to rotate. Generally, stones of the ruby or sapphire type are used to form counter-pivots or guide elements called bearings. The bearings can also be metallic. These counter-pivots and guide elements are intended to come into contact with the pivots in order to make the latter mobile in rotation and this, with minimal friction. Thus, they form, for example, all or part of a bearing of the mobile shaft mounted in rotation.

[0004] In principle, synthetic stones are used in watch movements. In particular, the Verneuil-type process is known for manufacturing stones of the monocrystalline type. There are also stones of the polycrystalline type, which are manufactured by pressing a precursor with a view to obtaining a green body of the future stone from a pressing tool.

[0005] The stones serving as a rotational guide element for a pivot generally have a through hole in which the pivot is inserted to rest on a counter-pivot. It is known to form a substantially hemispherical hollow around the hole on the pivot insertion face to facilitate insertion of the pivot. In addition, it allows the pivot to be put back in place in the event that it comes out due to a shock. The hollow is, for example, obtained by turning with a diamond chisel.

[0006] Figure 1 is an example of the prior art, of an assembly 1 comprising a stone 2 provided with a hole 3 and a hemispherical hollow 4 forming the entrance to the hole 3. The assembly 1 comprises yet a pivot 7 configured to be inserted into the hole 3 in order to allow the rotation of a movable element, not shown in the figure.

[0007] On the other hand, magnetism is a major problem for watch movements, because it affects the precision of the movements. To solve this problem, it is also known to use non-magnetic materials to form certain parts of the movement. Thus, these non-magnetic materials make it possible to produce rotating mobile shafts, which avoid magnetization of the pivot.

[0008] However, non-magnetic materials are often less hard than the magnetic metals usually used for rotary mobiles. However, with such a hollow, a protruding edge is present at the edge of the hole, so that a pivot made of a soft non-magnetic material can be damaged by said edge, when the pivot comes out of the hole and enters it again, by example under the effect of a shock. After several shocks of this type, the pivot quickly suffers premature wear, which will have repercussions on the precision of the movement thereafter.

Summary of the invention

The object of the present invention is to overcome all or part of the drawbacks mentioned above, by proposing an assembly, in particular for a timepiece, comprising a rotating mobile and a bearing, such as a stone, the rotating mobile being provided at least one pivot comprising at least partly a non-magnetic material, preferably entirely, the bearing comprising a face provided with a hole formed in the body of the bearing and with a functional geometry at the entrance to the hole.

[0010] To this end, the assembly is remarkable in that the functional geometry has the shape of a cone, and in that the non-magnetic material of the pivot comprises an alloy to be chosen from materials based on copper, materials based on palladium or aluminum based materials.

[0011] Thanks to this assembly, it is possible to use soft non-magnetic materials for rotating mobile pivots, because the conical entry of the hole avoids the risk of premature wear of the pivot in the event of shocks. Indeed, the edge bordering the hole and the cone is much less prominent, so that the pivot will not be damaged if it leaves the hole and re-enters it following a shock. In addition, materials such as copper-based, palladium-based or aluminum-based alloys are particularly well suited for this use.

According to a particular embodiment of the invention, the non-magnetic material has a Vickers hardness of less than 500 HV, preferably less than 450 HV, or even less than 400 HV.

[0013] According to a particular embodiment of the invention, the non-magnetic material is a copper-based alloy of the CuBe2 type.

According to a particular embodiment of the invention, the non-magnetic material is a palladium-based alloy comprising by weight: between 25% and 55% palladium, between 25% and 55% silver, between 10% and 30% copper, between 0.5% and 5% zinc, gold and platinum with a total percentage of these two elements between 5% and 25%, between 0% and 1% of one or more elements chosen from boron and nickel, between 0% and 3% of one or more elements chosen from rhenium and ruthenium a maximum of 0.1% of one or more elements chosen from iridium, osmium and rhodium and not more than 0.2% of other impurities, the respective amounts of the components being as added together, reach 100%.

According to a particular embodiment of the invention, the non-magnetic material is an alloy comprising by weight: between 30% and 40% palladium, between 25% and 35% silver, between 10% and 18% copper, between 0.5% and 1.5% zinc, and the alloy comprises gold and platinum by weight with a total percentage of these two elements between 16% and 24%.

According to a particular embodiment of the invention, the non-magnetic material is an alloy comprising by weight: between 34% and 36% palladium, between 29% and 31% silver, between 13.5% and 14.5% copper, between 0.8% and 1.2% zinc, between 9.5% and 10.5% gold between 9.5% and 10.5% platinum, a maximum of 0.1% of one or more elements chosen from iridium, osmium, rhodium and ruthenium and at most 0.2% of other impurities, the respective amounts of the components being as added together, reach 100%.

According to a particular embodiment of the invention, the non-magnetic material is a palladium-based alloy comprising by weight: between 25% and 55% palladium between 25% and 55% silver, between 10% and 30% copper, between 0% and 5% zinc, between 0% and 2% of one or more elements chosen from rhenium, ruthenium, gold and platinum, between 0% and 1% of one or more elements chosen from boron and nickel.

According to a particular embodiment of the invention, the non-magnetic material is an alloy comprising by weight between 38% and 43% palladium, between 35% and 40% silver, between 18% and 23% copper , and between 0.5% and 1.5% zinc.

According to a particular embodiment of the invention, the non-magnetic material is an aluminum-based alloy comprising by weight: between 83% and 94.5% aluminum, between 4% and 7% zinc, between 1% and 4% magnesium, between 0.5% and 3% copper, between 0% and 3% of one or more elements chosen from chromium, silicon, manganese, titanium and iron.

According to a particular embodiment of the invention, the non-magnetic material is an alloy comprising by weight: between 87.32% and 91.42% aluminum, between 5.1% and 6.1% zinc, between 2.1% and 2.9% magnesium, between 1.2% and 2% copper, between 0.18% and 0.28% chromium, between 0% and 0.4% silicon, between 0% and 0.3% manganese, between 0% and 0.2% titanium, and between 0% and 0.5% iron.

According to a particular embodiment of the invention, the stone comprises alumina Al2O3 or zirconia ZrO2.

According to a particular embodiment of the invention, the stone comprises an upper face and a lower face, the lower face comprising the cone.

According to a particular embodiment of the invention, the hole is through so as to connect said cone to the upper face of said stone.

The invention also relates to a timepiece comprising such an assembly.

Brief description of the drawings

Other features and advantages will emerge clearly from the description given below, by way of indication and in no way limiting, with reference to the appended drawings, in which: FIG. 1 is a diagrammatic representation of an assembly comprising a stone and a pivot of a rotary wheel known from the state of the art; Figure 2 is a schematic representation of an assembly comprising a stone and a pivot of a rotating mobile according to a first embodiment of the invention; Figure 3 is a schematic representation of a stone according to a second embodiment of the invention.

Detailed Description of Preferred Embodiments

As explained above, the invention relates to an assembly comprising a rotating wheel set and a bearing, such as a stone, in particular for a timepiece. The stone is intended to come into contact with a pivot of the rotating mobile, in order to make the latter mobile in rotation with minimal friction. However, such an assembly cannot be limited to the watchmaking field and can be applied to any mounted part that is mobile relative to a bearing.

[0027] The stone is preferably formed from alumina or zirconia, with a crystallographic structure of the monocrystalline or polycrystalline type. The stone forms, for example, a guide element intended to be mounted in a damping bearing of a timepiece.

In Figure 2, the stone 20 of the assembly 10 is crossed by a hole 8 intended to receive a pivot 17, also called pin. The stone 20 comprises an upper face 5 and a lower face 6, one of which comprises a cone 12 communicating with the through hole 8. In other words, the hole 8 communicates with the upper face 5 and also with a substantially conical recess defined in the underside 6. This recess then forms an engagement cone for the pierced stone 20. The cone 12 preferably has rotational symmetry. Cone 12 has a first opening 19 at its base and a second opening at its top. The first opening 19 is larger than the second, and is formed in the lower face 6 of the stone 20. The connection of the cone 12 and the hole 8 is carried out by the second opening to form an edge 15.

Thus, the widening of the cone 12 makes it easy to insert the pivot 17 of the shaft 16 of a rotating part, in particular in the event of an impact. The angle of the cone is chosen to prevent the edge 15 formed by the top of the cone and the hole 8 from projecting too much. For example, an angle of between 30° and 120°, preferably between 45° and 90°, is chosen.

We also note that an inner wall of the body of this stone 20 defined at the hole 8 has a rounded area intended to minimize contact with the pivot but also to facilitate any lubrication.

[0031] The upper face 5 of the stone comprises a rim 18, in particular to enclose laterally a counter-pivot in the case of a landing. The rim 18 is preferably peripheral, that is to say it delimits the edge of the upper face 5 of the stone 20. In addition, it defines an internal zone 9 of the upper face 5 comprising a face of support 11 and the outlet of the through hole 8, and a concentrically convex zone 9 from the support face 11 to the hole 8.

[0032] An upper face 5 with such a rim 18 makes it possible, for example, to block laterally an element arranged on the upper face of the stone 20. In the case of a bearing for a balance axis, in which the stone 20 serves guide element, a counter-pivot stone can be arranged so that it is blocked laterally by the internal side of the rim 18 while resting on the bearing face 11. The counter-pivot stone is dimensioned to correspond in zone 9 of stone 10. The stone thus forms an axial and radial support for a counter-pivot. The counter-pivot, not shown in the figures, can be fitted into stone 10 to support it axially and hold it laterally.

In addition, the stone 10 has a partially flared peripheral face 13 connecting the lower face 6 of smaller surface to the upper face 5 of larger surface.

Figure 3 shows an alternative embodiment of a stone 30 of a set. The stone 30 has a different shape, the upper face 25 being curved and the lower face 26 being substantially planar. This stone 30 does not include an edge, and must be inserted into a specific ring (or bezel). Through-hole 28 and cone 22 are similar to those in Figure 2.

[0035] According to the invention, the rotating mobile is provided with a pivot comprising at least partly a non-magnetic material, preferably entirely. The non-magnetic material makes it possible to limit the sensitivity of the pivot to magnetic fields. The non-magnetic material of the pivot comprises a metal alloy to be chosen from materials based on copper, based on palladium, or materials based on aluminium. The non-magnetic material included in the pivot is soft, that is to say it has a Vickers hardness of less than 500 HV, preferably less than 450 HV, or even less than 400 HV or 350HV. Thus, the non-magnetic material is a "soft" material compared to the harder metallic materials used to form the pivots of the usual revolving mobiles.

In a first embodiment, the non-magnetic material comprises an alloy of copper and beryllium, of the CuBe2 type. Preferably, the pivot is formed substantially entirely from this alloy of copper and beryllium. The alloy generally comprises at least 90% copper, even at least 95% copper, and even up to 98% copper, which is supplemented by beryllium.

In a second embodiment, the non-magnetic material is an alloy comprising by weight: between 25% and 55% palladium, between 25% and 55% silver, between 10% and 30% copper, between 0.5% and 5% zinc, gold and platinum with a total percentage of these two elements between 15% and 25%, between 0% and 1% of one or more elements chosen from boron and nickel, between 0% and 3% of one or more elements chosen from rhenium and ruthenium a maximum of 0.1% of one or more elements chosen from iridium, osmium and rhodium and a maximum of 0.2% of other impurities, the respective quantities of the components being as added together, they do not exceed 100%.

Advantageously, the non-magnetic material is an alloy comprising by weight: between 30% and 40% palladium, between 25% and 35% silver, between 10% and 18% copper, between 0.5% and 1.5% zinc, between 8 and 12% gold and 8 and 12% platinum with a proportion of rhenium and ruthenium between 0 and 6% by weight.

According to a preferred variant, the non-magnetic material is an alloy comprising by weight: between 34% and 36% palladium, between 29% and 31% silver, between 13.5% and 14.5% copper, between 0.8% and 1.2% zinc, between 9.5% and 10.5% gold between 9.5% and 10.5% platinum, a maximum of 0.1% of one or more elements chosen from iridium, osmium, rhodium and ruthenium and not more than 0.2% of other impurities, the respective amounts of the components being as added together, reach 100%.

According to an even more preferred variant, the non-magnetic material is an alloy consisting by weight of 35% palladium, 30% silver, 14% copper, 10% gold, 10% platinum and 1% zinc.

In the third embodiment, the non-magnetic material is an alloy comprising by weight: between 25% and 55% palladium, between 25% and 55% silver, between 10% and 30% copper, between 0% and 5% zinc, between 0% and 2% of one or more elements chosen from rhenium, ruthenium, gold and platinum, between 0% and 1% of one or more elements chosen from boron and nickel.

Preferably, the non-magnetic material is an alloy comprising by weight: between 38% and 43% palladium; and or between 35% and 40% silver; and or between 18% and 23% copper; and or between 0.5% and 1.5% zinc.

[0043] Even more particularly, the non-magnetic material is an alloy comprising 41% palladium, 37.5% silver, 20% copper, 1% zinc and 0.5% platinum.

In a fourth embodiment of the invention based on aluminum, the non-magnetic material is an alloy comprising by weight: between 83% and 94.5% aluminum, between 4% and 7% zinc, between 1% and 4% magnesium, between 0.5% and 3% copper, between 0% and 3% of one or more elements chosen from chromium, silicon, manganese, titanium and iron.

[0045] Preferably, an alloy known as an aluminum alloy of the "7075" (zicral) type is used, which comprises more precisely by weight: between 87.32% and 91.42% aluminum, between 5.1% and 6.1% zinc, between 2.1% and 2.9% magnesium, between 1.2% and 2% copper, between 0.18% and 0.28% chromium, between 0% and 0.4% silicon, between 0% and 0.3% manganese, between 0% and 0.2% titanium, and between 0% and 0.5% iron.

Of course, the present invention is not limited to the examples illustrated but is susceptible to various variants and modifications which will become apparent to those skilled in the art. For example, other materials such as brass, nickel silver, declafor, or even soft non-magnetic steels are known.

Claims (14)

1. Assembly (10), in particular for a timepiece, comprising a rotating wheel and a bearing, such as a stone (20, 30), the rotating wheel being provided with at least one pivot (17) comprising at least part of non-magnetic material, preferably entirely, the bearing having a face (6, 26) provided with a hole (8, 28) formed in the body of the bearing and with a functional geometry at the entrance of the hole (8 , 28), characterized in that the functional geometry has the shape of a cone (12, 22), and in that the non-magnetic material of the pivot (17) comprises an alloy to be chosen from materials based on copper, materials with palladium-based, or aluminum-based materials. 2. Assembly according to claim 1, characterized in that the non-magnetic material has a Vickers hardness of less than 500 HV, preferably less than 450 HV, or even less than 400 HV. 3. Assembly according to claim 1 or 2, characterized in that the non-magnetic material is a copper-based alloy of the CuBe2 type. 4. Assembly according to claim 1 or 2, characterized in that the non-magnetic material is a palladium-based alloy comprising by weight: – between 25% and 55% palladium, – between 25% and 55% silver, – between 10% and 30% copper, – between 0.5% and 5% zinc, – gold and platinum with a total percentage of these two elements between 5% and 25%, – between 0% and 1% of one or more elements chosen from boron and nickel, – between 0% and 3% of one or more elements chosen from rhenium and ruthenium – a maximum of 0.1% of one or more elements chosen from iridium, osmium and rhodium and – a maximum of 0.2% of other impurities, the respective quantities of the components being as added together, reach 100%. 5. Assembly, according to claim 4, characterized in that the non-magnetic material is an alloy comprising by weight: between 30% and 40% palladium, between 25% and 35% silver, between 10% and 18% copper , between 0.5% and 1.5% zinc, and the alloy comprises gold and platinum by weight with a total percentage of these two elements between 16% and 24%. 6. Assembly, according to claim 5, characterized in that the non-magnetic material is an alloy comprising by weight: – between 34% and 36% palladium, – between 29% and 31% silver, – between 13.5% and 14.5% copper, – between 0.8% and 1.2% zinc, – between 9.5% and 10.5% gold – between 9.5% and 10.5% platinum, – a maximum of 0.1% of one or more elements chosen from iridium, osmium, rhodium and ruthenium and – a maximum of 0.2% of other impurities, the respective quantities of the components being as added together, reach 100%. 7. Assembly according to claim 1 or 2, characterized in that the non-magnetic material is a palladium-based alloy comprising by weight: – between 25% and 55% palladium – between 25% and 55% silver, – between 10% and 30% copper, – between 0% and 5% zinc, – between 0% and 2% of one or more elements chosen from rhenium, ruthenium, gold and platinum, – between 0% and 1% of one or more elements chosen from boron and nickel. 8. Assembly, according to claim 7, characterized in that the non-magnetic material is an alloy comprising by weight between 38% and 43% palladium, between 35% and 40% silver, between 18% and 23% copper, and between 0.5% and 1.5% zinc. 9. Assembly according to claim 1 or 2, characterized in that the non-magnetic material is an aluminum-based alloy comprising by weight: – between 83% and 94.5% aluminum, – between 4% and 7% zinc, – between 1% and 4% magnesium, – between 0.5% and 3% copper, – between 0% and 3% of one or more elements chosen from chromium, silicon, manganese, titanium and iron. 10. Assembly, according to claim 9, characterized in that the non-magnetic material is an alloy comprising by weight: – between 87.32% and 91.42% aluminum, – between 5.1% and 6.1% zinc, – between 2.1% and 2.9% magnesium, – between 1.2% and 2% copper, – between 0.18% and 0.28% chromium, – between 0% and 0.4% silicon, – between 0% and 0.3% manganese, – between 0% and 0.2% titanium, and – between 0% and 0.5% iron. 11. Assembly according to any one of the preceding claims, characterized in that the stone (20, 30) comprises alumina Al203 or zirconia ZrO2. 12. Assembly according to any one of the preceding claims, characterized in that the stone (20, 30) comprises an upper face (5, 25) and a lower face (6, 26), the lower face (6 , 26) comprising the cone (12, 22). 13. Assembly according to any one of the preceding claims, characterized in that the hole (8, 28) is through, so as to connect said cone (12, 22) to the upper face (5, 25) of said stone (20, 30). 14. Timepiece comprising an assembly (10) according to any one of the preceding claims.