CH704770B1 - Pivot to watch and timepiece component comprising component. - Google Patents

Abstract

The present invention relates to a pivot (1) for a watch component, intended to be engaged in a guide means (3) and whose free end (6) is capable of bearing on a bearing face (5a). . The free end has a configuration in which the portion intended to bear with the bearing face is a contact end radially offset relative to the longitudinal axis (L) of pivoting pivot (1), in the direction of the periphery of said pivot (1).

Description

Technical area

The present invention relates to the general technical field of watchmaking and more particularly to the field of watch movements mounted in watches.

These generally incorporate various mechanisms and / or wheels whose operation can be influenced by their orientation with respect to gravity. Indeed, there are often differences in operation and / or performance of these mechanisms and / or wheels, when they go from a substantially horizontal orientation to a substantially vertical orientation and vice versa.

For example, when a watch movement extends substantially vertically, the axis on which it is mounted generally extends substantially horizontally. When the movement is oriented substantially horizontally, it is the axis which, in general, is oriented substantially vertically. It results from these different orientations, mechanical effects that can induce a difference in the movement.

The influence of the orientation with respect to gravity is particularly manifest in the friction between pivots and bearings and between pivots and counter-pivot stones.

[0005] Reference is made more particularly to pivots used to make a balance shaft or associated with a wheel of an escape mechanism, but the invention is not limited to these applications.

State of the art

[0006] Pivots with particular geometries are already known, in particular the cylindrical pivot, the conical pivot without bearing, the conical pivot whose end rubs at the bottom of a crapaudine, which are described in the illustrated professional dictionary of watchmaking. Berner, the flat-end pivot and the conical-diameter pivot, which are described in the communication No. 4 of the 46th Congress of the Swiss Society of Chronometry "Measurements of the fragility of balance shaft pivots" by Schlatter and Lehmann .

For example, it is known, particularly through the book "Theorie d'horlogerie", page 155, published by the Federation of Technical Schools (ISBN 2-940025-10-X, October). 1998), that the amplitude of a sprung balance of a watch is influenced by the variation of the friction on the pivots of the balance. Thus, when the watch is horizontal, the axis of the pendulum is supported vertically by the end of a pivot on a counter-pivot stone.

When the watch is vertical, the balance shaft is supported by its two pivots in the two stone holes or in bearings. The friction is therefore greater when the watch is in the vertical position.

In order to compensate for this variation of friction, it has been imagined to make pivots with flat ends rather than rounded to increase the radius of action of the friction force when the watch is horizontal and, consequently, to reduce the difference in friction between the horizontal and vertical positions of the watch. These flat pivots, however, have the disadvantage that the radius of action of the friction force can vary from one room to another, because, for example, the surface conditions of the parts in contact or dust or particles that can to be found in lubricating oils. The moments of the friction forces can then vary from one movement to another or over time for the same movement.

Similarly, these problems are also encountered with known cylindrical pins having a bearing in contact with the wall surrounding a stone hole.

The conical pivot bearing is in contact with the stone against pivot at a point centered on its axis of rotation when the watch is horizontal. Thus, the moment of friction force exerted by the counter-pivot stone is theoretically zero and low in practice. On the other hand, when the watch is vertical, the lever arm intervening in the calculation of the moments of the forces exerted by the bearings on the two pivots is equal to the radius of the pivot. The moment of friction force is then greater. By moving from a horizontal position to a vertical position, or vice versa, the difference between the moments of the friction forces exerted on the pivots is maximum. In the case of a resonator presenting a defect of isochronism (in this particular case, a variation of step according to the amplitude), the stability of the march of such a watch movement is thus affected.

Disclosure of the invention

The object of the present invention is to provide a new pivot for watchmaking components of watch movements overcomes the aforementioned drawbacks and to reduce the difference in motion of a movement, between its horizontal positions and vertical in relation to gravity.

Another object of the present invention is to provide a new pivot for clock components watch movements, the manufacture is simple and economical.

The aims of the invention are achieved by means of a pivot for watchmaking timepiece component, intended to be engaged in a guide means and whose free end is likely to come in support on a bearing face, characterized in that the free end has a configuration in which the portion intended to bear against the bearing face is a contact end radially offset relative to the longitudinal axis of pivoting of the pivot, towards the periphery of said pivot.

We then obtain an axial zone free of contact. The area in which is made a contact between the pivot and the bearing face is off-axis with respect to the pivot axis of said pivot and substantially localized with precision.

The guiding means is for example a bearing and the bearing face is for example a face of a counter-pivot stone.

The contact end preferably comprises at least one vertex to establish a substantially punctual contact with the counter-pivot stone.

According to a preferred embodiment of the pivot according to the invention, the free end of said pivot has a beveled shape to form the contact end.

According to another preferred embodiment of the invention, the pivot has at its free end a bore extending along the longitudinal axis, so as to define the contact end in the form of a contact ring. peripheral.

The term "piercing" should be understood in the present invention in a very broad sense, namely that it also refers to a flat bottom hole.

The peripheral contact ring advantageously has an internal chamfer to further deport the parts in contact towards the radial periphery of said pivot.

According to a preferred embodiment of the invention, the pivot is made of a metallic material.

The aims assigned to the invention are also achieved with the aid of such a clock component comprising a pivot axis with at least one such pivot.

The watch component is for example a pendulum or a wheel of a clockwork mechanism, for example an escape wheel.

The aims of the invention are also achieved with the aid of a watch movement comprising at least one watch component and a timepiece comprising such a movement.

A remarkable advantage of the pivot according to the invention is that it makes it possible to obtain a substantial reduction in the difference between the values of the moments of friction forces acting on the pivot, respectively in horizontal position and in position. vertical. For example, the pivot according to the invention makes it possible to obtain a typical measurement of "flat-hung" deviation of a given balance of about 10 °, whereas the same measurement for said balance having a round-ended pivot, can reach about 50 °. A gap measurement "flat-hung" consists of measuring the difference in amplitude of the balance between the horizontal position and the vertical position of the same clock movement.

Another advantage of the pivot according to the invention lies in its insensitivity to dust or particles that may be contained in the lubricating oil. These dusts and particles are no longer able to be introduced between the pivot and the bearing face of said pivot to move randomly the contact area, as is the case with flat pivots. The pivot according to the invention thus provides a high stability of the position of the contact zone.

The pivot according to the invention also has the advantage of attenuating the difference in operation resulting from the difference in amplitudes between the horizontal and vertical positions if the pendulum oscillations are not perfectly isochronous.

Brief description of the drawings

Other features of the present invention will appear more clearly on reading the description which follows, with reference to the accompanying drawing, given by way of non-limiting illustration, in which: <tb> fig. 1 <sep> represents an exemplary embodiment of a pivot according to the invention, in a horizontal position, <tb> fig. 2 <sep> represents an exemplary embodiment of a pivot according to the invention of FIG. 1, in a vertical position, <tb> fig. 3 <sep> represents another embodiment of a pivot according to the invention, according to a front view, <tb> fig. 4 <sep> represents another embodiment of a pivot according to the invention of FIG. 3, according to a left view, and <tb> fig. 5 <sep> represents yet another embodiment of a pivot according to the invention, according to a sectional view.

Mode (s) of realization of the invention

The structurally and functionally identical elements and present in several separate figures, are assigned a same reference numeral or alphanumeric.

FIG. 1 shows a pivot 1 according to an exemplary embodiment of the invention in a horizontal orientation, corresponding for example to a movement or a pendulum oriented vertically. Its longitudinal axis L thus extends horizontally. A cylindrical end portion 2 of the pivot 1 is engaged in a bearing 3 and rests more precisely on an inner face 3a of said bearing 3, establishing a line of contact. This bearing 3 can also be replaced by any type of guide means.

The pivot 1 has at its free end, an end face 4 facing a bearing face, for example a face 5a of a counter-pivot stone 5. In some applications, the stone counter- pivot 5 could be replaced by a complementary bearing or any other element having a bearing face.

The free end of the pivot 1 has, with its end face 4, a beveled shape with a vertex 6. The latter is offset radially relative to the longitudinal axis L, towards the periphery of the pivot 1. The parts establishing the contact between the pivot 1 and the counter-pivot stone 5 are therefore off-axis.

The bevel shape and therefore the top 6 are obtained for example by machining or rolling. The vertex 6 is preferably located as close as possible to the periphery of the end portion 2. Bulk polishing is preferably carried out after the rolling operation.

The line of contact between the end portion 2 and the inner face 3a extends at a first radial distance Rh from the longitudinal axis L. This first radial distance Rh corresponds to the radius of the end portion 2 .

FIG. 2 shows the pivot 1 according to the same embodiment of the invention, but in a vertical orientation. Its longitudinal axis L therefore extends vertically. The end portion 2 of the pivot 1 is always engaged in the bearing 3, but no longer rests on the inner face 3a of said bearing 3. On the other hand, in this orientation, the pivot 1 rests on the face 5a of the counter-stone. pivot 5 through the vertex 6. This provides a substantially punctual contact.

The top 6 thus makes the point of contact with the face 5a. This point of contact must be understood as being a point contact within the geometric limits imposed by the manufacture, generally by machining, of the vertex 6. This point of contact is situated at a second radial distance Rv from the longitudinal axis L. second radial distance Rv is in principle less than the first radial distance Rh. However, it is sought to make the end face 4 so that the value of the second radial distance Rv approaches the best value of the first radial distance Rh.

Figs. 3 and 4 illustrate another embodiment of the pivot 1. The latter has a contact end whose shape is obtained for example by an axial bore 8. The latter makes it possible to produce a contact end in the form of a peripheral contact ring 7. The latter extends continuously over the entire periphery of the free end of the pivot 1.

The contact ring 7 advantageously has an internal chamfer 8a to obtain or to get closer to a circular contact line between the pivot 1 and the face 5a, located closer to the periphery of the portion 2. The chamfer 8a can be obtained directly by the shape of the end of the drill used to perform the drilling. This end of drill bit or bit has for example a cone shape at 120 °. The chamfer 8a can also be obtained by an additional machining operation.

The ring 7 preferably has the smallest possible width. For this purpose, an additional machining operation to achieve the chamfer 8a may be advantageous when the ring 7 has a contact width considered too large.

FIG. 5 shows yet another embodiment of the pivot 1, in a sectional view. The pivot 1 has a hole in the form of a flat bottom hole 8b and the ring 7 has a contact end extending substantially in a circular line. The contact end corresponds to an annular apex delimited internally by the chamfer 8a, so as to reduce at best the width of said ring 7.

The contact ring 7 is located at a stable radial distance from the longitudinal axis L, substantially equal to the second radial distance Rv.

Thus, when the longitudinal axis L is horizontal, illustrated in FIG. 1, the force Fh exerted by each of the two bearings 3 on each of the two pivots 1 makes it possible to determine the moment of total friction forces Mh exerted by the bearings 3 on the pivots 1, namely: Mh = 2 × (Fh × μ × Rh) where μ is the coefficient of kinetic friction and Rh is the lever arm between the friction force and the longitudinal axis L.

When the longitudinal axis L is vertical, the force Fv exerted by a single stone against pivot 5 on a single pivot 1 allows to determine the moment of total friction forces exerted by said stone against pivot 5 on the pivot 1, namely: Mv = Fv × μ × Rv with Fv = 2 × Fh and Rv being the lever arm between the friction force and the longitudinal axis L.

There is then obtained a difference between the moments of friction forces proportional to the difference of the lever arms Rh and Rv, namely: Mh - Mv = 2 × Fh × μ × (Rh - Rv).

It therefore appears that a decrease in the difference between the lever arms Rh and Rv reduces the gap between the moments of friction forces Mh and Mv.

The shape of the ends of the pivots 1 according to the invention thus makes it possible to minimize the difference between the moments of friction force Mh and Mv and consequently to reduce the difference in amplitude and thus in the operation of, for example, a watch movement, between its horizontal and vertical positions.

The shape of a pivot 1 according to the invention therefore allows to deport towards its radial periphery the contact end of said pivot 1. This radial offset preferably reaches a value as close as possible to the radius of the pivot 1, account given the manufacturing and / or machining constraints of said pivot 1.

It is obvious that the present description is not limited to the examples explicitly described, but also includes other embodiments and / or implementation within the scope of the claims. Thus, a described technical feature can be replaced by an equivalent technical characteristic without departing from the scope of the present invention.

Claims (12)

1. Pivot (1) for a watch component, intended to be engaged in a guide means and whose free end is capable of bearing on a bearing face, characterized in that the free end has a configuration wherein the portion intended to abut with the bearing face is a contact end radially offset relative to the longitudinal pivot axis (L) of the pivot (1), towards the periphery of said pivot (1) . 2. Pivot (1) according to claim 1, characterized in that the contact end comprises at least one vertex (6) to establish a substantially point contact with the bearing face. 3. Pivot (1) according to claim 1 or 2, characterized in that the free end has a beveled shape to form the contact end. 4. Pivot (1) according to claim 1, characterized in that it has at its free end a bore (8) extending along the longitudinal axis (L) so as to delimit the contact end in the form of a peripheral contact ring (7). 5. Pivot (1) according to claim 4, characterized in that the contact ring (7) has an internal chamfer (8a) to further deport to the radial periphery of said pivot (1) the part of the contact ring (7) intended to bear against the bearing face. 6. Watch component comprising a pivot axis with at least one pivot (1) according to one of claims 1 to 5. 7. Horological component according to claim 6, characterized in that it constitutes a pendulum. 8. Horological component according to claim 6, characterized in that it constitutes a wheel of a clockwork movement. 9. Watchmaking movement comprising at least one watch component according to one of claims 6 to 8. 10. Timepiece according to claim 9, characterized in that the pivot (1) of the watch component is engaged in a guide means forming a bearing (3). 11. Watchmaking movement according to one of claims 9 and 10, characterized in that the pivot (1) of the watch component is supported on a bearing surface of a counter-pivot stone (5). 12. Timepiece comprising a watch movement according to one of claims 9 to 11.