CH714370B1 - Device for magnetic centering of a shaft in a watch movement. - Google Patents

Abstract

The device for magnetic centering of a shaft (1) along a determined axis in a watch movement, comprises at least a first magnetic bearing (20) provided with a magnet (6) to exert an attractive force on a first pivot ferromagnetic end (2) of the shaft (1). The first magnetic bearing comprises a central piece (4) of soft ferromagnetic material mounted between the magnet and the first end pivot of the shaft. The center piece is centrally placed in a washer (8) of non-magnetic material to center the flow of magnetic field generated by the permanent magnet through the center piece to magnetically attract the first end pivot of the shaft along the axis determined. The diameter of the center piece may be the same as or 0 to 20% smaller or 0 to 20% larger than the diameter of the first end pivot.

Description

FIELD OF THE INVENTION

[0001] The present invention relates to a device for magnetic centering of a shaft along a determined axis in a watch movement, the device comprising at least one magnetic bearing equipped with a magnet arranged to exert an attractive force on a pivot in magnetic material of the shaft.

PRIOR ART

[0002] It is known to use permanent magnets in rotating members of watch movements, such as to keep a shaft of a part rotating along a determined axis. This provides the advantage of generating significant and normally well-localized holding forces while limiting friction on the rotating shaft. However, the magnetic field can be offset by too large a value without magnetic centering means, which leads to obtaining a large number of parts, which are rejected after production.

[0003] We can cite patent application WO 2012/062524 A1, which describes, with reference to Figure 13 of the document, a device for pivoting a shaft with at least one magnetic bearing shown in Figure 1 as prior art . This Figure 1 represents a pivoting device, which comprises a shaft 1, the ends of which form two pivots referenced 2 and 3 respectively. The pivots are made of a magnetic material. Figure 1 also shows a first bearing and a second bearing arranged to support and guide in rotation the two pivots 2 and 3. Each of the two bearings comprises a bezel, respectively referenced 40 and 44, a permanent magnet, respectively referenced 4 and 6, mounted in the bezel and a stone with a support surface, respectively referenced 18A and 19A, inserted between the magnet and the mouth of the bezel. The magnets 4 and 6 of the first bearing and the second bearing are oriented so as to respectively attract the first pivot and the second pivot, so that the shaft 1 is held in the pivot axis, with a certain play, both radial than axial.

[0004] The production of reliable watch mechanisms operating according to the aforementioned principles represents a significant technical challenge, because the dimensions are extremely small. In addition, high spatial precision is required to accurately perform chronometric functions.

[0005] We can also cite patent application EP 3 106 934 A1, which describes a device for pivoting a shaft along a determined axis provided with at least one magnetic bearing with a magnet and a structure for centering the magnetic flux towards the pivot of the shaft. This centering structure comprises a peripheral part and a central part elastically connected to the peripheral part by a connecting element. The central part is made of a material with high magnetic permeability and having dimensions smaller than those of the magnet.

[0006] Generally, in a known magnetic centering device as described in patent applications EP 3 106 934 A1 or CH 711 220 A2, the different elements of the device are controlled during assembly and if the magnetic field generated by at unless a magnet in the magnetic bearing is off-center by too large a value, the parts produced are refused. Currently with a known magnetic centering device, there is too high a scrap rate, and the industrialization of such a device is difficult, which constitutes disadvantages.

SUMMARY OF THE INVENTION

[0007] An aim of the present invention is to remedy the drawbacks of the prior art by providing a device for magnetic centering of a shaft along a determined axis in a watch movement in which the magnetic field lines generated by at least one magnet are well centered in the direction of the axis of rotation of the shaft with a simplified construction.

[0008] Thus, the invention relates to a device for magnetic centering of a shaft along a determined axis in a watch movement, which comprises the characteristics defined in independent claim 1.

[0009] Particular embodiments of the magnetic centering device are defined in dependent claims 2 to 17.

[0010] An advantage of the magnetic centering device lies in the fact that with the centering pad of the magnetic field generated by the magnet, this makes it possible to properly center one of the end pivots of the shaft along a determined axis. An increase in the intensity of the magnetic field occurs at the central part, which is constituted by the pellet preferably made of soft ferromagnetic material, while also increasing the radial gradient of the magnetic field. The magnetic return force, which acts radially on the end pivot of the shaft, is thus increased to guarantee good centering of the shaft.

Another advantage of the magnetic shaft centering device lies in the fact that good centering of the magnetic field is easily obtained via the centering pad. In addition, the simplified magnetic bearing structure which includes the pad is easy to produce. The magnetic field is refocused by a factor of 2 to 3. Under these conditions, the number of parts rejected after manufacturing the magnetic centering device is greatly reduced compared to the devices of the prior art.

BRIEF DESCRIPTION OF THE FIGURES

[0012] The aims, advantages and characteristics of the device for magnetic centering of a shaft along a determined axis in a watch movement will appear better in the following description, particularly with reference to the drawings in which: – Figure 1 is a view in longitudinal section a magnetic pivoting device of the prior art; – Figure 2 is a view of the principle of magnetic centering of a shaft along a determined axis of a watch movement with the magnetic centering device according to the invention; and – Figure 3 is a partial sectional view of a part of the watch movement with the magnetic centering device according to the invention.

DETAILED DESCRIPTION OF THE INVENTION

[0013] In the following description, all the parts of a device for magnetic centering of a shaft along a determined axis in a watch movement, which are well known in this technical field, will only be described briefly.

[0014] Figure 2 represents in a simplified manner a device for magnetic centering of a shaft 1 along a determined axis in a watch movement. The magnetic centering device comprises at least one magnetic bearing 20 for centering a shaft 1 along a determined axis. To do this, the shaft 1 comprises at least one end pivot 2 made of ferromagnetic material. As shown in Figure 2, the magnetic centering device preferably comprises two magnetic bearings 20, 30 arranged on either side of two end pivots 2 and 3 of a shaft 1 intended to rotate during operation of the movement watchmaker. The two magnetic bearings 20, 30 have the function of maintaining the shaft 1 by magnetic attraction along an axis determined for its rotation.

[0015] In this Figure 2, the first magnetic bearing 20 comprises, successively from the first end pivot 2 of the shaft 1, at least a first counter-pivot support stone 10, which can be made of ruby, a first central piece 4, which may be a first pellet 4 of soft ferromagnetic material, placed centered on the first support stone. The first pellet 4 is for example placed centered on the support stone 10. The first pellet 4 is inserted or pushed out or glued into a central opening in a first washer 8 or socket made of non-magnetic material, such as brass for example. Directly above the assembly, which includes the first washer 8 and the first pad 4 for centering the magnetic field, there is arranged at least one first magnet 6, which can be of the same diameter as the first washer 8 This permanent magnet can be made of neodymium-iron-boron for example. The magnetic field flow generated by the first magnet 6 is refocused to pass through the first pellet 4 in order to increase the radial attraction force of the first ferromagnetic pivot 2 to center the shaft 1 along a determined axis. This determined axis is normally the axis of rotation of shaft 1 during operation of the watch movement.

[0016] In Figure 2, the magnetic centering device preferably further comprises a second magnetic bearing 30 disposed opposite a second end pivot 3 of the shaft 1 opposite the first end pivot 2. The second magnetic bearing 30 comprises, successively from the second end pivot 3, at least one second counter-pivot support stone 11, which may be made of ruby, a second central part 5, which may be a second pellet 5 made of ferromagnetic material soft, on the second supporting stone. The second pellet 5 is for example placed centered on the second support stone 11. The second pellet 5 is inserted or pushed out or glued in a central position in a second washer 9 or socket made of non-magnetic material, such as brass for example. Directly above the assembly, which includes the second washer 9 and the second pad 5 for centering the magnetic field, there is arranged at least one second magnet 7, which can be of the same diameter as the second washer 9 The magnetic field flow generated by the second magnet 7 is refocused to pass through the second pellet 5 in order to increase the radial force of attraction of the second ferromagnetic pivot 3 to center the shaft 1 along a determined axis.

The space remaining between the first support stone 10 and the first end pivot 2 or between the second support stone 11 and the second end pivot 3 is less than 0.1 mm and preferably less than 0.03mm. This depends on the dimension of the shaft 1 and the two end pivots 2, 3, which can be of a diameter less than 1 mm and preferably of the order of 0.15 mm. Thus, a magnetic attraction force of each pivot 2, 3 by the first and second permanent magnets 6, 7 through each pellet 4, 5, is sufficient. The thickness of each counter-pivot support stone 10, 11 is less than 1 mm and preferably of the order of 0.06 mm. Each central piece or pellet 4, 5 made of soft ferromagnetic material can have an external diameter identical to the diameter of each end pivot 2, 3 or a diameter, for example 0 to 20% smaller.

However, it can also be imagined that each central part or pellet 4, 5 in soft ferromagnetic material can have an external diameter identical to the diameter of each end pivot 2, 3 or a diameter, for example 0 to 20% greater .

[0019] With such an arrangement of each magnetic bearing 20, 30, this facilitates the assembly of each part and makes it possible to better refocus the magnetic flux of each magnet to maintain the two end pivots 2, 3 of the shaft 1 according to a determined axis. The refocusing of the magnetic flux generated by the magnets 6, 7 is by a factor of 2 to 3.

[0020] It should also be noted that each central part or pellet 4, 5, as well as the shaft 1, can be formed from a material with high magnetic permeability, such as a soft ferromagnetic material. The soft ferromagnetic material may be selected from iron, cobalt, nickel, magnesium, silicon, iron-cobalt alloy, nickel-cobalt alloy, or iron-nickel alloy. In one embodiment, the material may be nickel phosphorus with a phosphorus percentage less than or equal to 11%. According to another variant, the magnetic flux centering element can be made entirely of a magnetically soft material, characterized by a coercive field H of less than 5 kA/m, saturation greater than 0.5 T and a maximum permeability µR equal to or greater than 1000. According to another variant, the material could also be magnetically hard.

[0021] Figure 3 represents a section of a part of the watch movement with the magnetic centering device according to the invention. We can observe in this figure 3, mainly the first more complete magnetic bearing 20, and the first end pivot 2 of the shaft 1, which is held magnetically along an axis determined by the first magnetic bearing 20.

The first magnetic bearing 20 comprises a first support 22, which comprises a base on the side of the first end pivot 2 with an opening 23 of diameter greater than the diameter of the first end pivot 2. The first magnetic bearing 20 is arranged to support and guide the first end pivot 2 in rotation. The first end pivot 2 passes through the opening 23 of the first support 22 without direct contact. The first support 22 is also provided to position a first chat 21. For this purpose, the first chat 21 is held in a housing in the shape of an inverted cone of the first support 22 by elastic means 24 arranged in the upper interior part of the first support 22. The first support 22 is a part of revolution comprising a circular rim.

[0023] The first magnetic bearing 20 further comprises in the first chat 21 from the top successively, a first upper support stone 12, a first permanent magnet 6, a first central part or pellet 4 for centering the magnetic field flow generated by the first magnet 6, said first pellet 4 being driven into a first non-magnetic washer or socket 8, and a first counter-pivot support stone 10. The first end pivot 2 is well centered and attracted by the force of attraction of the magnetic field flow passing through the first pellet 4 made of soft ferromagnetic material.

The first upper support stone 12 is arranged to close the top of the bezel 21 and to serve as a support for the first magnet 6, which has an exterior diameter identical to the exterior diameter of the first upper support stone 12 The first washer 8 also has an external diameter identical to the external diameter of the first permanent magnet 6. The first counter-pivot support stone 10 has a diameter smaller than that of the first washer 8 by being fixed in a lower central recess of the first washer 8 on the side of the first end pivot 2. This first counter-pivot support stone 10 has a support surface for the first end pivot 2.

[0025] It should also be noted that in the event of an axial impact, the first end pivot 2 can push the first counter-pivot support stone 10 and the first chaton 21 comprising it upwards. The elastic means 24 make it possible to return the first bezel 21 to its initial position. In the event of radial movement following an impact of the first end pivot 2, the opening 23 of the first support makes it possible to limit its movement.

[0026] Only a first magnetic bearing 20 has been described with reference to Figure 3. However, a second magnetic bearing 30 can be provided on the side of a second end pivot 3 opposite the first end pivot 2. This second magnetic bearing comprises the same elements not shown as the first magnetic bearing.

The second magnetic bearing comprises a second support with an opening for the second end pivot, a second chat held by elastic means in the second support. The second bezel also successively comprises, from the bottom, a second lower support stone, a second permanent magnet, a second central piece or centering pellet for the magnetic field flow generated by the second magnet, said second pellet being driven out in a second washer or non-magnetic socket, and a second counter-pivot support stone for the second end pivot.

[0028] With the arrangement of the first magnetic bearing and the second magnetic bearing, the first and second end pivots of the shaft are kept in balance centrally by the maximum magnetic attraction force of the magnetic flux of the magnets passing through the ferromagnetic pellets.

[0029] It should also be noted that each bearing surface of the first and second counter-pivot bearing stones 10, 11 may have a recess in the form of a spherical cap to prevent excessive radial movement of the first and second pivots d end of the shaft.

[0030] From the description which has just been made, several alternative embodiments of the device for magnetic centering of a shaft along a determined axis in a watch movement can be designed by those skilled in the art without departing from the framework of the invention defined by the claims.

Claims (17)

1. Device for magnetic centering of a shaft (1) along a determined axis in a watch movement, the device comprising at least a first magnetic bearing (20) comprising a first magnet (6), to exert an attractive force on a first end pivot (2) made of ferromagnetic material of the shaft (1), characterized in that the first magnetic bearing (20) comprises at least a first central part (4) of ferromagnetic material mounted between the first magnet (6) and the first end pivot (2) of the shaft (1), this first central piece (4) being placed centrally in a first washer or socket (8) of non-magnetic material in such a way as to center the flow of magnetic field generated by the first magnet (6) through the first central piece (4) to magnetically attract the first end pivot (2) of the shaft (1) along the determined axis. 2. Magnetic centering device according to claim 1, characterized in that the diameter of the first central part (4) is identical or greater by 0 to 20% relative to the diameter of the first end pivot (2). 3. Magnetic centering device according to claim 1, characterized in that the diameter of the first central part (4) is identical to or less than 0 to 20% relative to the diameter of the first end pivot (2). 4. Magnetic centering device according to claim 1, characterized in that the first magnetic bearing (20) further comprises a first counter-pivot support stone (10), which is mounted between the first central part (4) and the first end pivot (2) of the shaft (1). 5. Magnetic centering device according to claim 4, characterized in that the first counter-pivot support stone (10) is made of ruby. 6. Magnetic centering device according to claim 1, characterized in that the first central part (4) is made of soft ferromagnetic material. 7. Magnetic centering device according to claim 1, characterized in that the first washer or socket (8) is made of brass. 8. Magnetic centering device according to claim 4, characterized in that the first central part (4) is glued in a central opening of the first washer or socket (8), and in that the first washer or socket (8) with the first central piece (4) are in direct contact with the first magnet (6) and the first counter-pivot support stone (10). 9. Magnetic centering device according to claim 4, characterized in that the first central part (4) is driven into a central opening of the first washer or socket (8), and in that the first washer or socket (8) with the first central piece (4) are in direct contact with the first magnet (6) and the first counter-pivot support stone (10). 10. Magnetic centering device according to one of claims 8 and 9, characterized in that the external diameter of the first magnet (6) is identical to the external diameter of the washer or socket (8) and to the external diameter of the first stone counter-pivot support (10). 11. Magnetic centering device according to one of claims 8 and 9, characterized in that the external diameter of the first magnet (6) is identical to the external diameter of the washer or socket (8), and in that the first stone counter-pivot support (10) has a diameter less than the diameter of the first washer or socket (8) by being fixed in a lower central hollow of the first washer or socket (8) on the side of the first end pivot ( 2). 12. Magnetic centering device according to one of claims 10 and 11, characterized in that the first magnetic bearing (20) comprises a first support (22), which comprises a base on the side of the first end pivot (2) with an opening (23) of diameter greater than the diameter of the first end pivot (2) for the contactless passage of the first end pivot (2), a first chaton (21) positioned in the first support (22) and held in an inverted cone-shaped housing of the first support (22) by elastic means (24), and in that the bezel successively comprises, a first upper support stone (12), the first permanent magnet (6) , the first central piece (4) placed in the first washer or socket (8), and the first counter-pivot support stone (10). 13. Magnetic centering device according to claim 1, characterized in that it comprises a second magnetic bearing (30) comprising a second magnet (7), which is intended to exert an attractive force on a second end pivot (3) made of ferromagnetic material of the shaft (1), the second end pivot (3) being opposite the first end pivot (2) of the shaft (1). 14. Magnetic centering device according to claim 13, characterized in that the second magnetic bearing (30) comprises a second central piece (5) of soft ferromagnetic material mounted between the second magnet (7) and the second end pivot ( 3) of the shaft (1), this second central part (5) being placed centrally in a second washer or socket (9) of non-magnetic material to center the flow of magnetic field generated by the second magnet (7) through the second central part (5) to magnetically attract the second end pivot (3) of the shaft (1) along the determined axis, in that the diameter of the second central part (5) is identical or greater than 0 at 20% relative to the diameter of the second end pivot (2), and in that the second magnetic bearing (30) also comprises a second counter-pivot support stone (11), which is mounted between the second part central (5) and the second end pivot (3) of the shaft (1). 15. Magnetic centering device according to claim 13, characterized in that the second magnetic bearing (30) comprises a second central piece (5) of soft ferromagnetic material mounted between the second magnet (7) and the second end pivot ( 3) of the shaft (1), this second central part (5) being placed centrally in a second washer or socket (9) of non-magnetic material to center the flow of magnetic field generated by the second magnet (7) through the second central part (5) to magnetically attract the second end pivot (3) of the shaft (1) along the determined axis, in that the diameter of the second central part (5) is identical or less than 0 at 20% relative to the diameter of the second end pivot (2), and in that the second magnetic bearing (30) also comprises a second counter-pivot support stone (11), which is mounted between the second part central (5) and the second end pivot (3) of the shaft (1). 16. Magnetic centering device according to one of claims 14 and 15, characterized in that the second counter-pivot support stone (11) is made of ruby. 17. Magnetic centering device according to one of claims 14 and 15, characterized in that the second washer or socket (9) is made of brass.