CH714791B1 - Toothed member for a timepiece. - Google Patents

Abstract

The invention relates to a toothed member (5), in particular a racket, in particular a fine adjustment racket, or a part intended to mesh with a racket or a fine adjustment racket, comprising: at least one toothed sector (51); and a flexible structure arranged under the roots of the teeth of the at least one toothed sector (51).

Description

The invention relates to a toothed member. The invention also relates to a system comprising such a toothed member. The invention also relates to a timepiece mechanism comprising such a system and/or such a toothed member. The invention finally relates to a timepiece comprising such a timepiece mechanism and/or such a system and/or such a toothed member.

[0002] Adjusting the frequency of a balance-spring mechanism, in order to adjust the rate of a movement, requires precision. Such adjustment is sometimes provided by a gear system whose purpose is to increase the movement of the adjustment racket to achieve this precision goal. However, the use of a gear introduces operating clearances between the teeth of the members meshing together. This involves tooth movement in the teeth and play catch-up when the racket is moved in a first direction and then in a second direction. These faults are not acceptable when it comes to adjusting the rate of a balance-spring mechanism.

The object of the invention is to provide a toothed member to avoid such games. In particular, the invention proposes a toothed member making it possible to ensure precise drive of a toothed member, in particular a racket, without backlashes interfering with this drive.

[0004] A toothed member according to the invention is defined by claim 1.

[0005] Different embodiments of the toothed member are defined by dependent claims 2 to 8.

A system according to the invention is defined by claim 9.

[0007] A timepiece mechanism according to the invention is defined by claim 10.

[0008] A timepiece according to the invention is defined by claim 11.

The appended figures show, by way of example, one embodiment of a timepiece according to the invention. Figure 1 is a perspective view of one embodiment of a timepiece. Figure 2 is a perspective detail view of a toothed member of the embodiment of the timepiece. Figure 3 is a perspective detail view of a rack of the embodiment of the timepiece. Figure 4 is a perspective detail view of a racket of the embodiment of the timepiece.

An embodiment of a timepiece 200 is described below with reference to Figures 1 to 4. The timepiece 200 is for example a watch, in particular a wristwatch. The timepiece comprises a timepiece mechanism 100, in particular a mechanical timepiece movement. The watch movement 100 is for example of the manual winding type or of the automatic winding type.

[0011] The watch movement 100 comprises an oscillator of the balance type 1 - hairspring 2. To adjust the rate, a first racket 10 of coarse adjustment, carrying a racket key 11 acting on the hairspring 2 is moved around a pivot axis 53 with respect to a cock 7, or balance bridge, fixed on a plate 8.

[0012] A stud holder 4 maintains a stud 3 on which the outer end of the hairspring is fixed.

The first racket 10 is pinched on a second racket 5 for fine adjustment, of which it accompanies the rotational movements around the axis 53. The friction torque between the racket 5 and the fine adjustment racket, however, makes it possible to roughly modify the angular position between the two rackets by means of a watchmaker's tool.

[0014] To allow precise rotational drive of the first racket around the axis 53, the second racket comprises a toothed sector 51 meshing with a pinion 6 mounted in a pivot connection on a frame of the movement, in particular mounted in a pivot connection on the rooster 7 around an axis 63.

[0015] Thus, a rotation of the pinion 6 around the axis 63 generates an angular displacement of the second racket 5 around its pivot axis 53. This modifies the length of the active part of the hairspring and makes it possible to adjust walk.

To facilitate the rotation of the pinion 6, an ad hoc drive cavity 9, easily accessible, is provided on the pinion 6. The cavity may be a slot 9 intended to receive one end of a screwdriver.

[0017] Thus, the watch mechanism 100 comprises a system 300, in particular a rack type system comprising the stud 3, the stud holder 4, the first rack 10, the second rack 5 and the pinion 6.

As illustrated more specifically in Figure 2, in the embodiment shown, the toothed member is the second racket 5. As mentioned above, the second racket 5 comprises a toothed sector 51 intended to mesh with teeth 61 of the pinion 6.

The second racket 5 also comprises a flexible structure 52 arranged under the feet of the teeth of this toothed sector 51.

[0020] By “flexible structure”, we mean a structure capable of deforming if a stress is applied to it and of returning to its original shape once the stress has disappeared. In other words, the flexible structure is an elastically deformable structure, in particular an elastically deformable structure in a radial direction with respect to the pivot axis 53.

[0021] By "under the feet of the teeth", it should be understood that the flexible structure 52 extends to a diameter less than, or just less than, the diameter of the foot of the teeth of the toothed sector 51 in the case of a circular or arcuate toothed sector. In other words, the flexible structure 52 is preferably arranged close to the toothed sector 51. In such a case, the difference between the root diameter of the teeth and the flexible structure is for example of the order of 0.2 mm. This difference is for example determined according to the material or materials of the flexible structure and/or its thickness, measured parallel to the pivot axis 53.

However, the flexible structure can be arranged anywhere between the toothed sector 51 and the pivot axis 53.

[0023] Preferably, the flexible structure 52 of the second racket 5 is perforated. Thus, the flexible structure 52 may for example have one or more circular holes or openings (not shown). Alternatively to these circular holes, or in combination of these circular holes, the flexible structure 52 can have openings or openings which can for example have square, rectangular shapes or even other shapes.

Preferably, as illustrated in Figures 1 and 2 and explained above, the second racket 5 is arranged to pivot around the pivot axis 53. The flexible structure 52 then extends for example over a flexible angular sector around this pivot axis 53. The flexible angular sector preferably has an amplitude equal, or substantially equal, to that of the angular sector over which the toothed sector 51 extends. Alternatively, the flexible angular sector can have a lower or an amplitude greater than the angular sector of the toothed sector 51.

According to the preferred embodiment, the flexible structure 52 has at least one elastic blade 522. Preferably, several elastic strips 522 equip the flexible structure 52. The strips 522 are oriented parallel or substantially parallel to a root surface of the teeth, as illustrated in FIG. 2, that is to say parallel or substantially parallel to the cylindrical surface passing through the roots of the teeth of the toothed sector 51.

At least two cutouts 521, or even more, are provided on either side of a blade 522 so as to generate this blade. These cutouts 521 preferably have a thickness, measured perpendicular to the root surface of the teeth, identical or substantially identical to that of the blades 522. Preferably again, the cutouts 521 are parallel to the blades 522. Alternatively, these cutouts 521 are thicker or thinner than the blades 522 and/or are not parallel to the blades.

[0027] By "tooth root surface" is meant a surface comprising and/or tangent to the bottoms of the teeth.

For example, the blades 522 have a thickness, measured perpendicular to the root surface of the teeth, of 0.06 mm.

[0029] For example, the blades 522 have a length (measured parallel to the root surface of the teeth) of 1 mm.

The toothed member 5 has, at the ends of the blades, legs 523 connecting the blades to the toothed sector 51. The legs 523 also connect the blades 522 to other blades 522. Finally the legs 523 connect the blades 522 to a rigid part 54 of the second racket 5. Preferably, the legs 523 extend radially or substantially radially with respect to the pivot axis 53 or perpendicular or substantially perpendicular to the root surface of the teeth.

The length of the blades 522 is further measured between two consecutive legs 523 located on the same side of the blade.

Preferably again, a leg 523, connecting a first and a second blade 522 to each other, connects one end of the first blade 522 to the middle or substantially to the middle of the second blade 522.

Preferably again, all the legs 523, connecting a first and a second blade 522 to each other, connect one end of a first blade 522 to the middle or substantially to the middle of a second blade 522.

[0034] Alternatively, the legs 523 connecting a first and a second blade 522 between them can connect one end of the first blade to the second blade at another location, such as for example at a third or a quarter of the length of the second blade. .

Preferably, the flexible structure 52 has several rows of blades 522, for example two or three or four or five or six rows of blades 522 arranged parallel or substantially parallel to the root surface of the teeth. In other words, these rows follow sectors of concentric circles, or substantially concentric, having centers located, or substantially located, on the pivot axis 53.

For example, the stiffness constant of the flexible structure 52 is Kr=65 N/mm in the radial direction relative to the axis 53, whereas it is Kt=1000 N/mm in the tangential or orthoradial direction relative to the axis 53. The radial direction is therefore a direction passing through the axes 53-63 and the tangential direction is therefore the direction perpendicular to a line passing through the axes 53-63 with a point of application of a force located at a point of contact between the toothing 51 and the toothing of the transmission 6.

Preferably, the radial stiffness constant Kr is lower, in particular significantly lower, than the tangential stiffness constant Kt. For example, the ratio of the radial stiffness constant Kr to the tangential stiffness constant Kt is lower than 0.1 . Thus, the deformation of the flexible structure is essentially radial, that is to say oriented in a direction passing through the axes 53-63.

The center distance between the pivot axis 53 of the second racket 5 and the axis of rotation 63 of the pinion 6 is predetermined. This predetermined center distance is less than the usual or usually used center distance for a gear having the same toothing characteristics. Indeed, the center distance is usually equal to the sum of the pitch radii of the members 5 and 6 to which a clearance is added, for example 4%. This ensures proper gear operation with backlash in the teeth.

Here, in the embodiment of Figures 1 to 4, the correction of the center distance depends on the manufacturing tolerances of components and the rigidity of the elastic structure 52 of the second racket 5. In this way once the organs 5 and 6 meshed, the flexible structure 52 deforms elastically in compression. This compression is exerted between the pivot axis 53 and the rotation axis 63. Such compression consequently ensures permanent contact at several points between the teeth of the toothed sector 51 of the second racket 5 and the teeth 61 of the pinion 6 There is permanently at least one contact between two pairs of tooth flanks of members 5 and 6, the clearances between the teeth of the second racket 5 and the teeth of the pinion 6 are then eliminated, the teeth being forced together in the other. The flexible structure 52 absorbs the deformation necessary for the meshing of the members 5 and 6. The meshing movement of the members 5 and 6 is therefore in no way hindered and is extremely precise. The adjustment of the rate is then precise and reliable. Indeed, the slightest angular displacement of the pinion 6 is transmitted to the second racket 5.

In the embodiment described, only the second racket is provided with a flexible structure. However, alternatively to the presence of a flexible structure on the second racket or in addition to the presence of a flexible structure on the second racket, it is possible to provide a flexible structure on the pinion, in particular a flexible structure surrounding the hub of the pinion 6. The flexible structure then connects this hub to the toothing 61 located around the flexible structure.

In the embodiment described, the flexible structure is made by practicing conformations, in particular openings in the toothed member. However, the flexible structure can be produced alternatively or additionally by adding an element made of an elastically deformable material and of appropriate rigidity between the toothing and the hub of the toothed member. The elastically deformable material may be a synthetic material, in particular an elastomer. The flexible structure is preferably made of steel or nickel alloy.

In the embodiment described, the racket comprises a first coarse adjustment racket and a second fine adjustment racket. However, the invention can also be applied to rackets comprising a single racket (equivalent to the two rackets 5 and 10 of the embodiment shown which would have been joined together).

In the embodiment described, the invention is applied to a racket system. However, the invention can also be applied to any toothed wheel or rack, in particular any toothed wheel or rack of a horological system, intended to take part in a gear where the backlash must be limited or eliminated.

Claims (11)

1. Toothed body (5), in particular racket or fine adjustment racket, or part intended to mesh with a racket or fine adjustment racket, comprising: - At least one toothed sector (51); and – an elastically deformable structure (52) arranged under the feet of the teeth of the at least one toothed sector (51), between the at least one toothed sector (51) and a pivot axis (53) of the member ( 5), the elastically deformable structure (52) being intended to deform elastically in compression once the member (5) is meshed. 2. Body (5) according to claim 1, characterized in that the elastically deformable structure (52) is an openwork structure. 3. Body (5) according to claim 1 or 2, characterized in that the elastically deformable structure (52) extends over an angular sector centered on the pivot axis (53) of the member (5), in particular an angular sector of amplitude equal to that of an angular sector centered on the pivot axis (53) over which the at least one toothed sector (51) extends. 4. Body (5) according to one of claims 1 to 3, characterized in that the elastically deformable structure (52) has an elastic blade (522) and preferably several elastic blades (522), the blade or blades (522 ) being in particular oriented parallel to a root surface of the teeth. 5. Body (5) according to the preceding claim, characterized in that the blades (522) have at their ends legs (523) connecting them to the toothed sector (51) or to other blades (522) or to a part rigid (54) of the member (5), in particular legs (523) extending radially with respect to the pivot axis (53). 6. Body (5) according to the preceding claim, characterized in that at least one of the legs (523), connecting a first and a second blade (522) between them, connects one end of a first blade (522) in the middle of a second blade (522). 7. Body (5) according to one of claims 4 to 6, characterized in that the elastically deformable structure (52) has several rows of blades (522), in particular two or three or four or five or six rows of blades ( 522) arranged parallel to the root surface of the teeth. 8. Body (5) according to one of the preceding claims, characterized in that the elastically deformable structure (52) has an essentially radial flexibility relative to the axis (53) of pivoting of the body. 9. System (300), in particular racket (3, 4, 5, 6), comprising a first member (5) according to one of the preceding claims meshing with a toothed wheel, such as a pinion (6), the toothed wheel being in particular a second member according to one of the preceding claims, the engagement causing a compression of the elastically deformable structure (52), in particular a radial compression with respect to the pivot axis (53). 10. Clockwork mechanism (100), in particular clockwork movement, comprising an oscillator, the clockwork mechanism (100) being characterized in that it comprises a system (300) according to claim 9 and/or a member (5) according to one of claims 1 to 8. 11. Timepiece (200), in particular wristwatch, characterized in that it comprises a timepiece mechanism (100) according to the preceding claim and/or a system (300) according to claim 9 and/or a member (5 ) according to one of claims 1 to 8.