CH702250B1 - Device Anti-Shock watch. - Google Patents

Abstract

A watch device comprising a first support (9), a second support (10) and an axis (8), comprising at its ends pivots (31) located in respective openings (33) of the supports and, near one at least pivots (31), a part (32) of larger section than the corresponding pivot (31), the opening (33) of at least one of the supports (9, 10) comprising a first part in which is located the pivot (31) corresponding with a first side game and a second part in which is located the correspondingly larger section portion (32) with a second side game, is characterized in that the second game is greater than the first game but is small enough so that, during a lateral impact pressing the pivot (31) against the wall of the first part, the part of larger section (32) can come into contact with the wall of the second part by a deformation purely elastic axis (8).

Description

The present invention relates to a watch device, in particular a regulating member, protection against shocks.

We know that in a mechanical watch movement, the axis of balance, the balance and the balance spring are very sensitive to shocks, including lateral. To prevent the balance shaft from breaking at its fragile pivots, it is known to provide the regulating member with an anti-shock device such as a device marketed under the trademark Incabloc ™ or a device of the type described for example in patent CH 251 930.

These anti-shock devices generally comprise, in large housings provided for this purpose in the movement plate and the balance bridge, pierced stones which respectively receive the pivots of the balance shaft, each pierced stone being mounted in a kitten on which is placed a counter-pivot stone subjected to the action of a spring. These anti-shock devices are relatively complicated to implement and are bulky. In addition, they can affect the aesthetics of movement by hiding the view on the sprung balance of the regulating organ.

The present invention aims to remedy at least in part these disadvantages and proposes for this purpose a clock device comprising a first support, a second support and an axis comprising at its ends pivots located in respective openings of the supports and, near at least one of the pivots, a portion of larger section than the corresponding pivot, the opening of at least one of the supports comprising a first part in which is located the corresponding pivot with a first lateral clearance and a second part in which is located the part of larger section corresponding with a second side game, characterized in that the second game is greater than the first game but is small enough that, during a side impact pressing the pivot against the wall of the first part, the part of larger section can come into contact with the wall of the second part by deformation puremen t elastic axis.

Thus, in the present invention, the large housings formed in the supports (bridge, platinum), the pierced stones, their kittens, the counter-pivot stones and the spring are removed. The anti-shock effect is obtained not by the addition of a specific device, as in the prior art, but by appropriate dimensioning of the axis and the openings or bearings of the supports. Current manufacturing processes indeed allow a very precise sizing and great control of games. The first clearance between the pivot and the wall of the first part of the opening can thus be small enough to ensure accurate and stable positioning of the axis. The first game is smaller than the second game so that it is the pivot that slides on the wall of the opening during the normal operation of the watch device rather than the part of larger section, in order to minimize friction. The second set is nevertheless small enough that the part of larger section of the axis, part which is stronger than the pivot, abuts against the wall of the opening, more precisely against the wall of the second part of the opening, before the elastic limit of the material in which the axis is made is exceeded. In this way, not only the pivot does not break in case of side impact, but it does not undergo permanent deformation either. Once the effect of the shock has stopped, the axis returns to its original shape.

Typically, the second set is at most equal to 40 microns. It is preferably at least equal to 10 μm and at most equal to 40 μm, and more preferably equal to approximately 25 μm.

The first set is typically at least 3 microns and at most equal to 8 microns, and is preferably about 5.5 microns.

Advantageously, the axis is made of titanium.

Preferably, at least one of the supports is a transparent material such as diamond, glass or sapphire.

The axis may comprise an amorphous adiamantin carbon coating.

Each of the supports is for example a bridge or a plate.

At least one of the supports may comprise at least two superimposed boards.

At least one of the openings may be closed at its end opposite to that receiving the axis by a stopper length chosen so that the axial play between the axis and the supports is equal to a predetermined value.

In a preferred application of the present invention, said axis is a regulating member axis such as a balance shaft.

The present invention also proposes a watch movement, characterized in that it comprises a watch device as defined above and in that this watch device is in the form of a module attached to the rest of the movement by screws putting damping washers in compression. This clock device is for example a regulating organ.

In a particular embodiment, the first and second supports are respectively an upper bridge and a lower bridge of the clock device, and these bridges are interconnected by pillars assembled to the bridges by screws with compression damping washers .

Advantageously, the threadlock is provided in the thread of at least one of the screws.

Other features and advantages of the present invention will appear on reading the following detailed description with reference to the accompanying drawings, in which: <tb> fig. 1 <SEP> is a plan view from above of a movement comprising a regulating member according to a preferred embodiment of the invention; <tb> fig. 2 <SEP> is a perspective view from above of the movement illustrated in FIG. 1; <tb> fig. 3 <SEP> is a sectional view of the regulating member forming part of the movement illustrated in FIGS. 1 and 2, this sectional view being taken along the broken line III-III of FIG. 1; <tb> fig. 4 <SEP> is a sectional view of the regulating member forming part of the movement illustrated in FIGS. 1 and 2, this sectional view being taken along the line IV-IV of FIG. 1; <tb> fig. <SEP> is a sectional view of the regulating member forming part of the movement illustrated in FIGS. 1 and 2, this sectional view being taken along the line V-V of FIG. 1; and <tb> fig. 6 <SEP> is a detail view of the zone VI of FIG. 3.

[0019] Referring to FIGS. 1 to 5, a clock device according to a preferred embodiment of the invention is constituted by a regulating member 1 in the form of a module fixed in an opening 2 of the plate 3 of a movement (FIG. and 2). The regulating member 1 comprises a balance 4, a hairspring 5 and large and small trays 6, 7 mounted on an axis 8 called "balance shaft" (Figures 3 and 5). In the example shown, the plates 6, 7 are monolithic with the balance shaft 8. The balance shaft 8 is mounted between an upper bridge 9 and a lower bridge 10 separated by pillars 11, two in number in each case. the example shown, each having the upper shoulder 12 and lower 13 on which rest the bridges 9, 10. The upper bridge 9 is clamped between the upper shoulder 12 of the pillars 11 and the clamping screw head 14 screwed into the upper end of the pillars 11. The lower bridge 10 is clamped between the lower shoulder 13 of the pillars 11 and the plate 3 by clamping screws 15 screwed into the lower end of the pillars 11 and whose head bears against the plate 3. Larger pillars 16, two in number in the example shown, connect the upper bridge 9 of the module to a bridge 17 of the movement, namely the barrel and gear wheel, fixed to the plate 3. These pillars 16 each also comprise an upper shoulder 18 and a lower shoulder 19. The upper bridge 9 is clamped between the upper shoulder 18 and the tightening screw head 20 screwed into the upper end of the pillars 16. Other screws 21 are screwed in the lower end of the pillars 16 and have their head respectively bearing against the bridge 17 and against another bridge 22 of the movement, namely the middle mobile bridge (Fig. 4). A bridge 23 connects the lower ends of the pillars 16 being for example glued to these lower ends, against the shoulder 19.

The regulating member 1 also comprises an anchor 24 mounted on an axis 25 itself mounted between the upper deck 9 and an anchor lower deck 26 (Figures 4 and 5). The bridges 9, 26 are separated by intermediate parts 27 having shoulders which receive the bridges 9, 26. The lower end of the intermediate parts 27 is fixed, for example by gluing, in the lower anchor deck 26. Screws tightening 28 screwed into the intermediate parts 27 and whose head bears against the upper deck 9 fix the lower anchor bridge 26 to the upper deck 9.

The regulating member 1 also comprises an escape wheel 29 mounted on an axis 30 mounted itself between the upper bridge 9 of the module and the bridge 23 connecting the pillars 16 (Figures 1, 2 and 5). . The shaft 30 also carries an exhaust pinion 29a. The anchor 24 cooperates traditionally on the one hand with the escape wheel 29 and on the other hand with the large and small plates 6, 7 of the balance shaft 8.

To better maintain the module on the plate 3 and the assembly of the bridges 9, 10 and 26 of the module between them, the thread lock can be used between the threads of the screws 14, 15, 20, 21 and 28 and the threads of the pillars 11, 16 and the intermediate pieces 27.

Advantageously, a damping washer 30 is interposed between the head of at least some and preferably each of the screws 14, 15, 20, 21 and 28 and the surface against which said head supports. The damping washers 30 may be of elastomer or other suitable damping material. Thus put into compression, these washers 30 constitute filters which isolate the active components of the regulating member 1 (balance 4, spiral 5, exhaust 6, 7, 24, 29, balance shaft 8) vibrations and small shocks undergone by the rest of the movement.

To increase the mechanical strength of the bridges 9, 10, these are advantageously each constituted by at least two superimposed boards pressed against each other without any fastening means other than the tightening exerted by the screws 14, 15, 20, 28. In case of vibrations or small shocks, these two boards may undergo a small relative movement which will force the pillars 11, 16 to deform a little to absorb some of the stresses in place of the bridges 9, 10 .

To protect the balance shaft 8 against the greatest shocks, the end portions of the axis 8 and the corresponding openings of the bridges 9, 10 in which these end portions pivot have a geometry and dimensions. particulars which are described below.

As shown in FIGS. 3 and 6, each end portion of the axis 8 comprises a pivot 31, which terminates the axis, and before this pivot 31, a portion 32 of larger diameter or section. Each end portion of the axis 8 pivots in a bearing formed by an opening 33 of the bridge 9, 10 corresponding itself comprising a first portion 34 which receives the corresponding pivot 31 and a second portion 35 which receives the part of more The first portion 34 is preferably formed in the outer plank of the corresponding bridge 9, 10 and the second portion 35 in the inner plank of said bridge. In the example shown, the part of larger section 32 near the upper pivot 31 constitutes the small plate 7 with which the dart 24a of the anchor 24 cooperates (see Fig. 5). According to this example, a clearance 36 communicating with the second portion 35 of the opening 33 is formed in the bridge 9 for the dart 24a.

The dimensions of each pivot 31 and the first portion 34 of the corresponding opening 33 are such that a lateral clearance (that is to say orthogonal to the axis of balance 8) between 3 and 8 μm exists between the pivot 31 and the wall of the first portion 34 of the opening 33. This lateral clearance is preferably about 5.5 microns. A lateral clearance is also provided between the part of larger section 32 and the wall of the second part 35 of the opening 33. This latter lateral clearance is greater than that between the pivot 31 and the wall of the first part 34 of the opening 33, but it is small enough so that the larger section portion 32 can abut against the wall of the second portion 35 of the opening 33 under the effect of a lateral impact, by a purely elastic deformation, c that is to say without plastic component, the pivot 31. This avoids a permanent rupture or deformation of the pivot 31 during such a shock, this without resorting to complicated anti-shock devices Incabloc ™ type (brand Mark). The lateral clearance between the part of larger section 32 of the axis 8 and the wall of the second portion 35 of the opening 33 is typically at most 40 μm and at least 10 μm. It is preferably about 25 μm.

In the event of an axial impact, one of the larger section 32 portions of the axis 8 can abut against the bottom of the second portion 35 of the corresponding opening 33 to protect the pivot 31 corresponding. Alternatively, as shown in the drawings, the openings 33 may be through and their outer ends, opening on the outer surface of the bridges 9, 10, may be closed by plugs 37 each having an axial protrusion 38 which penetrates forcibly into the corresponding aperture 33 and a head 39 which rests on the outer surface of the bridge 9 or 10 corresponding. The plugs 37, which are for example made of steel or titanium, serve as axial abutments to the axis 8 and can be chosen from plugs of different lengths to adjust the axial play of the axis 8 with respect to the bridges 9, 10 .

The axis 8 is made of an elastic material such as titanium. It could nevertheless be made in other materials such as steel. The bridges 9, 10, 23, 26 are preferably made of a transparent material, for example diamond (natural or synthetic), glass or sapphire, to make visible the active components of the regulating organ including the balance-hairspring . In particular, thanks to the absence of the abovementioned anti-shock devices, the central part of the balance spring can be made visible. The rocker 4, the anchor 24, the wheel and the escape gear 29, 29a as well as the wheels, gables, planks, bridges and platinum of the movement can also be made of a transparent material of the diamond type (natural or synthetic) , glass or sapphire. The openings 33 can be made, for example, by laser etching or by deep reactive ion etching (DRIE). In the case in particular where the bridges 9, 10 and 26 are diamond, the axes 8, 25 and 30 are advantageously metal coated with a layer of amorphous carbon adiamantin ADLC (amorphous diamond-like carbon) to reduce friction.

The geometry and anti-shock dimensioning of the axis and corresponding openings as described above for the balance shaft 8 can be applied to the other axes of the regulating member, namely the axis 25 of the anchor 24 and the axis 30 of the escape wheel 29, as well as the other axes of the movement. In the example shown, the geometry and the anti-shock dimensioning are applied to one of the two ends of the axis 30, namely its upper end as shown in FIG. 5, and are not applied to the axis 25 of the anchor 24. It is also possible, for a given axis, to shape and size one of the ends of the axis and the opening of the bridge or the corresponding platen as described in relation to the balance shaft 8, and use for the other end a traditional anti-shock device. The plugs 37 can also be used for the other axes of the regulating member as well as for the other axes of the movement.

Furthermore, although the embodiment described above and illustrated in the drawings is particularly advantageous in terms of resistance to shock and vibration, one could implement the geometry and anti-shock dimensioning of the axis and corresponding openings as described above without using damping washers 30. Conversely, it could achieve a clock device such as a regulating member in the form of a module attached to the rest of the movement by screws with damping washers in compression, without implementing the abovementioned anti-shock geometry and dimensioning.

Claims (19)

1. watch device (1) comprising a first support (9), a second support (10) and an axis (8) comprising at its ends pivots (31) located in respective openings (33) of the supports and, close to at least one of the pivots (31), a portion (32) of larger section than the pivot (31) corresponding, the opening (33) of at least one of the supports (9, 10) comprising a first portion (34) in which is located the pivot (31) corresponding with a first lateral clearance and a second portion (35) in which is located the correspondingly larger portion (32) with a second lateral clearance, characterized in that that the second game is greater than the first game but is small enough so that, during a side impact pressing the pivot (31) against the wall of the first portion (34), the larger section portion (32) can come in contact with the wall of the second part (35) by a purely elastic deformation of the xe (8). 2. Watch device according to claim 1, characterized in that the second clearance is at most equal to 40 microns. 3. Watch device according to claim 2, characterized in that the second clearance is at least equal to 10 microns. 4. Watch device according to claim 3, characterized in that the second clearance is equal to about 25 microns. 5. Watch device according to one of claims 1 to 4, characterized in that the first set is at least equal to 3 microns. 6. Watch device according to claim 5, characterized in that the first set is at most equal to 8 microns. 7. Watch device according to claim 6, characterized in that the first clearance is approximately 5.5 microns. 8. Watch device according to one of claims 1 to 7, characterized in that the axis (8) is made of titanium. 9. Watch device according to one of claims 1 to 8, characterized in that at least one of the supports (9, 10) is a transparent material. 10. Device according to claim 9, characterized in that said transparent material is diamond, glass or sapphire. 11. Watch device according to one of claims 1 to 10, characterized in that the axis (8) comprises an amorphous adiamantin carbon coating. 12. Watch device according to one of claims 1 to 11, characterized in that each of the supports (9, 10) is a bridge or a plate. 13. Watch device according to claim 12, characterized in that at least one of the supports (9, 10) comprises at least two superimposed boards. 14. Watch device according to one of claims 1 to 13, characterized in that at least one of the openings (33) is closed at its end opposite to that receiving the axis (8) by a plug (37). length chosen so that the axial clearance between the axis (8) and the supports (9, 10) is equal to a predetermined value. 15. Watch device according to one of claims 1 to 14, characterized in that said axis (8) is a regulating member axis such as a balance shaft. 16. Watch movement characterized in that it comprises a watch device (1) according to one of claims 1 to 15 and in that said watch device is in the form of a module attached to the rest of the movement by screws (15, 21) putting damping washers (30) in compression. 17. Clock movement according to claim 16, characterized in that said clock device (1) is a regulating member. Clock movement according to Claim 16 or 17, characterized in that the first and second supports (9, 10) are respectively an upper bridge and a lower bridge of the clock device, and in that these bridges are interconnected by means of pillars (11) assembled to the bridges by screws (14, 15) putting damping washers (30) in compression. 19. Watch movement according to one of claims 16 to 18, characterized in that it comprises threadlock in the thread of at least one of the screws (14, 15, 21).