HOROLOGICAL MOVEMENT COMPRISING A STRIKING MECHANISM PROVIDED WITH A FLEXIBLE GUIDE

Abstract

A horological movement includes a striking mechanism of a watch including a vibrating element and a device for striking the vibrating element including a hammer fastened cantilevered to a structure of the horological movement through blades of a flexible guide. The blades are arranged so as to extend according to directions parallel to an axis T tangent to the vibrating element.

Claims

1-8. (canceled)

9. A horological movement comprising: a striking mechanism of a watch comprising a vibrating element and a device to strike said vibrating element comprising a hammer fastened cantilevered to a structure of the horological movement through elastic blades forming a flexible guide, wherein said blades are arranged so as to extend according to directions parallel to an axis T tangent to the vibrating element at a striking point of the hammer.

10. The horological movement according to claim 9, wherein the striking device is fastened to the structure of the horological movement only by an embedded type mechanical connection.

11. The horological movement according to claim 9, wherein at least the blades are made of silicon, by deep reactive-ion etching.

12. The horological movement according to claim 9, wherein at least the blades are made by laser machining or by electrical discharge machining.

13. The horological movement according to claim 9, wherein at least the blades are made by laser machining by femtosecond laser.

14. The horological movement according to claim 9, wherein the striking device is made in one-piece.

15. The horological movement according to claim 14, wherein the striking device is made of amorphous metal, by moulding or by hot forming.

16. The horological movement according to claim 14, wherein the striking device is made of nickel or of nickel-phosphorus, by the LIGA process.

17. The horological movement according to claim 9, wherein the blades have a smaller thickness than a thickness of the hammer.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0017] Other features and advantages of the invention will appear upon reading the following detailed description given as a non-limiting example, with reference to the appended drawings wherein:

[0018] FIG. 1 schematically represents a top view of a striking mechanism comprising a striking device in a rest state, according to a preferred embodiment of the invention;

[0019] FIG. 2 schematically represents a cross-sectional view of the striking device of the striking mechanism of FIG. 1.

[0020] It should be noted that the figures are not necessarily drawn to scale for clarity purposes.

DETAILED DESCRIPTION OF THE INVENTION

[0021] FIG. 1 shows a striking mechanism 10 of a horological movement of a watch in a preferred embodiment of the invention.

[0022] The striking mechanism 10 comprises a vibrating element 11 and a striking device 120 intended to hit said vibrating element 11 in order to cause the production of a sound. The vibrating element 11 is fastened to a structure of the horological movement, for example to a bridge, to a disc, etc., and is, in the embodiment represented in FIG. 1, formed by a timbre.

[0023] The striking device 120 comprises a hammer 121 fastened cantilevered to the structure of the horological movement through several blades 122 forming a flexible guide. The blades 122 have an elastic deformation capacity and are used in the present invention for guiding and driving the hammer 121. Preferably, the blades 122 are two in number. In particular, each blade 122 has a rectilinear shape when the striking device 120 is in a rest state, i.e. in a position of equilibrium. The flexible guide formed by the blades 122 is a translational guide.

[0024] To sum up, in a manner known per se by a person skilled in the art, the striking device 120 is cocked by an activation mechanism (not represented in the figures), such as a lift or any other dedicated mechanism, i.e. the hammer 121 is driven away from the vibrating element 11, so as to constrain the blades 122 to be deformed progressively, until reaching a cocked state. Next, in response to the passage of a predefined time value of the current hour or upon instruction of the user, the activation mechanism releases the hammer 121 which is then driven, by the effect of the elastic biasing force of the blades 122, to hit on the vibrating element 11, the striking device 120 then being in a striking state.

[0025] Advantageously, the blades 122 allow positioning the hammer 121 very accurately with respect to the structure of the horological movement, and in particular with respect to the vibrating element 11, without any backlash and without lubrication, in contrast with a conventional timepiece pivot. Moreover, the blades 122 provide a constant amount of energy to move the hammer 121 in translation, upon each hit of the striking device 120 on the vibrating element 11.

[0026] As schematically shown in FIGS. 1 and 2, the blades 122 extend between two longitudinal ends. Hence, each blade 122 is mechanically connected, by one of its longitudinal ends, to the structure of the horological movement, and by its other longitudinal end, to the hammer 121. In other words, the striking device 120 is fastened to the structure of the horological movement only by an embedded type mechanical connection, i.e. the blades 122 form the only mechanical connection between the hammer 121 and the structure.

[0027] In particular, each blade 122 may be fastened to the structure of the horological movement by welding, screwing, gluing, tight fitting, or by any other suitable means within the reach of a person skilled in the art.

[0028] The blades 122 are arranged so as to extend according to directions parallel to an axis T tangent to the vibrating element 11, as shown in FIG. 1. More specifically, the axis T is tangent to the vibrating element 11 at a point intended to be subjected to the impact of the hammer 121, i.e. at the striking point of the hammer 121. Thus, the hammer is driven in translation according to a direction D perpendicular to the axis T, or substantially in translation according to a direction tangent to a direction D perpendicular to the axis T.

[0029] This feature has many advantages.

[0030] Indeed, this feature allows maximising the normal component of the forces applied by the hammer 121 on the vibrating element 11 upon hitting, and possibly suppressing any tangential component. Thus, the hit is more effective in terms of forces transmitted to the vibrating element 11 for given elastic characteristics of the blades 122, which generates a higher loudness produced by said hit.

[0031] Moreover, this feature allows for a better control of the position of the striking point of the hammer 121 on the surface of the vibrating element 11, and thus allows for a better control of the vibratory reaction of said vibrating element 11 and therefore of the sound effect produced upon hitting. More specifically, the sound effect produced upon hitting is different depending on whether the striking point is located on a vibration antinode or on a vibration node of a vibratory mode of the vibrating element 11.

[0032] Finally, the use of a flexible guide and its particular arrangement allows reducing the bulk of the striking device 120 and considerably reducing the number of parts forming said device, to the extent that said flexible guide fills both a guidance function and an elastic biasing function.

[0033] Preferably, the striking device 120 is made in one-piece. Thus, the striking device 120 is particularly simple to make, and its manufacturing cost is limited. Furthermore, the mechanism is not likely to suffer from a decrease in power upon hitting related to possible mechanical backlashes that would have existed if the striking device 120 were designed by assembling various parts.

[0034] In particular, the striking device 120 may be made of amorphous metal, for example by moulding or hot forming, or of nickel or of nickel-phosphorus, for example by the LIGA process.

[0035] Alternatively, the striking device 120, and in particular the blades 122, may be made of silicon, for example by dry etching, and more particularly by deep reactive-ion etching, a manufacturing method known as such to a person skilled in the art by the acronym DRIE standing for Deep Reactive Ion Etching. Alternatively, the blades 122 may be made of steel, by laser machining, in particular by femtosecond laser, or by electrical discharge machining.

[0036] In particular, the hammer 121 may include one or more mass(es) made of a metal material, for example of tungsten or of steel, to which the blades 122 are fastened by driving, gluing, by screws or stud-bolts.

[0037] Advantageously, the blades 122 have a smaller thickness than that of the hammer 121, as shown in the schematic sectional view of FIG. 2. This feature allows increasing the mass of the hammer 121 compared to that of the blades 122, and therefore increasing the energy supplied by the latter when hitting against the vibrating element 11.

[0038] It should be noted that the thickness is defined as being the dimension extending according to a direction perpendicular to a plane in which the striking device 120 and the vibrating element 11 are movable.

[0039] More generally, it should be noted that the implementations and embodiments considered hereinabove have been described as non-limiting examples, and that other variants could consequently be considered.

[0040] In particular, the hammer has a trapezoidal shape in the embodiment represented in FIG. 1, but it may also have any shape suitable for carrying out the strike.

[0041] Furthermore, in the embodiment represented in FIG. 1, the vibrating element 11 is formed by a timbre comprising a strand extending according to a circular direction inside which the striking device 120 is arranged. Alternatively, the striking device 120 could be arranged outside the strand of the timbre.

[0042] Moreover, the vibrating element 11 may adopt any suitable shape enabling it to vibrate following a hit of a hammer and gee rate a sound when vibrating, like a bell or a gong.