CH702720A2 - Hybrid hammer for striking mechanism in e.g. mechanical watch, has impact part made of material harder than hardened steel and whose volume is greater than that of metallic bead, where bead allows mounting of hammer on plate of mechanism - Google Patents

Abstract

The hammer (2) has an impact part (2') constituted of a material e.g. hard metal or cobalt tungsten carbide, harder than hardened steel. The impact part strikes a gong (11) of a striking mechanism (1). A metallic bead (2'') allows mounting of the hammer on a plate of the mechanism. A drive pin (6) is arranged between a rotational shaft (7) and the impact part. The bead and the shaft are made of hardened steel. The impact part has density greater than/equal to 14700 kilogram per cubic meter, modulus of elasticity greater than/equal to 630 gigapascal, and volume greater than that of the bead.

Description

The invention relates to a hammer of a striking mechanism of a watch. Said hammer in the striking mechanism is able to strike at least one stamp of the striking mechanism in periods of time determined for the production of a sound.

In the field of watchmaking, a traditional architecture is used to perform a movement, which may be provided with a striking mechanism, for example for minute repetitions. For such an embodiment, the stamp used is a wire, for example steel, which may be generally circular. This wire is arranged around the movement, in the watch cage. This stamp is fixed, for example by solder, to a stamp holder, which is itself secured to the watch plate. The vibration of the stamp is produced by the impact generally near the stamp holder of at least one hammer. The sound produced by the hammer hit is within the audible frequency range of 1 kHz to 20 kHz to signal to the wearer of the watch a definite time, a programmed alarm or a minute repeater.

As indicated above in a mechanical or electromechanical watch, a striking mechanism may comprise one or more metal stamps, configured for example in a portion of a circle. Generally, the stamp (s) surround part of the movement of the watch. Each stamp may be struck by a respective hammer rotatably mounted on the watch plate near the stamp holder, and held by a spring element in a rest position as shown for example in the patent document EP 1 574 917.

In the state of the art, it is still used a hammer that is easily made of steel, especially hardened steel. This hammer hardened steel is considered hard enough for the production of a sound by the stamp struck by said hammer. However, with such a hardened steel hammer, the sound produced by the stamp hit by this hammer is at an acoustic level often insufficiently high and not very crystalline for the wearer of the watch, which can be a disadvantage. Another disadvantage of such a hardened steel hammer is that its density is not large enough. As a result, it does not have an inertial mass sufficient to produce a high acoustic level when the hammer hits the stamp.

The invention therefore aims to overcome the disadvantages of the state of the art by providing a hammer for a striking mechanism of a watch, made in such a way as to increase the sound level of the sound produced by the stamp struck by said hammer.

For this purpose, the invention relates to a hammer for a striking mechanism of a watch, which comprises the features defined in the independent claim 1.

[0007] Particular embodiments of the hammer for a striking mechanism of a watch are defined in the dependent claims 2 to 13.

An advantage of the hammer according to the present invention lies in the fact that the first impact part of the hammer is made of a harder material than hardened steel, especially in a hard metal. With this first hard metal impact part, this makes it possible to produce a more crystalline sound and a higher acoustic level, when the stamp is struck by said hammer. Until now, it has never been imagined to be able to make a hammer with a first impact part of high hardness material, fixed to a metal heel including hardened steel. Since the first hard metal impact part is very difficult to work with and possibly brittle, it can thus be expected to easily hunt, river or glue a hammer rotation rod on a ring mechanism plate and / or a Hammer drive pin on or through an end portion of the hardened steel heel.

Advantageously, the material of the first impact part is of greater density than the density of the material of the metal heel. In addition, the volume dimensions of the first impact part are much larger than those of the metal heel so as to obtain a large inertial mass of the hammer even in a limited space available inside the watch. Thanks to this important inertial mass of the hammer, the striking of the stamp by the hammer can be carried out with a maximum of energy.

Advantageously, a hammer rotation rod and / or a hammer driving pin can be driven, riveted or glued on or through an end portion of the metal heel, after positioning and fixing the first part of the hammer. impact on the metallic heel. Preferably, the first impact portion of the hammer is welded or brazed to an edge of the metal bead. After positioning and fixing the first impact part on the metal bead, one or more holes, for example through, can then be made in the metal bead being well positioned and oriented relative to the main body of the hammer. The rotating rod and / or the drive pin can then easily be driven out or glued into a corresponding hole in the metal bead.

Advantageously, the first impact part of the hammer is made with a hard metal having a hardness greater than 1000 HV, preferably hardness more than twice that of hardened steel. This hard metal may be cobalt tungsten carbide. It can also be imagined a first impact part of the hammer made of ceramic or even diamond. In addition, both the density and the modulus of elasticity of the hard metal selected may be nearly twice the density and modulus of elasticity of hardened steel. The first impact part of high hardness material is thus scratchproof and very resistant to oxidation.

The purposes, advantages and characteristics of the hammer for a striking mechanism of a watch will appear better in the following description in particular with reference to the drawings in which: <tb> fig. 1 <sep> schematically represents a striking mechanism of a watch, which is provided with a hammer according to the invention for striking a stamp of the striking mechanism, <tb> fig. 2 <sep> represents a more detailed top view of the two assembled parts of the hammer according to the invention for a striking mechanism of a watch, and <tb> fig. 3 <sep> represents a partial sectional view along the line III-III of FIG. 2 of the hammer according to the invention for a striking mechanism of a watch.

In the following description, all parts of the striking mechanism of a watch, which is provided in particular with a hammer to hit at least one stamp, which are well known in this technical field, will be described only briefly.

In FIG. 1, there is shown in a simplified manner a striking mechanism 1, which comprises at least one stamp 11 connected to a stamp holder 12, which can be fixed on a plate of the not shown striking mechanism. A hammer 2 of the striking mechanism is rotatably mounted about an axis 7 on the plate near the stamp holder 12. This hammer is used to hit the stamp 11 to produce a sound to signal for example the hours, minutes or a scheduled alarm time. The stamp 11 can be made in the form of a circle portion for example by means of a wire generally made of steel, or also in a precious metal or metal glass. This portion of a circle traditionally surrounds part of the unrepresented watch movement.

The hammer 2 generally comprises two parts 2 and 2, which are fixed to one another. A first impact portion 2 of the hammer is made of a harder material than hardened steel and high density. This first impact part 2, which is preferably made of hard metal, is used to strike by a rounded edge 2a at least one stamp 11 of the striking mechanism 1. A second part constitutes a heel 2 by the intermediate of which the hammer 2 can be mounted on a plate of the striking mechanism. This heel 2 "is preferably made of metal material, such as hardened steel. The attachment of the first impact part 2 to the metal heel 2 is advantageously carried out by brazing or soldering as explained hereinafter with reference to FIGS. 2 and 3.

A rotation rod 7 of the hammer 2 on the plate is preferably driven into a through hole of diameter slightly less than the diameter of the rod 7. This through hole is formed in an end portion of the metal heel 2 . This rod 7 may also be made of metal, such as hardened steel. This rod 7 is rotatably mounted on an opening of the not shown plate, to form the axis of rotation of the hammer 2 on the plate.

Of course, the rotation rod 7 can also be riveted or glued on or through a hole of an end portion of the metal heel 2. This rod can also come from material with the metal heel to form a single piece.

For the striking mechanism 1, the first impact portion 2 of the hammer 2 is held at rest at a distance from the stamp 11 by a damping assembly 4, 4a and 5. This damping assembly comprises in known manner a lever 5 rotatably mounted about an axis 8 fixed to the plate of the striking mechanism of the watch, and a wheel 4 of adjustment. A pin 4a is placed off-center on the adjusting wheel. This pin is in contact with a surface of a first cam-shaped end of the lever. The other arcuate end of the lever 5 holds the hammer 2 by means of a drive pin 6 in a rest position. This drive pin 6 is fixed on the metal heel 2 "of the hammer. This drive pin can advantageously be driven into a through hole made in the heel between the rod 7 and the first impact part 2. The rest distance between the rounded edge 2a of the first impact portion 2 of the hammer and the stamp 11 can be adjusted by means of the wheel 4 with the off-center pin 4a in contact with the surface of the first end of the lever 5.

To produce a vibration stamp struck, the hammer 2 is pushed sharply on its drive pin 6 towards the stamp 11 by a free end of a spring 3. This spring 3 is previously armed through a lift not shown. The damping assembly, in particular the arcuate part of the lever 5 which can flex, must also be made in such a way as to prevent a double impact of the hammer against the stamp as a result of the action of the reinforced spring 3. To do this, the damper assembly can be made for example of hard metal whose modulus of elasticity is about triple that of traditional hardened steel. The elastic deformation of the damper is three times lower for a given stress.

According to the invention, the first impact part 2 of the hammer 2 is made of a harder material than hardened steel, which has a hardness of the order of 650 HV. This material with high hardness can advantageously be a hard metal of hardness greater than 1000 HV. An example of a hard metal is cobalt tungsten carbide (WCCo), which has a hardness of the order of 1540 HV.

The material of this first impact part 2 of said hammer 2 must also be of high density to obtain a large inertial mass of the hammer. This density must be greater than that of hardened steel which is of the order of 8000 kg / m <3>. With a large density of the selected material of the first impact part 2, for example greater than 10,000 kg / m <3>, this increases the energy at the impact of the hammer 2 against the stamp 11 according to a given speed of the hammer. Preferably, the density of the selected material, such as hard metal, should be at least 1.5 to 2 times greater than that of hardened steel, for example equal to or greater than 14,700 kg / m 3.

The first impact part 2 of the hammer 2 can still be made with a hard material, whose modulus of elasticity is greater than that of hardened steel, which is of the order of 220 GPa. Preferably, this modulus of elasticity of the material used to make the hammer may be greater than 500 GPa, especially greater than or equal to 630 GPa. With a large modulus of elasticity of the material of the hammer 2, it is possible to minimize the elastic deformation of the hammer during impact against the stamp for a given stress. This also minimizes internal losses due to deformation. With such a material constituting the first impact part 2 of the hammer, the acoustic level of the sound produced by the stamp 11 struck by the hammer is increased, which is desired.

To explain the realization of such a hammer, reference is now made to FIGS. 2 and 3, which represent on the one hand the two parts 2 and 2 assemblies of the hammer 2 in plan view, and on the other hand a partial section of the hammer 2 along the line III-III of FIG. 2.

In FIG. 2, the hybrid hammer 2 essentially comprises two parts 2 and 2 assembled to each other. Preferably, the first impact portion 2 of the hammer is made of a harder material than hardened steel traditionally used for producing a hammer of a striking mechanism of a watch. This first impact part 2 is preferably a hard metal, such as cobalt tungsten carbide (WCCo), which has a hardness of the order of 1540 HV and a density greater than 14 700 kg / m <3 >. To obtain a large inertial mass of the hammer 2, the first impact part 2 must be of a greater volume than the volume of the second part, which is a metal heel 2. This first hard metal impact part 2 can advantageously be brazed or welded to the metal bead 2 of the hammer. The edge of the metal bead 2 and the assembly portion of the first impact portion 2 are represented by the two parallel lines in broken lines in this FIG. 2.

As the first impact part 2 is hard metal, this first impact part is difficult to work and can be brittle. This first impact part is therefore advantageously brazed or welded to the metal bead 2 including hardened steel in which it is easier to make holes for fixing a rotating rod or drive pin. The assembly portion of the first impact portion 2 is firstly brazed or welded to an edge of the metal heel 2. Subsequently, it is easy to make a first hole 7 to receive a hammer rotation rod on the plate, and a second hole 6 to receive a hammer drive pin. These two holes 6 and T are well positioned and well oriented relative to the main body of the hammer 2 according to the position of the first impact part fixed on the metal heel.

In FIG. 3, it is well represented the assembly portion of the first impact part 2 welded or brazed by a metal material 14 on an edge of the metallic bead 2. The assembly portion of the first impact portion 2 is in the form of a notch 13, which consists mainly of two flat surfaces arranged for example perpendicular to one another. This connecting portion is brazed or welded to a complementary shaped edge, which comprises two surfaces, for example at right angles, of the metal heel 2. To facilitate the positioning, as well as the solder or solder attachment of the first impact part 2 on the metal heel 2, an inner groove 15 is made in an angle of the notch 13 of the assembly portion of the first part of impact.

Of course, the shape of the edge or the connecting portion may be different from that described above as far as it is easy to fix by brazing or welding or other means the first impact part 2 on the metallic heel 2. It could be envisaged to screw the first impact part on the metal heel, but it requires to practice with difficulty at least one hole in the hard material of the first impact part. In addition, the attachment of the first impact part on the metal heel can be performed by a dovetail attachment.

Once the first impact part 2 is fixed on the metal heel 2, the holes 6 and 7 are formed in the heel to receive the drive pin 6 and the rotation rod 7 Preferably, the chamfered pin 6 and the chamfered rotating rod 7 are driven into each corresponding hole 6 and 7 of slightly smaller diameter. The pin 6 and the rod 7 can also be glued into each corresponding hole or on the heel without making holes, or also riveted on the metal heel. Wherever possible, it may also be envisaged to make the pin and the rod coming from material with the metal heel before fixing said heel 2 "with the first impact part 2.

From the description that has just been made, several embodiments of the hammer for a striking mechanism of a mechanical watch or electro-mechanical can be designed by the skilled person without departing from the scope of the present invention. invention defined by the claims. The hard material of the first impact part of the hammer may also be ceramic or diamond, but under these conditions, an additional mass must be placed on the first part.

Claims (13)

Hammer (2) for a striking mechanism (1) of a watch, which comprises at least one stamp (11) capable of being struck by said hammer to produce a sound, characterized in that the hammer comprises two parts fastened to each other, a first part being made of a material harder than hardened steel to constitute an impact part (2) of the hammer against a stamp (11) of the striking mechanism, while a second part is a heel (2) through which the hammer can be mounted on a plate of the striking mechanism. 2. Hammer (2) according to claim 1, characterized in that the first impact part (2) of the hammer is made of hard metal, and in that the first impact part (2) is fixed by solder or solder on the metallic heel (2). 3. Hammer (2) according to claim 2, characterized in that the first impact part (2) of the hammer consists of a hard metal having a hardness greater than 1000 HV, preferably greater than 1500 HV. 4. Hammer (2) according to one of the preceding claims, characterized in that the material of the first impact portion (2) of the hammer is tungsten carbide-cobalt. 5. Hammer (2) according to claim 1, characterized in that the density of the material of the first impact part (2) of the hammer is greater than 10 000 kg / m <3>, preferably equal to or greater at 14,700 kg / m <3>. 6. Hammer (2) according to claim 1, characterized in that the modulus of elasticity of the first impact part (2) hard metal hammer is greater than 220 GPa, preferably equal to or greater than 630 GPa . 7. Hammer (2) according to one of the preceding claims, characterized in that the metal heel (2) is made of steel, and in that a rod (7) is driven, riveted or glued on or on through an end portion of the metal bead (2) to serve as the axis of rotation of the hammer, when mounted on a plate of the striking mechanism. Hammer (2) according to one of claims 1 to 6, characterized in that a rotation rod (7) of the hammer is made of material with the metal heel (2), and in that the metal heel and the rotating rod are made of hardened steel. Hammer (2) according to one of claims 7 and 8, characterized in that a pin (6) driving the hammer is driven or riveted or glued on or through the metal heel (2) parallel to the hammer rotation shaft and between the rotation rod (7) and the first impact part (2) of the hammer. 10. Hammer (2) according to one of claims 7 and 8, characterized in that a pin (6) for driving the hammer comes from material with the metal heel (2), said pin being parallel to the rotating rod (7) of the hammer and between the rotation rod and the first impact part (2) of the hammer. 11. Hammer (2) according to one of the preceding claims, characterized in that the first impact portion (2) is of a volume greater than the volume of the metal heel (2). 12. Hammer (2) according to one of claims 2 to 11, characterized in that the first impact part (2) of the hammer comprises an assembly portion in the form of a notch (13), which consists mainly of two plane surfaces arranged perpendicular to each other, the joining portion being brazed or welded to a complementary shaped edge, which comprises two right-angle surfaces, of the metal heel (2 ). 13. Hammer (2) according to claim 12, characterized in that an inner groove (15) is formed in an angle of the notch (13) of the connecting portion of the first impact portion (2) for facilitate positioning and attachment by brazing or welding (14) of the first impact part on the metallic heel (2).