CH703346A2 - Escapement system for use in timepiece, has rod including arms for receiving pallets, where part of system and pallet assembly are made of material that is partially amorphous and comprises metallic element - Google Patents

Abstract

The system (1) has a pallet assembly (7) provided with a fork that cooperates with a pin mounted on a roller (5). A rod has arms (13) for receiving pallets (21) to cooperate with an escapement wheel (23), where a part of the system and the pallet assembly are made of a material that is partially amorphous and comprises a metallic element. The wheel, the pallets and the roller are made of the material. The part of the system includes recesses to reduce moment of inertia of the part.

Description

The present invention relates to an exhaust system. This exhaust system comprises an anchor provided with a fork intended to cooperate with a pin mounted on a plate, and a rod having arms for receiving paddles to cooperate with at least one escape wheel.

The technical field of the invention is the technical field of fine mechanics.and more particularly watchmaking

BACKGROUND TECHNOLOGY

[0003] Timepieces comprise a source of energy, such as the barrel, which supplies energy to the workpiece and in particular to transmission wheels. These wheels cooperate with the exhaust system via the escape wheel. The rotation of the latter is regulated by the anchor of the exhaust system whose pulses are provided by the balance spring. The exhaust system includes an anchor pivotally mounted on an axle. This anchor comprises a rod provided with a fork, at a first end, intended to cooperate with a pin mounted on a plate, and provided with arms, at a second end, intended to receive pallets in order to cooperate with the wheel. exhaust. During operation, the anchor pivots on its axis so that the paddles of the arms come into contact with the teeth of the escape wheel in order to regulate the rotation of the wheels.

However, currently, the efficiency of the exhaust is relatively low. Indeed, the operation of the exhaust system comprises friction, shock and dissipation of energy in the constituent materials of the wheel and the anchor in particular. A material used is for example 15P or 20AP steel. These materials are crystalline materials Gold, a disadvantage of crystalline metal components is their low mechanical strength when high stresses are applied. Indeed, each material is characterized by its Young's modulus E also called modulus of elasticity (generally expressed in GPa), characterizing its resistance to deformation. Each material is also characterized by its elastic limit σe (generally expressed in GPa) which represents the stress beyond which the material deforms plastically. It is then possible, for given dimensions, to compare the materials by establishing for each the ratio of their elastic limit on their Young's modulus σe / E, said ratio being representative of the elastic deformation of each material. Thus, the higher this ratio, the higher the limit of elastic deformation of the material. Typically, for an alloy of the Cu-Be type, the Young's modulus E is equal to 130 GPa and the elastic limit σe is equal to 1 GPa, which gives a ratio σe / E of the order of 0.007 c that is to say, weak. Parts made of metal or crystalline alloy have, therefore, a limited capacity for elastic deformation.

In addition, the efficiency of an exhaust is related to the energy restitution factor during shocks, these shocks being the shocks between the pallets of the anchor of the escape wheel and the shocks between the ankle. the tray and the fork entrance.

However, the kinetic energy accumulated during the displacement of the anchor or the escape wheel is dependent on the moment of inertia which is a function of the mass and the radius of inertia, so dimensions.

[0007] Since the maximum energy that can be stored elastically is calculated as being the ratio between the square of the elastic limit cre on the one hand and the Young's modulus E on the other hand, the low elastic limit of the metals crystalline causes a low level of energy storage capacity. However, the steels 15P or 20AP are dense and therefore the anchors and escapement wheels have high masses. The moment of inertia is then high and the kinetic energy accumulated during the movements of the anchor and the escape wheel is important.

[0008] However, since crystalline metals can not store a large amount of energy, energy losses occur during raised shocks / teeth of the escape wheel and during shocks between the plateau peg and the entrance. of fork.

As a result, a significant portion of energy delivered by the barrel is lost during operation of the timepiece, thus reducing its power reserve.

[0010] Moreover, watchmaking traditionally uses carbon steels with lead-tempered sulfur and lead which offer good machinability and very good mechanical properties but which are magnetic. Non-magnetic alternatives are rare and generally more difficult to machine and offer poorer mechanical properties.

SUMMARY OF THE INVENTION

The invention aims to overcome the disadvantages of the prior art by proposing to provide an exhaust system with higher efficiency and simpler to achieve.

For this purpose, the invention relates to the exhaust system cited above which is characterized in that at least a portion of the exhaust system is made of a material at least partially amorphous and comprising at least one metal element.

A first advantage of the present invention is to allow the exhaust system to have a better energy restitution factor than current exhausts. Indeed, an amorphous metal is characterized by the fact that, during its manufacture, the atoms composing these amorphous materials do not arrange according to a particular structure as is the case for crystalline materials Thus, even if the modules of Young E of a crystalline metal and an amorphous metal are substantially identical, their elastic limits σe are different. An amorphous metal is then differentiated by an elastic limit σeCplus higher than that σeC of the crystalline metal by a factor of two to three. The elastic limit σe is increased to increase the ratio σe / E so that the stress limit beyond which the material does not return to its initial shape increases, and especially so that the maximum energy that can be stored elastically increases .

Another advantage of the present invention is to allow great ease in formatting for the development of complicated shapes with greater precision. Indeed, the amorphous metals have the particular characteristic of softening while remaining amorphous for a certain time in a given temperature range [Tg -Tx] specific to each alloy (with Tx: crystallization temperature and Tg: glass transition temperature ). It is thus possible to shape them under a relatively low pressure stress and a low temperature then allowing the use of a simplified process compared to machining and stamping. The use of such a material also makes it possible, in the case of shaping by molding, to reproduce very precisely fine geometries because the viscosity of the alloy decreases sharply as a function of the temperature in the range of temperature [Tg - Tx] and the alloy thus marries all the details of a negative. Negative means, a mold which has a hollow profile complementary to that of the desired component. It then becomes easy to make complex but precise designs.

Advantageous embodiments of this exhaust system are the subject of dependent claims 2 to 12.

BRIEF DESCRIPTION OF THE FIGURES

The objects, advantages and characteristics of the exhaust system according to the present invention will appear more clearly in the following detailed description of at least one embodiment of the invention given solely by way of non-limiting example and illustrated by the attached drawings in which: <tb> figs. 1 and 2 <sep> schematically represent a timepiece exhaust system according to the invention;

DETAILED DESCRIPTION

In figs. 1 and 2 is shown an exhaust system 1 with its resonator 3, that is to say the balance spring. In the usual way, the resonator 3 cooperates with the exhaust system 1 by means of a plate 5 mounted on the balance shaft. The exhaust system 1 comprises a Swiss anchor 7 formed by a main face (visible in Fig. 1) in projection. The Swiss anchor 7 is mainly formed by a rod 9 connecting the fork 11 and the arms 13. The fork 11 comprises two horns 15 opposite each other which is mounted on a stinger 17 in order to cooperate respectively with a pin fixed on said plate 5 of the balance shaft and the lower part of said plate 5.

The rod 9 receives, between the two arms 13, a rod 19 for mounting in rotation the anchor between a bridge and the plate of the movement. Finally, on each arm 13 is fitted a pallet 21 intended to come into contact with the escape wheel 23 via its teeth 25. The pallets may, for example, be formed of synthetic ruby. Of course, the present invention may also be used for the type coaxial escapement as in watchmaking.

Preferably according to the invention, at least a part of the exhaust system 1, that is to say the plate 5 or the anchor 7 or the escape wheel 23 is made of a material at least partially amorphous comprising at least one metallic element. This metal element may be valuable such as gold, platinum, palladium, rhenium, ruthenium, rhodium, silver, iridium or osmium. It will be understood by at least partially amorphous material that the material is capable of solidifying at least partially in the amorphous phase.

Of course, it will be understood that, in a particular embodiment, all parts of the exhaust system 1 are made of at least partially amorphous material comprising at least one metal element. Nevertheless, these parts can be made of different amorphous materials.

The advantage of amorphous metal alloys comes from the fact that, during their manufacture, the atoms of these amorphous materials do not arrange according to a particular structure as is the case for crystalline materials. Thus, even if the Young E moduli of a crystalline metal and an amorphous metal are substantially identical, their elastic limits σe are different. An amorphous metal is then differentiated by an elastic limit σeAplus higher than that σeC of the crystalline metal by a factor substantially equal to two. A higher elastic limit therefore means that a piece of amorphous metal alloy or amorphous metal deforms plastically under a higher stress than the same piece of crystalline metal.

However, the losses of an exhaust system 1 are related to the friction between the pallets 21 of the anchor 7 and the teeth 25 of the escape wheel 23 during the training phase and shocks between the teeth 25 of the escape wheel 23 and the pallets 21 of the anchor 7 during the fall phase.

Losses related to shocks between the teeth 25 of the escape wheel 23 and the pallets 21 of the anchor 7 during the fall phase are a function of the kinetic energy. This kinetic energy, accumulated during the operation of the exhaust system 1, is dependent on the moment of inertia. This moment of inertia is a function of the mass and the radius of inertia. In the case of an escape wheel, the greater it will have a large diameter or the greater the mass of the wheel 23 will be significant and the moment of inertia of said wheel 23 will be high. This increase in the moment of inertia results in an increase in the kinetic energy of said escape wheel 23. Consequently, during shocks between the teeth 25 of the escape wheel 23 and the pallets 21 of the anchor 7, during the fall phase, the accumulated kinetic energy is dissipated without being transmitted. Thus, to reduce these losses, a decrease in the kinetic energy of the wheel 23 is a solution. As a result, a decrease in the mass or diameter of said escape wheel 23 results in a reduction of the moment of inertia and thus of the kinetic energy of said escape wheel 23.

An important characteristic of the material used for the manufacture of such parts is to maximize the specific resistance which is defined by the ratio of the elastic limit on the density. For crystalline alloys, the maximum specific resistance is of the order of 200-250 MPa * cm <3> / g. On the other hand, the specific resistance of the amorphous alloys is of the order of 300-400 MPa * cm <3> / g.

It is thus possible, for a given piece geometry and mechanical strength required, to use an amorphous alloy having a density significantly lower than that of the crystalline alloy satisfying the same criterion. As a result, the moment of inertia of the system will be decreased and its operation improved.

Another solution is to reduce the mass of the workpiece by removing the material, preferably in the areas contributing the most to the moment of inertia, that is to say in the parts furthest from the axis rotation of the piece. It is possible, for example, to make recesses 29, crossing or not, and / or to locally reduce the thickness 27 of the part. To compensate for this decrease in material, an amorphous alloy having a mechanical strength greater than the crystalline alloy will be chosen. Given the advantageous specific resistance of the amorphous alloys, the density of the amorphous alloy may be chosen to be equal to or slightly less than that of the crystalline alloy and consequently the moment of inertia of the system 1 will be decreased.

A third possibility is to reduce the dimensions of the elements of the exhaust system 1 as the anchor 7 or the wheel 23 or the plate 5. By choosing an amorphous alloy of higher strength than the crystalline alloy used for current dimensions, this decrease in size and mass does not lead to a decrease in the mechanical strength of the exhaust system 1. However, the specific strength of the amorphous alloys being greater in comparison with the crystalline alloys, the density of the The amorphous alloy selected may be equal to or less than that of the crystalline alloy used for the standard part, and consequently the moment of inertia and the size of the system 1 may be reduced.

Preferably, it will be chosen to reduce the mass of the parts of the exhaust system 1 which are metal or amorphous metal alloy. This makes it possible to keep the same size as an exhaust system 1 made of crystalline material and thus to keep standard dimensions while having a better resistance to stresses.

To achieve such an amorphous metal exhaust system it is advantageous to use the properties of the amorphous metal to shape it. Indeed, the amorphous metal allows great ease in shaping allowing the development of complicated shapes with greater precision. This is due to the particular characteristics of the amorphous metal which can soften while remaining amorphous for a certain time in a given temperature range [Tg - Tx] specific to each alloy (for example for a Zr41.24Ti13.75Cu12.5Ni10Be22 alloy. 5, Tg = 350 ° C and Tx = 460 ° C). It is thus possible to shape them under a relatively low stress and at a low temperature then allowing the use of a simplified process such as hot forming. The use of such a material also makes it possible to reproduce fine geometries very precisely because the viscosity of the alloy decreases sharply as a function of the temperature in the temperature range [Tg-Tx] and the alloy thus allies the details of the negative. For example, for a platinum-based material, the shaping is done around 300 ° C for a viscosity up to 10 <3> Pa.s for a stress of 1MPa, instead of a viscosity of 10 <12 > Pa.s at temperature Tg. The use of matrices has the advantage of creating parts in three dimensions of high precision, which cutting or stamping do not make it possible to obtain.

One method used is the hot forming of an amorphous preform. This preform is obtained by melting the metal elements intended to constitute the amorphous alloy in a furnace. Once these elements are melted, they are cast as a semi-finished product, then cooled rapidly to maintain the at least partially amorphous state. Once the preform is made, the hot forming is performed in order to obtain a final piece. This hot forming is performed by pressing in a temperature range between its glass transition temperature Tg and its crystallization temperature Tx for a predetermined time to maintain a totally or partially amorphous structure. This is done in order to maintain the characteristic elastic properties of the amorphous metals.

Typically for the alloy Zr41.2Ti13.8Cu12.5Ni10Be22.5 and for a temperature of 440 ° C, the pressing time should not exceed about 120 seconds. Thus, hot forming makes it possible to maintain the at least partially initial amorphous state of the preform. The different stages of definitive formatting of an element of the exhaust system are then: <tb> a) <sep> Heating the dies having the negative form of the element of the exhaust system 1 to a chosen temperature <tb> b) <sep> Introduction of the amorphous metal preform between the hot matrices, <tb> c) <sep> Application of a closing force on the matrices in order to replicate the geometry of the latter on the amorphous metal preform, <tb> d) <sep> Waiting for a chosen maximum time, <tb> e) <sep> Opening the matrices, <tb> f) <sep> Rapid cooling of the exhaust system element below Tg so that the material keeps its at least partially amorphous state, and <tb> g) <sep> Exit of the exhaust system element 1 of the matrices.

These characteristics of ease of formatting, accuracy of the part obtained and very good reproducibility are very useful for the realization of variable thicknesses and recesses. This ease of formatting also makes it possible to produce complex parts easily, such as, for example, the plate 5 of the exhaust system 1 with its pin.

In addition, the ability to easily shape complex parts makes it possible to perform complicated designs. However, this can be interesting for shaping the teeth of the escape wheel and the shaping of the anchor so as to improve the cooperation between the escape wheel and the anchor.

It will be understood that various modifications and / or improvements and / or combinations obvious to those skilled in the art can be made to the various embodiments of the invention described above without departing from the scope of the invention defined by the appended claims.

Of course, it will be understood that the elements of the exhaust system can be made by casting or injection. This process involves casting the alloy obtained by melting the metal elements in a mold having the shape of the final piece. Once the mold is filled, it is rapidly cooled to a temperature below Tg in order to avoid crystallization of the alloy and thus obtain a system 1 of amorphous or partially amorphous metal.

Of course, one can also imagine that the pallets 21 of the anchor 7 are made of metal or amorphous alloy. These pallets 21 can form one and the same piece with said anchor or be overmolded after manufacture of the anchor 7. It then becomes possible that the pallets 21 and the anchor 7 are made of metal or amorphous alloy but different from each other. one of the other.

Claims (12)

An escapement system comprising an anchor (7) provided with a fork (11) intended to cooperate with an anchor mounted on a plate (5), and a rod (9) comprising arms (13) intended to receiving pallets (21) to cooperate with at least one escape wheel (23), characterized in that at least a part of the exhaust system is made of at least partially amorphous material and comprising at least one element metallic. 2. Exhaust system according to claim 1, characterized in that the anchor (7) is made of an at least partially amorphous material and comprising at least one metal element. 3. Exhaust system according to claims 1 or 2, characterized in that the pallets (21) of the anchor (7) are made of an at least partially amorphous material and comprising at least one metal element. 4. Exhaust system according to claims 1 or 2 or 3, characterized in that the pallets (21) of the anchor and the anchor (7) form a single piece. 5. Exhaust system according to one of the preceding claims, characterized in that the escape wheel (23) is made of an at least partially amorphous material and comprising at least one metal element. 6. Exhaust system according to one of the preceding claims, characterized in that the plate (5) is made of an at least partially amorphous material and comprising at least one metal element. 7. Exhaust system according to one of the preceding claims, characterized in that at least a portion of the exhaust system comprises recesses (29) to reduce the moment of inertia of this part. 8. Exhaust system according to claim 7, characterized in that the recesses are through. 9. Exhaust system according to one of the preceding claims, characterized in that at least a portion of the exhaust system comprises thinned areas (27) to reduce the moment of inertia of this part. 10. Exhaust system according to one of the preceding claims, characterized in that said anchor (7), said escape wheel (23) and said plate (5) are made of an at least partially amorphous material and comprising at least less a metal element. 11. Exhaust system according to one of the preceding claims, characterized in that the material is totally amorphous. 12. Exhaust system according to one of the preceding claims, characterized in that the material is completely metallic.