CH705465B1 - The process of formation of a sprung balance assembly of watches and oscillation frequency adjustment. - Google Patents

Abstract

The invention relates to a method for constituting a pendulum balance-balance and oscillation frequency adjustment assembly comprising the following steps: - pilot means of production to be able, according to normal laws of average and predetermined maximum standard deviation, to perform the machining of: - spirals capable of a given oscillation frequency (NO) for a predetermined pendulum inertia (J0), each finished, cut for its pitonnage and ready to 'assembly; - And rockers capable of said frequency (NO) for a pair of spiral (C0) predetermined; The average and standard deviation manufacturing parameters of the pendulums are determined so as to have, between the Gaussian distributions of the theoretical frequency values, on the one hand balancers, and on the other hand spirals, a difference corresponding to a possible reduction of inertia of each pendulum; Randomly taking any finite spiral (Sx) and any balance (By); A balancing adjustment machining operation is performed for said balance (By) taken to bring it within a given balancing tolerance, and a complementary inertia adjustment machining as a function of the torque of said hairspring (Sx) taken, so as to constitute a sprung-balance assembly capable of oscillating at said oscillation frequency (N0) after said inertia adjustment operation.

Description

Field of the invention

The invention relates to a method of constituting a pendulum balance-spiral clock and adjusting oscillation frequency.

The invention relates to the field of the manufacture of timepiece components, and in particular the manufacture of sets, and the operation of their adjustment frequency adjustment.

Background of the invention

Traditionally, the pendulums and spiral are manufactured, then sorted into a large number of classes. To constitute a balance-spiral assembly capable of oscillating in the vicinity of a certain frequency of oscillation, it is then necessary to take a balance and a spiral each in a class capable of approaching this frequency, then to adjust the pair thus formed to actually obtain the desired frequency, adjusting the length of the hairspring, and / or changing the inertia of the balance.

Therefore, a large work in progress is needed to meet the demand. And, despite this work in progress, operations are still necessary on the balance spring and balance, which are not ready for use.

Frequency adjustment accuracy naturally depends on the magnitude of each class of spirals and pendulums, which explains their high number.

Summary of the invention

The invention proposes to eliminate these extremely expensive work in progress, and to implement a new process that allows to manufacture, extremely quickly and economically, balanced balance-balance assemblies correctly adjusted to a frequency given oscillation.

The invention proposes, still, to treat at the same time the problem of balancing necessary for the pendulums.

For this purpose, the invention relates to a method of constituting a pendulum-balance spring and oscillation frequency adjustment assembly, whereby: <tb> - <SEP> pilot means of production to be able, according to normal laws of average and predetermined maximum standard deviation, to perform the machining of: <tb> <SEP> - <SEP> spirals capable of a given oscillation frequency for a predetermined balance inertia, each finished, cut for its pitonnage and ready for assembly; <tb> <SEP> - <SEP> and rockers capable of said frequency for a predetermined pair of hairsprings; <tb> - <SEP> one determines the parameters of manufacture of average and standard deviation of the rockers, to have, between the Gaussian distributions of the theoretical values of frequencies, on the one hand of the rockers, and on the other hand of the spirals, a gap corresponding to a possible decrease of inertia of each pendulum; <tb> - <SEP> we take at random any finite spiral and any pendulum; <tb> - <SEP> balancing adjustment machining of said picked-up rocker is carried out to bring it within a given balancing tolerance, and additional machining of inertia adjustment as a function of the torque of said hairspring taken, so as to constitute a sprung-balance assembly capable of oscillating at said oscillation frequency after said inertia adjustment operation.

According to a particular embodiment of the invention, a population of spirals capable of a given oscillation frequency is produced as a function of a reference balance inertia, according to a normal law of predetermined average and of standard deviation limited to a predetermined value, said spirals of said population being each finite, of predetermined length for its pitonnage and ready to be assembled with a balance to form a balance sprung-balance.

Detailed Description of the Preferred Embodiments

The invention relates to a method of constituting a pendulum balance-spiral clock and oscillation frequency adjustment.

According to this method, the following operations are carried out: <tb> - <SEP> means of production are piloted in terms of normal laws of predetermined mean and maximum standard deviation, for the machining of spirals capable of a given oscillation frequency N0 for an inertia of predetermined balance J0, each of these spirals being finished, cut for pitonnage and ready for assembly, and for machining balances capable of this same frequency N0 for a predetermined pair of spiral C0; <tb> - <SEP> one determines the parameters of manufacture, to have, between the Gaussian distributions of the theoretical values of the frequency of the pendulums and the spirals a difference corresponding to a possible decrease of inertia of each pendulum, <tb> - <SEP> randomly picks up any hairspring and pendulum <tb> - <SEP> balancing adjustment machining of the picked-up beam is carried out to bring it into a given balancing tolerance if necessary, and complementary machining of inertia adjustment, depending on the torque, measured before or at the latest during this operation, the hairspring taken, <tb> <SEP> so as to constitute a sprung-balance assembly capable of oscillating at the oscillation frequency N0 after said inertia adjustment operation.

More particularly, this method is such that: <tb> - <SEP> is produced in a production process driven by capability control means means of production according to a normal law of predetermined average ms and standard deviation as limited to a predetermined value, a population of spirals capable of a given oscillation frequency N0 as a function of a reference rocker inertia J0, these spirals being each finite, of predetermined length for its pitonnage and ready to be assembled with a balance to constitute a pendulum assembly; spiral, <tb> - <SEP> is produced, in a production process driven by capability control means production means according to a normal law of predetermined mb average and standard deviation σb limited to a predetermined value, and in a given unbalance tolerance, a population of balances capable of this given oscillation frequency N0 as a function of a reference spiral torque C0; <tb> - <SEP> the manufacturing parameters, according to these normal laws, of the pendulums and the spirals are determined in order to qualify the average mb of the population of pendulums, according to the average ms of the spiral population, such way it remains, between: <tb> - <SEP> on the one hand the Gaussian distribution of the theoretical frequency values for each pendulum as a function of the reference spiral torque C0, <tb> - <SEP> and on the other hand the Gaussian distribution of the theoretical frequency values for each hairspring as a function of the reference inertia J0, a difference corresponding to a possible inertia decrease of each pendulum; <tb> and, to constitute such a balance-spiral assembly and proceed to its adjustment in oscillation frequency: <tb> - <SEP> is taken at random from the spiral population any spiral Sx and is taken at random from among the population of pendulums any balance By, <tb> - <SEP> then performs an inertia adjustment operation consisting of performing, simultaneously or successively: <tb> - <SEP> a balancing adjustment machining of the balance taken By to bring it within a given balancing tolerance if the unbalance of this balance taken By is greater than the given balancing tolerance, and <tb> - <SEP> a complementary machining of adjustment of the inertia of this pendulum By, as a function of the torque, measured beforehand, of this hairspring Sx, so as to constitute a Sx-By balance-hairspring assembly capable to oscillate at the oscillation frequency N0 after this inertia adjustment operation.

Preferably, when determining the manufacturing parameters, according to these normal laws, rockers and spirals, to qualify the average mb of the population of rockers, depending on the average ms of the spiral population. it is done in such a way that it remains, between: <tb> - <SEP> on the one hand the Gaussian distribution of the theoretical frequency values for each pendulum as a function of the reference spiral torque C0, <tb> - <SEP> and on the other hand the Gaussian distribution of the theoretical frequency values for each hairspring as a function of the inertia of reference beam J0, a difference corresponding to a possible decrease of inertia of each said balance, <tb> and this possible reduction of inertia is limited to the maximum value of the unbalance tolerance.

In an alternative embodiment, a machining is carried out by removal of material on the balance taken By for a first inertia setting without balancing, then after a measurement of the balance of this By balance and a calculation of definition of machining, balancing and second inertia machining to a value calculated so that the Sx-By spiral balance assembly oscillates at the oscillation frequency N0.

In a particular embodiment, in particular to highlight a possible infringement, it performs a machining by removal of material on the pendulum By reserving some first surfaces of the pendulum By this machining first inertia setting, and by reserving certain second surfaces of this By balance for the balancing and second inertia setting machining.

We can then determine these first surfaces as distinct from these second surfaces of the By balance.

It is possible to impose the position of the different surfaces, and it is possible in particular to define the first surfaces and the second surfaces of the beam By at least prohibiting any machining in certain third zones of the beam By, reserved for the reception of weights balancing or reported components.

In particular, in a variant, the first surfaces and the second surfaces of the By balance are defined at least by prohibiting any machining on the arms of the By balance.

In a particular embodiment, the balancing machining is carried out symmetrically with respect to a plane passing through the axis of pivoting of the balance beam By, and in the vicinity of this plane.

In a particular variant, at least the machining of first inertia setting is carried out symmetrically with respect to the pivot axis of the By balance.

In an advantageous variant, the volume of material to be removed in each machining zone is calculated, and the flow of material is distributed over a sufficient area to respect predefined minimum sections in the different zones of the By beam, so that to prevent any problem of fatigue resistance.

In particular, the volume of material to be removed in each machining zone is calculated so as not to exceed a certain predefined mass flow rate with respect to the total weight of the By balance, and the material flow is distributed at level of surfaces sufficiently far from the axis of pivoting of the balance By to reach the value of inertia calculated for the balance By.

Preferably, after final adjustment of the inertia of the pendulum By to constitute a Sx-By balance-hairspring assembly of the desired oscillation frequency N0, as a function of the measured torque of the spiral Sx, the reference is taken to the reference point. one on the other this spiral Sx on this pendulum By.

The invention can drastically reduce work in progress. It makes it possible to dispose almost instantaneously of a balance-spiral set tuned to a particular frequency, with a great reliability and a great precision.

Claims (16)

1. Method for constituting a pendulum-balance spring and oscillation frequency adjustment assembly, characterized in that: <tb> - <SEP> pilot means of production to be able, according to normal laws of average and predetermined maximum standard deviation, to perform the machining of: <tb> <SEP> - <SEP> spirals capable of a given oscillation frequency (N0) for a predetermined pendulum inertia (J0), each finished, cut for its pitonnage and ready for assembly; <tb> <SEP> - <SEP> and rockers capable of said frequency (N0) for a predetermined spiral torque (C0); <tb> - <SEP> one determines the parameters of manufacture of average and standard deviation of the rockers, to have, between the Gaussian distributions of the theoretical values of frequencies, on the one hand of the rockers, and on the other hand of the spirals, a gap corresponding to a possible decrease of inertia of each pendulum; <Tb> <September> <tb> - <SEP> random draws any finite spiral (Sx) and any balance (By); <tb> - <SEP> balancing adjustment machining of said balance (By) taken to bring it into a given balancing tolerance, and complementary machining of inertia adjustment according to the torque of said balancing spiral (Sx) taken, <tb> <SEP> so as to constitute a sprung-balance assembly capable of oscillating at said oscillation frequency (N0) after said inertia adjustment operation. 2. Method according to claim 1, characterized in that: A population of spirals capable of a given oscillation frequency (N0) is produced as a function of a reference inertia of balance (J0), according to a normal law of mean (ms) predetermined and of standard deviation ( σs) limited to a predetermined value, said spirals of said population being each finite, of predetermined length for its pitonnage and ready to be assembled with a pendulum to form a balance sprung-balance. 3. Method according to claim 2, characterized in that: A population of balances capable of said given oscillation frequency (N0) is produced as a function of a reference spiral torque (C0), according to a normal law of predetermined mean (mb) and of standard deviation (σb) ) limited to a predetermined value. 4. Method according to claim 3, characterized in that: <tb> - <SEP> is said average (mb) of said population of rockers, according to said average (ms) of said spiral population, such that there remains, a difference corresponding to said decrease of possible inertia of each said pendulum between: <tb> <SEP> - <SEP> on the one hand the Gaussian distribution of the theoretical frequency values for each pendulum as a function of said reference spiral torque (C0), <tb> <SEP> - <SEP> and on the other hand the Gaussian distribution of the theoretical frequency values for each spiral as a function of said reference balance inertia (J0). 5. Method according to claim 4, characterized in that, to constitute a said sprung-balance assembly and proceed to its adjustment in oscillation frequency, when performing said balancing adjustment machining said balance (By) taken to bring it into a given balancing tolerance if necessary, and said complementary inertia adjustment machining, an inertia adjustment operation is performed consisting of performing, simultaneously or successively: A balancing adjustment machining operation of said picked up beam (By) to bring it into a given balancing tolerance if the unbalance of said picked up beam (By) is greater than said given balancing tolerance, and A complementary machining of adjustment of the inertia of said balance (By), as a function of the torque, measured beforehand, of said hairspring taken (Sx), so as to constitute a so-called spring-balance assembly (Sx-By) capable of oscillating at said oscillation frequency (N0) after said inertia adjustment operation. 6. Method according to claim 5, characterized in that, when determining the manufacturing parameters, according to said normal laws, said balances on the one hand and said spirals on the other hand, it limits said possible decrease of inertia to the maximum value of said balancing tolerance. 7. Method according to claim 5 or 6, characterized in that a machining by removal of material on said balance (By) for a first inertia setting without balancing, then, after a measurement of the imbalance of said balance (By and a machining definition calculation, balancing and second inertia machining to a value calculated for said sprung balance assembly (Sx-By) to oscillate at said oscillation frequency (N0). 8. A method according to claim 7, characterized in that a machining by removal of material on said balance (By) by reserving some first surfaces of said balance (By) to machining first implementation of inertia, and reserving certain second surfaces of said balance (By) to said balancing machining and second inertia setting. 9. The method of claim 8, characterized in that said first surfaces are determined as distinct from said second surfaces of said beam (By). 10. Method according to claim 8 or 9, characterized in that said first surfaces and said second surfaces of said balance (By) are defined at least by prohibiting any machining in certain third zones of said balance (By) reserved for the reception of weights balancing or reported components. 11. The method of claim 8 or 9, characterized in that said first surfaces and said second surfaces of said beam (By) are defined at least by prohibiting any machining on the arms of said beam (By). 12. Method according to one of claims 7 to 11, characterized in that said balancing machining is performed symmetrically with respect to a plane passing through the pivot axis of said balance (By) and in the vicinity of said plane. . 13. Method according to one of claims 7 to 11, characterized in that performs at least said machining first inertia setting symmetrically with respect to the pivot axis of said beam (By). 14. Method according to one of claims 7 to 13, characterized in that calculates the volume of material to be removed in each machining area of said beam (By), and that the flow of material is distributed on a surface sufficient to respect predefined minimum sections in the different zones of said balance (By). 15. Method according to one of claims 7 to 14, characterized in that calculates the volume of material to be removed in each machining area so as not to exceed a certain mass flow predefined in relation to the total mass said balance (By), and that the flow of material is distributed at sufficiently far away from the axis of pivoting of said balance (By) to reach the inertia value calculated for said balance (By). 16. Method according to one of claims 7 to 15, characterized in that, after final adjustment of the inertia of said balance (By) to form a balance-spiral assembly (Sx-By) of said oscillation frequency (N0 ), as a function of the measured torque of said hairspring (Sx), the hairspring (Sx) on said pendulum (By) is displaced from one another.