CH708885B1 - Method of dimensioning and tuning one or more timbres for a timepiece and stamp (s) sized and tuned by this method. - Google Patents

Abstract

The invention relates to a method of dimensioning and tuning of one or more timbres able to equip a timepiece comprising a striking mechanism, the stamp or stamps each comprising a vibrating member (2a, 2b) coming from a piece with or embedded by one of its ends in a heel (1a, 1b). The method comprises the following steps: choosing a material for the vibrating member (s) according to the materials used for the box and / or the movement of the timepiece; determining a length L for the vibrating member (2a, 2b) of the stamp or stamps as a function of the space available between the timepiece box and its movement, this length L being substantially the same for all the vibrating members (2a, 2b); determine the radial thickness e of the vibrating member (2a, 2b) of each patch according to the note that must produce the vibration of the vibrating member (2a, 2b) of this stamp. The invention also relates to a set of timbres for a timepiece whose vibrating members are all made of the same material and having the same length L. The timbres of the set are differentiated from one another by the radial thickness e of their vibrating member (2a, 2b), and the frequencies of the partials of each patch are directly proportional to the radial thickness e of their vibrating member (2a, 2b).

Description

Description: [0001] The present invention relates to stamps for ringing timepieces. Generally, these stamps are constituted by a vibrating member made in one piece with or embedded in a heel by one of these ends. The heel is intended to be fixed on a watch movement, a box of a timepiece or on the ice of a timepiece. The vibrating member is generally made by a wire of circular, oval or polygonal section and extends between the timepiece box and its movement. The shape seen in plan of this vibrating organ is dictated by the space available between the movement and the timepiece box and its length determines the note or height of the sound produced by the vibration of this vibrating body.

In a timepiece comprising several timbres delivering sounds of different heights, the first stamp delivering the lowest sound is also the longest. The other or more acute timbres are shorter: the higher the sound must be acute the vibrating organ of the timbre considered must be short.

This has a disadvantage, because we know that to deliver a significant volume and good sound quality, a stamp must be as long and massive as possible. Thus, in existing timepieces having multiple timbres, only the tone delivering the lowest sound can be optimized, in terms of length and the mass of its vibrating member, to deliver a loud sound and quality. The other timbres, whose vibrating organ is shorter because they deliver more acute sounds, can not be optimized to obtain the best volume and the best quality of sounds delivered.

[0004] An additional drawback arises from the fact that the frequency differences between the partials of the same order of the spectrum produced by the vibration of two vibrating members of different lengths are not constant, so that it is never possible to achieve a perfect match between two timbres with vibrating members of different lengths.

The present invention aims to allow the realization of timbres for timepiece more efficient, delivering a wide and better sound and can be tuned between them in an improved manner.

The present invention relates to a method of dimensioning and tuning of one or more stamps for a timepiece, which process is distinguished by the features set forth in claim 1.

The present invention also relates to a stamp or a set of timbres for a timepiece sized and tuned by means of the method according to claim 1 and having the features set forth in claim 3.

Finally, the present invention also relates to a timepiece comprising a stamp or a set of stamps according to claim 5 or claim 6.

The accompanying drawing illustrates schematically and by way of example different embodiments of one or more stamps according to the invention.

Fig. 1 illustrates in plan a stamp according to the invention.

Fig. 2 illustrates a section along the line A-A of FIG. 1.

Fig. 3 illustrates in perspective a set of two stamps according to the invention.

Fig. 4 illustrates the set of stamps illustrated in FIG. 3 seen in plan.

Fig. 5 is a section along the line B-B of FIG. 4.

Fig. 6 illustrates on a larger scale the detail C of FIG. 5.

Fig. 7 is a graph showing the frequency spectrum of the stamps of the set of stamps illustrated in FIGS. 3 to 6.

If we consider a timepiece complication sound, it includes a watch case containing a clockwork comprising a striking mechanism. Between this watch case and the movement, this timepiece comprises a peripheral space able to receive one or more stamps. These stamps have a heel for attaching them rigidly on the watch case or movement and a vibrating member extending in said peripheral space.

The method of sizing and tuning one or more stamps comprises the following steps: - the choice of the material constituting in particular the vibrating member is made according to the acoustic qualities of said material and materials used for the box of shows; - The shape and dimensions of the vibrating member in plan view in particular, generally its length and its winding diameter, are determined according to the peripheral space of the timepiece receiving the stamp or stamps; the frequency of the audible first partial and the audible partial of the following order is determined, according to the desired note, by adjusting the radial thickness of the vibrating member.

According to this method it is no longer the length of the vibrating or vibrating organs or timbres that determines the frequency of sound, or note, emitted by the vibrating member but its radial thickness e. It follows that when placing a set of stamps in a timepiece, all the stamps may have a vibrating member of the same length L or a substantially equal length L. This makes it possible to give a maximum of volume and power to all the timbres and not only to the timbres emitting the most serious sound.

In addition, since the frequencies of the eigen modes of each timbre are directly proportional to the thickness e of the vibrating member of the timbre considered, the difference between the audible partials is constant which allows to achieve a perfect agreement between the different stamps of a set intended for the same timepiece. Indeed, the difference between audible partials of the same order between a thick stamp e is the same as between the audible partial of a thin stamp e. This difference therefore always represents the same number of semitones so that the note emitted remains the same and is not disturbed as is the case when tuning timbres whose vibrating members have different lengths.

The formula for calculating the bending resonance frequencies of a beam embedded at one of its ends is: where

fn represents the resonance frequency, L is the length of the beam, E is the modulus of elasticity or Young's modulus and p is the density which depend on the parameters of the selected material, λη is a coefficient depending on the boundary conditions of the beam, and e the radial thickness of the beam.

The resonance frequencies of a stamp are therefore directly and linearly proportional to the radial thickness of the vibrating member of the stamp.

It is found that the resonance frequencies of a stamp are not influenced by the height h of the section of the vibrating member of the stamp.

In practice, in a set of stamps for the same timepiece, the height h of the stamps is adjusted so that the mass of each stamp is identical which further improves the quality of the sound produced by all the stamps.

FIG. 1 illustrates a stamp comprising a heel 1 and a vibrating member 2 of circular shape with a diameter d, of rectangular section, radial thickness e and height h. The length L of the vibrating member is the largest possible given the space available between the timepiece box and its movement.

To size or tune the stamp, its material is determined according to the desired sound qualities which determines the factors E and p. The characteristic λη is determined in particular by the method of fixing the stamp and its heel on the timepiece. Then, we choose the length L of the vibrating member of the stamp according to the space available between the timepiece box and its movement.

The height of the sound or note produced by the timbre is then determined according to the desired ring and to achieve this desired note, all other parameters of the vibrating member being determined, it is the radial thickness e of the vibrating member 2 that is adjusted.

The patch is thus tuned to the desired note by changing its radial thickness e.

The height h of the vibrating member 2 of the stamp which does not interfere in the determination of the vibration frequencies of the stamp is determined, it, depending on the available space between the timepiece box and its movement to get the maximum power of the sound produced, which is influenced by the mass of the tone.

It is interesting to note that by tuning the tone by varying its radial thickness e, it does not change the way of vibrating the tone. Indeed, since the length L of the patch is not modified, the nodes defining the parts or spindles of the vibrating member for each part remain in the same places, so that the frequency differences between the partial of the same order are proportional to the radial thickness of the vibrating member.

This characteristic of the stamp is particularly important when sizing or making several timbres to be tuned together to ring a chord, as is the case for example for the two stamps illustrated in Figs. 3 to 7.

We see in these figures two timbres whose vibrating members 2b, 2a differ in their radial thickness e, eb = 0.43 mm and ea = 0.54 mm respectively, and therefore produce different notes. The purity of the produced sound chord is perfect since the frequency of the same-order partials of these timbres present deviations in constant semitones, that is to say that the frequency of each partial of the timbre whose radial thickness is weak is equal to the frequency of the partial of the same order of a timbre whose radial thickness is higher multiplied by a constant factor for each partial order as represented in FIG. 7.

To optimize the sound volume of the two tuned timbres, one chooses for each of them a height h of the vibrating member so that the mass of the two vibrating bodies of the stamps is equal or substantially equal.

In the illustrated example, if the first tone is tuned to ring a DO and that the second tone is tuned to ring an Ml by a variation of the radial thickness between the two timbres, the frequencies of the same order partial the first low tone will all be multiplied by a constant factor of 1.26 for the second acute tone whose radial thickness is greater than that of the first low tone. Thus, for each partial, we find the same difference of half-tones and the agreement or note of each stamp and the agreement of the two stamps relative to each other for the agreement of DO-MI will be perfect , which can not be achieved with timbres tuned by changing their length L, since in this case, the nodes of the two stamps are not located in the same places and the vibration spindles of the two stamps are not the same length.

With this method of sizing stamps, it is possible to produce sets of several sounding tones in perfect agreement made in the same material, having the same length but different radial thicknesses and possibly different heights.

In these sets of stamps, the height of each stamp is preferably chosen so that all the stamps of the set of stamps have a substantially identical mass.

The invention also relates to a timepiece comprising a striking mechanism whose stamp (s) have been sized according to the method described, that is to say by varying the radial thickness e of the vibrating bodies of the stamps to grant them on a given note each and grant them together on a specific agreement.

In variants, the section or vibrating members may be different for example oval, polygonal or circular. However, it is always the radial thickness of the vibrating organ that is modified to tune the tone to a selected note or to another tone to ring a determined chord.

This method of sizing and tuning makes it possible to produce homogeneous patches between them both by the length and the section and therefore their mass. This gives similar acoustic qualities between different timbres of the same timepiece.

One can thus obtain a set of stamps, two, three or more, which are all of the same material, all having the same length and having varying heights so that the mass of each stamp is preferably substantially equal. Each stamp of the set is differentiated by its radial thickness. The natural frequencies of each patch are proportional to the radial thickness of the vibrating member of said patch.

Claims (6)

claims 1. A method of dimensioning and tuning of one or more timbres adapted to equip a timepiece comprising a striking mechanism, the stamp or stamps comprising a vibrating member (2; 2a, 2b) from a piece with or embedded by one of its ends in a heel (1; 1a, 1b), the method according to which: - a material is chosen for the vibrating member (s) depending on the materials used for the box and / or the movement of the piece of watches; a length L for the vibrating member (2; 2a, 2b) of the stamp or stamps is determined as a function of the space available between the timepiece box and its movement, this length L being substantially the same for all vibrating members (2; 2a, 2b); and the radial thickness e of the vibrating member (2; 2a, 2b) of each patch is determined as a function of the note that the vibration of the vibrating member (2; 2a, 2b) of this stamp must produce. to satisfy the formula in which: fn represents the resonance frequency, L is the length of the vibrating member (2; 2a, 2b), E is the modulus of elasticity or Young's modulus and p is the density of the material selected for the vibrating member ( 2; 2a, 2b), λη is a coefficient which depends on the boundary conditions of the vibrating member (2; 2a, 2b). 2. A method of dimensioning and tuning of several stamps according to claim 1, characterized in that the height h of the vibrating member (2; 2a, 2b) of each stamp is determined so that the mass each vibrating member (2; 2a, 2b) is substantially the same. 3. Set of stamps for a timepiece comprising a striking mechanism, each stamp comprising a vibrating member (2; 2a, 2b) coming from a piece with or embedded by one of its ends in a heel (1; , 1b), the stamps being dimensioned and tuned by means of the method according to claim 1 or 2, characterized in that all the stamps forming the assembly consist of the same material and have a vibrating member (2; 2a, 2b) of the same length L; in that the vibrating members (2; 2a, 2b) of the timbres of the assembly are differentiated from each other by their radial thickness e, plus this radial thickness e is large, the more the sound produced by the timbre being acute; and in that the frequencies of the partials of each patch are directly proportional to the radial thickness e of its vibrating member (2; 2a, 2b). 4. set of stamps according to claim 3, characterized in that the height h of the vibrating member (2; 2a, 2b) of each stamp is such that the mass of each vibrating member is substantially the same. 5. Timepiece comprising at least one stamp dimensioned and tuned by means of the method according to claim 1. 6. Timepiece comprising a set of stamps according to claim 3 or 4.