CH717564A1 - Watchmaker spring for barrel and process for manufacturing such a spring. - Google Patents

Abstract

The invention relates to a watchmaking spring (R) for a barrel, comprising an inner end which does not undergo deformation during the strapping and/or the unwinding of the said spring, an outer end which undergoes during the said strapping and/or the said unwinding the maximum deformation, turns (30', 30'', 30''') between the first end and the second end arranged to wind up and/or unwind in the strapping plane, said turns having a height (h , h', h'', h''') substantially perpendicular to said plane in which said height (h, h', h'', h''') varies between the inner end and the outer end. The variation in height (h, h', h'', h''') makes it possible to obtain a more regular driving force for the barrel. The invention also relates to a method of manufacturing such a spring.

Description

Technical area

The present invention relates to a watch spring for barrel and a method of manufacturing such a spring. It also relates to a barrel comprising such a spring.

State of the art

[0002] The barrel of a mechanical watch is an energy accumulator. As a general rule, it comprises a barrel drum, that is to say a cylindrical box closed by a barrel cover and a barrel spring, housed in this box.

[0003] The known barrel spring is a blade with a generally rectangular section. Before being housed in the drum, it usually has an upturned "S" shape, as shown in Figure 1A. During its assembly in the drum T, the barrel spring R is deformed since it is wound around the barrel arbor A which is at the center of the drum T, as illustrated in FIG. 1B. This process is called strapping. The free space between the barrel arbor A and the inner radius of the drum T is reserved for winding and unwinding the barrel spring R. The unwinding of the blade of the barrel spring R which seeks to resume its initial shape restores the energy needed to operate a mechanical watch. The teeth of the barrel drum T transmit the torque to the train of the watch. Once disarmed, the barrel spring R is relaxed against the walls of the drum T, as shown in Figure 1C. The reference N' indicates the number of turns of the barrel spring R wound around the barrel arbor A (figure 1B) and the reference N" the number of turns of the barrel spring R disarmed and therefore relaxed against the walls of the barrel drum T (Figure 1C).

By comparing Figures 1A to 1C, we see that the barrel spring R has a point or area 10 which does not undergo deformation during strapping. This point corresponds to one of its two ends, in particular the so-called inner end (when the spring is wound in its barrel), illustrated for example in FIG. 1A. The barrel spring R also has a point or zone 20 which undergoes during strapping the maximum deformation among the deformations undergone by all the points or zones of the barrel spring R. This point corresponds to the other end of the spring R, in particular the so-called outer end (when the spring is wound in its barrel), also illustrated for example in FIG. 1A. The intensity of this maximum deformation depends, among other things, on the number of winding turns of the barrel spring R, that is to say the number of turns of the barrel spring during strapping. This number in fact defines the state of the tension of the mainspring R and therefore the torque available, generally measured in N mm.

[0005] A problem with traditional barrel springs is linked to the difference in torque provided when the barrel spring is completely stretched or practically unwound. The torque provided by a known barrel spring in fact depends on the position of the barrel spring in the barrel drum. There is a torque zone corresponding to a small angular range, in which the watch operates with optimum precision. Indeed in this zone the torque is constant and adapted to the needs of the train, which corresponds to an optimal precision of the watch. Mechanical watches equipped with a torque meter measuring the torque of the barrel spring and making it possible to visualize this torque zone in which the watch operates with optimum precision are known.

[0006] To obtain a more constant torque regardless of the position of the barrel spring or the level of winding, known solutions employ a fusee-chain energy transmission device developed by Leonardo da Vinci: the difference in diameter between the base and top of a conical rocket, around which is wound a chain connected to the mainspring, functions as a differential compensating for differences in torque as the mainspring relaxes. This device therefore maintains a substantially constant torque throughout the period covered by the reserve of the watch. However, this mechanism is complex and it is not easy to manufacture it in dimensions suitable for a wristwatch. Furthermore, it requires precautions to be taken, for example a device which blocks the winding procedure and thus prevents the chain from breaking.

[0007] Other known solutions for trying to make the torque provided by a barrel spring more constant regardless of the position of the barrel spring or the level of winding, provide for a locking system of the barrel spring, which avoids exploiting its first and last rounds. This provides a much more constant energy torque but nevertheless reduces the autonomy of the wristwatch.

[0008] The document CH375275 describes a barrel spring whose force gradually decreases going from the inner end to the outer end in order to obtain a more regular driving force of the barrel and, consequently, an almost constant amplitude of the pendulum. To do this, the thickness of the mainspring, i.e. the dimension of the mainspring parallel to the plane in which this spring rolls and/or unrolls (hereinafter referred to as the "strapadage plane") and perpendicular to the length of its whorls, gradually decreases from the inner end to the outer end.

[0009] The document FR1583064 describes a rolling mill making it possible to produce the spring described in the document CH375275.

[0010] The document EP0649075 also describes a mainspring whose thickness decreases as a function of the winding angle of the spring, by specifying in particular the law of this reduction.

[0011] The document EP2520821 describes a barrel spring which makes it possible to obtain a constant torque throughout its expansion by producing energy storage curvatures in certain portions of certain turns. The thickness of these curvatures may be different from that of the portions of turns devoid of such curvatures. This spring is complicated to make.

[0012] The document CN102768491 describes a barrel spring comprising additional means for accumulating elastic energy in the form of several tongues or cilia in the plane of the spring, which extend from the turns and form an angle with the latter. . This spring is also complicated to make.

[0013] There is therefore a need for a watch spring for a barrel, which makes it possible to avoid at least one of the limitations of the state of the art mentioned.

[0014] There is also a need for a watch spring for a barrel, which is easy to manufacture, while making it possible to make the torque provided by the barrel spring more constant regardless of the position of the barrel spring or the level of winding.

[0015] There is also a need for a watchmaker's spring for a barrel, which makes it possible not to reduce or to reduce less than the known solutions the autonomy of the timepiece, for example a wristwatch, to which it belongs, while also making it possible to make the torque provided by the barrel spring more constant regardless of the position of the barrel spring or the level of winding.

[0016] There is also a need for a watch spring for a barrel, an alternative to the watch springs for a barrel of the state of the art.

Brief summary of the invention

[0017] An object of the present invention is to provide a watch spring for a barrel that is free from the limitations of known barrel springs.

Another object of the present invention is to provide a watch spring for a barrel which is easy to manufacture, while making it possible to make the torque supplied by the barrel spring more constant whatever the position of the barrel spring or the level of reassembly.

Another object of the present invention is to provide a watch spring for a barrel which makes it possible not to reduce or to reduce less than the known solutions the autonomy of the timepiece, for example a wristwatch, to which it belongs, while also making it possible to make the torque supplied by the barrel spring more constant whatever the position of the barrel spring or the level of winding.

[0020] Another object of the present invention is to provide a clock spring for a barrel, an alternative to the clock springs for a barrel of the state of the art.

[0021] According to the invention, these objects are achieved in particular by means of the watch spring for the barrel according to claim 1 and by means of the method of manufacturing this watch spring according to claim 10, preferential embodiments being given in the claims dependent.

[0022] The watch spring according to the invention comprises an inner end which does not undergo any deformation during the strapping and/or the unwinding of the spring, an outer end which undergoes during the strapping and/or during the unwinding of the maximum deformation, and turns between the first end and the second end arranged to wind and/or unwind in the strapping plane xy, these turns having a height substantially perpendicular to this plane.

According to the invention, the height of the turns varies between the inner end and the outer end. This variation makes it possible to obtain a more regular driving force of the barrel and, consequently, an almost constant amplitude of the balance wheel of the movement to which the spring of the invention belongs.

In a preferred embodiment, the height of the turns decreases from the inner end to the outer end. In this way, the force gradually decreases going from the inner end to the outer end in order to obtain a more regular driving force of the barrel.

[0025] In one embodiment, the variable height is combined with the variable thickness, in particular with a thickness of the turns which decreases from the inner end to the outer end. This makes it possible to obtain a driving force for the barrel that is more regular than the known solutions, in which only the thickness was variable.

[0026] In a variant, at least a part of the turns comprises holes, in which the density of the holes decreases from the inner end to the outer end.

[0027] In a variant, at least part of the turns comprises a core and an envelope, the core being hollow, the core having a height which varies between the inner end and the outer end. Alternatively, the height of the core decreases from the inner end to the outer end.

[0028] Alternatively, the watch spring is made of a material in which the rigidity of this material decreases from the inner end to the outer end.

In a variant, this material comprises impurities arranged so that the rigidity of this material decreases from the inner end to the outer end.

[0030] In a variant, the watch spring is made of two or more materials, in which the rigidity of the material of the inner end is greater than that of the material of the outer end.

The present invention also relates to a method of manufacturing the watch spring according to the invention, comprising the steps of: at least partially superimposing sheet-shaped elements, so as to obtain a piece of variable height; fix the elements together, so as to obtain a one-piece piece; cut the part, so as to obtain a blade with variable height; wind the blade, so as to obtain the watch spring.

[0032] In a variant, the manufacturing process comprises the step of: producing these elements, the part and/or the watch spring by additive or subtractive manufacturing, so that the thickness of the turns in the strapping face varies between the inner end and the outer end.

[0033] In a variant, the manufacturing process comprises the step of: making holes in these elements, the part and/or the watch spring, the density of these holes decreasing from the inner end to the outer end.

[0034] In a variant, the manufacturing process comprises the step of: produce a hollow core surrounded by an envelope, the core having a height which varies between the inner end and the outer end, for example which decreases from the inner end to the outer end.

[0035] A spring having such a hollow core can be made by subtractive manufacturing, for example by ablation of the material by chemical and/or mechanical means. Such a spring can additionally and/or alternatively be produced by additive manufacturing, for example and in a non-limiting way by the PVD deposition process (thick or not), for example around a sacrificial core having a variable height: this makes it possible to lay around a core a layer of material which constitutes the envelope. The core can be made for example of plastic and chemically attacked after the deposition of the envelope, in order to obtain a hollow spring. Another example of additive manufacturing is 3D printing.

[0036] In a variant, the manufacturing process comprises the step of: doping the elements, the part and/or the watch spring with impurities, so that the rigidity of the material decreases from the inner end to the outer end.

The present invention also relates to a barrel comprising the watch spring according to the invention, which can be integrated into a watch mechanism, just like the spring according to the invention.

The watch spring according to the invention, the barrel t/or the watch mechanism can be integrated into a timepiece such as, for example and without limitation, a wristwatch.

According to an independent aspect, the invention relates to a watch spring, for example a barrel spring, in which the height of the turns is constant and at least part of the turns comprises a core and an envelope, the core being hollow. , the core having a height which varies between the inner end and the outer end, so as to make the torque supplied by the barrel spring more constant whatever the position of the barrel spring or the level of winding. Alternatively, the height of the core decreases from the inner end to the outer end.

[0040] According to another independent aspect, the invention relates to a watch spring, for example a barrel spring, in which the height of the turns is constant, and in which at least a part of the turns comprises holes, in which the density holes is variable between the inner end and the outer end, so as to make the torque provided by the mainspring more constant regardless of the position of the mainspring or the level of winding. Alternatively, the hole density decreases from the inner end to the outer end.

Brief description of figures

Examples of implementation of the invention are indicated in the description illustrated by the appended figures in which: FIG. 1A illustrates a known barrel spring in the shape of an S turned over before the strapping operation and its mounting the barrel drum. Figure 1B illustrates a known barrel spring wound around the barrel arbor. Figure 1C illustrates a known barrel spring relaxed against the walls of the barrel drum. FIG. 2 illustrates a perspective view of a blade for the watch spring according to one embodiment of the invention. FIG. 3 illustrates a view in partial section of a few turns of the watch spring according to one embodiment of the invention. FIG. 4 illustrates a perspective view of a blade for the watch spring according to another embodiment of the invention. FIG. 5 illustrates a view in partial section of a few turns of the watch spring according to another embodiment of the invention. FIG. 6 illustrates a perspective view of a blade for the watch spring according to another embodiment of the invention. FIG. 7 illustrates a perspective view of a blade for the watch spring according to another embodiment of the invention. FIGS. 8A to 8C illustrate a sectional view of a blade for the watch spring according to three possible embodiments which do not belong to the invention as claimed. FIG. 9 illustrates a view in partial section of a few turns of the watch spring according to the embodiment of FIG. 8C. FIG. 10 illustrates a view of the sheet-shaped elements used to produce the watch spring according to one embodiment of the invention.

[0042] The proportions indicated in the figures are indicative only and have in certain cases been modified to improve the clarity of the figures. They are not limiting at all.

Example(s) of embodiment of the invention

[0043] Figure 2 illustrates a perspective view of a blade 100 for the watch spring R according to one embodiment of the invention. This blade 100 is intended to be wound, in order to form the watch spring R, and placed in a barrel, in particular in a barrel drum T.

The blade 100 comprises an inner end 10 which, when it is rolled up and placed in a cylinder, does not undergo deformations, and an outer end 20 which, when it is rolled up and placed in a cylinder, undergoes the maximum deformation.

When the blade 100 is rolled up, turns will be formed between the first end 10 and the second end 20: they will be arranged to roll up and/or unroll in the xy strapping plane. These turns have a height substantially perpendicular to the xy plane, which corresponds to the height h in the z direction of the blade 100 of Figure 2.

According to the invention and as shown in Figure 2, this height h varies between the inner end 20 and the outer end 10. In particular, this height h decreases from the inner end 10 to the outer end 20.

Although in Figure 2 this decrease is linear, as well as in Figures 3 to 7, this is not limiting for the invention. In a preferred variant, this decrease is on the contrary non-linear and calculated so as to make the torque provided by the mainspring more constant regardless of the position of the mainspring or the level of winding. The decrease can be for example parabolic, exponential, etc.

In a preferred variant, the type of height variation, as well as the law of this variation, are calculated numerically (for example using finite element calculation or numerical mathematical methods for solving equation) under the constraint that the torque provided by the barrel spring is more constant or as constant as possible.

Although in Figure 2, as well as in Figures 3 to 7, this decrease is continuous, this is not limiting for the invention: in a variant, the height in correspondence of the inner end 10 is greater than that in correspondence of the outer end 20, but it is possible that points or zones between the inner end 10 and the outer end 20 have a variable height, not necessarily included between that of the inner end 10 and that of the outer end 20. It is for example possible that a zone close to the outer end 20 has a greater height than that of a zone close to the inner end 10.

Although in Figure 2, as well as in Figures 3 to 9, the section S of the blade 100 and therefore of the spring R is rectangular, this is not limiting for the invention and any other type of section , for example rectangular with rounded corners, oval, elliptical, etc. may be provided within the scope of the invention.

If the variation in the height of the blade 100 necessary for the torque provided by the barrel spring to be more regular, requires heights which may be too great for the spring to be integrated into a wristwatch, in a variant it It is possible to reduce this (these) height(s) by varying the thickness of the blade 100. In other words, a spiral spring will be produced having heights smaller than those necessary, but a (constant) thickness greater than that initially planned, the increase in thickness being calculated to compensate for the reduction in height initially calculated, so that the torque supplied by the barrel spring is more regular.

[0052] FIG. 3 illustrates a view in partial section of a few turns 30', 30'' and 30''' (and not of all the turns) of the watch spring R according to one embodiment of the invention. The turn 30' is closer to the inner end 10 (not shown) of the spring R: in this example it therefore has a height h' greater than those of the turns 30'' and 30''', which are closer from the outer end 20 (not shown) of the spring R.

[0053] Figure 4 illustrates a perspective view of a blade 100 for the watch spring R according to another embodiment of the invention. As for the variant of Figure 2, the height h of the blade 100 varies between the inner end 20 and the outer end 10. In particular, this height h decreases from the inner end 10 to the end 20. In this case, the thickness e also varies between the inner end 10 and the outer end 20, in particular it decreases from the inner end 10 to the outer end 20.

Although in Figure 4 the decrease in thickness is linear, this is not limiting and any other type of decrease, for example parabolic, exponential, etc. may be provided within the scope of the invention.

In a preferred variant, as for the height, the type of thickness variation, as well as the law of this variation, are calculated numerically (for example using calculation by finite elements or methods numerical mathematics of equation resolution) under the constraint that the torque provided by the barrel spring is more constant or as constant as possible.

The height h and thickness e decrease laws are not necessarily identical, even if they can be.

[0057] FIG. 3 illustrates a view in partial section of a few turns 30′, 30″ and 30″ (and not of all the turns) of the watch spring R according to one embodiment of the invention. As for Figure 3, the coil 30' is closer to the inner end 10 (not shown) of the spring R: in this example it therefore has a height h' greater than those of the coils 30'' and 30'' ', which are closer to the outer end 20 (not shown) of the spring R. The turn 30' also has a thickness e' greater than those of the turns 30'' and 30'''.

The effect of combining the variation, and in particular the reduction, of the height h with that of the thickness e makes it possible to obtain better results in terms of regularity of the driving force of the barrel compared to known solutions, in which only the thickness e varied.

[0059] Figure 6 illustrates a perspective view of a blade 100 for the watch spring according to another embodiment of the invention. In this case, the blade 100 (and therefore at least certain turns when the blade is wound in the form of a spring) comprises holes 40.

The holes 40 can be blind and/or through.

Although the holes 40 have been illustrated in Figure 6 (as well as in Figure 7) with a substantially round / oval shape, this is not limiting for the invention and any other shape of holes 40, for example square, rectangular, polygonal, etc. can be envisaged within the scope of the invention.

Although the holes 40 have been illustrated in Figure 6 (as well as in Figure 7) all with the same shape, this is not limiting for the invention and it is possible to provide holes with shapes different.

These holes 40 can be made only in (at least) a side surface SL of the blade 100 (yz plane), as illustrated in Figure 6, or as illustrated in Figure 7, only in the upper surface SS of the blade 100 and/or also in the lower surface (xy plane), which is not visible in figures 6 and 7.

In a variant not shown, these holes 40 can be made only in the section S of the blade 100 (xz plane).

These variants can be combined: by way of non-limiting example, it is possible to envisage a spring in which the holes are made both in a side surface SL of the blade 100 (plane yz), and in the upper surface SS of the blade 100.

In a preferred variant and for all the variants above, the density of the holes 40 decreases from the inner end 10 to the outer end 20.

The number of holes 40 must be sufficient to achieve the desired regularity of the driving force of the barrel, but not too high to avoid increasing too much the fragility of the spring R and therefore risking its breakage.

The number of holes 40 of Figures 6 and 7 and their dimensions are purely indicative and do not necessarily correspond to the actual number and / or dimensions.

[0069] Figures 8A to 8C illustrate a sectional view of a blade 100 for the watch spring according to three possible embodiments which do not belong to the invention as claimed, because the height of the blade 100 according to the z direction is constant.

This variant makes it possible to produce a spring in which at least certain turns comprise a core 60 and an envelope 70, the core 60 being hollow, the core 60 having a height which varies between the inner end 10 (ha' ) and the outer end 20 (ha''). In a variant, the height of the web decreases from the inner end 10 to the outer end 20 (ha''<ha').

In the examples of Figures 8A to 8C, the core 60 is a quadrilateral, ie it is defined by four sides. In another variant, not shown, the number of sides which define the core 60 is different from four.

[0072] In a variant, only one side of the web 60 in the yz plane has an inclination, allowing this variation in the height of the web 60 (FIG. 8A, upper side; FIG. 8B, lower side).

In another variant, two sides of the core 60 in the yz plane have an inclination, allowing this variation in the height of the core 60 (FIG. 8C, upper and lower side).

In the yz plane, the web 60 can be centered in height (z direction) and/or in width ((y) direction with respect to the section of the blade 100, or not.

[0075] Although in FIGS. 8A to 8C only one hollow core has been illustrated, in other variants the blade 100 comprises two or more hollow cores, aligned for example along the y or z direction.

[0076] Although in FIGS. 8A to 8C the blade 100 has a constant height h from the inner end 10 to the outer end 20, in one embodiment the characteristic according to which at least certain coils of the spring comprise a core 60 and a casing 70, the core 60 being hollow, the core 60 having a height which varies between the inner end 10 and the outer end 20 can be combined with a blade 100 having a variable height from the inner end 10 to outer end 20 according to the invention. This combination can also apply for all the optional characteristics of the spring with the core 60 described above, as well as for all the optional characteristics of the spring according to the invention described in this document.

The shape of the core 60 of Figures 8A to 8C and its dimensions are purely indicative and do not necessarily correspond to the actual shape and/or dimensions.

FIG. 9 illustrates a view in partial section of a few turns 30', 30'' and 30''' of the watch spring R according to the embodiment of FIG. 8C. Although in the variant of Figure 9 the thickness ea of the core 60 is constant, in another variant not shown it also varies from the inner end 10 to the outer end 20, in particular it decreases the inner end 10 to the outer end 20. This is possible even if the height h of the blade 100 varies.

In a preferred variant, as for the height and/or the thickness of the blade 100, the type, number and/or arrangement of the holes 40 as well as the type, number and/or arrangement of the core 60, are calculated numerically (for example using finite element calculations or numerical mathematical methods for solving an equation) under the constraint that the torque provided by the barrel spring is more constant or as constant as possible

[0080] In a variant (not shown) the watch spring is made of a material, in which the rigidity of this material decreases from the inner end 10 to the outer end 20.

In a variant, this material comprises impurities arranged so that the rigidity of this material decreases from the inner end to the outer end. For example, the spring can be made of silicon which is doped with a first material in correspondence of the inner end 10 and with a second material different from the first in correspondence of the outer end 20, so that its rigidity decreases from inner end 10 to outer end 20.

In a variant, the watch spring is made of two or more materials, in which the rigidity of the material of the inner end 10 is greater than that of the material of the outer end 20.

[0083] All the variants described can be combined with each other: by way of example, it is possible to provide a spring with holes 40 as in FIG. 7, having been doped so that its rigidity decreases from inner end 10 to outer end 20. By way of example, it is possible to provide a spring R with a variable thickness as in FIG. 3, and comprising a hollow core 60.

[0084] FIG. 10 illustrates a view of the sheet-shaped elements or platelets 50, used to produce the watch spring according to one embodiment of the invention.

These sheet-shaped elements 50 are superimposed at least partially, for example and in a non-limiting manner as illustrated in FIG. 10. This makes it possible to obtain a part of variable height.

[0086] Then, they are fixed together, in particular irremovably, so as to obtain a one-piece part. This part is then cut, in the case of FIG. 10 along the z direction, so as to obtain a blade with variable height. This blade is then rolled up, so as to obtain the watch spring.

[0087] In a variant, the manufacturing process comprises the step of: produce by additive or subtractive manufacturing these elements 50, the part and/or the watch spring R, so that the thickness of the turns in the strapping face varies between the inner end and the outer end.

[0088] In a variant, the manufacturing process comprises the step of: make holes 40 in these elements, the part and/or the watch spring, the density of these holes decreasing from the inner end 10 to the outer end 20.

[0089] In a variant, the manufacturing process comprises the step of: make a hollow core 60 surrounded by an envelope 70, the core 60 having a height which varies between the inner end 10 and the outer end 20, for example which decreases from the inner end 10 to the outer end 20.

[0090] In a variant, the manufacturing process comprises the step of: dope the elements 50, the part and/or the watch spring R with impurities, so that the rigidity of the material decreases from the inner end 10 to the outer end 20.

Reference numbers and signs used in the figures

[0091] 10 Inner end of the spring R, which does not undergo deformation 20 Outer end of the spring R, which undergoes the maximum deformation 30', 30'', 30''' Spire 40 Hole 50 Sheet-shaped elements/plate 60 Core 70 Casing 100 Blade A Barrel arbor e, e', e'', e''' Thickness of turns ea Thickness of core h, h', h'', h''' Height of turns ha' , ha'', ha''' Height of web N' Number of turns of barrel spring R wound N'' Number of turns of barrel spring R uncoiled R Barrel spring S Section of spring R SL Side surface of spring R SS Spring top surface RT Drum

Claims (15)

1. Watchmaker's spring (R) for a barrel, comprising an inner end (10) which does not undergo deformation during the strapping and/or the unwinding of the said spring, an outer end (20) which undergoes during the said strapping and/or said unwinding the maximum deformation, of the turns (30', 30'', 30''') between the first end (10) and the second end (20) arranged to wind up and/or unwind in the plane of strapping, said turns having a height (h) substantially perpendicular to said plane characterized in that said height (h) varies between the inner end (10) and the outer end (20). 2. Watch spring according to claim 1, wherein said height (h) decreases from the inner end (10) to the outer end (20). 3. Watch spring according to one of claims 1 or 2, said turns (30', 30'', 30''') having a thickness (e) in said plane, said thickness (e) varies between the inner end (10) and the outer end (20). 4. Watch spring according to claim 3, wherein said thickness (e) decreases from the inner end (10) to the outer end (20). 5. Watch spring according to one of claims 1 to 4, at least part of said turns (30', 30'', 30''') comprising holes (40), in which the density of said holes (40) decreases from the inner end (10) to the outer end (20). 6. Watch spring according to one of claims 1 to 5, at least a part of said turns comprising a core (60) and an envelope (70) surrounding the core (60), the core (60) being hollow and having a height (ha', ha'') which varies between the inner end (10) and the outer end (20). 7. Watch spring according to claim 6, in which height (ha', ha'') of the core (60) decreases from the inner end (10) to the outer end (20). 8. Watch spring according to one of claims 1 to 7, made of a material, wherein the rigidity of said material decreases from the inner end (10) to the outer end (20). 9. Watch spring according to claim 8, wherein said material comprises impurities arranged so that the rigidity of said material decreases from the inner end (10) to the outer end (20). 10. A method of manufacturing the watch spring (R) according to one of claims 1 to 9, comprising the steps of: – overlapping at least partially sheet-shaped elements (50), so as to obtain a part of variable height; – fix the elements together, so as to obtain a one-piece piece; – cut the part, so as to obtain a blade (100) with variable height; – winding the blade (100), so as to obtain said watch spring (R). 11. A method of manufacturing the watch spring according to claim 10, comprising the step of: – producing by additive or subtractive manufacturing said elements (50), said part and/or said watch spring (R), so that the thickness (e) of the turns in said strapping face varies between the inner end (10 ) and the outer end (20). 12. A method of manufacturing the watch spring according to one of claims 10 or 11, comprising the step of: – making holes (40) in said elements (50), said part and/or said watch spring (R), the density of said holes (50) decreasing from the inner end (10) to the outer end (20). 13. A method of manufacturing the watch spring according to one of claims 10 to 12 comprising the step of: – make a hollow core (60) surrounded by an envelope (70), the core (60) having a height (ha', ha'') which varies between the inner end (10) and the outer end (20 ), for example which decreases from the inner end (10) to the outer end (20). 14. A method of manufacturing the watch spring according to one of claims 10 to 13, comprising the step of: – doping with impurities the elements (50), said part and/or said watch spring (R), so that the rigidity of said material decreases from the inner end (10) to the outer end (20 ). 15. Barrel comprising the watch spring (R) according to one of claims 1 to 9.