CH716972A2 - Clockwork balance. - Google Patents

Abstract

The invention relates to a balance (1) for a clockwork movement, comprising rigid parts constituted by a hub (2) defining the pivot axis (D) of the balance (1), at least one serge sector ( 3), at least one arm (4) connecting said at least one serge sector (3) to said hub (2), and comprising a slot (7) for receiving and gripping in position of a weight, the slot ( 7) opening into a housing (10) delimited on the one hand by a rigid part of said balance (1), and on the other hand an elastic arm (5) comprising a first end (5b) integral with a rigid part of said balance (1), and a second free distal end (5a). According to the invention, the elastic arm (5) comprises a body (5c) in the form of a hook, the distal end (5a) free of the hook being parallel to a part of the balance (1) having a rigidity greater than or equal to that elastic arm (5).

Description

Field of the invention

The invention relates to a balance for a clockwork movement, comprising rigid parts constituted by a hub defining the pivot axis of the balance, a rim, and at least one arm connecting the rim to the hub, and comprising at least a holding member for receiving and clamping in position a rod of a weight.

[0002] The invention relates to the field of clock oscillators, and more particularly to the field of balances comprising means for adjusting inertia and / or balancing.

Background of the invention

[0003] Numerous embodiments of balances are known with means for adjusting inertia and / or balancing. In particular, balances with screw weights or driven out in implantations of the rim of a balance are known. Some embodiments have attempted to ensure the retention of weights by pinching. Document CH 705 238 is thus known, which discloses a balance comprising at least one slot for receiving and clamping in position a rod of a weight, the slot being delimited by, on the one hand, a so-called rigid part of the balance. , and on the other hand an elastic arm permanently biased towards said rigid part of said balance defining said slot to hold the weight.

During the insertion of the weights the elastic arm undergoes significant plastic deformations due to its spacing. These plastic deformations can then cause defects in the material, such as cracks. This can therefore adversely affect the reliability of the balance, or even damage it, since the weight can no longer be held correctly by the elastic arm and can become dislodged.

Summary of the invention

[0005] The object of the invention is in particular to overcome the various drawbacks of these known techniques.

[0006] More precisely, an objective of the invention is to provide a balance making it possible to obtain better maintenance of the weights with an elastic arm capable of remaining within stress levels not exceeding its elastic limit and thus minimizing the risk of defaults.

Another objective of the invention is to provide a balance with an elastic arm having a sufficiently rigid geometry and allowing sufficient support force to allow the weight to be held in place regardless of the type of shock. that the watch undergoes.

[0008] These objectives, as well as others which will emerge more clearly below, are achieved according to the invention using a balance for a clockwork movement according to claim 1.

[0009] According to other advantageous variants of the invention: the free distal end of the elastic arm has a flat, the flat being arranged opposite the part of the balance having a rigidity greater than or equal to that of the elastic arm; the elastic arm comprises an inner surface of constant curvature over an angle α, at the center of the circle with center C, greater than 240 °; the elastic arm comprises a constant section over an angle β, at the center of the circle with center C, greater than 150 °; the flat extends over an angle γ, at the center of the circle with center C, between 20 ° and 50 °; the slot extends parallel to a radial from said pivot axis; the elastic arm is shaped to remain under a plastic deformation threshold of 0.3% at the bottom of the housing during a substantially vertical rise of the elastic arm with respect to the rigid part of the balance in order to position the rod of the weight; the housing is circular in shape with an entrance defined by the slot and a bottom, the bottom of the housing having dimensions greater than the entrance of the housing; the elastic arm provides a holding force of at least 0.7N; the rigid part comprises a notch for positioning the weight, the width of the opening being less than the diameter of the shank of the weight; the elastic arm is integral with the rim; the elastic arm is integral with the hub; at least one elastic arm is integral with the balance; the balance comprises several elastic arms, the elastic arms being arranged in a central symmetry having as center that of the balance.

The invention also relates to a timepiece movement comprising a sprung balance oscillator system according to the invention.

The invention also relates to a timepiece comprising a timepiece movement according to the invention.

The invention also relates to a method of mounting a weight on a balance according to the invention.

Thus, the object of the present invention, by its various functional and structural aspects described above, makes it possible to obtain a more robust balance, in particular thanks to the disappearance of surface tensile stress along the inner surface. of the elastic arm, this making it possible to limit the formation of weakened zones.

Brief description of the drawings

Other characteristics and advantages of the invention will emerge more clearly on reading the following description of a particular embodiment of the invention, given by way of simple illustrative and non-limiting example, and the appended figures , among : FIG. 1 is a top view of a balance according to the invention according to a first embodiment; FIG. 2 is a top view of an elastic clamping member of a balance according to the invention according to a first embodiment; FIG. 3 is a top view of a balance according to the invention according to a second embodiment; FIGS. 4a and t4b illustrate weights which can be fitted to a balance according to the invention.

Detailed description of the preferred embodiments

A balance according to an exemplary embodiment will now be described in what follows with reference jointly to Figures 1, 2, 3, 4a and 4b.

The invention relates to a balance 1 for a timepiece movement. The balance comprising rigid parts constituted by a hub 2, the center of which defines the pivot axis A of the balance 1, a rim 3, and at least one arm 4 connecting the rim 3 to the hub 2.

According to the needs of those skilled in the art, the balance is made of copper, or of a copper alloy such as nickel silver. The balance wheel can also be made of aluminum, an aluminum alloy, titanium or titanium alloy, gold or gold alloy, platinum or platinum alloy.

The balance 1 also comprises at least one elastic arm 5 comprising a first end 5B integral with the rim of the balance 1, and a second distal end 5A free relative to the hub 2, to the arm 4, and to the rim sector 3 , the free end 5A being able to deform in the plane of the rim and tighten a weight 6 on the balance. The balance also has a slot 7 capable of receiving the weight 6, the slot 7 being delimited on the one hand by the free end 5A of the elastic arm, and on the other hand by a rigid part 8 integral with the rim and the hub. . The slot 7 has an opening 9 allowing the end 5A of the elastic arm to move perpendicularly with respect to the arm 4 and to be in contact with the weight 6 to clamp it against the arm 4 when the latter is placed in the slot .

According to the invention, the elastic arm 5 comprises a hook-shaped body 5C, the free distal end 5A of the hook being parallel to a part of the balance which has a rigidity greater than or equal to that of the elastic arm 5, such a hook shape allows a good distribution of the stresses while limiting the size in the free space between the rim and the hub.

In addition, such a geometry makes it possible to stress the bottom of the housing formed by the elastic arm 5, namely the inner surface S1, in compression and no longer in traction as usual in the state of the art. The main advantage of this is to compensate for the defects which may form as microcracks, this zone working in compression it therefore becomes less subject to these defects.

As can be seen in Figure 2, the free distal end 5A of the elastic arm 5 has a flat 50 disposed vis-à-vis the part of the balance having a rigidity greater than or equal to that of the arm elastic 5, the rigid part possibly being an arm 4 of the balance or another elastic arm 5 for example.

Note that the elastic arm 5 comprises an inner surface S1 of constant curvature over an angle α, in the center of the center circle C, greater than 240 °, such a configuration allowing the arm to work in compression along the inner surface S1.

The elastic arm 5 also comprises a constant section over an angle β, in the center of the circle of center C, greater than 150 °, such a configuration making it possible to have more material under stress.

The flat 50 extends over an angle γ, at the center of the circle with center C, between 20 ° and 50 °.

Advantageously, the slot 7 extends parallel to a radial R from said pivot axis D, and opens into a housing 10 and comprises a notch 11 for precisely positioning the weight 6 and holding it in place. The width of the opening 9 is provided less than the diameter of the weight or of the shank of the weight to hold the weight in place.

The weight 6 comprises a head 61 having an adjustment profile 63 arranged to cooperate with a tool. The weight 6 may include a rod 62 which extends this head 61, which has a diameter greater than that of the rod 62.

In the example illustrated in the figures, the weight 6 is equipped with a foot 65, that the rod 62 then connects to the head 61, the latter and the foot 65 then both having a diameter greater than that of the rod 62, so as to limit the travel of the weight 6 at the level of the elastic arm 5, in a direction parallel to the pivot axis D, or even to immobilize it in this direction.

The rod 62 extends along an axis passing through the center of the weight 6, once gripped by the elastic arm 5, the weight is angularly orientable around this axis by means of a tool on the adjustment profile 63. The weight 6 has an unbalance around this axis, which results for example from a flat 64 made on the head 61, as can be seen in FIG. 2a.

When the weight 6 is placed in the notch 11 of the opening 9, the free end 5A of the elastic arm 5 is moved perpendicular to the general direction of the radius connecting the attachment of the rigid arm to the hub and to the serge relative to the rigid wall 8. The free end 5A has a flat face, facing the notch 11, to provide good support for the rod of the weight 6.

The weight 6 comprises a rod 62 whose minimum diameter is greater than the width of the slot 7 in the free state, and whose maximum diameter is less than the width of the slot 7 when the elastic arm 5 is moved apart the rigid part 8 of the balance 1 delimiting the slot 7 under the effect of a separation force applied to the slot 7 or to the elastic arm 5.

According to the invention, the elastic arm 5 forms a housing 10 delimited by a wall 50, the body 5C of the elastic arm being arranged to deform elastically during the assembly of the weight 6 to the balance, the free end 5A of the elastic arm 5 being able to move substantially perpendicularly, in the plane of the rim, relative to the arm 4.

As shown in Figure 3, the housing 10 has a circular shape with center C, inner radius R1 and outer radius R2, the distance between the two radii R1 and R2 representing the thickness of the arcuate portion circle.

Advantageously, the body 5C of the elastic arm 5 has a first portion in the form of a circular arc of constant section. The circular arc shape makes it possible, on the one hand to increase the surface over which the stresses are distributed, and on the other hand to store as much elastic energy as possible thanks to a volume of material under stress that is greater than to the prior art. The body 5C also comprises a second portion in the extension of the first portion, the second portion being parallel to said arm.

As can be seen in Figure 2, the first portion of the arm has a greater thickness compared to the second portion. Such a configuration makes it possible to have more material under stress and therefore to store more energy and thus restore a good holding force on the weight 6. In the present case, the first portion in the form of a circular arc does not. undergoes very little plastic deformation while providing very good retention of the weight.

The second portion of the arm, arranged parallel to the rigid part 8, has a lesser thickness compared to the first portion. The second portion of the elastic arm can be considered as an embedded beam of non-constant section stressed in bending, the body 5C therefore only undergoes very little plastic deformation.

According to the tests carried out by the inventors, the elastic arm 5 undergoes only 0.3% of plastic deformations along the wall of the arcuate portion while the solution used in the prior art undergoes 2% plastic deformations. The solution used therefore makes it possible to reduce the stresses undergone by the elastic arm 5 during the installation of the weight 6. Such a geometry makes it possible to stress the inner wall of the arcuate portion of the elastic arm 5 in compression and the outer wall in tension. Such a configuration also makes it possible to limit, or even eliminate, the formation of weakened zones such as microcracks that are harmful to the good maintenance of the weight over time.

The dimensions and the geometry of the elastic arm 5 are determined to obtain a minimum desired holding force of the weight, the holding force obtained by the elastic arm being at least 0.7N.

Likewise, the length and width of the arcuate portion of the elastic arm 5 are determined to remain below a stress level in order to avoid plastic deformation. The dimensions of the elastic arm 5 make it possible to store a significant elastic energy resulting from the deformation of the arm, the deformation energy being restored in the form of a holding force on the rod of the weight clamped by the elastic arm 5, which ensures its strength and torque resistance in the notch 11.

It will also be noted that the housing 10 formed by the elastic arm 5 has a relatively large radius at the bottom of curvature, this particular shape is determined to obtain a better distribution of the stresses during the assembly of the weight 6, the stresses being distributed over a much larger area compared to the prior art, this makes it possible to avoid weakening the structure along the curvature formed by the arc of a circle. In fact, in the prior art, the radius at the bottom of the curvature of the holding member is much smaller, which implies a very localized distribution of stresses, the formation of microcracks at this location, and therefore a gradual reduction in the stress. holding force over time.

The invention allows, by the particular geometry of the elastic arm 5, to obtain a satisfactory holding force of the weight and to eliminate the formation of weakened areas when the arm is moved to place the weight 6. It appears that the quantity of material under stress is decisive to exert a satisfactory holding force on the weight (According to Clapeyron's formula, the elastic energy stored in the material body is equal to the work of all the forces applied, W =

The ideal solution would therefore be to increase as much as possible the amount of material under stress so that the elastic arm restores a greater holding force. However, such an option implies a larger size of the elastic arms, which would significantly modify the inertia of the balance and complicate the assembly of the latter, in particular the bolt.

According to the embodiments, illustrated in Figure 1 and Figure 3, the balance may include two or four elastic arms 5.

The invention also relates to a method of mounting a weight on a balance as described above. The assembly method according to the invention comprises the following steps: a) placing the balance 1 on a support and keeping it in place; b) moving the free end 5A of the elastic arm 5 perpendicularly in the plane of the rim, relative to the arm 4; c) placing the weight 6 at the level of the notch 11 so that the foot 65 coincides with the location of the notch 11; d) moving the weight 6 in a rectilinear direction towards the notch 11 to accommodate the foot 65 in the latter.

The method may include an optional step following step c) during which the weight 6 is finely positioned so that the head of the weight is in contact with the upper face of the arm 5 and the face top of the rigid wall 8.

The invention also relates to a balance 1 which comprises a plurality of retaining members 5, each being arranged to receive at least one weight 6.

The invention also relates to a timepiece movement comprising at least one such balance 1 as described above.

The invention also relates to a timepiece comprising at least one such movement, and which is preferably a watch.

Claims (15)

1. Balance (1) for a clockwork movement, comprising rigid parts constituted by a hub (2) defining the pivot axis (D) of said balance (1), at least one serge sector (3), at least an arm (4) connecting said at least one serge sector (3) to said hub (2), and comprising at least one slot (7) for receiving and clamping in position a weight (6), said at least a slot (7) opening into a housing (10) delimited on the one hand by a rigid part (8) of said rocker (1), and on the other hand an elastic arm (5) comprising a first end (5B) integral with the rim of said balance (1), and a second distal end (5A) free relative to said hub (2), to said arm (4), and to said rim sector (3), characterized in that said elastic arm (5) comprises a hook-shaped body (5C), the free distal end (5A) of the hook being parallel to a part of the balance having a rigidity greater than or equal to that of the elastic arm ( 5). 2. Balancer (1) according to claim 2, characterized in that the distal end (5A) free of the elastic arm (5) has a flat (50), the flat (50) being disposed vis-à-vis the part of the balance having a rigidity greater than or equal to that of the elastic arm (5). 3. Balance (1) according to one of claims 1 to 3, characterized in that the elastic arm (5) comprises an inner surface (S1) of constant curvature over an angle α, at the center of the center circle C, greater at 240 °. 4. Balancer (1) according to one of claims 1 to 4, characterized in that the elastic arm (5) comprises a constant section over an angle β, at the center of the circle of center C, greater than 150 °. 5. Balance (1) according to one of claims 2 to 4, characterized in that the flat (50) extends over an angle γ, at the center of the circle with center C, between 20 ° and 50 °. 6. Balance (1) according to one of claims 1 to 5, characterized in that the slot (7) extends parallel to a radial (R) from said pivot axis (D). 7. Balancer (1) according to one of claims 1 to 6, characterized in that the elastic arm (5) is shaped to remain under a plastic deformation threshold of 0.3% at the bottom of the housing (10) during a substantially vertical rise of the elastic arm (5) relative to the arm (8) of the balance when the rod of the weight is put in place. 8. Balancer (1) according to one of claims 1 to 7, characterized in that said housing (10) is of circular shape with center (C) and radius (R1) with an entrance defined by the slot (7). and a background. 9. Balance (1) according to one of claims 1 to 8, characterized in that the elastic arm provides a holding force of at least 0.7N when the weight is mounted. 10. Balancer (1) according to one of claims 1 to 9, characterized in that said rigid part (8) comprises a notch (11) for positioning the weight, the width of the opening being less than the diameter of the rod. of the flyweight. 11. Balance according to one of the preceding claims, characterized in that said at least one elastic arm (5) is integral with the balance (1). 12. Balance according to one of claims 1 to 11, characterized in that it comprises several elastic arms (5), the elastic arms being arranged in a central symmetry having as its center that of the balance. 13. Timepiece movement comprising at least one balance (1) according to one of claims 1 to 12. 14. Timepiece comprising at least one movement according to claim 13, characterized in that it is a watch. 15. A method of mounting a weight (6) on a rocker (1) according to claims 1 to 12, the mounting method comprising the following steps: a) place the balance (1) on a support and keep it in place; b) placing the weight (6) at the level of the housing (10) so that the foot (65) rests in the housing, the foot (65) being positioned in line with the slot (7); c) moving the weight (6) in a rectilinear direction towards the slot (7) to accommodate the foot in the notch (11), the foot of the weight separating the elastic arm (5) during its movement.