CH700536B1 - column wheel for chronograph control mechanism and chronograph watch comprising such a wheel. - Google Patents

Abstract

The invention relates to a chronograph column wheel, a chronograph control mechanism and a chronograph watch comprising such a wheel. The column wheel (1) for chronograph comprises: - a ratchet (2) provided with a plurality of teeth (3) whose shape defines a direction of rotation for the column wheel; A coaxial superstructure at the ratchet and having a symmetry of rotation of order n> = 3, the peripheral part of the superstructure forming n columns (10) parallel to the axis of the wheel and arranged substantially along the periphery of the ratchet (2), each column having an outer portion whose cross section has substantially the shape of a truncated triangle with a base (14) substantially parallel to the circumference of the wheel and a front side (12), said edge of attack, and a trailing edge (13), said trailing edge, extending from the base towards the inside of the wheel. The column wheel is characterized in that said cross section is asymmetrical, a first angle α between the leading edge (12) and the base (14) being smaller than a second angle β between the base and the trailing edge ( 13).

Description

Technical field of the invention

The invention relates to a column wheel for chronograph comprising columns whose shape is optimized. It also relates to a chronograph control mechanism and a chronograph watch comprising such a column wheel.

State of the art

In a chronograph watch, in order to control and manage the various functions of the chronograph, it is known to use a column wheel. Column columns of the column wheel typically have a cross section often substantially shaped truncated triangle (see Fig. 1). This type of shape makes it possible to manufacture the wheel and the columns in a simple and inexpensive way. However, the various levers subjected to the action of the columns are subjected to efforts sometimes too important, thus increasing the levels of friction and wear. In addition, the level of precision, when implementing the various functions of the chronograph, is not always optimal.

Presentation of the invention

An object of the present invention is to overcome the aforementioned drawbacks of the prior art by providing a column wheel for a better distribution of forces on the levers and a higher level of precision in the management of chronograph functions. It achieves this goal by providing a column wheel according to the appended claim 1.

It will be understood that it is with respect to the direction of rotation of the column wheel that are defined a front side and a rear side of the truncated triangle shaped cross section.

The characteristics of the invention make it possible to optimize the general mechanical characteristics of the levers cooperating with the columns: for example, a reduction in friction, wear and energy losses, and a better accuracy of the arrangements of parts are obtained. and resulting functions, etc. This results in better management of the chronograph functions.

[0006] The geometry of the columns makes it possible to precisely define the direction of the force vectors necessary for lifting the levers. This results in a reduction of the forces involved, a better performance, a decrease in wear and increased control of the force to exert on the command "start / stop".

According to an advantageous embodiment, the base is convex so as to be substantially parallel to the circumference of the column wheel.

The angle α is advantageously less than the angle β of at least 10% and preferably at least 20%. Moreover, the angle α is preferably between 50 and 53 degrees. It will be understood on the one hand that by choosing a sufficiently salient angle α (α <53 °), it is possible to maximize the length of the beak stroke, which allows either to increase the lever lift angle or to increase the length of the lever arm while keeping the same lifting angle. On the other hand, if the angle α is too salient (α <50 °), the efforts are concentrated on the angle α, which can result in an undesirable increase of the losses and the force necessary to actuate a ordered.

According to another advantageous embodiment, the superstructure of the column wheel comprises a hub connected to the columns by arms so as to strengthen the columns.

According to yet another advantageous embodiment, the hub and the arms have a height of between 10% and 50% of the height of the columns.

The invention also provides a chronograph control mechanism comprising a column wheel as previously described and at least one pivoting lever whose beak is likely to cooperate with the columns of the column wheel.

The invention further provides a chronograph watch comprising a column wheel as previously described and at least one pivoting lever whose beak is likely to cooperate with the columns of the column wheel. The lever may for example be a clutch rocker, a hammer or a blocker.

Brief description of the drawings

Other features and advantages of the present invention will appear on reading the description which follows, given solely by way of non-limiting example, and with reference to the accompanying drawings in which: <tb> fig. 1 <SEP> shows a perspective view of a known type column wheel; <tb> fig. 2 <SEP> is a schematic top view in cross section of a column wheel column according to a particular embodiment of the present invention; <tb> fig. 3 <SEP> is a perspective view of the column wheel of FIG. 2; <tb> fig. 4 <SEP> is a top view of the column wheel of FIGS. 2 and 3; <tb> fig. <SEP> is a train side view showing an example of integration in a chronograph watch of a column wheel according to a particular embodiment of the present invention; <tb> figs. 6a and 7 to 12 <SEP> correspond to seven successive snapshots describing the function "start", that is to say the sequence during which a pressure of the user on a pusher advances by a step of 30 ° the column wheel mounted in a chronograph watch. Advancing the column wheel to raise a hammer to release the chronograph hearts and also actuate the clutch rocker to start the chronograph hand. The seven "snapshots" are taken every 5 °; <tb> fig. 6b <SEP> describes the same instant as FIG. 6a, but shows the whole mechanism.

Detailed description of an embodiment

Fig. 1 shows a perspective view of a known type column wheel. The columns are evenly distributed around the rim. Considering a cross section of a column, a symmetrical profile is obtained, substantially in the form of a truncated triangle, or a trapezium, whose large base is parallel to the circumference of the column wheel and turned towards the outside of the column. the teeth of the ratchet. Such a symmetrical arrangement has advantages in terms of design and especially the manufacture of columns.

FIG. 3 shows a perspective view of a column wheel 1 according to a particular embodiment of the invention. Fig. 4 shows a top view of the same column wheel. These two figures make it possible to clearly view the ratchet 2 provided with teeth 3 distributed symmetrically around its periphery. The ratchet 2 is drilled in its center to provide an assembly element for mounting the wheel 1 in a chronograph device. The ratchet 2 is capped with a superstructure constituted by a hub 21, by arms 20 and by columns 10. The six columns 10 are arranged symmetrically on the periphery of the ratchet 2 thus giving the superstructure 10, 20, 21 a symmetry of rotation of order 6. It is also possible to check in FIG. 4 that the ratchet 2 has 12 teeth regularly spaced from each other by 30 °. Those skilled in the art will understand that the column wheel of the present example is a two-stroke column wheel. However, the present invention naturally applies equally well to three-stroke column wheels. The arrow R in FIG. 4 illustrates the direction of rotation of the column wheel 1, ie the clockwise direction.

FIG. 2 shows a cross section of a column 10. It is observed that the section of the column generally has a non-isosceles triangle shape truncated in the area of the summit. The three sides of the triangle are the large base 14, located near the edge of the ratchet 2, the leading edge 12, and the trailing edge 13. The leading edge 12 is so designated because it is the first to come into contact with the spout of the lever (s) of the chronograph mechanism during the rotation of the wheel 1. The trailing edge 13 designates the last face to contact the lever before the latter plunges into the inter column space 22 and is free.

The two angles a and p adjacent to the large base 14 are rounded. As will be seen below, this feature facilitates the progression of the nozzle of the lever cooperating with the column during operation of the chronograph.

With reference to the figures, it is noted that the truncated or trapezoidal triangle shape of the cross section of a column is asymmetrical, with an angle α less than the angle β, where the angle α represents the an angle formed between the large base 14 and the leading edge 12, while the angle β represents the angle formed between the large base 14 and the trailing edge 13. According to such an arrangement, the leading edge 12 is substantially projected forward (in the direction of rotation R) in comparison with a conventional symmetrical arrangement as shown in FIG. 1.

In the illustrated example, the angles α and β are respectively 51.5 degrees and 69.5 degrees. According to various alternative embodiments, the angle α may vary, but it is preferably between 50 and 53 degrees. In the present example, the angle α is about 26% lower than the angle β. According to various embodiments, the distance between the two angles is preferably between 23 and 28%.

Figs. 2, 3 and 4 also make it possible to clearly visualize the hub 21 and the arms 20 serving to reinforce the columns 10. The arms 20 extend between the columns and the hub 21 which is centered on the axis of the wheel. The arms and the hub make it possible to stiffen the construction of the wheel in general, and the columns in particular. This stiffening of the columns allows operation with a particularly high level of precision. In the present example, the hub 21 and the arms 20 have a height less than that of the columns 10. The height of the hub and the arms will preferably be between 10% and 50% of the height of the columns. The column wheel according to the invention is preferably manufactured entirely on a lathe. A manufacture without recovery on a lathe allows to give the piece a remarkable precision.

FIG. 5 shows an example of implementation of a column wheel 1 according to the invention in a chronograph control mechanism. In addition to the components of the column wheel already described in relation to FIGS. 3 and 4, FIG. 5 shows a jumper 24 whose spout 25 is provided to cooperate with the teeth of the ratchet 2, a second / minute hammer lever 40 mounted for pivoting about an axis 42, a clutch rocker 50 with a spout 51 and, finally, a blocking lever 30. FIG. 6b is a corresponding view in which the main elements of a chronograph are shown. The blocking lever 30 is integral with a shoe 32 and is arranged to cooperate with the column wheel to alternately brake and release the chronograph mobile (referenced 5). The hammer lever 40 is pivotally mounted about an axis 42 (FIG 5) and is provided with a spout 41 capable of cooperating with the columns of the column wheel so as to act on the cores 43 to control and manage the chronograph return to zero function. Fig. 6b represents the hammer 40 in a lowered position where it cooperates with the cores 43. It is still seen in FIG. 6b that the lowered position of the hammer corresponds to a position of the column wheel which allows the spout 41 of the hammer lever 40 to plunge into the gap between two columns 10. This position of the column wheel, identified as 0 degree , serves as a reference. Figs. 6a, and 7 to 12 show the evolution of the position of the wheel, in steps of 5 degrees, to a position of 30 degrees (Figure 12).

The snapshot shown in FIG. 6a corresponds to the 0 ° position of the column wheel. In this position, as already mentioned, the hammer is lowered against the cores and the hammer nose 41 is positioned freely between two columns 10. It is still seen in FIG. 6a that position 0 °, the spout 51 of the clutch rocker 50 bears against the outer face of a column 10. The clutch lever is thus lifted which has the effect of maintaining a return 28 removed of the chronograph wheel 5, and thus to disengage the latter. Note further that the hammer 40 and the blocking lever 30 are shaped to cooperate so that the blocker is held up regardless of the position of the column wheel as the hammer is lowered against the cores 43.

The snapshot shown in FIG. 7 corresponds to the 5 ° position of the column wheel. We see that in this position, the hammer 40 and always lowered against the cores 43 and the blocker 30 is always lifted. However, it is seen that the hammer nose 41 initiates contact with the leading edge of a column A. The spout 41 is substantially tangent to the leading edge. It is therefore understood that the shape of the columns according to the invention makes it possible to distribute as much as possible the forces acting on the spout 41. On the other hand, as in FIG. 6a, the spout 51 of the clutch rocker 50 bears against the outer face of the column A.

The snapshot shown in FIG. 8 corresponds to the 10 ° position of the column wheel. It can be seen that in this position, the hammer nose 41 is slightly pushed back by the leading edge of the column A and the hammer has slightly detached from the cores 43. It can also be seen that the clutch rocker nose 51 slides. always against the great base of this same column. Blocker beak 31 is about to initiate contact with column B.

The snapshot shown in FIG. 9 corresponds to the position 15 ° of the column wheel. It can be seen that in this position the lifting of the hammer beak 41 is accentuated by the action of the column A. The hammer has now completely released the cores 43. It can also be seen that the clutch lever 51 arrives near the rear area of the large base 14 of the column A. On the other hand, the hammer 40 is releasing the blocker 31, but simultaneously the jammer nose 31 initiates contact with the outer face of the column B .

The snapshot shown in FIG. 10 corresponds to the 20 ° position of the column wheel. We see that in this position, the lifting of the hammer beak 41 is almost completed. It is also seen that the clutch rocker nose 51 is about to plunge. On the other hand, the blocker beak 31 is now well against the large base 14 of the column B.

The snapshot shown in FIG. 11 corresponds to the 25 ° position of the column wheel. It can be seen that in this position, the hammer nose 41 bears against the large base 14 of the column A. The clutch rocker nose 51 has plunged between two columns, but the chronograph mobile 5 is not yet engaged. The blocker nose 31 is still resting against the large base 14 of the column B.

The snapshot shown in FIG. 12 corresponds to the 30 ° position of the column wheel. It can be seen that in this position, the clutch lever 51 is always lowered between two columns and the gear 28 now meshes with the chronograph mobile which is thus engaged, which corresponds to the start ("start") of the chronograph. The blocker beak 31 remains in abutment against the large base 14 of the column B.

We note from the foregoing, and particularly figs. 7-11, that the stroke of the hammer lever nose along the leading edge of a column is greater than if the leading edge 12 and the trailing edge 13 were symmetrical. This spreading of the displacement over a greater distance makes it possible to reduce the applied force. These characteristics make it possible to optimize the general mechanical characteristics of the levers: for example, a reduction in friction, wear and energy losses, and a better accuracy of the arrangements of parts and the resulting functions, etc. are obtained. In particular, the execution of the lifting and diving of the levers 30, 40 and 50 by the asymmetric columns with advanced leading edge are performed very precisely with optimized synchronization of the respective movements of the parts during the performance of the functions. of the chronograph. This results in better management of the chronograph functions. This geometry of the columns makes it possible to precisely define the direction of the vectors of forces necessary for the lifting of the levers. A reduction in the forces involved, a better efficiency, a reduction in wear and an increased control of the force to be exerted on the "start / stop" command are thus obtained.

It will further be understood that various modifications and / or improvements obvious to a person skilled in the art can be made to the embodiment which is the subject of the present description without departing from the scope of the present invention defined by the appended claims. In particular, the invention and its various variants have just been described in connection with a particular example with six columns. Nevertheless, it is obvious to a person skilled in the art that the invention can be extended to an embodiment with a different number of columns, in particular with eight columns.

Claims (11)

1. Column wheel (1) for a chronograph comprising: - a ratchet (2) provided with a plurality of teeth (3) whose shape defines a direction of rotation for the column wheel; A coaxial superstructure at the ratchet and having a symmetry of rotation of order n> = 3, the peripheral part of the superstructure forming n columns (10) parallel to the axis of the wheel and arranged substantially along the periphery of the ratchet (2), each column having an outer portion whose cross section has substantially the shape of a truncated triangle with a base (14) substantially parallel to the circumference of the wheel and a front side (12), said edge of attack, and a trailing edge (13), said trailing edge, extending from the base towards the inside of the wheel; characterized in that said cross section is asymmetrical, a first angle α between the leading edge (12) and the base (14) being smaller than a second angle β between the base and the trailing edge (13). 2. column wheel (1) for chronograph according to claim 1, wherein the base (14) is substantially rounded convex. 3. Chronograph column wheel (1) according to claim 1 or 2, wherein the angle α is less than the angle β of at least 10% and preferably at least 20%. 4. column wheel (1) for chronograph according to claim 1, 2 or 3 wherein the angle α is between 50 degrees and 53 degrees. 5. column wheel (1) for chronograph according to one of the preceding claims, characterized in that the superstructure comprises a hub (21) connected to the columns (10) by arms (20) so as to strengthen them. 6. column wheel (1) for a chronograph according to claim 5, wherein the arms (20) and the hub (21) have a height of between 10% and 50% of the height of the columns. 7. Chronograph control mechanism comprising a column wheel (1) according to one of claims 1 to 6, and at least one pivoting lever (30, 40, 50) whose beak is capable of cooperating with the columns (10). ) of the column wheel. 8. chronograph control mechanism according to claim 7, wherein a lever is a clutch rocker (50). 9. chronograph control mechanism according to claims 7 or 8, wherein a lever is a hammer (40). 10. chronograph control mechanism according to one of claims 7, 8 or 9, wherein a lever is a blocker (30). 11. Chronograph watch comprising a chronograph control mechanism according to one of claims 7 to 10.