CH712052A1 - Escape mechanism with lost strokes. - Google Patents

Abstract

A lost-blow escapement mechanism includes: an escape wheel (12) for receiving energy from an energy source to rotate it, and directly providing a plot of energy energy to a balance (10), a locking member (16) intended to cooperate with the escape wheel (12) to block its rotation, a trigger wheel (22) rotatably mounted and arranged to cooperate directly or indirectly with the exhaust wheel (12), a unidirectional drive system for mounting on the balance (10). The mechanism is arranged so that the unidirectional drive system once actuates the triggering wheel (22) by oscillation to drive it in rotation, periodically releasing the escape wheel (12) to give an impulse to the balance. (10).

Description

Description TECHNICAL FIELD [0001] The present invention relates to the field of watchmaking. It relates, more particularly, to an escape mechanism comprising - an escape wheel intended to receive energy from an energy source to rotate it, and to directly supply a parcel of energy to a pendulum to maintain its oscillations, and - a locking member for cooperating with the escape wheel to block its rotation.

STATE OF THE ART [0002] Among the various types of escapement, the lost-shot escapement family proposes not to transmit an impulse to the balance wheel at each of its alternations. Escapement exhausts are probably the best known escapement with lost strokes, with a blow lost by oscillation, an impulse every two alternations.

This type of escape is interesting in that it limits the disturbances to the oscillator and increase the power reserve. However, there are extremely few mechanisms that offer more silent switching. For example, among the historical systems, there is the Jacot duplex escapement, which offers an exhaust with triple lost strokes, or a pulse every two alternations.

However, since the oscillations of the pendulum are maintained at a slower frequency than for escapements without a blow, it is preferable that the quality factor of the balance is particularly high.

The present invention aims to provide a new type of escapement strokes, can be used with an oscillator having a high quality factor, but which can also be used with a conventional oscillator.

DISCLOSURE OF THE INVENTION [0006] More precisely, the invention relates to an escape mechanism as defined in the claims. BRIEF DESCRIPTION OF THE DRAWINGS [0007] Other details of the invention will appear more clearly on reading the description which follows, given with reference to the appended drawing in which: FIG. 1 is an overall view of a first embodiment of the invention, FIGS. 2 to 6 are chronological views of successive phases of the mechanism of FIG. 1, in operation, FIGS. 7, 8 and 9 propose additional embodiments of the invention, the shaded areas schematizing the movements of certain parts or elements, and FIG. 10 proposes a variant of the first embodiment.

Embodiment of the Invention [0008] FIG. 1, an escape mechanism according to a first embodiment of the invention. The function of the escapement is to count and maintain the oscillations of the regulating member, in this case a rocker 10, associated with a return spring, of spiral or other type.

The exhaust mechanism comprises an escape wheel 12 for receiving energy from a power source, a barrel spring for example. The energy is provided in the form of a rotational torque tending to turn the escapement wheel 12 into rotation. The exhaust mechanism according to the invention is a direct exhaust and the escape wheel 12 is arranged to directly supply a parcel of energy to the beam 10, cooperating with an anchor 14 or an ellipse integral with the beam 10.

The exhaust mechanism according to the invention further comprises a locking member 16 for cooperating with the escape wheel 12 to block its rotation. As will be understood later, this rotation is intermittently blocked, which momentarily releases the torque provided by the energy source.

In the embodiment of FIG. 1, the locking member 16 is an intermediate piece, of the weighing type, comprising a rest pallet 18 intended to block the rotation of the escape wheel 12. The rocker is held elastically against a stop 20 under the action of a spring 21, in a waiting position. In this position, the rest pallet 18 is in the race of the teeth of the escape wheel 12 which, under the action of the torque transmitted by the energy source, comes to rest on the pallet rest 18. It is within the reach of the skilled person to determine the conformations of the teeth of the escape wheel 12 and the pallet rest 18, to optimize the interactions between these elements. It will be noted, however, that the escape wheel 12 can be active on different levels. In the example, the escape wheel 12 has arms 12a defining a first plane and at the end of which are arranged the teeth 12b, arranged in a different plane. The arms 12a of the escape wheel 12 are located in the plane of the pin 14 of the rocker 10 and the teeth 12b in the plane of the locking member 16.

The escapement mechanism according to the invention further comprises a trigger wheel 22 rotatably mounted and arranged to cooperate directly or indirectly with the exhaust wheel 12, in order to release it. The axis of the trigger wheel is distinct from the axis of the balance.

In the embodiment of FIG. 1, this cooperation is indirect and is done by the intermediate piece. To do this, the trigger wheel 22 is mounted coaxially and rotatably connected to a trigger cam 24 intended to cooperate periodically with the intermediate piece, via a release pallet 26 that includes the intermediate piece. In the example, the trip cam 24 comprises teeth (in this case 3), arranged to cooperate with the pallet clearance 26 and cause the release of the escape wheel 12 of the pallet rest 18.

The trigger wheel 22 is mounted free to rotate on its axis. It is positioned by a jumper 28, which also makes it possible to regulate the rotation by steps of the triggering wheel 22.

To rotate the trigger wheel 22, the exhaust mechanism according to the invention comprises an elastic pawl 30 to be mounted on the rocker 10. This pawl 30 comprises a finger 32 capable of cooperating with the trigger wheel 22 during pendulum oscillations 10. A stud 34 is arranged in such a way that the pawl 30 closes during alternations in one direction (counterclockwise in FIG 1), and that the pawl 30 pushes the trigger wheel 22 in the other direction (clockwise rotation in Fig. 1). Those skilled in the art can consider various types of unidirectional drive, such as ratchets of various shapes or a pin shaped to exercise an effective motor action for the alternations in one direction.

Thus, with each oscillation, the resilient pawl 30 actuates once the trigger wheel 22 to drive it in rotation. This rotation is a step, under the action of the jumper 28. The escape wheel 12 is released periodically, in this case, when the trigger cam 24 cooperates with the intermediate piece. The escape wheel 12 can then give a direct impulse to the balance 10.

We will now explain the operation of the mechanism as proposed in FIG. 1, with reference to FIGS. 2 to 6.

In FIG. 2, the escape wheel 12 is at rest, resting on the pallet 18, the intermediate piece being positioned against the stop 20 by the action of the spring 21, not shown in this figure. The rocker 10 is in its alternation in the clockwise direction and the resilient pawl 30 pushes one of the teeth of the trigger wheel 22, which rotates without operating anything at the trigger cam 24 in this figure. The jumper 28 positions the trigger wheel 22 after the drive by the resilient pawl 30.

As the advances of the trigger wheel 22, the trigger cam 24 is in the position shown in FIG. 3, adapted to cooperate with the release pallet 26 of the intermediate piece. Under the action of the trip cam 24, the intermediate piece pivots, which releases the escape wheel 12 of the pallet rest 18.

The arm 12a of the tooth 12b of the escapement wheel 12 which has just been released then gives a pulse to the rocker 10 by pushing the pin 14. The intermediate piece returns to its initial position against the stop 20 under the action of the spring 21.

The rotation of the exhaust wheel 12 continues, driven by the energy source. The next arm 12a falls on the pallet of rest 18 (FIG 5) and the escape wheel 12 returns to the position of FIG. 2.

During the next alternation of the balance 10, the pawl 30 unclips on the trigger wheel 22, without actuating it (Figure 6).

Thus, by adjusting the ratio between the number N of teeth of the trigger wheel 22, and the number n of teeth or more generally triggers of the trip cam 24, we can define the number of shots. lost, that is to say the number of alternations during which there is no pulse transmitted to the pendulum 10. It is implied that N> n. An impulse is transmitted to the balance 10 every 2 x (N / n) alternations.

FIG. 10 proposes a variant of this first embodiment, wherein the locking member 16, more particularly the rocker-type intermediate piece, is not held elastically in its standby positron, but is brought back into this position by the action of an additional arm 40, arranged to cooperate with a positioning cam integral with the trigger wheel. The skilled person then provides an angle of draw between the escape wheel and the locking member to maintain the latter against the stop 20, without disrupting the rotation of the trigger wheel.

In the proposed example, it is the trigger cam 24 which also acts as a positioning cam, but the two functions could be performed by two separate cams, coaxial and rotatably connected. After the release made by a first tooth of the actuating cam, another tooth cooperates with the additional arm 40 to return the latch to its standby position.

One could also consider a safety device that would limit the movements of the locking member 16 in case of shocks, for example by adding another arm to the locking member 16 or an additional level on the arm 40 to cooperate with an additional safety cam, not shown, located on the trigger wheel.

FIG. 7 shows a second embodiment of the invention, wherein the locking member 16 is disposed on the release wheel 22. More particularly, the locking member 16 is formed of a stud 34 mounted on the projection Trigger wheel 22. The stud 34 is arranged to cooperate with the escape wheel 12, more particularly with its teeth, in order to lock it in rotation.

In an original way, the trigger wheel 22 is positioned by a jumper 28 cooperating with a structure 36, called the positioning structure, that comprises the trigger wheel 22. The jumper 28 and the structure 36 are configured so that that the jumper 28 returns the trigger wheel 22 to a single preset position, after actuation by the resilient pawl 30, in an oscillatory rotation. In other words, the angular sector in which the jumper 28 and the positioning structure 36 cooperate, is greater than the angular stroke traveled by the trigger wheel 22 when actuated by the pawl 30.

Furthermore, the trigger wheel 22 comprises one, in this case, a single tooth 22a, intended to cooperate with the elastic pawl 30 carried by the balance 10. In this case, the concept of tooth more generally encompasses a driving portion, capable of receiving a driving action of the pawl 30.

Thus, when the pawl 30 drives the triggering wheel 22 in clockwise rotation (with reference to FIG 7), the jumper 28 is always in cooperation with the positioning structure 36 when the pawl 30 escapes from the tooth 22a of the trigger wheel 22. The jumper 28 exerts a force on the positioning structure 36 which has the effect of bringing the trigger wheel 22 back to its initial position, by rotating counterclockwise (still in reference in Fig. 7). The rotation of the trigger wheel 22 was sufficient to allow the stud 34 to release the escape wheel 12. The arm 12a which has just been released can then transmit a pulse to the balance 10, via the ankle 14.

In this embodiment, there is a single blow, so a pulse oscillation.

Figs. 8 and 9 propose another embodiment, derived from the embodiment of FIG. 7. The locking member 16 is always disposed on the trigger wheel 22. The locking member 16 is this time formed by a plurality of pads 34, projecting and distributed over the trigger wheel 22.

In this embodiment, the trigger wheel 22 is arranged to be rotated in a continuous direction, as in the first embodiment. It therefore has a toothing or a series of drive portions, over its entire periphery. The jumper 28 ensures the positioning of the trigger wheel 22 at each step.

In FIG. 8, there is a stud 34 per tooth of the trigger wheel 22, which allows to obtain a blow lost by oscillation.

In FIG. 9, each stud 34 extends facing a plurality of teeth of the trigger wheel, preferably forming a circular arc, advantageously positioned in a peripheral zone of the trigger wheel 22. The number of studs 34 is reduced compared to FIG. 8 and the angular sector covered by them is increased. Those skilled in the art can adjust the ratio between the number N of teeth of the trigger wheel 22 and the number k of pads 34. k is an integer> 1 and less than N / 2.

It will be noted that the skilled person can also adjust the pitch of the toothing of the trigger wheel 22, particularly at the intervals between two consecutive pads 34, that is to say in the areas corresponding to the clearance of the escape wheel 12, for example to have a greater pitch during this clearance and facilitate the passage of the arm 12a of the escape wheel 12 between the pads 34.

Thus is proposed an innovative exhaust mechanism, in particular in that it implements a trigger wheel 22, rotatable in either a continuous direction, or in an oscillatory rotation. In addition, it is possible to program the number of strokes lost and thus optimize the performance of the exhaust. Depending on the number of strokes lost, this escape mechanism can be used with any type of oscillator. However, it is particularly advantageous to be used with a high quality oscillator comprising a pivot as proposed in document PCT / EP 2015/065 884, filed in the name of the applicant and integrally incorporated by reference in the present application, in particular passages describing blade pivot configurations.

More particularly, such a timepiece pivot pivotally connects a first part with a second part in a pivot axis about a pivot axis. The pivot comprises a blade provided with a wire, secured to one of the first or second parts and parallel to the axis of the pivot, and a support zone secured to the other of the first and second parts and against which the wire blade is supported, the contact points of the blade and the bearing zone being substantially located on the axis of the pivot. The pivot comprises means arranged to hold the blade in abutment against the bearing zone. The median plane of the blade passing through the wire defines a blade plane. In normal operating mode, said means are

Claims (13)

arranged so that the first and second parts are not free to translate one with reference to the other in the direction orthogonal to the axis of the pivot contained in the blade plane. claims 1. Stroke escape mechanism comprising; an escape wheel (12) intended to receive energy from an energy source in order to turn it into rotation, and to directly supply a parcel of energy to a rocker (10), a blocking member (16) intended to cooperate with the escape wheel (12) to block its rotation, - a trigger wheel (22) rotatably mounted and arranged to cooperate directly or indirectly with the escape wheel (12), - a system unidirectional drive means for mounting on the balance (10), said mechanism being arranged in such a way that the unidirectional drive system actuates the trigger wheel (22) once by oscillation to drive it in rotation, releasing periodically the escape wheel (12) to give a pulse to the beam (10). 2. Exhaust mechanism according to claim 1, characterized in that the unidirectional drive system is a latching system. 3. Exhaust mechanism according to one of claims 1 and 2, characterized in that the locking member (16) is an intermediate piece comprising a pallet rest (18) for blocking the rotation of the wheel of exhaust (12). 4. Exhaust mechanism according to claim 3, characterized in that the intermediate piece is a rocker held elastically in a waiting position, against a stop (20). 5. Exhaust mechanism according to claim 3, characterized in that the intermediate piece is a rocker comprising an additional arm (40) arranged to cooperate with a positioning cam integral with the trigger wheel, to return said latch in a position waiting, against a stop (20). 6. Exhaust mechanism according to one of claims 2 to 5, characterized in that the trigger wheel (22) is mounted coaxially and rotatably connected to a trigger cam (24) for periodically cooperating with the workpiece intermediate. 7. Exhaust mechanism according to claim 6, wherein the trigger wheel (22) comprises N teeth and the trip cam (24) n release members, characterized in that the exhaust is arranged to provide a pendulum pulse (10), every 2 x (N / n) alternations. 8. Exhaust mechanism according to claim 1, characterized in that the locking member (16) is disposed on the trigger wheel (22). 9. Exhaust mechanism according to claim 8, characterized in that the locking member (16) is formed of a stud (34) mounted projecting on the trigger wheel (22). 10. Exhaust mechanism according to claim 9, characterized in that the trigger wheel (22) is positioned by a jumper (28) cooperating with a structure (36) that comprises the trigger wheel (22), the jumper ( 28) and the structure (36) being configured so that the jumper (28) returns the trigger wheel (22) to a single predefined position, after actuation by the resilient pawl (30), in an oscillatory rotation. . 11. Exhaust mechanism according to claim 8, characterized in that the locking member (16) is formed by a plurality of studs (34), projecting and distributed over the trigger wheel (22). 12. Exhaust mechanism according to claim 11, characterized in that it comprises N / k pads (34) where N is the number of teeth of the trigger wheel (22) and where k is an integer> 1 and lower at N / 2. 13. Exhaust mechanism according to claim 12, characterized in that the trigger wheel (22) is positioned by a jumper (28) cooperating with a structure (36) that comprises the trigger wheel (22), the jumper ( 28) and the structure (36) being configured so that the jumper (28) positions the trigger wheel (22) at each step caused by actuation by the resilient pawl (30).