FR3073056A1 - COMPACT OSCILLATOR-EXHAUST SYSTEMS FOR WATCHES - Google Patents

Abstract

The present invention relates to oscillator-exhaust systems for watch movement. It makes it possible to reduce the volume occupied generally by these and to create non-cage, ultra-flat, tourbillon escapement-oscillator systems. In these systems, the axis of rotation of the oscillator (3) coincides with the axis of rotation of the escapement wheel (1). The peg (13) allowing the release and receiving the pulse is located on one of the components of the oscillator, the rod (9) of anchor with its fork and its dart is on the same side of the arms (8) supporting the entry and exit pallets.

Description

Technical area

The present invention relates to oscillator-escapement systems for a watch movement. It makes it possible to reduce the volume generally occupied by these and to use free exhausts. It allows the production of cage-free tourbillon escapement-exhaust systems.

State of the art

Mechanical movements for watchmaking use a regulating organ: the oscillator, and a distributor organ: the escapement.

In the wristwatch, the mechanical oscillator is generally a balance-spring and the distributor is a free escapement with anchor.

The escapements use a mobile equipped with a pinion driven by a gear train from the clockwork mechanism.

The exhaust mobile rotates along an axis parallel to the axis of the oscillator. The center distance may vary depending on the type of exhaust and its geometry. In the case of a standard anchor escapement, the wheel axis is offset outside the cylinder, showing the vertical projection of the outer crown of the balance wheel.

As part of a vortex, the volume swept by the cage increases the diameter and the height of the cylinder which displays the occupied volume.

Disclosure of invention

Depending on the free exhaust selected, the present invention allows the exhaust oscillator system to maintain its operation and performance while reducing the volume of the assembly.

In the context of the creation of a vortex, performance is improved due to the removal of the cage and its mass.

In these systems, the axis of rotation of the oscillator is coincident with the axis of rotation of the exhaust mobile. As part of an anchor escapement, the ankle allowing the release and receiving the impulse is located on one of the components of the oscillator, the anchor rod with its fork and its stinger is on the same side of the arms holding the input and output pallets.

Depending on the anchor escapement chosen, the geometry of the anchor is adapted by repositioning the rod with the fork and its stinger. The rod is no longer on the same plane as the arms supporting the pallets, the two planes are adjusted in height according to the positioning of the dowel and the escape wheel. The limiting stops are positioned at the level of the two arms holding the pallets.

The distance between the pivot axis of the anchor and the two coincident axes of the escapement wheel and of the balance, as well as the length of the anchor rod are resized according to the type of escapement used. If the escapement selected is of equidistant type, the pivot axis of the anchor is equidistant from the axis of the escapement wheel and the axis of the balance, the length of the rod of the anchor remaining identical to the rod of the anchor initially retained.

The architecture of these systems makes it possible to position the components of the exhaust oscillator on different planes.

The placing on the market of ceramic micro-ball bearings offers an optimum solution for the production of bearings: low friction and no lubrication. In its operation the pivoting is done either on the inner ring and the outer one is fixed or on the outer one and the inner ring is fixed.

Depending on the constraints imposed by the clockwork mechanism, different degrees of compactness are achievable. In all the cases described, the pivot bearings of the oscillator axis can be replaced by ceramic ball bearings.

As an assembly example, different non-limiting frameworks of use are possible.

The outer ring of the bearing is embedded in the frame, the pivoting is done on the inner ring secured to the exhaust mobile. The bearing associated with the exhaust mobile is located between the outer parts of the pivot bearings of the oscillator axis. The anchor works like a standard anchor.

In the case of using a pinion of the standard exhaust mobile, the inner ring is fixed and the exhaust mobile covers the outer ring which pivots. This makes it possible to have a remote pinion on the edge of the oscillator-exhaust system adapting to the characteristics of the mechanism retained.

Within the framework of a specific watch mechanism, the fixed inner ring is fitted on the outer part of one of the pivot bearings of the oscillator so as to offer a very thin solution. The exhaust mobile consisting of the wheel and its pinion is fitted on the outer ring of the bearing.

The creation of a whirlpool can be performed according to the principle of Albert Potter. The exhaust mobile fitted with a pinion supports the anchor. The anchor pivots around the escapement wheel which is fixed. The fundamental difference is that the Albert Potter vortex is made with a cage. In our case, this is no longer necessary, the hairspring can be attached directly to the exhaust mobile. For example, the extension of the pivot axis of the anchor can be used as a fixing.

The creation of a tourbillon can be carried out according to the principle of Achille Hubert Benoit. The impulse is transmitted to the hairspring. The escapement mobile is the wheel fitted with a pinion, the hairspring bolt is integral with the latter.

The possibilities according to the type of escapement retained which can be associated with the production of a tourbillon without cage are too important to be all dealt with in the context of this description which would not be exhaustive.

Brief description of the drawings

The drawing represents a section in perspective of an anchor escapement with the mobile provided with its pivoting aligned axially with the oscillator, the representative views of the volume occupied by current exhausts, the oscillator-exhaust system according to the description of the present invention. and several embodiments by way of examples.

- Figures 1 and 2 are views of an anchor escapement with the escapement movable provided with its pivoting aligned axially with the oscillator.

- Figures 3, 4, 5 and 6 are views which show the volumes occupied by the current anchor escapements according to the architectures used.

- Figures 7 and 8 are front and sectional views of Figure 2 with the exhaust mobile and its pivoting in different architectures.

- Figure 9 is a perspective view of Figure 8 according to the present invention.

- Figures 10, 11 and 12 are views of an embodiment of a compact anchor escapement oscillator according to the present invention.

- Figures 13, 14 and 15 are views of an embodiment of a tourbillon escapement oscillator without a pivoting anchor cage according to the present invention.

Mode (s) of carrying out the invention

- Figure 1 is a perspective sectional view of an oscillator-exhaust system with the exhaust mobile (1) provided with its pivot (2) positioned with the balance spring (5) and its axis (3) provided its pivot bearings (4) in the case of an equidistant anchor escapement whose rod (9) with its fork and its sting is inverted on the same side as the arms (8) holding the input and output pallets .

- Figure 2 is a front view in section of Figure 1.

- Figure 3 is a perspective view of a standard anchor escapement oscillator, the pivot axis of the wheel is offset outside the cylinder showing the vertical projection of the outer ring of the pendulum serge. The surface occupied on the stage following the vertical projection of the constituent elements of the escapement oscillator is significant.

- Figure 4 is a perspective view of a standard anchor-oscillator-exhaust system with its exhaust mobile, rotating on an axis provided with two pivots, axially aligned with the oscillator outside the plane passing through the external surface of the adjacent bearing of the oscillator. The height occupied by all the constituent elements of the escapement oscillator is significant.

- Figure 5 is a perspective view of the Albert Potter vortex with the cylinder located within the cage which shows the volume occupied by the oscillator provided with its bearings. The volume swept by the rotating cage is important.

- Figure 6 is a front view and a sectional view of Figure 5.

- Figure 7 shows a front view and a sectional view according to Figure 2 with the exhaust mobile which pivots with the outer ring of a ball bearing (2) whose inner ring is fitted on the outer part d 'a pivot bearing (4) of the oscillator.

- Figure 8 shows a front view and a sectional view according to Figure 2 with the exhaust mobile (11) which caps and pivots with the outer ring of a ball bearing (2) whose inner ring is fitted on the outer part of a pivot bearing (4) of the oscillator.

- Figure 9 is a perspective view of Figure 8 of an embodiment of an exhaust oscillator according to the present invention.

- Figures 10, 11 and 12 are views of an embodiment of a compact anchor-escapement oscillator according to the present invention, the exhaust mobile corresponds to the wheel (1) and its pinion in the case of a equidistant anchor escapement whose rod (9) with its fork and its sting is reversed on the same side as the arms (8) holding the input and output pallets, the limiting stops (10) are positioned at arm level , the measurement giving a total thickness of the oscillator-exhaust system is calculated with standard components: "Incabloc" shock-absorbing bearing in the manufacturer's catalog ...

- Figures 13, 14 and 15 are views of an embodiment of a tourbillon escapement-oscillator without a pivoting anchor cage according to the present invention, the exhaust mobile corresponds to the anchor (8, 9) and its support (12) which, driven by the pinion, pivot around the fixed escapement wheel, the stud (7) of the hairspring (6) is fixed as a stop at the end of the anchor axis of the support (12) to produce a tourbillon without cage, the measurement giving a total thickness of the oscillator-exhaust assembly is based on the same calculation as the previous embodiment.

Claims (12)

claims 1. Oscillator-escapement, for a watch movement, comprising, engaged with a gear train driven from an energy source of the timepiece, an escapement mobile, (1) provided with a pinion and its pivoting, whose axis of rotation coincides with the axis (3) of rotation of the oscillator, and characterized in that said exhaust mobile (1) comprises for bearing (2) a ball bearing. 2. Exhaust oscillator according to claim 1, characterized in that said ball bearing (2) has its inner bearing ring or its fixed outer bearing ring. 3. Exhaust oscillator according to claim 1, characterized in that the plane of rotation of said exhaust mobile (1) is located between the outer parts of the bearings (4) for pivoting the axis (3) of the oscillator or outside at one of the bearings (4). 4. Exhaust oscillator, according to claim 1, characterized in that said exhaust mobile (1) belongs to a free exhaust whose geometry of the components (1, 8, 9, 10, 13) is adapted to the coincidence of axes of rotation (2, 3) of said exhaust mobile (1) and of the oscillator. 5. Exhaust oscillator according to claims 1, characterized in that said ball bearing (2) has its fixed outer ring and is connected to the frame and its inner ring pivots the exhaust mobile (1). 6. Exhaust oscillator according to claims 1, characterized in that said ball bearing (2) has its fixed inner ring and connected to the frame and its outer ring capped by said exhaust mobile (1). 7. Exhaust oscillator according to claims 1, characterized in that said ball bearing (2) has its fixed inner ring and connected to the frame by the outer part of a bearing (4) of the oscillator. 8. Exhaust oscillator according to claim 4, characterized in that said exhaust consists of an exhaust mobile (1), an anchor (8, 9) whose arms (8) holding the pallets inlet and outlet are reversed on the same side as the rod (9) with its fork and its stinger and two stops (10). The arms (8) and the rod (9) are not on the same plane. 9. Exhaust oscillator, according to claim 4, characterized in that said exhaust (1, 8, 9, 10, 13) is composed of a pin (13) allowing the release and receiving the impulse from the anchor ( 8, 9). Said dowel is located on one of the components of the oscillator. 10. Exhaust oscillator according to claim 4, characterized in that said exhaust mobile (1) corresponds to the anchor (8, 9) and its support, which, driven by a pinion, pivot around the wheel d 'fixed exhaust, the stud (7) of the hairspring (6) is coupled to the exhaust mobile (1) to produce a tourbillon without cage. 11. Exhaust oscillator according to claim 4, characterized in that said exhaust mobile (1) corresponds to the escape wheel and its pinion coupled to the stud (7) of the hairspring (6) to produce an escapement with a vortex without cage, the impulse of which is transmitted to the balance spring. 12. Exhaust oscillator according to claim 8, characterized in that said anchor (8, 9) has stops (10) two elements placed near the arms (8) holding the entry and exit pallets.