CH711477B1 - Mechanical movement with an adjustable tourbillon. - Google Patents

Abstract

The present invention relates to a clockwork with a tourbillon unit, comprising: a plate, a bogie (1.03) connected to a second drive (1.21.3) and rotatably mounted on the plate, a balance wheel mounted on the bogie (1.03) and a balance wheel on the bogie (1.03) mounted escape wheel in operative connection with the balance, a balance stop device which can be brought into engagement with the balance, characterized in that it also has an adjustment device controlled from the outside by an actuating element for any angular alignment of said bogie (1.03).

Description

Technical area

The present invention relates to a mechanical clockwork with a tourbillon and a mechanical clock equipped therewith.

background

Tourbillons for mechanical watches and clockworks are well known. Here, the escape wheel, the armature and the so-called balance wheel of the clockwork are arranged on a bogie, which is coupled or firmly connected to the shaft of the seconds wheel, i.e. the seconds drive. The balance wheel or the balance wheel axis typically coincides with an imaginary axis extension of the second drive. A gear connected to the escape wheel meshes with a stationary gear arranged coaxially to the balance axis, so that the tourbillon, and therefore its frame, rotates one full revolution per minute.

For the precise setting of a mechanical watch with hands, it is necessary to stop the seconds display. In conventional watch movements, this is usually achieved by a so-called balance stop, which can be activated, for example, by pulling out a crown and deactivated again by pushing in the crown wheel.

In watches with a minute tourbillon, in which the seconds display is implemented directly by the bogie of the tourbillon, the implementation of such a balance stop is extremely difficult and complicated.

A balance stop for a tourbillon is known, for example, from EP 2 793 087 A1. This has a braking element that can be brought into engagement with the balance and is movable axially to the balance axis. In order to compare the watch with a time standard, it is thus possible to stop the balance and thus the tourbillon mechanism at will.

Summary of the invention

In contrast, the present invention is based on the object of providing an improved balance stop for a tourbillon of a mechanical watch. In addition to stopping the tourbillon, any desired angular orientation of the tourbillon should also be implemented. This is intended to provide an increased range of functions, in which, for example, the position of the bogie in relation to the gear train and thus the pointer train can be readjusted or adjusted at any time.

This object is achieved with a clockwork with a tourbillon unit according to independent claim 1 and with a clock according to claim 14 having such a clockwork. Advantageous configurations are the subject of dependent claims.

The invention makes it possible for the first time to move an entire tourbillon independently of its escapement part in the clockwork controlled from the outside. This independent movement enables a tourbillon to be rotated more quickly to a movable point in any of its possible positions. This option can be used to set the time to the second or for other functions, such as short-term measurements using the tourbillon.

The present movement is further provided with a balance stop device which can be brought into engagement with the balance wheel. By means of the balance stop device, the balance can be fixed at least temporarily for stopping the clockwork relative to the plate or relative to the frame. Furthermore, the movement is provided with a fixed gear unit that can be switched off, which allows the angular alignment of the frame to be set in any position. According to a preferred embodiment, the disengageable fixed wheel unit can optionally be brought into engagement with the frame or with the plate in a rotationally fixed manner; the fixed gear unit, which can be switched off, is typically in non-rotatably engaged engagement with the circuit board during normal operation of the clock.

That is, the disengageable fixed wheel unit is fixed relative to or on the board, while the frame together with the entire tourbillon unit is subjected to a rotary movement relative to the board. When the clockwork is stopped, the fixed gear unit, which can be switched off, can also be detached from the plate or decoupled by rotating it so that it can be rotated relative to the plate. It is typically in rotationally fixed engagement with the frame. The fixed gear unit, which can be switched off, is thus preferably always either in a rotationally fixed engagement with the frame or in a rotationally fixed engagement with the plate or even in a rotationally fixed engagement with both the frame and the plate.

In order to enable the setting of the angular position of the bogie, it is also necessary to decouple the tourbillon drive at least temporarily from the energy storage device of the clockwork. A coupling device for the second drive is preferably available for this purpose.

The present clockwork is coupled to an adjustment mechanism which is controlled, for example, by a winding or adjustment crown of the clockwork. By successively and step-by-step pulling out the crown, you can choose between 3 different operating modes, in which the winding crown has a specific function, namely winding the barrel, setting the pointer and setting the tourbillon.

According to a preferred embodiment of the claimed clockwork, where the crown can be in three different axial positions, the first, in which, for example, a barrel can be wound through the crown as usual, is the so-called rest position; in the second position the balance wheel is stopped, e.g. as in accordance with the solution of EP2793087, and thus the pointer position is possible; finally in the third axial position, in which the disengageable fixed gear unit is no longer in engagement with the plate but now with the frame, the tourbillon is also decoupled from the gear train at the same time so that the angular alignment is made possible by turning the crown.

[0014] Preferably, a minute detent can also be present, including pointer trituration in a minute wheel assembly similar to that shown in patent EP2224294; for this, however, the tourbillon drive should preferably be designed in two parts, a first part being coupled to the drive, and the other part being adjustable thanks to a second toothing that is non-rotatable with the frame, so that the synchronization with the minute display is not lost.

According to a further development it is provided that the existing control mechanism, which determines the respective functions of the crown, has a camshaft with 3 superposed cams that intervene on three different circuit diagrams, and each the balance stop, the release of the holding lever for the switchable The fixed gear unit and the decoupling of the second drive cause. The balance stop preferably takes place in the second position of the crown, with both the release of the holding lever and the decoupling of the second drive take place at the same time when the crown is pulled from the second position to the third position.

According to a further embodiment, the disengageable fixed wheel unit has a carrier wheel with a rim-like rotating ring. The circumferential ring is rotatably mounted on at least three bearing rollers arranged on the plate. The fixed gear unit, which can be switched off, has, in particular, a ring-like basic geometry. In a final assembly configuration of the clockwork, the hub of the tourbillon unit typically extends through the free ring center of the fixed gear unit that can be switched off. By means of a mounting over the outer circumference on the carrier wheel, the fixed wheel unit, which can be switched off, can also be rotated on the plate independently of the hub of the tourbillon unit. In order to set the angular alignment of the tourbillon unit as desired, the disengageable fixed gear unit also has external teeth which engage with an adjusting wheel controlled by the winding crown in the third pulled position of the winding crown.

According to a further embodiment, the disengageable fixed gear unit has a ring-like planetary gear with internal teeth that mesh with a pinion of the escape wheel. The rotating wheel of the disengageable fixed wheel unit, which is also fixed relative to the plate in the basic configuration or when the clockwork is running, meshes with the escape wheel. The escape wheel moves, in particular due to the toothing of its pinion with the internal toothing, along that internal toothing when the tourbillon unit is subject to a rotary movement that is predominant during operation of the clockwork. In the basic configuration, the fixed gear unit, which can be switched off, functions as an extended circuit board, the internal toothing of which is followed by the escape wheel with its pinion.

According to a further embodiment of the clockwork, the disengageable fixed gear unit has a stop ring which is axially movable with respect to its axis of rotation. This has on a radially outer edge a run-up bevel which corresponds to a run-up bevel of a balance stop lever movably arranged on the plate. Typically two diametrically opposed balance stop levers are provided. When the crown is pulled out, these can experience a radially inward movement in the direction of the stop ring.

By means of the mutually corresponding and mutually coordinated run-up bevels of the stop ring and balance stop lever, the stop ring experiences an axial movement when the balance stop lever is moved radially inward. A radial movement can thus be converted into an axial movement by means of the mutually corresponding run-up bevels of the stop ring and balance stop levers.

According to a further embodiment, that axially movably mounted stop ring on the disengageable fixed gear unit on a radially inner edge has a further run-up bevel which interacts with at least one cam at least one pawl mounted radially inwardly against a restoring force on the disengageable fixed gear unit. In this way, by axially displacing the stop ring with respect to the disengageable fixed gear unit, in particular with respect to the at least one pawl mounted axially adjacent thereto, that pawl can be pivoted radially.

It is provided in particular that the at least one pawl of the disengageable fixed gear unit can be deflected radially inward by an axial movement of the stop ring induced by means of the at least one balance stop lever. The mutual engagement of balance stop lever, stop ring and pawl of the disengageable fixed gear unit can ensure that a pivoting movement acting radially from the outside on the disengageable fixed gear unit is converted into a pivoting movement of a pawl provided radially on the inside on the disengageable fixed gear unit.

According to a further embodiment, the at least one pawl has at its radially inner end a run-on bevel which can be brought into engagement with a run-on bevel of a brake ring. The brake ring is typically arranged axially adjacent to the pawl and is also mounted axially displaceably with respect to the disengageable fixed wheel unit on a main axis of the tourbillon unit, for example on the hub of the tourbillon unit. Since the at least one pawl and the brake ring engaging with it have mutually corresponding run-up bevels, the typically radially inwardly directed pivoting or adjustment movement of the pawl can be converted into an axially directed displacement movement of the brake ring.

According to a further embodiment of this, it is finally provided that a brake pin is axially movably guided in a hub of the tourbillon unit or in the frame and is axially displaceable by means of the brake ring to deflect the brake element and to stop the balance. The brake bolt can be displaced axially to the brake ring in particular against a restoring force, in particular against the action of a spring element. In particular, the brake bolt deflects the brake element, which is axially movable to the balance axis, in such a way that it frictionally or frictionally engages the balance and ultimately stops the balance.

On the disengageable fixed gear unit is typically not just one, but several, approximately three pawls arranged equidistantly from one another in the circumferential direction, which perform a synchronous, radially inward movement as a result of an axial movement of the stop ring arranged next to it. Accordingly, a displacement force that is as uniform and symmetrical as possible can be exerted on the brake ring, which ultimately leads to the axial advance of the brake bolt.

Regardless of the fixed gear unit, which can be switched off, the tourbillon drive can be decoupled similarly with the aid of an inwardly controlled pivoting movement of clutch levers, which, for example, is preferably actuated by pulling out the winding crown from the second to the third axial position, and one Axial downward displacement of the second drive is effected so that it is no longer in engagement with a coupling attachment of the tourbillon drive. The tourbillon drive is thus decoupled from the drive force of the drive. However, as soon as the crown is moved back into the second axial position, the second drive is pressed again against the coupling shoulder due to the restoring force exerted by the coupling spring, and the coupling between them is restored.

According to a further aspect, a clock, in particular a mechanical wristwatch, is finally provided, which is equipped with a clockwork described above.

Brief description of the figures

Further goals, features and advantageous configurations are explained in the following description of an exemplary embodiment with reference to the drawings. 1 shows a plan view of parts of the clockwork from the dial side, FIG. 2 shows a plan view of parts of the clockwork from the bridge side according to FIG. 1, FIG. 3 shows an exploded view of the tourbillon unit of the clockwork with the disengageable fixed gear unit and the tourbillon drive ; 4 shows a cross section through the tourbillon unit according to FIG. 3, FIG. 5 shows an exploded view of the disengageable fixed gear unit, FIG. 6A shows a plan view of the control mechanism actuated by the winding crown in the basic configuration (winding position), and FIG. 6B shows a cross section through the tourbillon unit in FIG this basic configuration; 7A shows a plan view of the control mechanism actuated by the winding crown in the first pulled position (pointer position), and FIG. 7B shows a cross section through the tourbillon unit in this second operating mode; 8A shows a plan view of the control mechanism actuated by the winding crown in the second pulled position of the winding crown (pointer position), and FIG. 8B shows a cross section through the tourbillon unit in this third operating mode; Fig. 9 A view of the tourbillon unit of the clockwork, with the disengageable fixed gear unit and the tourbillon drive from below, whereby the inner pivoting movement of the balance stop lever & the pawls, the outer pivoting movement of the holding lever, and the downward axial movement of the seconds drive are emphasized during the setting process of the bogie ; 10A shows a cross section through the drive between the barrel and the tourbillon unit according to the preferred embodiment for an adjustable tourbillon with a minute notch from FIG. 10A, 10B show a cross section through the running gear between the barrel and the minute barrel according to a preferred embodiment for an adjustable tourbillon which also has a minute detent.

Detailed description

The present movement is composed like a classic movement with tourbillon, which is also described with a balance stop device (which is often referred to as "stop second") as already described in the invention EP2793087 "balance stop in the flying tourbillon" by the same applicant . The tourbillon unit 1 has the same structure as a normal tourbillon, ie with a bogie 1.03 driven by a tourbillon drive, which is also provided with an arrow 1.031 for the seconds display, and in which a balance wheel 1.01 or balance spring 1.01a and escape wheel 1.04 are arranged . The tourbillon unit 1 is now preferably expanded with a so-called disengageable fixed gear unit 1.10, and the tourbillon drive 1.21 is supplemented by a clutch.

Figures 1 & 2 each show a complete view from above and below of the entire clockwork, which represents both the supplemented tourbillon unit 1 and the winding and pointer setting mechanism, and the circuit for the stop second and further to setting the tourbillon. All setting functions are carried out here by turning a winding crown, although only the winding crown shaft 6.1 is illustrated. The winding crown shaft 6.1 has 3 axial positions, each defining a specific operating mode, which are further explained in detail by FIGS. 6 A / B, 7A / B and 8A / B. However, a pusher could alternatively be provided as an external actuating element, in particular for the present setting device for the tourbillon unit.

According to the preferred embodiment shown, the present movement has a three-stage winding mechanism, as is customary for watches with quick date adjustment via the winding crown. Here a variant with an adjusting lever 6.3, on which a first pointer adjusting wheel 6.4 is mounted, was chosen.

A toothing on the angle lever 6.2 transmits the three possible axial positions of the winding shaft 6.1 to a camshaft 5, which has a gear 5.1 which cooperates with a toothing of the angle lever 6.2. The camshaft 5 is composed of a first cam 5.2 for the balance stop lever (2.1,2.2), a second cam 5.3 for the retaining lever 3, and a third cam 5.4 for the clutch lever 4.1, 4.2 and the gearwheel 5.1 for the camshaft 5. By means of the respective cams, the balance stop levers 2.1 & 2.2, the clutch levers 4.1 & 4.2 and the retaining lever 3 are opened and closed against their respective springs (i.e. reference numbers 2.3, 4.3, and 3.3) according to the respective function via the respective reversing levers 2.4, 3.4, 4.4 .

In the winding mechanism 6 are also, as usual, another clutch lever 6.6 for the elevator of the barrel 9, a spring 6.5 for the angle lever 6.2, so that it is always in the same rest position in the basic configuration, ie the first axial position of the winding shaft 6.1 , is located, and otherwise an ordinary clutch drive 6.7 and an ordinary elevator pinion 6.8.

For the pointer position in the second axial position of the winding shaft 6.1 a first gear chain is available, which can be brought with a toothing of the clutch drive 6.7 first pointer setting wheel 6.4 via a second and third pointer setting wheel - each with reference numbers 25.26 - then with the Comb hour wheel 29 and minute wheel 8.

For the setting of the tourbillon in the second axial position of the winding shaft 6.1, a second gear chain is also present, which here also from the first pointer setting wheel 6.4, which can be brought with a toothing of the clutch drive 6.7, via two tourbillon setting wheels arranged on top of one another - each with reference numbers 12,13 - then mesh with a second tourbillon adjusting wheel 11 and a first tourbillon adjusting wheel 10, which ultimately engages in the external toothing 1.10.1 of the disengageable fixed wheel unit 1.10. A rotary movement of the winding crown in this third axial position can thus be transmitted to the fixed gear unit 1.10 which can be switched off; such a transmission chain thus offers a preferred embodiment for the claimed adjustment device according to the present invention. Those of ordinary skill in the art will understand that a different number of tourbillon wheels are possible and the gear ratios between these wheels can be adapted. It would also be possible to arrange the first tourbillon setting wheel 10 in direct engagement with the bogie; the illustrated preferred variant, however, offers an aesthetic advantage since the adjustment device can be completely hidden under the bogie.

Figure 3 shows an exploded view of the tourbillon unit 1 of the clockwork, which highlights the structure of the disengageable fixed gear unit 1.10 and the tourbillon drive 1.21. The bogie 1.03 of the tourbillon unit 1, driven by the tourbillon drive 1.21, should, via the escapement with the escape wheel 1.04, the pinion 1.04 of which meshes with the internal toothing 1.10.2 of the disengageable fixed gear unit 1.10, rotate the planetary gear 1.14 in the disengageable fixed gear unit 1.10 with one rotation in 60 seconds (one minute) with the arrow 1.031 indicating the seconds. The disengageable fixed wheel unit 1.10 is therefore considered a fixed wheel for the tourbillon unit as long as a retaining lever 3 (not shown in this figure) presses on the rotating ring 1.12 of the rotating wheel 1.14, and ensures that it remains rotationally fixed with the plate 2.

The pawls 1.18, the stop ring 1.11, the two bolts 1.06 and 1.07, the hub 1.22, the expanding spring 1.09 and the ring 1.08 belong to a preferred embodiment of a balance stop device, as published in patent application EP2793087 "Balance stop in the flying tourbillon", and is therefore not further described.

The tourbillon drive 1.21 is no longer formed in one piece, but consists of several parts in order to enable decoupling with the second drive 1.21.3. The tourbillon drive is rotatably mounted on a holding pad 1.31 and rotates around the axis of rotation 1.20 of the entire tourbillon unit 1, which also corresponds to that of the balance wheel 1.01 and the disengageable fixed gear unit 1.10. It contains a shaft 1.21, a coupling attachment, and a second drive 1.21.3, which has a bevel to simplify the cooperation with the coupling lever 4.1, 4.2. The second drive 1.21.3 is axially displaceable along the axis of rotation 1.20 and is mounted on a clutch spring 1.21.4, which is supported on a clutch spring bearing 1.21.5. According to the illustrated preferred embodiment, there is a friction clutch between the second drive 1.21.3 and the clutch attachment 1.21.2; however, interlocking toothings could also be provided for the transmission of the respective rotary movement between these two parts.

FIG. 4 shows a cross section through the tourbillon unit 1, which has a balance stop device, as published in the patent application EP2793087 “Balance stop in the flying tourbillon”. Such a construction is a prerequisite for enabling the rotary movement of the bogie 1.03 of the tourbillon unit 1. Now, however, the tourbillon unit 1 is extended with a fixed gear unit 1.10 which can be switched off and which interacts with a tourbillon setting wheel 10, and also with a coupling device 4 which is intended to ensure that the tourbillon drive 1.21 is decoupled from the drive when the bogie 1.03 is set.

The coupling device 4 includes two coupling levers 4.1 and 4.2, each of which has a bevel 4.1a and 4.2a, and interact with the upper bevel 1.21.3a of the second drive 1.21.3. When the winding crown is pulled out from the second to the third axial position, the clutch levers 4.1 & 4.2 swivel inwards, which then presses the second drive 1.21.3 downwards and interrupts the friction clutch with the clutch attachment 1.21.2, as shown later in Figures 8A / 8B visible.

The multi-part structure of the fixed gear unit 1.10 which can be switched off is illustrated with reference to FIG. The fixed gear unit 1.10, which can be switched off, has a planetary gear 1.14 which has a through opening in the center, which is delimited by an inner edge, and from which pawls 1.18 arranged in a distributed manner protrude radially inward. These are rotatably or pivotably mounted in the plane of the planet wheel 1.14 and can be deflected radially inward.

Each of the three pawls shown here 1.18 has at its free and inwardly protruding end a control bevel 1.18a. A dome-like pawl cam 1.18b is formed on the underside of the pawls 1.18. Furthermore, each of the pawls 1.18 is coupled to a pawl spring 1.19, by means of which the individual pawls 1.18 can be deflected radially inward against a spring force. The deflection directed radially inward takes place via an axial force acting on the pawl cams 1.18b. When the force decreases, the individual pawl springs 1.19 cause the pawls 1.18 to move radially outward, into the starting position shown in FIG. 4.

On the radially outer edge of the disengageable fixed gear unit 1.10, as shown in FIG. 5, a circumferential ring 1.12 is formed. Axially offset to this, the disengageable fixed gear unit 1.10 has external gearing 1.10.1. A planet wheel 1.14 is arranged on the top of the fixed gear unit, which can be switched off. The planet wheel 1.14 also has an annular contour. A circumferential internal toothing 1.10.2 is formed on an inner side of the planet wheel 1.14, which, as already mentioned, meshes with the pinion 1.04a of the escape wheel.

A stop ring 1.11 is also attached to the underside of the disengageable fixed gear unit 1.10. The stop ring 1.11 has on its outer edge an outer run-up bevel 1.11a which can interact with the respective run-up bevels 2.1a and 2.2a of the balance stop lever. In addition, the stop ring 1.11 is axially displaceable and, as shown in FIG. 4, also has a further inner bevel 1.11b which can interact with the pawl cams 1.18b.

Due to the axial displaceability of the stop ring 1.11, the inner run-up bevel 1.11b of the stop ring 1.11 can with the pawl cams when the winding crown is pulled out of its first axial rest position in the second axial position, which cause a pivoting movement of the two balance stop levers 2.1 and 2.2 1.18b come into engagement. An upward axial movement of the stop ring 1.11 thus causes a radially inward deflection of the three pawls 1.18, which moves the brake ring 1.08 and the bolts 1.06 fixed to it upwards, and accordingly presses the brake spring 1.05 against the double roller 1.02 of the balance wheel 1.01, so that its free end comes into engagement in a frictional manner and in the axial direction with a correspondingly configured friction surface of a double roller 1.02, which is connected to the balance wheel 15. In this way, the balance 15 can be stopped and fixed with respect to the bogie 1.03.

The brake bolt 1.06 can be transferred from the starting or basic position shown in FIG. 4 into the braking position shown in FIGS. 7A / B by means of the axially displaceably mounted brake ring 1.08. Radially on the outside and at the lower end, the brake ring 1.08 has a run-on bevel 1.08a, which is designed circumferentially and is designed to correspond to the control run-up bevel 1.18a of the pawls 1.18. A radially inward pivoting movement of the pawls 1.18 thus leads to an upward axial displacement of the brake ring 1.08 in the direction of the bogie 1.03, as a result of which the brake pin 1.06 and thus also the brake spring 1.05 are axially displaced or axially deflected. Due to the radially inward pivoting movement of the pawls 1.18, the brake spring 1.05 finally engages with the double roller 1.02 of the balance wheel 1.01.

The axial displacement of the brake ring 1.08 relative to the hub 1.22 or relative to the bogie 1.03 takes place against the restoring force of a spreading spring 1.09 which is arranged axially between the hub 1.22 and the brake ring 1.08 (see also FIG. 3). If, for example, the pawls 1.18 are pivoted back into the starting position shown in FIG. 4 under the action of their respective pawl springs 1.19, the braking ring 1.08 also moves into its starting position shown in FIG. 4 under the action of the expanding spring 1.09. As a result, the balance wheel 1.01 is released again, whereby the stopped clockwork starts up again automatically.

To stop the clockwork and the tourbillon unit 1, two opposing, first and second balance stop levers 2.1, 2.2 are provided on the outer circumference of the disengageable fixed gear unit 1.10, which are visible in FIGS. 1, 2 and 4. The first balance stop lever and the second balance stop lever 2.2 are pivotably mounted on the plate 2. A first bevel 2.1a and a second bevel 2.2a are provided at each of their free ends. These are designed, for example, in the form of conical wheels. The first and second bevels 2.1a & 2.2a of the first and second balance stop levers 2.1, 2.2 are located at the level of the outer bevel 1.11a provided on the outer edge of the stop ring 1.11.

A radially inward pivoting of the first and second balance stop lever 2.1, 2.2 leads to a uniform lifting or axial displacement of the stop ring 1.11 from the starting position or basic configuration shown in Fig. 4 into the stop configuration shown in Fig. 7A / B. The axial movement of the stop ring 1.11 leads, as already described, to the radially inward deflection of the pawls 1.18 and thus to an axial displacement of the brake pin 1.06 and ultimately to a deflection of the brake spring 1.05 that sustains the balance wheel 1.01.

The synchronous pivoting movement of the two first and second balance stop levers 2.1, 2.2 which brings about a stop of the clockwork 1 can be effected by pulling out a crown into a predetermined detent position. The clockwork is thus stopped. If the winding crown, which is not explicitly shown in the present case, is pulled out from that stop configuration into a further, for example, a second detent position, this causes a coupled pivoting of the holding lever 3, as shown in FIGS. 8A / B.

The fixed gear unit 1.10, which can be switched off, can be releasably fixed on the circuit board 2 via a fixing element, which in the present case is designed as a holding lever 3. A free end of the holding lever 3 is, for example, frictionally engaged with an outer edge of the disengageable fixed wheel unit 1.10, for example on the rotating ring 1.12.

By a pivoting movement of the holding lever 3, the disengageable fixed wheel unit 1.10 can be released so that it can be rotated relative to the board 2 with respect to the central axis of rotation 1.20. The axis of rotation 1.20 of the disengageable fixed gear unit 1.10 can in particular preferably coincide with the balance axis as well as with the axis of the seconds drive 1.21.3 (and generally also of the tourbillon drive 1.21).

For the setting of the tourbillon via the disengageable fixed wheel unit 1.10, according to the preferred embodiment of the present invention, a mechanism with holding and coupling levers is required. In the following this mechanism, which is controlled via a cam circuit from the angle lever of the elevator mechanism, is shown The setting of the hands and the tourbillon is also operated via the winding crown.

FIGS. 6A & 6B each show two views in the basic configuration of the clockwork, where the barrel 9 of the clock is wound over the winding crown. This corresponds to the first axial position for the winding crown.

It should be noted that FIG. 6A actually corresponds exactly to FIG. 4 already described.

In this configuration, the balance stop levers 2.1 and 2.2 are opened against the spring force of the spring 2.3 by the deflection on the first cam 5.2. The stop ring 1.11 on the disengageable fixed gear unit 1.10 is pressed down by opening the pawl 1.18. The brake spring 1.05 rests on the bogie 1.03 and the balance wheel 1.01 can move freely.

The coupling levers 4.1 and 4.2 are deflected by the third cam 5.4 via the reversing lever 4.4 against the force of the spring 4.3. The coupling between the second drive 1.21.3 and the coupling attachment 1.21.2 is closed so that the rotary movement from the small third wheel 7 can be transferred to the balance wheel 1.01 in the bogie 1.03 by the tourbillon drive 1.21. The holding lever 3 does not experience any deflection and fixes the disengageable fixed wheel unit 1.10 by the force of the spring 3.3. The tourbillon can run on the internal teeth of the disengageable fixed gear unit 1.10 like any conventional tourbillon. The position of the winding shaft decouples the winding mechanism 6.7 of the winding mechanism from the first pointer adjusting wheel 6.4 through the adjusting lever 6.3 and the coupling lever 6.6, and a rotary movement of the winding shaft 6.1 causes the winding of the barrel 9 by the winding pinion 6.8.

FIGS. 7A and 7B each show two identical views of the movement as in FIGS. 6A / 6B, but now in the balance-stop and pointer position position, i.e. when the winding crown is in the second axial position.

Now the winding shaft 6.1 is pulled out one step away from the clockwork.

Angle lever 6.2 and clutch lever 6.6 allow the clutch drive 6.7 to engage in the first pointer setting wheel 6.4. The coupling of the clutch drive 6.7 to the elevator of the barrel (crown wheel) is interrupted. The first pointer setting wheel 6.4, which is in engagement with the second pointer setting wheel 25, can be used to set in the gear chain: third pointer setting wheel 26 - change gear 27 - hour wheel 29 and the minute tube 28a, and thus the pointer mechanism.

The camshaft 5 was rotated accordingly via the toothing on the angle lever 6.2. The first cam 5.2 now releases the reversing lever 2.4 for stopping the balance. The spring 2.3 presses the two balance stop levers 2.1 and 2.2 together, so that the stop ring 1.11 is pushed upwards and the three pawls 1.18 are deflected inwards. The pawls 1.18 lift the brake ring 1.08. This in turn presses against the brake spring 1.05 via the bolt 1.06. The brake spring 1.05 presses against the double roller 1.02 on the balance wheel 1.01 and thereby stops it. The tourbillon is stopped and at the same time held in place by the three pawls 1.18 in the disengageable fixed wheel unit 1.10. The holding lever 3 and the coupling levers 4.1 and 4.2 remain unchanged so far.

If the winding shaft 6.1 is pushed back into its basic position (ie the position illustrated by FIGS. 6A / 6B), the balance stop levers 2.1 and 2.2 are opened again and ultimately the balance 1.01 is released again so that the tourbillon continues to run can.

Figures 8A & 8B each show two identical views of the movement as in Figures 6A / 6B & 7A / 7B, but now in the setting position for the tourbillon unit 1.10, i.e. when the winding crown is in the third axial position.

In this position, the winding shaft 6.1 is pulled further to its 3rd position, and thus the adjusting lever 6.3, guided by the pin of the angle lever 6.2 in the guide groove in the adjusting lever 6.3, moves the first pointer setting wheel 6.4 away from the second pointer setting wheel 25 to engage in the fourth tourbillon adjusting wheel 13. When the angle lever 6.2 is moved to this third axial position, the third cam 5.4 first releases the reversing lever 4.4 for the coupling levers 4.1 & 4.2. This reversing lever 4.4 closes the coupling levers 4.1 and 4.2 by the force of the spring 4.3 against the second drive 1.21.3 and against the spring 1.21.4 to the holding pad 1.31 on the wheel bridge 20. The spring 4.3 provides so much force that by the engagement of the clutch levers 4.1 and 4.2, the second drive 1.21 is held firmly and at the same time is pressed firmly against the holding pad 1.31. This must be coordinated in such a way that the braking effect generated is held securely against the torque from the small third wheel 7. Only after the second drive 1.21.3 on the tourbillon drive 1.21 is safely on the brakes, the reversing lever 3.4 for the holding lever 3 is deflected by the second cam 5.3 and opens the holding lever 3 against the spring 3.3. The disengageable fixed gear unit 1.10 can now be rotated with the entire tourbillon, i.e. in particular the bogie 1.03 in the clockwork, detached from the gear train. The locking point for the third position of the angle lever 6.2 is finally reached. The third tourbillon setting wheel 13 is connected to the second tourbillon setting wheel 11 in a rotationally fixed manner, and via the gear chain of the tourbillon setting wheels 4 to 1, i.e. the tourbillon setting wheels shown with reference numbers 13 - 12 - 11 - and 10, the disengageable fixed gear unit 1.10 and thus the entire tourbillon unit 1 with fixed balance wheel 1.01 can be rotated to the desired position in both directions with the help of the winding shaft.

FIG. 9 is a view of the tourbillon unit 1 of the movement of the present invention, which shows both the inner pivoting movement of the balance stop lever 2.1, 2.2 & the pawls 1.18, the outer pivoting movement of the holding lever 3, and the axial movement of the second drive 1.21.3 downwards highlights in the setting procedure of the bogie. This also provides a summary for switching between the different operating modes of the clockwork, depending on the axial position of the winding shaft 6.1 of the winding crown. Namely, the inner pivoting movement of the two balance stop levers 2.1 & 2.2 (arrow A) when changing the axial position of the winding shaft from the first axial position to the second position is illustrated. This pivoting movement also causes an inner pivoting movement of the two pawls 1.18 (arrow A '), which activates the balance stop device. When changing from the second axial position to the third axial position of the crown, there is an inner pivoting movement of the coupling levers 4.1 & 4.2 (arrow B), which in an axial movement of the second drive 1.21.3 downwards (arrow D for decoupling from the tourbillon drive) is implemented, as well as an external pivoting movement of the holding lever 3 (arrow C).

Further alternative options are available in the manner of operation. It is possible to arrange the mechanism in such a way that the tourbillon can be in the 2nd position of the winding shaft and the pointer in the 3rd position of the winding shaft. Combinations with handle operation are also conceivable.

Finally, FIGS. 10A and 10B provide an illustration of a particularly preferred embodiment for the adjustable tourbillon, which also has a coupled minute display. 10A is a cross section through the drive between the barrel and the tourbillon unit, the tourbillon drive of which has a second torsion-proof toothing, and FIG. 10B is a cross section through the drive between the barrel and the minute barrel, which has the minute detent, according to the same preferred embodiment for an adjustable tourbillon with a minute notch.

The example shown by FIGS. 1-9 has no coupling to the minute display. When setting the pointer, the minute tube 28a is simply rotated to the minute drive of the minute wheel 8, quite conventionally, against a frictional resistance.

However, it is possible to expand this invention with the coupled minute detent, similar to patent EP2224294 “Mechanism for setting the minute hand for an automatic zero position of the second hand”. For this, only the tourbillon drive has to be equipped with a second, non-rotating toothing. A fixed translation of the displayed second of the minute tourbillon and the displayed minute can be produced via a double toothing on the third wheel, which is connected via a friction clutch and a minute wheel with the locking device as described in patent EP2224294 by the same applicant.

Instead of the second drive for an ordinary clockwork without a tourbillon, the tourbillon drive 1.21 must be designed in two parts, so that it also has a second fixed toothing 1.21a that meshes with an upper pinion 7a. In the present description of the adjustable tourbillon, the frictional connection between the retaining lining 1.31, clutch drive 1.21 and the clutch lever 4.1 & 4.2 prevents uncontrolled unclamping of the drive when the tourbillon is disengaged in the setting function. The structure of the small third wheel 7 has an upper, adjustable small third wheel 7a, and a lower, lower small third wheel 7b arranged in the power flow with the barrel 9, the two small third wheel being coupled to one another with a friction clutch 7c. In contrast, the central minute wheel 28 has a minute notch 28c instead of a friction clutch between an upper minute wheel 28a, which corresponds to the minute tube, and a lower minute wheel 28b.

Such an arrangement makes it possible to stop the drive, to block it, to release the tourbillon and to create a connection from the tourbillon to the centric minute wheel 28, which is released from the fixed drive. If the tourbillon is coupled into the drive again and the drive runs normally, the central minute wheel 28 must be connected to the drive again; this is done here again by the friction clutch 7c in the third wheel 7.

Through the interaction of a disengageable fixed gear unit 1.10 and a clutch in the tourbillon drive 1.21, also with an existing advantageous balance stop device, it is possible for the first time to move an entire tourbillon unit 1 independently of the escapement in the clockwork controlled by an external actuator. That independent movement enables a tourbillon unit 1 to move more quickly and automatically to a reference point in any conceivable position. This option is particularly suitable for a so-called minute tourbillon, which also serves as a seconds display.

It is particularly advantageous here that no radial forces act on tourbillon unit 1, neither when the balance wheel 1.01 is stopped, nor during the adjustment process. The escapement is stopped during the adjustment process and is thus protected against external influences. Furthermore, the configuration of the adjustment device with the balance stop device shown here enables a small structural intervention in an existing flying tourbillon, as is known, for example, from EP 2 793 087 A1. The tourbillon adjusting wheels, which are responsible for setting the angular alignment, can also be easily hidden under the bogie for aesthetic reasons.

List of reference symbols

1 tourbillon unit 1.01 balance wheel 1.01a balance spring 1.02 double roller 1.03 bogie 1.031 arrow for second display 1.04 escape wheel 1.04a pinion of escape wheel 1.05 brake spring 1.06 bolt 1 1.07 bolt 2 1.08 brake ring 1.08a bevel of brake ring 1.09 expansion spring 1.10 disengageable fixed gear unit 1.10.1 outer toothing of the Disengageable fixed gear unit 1.10.2 Internal toothing of the disengageable fixed gear unit 1.11 Stop ring 11.1a Outer bevel of the stop ring 1.11 11.1b Inner bevel of the stop ring 1.11 1.12 Circumferential ring 1.14 Circular wheel 1.18 Pawl 1.18a Control bevel of the pawl 1.21a 1.18b Pawl cams 1.19 Rotary axis Pawl spring 1.21a 1.18b Pawl cams Toothing 1.21.1 Shaft 1.21.2 Clutch attachment 1.21.3 Second drive 1.21.3a Starting bevel of the second drive 1.21.4 Clutch spring 1.21.5 Clutch spring bearing 1.22 Hub 1.31 Holding pad 2 Plate 2.1 Balance stop lever 1 2.1a Starting bevel of the Balance stop lever 1 2.2 Balance stop lever 2 2.2a Starting bevel of the balance stop lever 2 2.3 Spring for balance stop lever 2.4 Deflection lever for balance stop 20 Wheel bridge 3 Holding lever 3.3 Spring for holding lever 3.4 Deflection lever for holding lever 4 Coupling device 4.1 Clutch lever 1 4.1a Starting bevel of the clutch lever 1 4.2 Starting bevel of the clutch lever 2 4.2 2 4.3 Spring for the clutch lever 4.4 Deflection lever for the clutch lever 5 Camshaft 5.1 Gear on the camshaft 5.2 Cam 1 for balance stop 5.3 Cam 2 for holding lever 5.4 Cam 3 for coupling the tourbillon drive 6 Winding mechanism 6.1 Winding shaft 6.2 Angle lever 6.3 Adjusting lever 6.4 Pointer adjusting wheel 1 6.5 Angle lever spring 6.6 Clutch lever 3 (for the elevator) 6.7 Clutch drive 6.8 Elevator pinion 7 Third wheel 7a Upper third wheel 7b Lower third wheel 7c Friction clutch Third wheel 8 Minute wheel 9 Spring barrel 10 Tourbillon wheel 1 11 Tourbillon wheel 2 12 Tourbillon wheel 3 13 Tourbillon wheel 4 25 Hand wheel 2 26 Hand wheel 3 27 Change wheel 28 Centric minute wheel 28a Upper minute wheel (minute tube) 28b Lower minute wheel 28c Notch minute wheel 29 Hour wheel (A) Inner pivoting movement of the two balance stop levers 2.1 & 2.2 (A ') Inner pivoting movement of the two pawls 1.18 (B ) Inner pivoting movement of the coupling levers 4.1 & 4.2 (C) Outer pivoting movement of the holding lever 3 (D) Axial movement of the second drive 1.21.3 downwards (decoupling)

Claims (14)

1. Movement with a tourbillon unit (1), comprising: - a circuit board (2), - A bogie (1.03) connected to a second drive (1.21.3) and rotatably mounted on the plate (2), - a balance wheel (1.01) mounted on the bogie (1.03) and an escape wheel (1.04) mounted on the bogie (1.03) and operatively connected to the balance (1.01), - A balance stop device which can be brought into engagement with the balance (1.04), characterized in that it furthermore - has an adjusting device controlled from the outside by an actuating element for any angular alignment of said bogie (1.03), and wherein said adjusting device has a disengageable fixed wheel unit (1.10) which can be engaged with either the bogie (1.03) or the plate (2) in a rotationally fixed manner, and in a basic configuration is fixed in a non-rotatable manner on the plate (2). 2. Clockwork according to claim 1, wherein said disengageable fixed gear unit (1.10) has a ring-like planetary gear (1.14) which meshes with an internal toothing (1.10.2) which meshes with a pinion (1.04a) of the escape wheel (1.04), and with an external toothing (1.10.1) which meshes with a first engageable tourbillon setting wheel (10) is provided. 3. Movement according to claim 2, wherein said disengageable fixed gear unit (1.10) has a stop ring (1.11) which is axially movable with respect to its axis of rotation, which corresponds to the axis of rotation (1.20) of said tourbillon unit (1), which stop ring (1.11) is located on a radially outer edge has an outer bevel (1.11a) which corresponds to a respective first or second bevel (2.1a, 2.2a) of a first or second balance lever (2.1, 2.2) movably arranged on the plate (2). 4. Clockwork according to one of the preceding claims, wherein said balance stop device is arranged on the bogie (1.03) and can be brought into frictional engagement with the balance (1.01) axially to an axis of rotation (1.20) which corresponds to that of said tourbillon unit (1), movable Has brake spring (1.05). 5. Clockwork according to one of the preceding claims, wherein the tourbillon unit (1) further comprises a coupling device (4) between a tourbillon drive (1.21) connected in a rotationally fixed manner to said bogie (1.03) and said second drive (1.21.3), which is in the power flow with the barrel (9) has. 6. Clockwork according to claim 6, wherein said coupling device (4) has pivotable coupling levers (4.1,4.2) which effect an axial displacement of said second drive (1.21.3) against a retaining lining (1.31), and a coupling spring (1.21.4 ), which exerts a restoring force for said second drive (1.21.3) along the axis of rotation (1.20) of the tourbillon unit (1). 7. Clockwork according to one of the preceding claims, wherein the actuating member is a winding crown which can take three different axial positions, the first axial position corresponding to the basic configuration in which a rotary movement of the winding crown causes the winding of the barrel (9), wherein in the second axial position of said winding crown the balance stop device is activated and a rotary movement of said winding crown causes the pointer position, in the third axial position of said winding crown a rotary movement of said winding crown causes the angular orientation of said bogie (1.03) to be adjusted. 8. Clockwork according to claim 7, wherein in the third axial position of the winding crown both the disengageable fixed gear unit (1.10) is released from the plate (2) and is rotationally fixedly engaged with the bogie (1.03), as well as the coupling device between a is activated with the said bogie (1.03) rotatably connected to the tourbillon drive (1.21) and the said second drive (1.21.3), which is in the power flow with the barrel (9). 9. Clockwork according to claim 8, wherein at least the balance stop lever (2.1,2.2) is provided for the activation of said balance stop device, a holding lever (3) being provided for holding the said disengageable fixed gear unit (1.10) against the plate (2), and wherein at least the coupling lever (4.1,4.2) is provided for the decoupling between the tourbillon drive (1.21) and the said second drive (1.21.3). A clockwork mechanism according to claim 9, wherein the respective rest and working positions of said balance stop levers (2.1,2.2), said holding lever (3), and said clutch levers (4.1,4.2) are controlled by a camshaft (5). 11. Clockwork according to claim 10, wherein said camshaft (5) has three superposed cams, each working in a dedicated circuit diagram, namely a first cam (5.2) for controlling the balance stop lever (2.1, 2.2), a second cam ( 5.3) for controlling the holding lever (3), and a third cam (5.4) for controlling the clutch lever (4.1,4.2). A clockwork mechanism according to claim 11, wherein said camshaft (5) further comprises a toothed wheel (5.1) which cooperates with an angle lever (6.2) coupled to said actuating member. 13. Clockwork according to one of the preceding claims, which has a coupling to the minute display, wherein in particular a second fixed toothing (1.21a) is arranged on the tourbillon drive (1.21). 14. Clock with a clockwork (1) according to one of the preceding claims.