RU2822300C1 - Clock control element with precise stroke adjustment unit - Google Patents

Abstract

FIELD: clocks and other time meters.

SUBSTANCE: present invention relates to adjusting element (1, 40) for a clock mechanism, comprising an inertial mass, for example balance (23), balance spring (25) and stroke adjustment unit (20, 60) for adjusting the stroke of balance spring (25), wherein balance spring (25) comprises coiled band (2) and means for adjusting the stiffness of the balance spring, which comprise resilient element (5) arranged in series with coiled band (2), wherein stroke adjustment unit (20) is configured to adjust the stroke of the control element with a resolution which is less than or equal to 1 second a day, preferably less than or equal to 0.5 second a day and may be less than or equal to 0.1 second a day.

EFFECT: disclosed is a clock control element with a precise stroke adjustment unit.

17 cl, 8 dwg

Description

Field of technology to which the invention relates

The present invention relates to the field of watchmaking, in particular to the field of mechanical watches, where the driving energy is controlled by a control element. More specifically, the invention relates to a control element having a precision adjustment unit, a clock mechanism containing such a control element, as well as a watch containing such a clock mechanism.

State of the art

In most mechanical watches, the energy required to rotate the hands (such as the minute and hour hands) is stored on a barrel and then transferred by a balance-spring system that contains a flywheel called the balance, connected to a spring in the form of a coiled ribbon called the balance spring.

At the inner end, the balance spring is attached to an axis rigidly connected to the balance; at the outer end, the balance spring is attached to a column mounted on a column holder, which is itself attached to a fixed bridge.

Maintaining the rotation of the balance and counting its oscillations is carried out by an escapement mechanism containing an anchor fork, which makes oscillatory movements with low amplitude and contains two pallet stones acting on the teeth of the escape wheel. As a result of this effect, the escape wheel performs a step-by-step rotational movement, the frequency of which is determined by the oscillation frequency of the anchor fork, which itself is tuned to the oscillation frequency of the spring balance.

In a traditional escapement the vibration frequency is approximately 4 Hz or approximately 28,800 vibrations per hour. The task of the best watch manufacturers is to ensure that the balance is isochronic and periodic (or constant).

The stroke of the balance is adjusted in a known manner by adjusting the working length of the balance spring, defined as the curved length between its inner end and a reference point located near the outer end of the balance spring and determined by a pair of lock pins mounted on the stroke adjustment unit.

During operation, said stroke adjustment unit is fixed in such a way that it can rotate relative to the center line of the balance spring. However, the angular position can be finely adjusted by manual intervention, for example using a screwdriver to turn the eccentric, which acts like a cam on the stroke adjustment unit.

The assembly containing the axle, stroke adjustment assembly, lock, column holder, column, axle, spring and balance is usually called a "control element". Examples of control elements are given in document WO 2016/192957 and document EP 2 876 504, which belong to the watch manufacturer ETA.

There are stroke adjustment assemblies that include a column holder to which one end of the helix is attached, wherein the lock of said stroke adjustment assembly has play to allow movement of the helix between two pins. However, the chronometric properties of the watch, in particular the amplitude-dependent anisochronism, are very sensitive to the play of the lock of the speed adjustment unit, and in addition, this play is difficult to regulate with the required accuracy.

On some devices, the lock pins can be adjusted to tighten the balance spring and thus eliminate play, particularly during the operation of the balance spring. In this case, the stroke is first adjusted by moving the stroke adjustment lock, after which the balance spring is pressed against the lock. However, clamping the balance spring with the lock of the stroke adjustment unit can deform it and create chronometric defects, in particular, by disturbing the centering of the coils. In addition, eliminating the backlash also changes the stroke, and immediately after the balance spring is clamped, the stroke adjustment assembly lock can no longer move along the balance spring to complete fine stroke adjustment.

Other balance springs contain a built-in adjustment device. In such balance springs, the stroke is adjusted not by changing the working length of the balance spring, but by applying force or torque to an elastic element located in series with the balance spring. The stiffness of the elastic element and thus the balance spring can be changed as a whole. Adjusting the stiffness of the balance spring allows you to adjust the stroke of the control element. Such a balance spring with an elastic element is, for example, described in document EP 21202213.1.

However, in such cases, traditional stroke adjustment units cannot be used because they are not compatible with the balance spring adjuster. In addition, since the stroke requires very fine adjustment, it is essential that there is no play between the balance spring and the areas where it interacts with the stroke adjustment unit. This is because there would otherwise be a risk of the stroke changing in the event of an impact if the balance spring itself did not change position in exactly the same way after an impact.

Disclosure of the invention

The object of the present invention is to eliminate some or all of the above disadvantages by providing a stroke adjustment unit compatible with the specified type of control device.

To this end, the present invention relates to a control element for a watch movement comprising an inertial mass, such as a ring balance, a balance spring and a stroke adjustment unit for adjusting the travel of the balance spring, the balance spring comprising a coiled band and means for adjusting the stiffness of the balance spring, which contain an elastic element located in series with a coiled tape.

The invention is characterized in that the stroke adjustment unit is configured to regulate the stroke of the control element with a resolution that is less than or equal to 1 second per day, preferably less than or equal to 0.5 seconds per day, and may be less than or equal to 0.1 seconds per day.

Using the invention, it is possible to obtain a stroke adjustment unit, which allows you to adjust the stroke of the control element with very high accuracy, which is unknown today.

In fact, by activating the stroke control unit, it is possible to change the stiffness of the resilient member by changing the force or torque applied to the resilient member.

In addition, such a stroke adjustment unit is easy to use and does not require any significant modification to install it on the watch movement, since the installation is not very different from the installation of a stroke adjustment unit usually used for a standard balance spring.

According to a particular embodiment of the invention, the stroke adjustment unit contains setting marks corresponding to the specified resolution.

According to a particular embodiment of the invention, the stroke adjustment unit contains a column holder mechanically connected to an elastic element, wherein the column holder contains a first column and a second column, wherein the elastic element is located between the first column and the second column, and the first column is movable relative to the second column , while moving the first column changes the stiffness of the balance spring.

According to a particular embodiment of the invention, the column holder comprises a first part containing a first column and a second part containing a second column, the first part being movable relative to the second part to move the first column.

According to a particular embodiment of the invention, the first part and the second part are superimposed on each other.

According to a particular embodiment of the invention, the stroke adjustment unit contains an eccentric that interacts with the first part so that it can move when it rotates.

According to a particular embodiment of the invention, the stroke adjustment assembly includes a lever located on the first part and a cam interacting with the lever, so that actuation of the cam causes movement of the first part relative to the second part.

According to a particular embodiment of the invention, the stroke adjustment assembly includes a spring that applies a force between the first part and the second part to hold the lever of the first part on the cam.

According to a particular embodiment of the invention, the first part is movable by rotation relative to the second part.

According to a particular embodiment of the invention, the first column is movable by rotation.

According to a particular embodiment of the invention, the elastic element is located between the first column and the second column, and movement of the first column changes the rigidity of the elastic element.

According to a particular embodiment of the invention, the control means comprise means for creating a prestress for applying a variable force or torque to the flexible element.

According to a particular embodiment of the invention, the prestressing means are located between the first column and the second column, wherein movement of the first column relative to the second column actuates the prestressing means.

According to a particular embodiment of the invention, the prestressing means comprise a lever connected to a flexible member, the first column being attached to the free end of the lever.

According to a particular embodiment of the invention, the flexible element is connected to a rigid support, the second column being attached to the rigid support.

According to a particular embodiment of the invention, the prestressing means comprise a semi-rigid element arranged parallel to the flexible element, the lever being connected to the semi-rigid element.

The invention also relates to a watch mechanism containing such a control element.

The invention also relates to watches, for example wristwatches or pocket watches, containing such a movement.

Brief description of drawings

The objects, advantages and features of the present invention will become clear from several embodiments, presented only as non-limiting examples with reference to the accompanying drawings.

In fig. 1 is a schematic perspective view of a control element according to a first embodiment of the invention, the control element being located inside a clock mechanism;

in fig. 2 is a schematic perspective view of a portion of the first embodiment of the control element shown in FIG. 1, without balance bridge and without stroke adjustment unit;

in fig. 3 - schematic top view of the balance spring of the regulating element;

in fig. 4 is a schematic perspective view of a part of a control element according to a second embodiment of the invention, wherein the control element is located in the clock mechanism;

in fig. 5 is a schematic perspective view of a second embodiment of the control element shown in FIG. 4;

in fig. 6 is a schematic perspective view of a modification of the column holder of the second embodiment of the invention;

in fig. 7 is a schematic perspective view of the second part of the column holder of the embodiment shown in FIG. 6; And

in fig. 8 is a schematic perspective view of the second part of the speaker holder mounted on the balance bridge.

Carrying out the invention

In fig. 1 and 2 show a schematic view of a first embodiment of a control element 1 located inside a clock mechanism 10. The clock mechanism 10 includes a plate 21, an inertial mass, an elastic return element for the inertial mass configured to cause it to oscillate, and a balance bridge 22.

The adjusting element 1 also includes a stroke adjustment unit 20, a ring balance 23 acting as an inertial mass, a balance axis 24 and a balance spring 25 acting as an elastic return element.

The plate 21 has a recess 26, which is designed to accommodate the regulating element 1 and inside which, in the direction from bottom to top, a balance 23, a balance spring 25, a balance bridge 22 and a stroke adjustment unit 20 are superimposed on each other.

The balance axis 24 is centered within the recess 26 and passes through the center of the balance 23, the balance spring 25 and the balance bridge 22. The balance shaft 24 is supported by two impact-resistant supports 28 located at the two ends of the balance shaft 24. A first support is located at the bottom of the recess 26, and a second support 28 is located above the recess 26 and is supported by a balance bridge 22, the balance bridge 22 extending through the top of the recess 26 and through the central center line of the recess 26. The balance bridge 22 has an opening, in this case a through hole a hole within which the second support 28 is held. The stroke adjustment unit 20 is mounted on the balance bridge 22 and is located in this embodiment along the central centerline of the recess 26.

As shown in FIG. 2 and 3, the balance spring 25 preferably extends substantially in one plane. The balance spring 25 contains a flexible tape 2, wound around itself in several turns, and the tape 2 has a given rigidity. The inner end 9 of the tape 2 is integral or connected to a support 3, usually called a block. The support 3 has a substantially triangular shape and is mounted on the balance shaft 24 .

The balance spring 25 also contains means for adjusting its stiffness. For example, the control means may in particular be actuated by the user when the control element is mounted on the watch plate.

The control means include a flexible element 5 located in series with the tape 2, and the flexible element 5 connects one end 4, 9 of the specified tape 2 with a rigid support 17 and is attached to one of the ends 4, 9 of the tape 2. The flexible element 5 is made as one integral with the end 4 of the tape 2. The elastic element 5 and the tape 2 are different elements.

The flexible element 5 imparts additional rigidity to the belt 2. Preferably, the flexible element 5 has a higher rigidity than the belt 2. The flexible element 5 in this case is located on an extension of the belt 2. Preferably, the adjustment means and the belt 2 are made as one piece or even made of the same material, for example silicon.

The flexible element 5 of the balance spring 25 contains a non-crossed flexible hinge. The hinge contains two flexible non-crossing strips 11, 12 and a rigid section 18. In the transverse direction, on one side, the flexible strips 11, 12 are connected to the rigid support 17, and on the other hand, to the rigid section 18, converging towards each other. Thus, preferably, the flexible strips 11, 12 move away from each other, starting from the rigid section 18, up to the rigid support 17. The outer end 4 of the strip 2 is connected to the rigid section 18. The rigid support 17 cannot move relative to the plate 21. The rigid support 17 has an L-shape, with the first branch 46 of the L-shaped rigid support serving as a connector of the flexible strips 11, 12, and the second branch 47 of the L-shaped rigid support directed in the opposite direction from the non-cross hinge to ensure its connection with the clock mechanism 10 .

The balance spring 25 adjusting means also includes pre-stress means 6 for applying a variable force or torque to the flexible member 5. Thus, it is possible to adjust the balance spring stiffness. The torque or force can be continuously adjusted using the prestress means 6. In other words, torque or force is not limited to discrete quantities. Thus, it is possible to regulate the rigidity of the flexible element 5 with great precision.

The prestressing means 6 comprise an auxiliary flexible strip 19 located on the opposite side of the rigid section 18 in the extension of the non-cross hinge. An auxiliary flexible strip 19 is located tangentially relative to the tape 2 at the outer end 4.

At the other end, the auxiliary flexible strip 19 is connected to a curved arm 14, which is located around the strap 2. In addition to the auxiliary flexible strip 19, the arm 14 is connected to a semi-rigid structure 27 connected to a rigid support 17. The semi-rigid structure 27 is partially deformed when the arm is actuated into action by applying force or torque to it.

A force or torque is applied to the free end 15 of the lever 14. Thus, the lever 14 of the prestressing means 6 transmits a force or torque to the flexible element 5 through the auxiliary flexible strip 19 and the semi-rigid structural element 27 to change the stiffness of the balance spring 25.

To enable the application of variable force or torque to the balance spring 25, the control element includes a special stroke adjustment unit 20 according to the invention.

In the first embodiment of the invention shown in FIG. 1 and 2, the stroke adjustment unit 20 is equipped with a column holder 31 consisting of two parts: a first part 32 and a second part 33. The first part 32 of the column holder 31 holds the first column 34, while the second part 33 of the column holder 31 is equipped with the second column. 35. The column holder 31 is mechanically connected to the elastic element 5, but does not block the tape 2.

The first part 32 of the speaker holder 31 is located partially above the second part 33 of the speaker holder 31, which is in contact with the balance bridge 22. The stroke adjustment unit 20 contains two eccentrics 36, 37. The first eccentric 36 is installed on the second part 33 of the column holder 31 and ensures that the two parts of the column holder 31 are installed at a given angle with each other, which ensures the stroke adjustment. The second eccentric 37 is installed on the balance bridge 22 and allows for adjustment of the angular position of the column holder 31 relative to the platinum 21, which ensures installation of the base. The two parts of the column holder 31 are held and positioned by the damper 28.

The adjusting element 1 also contains locking means configured to lock the second part 33 of the column holder 31 in an angular position relative to the platinum 21 of the clock mechanism. The locking means contain a second eccentric 37.

Thus, during installation of the stroke adjustment unit 20, the second part 33 of the column holder 31, which is movable, is first installed and then locked by the second eccentric 37 so that it cannot move relative to the plate 21. Thereafter, the first part 32 of the column holder 31 is installed. column, and then it is locked in the angular direction by the first eccentric 36 so that it cannot move relative to the second part 33. Accordingly, by driving the second eccentric 37, the entire column holder 31 rotates around the center line of the balance to set the base. To unlock and move the first part 32, the first eccentric 36 is actuated. In this case, only the first part 32 of the column holder 31 rotates around the axis of rotation of the balance, which allows the first column 34 to move and act on the elastic element 5 to change the stroke.

Accordingly, only the first part 32 of the column holder 31 moves relative to the balance bridge 22 after installation and can move the first column 34 and act on the elastic member 5.

Two parts 32, 33 surround the second support 28. To this end, each part 32, 33 includes a central ring 38, 39 located around the second support 28, with the two central rings 38, 39 superimposed on each other.

The first portion 32 includes two projections 41, 42 extending radially from the central ring 38, the first projection 41 holding the first column 34 directed downward into the recess 26 by means of a first screw 74, and the second projection 42 having the shape of an arc of a circle and cooperating with the first eccentric 36.

The second portion 33 includes three projections 43, 44, 45 extending from the central ring 39. The first projection 43 holds the second column 35 directed downward into the recess 26 by a second screw 75, the second projection 44 extends around the first eccentric 36, and the third projection 45 has the shape of a circular arc and interacts with the second eccentric 37.

In the basic arrangement, the first column 34 and the second column 35, for example, are located substantially symmetrically about the balance axis 24.

The first column 34 interacts with the free end 15 of the lever 14, and the second column 35 interacts with the second branch 47 of the rigid support 17. Thus, the prestress means 6 and the elastic element 5 are supported by the stroke adjustment unit 20 on which they are suspended.

Two columns 34, 35 are located on either side of the prestressing means 6 and the elastic element 5. In addition, the two columns 34, 35 are rigidly connected to the lever 14 and the rigid support 17. In other words, the first 34 and second 35 columns are respectively attached to lever 14 using the free end 15 and to the rigid support 17 using the second leg 47. The columns and balance spring 25 are connected, for example, by metallization, soldering, welding, deformation of metal glass or mechanical fastening.

The first column 34 can be moved relative to the second column 35. For this purpose, the first part 32 can be moved relative to the second part 33. The first part 32 can be moved by rotation about the second support 28. Thus, the first column 34 moves with the first part 32, while the first column 34 can be moved by rotation about the second support 28. For example, the first column 34 can be moved in an angular range of 20° or 10°.

The movement of the first column 34 relative to the second column 35 changes the stiffness of the elastic element 5, since due to such movement, more or less force or torque is applied to the lever 14 of the prestressing means 6, so that the rigidity of the elastic element 5 changes, and thus the stiffness of the entire balance spring changes. Thus, the stroke adjustment unit 20 can be used to regulate the stroke of the control element 1.

To this end, the stroke adjustment unit 20 adjusts the position of the first column 34 relative to the second column 35 by means of a second circular arc shaped protrusion 42 of the first portion 32 and a first eccentric 36. The circular arc has a diameter that is slightly smaller than the head of the first eccentric 36, so that the movement the first eccentric 36 causes the second protrusion 42 and therefore the first part 32 to move relative to the second part 33 in a circle around the second support 28, while the second part 33 remains in place when the first part 32 is driven. Thus, due to the rotation of the first eccentric 36, the second arc-shaped protrusion 42 moves in a circle around the second support 28. The first part 32 moves relative to the second part 33, causing the first column 34 to move relative to the second column 35 to change the force or torque, applied to the means 6 for creating pre-tension of the balance spring 25. The absence of play between the eccentrics 36, 37 and the arcs 42, 45 ensures adjustment without deviation.

On the second protrusion 42 in the form of an arc around the first eccentric 36 there are adjustment marks 29. Thus, to adjust the stroke adjustment unit 20, the first eccentric 36 is oriented in accordance with the preferred mark.

The stroke adjustment unit 20 is configured to regulate the stroke of the control element 1 with a resolution that is less than or equal to 1 second per day, preferably less than or equal to 0.5 seconds per day, and may be less than or equal to 0.1 seconds per day. Accordingly, the stroke control unit 20 is calibrated such that its actuation provides such resolution. The layout of the control element 1 allows one to achieve such accuracy.

Preferably, the setting marks 29 correspond to the resolution. In other words, the difference between two consecutive marks corresponds to 1 second, 0.5 seconds and maybe 0.1 seconds per day.

In the second embodiment of the control element 40 shown in FIG. 4 and 5, features of the adjusting element 40 are substantially identical to those of the first embodiment of the invention with the exception of features relating to the adjustment of the stroke adjustment unit 60.

The first portion 52 of the stroke adjustment assembly 60 includes a lever 63 extending radially outward from the first portion 52 in one plane. The second part 53 does not include a protrusion in the shape of a circular arc.

The stroke adjustment unit 60 includes a cam 55 that is moved by rotation instead of the first eccentric. Cam 55 engages arm 63 of first portion 52 to cause it to rotate about second support 28. Preferably, end 56 of arm 63 is in constant contact with cam 55 such that rotation of cam 55 causes arm 63 to move depending on the angular position of cam 55. Thus, the first part 52 of the stroke adjustment unit 60 moves in a similar manner to the first embodiment of the invention. Such a stroke adjustment unit 60, equipped with a cam 55, allows you to linearly change the stiffness of the balance spring 25.

To maintain the lever 63 of the first portion 52 in contact with the cam 55, the stroke adjustment assembly 60 includes a spring 57 that applies a pressing force to the first portion 52. The spring 57 is substantially U-shaped and surrounds the locking screw 77, with the first end 58 being U-shaped. The spring is connected to the second part 53 of the stroke adjustment unit 60, and the second end 59 of the U-shaped spring is held by a retaining hook 61 located on the first part 52. The spring 57 is located on the second part of the column holder 51 symmetrically with the cam 55 relative to the second support 28.

Thus, the spring 57 applies a return force to the two parts 52, 53 of the stroke adjustment assembly 60, the return force being designed to maintain the lever 63 of the first part 52 in contact with the cam 55 at all times. When acting on the cam 55, the first part 52 rotates to move the first column 34 relative to the second column 35 and is subjected to the return force applied by the spring 57 so that the lever 63 of the first part 52 can come into contact with the cam 55, particularly when the peripheral surface 64 moves away from the lever 63.

According to the invention, the stroke adjustment unit 60 is configured to regulate the stroke of the control element 40 with a resolution that is less than or equal to 1 second per day, preferably less than or equal to 0.5 seconds per day, and may be less than or equal to 0.1 seconds per day. The arrangement of the control element 40 allows such precision to be achieved.

The adjusting element 40 also includes locking means configured to lock the second part 53 of the column holder 51 in one position relative to the balance 22 of the clock mechanism. The locking means includes a lock plate 62 and a lock screw 77 for connecting the lock plate 62 to the second part 53 and fixing its position.

Preferably, the locking plate is shaped to engage the balance bridge 72 on one side and the second support 28 on the other. The locking screw 77 extends through the locking plate 62 and is screwed into the balance bridge 72 located below the locking plate 62. Thus Thus, by tightening the locking screw 77, the locking plate 62 at least partially applies a force to the second part 53 of the column holder 51 at the support 78 of the first end 58 of the U-shaped spring 57, which support rests on the second part 53 of the column holder 51.

Thus, when installing the stroke adjustment unit 60, the second part 53 of the column holder 51, which is movable, is first installed, and then it is locked by the lock plate 62 and the lock screw 77 so that it cannot move relative to the balance bridge 72. Once installed, only the first part 52 can move relative to the balance bridge 72 to allow the first column 34 to move and act on the elastic element 5.

On cam 55 there are also setting marks 49. Thus, to adjust the stroke adjustment unit 60, the cam 55 is moved, for example, by an adjustment knob (not shown in FIGS. 4 and 5) located on the cam 55 and rotated. Thus, to adjust the stroke adjustment unit 60, the cam 55 is oriented to a preferred mark.

Preferably, the setting marks 49 correspond to the resolution. In other words, the difference between two successive marks allows the rate to change by 1 second, 0.5 seconds and perhaps 0.1 seconds per day. In fig. 6, the resolution of the 49 setting marks is 0.1 seconds.

In fig. 6 and 7, the column holder 51 is a modification of the second embodiment, in which the second part 53 includes a curved arm 70 on one side and a pair of grips 71 on the other side, as well as a generally circular open through hole 68 in the middle. A curved lever 70 is designed to engage a locking plate 62. A pair of claws 71 are designed to hold the cam axis and rest on the balance bridge 72 of the clock mechanism.

The through hole 68 allows for the insertion of an impact-resistant balance support 28 around which the speaker holder 51 is mounted and supported. The open through hole 68 is opened by a groove to provide flexibility to the portion 73 defining the hole 68. Thus, the support 28 can be inserted into the hole 68 and held therein. Due to this flexibility, the portion 73 can allow the support 28 to be inserted into the hole 68 and apply sufficient force to retain it. The shapes of the hole 68 and the impact-resistant balance support 28 correspond to each other, with the size of the support 28 preferably being slightly larger than the size of the hole 68.

In addition, the geometry of the hole 68 provides direction for the column holder 51 during rotation. In effect, the flexible portion 73 guides the column holder 51 as it rotates about the impact-resistant balance support 28 while maintaining concentricity with the centerline of the balance (not shown in the figures).

In fig. 6, a rotating adjustment head 65 is mounted on the cam, wherein the head 65 contains peripheral adjustment marks 66, and the adjustment marks 66 correspond to the invention.

In fig. 8 shows how the locking means lock the second part 53 of the column holder 51 on the balance bridge 72. The locking plate 62 rests on the curved lever 70. The locking screw 77 extends through the locking plate 62 and through the curved lever 70 to reach the balance bridge 72 located below. Thus, the second part 53 of the column holder 51 is located between the stop plate 62 and the balance bridge 72. In addition, the locking plate 62 holds the spring 57.

It goes without saying that the invention is not limited to the embodiments of the control elements described with reference to the figures, and other embodiments can be considered without deviating from the scope of the invention.

Claims (17)

1. A control element (1, 40) for a watch mechanism, containing an inertial mass, for example a balance (23), a balance spring (25) and a stroke adjustment unit (20, 60) for regulating the stroke of the balance spring (25), wherein the spring (25 ) of the balance contains a coiled tape (2) and means (30, 50) for adjusting the stiffness of the balance spring, which contain an elastic element (5) located in series with the coiled band (2), characterized in that the unit (20, 60) stroke adjustment is configured to regulate the stroke of the control element (1, 40) with a resolution that is less than or equal to 1 second per day, preferably less than or equal to 0.5 seconds per day and may be less than or equal to 0.1 seconds per day . 2. The adjusting element according to claim 1, characterized in that the stroke adjustment unit (20, 60) contains setting marks (29, 49) corresponding to the specified resolution. 3. The adjusting element according to claim 1 or 2, characterized in that the stroke adjustment unit (20, 60) contains a column holder (31, 51), mechanically connected to an elastic element (5), and the column holder (31, 51) contains the first column (34) and the second column (35), wherein the elastic element (5) is located between the first column (34) and the second column (35), and the first column (34) is configured to move relative to the second column (35), in this case, the movement of the first column (34) changes the stiffness of the balance spring. 4. The control element according to claim 3, characterized in that the column holder contains a first part (32, 52) containing a first column (34), and a second part (33, 53) containing a second column (35), wherein the first part (32, 52) is movable relative to the second part (33, 53) to move the first column (34). 5. Regulating element according to claim 4, characterized in that the first part (32, 52) and the second part (33, 53) are superimposed on each other. 6. The adjusting element according to claim 4 or 5, characterized in that the stroke adjustment unit (20) contains an eccentric (36) interacting with the first part (32) with the possibility of its movement when it rotates. 7. The adjusting element according to claim 4 or 5, characterized in that the stroke adjustment unit (60) contains a lever (63) located on the first part (52) and a cam (55) interacting with the lever (63), so that actuation of the cam (55) causes movement of the first part (52) relative to the second part (53). 8. The adjusting element according to claim 7, characterized in that the stroke adjustment unit (60) contains a spring that applies a force between the first part (52) and the second part (53) to hold the lever (63) of the first part (52) on the cam ( 55). 9. Regulating element according to any one of paragraphs. 4-8, characterized in that the first part (32, 52) is configured to move by rotation relative to the second part (33, 53). 10. Regulating element according to any one of paragraphs. 3-9, characterized in that the first column (34) is movable by rotation. 11. Regulating element according to any one of paragraphs. 1-10, characterized in that the control means (30, 50) contain means (6) for creating pre-stress for applying a variable force or torque to the flexible element (5). 12. The control element according to claim 11, characterized in that the means (6) for creating prestress are located between the first column (34) and the second column (35), and the movement of the first column (34) relative to the second column (35) activates means (6) for creating prestress. 13. The adjusting element according to claim 11 or 12, characterized in that the means (6) for creating prestress comprise a lever (14) connected to a flexible element (5), and the first column is attached to the free end (15) of the lever (14) . 14. Regulating element according to any one of paragraphs. 11-13, characterized in that the means (6) for creating prestress contain a semi-rigid element located parallel to the flexible element (5), and the lever (14) is connected to the semi-rigid element. 15. Regulating element according to any one of paragraphs. 1-14, characterized in that the flexible element (5) is connected to a rigid support (17), and the second column (35) is attached to the rigid support (17). 16. A clock mechanism, characterized in that it contains a control element (1, 40) according to any one of paragraphs. 1-15. 17. A watch, for example a wristwatch or pocket watch, characterized in that it contains a clock mechanism according to claim 16.

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