RU2794422C1 - Clock mechanism containing a moving element equipped with means for variable incline control - Google Patents

Abstract

FIELD: clockwork.

SUBSTANCE: invention relates to a clockwork comprising a bottom plate (33) continuing substantially in a first plane, the bottom plate (33) being configured to support other parts of the clockwork, such as an at least partially movable element, said element continuing at least partially in the second plane, and the clock mechanism contains drive means, including a system (98) of gears, while the specified element contains a drive gear rim that ensures its actuation, characterized in that it contains means (30, 40, 130) of variable control, intended for variable control of the inclination of the specified element relative to the bottom plate (33) so that the second plane forms an angle of variable magnitude with the first plane of the bottom plate (33), and the variable control means (30, 40, 130) contain a transmission gear (80, 131) or the first transmission gear (31) located on the bottom plate (33) and designed to interact with the drive gear rim of the specified element, while the transmission gear (80, 131) or the first transmission gear (31) is rotatable relative to the bottom plate (33) by means of driving means, wherein the transmission gear (80, 131) or the first transmission gear (31) has a concave peripheral surface containing a substantially spherical ring gear (32, 81, 181) designed to engage with the ring gear of the specified element and actuating it regardless of the orientation of said element relative to the bottom plate (33). The invention also relates to clock with such a mechanism.

EFFECT: effective performance.

16 cl, 28 dwg

Description

The field of technology to which the invention belongs

The present invention relates to watch movements comprising a movable element, in particular a movable element provided with means for variable tilt adjustment.

State of the art

At present, most mechanical watches are equipped with at least partially movable elements, such as a display device containing hands, a movable automatic device, a moon phase indicator, or a movable decorative element, which can be actuated by means of the movement's driving means.

More specifically, there are adjusting elements comprising a spring balance and a Swiss anchor escapement. The spring balance is the time base of the watch. It is also called a resonator.

The trigger mechanism has two main functions:

- to support the oscillatory movements of the resonator;

- count the indicated oscillatory movements.

To assemble a mechanical resonator, an inertial mass, a guide, and an elastic return element are required. Usually, a balance spring acts as an elastic return element for an inertial mass formed, for example, by a balance. This balance is directed in rotation by axes that rotate inside smooth ruby supports.

To reduce undesirable gravitational influences on the movement of the regulating element, there are complications such as tourbillon or carousel, which provide rotation of the regulating element around the axis. These complications, in particular, also have an aesthetic purpose, as they make the watch particularly attractive.

For aesthetic reasons, and in particular to facilitate the user's observation, certain control elements on the plate are tilted. In some models, the adjusting element even tilts along multiple axes.

However, the slope is usually determined during the design and assembly of the adjusting element on the watch movement and cannot be changed during use.

Disclosure of the essence of the invention

The object of the present invention is to overcome the above drawbacks and to provide a clock mechanism comprising at least a partially movable element which can tilt at an adjustable inclination angle.

To this end, the invention relates to a movement comprising platinum continuing substantially in a first plane, the platinum being configured to support other parts of the movement, such as an at least partially movable element, said element continuing at least partially in a second plane. plane, moreover, the clock mechanism contains drive means, including a system of gears, while the specified element contains a drive ring gear that ensures its actuation.

This clockwork is notable in that it contains means for variable adjustment of the inclination of the specified element relative to the platinum so that the second plane forms an angle of variable magnitude with the first plane of the platinum, and the means for variable adjustment contain a transmission gear or a first transmission gear located on the platinum and designed to interact with the drive gear rim of the specified element, while the transmission gear or the first transmission gear is made rotatable relative to the platinum with the help of drive means, and the transmission gear or the first transmission gear has a concave peripheral surface containing an essentially spherical gear rim designed to engage with the gear rim of the specified element and actuating it regardless of the orientation of the specified element relative to the platinum.

Thus, said element can be tilted relative to the platinum to a preferred position, enabling the movable element to be actuated by means of a transmission gear. The transmission gear is engaged with the ring gear of the specified element, regardless of the inclination of the specified element relative to the platinum. More specifically, the concave peripheral surface of the transfer gear ensures that the transfer gear remains in optimal engagement with the ring gear of said element in all orientations of said movable element relative to the platinum. In particular, the transmission gear enables the transmission of the driving force generated by the driving means to actuate the movable element.

Thanks to the invention, said element is no longer fixed in a predetermined position of the clock mechanism. Depending on the orientation of the clock, said element may tilt to a preferred position, in particular for better viewing.

According to a particular embodiment of the invention, the transmission gear or the first transmission gear has double cut teeth, in which a concave spherical cut and a straight cut are combined.

According to a particular embodiment of the invention, the means for variable adjustment of the inclination of the said element comprise a carriage inside which the said element is located.

According to a particular embodiment of the invention, the carriage comprises an external ring gear which acts as a ring gear intended to actuate said element, wherein the external ring gear is designed to engage with the transmission gear regardless of the inclination of the adjusting element, while the transmission gear causes rotation of the carriage .

According to a particular embodiment of the invention, the means for variable adjustment comprise a gear located at the radius mounted on the specified element, and the gear located at the radius contains a peripheral gear rim, which acts as a gear rim designed to drive the specified element, while a substantially spherical ring gear of the concave peripheral surface of the first transmission gear is in engagement with the gear located on the radius, regardless of the inclination of the specified element.

According to a particular embodiment of the invention, the teeth of the peripheral ring gear are inclined to engage with the ring gear of the transmission gear or the first transmission gear.

According to a particular embodiment of the invention, the drive means comprise a gear for the transmission gear or the first transmission gear, said gear cooperating with the area of the straight teeth of the transmission gear or the first transmission gear.

According to a particular embodiment of the invention, the means for variable regulation comprise a second transmission gear located on the platinum, the second transmission gear being rotatable relative to the platinum by means of drive means, the second transmission gear having a concave peripheral surface with a substantially spherical ring gear, moreover the carriage contains an external ring gear, made with the possibility of engagement with the second transmission gear, regardless of the inclination of the specified element, while the second transmission gear drives the carriage.

According to a particular embodiment of the invention, the second transmission gear contains teeth of a double cut, in which a concave spherical cut and a straight cut are combined.

According to a particular embodiment of the invention, the drive means comprise a crown wheel with an internal gear rim located around said element for engagement with the second transmission gear.

According to a particular embodiment of the invention, the two transmission gears are simultaneously driven by the drive means.

According to a particular embodiment of the invention, the angle of inclination of said element relative to the platinum is in the range of 0-90°, preferably 0-45°, or even 0-30°.

According to a particular embodiment of the invention, the means for variable adjustment of the inclination of said element comprise an inclined bridge on which said element is mounted, the inclined bridge being inclined relative to the platinum.

According to a particular embodiment of the invention, the clock mechanism comprises means for actuating the inclined bridge.

According to a particular embodiment of the invention, the specified element is a control element having an inertial mass, a guide and an elastic return element for the inertial mass, configured to provide vibrations of the inertial mass in the second plane, as well as a trigger mechanism that interacts with the inertial mass, moreover, the control element is located on platinum.

The invention also relates to watches containing such a movement.

Brief description of the drawings

Objects, advantages and features of the present invention will become clear after studying several embodiments of the invention, presented for the purpose of explanation only and not intended to limit the invention, with reference to the attached drawings.

In FIG. 1 shows a schematic perspective view of the carousel according to the invention in a position parallel to the first plane of the platinum;

in fig. 2 is a schematic side view of the carousel according to the invention in an inclined position with respect to the first plane of the platinum;

in fig. 3 is a schematic sectional view of the carousel along a plane passing through the first and second transmission gears, with the carousel in a position parallel to the first plane of the platinum;

in fig. 4 is a schematic sectional view of the carousel along a plane passing through the trigger and the first transmission gear, with the carousel in a position parallel to the first plane of the platinum;

in fig. 5 is a schematic side view in section through the stages of machining of the transmission gear of the carousel according to the invention;

in fig. 6 is a schematic perspective view of the carousel according to the invention in a position parallel to the first plane of the platinum;

in fig. 7 is a schematic bottom view of the carousel according to the invention in a position parallel to the first plane of the platinum;

in fig. 8 is a schematic plan view of the carousel according to the invention in a position parallel to the first plane of the platinum;

in fig. 9 is a schematic perspective view of the gear wheel engagement of the crown wheel carousel according to the invention in a position parallel to the first plane of the platinum;

in fig. 10 is a schematic perspective view of the base of a clock with a carousel according to the invention in an oblique position with respect to the first plane of the base;

in fig. 11 is a schematic side view of the engagement of the first transmission gear of the carousel with the gear system according to the invention in a position parallel to the first plane of the platinum;

in fig. 12 is a schematic perspective view of the inclined bridge of the carousel according to the invention;

in fig. 13 is a schematic side view in section of the carousel along the axis passing through the bridge;

in fig. 14 is a schematic perspective view of a tourbillon according to the invention in a position parallel to the first plane of the plate;

in fig. 15 is a schematic side view of a tourbillon according to the invention in an oblique position with respect to the first plane of the plate;

in fig. 16 is a schematic sectional view of a tourbillon according to the invention in a position parallel to the first plane of the plate;

in fig. 17 is a schematic side view of the engagement of a tourbillon ring with a gear according to the invention, with the tourbillon in a position parallel to the first plane of the plate;

in fig. 18 is a schematic plan view of a tourbillon according to the invention, with the tourbillon in a position parallel to the first plane of the plate;

in fig. 19 is a schematic perspective view of a tourbillon according to the invention in an oblique position with respect to the first plane of the plate;

in fig. 20 is a schematic bottom view of a tourbillon according to the invention in a position parallel to the first plane of the plate;

in fig. 21 is a schematic perspective view of a watch fitted with a tourbillon according to the invention in an oblique position with respect to the first plane of the plate;

in fig. 22 is a schematic perspective view of the tilted tourbillon bridge according to the invention;

in fig. 23 is a schematic sectional view of the adjusting element according to the invention in a position parallel to the first plane of the platinum;

in fig. 24 is a schematic perspective view of a regulating element according to the invention in a position parallel to the first plane of the platinum;

in fig. 25 is a schematic perspective view of a control element according to the invention in an inclined position with respect to the first plane of the platinum;

in fig. 26 is a schematic side view of a regulating element according to the invention in an inclined position with respect to the first plane of the platinum;

in fig. 27 is a schematic bottom view of the adjusting element according to the invention in a position parallel to the first plane of the platinum; And

in fig. 28 is a schematic plan view of a regulating element according to the invention in a position parallel to the first plane of the plate.

Implementation of the invention

The present invention relates to a clockwork comprising a platinum extending substantially in a first plane, the platinum being configured to support parts of the clockwork. The clock mechanism contains drive means containing a drum, a system of gears and at least partially a movable element.

In the embodiments of the invention shown in the figures, at least partially, the movable element is a control element containing an inertial mass, a guide, an elastic return element for the inertial mass, configured to provide oscillation of the inertial mass in the second plane, as well as a trigger mechanism that interacts with inertial mass.

In addition, in these embodiments of the invention, the drive gear rim of the specified element is formed either by the outer gear rim of the carriage, or by the peripheral gear rim of the regulating element located on the radius of the gear wheel.

In the following description, actuating means refers to parts for supplying and transmitting the energy necessary to operate the control mechanism, adjusting means refers to elements designed to tilt and actuate the adjusting element, while ensuring the transfer of energy, and actuating means refer to to parts made with the possibility of changing the inclination of the regulating element, for example, by the user.

In FIG. 1-13, in particular, the regulating element 1 of the carousel type is shown. The invention, in particular, does not relate to the characteristic features and operation of the carousel, which are known to a person skilled in the art in question.

The carousel 1 contains a carriage 2 of the carousel, inside of which there is a mechanical resonator with an inertial mass 3, a guide and an elastic return element 4, as well as a Swiss anchor trigger 5. The carriage 2 of the carousel is installed with the possibility of rotation around the axis of rotation using a ball bearing 6 installed between the carriage 2 carousels and an inclined bridge 7, on which the carriage 2 of the carousel is installed.

The carriage 2 of the carousel contains an upper support 8 and a lower support 9, which are connected by means of screws 11 inserted into three racks 12. A mechanical resonator with an inertial mass, a guide and an elastic return element, as well as a trigger mechanism are suspended between the upper support 8 and the lower support 9 According to another non-limiting embodiment of the invention, the upper support 8 is a round wheel, containing in this case three legs 13 connected to a central hub 15. The lower support 9 in this case comprises three arms 14 extending from the central connection, the arms connecting the three eccentric racks 12 with a central connection point. Three posts 12 are distributed circumferentially around the periphery of the carousel carriage 2 and connect the round wheel to each arm 14.

The inertial mass 3 is an annular balance mounted on an axial first axle 16 located in the middle part of the carousel carriage 2. The axial first axis 16 is substantially perpendicular to the second plane of the inertial mass.

The balance is located at the top of the carriage 2 of the carousel, so it is visible from the outside. Inside the carousel carriage 2, the balance is configured to perform a rotational oscillatory movement around the axial first axis 16 at a predetermined frequency, as shown in FIG. 3 and 4.

To actuate the mechanical resonator under the axial first axis 16 is the axial second axis 17, which is essentially on the same straight line with the axial first axis 16. Part of the axial second axis 17 continues under the carousel carriage 2 and the inclined bridge 7. connected to the axial second axis 17 in its center, mounted coaxially with the balance and located under the carriage 2 of the carousel.

In the carriage 2 of the carousel, under the balance, there is an intermediate wheel 19 rigidly connected to the axial second axle 17. The intermediate wheel 19 engages with the escapement tribe 21 mounted on the third axle 22 located on the radius, which is essentially parallel to the axial axes 16, 17. at a radius, the third axle 22 is located in the carriage 2 of the carousel. The radially located third axle 22 also supports the escape wheel 25, which is mounted above the escapement tribe 21. The escape wheel 25 interacts with a Swiss anchor 26 located perpendicularly between the axial first axle 16 and the periphery of the escape wheel 25. The escape wheel 26 has an elongated body with horns at the first end, and the horns are made with the possibility of interaction with the pin of the axial first axis 16, which is associated with the balance mechanism. The second end of the anchor fork 26 contains two pallets, made with the possibility of interaction with the escape wheel 25 and alternately blocking its rotation, causing the stepwise movement of the escape wheel. The anchor fork 26 is supported by a fourth axle 27 located on a radius located in the carousel carriage 2 between the axial first axle 16 and the third axle 22 located at a radius.

The inclined bridge 7 supports the adjusting element, and the axial second axis 17 passes through the inclined bridge 7. The axial first pinion 18 is located under the inclined bridge 7.

The rotation of the axial first tribe 18 actuates the escape wheel 25, the anchor fork 26 and the balance mechanism with the help of the intermediate wheel 19 and the escapement tribe 21, which rotate the third axle 22 located on the radius.

The carousel 1 also includes a radial gear wheel 29 which is located under the carousel carriage 2 in engagement with the axial first pinion 18. The radially located gear wheel 29 is supported by a fifth axle 28 located at the radius which is located under the carousel carriage 2. The actuation of the gear wheel 29 located on the radius causes the rotation of the axial first pinion 18.

The clockwork includes variable adjustment means 30 for varying the inclination of the adjusting element relative to the plate so that the second plane of the inertial mass forms a variable angle with the first plane of the plate, as shown in FIG. 1 and 2.

Thus, the carousel 1 can move between a position in which the second plane of the inertial mass is substantially parallel to the first plane of the platinum, and an inclined position in which the second plane of the inertial mass forms an angle with the first plane of the platinum.

The angle of inclination can be selected using the means 30 variable tilt. Preferably, variable adjustment means 30 change the angle of inclination of the adjusting element relative to the platinum in the range of 0-45°. Thus, at 0° the balance of the adjusting element is preferably parallel to the first plane of the plate, while at 45° the adjusting element is inclined relative to the first plane of the plate. By means of the variable adjustment means 30, the angle can take on any value between the two extreme values. In FIG. 1 shows the minimum angle, which is essentially 0°, and FIG. 2 shows the maximum angle, which is 30°. In this embodiment, the maximum angle is 30°.

According to the invention, in order to achieve such an adjustable inclination, the variable adjustment means 30 comprise a first transmission gear 31 located on the platinum. The first transmission gear 31 is rotatable relative to the platinum by driving means. The first transmission gear 31 is inclined relative to the platinum. The first transmission gear 31 has a substantially spherical ring gear 32 configured to engage with a radially positioned control gear 29 for trigger actuation and balance.

The first transmission gear 31 has an hourglass shape with concave cylindrical symmetry about the longitudinal axis of symmetry. The peripheral surface of the first transmission gear 31 is inwardly concave. Thus, the diameter and perimeter of the center of the first transmission gear is smaller than the nominal diameter and perimeter of the ends of the first transmission gear 31. Preferably, the nominal perimeter and diameter at the two ends of the first transmission gear 31 are respectively identical. The length of the first transmission gear 31 is preferably greater than the nominal diameter of the first transmission gear.

The concave peripheral surface allows the radial gear 29 to engage with the first transmission gear 31 regardless of the inclination of the carousel 1. Thus, the substantially spherical ring gear 32 has a concave shape. The curvature of the surface is chosen to match the radius and inclination of the radial gear 29. Thus, regardless of the inclination of the carousel, the first transmission gear 31 is engaged with the radial gear 29. All teeth are bent in the inward direction of the first transmission gear 31 and have the same radius of curvature. Such a concave spherical cut promotes engagement with the gear wheel 29 located at the radius, regardless of it relative to the first transmission gear 31.

The first transmission gear 31 has a straight cut. Thus, the first transmission gear 31 has a double cut in which a concave spherical cut and a straight cut are combined. Straight cutting means that the teeth have an identical profile over the entire height of the tooth. A double cut is obtained by performing a first, concave, spherical cut to obtain teeth that are curved in the inward direction of the first transmission gear 31. As a result, the teeth have a varying profile along the tooth height, with the teeth having a thicker tip. A second, straight cut is then carried out, in particular on the thick ends of the teeth, to obtain teeth with essentially the same profile at the ends.

Thus, the first transmission gear 31 has a portion 23 in which the teeth are straight. Section 23 is located above the essentially spherical ring gear 32 around the entire circumference of the first transmission gear 31. This section 23 facilitates engagement with the gear wheel 20.

The gear wheel 20 has a ring gear 83 with inclined teeth designed to interact with the section 23 of the first transmission gear 31, and the first transmission gear 31 is inclined relative to the axis of the gear wheel 20.

As a result, the toothed gear 20 does not change its plane, so that its beveled ring gear 83 actually interacts with the portion 23 of the first transmission gear 31, which itself is inclined.

The radial gear wheel 29 has a peripheral ring gear which is adapted to engage with the straight teeth of the section 23 of the first transmission gear 31. plane located on the radius of the gear wheel 29. Located on the radius of the gear wheel 29 has a smaller diameter and perimeter at the base than the diameter and perimeter in its upper part. The diameter and perimeter of the specified wheel increase from the base to the top.

The radially positioned gear wheel 29 can tilt between a minimum tilt position and a maximum tilt position. In the minimum inclination position, the peripheral ring gear 34 of the radially located gear wheel 29 is engaged with the substantially spherical ring gear 32 of the first transmission gear 31 at the lower end of the first transmission gear 31, while in the maximum inclination position, the peripheral ring gear 34 located on radius of the gear wheel 29 is engaged with the substantially spherical ring gear 32 of the first transmission gear 31 at the upper end of the first transmission gear 31.

The variable adjustment means 30 for the carousel 1 comprise a second gear 35 located on the platinum, the second gear 35 being rotatable relative to the platinum. The second transmission gear 35 is configured to hold the adjusting element carousel carriage 2 by means of an outer ring gear 36 of the carousel carriage 2. The outer ring gear 36 is located on the periphery of the upper support 8, and the teeth continue radially from the carriage 2 of the carousel. Thus, the second transmission gear 35 limits the rotational movement of the carousel carriage 2 so that the carousel carriage 2 rotates about its rotation axis at a predetermined speed, and thus prevents it from rotating too fast. The rotational movement of the second transmission gear 35 itself around its axis of rotation is limited by the driving means of the clockwork.

The second gear 35 is preferably similar to or even identical to the first gear 31, whereby the second gear 35 also has a substantially spherical ring gear 37 and straight cut teeth 70. The straight cut teeth 70 are located under the substantially spherical ring gear 37.

In FIG. 5, the cutting of the first or second transmission gear 31, 35 is carried out in two different ways. In the gear blank, a first cut is first cut to form a substantially spherical ring gear 32, 37. A second, straight cut is then performed to obtain the final gear 31, 35 shown on the right. Straight cutting allows you to get teeth with the same profile over the entire height of the straight cutting section.

Two transmission gears 31, 35 are located on both sides of the carousel carriage 2. The first gear 31 is inclined on the platinum, while the second gear 35 is positioned substantially perpendicular to the platinum. The second transmission gear 35 is located above the first transmission gear 31. More specifically, the second transmission gear 35 interacts with the upper support wheel 8, which is located at the top of the carousel carriage 2, while the first transmission gear 31 cooperates with the gear wheel 29 located at the radius , which is located at the bottom of the carriage 2 of the carousel.

In the vertical position, the upper bearing 8 is engaged with the upper part of the second transmission gear 35, while the radial gear 29 is engaged with the lower part of the first transmission gear 31. In the inclined position, the upper bearing 8 is engaged with the lower part the second transmission gear 35 while the radial gear 29 is engaged with the top of the first transmission gear 31.

With respect to the carousel 1, the two transmission gears 31, 35 rotate simultaneously, with the first transmission gear 31 driven by the gear system 98 shown in FIG. 6 to 9 while the second gear 35 is driven by the movement of the carousel carriage 2 and is held back by the driving means.

To this end, the drive means comprise a crown wheel 38 with an internal ring gear 24 as shown in FIG. 6–9. The crown wheel 38 is disposed around the carousel carriage 2 so that it can restrain the second transmission gear 35 when the second transmission gear 35 rotates, the crown wheel 38 rotating around the carousel carriage 2. Thus, by restraining the second transmission gear 35, the crown wheel 38 controls the movement of the carousel carriage 2 and also enables the escapement and balance mechanism to be actuated. The crown wheel 38 is engaged with the straight cut teeth 70 of the second transmission gear 35. The crown wheel also includes an outer ring gear 92 configured to mesh with the gear wheel 93 of the gear system 98.

The drive means comprise a gear wheel 20 for the first transmission gear 31 shown in FIG. 11, the gear wheel 20 is also driven by the gear system 98.

In addition, the variable adjustment means 30 for variable adjustment of the inclined control element comprise an inclined bridge 7 on which the carousel carriage 2 is mounted, with a ball bearing 6 located between the carousel carriage 2 and the inclined bridge 7. element. The inclined bridge 7 is located under the carousel carriage 2 above the axial _first pinion 18 and the gear wheel ₂₉ located at the radius. inclined bridge 7 and preferably parallel to the plane of the platinum. The inclined bridge 7 comprises two external axles 42, 43 symmetrically located on both sides of the carousel carriage 2, with each axle 42, 43 extending from a post located at the end of the inclined bridge 7.

Each of the axes 42, 43 interacts with the support 39, 41 of the platinum, and the axes 42, 43 are located along the axis D ₁ of rotation of the inclined bridge 7. Each support 39, 41 has an opening for inserting the axis 42, 43 into it. Two axes 42, 43 can rotate within each support 39, 41. Thus, the tilt bridge 7 can rotate around the axis of rotation D ₁ using axes 42, 43 and supports 39, 41.

The variable adjustment means 30 comprise a wheel 44 rigidly mounted on an inclined bridge 7, and actuation of the wheel 44 causes the inclined bridge 7 to tilt. parallel to the axis D ₁ of rotation of the inclined bridge 7. The inclined ring gear 45 cooperates with the actuating means. The actuating means are engaged with the wheel 44 so that the tilt bridge 7 rotates about the pivot axis D ₁ .

In FIG. 6-8 show tilting actuating means which comprise a roller 46 and a gear system 47 . The roller 46, for example, is driven by a head which is not shown in the figures. The roller 46 includes a pinion 48 having a peripheral ring gear 49 engaged with a transmission gear 51 which drives the gear system 47. The system 47 of gears contains a group of gears and pinions, which are driven by the transmission gear 51 to transmit to the inclined bridge 7 the rotational force perceived by the roller 46. inclined bridge 7. Thus, by rotating the shaft 46 around its axis, the gear system is driven up to the wheel 44, which inclines the inclined bridge 7 to a predetermined angle.

Other embodiments of the actuating means may be considered, for example jumping into position.

In FIG. 10 shows the platinum 33 containing the carousel and actuating means. Roll 46 extends outward of the platinum to allow actuation of the adjusting element and change of inclination. Platinum 33 has a recess in which the regulating element is located.

In FIG. 11 shows an assembly comprising a first gear 31 and a radial gear 29. The radial gear 29 and the gear 31 cooperate so that the radial gear 29 can be tilted while maintaining a sufficient amount of engagement. between gear and gear. This means that regardless of the inclination of the gear wheel, the possibility of transmitting rotational motion from one specified element to another remains the same within a specified operating range between the minimum and maximum inclination.

In FIG. 12 and 13 show an inclined bridge 7 having a main longitudinal plate 53, at the ends of which are posts for axles 42,43. located on the radius of the fifth axis 28.

The tilt bridge 7 has an auxiliary plate 54 located below the main plate 53. The auxiliary plate 54 includes a first support 50 into which an axial second axle 17 can be inserted. the second eccentric support 94, designed to be inserted into it located on the radius of the fifth axis 28, and the second support 94 is located in line with the eccentric support of the main plate 53. Thus, located on the radius of the fifth axis 28 is held between the main plate 53 and the auxiliary plate 54 .

A ball bearing is inserted into the central hole, which is held in a recess located between the main plate 53 and the auxiliary plate 54.

In the second embodiment of the invention shown in FIG. 14–22, the regulating element is a tourbillon. The invention, in particular, does not relate to the characteristic features and operation of the tourbillon, which are known to the person skilled in the art.

The tourbillon 10 contains a movable carriage 55, inside of which there is an inertial mass 56, a guide, an elastic return element 68 and a trigger 69.

The tourbillon cage 55 is mounted in such a way that it rotates about the axis of rotation by means of a ball bearing 60 located between the tourbillon cage 55 and the inclined bridge 57 on which the tourbillon cage 55 is mounted.

The tourbillon carriage 55 comprises an upper support 58 and a lower support 59, which are connected by means of screws inserted into two columns 61. The upper leg 58 and the lower leg 59 are cruciform with two branches 63, 64 intersecting at the point 65 of intersection. Two supports 58, 59 are arranged parallel to each other one above the other. Two posts 61, 62 connect two legs 58, 59 to each other, with each leg 61, 62 connecting one end of leg 63 of leg 58 to the end of a corresponding leg of another leg 58, 59. and the axis of the escape wheel. Racks 61, 62 are connected to two supports 58, 59 with screws 66.

In FIG. 16, the inertial mass 56 is an annular balance mounted on a radially located first axle 67 which is mounted radially parallel to the pivotal axis of the tourbillon carriage 55. The balance is off-center and is set in the upper half of the 55 tourbillon carriage. Inside the tourbillon carriage 55, the balance is made with the possibility of performing a rotational oscillatory movement with a given frequency around the first axis 67 located at the radius.

A radial second axle 72 is located in a tourbillon cage 55, with a second axle 72 located at a radius supporting an escape wheel 73 which is positioned above an escapement tribe 74 also supported by a second axle 72 located at a radius. The second axle 72 located at a radius is parallel to the axis of rotation of the carriage 55 tourbillon and located on the radius of the first axis 67. The trigger pin 74 protrudes below the tourbillon cage 55 in an off-center location.

The escape wheel 73 is located at the top of the tourbillon carriage 55 so that it can be seen from the outside. The escape wheel 73 interacts with a Swiss anchor 75 located perpendicularly between the first axle 67 located at the radius and the periphery of the escape wheel 73. 67, which is related to the balance mechanism. The second end of the anchor fork contains two pallets, made with the possibility of interaction with the escape wheel 73 and alternately blocking its rotation, providing incremental rotation of the escape wheel. The yoke 75 is supported by a third axle 76 located on the radius located in the tourbillon cage 55 between the first axle 67 located on the radius and the second axle 72 located on the radius.

In the axial direction under the tourbillon carriage 55, between the inclined bridge 57 and the tourbillon carriage 55, there is a second wheel 71. The second wheel 71 does not rotate with the tourbillon carriage 55 and is rigidly connected to the inclined bridge 57. located on the radius of the second axis 72. The second wheel 71 can move relative to the platinum together with the inclined bridge 57.

Thus, due to the rotation of the tourbillon carriage 55 around its axis of rotation, the escapement pinion 74 starts to rotate the seconds wheel 71, so that the escapement wheel 73, the yoke 75 and the balance mechanism are driven.

According to the invention, the movement comprises variable adjustment means 40 for varying the inclination of the tourbillon relative to the plate so that the second plane of the inertial mass forms a variable angle with the first plane of the plate, as shown in FIG. 14 and 15. Thus, the tourbillon 10 can move between a straight position, in which the second plane of inertial mass is substantially parallel to the first plane of the platinum, and an inclined position, in which the second plane of inertial mass forms an angle with the first plane of the platinum.

The angle of inclination can be changed by the means 40 of variable inclination. Variable control means 40 make it possible to change the angle of inclination of the control element relative to the platinum in the range of 0–90°. Thus, at 0° the balance of the adjusting element is preferably parallel to the first plane of the platinum, while at 90° the adjusting element is substantially perpendicular to the platinum. Preferably, the range is 0-45° when the adjusting element is tilted with respect to the first plane of the plate. By means of the variable adjustment means 40, the angle can take on any value between the two extreme values.

In FIG. 14 shows the minimum angle, which is essentially 0°, and FIG. 15 shows the maximum angle, which is 30°. In this embodiment, the maximum angle is 30°.

The variable adjustment means 40 comprises a gear 80 disposed on the platinum, the gear 80 being rotatable relative to the platinum by means of driving means, the gear 80 having a substantially spherical ring gear 81 operable to engage with the tourbillon cage 55 for putting it into action.

The tourbillon carriage 55 has a peripheral ring gear 77 located on the lower bearing 59. The lower bearing 59 comprises an outer ring 82 on which there is a peripheral ring gear 77. Thus, due to the engagement with the outer ring 82, the tourbillon carriage 55 rotates about its axis.

The transmission gear 80 is similar to or even identical to the gears described with respect to the carousel. It has a cylindrical shape, with the ring gear 81 on its peripheral surface being substantially concave, which allows the peripheral ring gear 77 of the outer ring 82 to engage with the pinion 80 regardless of the inclination of the tourbillon 10.

For example, the ring gear 81 of the transmission gear 80 has a double tooth cut in which a concave spherical cut and a straight cut are combined. The concave spherical cut assists in engagement with the tourbillon cage 55 regardless of the orientation of the tourbillon cage 55 relative to the transfer gear 80. Straight cut means that the teeth of the transfer gear are substantially the same width throughout the straight cut. Thus, the pinion gear 80 has a straight tooth portion 90 so that it can engage with the gear wheel.

In addition, the teeth of the peripheral ring gear 77 of the outer ring 82 are preferably inclined relative to the plane of the outer ring 82 for engagement with the transmission gear 80.

Unlike the carousel of the first embodiment of the invention, the variable adjustment means 40 comprise a single transmission gear 80 which only drives the tourbillon cage 55 10 to actuate the escapement. The escapement pin 74 is actuated by moving the tourbillon carriage 55 and applying voltage to the fixed wheel 71. In other words, the escapement is arranged in series with the tourbillon carriage 55 with respect to the driving means.

To drive the transmission gear 80, a device similar to a carousel is used. For example, the variable control means 40 comprises a gear for the first transmission gear driven by a gear system. Alternatively, a crown wheel similar to the crown wheel driving the carousel's gear may be used to drive the tourbillon gear.

In FIG. 21 shows a watch 84 having a case 86 and a dial 85 on which the hands move. The watch contains a tourbillon recess 10, with a hole provided in the dial 85 to allow the oblique tourbillon to be seen.

The variable adjustment means 40 for variable adjustment of the inclination of the tourbillon 10 comprises an inclined bridge 57 (shown in FIG. 22) on which a tourbillon carriage 55 is mounted, a ball bearing 60 being disposed between the tourbillon carriage 55 and the inclined bridge 57. The inclined bridge 57 can be tilted to select the inclination of the tourbillon 10. The inclined bridge 57 is located under the carriage, while the fixed seconds wheel 71 is located between the inclined bridge 57 and the tourbillon carriage 55.

The slant bridge 57 is mounted so that it can be rotated about an axis of rotation D ₂ passing through the tourbillon cage 55, said axis being parallel to the slant bridge 57 and preferably parallel to the first plane of the plate. The inclined bridge 57 has a main longitudinal plate 96 with a central hole 89 and posts at the ends of the plate 96. Each post contains external axles 87, 88 located along the axis D ₂ of rotation on both sides of the tourbillon carriage 55 and interacting with platinum supports (not shown). The ball bearing 60 is inserted in the central hole 89 or preferably in the seconds wheel 71.

Other features may be identical to those of the carousel bridge. The variable adjustment means 40 comprise, for example, a wheel 91 rigidly mounted on an inclined bridge 57, wherein the wheel 91 has an inclined ring gear, whereby actuating the inclined wheel 91 causes the inclined bridge 57 to tilt.

The tilt actuating means are identical to the tilt actuating means described with reference to the carousel embodiment with respect to the wheel rigidly mounted on the tilt bridge.

In the third embodiment of the invention shown in FIG. 23-28, the adjusting element is a conventional adjusting element 100, which can be tilted as needed. The invention, in particular, does not relate to the characteristics and operation of a conventional control element, which are known to a person skilled in the art in question.

A typical control element 100 includes an inertial mass 103, a guide, an elastic return element, and a release mechanism.

In FIG. 23-28, a conventional control element 100 comprises a conventional control element carriage 102, within which are located a mechanical resonator with an inertial mass 103, a guide and an elastic return element 104, as well as an escapement mechanism 105 with a Swiss anchor plug 126. The conventional control element carriage 102 is installed in this way that it is rigidly connected to the inclined bridge 107.

The carriage 102 of a conventional adjusting element includes an upper support 108 and a lower support 109, which are connected by means of screws 111 inserted into three posts 112. lower support 109. The upper support 108 is a circular ring with three branches 113 connected to the central hub. The bottom support 109 includes three arms 114 extending from the central junction, with the arms 114 connecting the three eccentric posts 112 to the central junction. Three columns 112 are located in the circumferential direction on the periphery of the conventional adjuster carriage 102 and connect the wheel to each shoulder 114.

In FIG. 23, the inertial mass 103 is an annular balance located on an axial first axle 116 mounted in the central part of the carriage 102 of a conventional adjuster. The balance is located at the top of the carriage 102 of the conventional adjuster so that it is visible from the outside. Inside the carriage 102 of a conventional adjusting element, the balance is configured to carry out a rotational oscillatory movement at a predetermined frequency around the axial first axis 116.

To actuate the mechanical resonator, an axial second axle 117 is positioned below the axial first axle 116 and is substantially in line with the axial first axle 116. A portion of the axial second axle 117 extends under the conventional adjuster carriage 102 and tilt bridge 107. The axial first pinion 118 , rigidly connected to the axial second axis 117 in its center, is in line with the balance and is located under the carriage 102 of the conventional adjusting element.

In the conventional adjuster carriage 102, the intermediate wheel 119 is rigidly connected to the axial second axle 117 under balance. The intermediate wheel 119 engages the escapement pinion 121 mounted on a radially located third axle 122 that is substantially parallel to the axial axles 116, 117. The radially located third axle 122 is located in the carriage 102 of the conventional adjuster. The radially located third axle 122 also supports the escape wheel 125, which is located above the escapement pinion 121. The escape wheel 125 interacts with a Swiss fork 126 located perpendicularly between the axial first axle 116 and the periphery of the escape wheel 125. The escape wheel 126 has an elongated body with horns. at the first end, and the horns are made with the possibility of interaction with the pin of the axial first axis 116, which is associated with the balance mechanism. The second end of the yoke 126 contains two pallets configured to interact with the escape wheel 125 and alternately block its rotation, allowing the escape wheel to rotate incrementally. The yoke 126 is supported by a radially located fourth axle 127 located in the conventional adjuster carriage 102 between the axial first axle 116 and the radially located third axle 122.

Rotation of the axial first pinion 118 actuates the escape wheel 125, the anchor fork 126 and the balance mechanism by means of the intermediate wheel 119 and the trigger pin 121, which rotate the third axle 122 located at a radius.

The conventional adjuster 100 also includes a radial gear 129 that is mounted below the conventional adjuster carriage 102 and is engaged with the axial first pinion 118. regulating element. Activation of the radial gear 129 causes rotation of the axial first pinion 118.

According to the invention, the clock mechanism comprises variable adjustment means 130 for variable adjustment of the inclination of the adjusting element 100 relative to the plate so that the rotary axis and the second plane of the inertial mass form a variable angle with the first plane of the plate. Thus, the adjusting element 100 can be tilted to obtain a variable angle of inclination, and the specified angle can be selected using the variable adjustment means 130.

Preferably, the variable adjustment means 130 changes the angle of the adjustment element relative to the platinum in the range of 0-45°. Thus, at 0° the balance of the control element is parallel to the first plane of the plate, while at 45° the control element is inclined relative to the first plane of the plate. By means of the variable adjustment means 130, the angle can take on any value between the two extremes.

In FIG. 24 shows the minimum angle, which is essentially 0°, and FIG. 25 shows the maximum angle, which is 30°. In this embodiment, the maximum angle is 30°.

In order to achieve this adjustable inclination, the variable adjustment means 130 comprise a gear 131 located on the platinum. The transmission gear 131 is rotatable relative to the platinum by means of driving means. The transmission gear 131 has a substantially spherical ring gear 181 configured to engage with the radial gear 129 of the adjusting member 100 to actuate it.

The transmission gear 131 is similar to or even identical to the first transmission gear of the carousel. It has a cylindrical shape, while the ring gear 181 on its peripheral surface is spherical, which allows located on the radius of the gear wheel 129 to engage with the transmission gear 131, regardless of the inclination of the conventional adjusting element. Such a ring gear 181 facilitates engagement with the radial gear 129 regardless of the orientation of the radial gear 129 relative to the pinion 131.

The transmission gear 131 also has double cut teeth in which a concave spherical cut and a straight cut are combined. Straight cut means that the teeth of the transmission gear 131 are substantially the same width throughout the straight cut portion.

Thus, the transmission gear 131 has a straight tooth portion 180 so that it can cooperate with the gear. Plot 180 is located above the concave peripheral surface.

In addition, the radial gear 129 preferably includes a peripheral ring gear 182 whose teeth are inclined relative to the plane of the radial gear 129 to engage with the straight cut teeth 180 of the transmission gear 131.

The variable adjustment means 130 comprise a single gear 131 which only drives the trigger. The tilt actuating means are identical to the tilt actuating means described with respect to the carousel and the tourbillon.

The transmission gear 131 is driven by the drive means through a system of 98 gears. To this end, the drive means comprise a gear wheel which directly drives the transmission gear 131 via straight teeth 180, as in the case of the first transmission gear for the carousel. Alternatively, the drive means may comprise an internally toothed crown wheel disposed around the conventional adjuster carriage 102 so that it can drive the transfer gear 131 as the crown wheel rotates around the conventional adjuster carriage 102, as is the case with the second gear. carousel gear.

Thus, due to the rotation of the transmission gear 131, the crown wheel or gear provides movement of the escapement and balance in the carriage 102 of the conventional adjuster 100. In this embodiment of the conventional adjuster 100, the carriage 102 of the conventional adjuster does not move relative to the tilt bridge 107.

The variable adjustment means 130 for variable adjustment of the inclination of the adjusting element 100 comprises an inclined bridge 107 on which a conventional adjusting element carriage 102 is mounted. The tilt bridge 107 can be tilted to select the tilt of the adjuster 100. The tilt bridge 107 is located under the carriage 102 of the conventional adjuster.

The tilt bridge 107 is similar or identical to the carousel tilt bridge of the first embodiment.

The tilt bridge 107 is mounted so that it can pivot about a pivot axis D ₃ passing through a conventional adjusting member, the pivot axis D ₃ being parallel to the tilt bridge 107. The tilt bridge 107 comprises a longitudinal main plate 97 with a central hole and posts at the ends of the plate 97 Each strut comprises outer axles 187, 188 located along the axis of rotation D ₃ on both sides of the carriage 102 of the conventional adjuster and cooperating with two platinum supports.

Other features are identical to those of the carousel bridge 1 with tilt bridge 107, wherein tilt bridge 107 also includes an auxiliary plate 99. The actuating means comprise a wheel 185 rigidly mounted on tilt bridge 107, and actuation of wheel 185 causes tilt bridge 107 to tilt.

The actuating means comprise a wheel 185 rigidly mounted on the tilt bridge 107, and actuation of the wheel 185 causes the tilt bridge 107 to tilt. parallel to the D axis ₃ turns. The slanted ring gear 145 interact with the actuating means. The driving means are engaged with the wheel 185 so that the tilt bridge 107 rotates about the pivot axis D ₃ .

The tilt actuating means are identical to the tilt actuating means of the carousel 1 and tourbillon 10 embodiments.

It goes without saying that the invention is not limited to the embodiments of the control elements described with reference to the drawings, and other embodiments of the invention that fall within the scope of the invention may be taken into account. In particular, the at least partially movable elements can be, for example, an automatic device or a movable decorative piece, such as a diamond, or an Earth rotation indicator, or a day/night indicator, which can be tilted depending on preference. The at least partially movable element may also be a moon phase indicator, a date indicator, a power reserve indicator, a chronometer minute counter, or even a hidden dial window or GMT dial. Said element may also be a small seconds dial, for example made of a precious stone, which can be seen from different angles due to means for adjusting the inclination of said element.

Claims (16)

1. Clockwork containing platinum (33) continuing essentially in the first plane, and the platinum (33) is configured to support other parts of the clockwork, such as at least partially movable element, and the specified element continues at least partially in of the second plane, while the clockwork contains drive means, including a system (98) of gears, and the specified element contains a drive ring gear that ensures its actuation, characterized in that it contains means (30, 40, 130) of an alternating adjustments intended for variable adjustment of the inclination of the specified element relative to the platinum (33) so that the second plane forms a variable angle with the first plane of the platinum (33), and the variable control means (30, 40, 130) include a transmission gear (80, 131) or the first transmission gear (31) located on the platinum (33) and designed to interact with the drive gear rim of the specified element, while the transmission gear (80, 131) or the first transmission gear (31) is rotatable relative to the platinum ( 33) by means of driving means, wherein the transmission gear (80, 131) or the first transmission gear (31) has a concave peripheral surface containing a substantially spherical ring gear (32, 81, 181) designed to engage with the ring gear of the specified element, to actuate it regardless of the orientation of said element relative to the platinum (33). 2. The clock mechanism according to claim 1, characterized in that the transmission gear (80, 131) or the first transmission gear (31) includes double cut teeth, in which a concave spherical cut and a straight cut are combined. 3. The clock mechanism according to claim 1 or 2, characterized in that the means (30, 40, 130) of variable regulation, intended for variable regulation of the inclination of the specified element (1, 10, 100), contain a carriage (2, 55, 102) , which contains the specified element (1, 10, 100). 4. Clock mechanism according to claim 3, characterized in that the carriage (55) contains an external gear rim (77), which acts as a gear rim designed to actuate the specified element, and the outer gear rim (77) is configured to engagement with the transmission gear (80) regardless of the inclination of the adjusting element (10), while the transmission gear (80) causes the carriage (55) to rotate. 5. The clock mechanism according to claim 1 or 2, characterized in that the variable control means (30, 130) comprise a gear wheel (29, 129) located on the radius, mounted on the specified element, and the gear wheel (29, 129) located on the radius ) contains a peripheral ring gear (34, 182), which acts as a ring gear designed to actuate the specified element, while the essentially spherical ring gear (32, 181) of the concave peripheral surface of the first transmission gear (31, 131) is in engagement with a gear wheel (29, 129) located on the radius, regardless of the inclination of the specified element (1, 100). 6. Clock mechanism according to claim 5, characterized in that the teeth of the peripheral ring gear (34, 182) are inclined to interact with the ring gear (32, 181) of the transmission gear (131) or the first transmission gear (31). 7. Clockwork according to any one of paragraphs. 1-6, characterized in that the drive means contain a gear wheel (20) for the transmission gear (80, 131) or the first transmission gear (31), while the specified gear (20) is made with the possibility of interacting with the section (23, 131 ) the straight teeth of the gear (80, 131) or the first gear (31). 8. Clockwork according to any one of paragraphs. 1-7, characterized in that the means of variable regulation contain a second transmission gear (35) located on the platinum (33), and the second transmission gear (35) is made rotatable relative to the platinum (33) using drive means, while the second transmission gear (35) has a concave peripheral surface with a substantially spherical ring gear (37), and the carriage (2) contains an external gear ring (36), made with the possibility of engagement with the second transmission gear (35) regardless of the inclination of the specified element, and the second transmission gear (35) limits the rotation of the carriage (2). 9. Clock mechanism according to claim 8, characterized in that the second transmission gear (35) contains double cut teeth, in which a concave spherical cut and a straight cut are combined. 10. The clock mechanism according to claim 8 or 9, characterized in that the drive means comprise a crown wheel (38) with an internal gear ring (24) located around the specified element so that it is engaged with the second transmission gear (35). 11. Clockwork according to any one of paragraphs. 8-10, characterized in that the two transmission gears (31, 35) are driven simultaneously by the drive means. 12. Clockwork according to any one of paragraphs. 1-11, characterized in that the angle of inclination of the specified element relative to the platinum (33) is in the range from 0 to 90°, preferably from 0 to 45° or even from 0 to 30°. 13. Clockwork according to any one of paragraphs. 1-12, characterized in that the means (30, 40, 130) of variable regulation, designed for variable regulation of the inclination of the specified element, contain an inclined bridge (7, 57, 107), on which the specified element is installed, and the inclined bridge (7, 57, 107) is made with the possibility of inclination relative to the platinum (33). 14. Clock mechanism according to claim 13, characterized in that it contains means for tilting the inclined bridge (7, 57, 107). 15. Clockwork according to any one of paragraphs. 1-14, characterized in that the specified element is a control element (1, 10, 100) having an inertial mass (3, 56, 103), a guide and an elastic return element (4, 68, 104) for the inertial mass (3, 56, 103), made with the ability to cause its oscillations in the second plane, as well as the trigger (25, 69, 125) interacting with the inertial mass (3, 56, 103), moreover, the control element (1, 10, 100) is located on platinum. 16. A watch containing a clockwork according to any one of paragraphs. 1–15.

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