RU2456658C2 - Coaxial clock mechanism - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: clock mechanism has an energy storage, systems fitted with time display elements, apparatus for kinematic connection for increasing or reducing transmission ratios between different systems and an adjustment element. The energy storage, systems and adjustment element are placed coaxially. Each system has the shape of a cup, each cup having a different diameter in order to allow partial insertion of one into the other(s). The clock mechanism also has a differential placed coaxially to the energy storage to provide kinematic connection of the energy storage with one of the cups through a main shaft and a main bushing, placed coaxially to the main shaft, wherein said bushing is meant for holding the other cup(s), as well as said apparatus for kinematic connection. One of the cups can contain a second system inside of which the adjustment element is fitted.

EFFECT: reduced size of the clock mechanism.

10 cl, 17 dwg

Description

The invention relates to watchmaking, in particular to a coaxial clockwork.

A standard clock mechanism contains a spiral spring box (energy storage element), a gear wheel mechanism (transmission organs), a trigger mechanism (energy distribution organ) and a spiral balancer (regulatory organ). These elements are usually mounted on a plurality of shafts that are distributed throughout the platinum or at designated locations. In this configuration, the consequence of combining these elements is to determine the boundaries of reducing the size of the clockwork.

EP0681227 discloses a mechanical watch component comprising a watch system as well as a minute system, each system consisting of a transparent disk onto which the minute hand and the clock hand are respectively deposited. A feature of this watch part is a rotor located in the center and installed coaxially with the hour, minute systems and coil spring box.

In addition, two indicator discs contain at their periphery a rim made of metal material and having a shoulder for receiving a corresponding disc. The drive rims are glued to the indicator discs and each contain a peripheral outer toothed radial crown.

The gear ratios between the gearbox and the rotor are increased due to the first gear of the wheel mechanism, while the gear ratios between the gearbox and the indicator discs are provided by the second gear of the gear mechanism meshed with the radial gear ring of the drive rims.

Various shafts containing wheel mechanisms of the first and second gears are mounted on a platinum outside the perimeter, inside of which there is a spiral spring box and a rotor support. The placement of some wheel mechanisms is carried out outside the periphery of this zone to enable interaction with various drive rims located around the periphery of the indicator discs.

As a result of this, despite the fact that the coil spring box, time indication bodies, and also the rotor are located in the center of the clock mechanism, the size of the latter is still not reduced, since the transmission of the peripheral wheel mechanism is important to ensure adequate rotation of various organs.

Thus, the present invention is the development of a coaxial clock mechanism, which can significantly reduce the size of the clock mechanism.

The problem is solved by the clock mechanism according to paragraph 1 of the claims. This clock mechanism contains an energy accumulator, systems of movable elements associated with time display organs, kinematic communication means providing an increase or decrease in gear ratios between various mobile systems and a regulatory body. The energy accumulator, mobile systems and regulatory body are placed coaxially. Each movable system has a shape approaching a cup shape, with each cup having a different diameter in order to be partially inserted into one another or one into another. The clock mechanism further comprises, in addition, a differential coaxially coupled to the energy accumulator to provide kinematic connection of the energy accumulator with one of the cups using the main shaft and the main sleeve mounted coaxially around the main shaft, while the said sleeve is designed to hold another or other cups , as well as the said means of kinematic communication. Preferably, one of the cups corresponds to a movable second system within which a regulatory body is located.

The invention is further explained in the following description, which is not restrictive, with reference to the accompanying drawings, in which:

figure 1 depicts an exploded view in perspective view of the clock mechanism of the present invention,

figure 2 depicts an exploded view of the clockwork in front,

figure 3 depicts a front view of the assembled clockwork,

figure 4 depicts in detail the view of figure 3, representing part of the differential box spiral spring,

figure 5 depicts a top view of the clockwork,

Fig.6 depicts a partial sectional view of Fig.5 along aa,

Fig.7 depicts a partial detailed view of Fig.6,

Fig.8 schematically depicts a top view of a system of minutes, hours or an additional system,

Fig.9 depicts a front view of Fig.8 with a partial section,

figure 10 depicts an enlarged scale of figure 9,

11 depicts an exploded view in a perspective view of the planetary gear planetary gears with retaining elements,

Fig.12 depicts a top view in a perspective view of Fig.11,

Fig.13 depicts a top view of a planetary gear train with a partial cutaway,

Fig.14 depicts a front view of Fig.13 with a partial cutaway,

Fig.15 depicts a bottom view of Fig.13,

Fig.16 is a schematic exploded view of a differential of a coil spring box,

Fig depicts in a perspective view of the differential minutes, hours or additional.

In accordance with the main embodiment of the invention, the mechanical clockwork comprises a system of seconds (1), minutes (2) and hours (3), all three of which are located in the corresponding cup. These cups (1, 2, 3) are placed coaxially with the spring box (4) and the spiral balancer (5, 6) of the clockwork. According to FIGS. 3 and 6, a cup of seconds (1) is placed inside a cup of minutes (2), while the latter is partially placed in a cup of watches (3).

The energy of movement necessary for work is provided by the box (4). The latter is kinematically connected to one of the ends of the main shaft (7) by means of the differential (8) of the box, which allows you to increase the stroke of the box (4) using the means described below.

As can be seen in Fig. 16, this differential of the box (8) held by the caliper (8 ') (Fig. 2) is formed by a central annular part intended for precise placement on the main fixed sleeve (15) mounted coaxially with the main shaft (7) ) and rigidly connected to the platinum (16) clockwork. This differential (8) is equipped with three rods (9), made radially around the periphery of the central part through 120 ° one relative to the other. The bevel gear (10), made with the first and second diameters (10 ', 10 ”), is freely mounted on each shaft (9).

In accordance with FIG. 4, a part of the gear with a smaller diameter (10 ') is engaged with the gearbox wheel (11), while a part of the gear with a larger diameter (10 ”) is engaged with a disk (12) provided with an annular rack (12 '), while said disk (12) is rigidly connected to the main shaft (7) (Fig.6). The number and distribution of gears (10) is determined in such a way as to even out the distribution of mechanical stresses around the circumference of the cremallera (12 ') of the disk (12).

The gear ratios between the coil spring box wheel (11), the gears (10) and the rack (12 ') are selected to give a rotation of 360 ° per minute to the main shaft (7).

As shown in FIGS. 6 and 7, the seconds cup (1) is located on the upper part of the clock mechanism and is rigidly connected to the upper end of the main shaft (7). The spiral balancer (5, 6) and the trigger mechanism, which is meshed with the spiral balancer (5, 6), are placed inside the cup (1) and are fully visible from the clock face, as shown in Fig. 5. The advantage of this special arrangement is the mutual rotation of the spiral balancer (5, 6) and the trigger mechanism, which also performs the function of the central rotor, while the cup of seconds (1) can be connected to the support of the rotor.

From Fig.6 it is seen that the gear wheel (13) of the trigger mechanism is installed with the possibility of interaction with the gear rim (14) located under the cup seconds (1). The base of this rim (14) is directly placed on the main sleeve (15). The gear rim (14) is thus stationary, and the trigger gear (13) is configured to rotate 360 ° per minute around the circumference of said rim (14).

As shown in Fig.6, the annular clutch disc of the installation of the hour (17), made of graphite, is placed coaxially and rigidly connected to the cup seconds (1) using pins (18). This disk (17) thus makes one complete revolution around the main sleeve (15) every 60 seconds. This disk (17) performs the function of coupling with another disk (19), also made of graphite and which is part of the planetary transmission system, which will be described below.

Castings of annular disks (17, 19) are made with increased roughness of the surface texture. This allows both disks (17, 19) to mutually engage, without causing jerks of engagement in the mechanism, when the latter are in contact to transfer force normally to different cups (1, 2, and 3). When these two discs (17, 19) are in a disengaged state, the set of cups (1, 2, 3) can be moved along the main sleeve (15) to set the time on the clock using an appropriate device.

The clock mechanism comprises a first planetary gear system formed by elements schematically depicted in Figs. 8-15 to reduce the course of the cup seconds (1), so that the cup minutes (2) makes one revolution all the time.

This planetary clutch system is formed by an annular disk (19) of graphite, as shown in Fig. (11), equipped with three axes (20) located perpendicular to said disk (19) to its periphery through 120 ° one relative to the other, with the three said satellite wheels minutes (21), freely mounted on each end of the axles (20), with a toothed rim (23) placed around the inner circumference of the cup of minutes (2) near its base, as shown in Figs. 8-10, and also with a gear of minutes (22) ) mounted on the main sleeve (15) of the clockwork (f D.7 and 8).

In addition, three ring disks (24, 24 'and 25) are laid on top of one another and are coaxially mounted on the main sleeve (15) from the bottom of the graphite disk (17), which is rigidly connected to the second cup (1). 11 shows that the outer diameter of the upper and lower disks (24 and 24 ') is slightly larger than the outer diameter of the middle disk (25) to create an annular groove (26) so that the inner circumference of the annular graphite disk (19) is clamped in this groove (26). Figure 10 shows this groove 26 despite the fact that this drawing schematically depicts the holding of one of the cups (1, 2, 3) on the main sleeve (15) of the clock mechanism in the same manner. The contact surfaces between the graphite disk (19) and the groove (26) are machined over the surface in order to minimize the coefficient of friction. Preferably, the three ring disks (23, 24 'and 25) contain a teflon coating. The graphite disk (19) can also rotate around its axis of rotation with a minimum of friction.

As shown schematically in FIG. 13, the three minutes satellites (21) are meshed on one side with the fixed gear (22) and on the other side with the rim (23) of the minutes cup (2). The rotation of the disk (19) results in the orbital rotation around the main hub (15) of three satellites (21), while the latter rotate the cup for minutes (2).

The gear ratios of the gears between the gear wheel (22) and the rim (23) are selected so that the cup minutes (2) made one 360 ° rotation every hour.

In order to keep the watch cup (2) at a sufficient height on the main sleeve (15) and, on the other hand, rotate around its axis, three ring disks (24 ', 24 ”and 25'), similar to those used for drive into rotation of the disk (19) around its axis of rotation (11), superimposed on one another and coaxially mounted on the main sleeve (15) from the bottom of the gear wheel (22). In accordance with Figs. 9 and 10, the cup of minutes (2) contains a protrusion (27) around the entire inner circumference intended for placement in a recess (26) obtained by connecting three ring disks (24 ', 24' and 25). The cup of minutes (2) is preferably ceramic, while the annular discs (24 ', 24' and 25) contain a Teflon coating to minimize friction. A cup of minutes can also be rotated around its axis with minimal friction.

As can be seen from Fig.6, the diameter of the cup minutes (2) exceeds the diameter of the cup seconds (1) so that the latter can be installed coaxially and partially inside the mentioned cup minutes (2).

In accordance with Figs. 14 and 15, the lower part of this cup of minutes (2) contains an annular cremallera (28) designed to engage the second planetary gear system using the differential of minutes (29), as shown schematically in Fig. 17. Three gears (10) of this differential (29) are intended for gearing from different sides of the annular rack (28) of the cup of minutes (2), and the ring rack, not shown in the drawing, is placed at the bottom of the disk (30) like a disk (19) and is an integral part of the second planetary gear. The latter contains elements similar to the elements of the first planetary gear system, namely three wheels, called clock satellites (31), freely mounted on each of the axes (20 ') of the disk (30), gears (23') placed around the inner circle cups of watches (3) near its base, as well as a gear wheel (22 ') of the watch mounted on the main sleeve (15) of the clock mechanism.

By analogy with the first planetary gear system described above, this second planetary gear system allows you to reduce the progress of the cup minutes (2) so that the cup clock (3) performs one revolution every 12 hours.

The clock mechanism may also contain one or more additions. For example, an annular cremallera (32) can be provided at the bottom of the watch cup (3) near its periphery in order to kinematically connect the mentioned watch cup with the days cup (not shown in the drawing) via the watch differential (33) (Fig. 6) and an additional planetary gear systems, similar to those described above, to enable the indication of the day of the month. In the case of the drawing, the diameter of the cup of the watch (3) is smaller than the diameter of the cup of days so that it can be partially inserted inside the latter.

The display elements for seconds, minutes, hours (1 ', 2', 3 ') and, if necessary, the month numbers are rigidly installed on the cup of seconds, minutes, hours (1, 2, 3) and, if necessary, days of the month.

As can be seen in FIGS. 1, 2 and 6, three holding rods (34) are placed on the platinum (16) around the central sleeve (15) of the clock mechanism with an offset of 120 ° one relative to the other. These rods (34) allow you to distribute the mechanical forces arising in the clockwork, and to strengthen the structure that holds the various components of the clockwork.

In particular, the differentials of the coil spring box, minutes and hours (8, 29, 33), holding discs (24, 24 ', 25), planetary gear systems and gears (22, 22') contain three holes (35) in in accordance with the position of the three holding rods (34).

It follows that the invention is not limited to the exemplary embodiment presented above. As an example, the rotor / second cup (1) can be made of any height on the main sleeve (15), while the position of the cups (1, 2, 3) and accessories depends only on the design of the clockwork. The gear ratios of the gears are selected depending on the position of the cups (1, 2 and 3).

Claims (10)

1. A clock mechanism containing an energy accumulator (4), systems (1, 2, 3), on which time indication elements (1 ', 2', 3 ') are placed, kinematic communication means for providing an increase or decrease in gear ratios between different systems (1, 2, 3) and a regulator (5, 6), while the energy accumulator (4), systems (1, 2, 3) and a regulator (5, 6) are installed coaxially, characterized in that the clockwork further comprises a differential (8) mounted coaxially with the energy accumulator for kinematic bind the energy accumulator (4) with the systems (1, 2, 3) using the main shaft (7), as well as the main sleeve (15) mounted coaxially around the main shaft (7), while the sleeve (15) is designed to to carry another or other systems (1, 2, 3), as well as the mentioned means of kinematic communication. 2. Clockwork according to claim 1, characterized in that the energy accumulator is a coil spring box (4), the regulating body being formed by a balancer and a spiral spring (5, 6). 3. The clock mechanism according to claim 2, characterized in that it contains a system of seconds (1), rigidly connected to one of the ends of the main shaft (7), the other end of which is engaged with said differential (8), designed to increase the stroke boxes (4) of a spiral spring for driving the system of seconds (1) per revolution per minute. 4. The clock mechanism according to claim 3, characterized in that the minutes system (2) and the clock system (3) are installed around the main sleeve (15) and placed under the seconds system (1) and under the minutes system (2). 5. Clockwork according to claim 4, characterized in that the system of days is located around the main sleeve (15) and placed under the system of minutes (2). 6. Clockwork according to any one of the preceding paragraphs, characterized in that the systems of seconds, minutes, hours and days (1, 2, 3) are combined with the corresponding cups. 7. Clockwork according to claim 6, characterized in that the spiral balancer (5, 6) is installed inside and in the center of the second cup (1). 8. The clockwork according to claim 6, characterized in that the cup of seconds (1), minutes (2) and hours (3) are partially set inside the cup, respectively minutes (2), hours (3) and days. 9. The clock mechanism according to claim 6, characterized in that the indicators of hours (3 '), minutes (2') and seconds (1 ') are rigidly connected to the cup of hours (3), minutes (2) and seconds (1), respectively along their respective outer perimeter. 10. Bracelet watch containing a clockwork according to claim 1.

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