RU2577501C2 - Movable support for anti-shock device for wheel system of clock mechanism - Google Patents

Abstract

FIELD: physics; clocks.

SUBSTANCE: clock mechanism includes a movable support (70) of an anti-shock device for the wheel system, formed from an elastic device (72) having a rigid central part (74) and an elastic structure (26), connected to the said central part and extending at its periphery, wherein the central part has an opening in which there is a jewel hole (10), which is physically connected to the clock mechanism by the elastic structure. The said movable support also includes an end jewel (82) which forms an upper support for the journal for the balance shaft of the wheel system and is assembled with the said central part to move together. The movable support is characterised by that the jewel end extends at least partly above the elastic structure and is attached to the central part by a physical connection between the central part and the lower surface (83) of the jewel end. Preferably, the said lower surface of the jewel end forms the first vertical surface (86) and the central part of the elastic device forms the second vertical surface (76) lying opposite the first vertical surface.

EFFECT: improved design.

15 cl, 13 dwg

Description

FIELD OF THE INVENTION

The present invention relates to a movable support of a shockproof device for a clockwork wheel system. It is assumed that these movable bearings should partially absorb the energy transmitted to the wheel system in the event of an impact, in particular when the clockwork is subjected to lateral impact.

State of the art

Specialists in this field are known for various movable bearings of shockproof devices used in the watch industry. Figures 1 and 2 show a movable support of the standard type currently used in numerous clockworks. The movable support 2, called the support with a "double inverted cone", is described, for example, in patent FR No. 1532798. This movable support is located at the end of the balance axis 6 of the wheel system 4. In particular, the pin 8 of the balance axis 6 is installed in the hole of the through stone 10 forming the movable support 2. The movable support is formed from a bridge 12 with a central hole in its lower part for passage of the axis 6 balance wheel system. The bridge 12 has a recess, within which a base is installed. At this base, there is a through stone 10 and a laid stone 16 mounted above the through stone. The base and two stones are held inside the recess of the bridge 12 by a spring device 18, which, in the embodiment shown in FIGS. 1 and 2, includes two elastic legs that abut against the upper surface of the laid stone. It is believed that a movable support of this type has an attractive appearance, in particular, due to the presence of an overhead stone of relatively large diameter. In fact, the laid stone contributes to the attractive appearance of the clockwork and can be considered as a decorative element of the clockwork. Specialists in this field will appreciate the movable support of the standard type shown in Fig.1 and 2.

Figure 3 and 4 shows another movable support shockproof device described in patent No. 1696286. According to this second known embodiment, this movable support essentially differs from the conventional type of support described above in that the through stone 10 and the overlay stone 16A are assembled with the central part 28 of the smooth elastic device 22, i.e. continuing in a common plane. Thus, two stones are suspended in the center of an elastic device, the elastic structure or spring 26 of which is capable of undergoing axial and radial elastic deformation, i.e. in the general horizontal plane, as well as in the longitudinal direction of the axis 6 of the balance of the wheel system. This second embodiment has certain advantages over the typical movable support of the shockproof device described above, which are presented in patent application EP No. 1696296.

The elastic device 22 is formed by a peripheral ring 24 resting on an annular protruding portion provided in the lower part of the recess in the base 12A. The elastic structure 26 is formed of several elements representing a plurality of spring elements that extend along a circular arc between the peripheral ring 24 and the central part 28 of the elastic device 22. This central part has a central hole in which the through stone 10 is located. A patch stone 16A located on the upper surface of this central part, is held in place by a cover 30, which has holding brackets 32 that extend along the side surface centrally th part. The cover may be screwed or glued to this central part.

It should be noted that the resilient structure 26 has a relatively complex geometry with many spring elements connecting the peripheral ring 24 to the rigid central part 28. Thus, the resilient device 22 is preferably manufactured using LIGA technology known to those skilled in the art.

As is clear from FIGS. 3 and 4, the movable support 20 of the shockproof device has an unusual appearance. In fact, the top view shows the entire smooth elastic structure 26, and the overlay stone 16A is visible only through a small central hole in the lid 30. Thus, the diameter of the visible surface of this top stone 16A is essentially equal to the small diameter of the through stone 10. Comparing devices 2 and 20, respectively shown in FIGS. 1 and 3, the observer will notice a significant difference in the appearance of the two devices. As indicated above, the laid on stone of the movable support of the shockproof device in the running gear of a mechanical watch is decorative in nature and is used to increase the cost of the running gear of a mechanical watch. Despite the fact that the movable support 20 has a number of technical advantages and many functions, it has the disadvantage of significantly reducing the apparent diameter of the laid stone 16A.

Figure 5 shows the movable support 42 of the shockproof device according to the third embodiment according to the prior art, as described, in particular, in patent CH No. 254854. The movable support 42 eliminates the problem of a reduced diameter of the laid stone in the movable bearing 20 according to the second embodiment of the prior art described above. The movable support 42 includes a small thickness elastic device 22A that extends generally in a horizontal plane. Despite the fact that it has a completely different design compared to the elastic structure 26 of FIGS. 3 and 4, the elastic structure of the device 22A also provides elastic deformation in the horizontal plane and, thus, horizontal movement of the through stone 10. The elastic structure could also provide axial deformation. However, the embodiment of FIG. 5 does not take advantage of this characteristic of the elastic device 22A in contrast to the movable support 20 described above. In fact, the overlay stone 16 does not move together with the through stone and thereby the central part of the elastic device. This stone 16, which has a relatively large diameter, is located on the ring or support 46 on the peripheral part of the device 22A. The second elastic element 48 holds the stone 16 in place and allows it to move in the axial direction. This device 48 is formed from elastic tabs 50 resting on the convex upper surface of the stone 16. Since the elastic tabs 50 are spaced apart from each other, the stone 16 of the movable support 42 can be seen in a plan view through a large opening, so that the appearance of the movable support 42 similar to the appearance of the standard movable support 2 shown in FIGS. 1 and 2. However, to improve the attractiveness effect, which contributes to the improvement of the clock mechanism, the movable support 42 includes two different elastic their elements 22A and 48. The first elastic device is connected with the through stone 10, while the second elastic element is connected with the upper patch stone 16. Thus, the movable support 42 is relatively complex and expensive.

Disclosure of invention

The objective of the present invention is to eliminate the disadvantages of the existing prior art and, in particular, to offer a movable support shockproof device, which is efficient and inexpensive and has a standard appearance with a laid stone having a large diameter compared to the diameter of the through stone. In particular, the present invention provides a solution to this problem, while at the same time preserving the functional advantages provided by the movable support of the type shown in FIGS. 3 and 4.

Thus, the present invention relates to a watch mechanism provided with at least one movable support of the shockproof device for the wheel system, wherein the above movable support of the shockproof device includes an elastic device having a rigid central part and an elastic structure connected to the above central part and continuing at its periphery, while the central part has an opening in which there is a through stone, materially connected to the clockwork with using an elastic structure, so that the through stone is held in suspension by this elastic structure. The movable support of the shock-proof mechanism also includes a laid-on stone, which forms the upper stop for the axle of the balance axis of the wheel system and is assembled with the central part of the elastic device for joint movement with the above-mentioned central part, while the elastic structure is designed for radial / horizontal movement of the central part, which is a through stone, as well as the axial movement of the above central part, i.e. moving along the geometric axis formed by the balance axis of the wheel system installed in the movable support of the shockproof device. The clock mechanism is characterized in that the laid on stone is at least partially located above the elastic structure and that it is attached to the central part of the elastic device by means of a material connection between the above central part and the lower surface of the laid stone.

Due to the distinguishing characteristics of the invention, the movable support according to the invention includes an upper patch stone of a relatively large diameter and eliminates the disadvantages of the existing device shown in FIG. In fact, fastening a laid stone to the central part of the elastic device in which the through stone is located, by means of a material connection formed between the above central part and the lower surface of the laid stone, does not lead to a reduction in the diameter of the said laid stone. This is a major advantage of the present invention and allows relatively simple and inexpensive embodiments to be obtained.

According to a specific distinguishing characteristic of the invention, a gap is provided between the lower surface of the laid stone and the upper surface of the elastic structure, allowing the elastic structure to undergo a certain axial movement in the lower direction during the absorption of the axial impact. Thus, despite the fact that the patch stone is attached to the central part of the elastic device, continuing, in General, in the horizontal plane, the patch stone, at least partially, covers the elastic structure, while allowing the above structure to deform in the horizontal plane, perpendicular to the balance axis of the wheel system, and also in the axial direction.

According to a preferred embodiment of the invention, the lower surface of the laid stone includes a first vertical surface and the central part of the resilient device includes a second vertical surface opposite the vertical surface. These specific distinguishing characteristics are important when the watch is subjected to radial impact. The vertical surface of the central part forms a lateral stop for the vertical surface of the laid stone, so that a lateral or radial impact does not lead to the destruction of the material joint, in particular, the weld or adhesive joint between the laid stone and the central part of the elastic device. In a preferred embodiment, the first and second vertical surfaces are cylindrical, which allows easy machining, in particular of laid stone. In another specific embodiment, a gap is provided between the first and second vertical surfaces, filled with glue or soft solder.

Brief Description of the Drawings

Various embodiments and modifications of the present invention will be described below with reference to the attached drawings, given by way of non-limiting example, in which:

Figure 1 is a perspective view of the first existing movable support described above;

Figure 2 is a section from Figure 1 along the line II-II;

Figure 3 is a perspective view of the second existing movable support described above;

Figure 4 is a section from Figure 3 along the line IV-IV;

5 is a third embodiment of the existing movable support of the shockproof device described above;

6 is a section according to the first embodiment of the movable support of the shockproof device of the present invention;

7 is a section on the modification of the first embodiment;

Fig. 8 is a sectional view of a second embodiment of the invention;

Fig.9 is a modification of the second embodiment;

Figure 10 is another preferred modification of the second embodiment of the invention;

11 is a section according to a third embodiment of the invention;

12 is a modification of a third embodiment of the invention;

13 is a sectional view of a fourth embodiment of the invention.

The implementation of the invention

FIG. 6 shows a first embodiment of a clock mechanism 44 including a movable support 52 of a shockproof device for a wheel system 4. The movable support 52 includes a through stone 10 for accommodating a pin 8 of the balance axle 6 of the wheel system 4. It also includes an elastic device 56, which has a rigid central part 58 and an elastic structure 26 connected to the central part and extending along its periphery. The central part has an opening in which the through stone 10 is placed, and the aforementioned central part is actually connected to the clock mechanism by means of an elastic structure 26. The movable support 52 also includes an overlay stone 16 forming the upper stop for the journal 8. The elastic device 56 and the stones 10 and 16 are located inside the recess in the base or support element 54. The elastic device 56 also includes an annular peripheral part 24, which is supported by an annular shoulder provided in the lower part of the recess in the base 54. The elastic device 56 can be held at the base 54 by various methods known to those skilled in the art. This device 56 can be screwed into the recess in the base 54 or glued or welded to it. The patch stone is assembled with the central part 58 so that it moves together with the above central part. Thus, the central part 58 serves as a support for the through stone 10, as well as for the laid stone, and this assembly is suspended in the movable support 52 using an elastic structure 26.

According to the invention, the overlay stone 16 extends, at least partially, over the resilient structure 26 and is attached to the central part 58 by means of a connection between the above-mentioned central part and the lower surface 17 of the above-mentioned overlay stone. In the embodiment shown in FIG. 6, the joint between the patch stone 16 and the central portion 58 is formed by the adhesive joint 60. Preferably, the adhesive joint 60 has a certain thickness to form a gap 62 between the smooth bottom surface 17 of the patch stone 16 and the smooth upper elastic surface structures 26. The width of the gap 62 is preferably substantially equal to or slightly greater than the gap between the elastic structure 26 and the bottom of the recess in the base 54. This prevents a situation in which the outer edge the fine stone 16 can abut against the elastic device 16 in the event of an axial impact, which could cause the detachable stone 16 to detach and, thereby, the material connection between the patch stone and the central part of the elastic device. Thus, the gap 62 allows the node formed by the Central part 58, the through stone 10 and the overlay stone 16, to undergo a certain movement in the lower direction during the absorption of axial impact.

As shown in FIG. 6, the laid stone 16 has a large diameter compared to the diameter of the through stone 10. Due to the distinguishing characteristics of the invention, the diameter of the laid stone can only be slightly smaller than the diameter of the recess in the base 54. In particular, it is possible to provide a sufficiently large diameter of the laid stone to completely close the elastic structure 26.

7 shows an embodiment of the first embodiment described above. The characteristics described above will not be described in detail again. The movable support 64 of the shockproof device is different from the movable support 52 of FIG. 6 in that the elastic device 66 includes a rigid central portion 58A whose height is greater than the height of the elastic structure 26. The patch stone 16 is attached to the central portion 58A by means of a weld / soft solder 61. To provide a durable weld, the bottom surface 17 of the patch includes an adhesive or primer layer applied to at least a portion provided for the weld, i.e., at least an annular portion opposite the central portion 58A. This adhesive layer is formed, for example, of chromium (Cr). A thin layer of gold (Au) is preferably applied to the adhesive layer. Then a soft solder is applied, for example, a gold-tin alloy. This soft solder can be applied either to the patch stone 16 on top of the adhesive layer and the gold layer, or to the upper surface of the central part 58A formed, for example, of nickel (Ni) or nickel phosphorus (NiP). The supply of heat necessary for welding can be carried out in various ways known to specialists in this field. In particular, welding may be performed in a furnace. It should also be noted that the anti-diffusion layer, for example rhodium (Rh), is preferably applied to the adhesive layer provided on the patch stone and / or on the upper surface of the central part.

On Fig shows a second preferred embodiment of the present invention. The movable support 70 of the shockproof device includes an elastic device 72 located at the base 54. The elastic device 72 is similar to the elastic device of the first embodiment. It has a difference in the central part 74, the upper surface of which has a recess forming a vertical cylindrical surface 76 and an annular shoulder 77. This shoulder 77 is essentially at the level of the upper surface 80 of the elastic structure 26, so that the central part 74 has a protruding upper section 78 relative to the above upper surface. The bottom surface 83 of the laid stone 82 also has a recess forming a protruding lower section 84, the side surface 86 of which forms a cylindrical vertical surface opposite the vertical surface 76 of the central part 74. The edge of the section 84 of the laid stone 82 rests on the shoulder 77. Between the above shoulder and the laid on a stone may provide a film of glue or soft solder. The vertical surface 76 forms a lateral stop for the lower section 84 of the laid stone in case of side impacts of the clock mechanism in which the movable support 70 is mounted. The counter recesses in the central part 74 and the laid stone, on the one hand, provide easy centering of the laid stone when it is assembled with the central part, and, on the other hand, prevent the shearing of the laid stone and the central part when the clockwork is subjected to side impacts, i.e. radial impacts of the wheel system 4. This second embodiment provides a relatively large gap 62A between the lower surface 83 of the laid stone and the upper surface 80 of the elastic structure. The patch stone is attached to the central part 74 by means of an adhesive joint 88 or a weld. Preferably, the gap between the cylindrical surfaces 76 and 86 is filled with glue 88 or soft solder.

Figure 9 shows an embodiment of a second embodiment of the invention. The characteristics described above will not be described in detail again. The movable support 90 is substantially different from the movable support of FIG. 8 in that the vertical surface 76A of the center portion 75 of the elastic device 73 is formed by the side surface of the recess 92 provided in the center portion 75. The lower portion 84A of the overlay stone 82A is partially inserted into this recess 92. In this embodiment, the upper surface of the elastic device 73 is smooth and has no protruding portions. In another embodiment, which is not shown, two variants of Figs. 8 and 9 are combined. Thus, the rigid central part of the elastic device has, on the one hand, a protruding upper part and, on the other hand, a recess along the inner periphery of this protruding part. This means that the protruding upper part 84A of the laid stone has a large thickness and, in particular, the radial overlapping portion of the vertical surfaces 86 and 76 + 76A can be increased.

Figure 10 shows a preferred embodiment, which differs from previous versions in that the elastic device 56 has a smooth upper surface 80 at the same level and that the overlay stone 82B has a protruding lower portion 84B, the diameter of which essentially corresponds to the diameter of the through stone. This portion 84B is inserted into the hole passing through the central portion 58, and thus the cylindrical vertical surface 86B is located opposite the upper wall portion of this through hole. The lower surface 83B of the laid stone has a first recess forming, on the one hand, the lower part 84B and, on the other hand, the annular portion 134, which is glued or welded to the upper surface 80 of the central part 58. In the case of the movable support 130 shown in FIG. 10, this lower surface 83B has a second recess 132 to create a sufficiently high gap 62 between the resilient structure and the overlay stone. In another embodiment, which is not shown, as in the example of FIG. 6, a sufficiently thick layer of glue or soft solder / hard solder is provided to create the required gap without additional machining of the laid stone. Thus, as in the examples of Figs. 8 and 9, the lower surface of the laid stone is only at two horizontal levels, but with a protruding lower section that is inserted into the hole of the elastic device in which the through stone is located.

It should be noted that the space between the through stone and the overlay stone forms a small chamber for lubricating oil, which remains in the center due to the capillary effect. For oil to enter the hole in the through stone, recesses are provided in the hole wall of the central part of the elastic device. Thus, the air contained in the chamber can be removed through these recesses on the periphery of the through stone when oil enters the hole in the stone. These side recesses also allow you to clean the grease chamber by flushing it. And finally, as indicated in patent application EP No. 1696286, where these recesses are shown in Fig.7, the side recesses provide a certain elasticity, allowing you to screw through the stone in the rigid Central part of the elastic device.

11 shows a third embodiment of the invention. The elastic device 72A differs from the elastic device 72 of FIG. 8 in that the protruding upper portion of the PBA is located in the inner zone of the central portion 74A. This protruding portion has a vertical side surface 96 forming a cylindrical surface. The bottom surface 100 of the laid stone 98 has recesses 102, the side wall 104 of which forms a cylindrical vertical surface opposite the cylindrical surface 96 of the central part 74A. This vertical surface 96 serves as a lateral stop of the upper stone 98. The movable support 94 of the shockproof device has the same advantages as the movable supports 70 and 90 of the shockproof devices described above. This movable support 94 has the additional advantage that the machining performed on the lower surface 100 of the laid stone 98 is performed in its central zone. This allows the laid stone to have a convex upper surface with a smaller radius of curvature compared to the radius of curvature of the stones 82 or 82A in the second embodiment described above. This third embodiment also allows you to accurately determine the height of the gap 62, increasing the space available for the through stone 10, so that the height of the elastic structure 26 could be lower than in the previous embodiment.

12 shows an embodiment of a third embodiment. The movable support 110 differs from the movable support 94 of FIG. 11 in that the central portion 58B of the elastic device 66B includes an annular upper portion 78B whose width is substantially equal to the width of the central portion 58B. In addition, this embodiment differs from the previous embodiment in that the overlay stone 112 has a groove 116 obtained by machining in the lower surface 114. In the first embodiment, the groove 116 is annular and has a slightly wider width than the width of the upper portion 78B. The last indicated portion is partially inserted into the groove 116 of the stone 112, which is attached to this upper portion with glue 88 or soft solder / hard solder. In the second embodiment, the widths of the grooves 116 and the annular portion 78B are adjusted so that the annular portion can be screwed into the groove 112. One of the advantages of the movable support 110 is that the bottom surface of the overlay stone is smooth except for the groove 116, so that this lower the surface could be easily polished in the area located above the axle of the axis of balance of the wheel system.

The groove 116 has an outer side surface 117 and an inner side surface 118. These two side surfaces 117 and 118 form vertical cylindrical surfaces that are located opposite the two corresponding vertical surfaces of the upper portion 78B of the central part of the elastic device.

And finally, FIG. 13 shows a fourth embodiment of the invention. This fourth embodiment differs from other embodiments mainly in the material connection provided between the cover plate 126 and the rigid center portion 58C of the elastic device 56C. The movable support 120 includes pins 124, which, on the one hand, are located in the holes provided in the central part 58C, and, on the other hand, in the corresponding holes obtained by machining in the upper stone 126. The pins can be pressed in, welded or glued to a laid stone 126. If glued, the holes obtained by machining in the upper stone 126 have a slightly larger diameter than the diameter of the pins 124. It should be noted that it is sufficient to install two pins, but edpochtitelno set three pins. The method of attaching these pins to the upper stone 125 by gluing has an advantage from the point of view of industrial production, taking into account the machining tolerances. Thus, if the holes have a diameter that slightly exceeds the diameter of the pins, the pins will fit into the corresponding holes in the patch stone more easily and the glue will fill the remaining space.

Specialists in this field may provide other options and, in particular, other means for the formation of a material connection between the laid stone and the Central part of the elastic device without deviating from the scope of the present invention.

Claims (15)

1. A clock mechanism comprising a movable support of a shockproof device for a wheel system (4); wherein the movable support of the shockproof device includes:
- the through stone (10) for placing the journal (8) of the balance axis of the wheel system;
- an elastic device (56; 66; 72; 73; 72A; 66B; 56C) having a rigid central part (58; 58A; 74; 75; 74A; 58B; 58C) and an elastic structure (26) connected to the above central part and continuing at its periphery, while the central part has an opening in which there is a through stone, materially connected to the clockwork using an elastic structure;
- a laid stone (16; 82; 82A; 82B; 98; 112; 126) forming the upper stop for the above axle of the balance axis and assembled with the above central part, so as to move together with the above central part;
characterized in that the laid stone extends at least partially above the above elastic structure and is attached to the above central part by means of a material connection between the above central part and the lower surface (17; 83; 83B; 100; 114) of the laid stone. 2. The clock mechanism according to claim 1, characterized in that a gap (62; 62A) is provided between the lower surface of the laid stone and the upper surface of the elastic structure, allowing the above elastic structure to undergo a certain axial movement in the lower direction during the absorption of the axial impact. 3. The clockwork according to claim 1, characterized in that the aforementioned lower surface of the laid stone has a first vertical surface (88; 88B; 104; 117; 118) and the aforementioned central part of the elastic device has a second vertical surface (76; 76A; 96) located opposite the first vertical surface. 4. The clockwork according to claim 3, characterized in that the above first and second vertical surfaces are cylindrical. 5. The clockwork according to claim 4, characterized in that between the above first and second vertical cylindrical surfaces there is a gap filled with glue or soft solder (60; 88). 6. Clockwork according to claim 4 or 5, characterized in that the aforementioned first vertical surface is formed by the outer lateral surface of the protruding lower section (84; 84A; 84B) of the laid stone. 7. Clockwork according to claim 4 or 5, characterized in that the aforementioned first vertical surface is formed by the lateral surface of the recess (102) formed in the lower surface (100) of the laid stone. 8. Clockwork according to claim 4 or 5, characterized in that the aforementioned first vertical surface is formed by one of two side surfaces of the groove (116) made in the lower surface (114) of the laid stone. 9. The clockwork according to claim 4 or 5, characterized in that the aforementioned second vertical surface is formed by a protruding upper section (78; 78A) of the aforementioned central part of the elastic device. 10. Clockwork according to claim 6, characterized in that the aforementioned second vertical surface is formed by the lateral surface of the recess (92) provided in the aforementioned central part of the elastic device. 11. Clockwork according to any one of claims 1 to 5, characterized in that the above patch stone is attached to the central part of the elastic device using an adhesive joint (88). 12. The clockwork according to any one of claims 1 to 5, characterized in that the above patch stone is attached to the Central part of the elastic device by welding. 13. Clockwork according to claim 12, characterized in that the adhesive layer is applied to the lower surface (17) of the laid stone, at least in the welding zone. 14. Clockwork according to claim 1 or 2, characterized in that the above laid-on stone is attached to the central part of the elastic device using pins (124) inserted, on the one hand, into holes (128) made by machining in the lower surface of the laid stone, and, on the other hand, into the holes provided in the upper surface of the Central part (58C) of the elastic device. 15. The clock mechanism according to claim 6, characterized in that the diameter of the above protruding lower section is essentially equal to the diameter of the through stone, while the above lower section of the laid stone is inserted into the above hole in the above central part of the elastic device.

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