CH707158B1 - Adjustable screw-in element, for example crown for timepiece. - Google Patents

Abstract

The invention relates to an adjustable screw-on element comprising a cover (11) and a device for adjusting the angular orientation of the cover (11) relative to a watch middle, characterized in that the device for adjusting the The angular orientation of said cover (11) comprises a first part (23) provided with a first flat friction surface (231), a second part (3) secured to the cover (11) provided with a second friction surface (31). ) plane and means of recall. The cover (11) and the first part (23) are movable axially relative to each other between a first position in which the cover (11) is integral in rotation with respect to the first part (23), and a second position in which the cover (11) is free to rotate around the axis of rotation of the adjustable element to be screwed, the return means tending to make the cover (11) and the first part (23) integral in rotation ) in this first rest position. This element can be, for example, a crown for a timepiece.

Description

[0001] The present invention relates to a device for adjusting the orientation of screwed elements for timepieces and more particularly for crowns comprising a pattern or a logo on their end face and in which the pattern can be oriented to wish.

[0002] Screw-down crowns are commonly used to equip watches with the aim of improving their watertightness at the level of their winding or control stem. This type of crown has the particularity of being able to take an unscrewed position in which the watch can be wound, set the time, etc. and a screwed position in which the crown is screwed and locked on a tube driven or screwed into the middle of the watch case in order to compress a seal, thus improving the watertightness of the watch. The screwed position is therefore the one which corresponds to the normal position when the watch is worn and which is more or less always the same except for wear of the seal.

[0003] The manufacture and assembly of these crowns screwed onto watch cases are well known. However, the assembly methods for these crowns are poorly suited to screw-down crowns bearing on their end face an inscription or a pattern, for example a logo, a trademark or a similar sign. In fact, the known assembly methods generally do not make it possible to bring the crown into a determined orientation relative to the case after they are screwed, which harms the aesthetics of the case when an inscription is affixed to the face of the case. end of the crown. This situation is of course unacceptable when these crowns are fitted to luxury and high quality products.

[0004] To remedy these drawbacks in terms of reliability of orientation of a logo, document EP1411401 describes a particular crown comprising, on its upper external face, a substrate orientable relative to a head formed by a central body and a side skirt, the substrate being provided with an inscription and being able to be separated in rotation from the head of the crown when pressure is exerted against the braking means. The disadvantage of this solution is that it requires, on the one hand, an unconventional crown structure according to which the orientable logo is not formed in one piece with the head of the crown; on the other hand, this solution is not very robust in relation to shocks, the latter being able to also exert a pressure force on the substrate and therefore reorient it unintentionally in relation to the body of the crown. When handling the crown, it is also necessary to take numerous precautions to avoid applying any pressure force towards the middle if we want to avoid involuntary rotation of the substrate, which makes its use quite inconvenient.

[0005] Several other solutions have been proposed with more conventional crowns, comprising a hollow cover on an external face of which the logo to be oriented is machined, and inside which the orientation device is arranged. According to document EP 1 124 167 A1 for example, a shape memory alloy ring is placed either between the middle part and a tube, or between the crown and a tube to adjust, in a determined position or orientation, a crown after screwing of it on the tube. By varying the deformation of the ring, in particular by reducing its diameter by subjecting the watch to specific temperatures, a temporary clearance between the middle and the tube respectively between the crown and the tube can be created, which allows an angular adjustment of the crown in its screwed position. A disadvantage of this solution lies in the additional bulk of the ring, which must be taken into account in the dimensioning of the orientation device, and determines an overall volume necessarily greater for the crown than for a standard crown. Furthermore, shape memory alloys are not commonly available in the form of small dimension bars, so that it is difficult and expensive to machine the rings in question in the small dimensions required for the applications concerned. Finally, this process is only intended for the initial assembly of the crown by the watch manufacturer, but not for subsequent operations to adjust the orientation of the crown, which could damage other parts of the watch. shows, sensitive to temperature variations.

[0006] Document EP2182417 proposes an alternative device for the orientation of a screwed crown with a logoed cover, comprising 3 tubes, two of which are mutually oriented relative to each other using teeth which are held in contact via a nut. This solution certainly allows corrections to the adjustment of the orientation of the crown after initial assembly by unscrewing the nut, but is particularly cumbersome because it requires a deeper opening inside the crown to place this nut there. . Furthermore, the orientation adjustment cannot be carried out in a modular manner on a crown separated from the case, since certain indexing elements are integral with a tube screwed into the middle.

[0007] Document EP1701225 describes an adjustable crown screwed with a conventional cover on which there is an inscription, and a head secured to a winding stem. The head and the cover are secured in rotation using frustoconical surfaces kept in mutual contact using an elastic element, and the adjustment of the angular position of the cover is carried out by axially withdrawing the latter relative to the middle along the longitudinal axis of the crown. Given that the solidarity in rotation of the cover relative to the head is ensured only by the friction forces between the frustoconical surfaces, these surfaces must extend over a very large surface area to guarantee the maintenance of the cover, particularly when the Compressive forces exerted by the elastic element gradually fade over the life of the watch on which the crown is mounted. This solution is therefore not suitable for crowns of very small size or reduced height.

[0008] The present invention aims to remedy the drawbacks of the aforementioned prior art by providing a device for orienting a screw-in element, such as a traditional crown, of simple and economical construction, comprising a pattern such as a logo or brand and in which the position of the logo or brand affixed to the end face of said element can easily be adjusted to a determined position or orientation and whose size can be reduced.

[0009] For this purpose, the subject of the invention is an adjustable screw-on element comprising a cover formed of a cover secured to a side skirt and a device for adjusting the angular orientation of the cover relative to a middle part. watch, characterized in that the device for adjusting the angular orientation comprises a first part provided with a first plane friction surface, a second part secured to the cover provided with a second plane friction surface and means for reminder. The cover and the first part are movable axially relative to each other between a first position in which the cover is integral in rotation with respect to the first part, and a second position in which the cover is free to rotate around of the axis of rotation of the adjustable element to be screwed, the return means tending to make the cover and the first part integral in rotation in this first position.

[0010] The advantage of the cooperation of plane friction surfaces, although not natural for those skilled in the art due to the reduction in contact surfaces that it implies, is that it provides an advantage of compactness to the element to be screwed. This solution is therefore particularly suitable for very small rooms.

[0011] According to a preferred embodiment, the direction of the forces exerted by the return means as well as their intensity are determined in such a way that this adjustment can only be carried out by the manufacturer during assembly or for example during a service, but not by the user of the watch himself, without the help of a tool. Thus any handling error and/or any untimely change of orientation, following for example an impact, can be avoided.

[0012] Other characteristics and advantages of the present invention will appear in the following description of a preferred embodiment, presented by way of non-limiting example with reference to the appended drawings, in which: – Figure 1 shows a view from above of a screw-on element in the form of an adjustable crown, provided with a logo on the external face of the cover of its hood; – Figure 2 shows a half-section view of the adjustable crown of Figure 1 provided with an orientation adjustment device according to a preferred embodiment of the invention, at rest; – Figure 3 shows a bottom view of the adjustable crown of Figure 1, showing more particularly the external sections of a piston and a barrel; – Figure 4 is a sectional view similar to Figure 2, the crown being shown in a position in which its cover is separated from the head in view of the angular orientation in a determined position of the pattern carried by the cover, in position separated from the middle.

[0013] In the preferred embodiment illustrated by all of the following figures, the adjustable element to be screwed consists of a crown designated by the general reference 1. In Figure 1, which is a top view of the crown 1, we can distinguish the applicant's "Oméga" logo L, arranged on the external face 113 of the cover 112 of its cover 11, inside which is housed the orientation adjustment device described later in using Figures 2 to 4. For aesthetic reasons, this L logo is adjusted in a perfectly horizontal position preferably corresponding to the plane of the middle of the watch on which the crown is mounted. In this figure we can also distinguish, on the outer periphery of the cover, a toothing D which aims to improve the grip of the crown 1 by the user during its use.

[0014] Figure 2 is a sagittal half-section view along the axis of rotation A-A of the crown, which reveals the orientation adjustment mechanism according to a preferred embodiment of the invention. The crown 1 is shown in the screwed position on a threaded tube 10, intended to be screwed into a middle part of a watch case - not shown - by means of a first thread 101, while a tapping 102 cooperates with the thread 21 of a central barrel 2 of tubular shape. According to an alternative embodiment, the tapping 102 of the tube 10 could however consist of a 2<e>thread and the thread 21 of the central barrel 2 could reciprocally consist of a tapping, as for a conventional crown screwed directly onto the tube. A first seal 103 is intended to be placed between the tube 10 and the middle part for sealing reasons.

[0015] The cover 11 is formed by a cover 112 and an axial skirt 111, which mutually define a central opening 115 inside the crown forming the screw element 1 - referenced only in Figure 3 for reasons of readability - and in which the end of the threaded tube 10 secured to the middle is arranged, but also the central barrel 2. According to the preferred embodiment illustrated, the central threaded barrel 2 consists of an intermediate element between the cover 11 of the crown 1 and the middle of the watch as well as a rod (not shown, but conventionally mounted on the lower end 93 of the piston 9 via the tapping 91 in a blind hole) interacting with the movement. In the screwed position on the tube 10, the orientation of the central barrel 2 is always identical with respect to the tube 10, and consequently by transitivity to the middle, in which the latter is also screwed via the first thread 101. C It is therefore the relative orientation of the central barrel 2 with respect to the cover 11 of the crown 1, which determines that of the pattern or logo L inscribed on the upper face 113 of its cover 112. This orientation of the central barrel 2 can be determined by acting on gear profiles 24, provided for this purpose and arranged on its lower part and a preferred shape of which is illustrated by Figure 3 described below.

The relative axial position of the central barrel 2 is variable relative to the cover 11, and it determines respectively an adjustment mode and a locked mode for the orientation of the crown 1. The locked mode for the angular orientation of the cover 11, referenced P1, is illustrated in Figure 2, while the mode of adjusting the angular orientation of the cover 11, referenced P2, is illustrated in Figure 4 described below.

The piston 9 housed inside the central barrel 2 can slide against a spring 5 abutting on an internal surface 114 of the cover 112 of the cover 11, and in particular makes it possible to bring out the cover 11 from the middle when unscrewing crown 1 from tube 2 when using it to adjust a function (e.g. resetting the time, adjusting the date or manually winding the movement). The axial travel of the piston 9 along the axis A-A of rotation of the crown 1 is limited by a stop 22 arranged at the bottom of the central barrel 2, on which a first shoulder 92 of the piston 9 is positioned. The piston 9 comes to a stop when the crown 1 is unscrewed from the tube 10, as illustrated in Figure 4 described below. A second seal 7, such as for example an O-Ring, is interposed between the threaded tube 10 and the axial skirt 111 of the cover 11 so as to guarantee sealing with respect to the internal elements of the crown; in the screwed position of the crown, this second seal 7 is held axially between a first ring 6, or spacer, and a second ring 8, also commonly called deckring, which covers it at the level of the lower surface of the crown 1. This second seal 7 is compressed on a portion of the tube 10, as shown in Figure 1. As an alternative, the two rings 6 and 8 holding the second seal 7 could be replaced by an annular groove formed in the axial skirt 111 of the cover 11 and which would be directed towards the screwed tube 10.

According to the invention, the cover 11 is assembled to the central barrel 2 so that they are usually integral in rotation, as in the rest position P1 illustrated in Figure 2; this assembly is made so as to be detachable or reversible. This solidarity in rotation is obtained via the first and second flat friction surfaces 231.31 preferably arranged on annular wear parts mounted respectively on the central barrel 2 and the cover 11 of the crown, such as for example a collar 23 fixed at the upper end of the central barrel 2 and an annular orientation piece 3 fixed on the inside of the cover 11 for example by welding, crimping or any other appropriate means. The flange 23 of the central barrel 2 and the annular orientation part 3 thus form a preferred embodiment for the first part and the second part secured to the cover 11 of the crown 1 on which the friction surfaces in mutual contact are arranged. The advantage of choosing wearing parts to arrange the first and second flat friction surfaces 231.31 is twofold: on the one hand it allows you to choose materials different from those of the cover 11 and the central barrel 2 for the collar 23 and the orientation part 3, with better tribological properties (such as for example a composite material, mixture of a metal alloy and a ceramic, of the DMC “dual matrix composite” type presenting particularly high friction coefficients) , and on the other hand such a modular construction makes it possible to replace only the necessary part of the parts worn by friction during possible overhaul or repair services.

Return means distinct from those associated with the extension of the piston tend to make the cover 11 and the central barrel 2 integral in rotation by exerting a compressive force F1 between the flange 23 and the orientation ring 3, and thus maintain the first and second friction surfaces 231.31 in mutual contact. According to the preferred embodiment illustrated, the return means consist of a flat spring 4, with a thickness E1 of a maximum of 0.2mm, arranged between a second shoulder 232 arranged on the flange and a third shoulder 1141 of a surface interior 114 of the cover 111, substantially flat. The depth E2 of the third shoulder 1141 makes it possible to define the maximum axial stroke of the central barrel 2 on which the flange 23 is fixed, while the second shoulder 232 arranged on the flange 23 makes it possible to provide a greater lever arm to the flat spring and thus deform more easily. The width of the shoulder makes it possible to adjust this lever arm and thus adjust the force to be applied to disengage the first and second friction surfaces 31,231 from one another. The height requirement inside the crown due to such return means is therefore equal to a maximum of 0.4mm, i.e. much less than with usual elastic springs, such as for example a curved spring. To further save space in height, it is also possible to arrange the second plane friction surface 31 not on a dedicated part such as the annular orientation part 3 but directly on an upper surface of the spacer, c that is to say the first ring 6. According to the illustrated embodiment, the force F1 exerted by the return means acts in the direction of the axis of rotation A-A, downwards, which would correspond to the interior of the middle for a crown in the mounted position. Such an orientation of the force F1 makes it impossible for the user to change the orientation of the crown 1, who can only act on the cover 11 and thus never generate a force F2 tending to remove the central barrel 2 from the tube 10, as explained below in light of Figure 4.

[0020] Figure 3 shows a bottom view of the crown along the cutting axis B-B illustrated in Figure 2. The peripheral part of this figure shows the central opening 115 of the crown 1 in which the screwed tube is engaged 10, while we can distinguish the lower end of the central barrel 2, which has an opening of hexagonal section. This opening is intended to cooperate with the lower end of the piston 93, inside which we can see the tapping 91 for the connection with a rod (not shown) interacting with the movement. The lower end of the piston 93 in this case also takes a hexagonal shape of corresponding size, such that the central barrel 2 and the piston 9 are integral in rotation at least in the orientation adjustment position P2 of the crown . The arrangement of a particular hexagonal section makes it possible to easily manipulate the angular orientation of the central barrel 2 when the crown is unscrewed from the tube 10, as in Figure 4 described in the following paragraph, with a tool such as a traditional 6-sided wrench . Other sections for the opening made in the bottom of the central barrel, of the type for example square or triangular, are also possible to carry out this manipulation, depending on the tool you wish to favor. Due to the torsional constraints between the piston 9 and the central barrel 2 when acting directly on the piston 9 to adjust the angular orientation of the crown 1, the preferred embodiment described provides for the arrangement of gear profiles 24 at the lower periphery of the central barrel 2 for its rotational drive using a key having teeth of corresponding shape engaged on the profiles. The number of profiles and their depth depends on the moment that we wish to apply torsion to the barrel, in Figure 3 we can distinguish 8 of them.

[0021] Figure 4 shows the crown 1 of Figure 2 in the adjustment position P2 because the return means used, here the flat spring 4, are compressed by application of a force F2, of direction opposite to the force F1, using a key 20 engaged on the gear profiles 24 of the central barrel 2 such that the first and second flat friction surfaces 231, 31 are no longer in mutual contact. The axial travel of the central barrel 2 is determined by the depth E2 of the third shoulder 1141 of the internal surface of the cover 114, which is of the order of at most a few tenths of a millimeter. All parts shown in Figure 4 are identical to those in Figure 2; it can however be noted that, contrary to Figure 2, the spring 5 of the piston 9 can extend since there is no longer any axial stress either via the thread 21 for the position of the cover 11 or by the indexed position of the winding stem on which the piston 9 is intended to be mounted. It can be noted, however, that it is not the compressed or extended position of the spring 5 of the piston 9 which determines in which position P1 of locking or P2 of orientation adjustment the crown is located, this position being defined solely by the position of the return means 4.

[0022] According to a preferred embodiment, the flat spring 4 is determined such that the passage from position P1 to position P2 requires the exercise of a force F2 against the return means 4 of an intensity twice greater than the force F1 exerted by the return means at rest, that is to say in the locking position P1, such that any accidental handling error is excluded for the orientation of the crown 1. In the case where the force F1 exerted by the flat spring 4 is of the order of 14 Newton, i.e. significantly greater than the force required to change the axial position of a conventional zipper, which in general is much less than a ten Newtons we can for example configure the plastic properties of the flat spring 4 such that it is necessary to exert a force of the order of 28 Newtons to adjust the orientation of the crown 1. In order to slightly reduce the value of the desired force F2, to obtain an intensity between 23 and 28 Newtons and thus facilitate the handling of the crown during adjustment operations it is also possible to perforate the flat spring 4. According to a variant, the element return can consist of a flat spring made no longer from an elastic material, but from a shape memory alloy (SMA), which would have the effect of replacing the restoring force F2 with a temperature gradient for release the rotation locking link. In this case, the transition temperature should be well below the usual operating temperatures, preferably below -30 degrees.

[0023] It will be noted that according to the preferred embodiment described in Figures 2 and 4, it is impossible for the user to make the adjustment once the crown 1 is assembled to the tube 2. In fact, the arrangement of the first friction surface 231 on the internal face of the collar 23 and the exercise of the force F1 towards the inside prevents on the one hand any separation of the cover 11 from the central barrel 2 when the user pulls on the cover 11 to move the crown 1 axially out of the middle, because the axial movement of the cover 11 in this direction then tends to press the friction surfaces one on the other. On the other hand, pressing the cover 11 towards the middle part would not make it possible to separate the friction surfaces from each other: if the crown 1 is not in its proximal position relative to the middle part, it that is to say the axial position as close as possible to the middle, the return means can in this case be compressed, but the force to be exerted to separate the teeth should be much greater than that which returns the cover 11 to its position proximal to the middle by driving the winding stem. The cover would therefore first be returned to its proximal position, before the friction surfaces can be separated. Now in this position, no axial movement is possible towards the inside of the middle apart from screwing onto the tube 10, and therefore the return means can no longer be compressed to allow the friction surfaces to be disengaged. . In this way, any handling error is avoided and the orientation of the crown can only be changed when it is unscrewed from the tube 2 and a tool is applied to it, such as for example the key 20 on the profiles d gear 24, by applying the force F2 necessary to separate the cover 11 then the torque to adjust the angular position of the central barrel 2 relative to the cover 11.

[0024] Concerning the return means, the embodiment described with the aid of the figures and the flat spring 4, elastic or with shape memory, has the advantage of requiring only a restricted space between the upper surface of the central barrel 2 and the internal surface of the cover 114 in the central opening 115, equal to the sum of the thickness E1 of the flat spring 4 and the depth of the shoulder E2 of the internal surface of the cover 1141. Well that a minimum clearance must be provided to guarantee the possibility of axial movement of the central barrel 2 relative to the cover 11, other types of return means, for example magnetized surfaces near the friction surfaces, as by example a part of the collar 23 and a part of the annular orientation part 3, or even confused with the first and second friction surfaces 231.31 machined in a ferromagnetic material. The advantage of using magnetic return means makes it possible to dispense with the use of a dedicated additional part, which allows an additional gain in volume in the crown 1, in particular a gain in height equal to the thickness E1 of the flat spring 4, and therefore further improves the overall compactness of the system. However, the use of magnetic friction surfaces can be used not only as an alternative for a flat spring, but as a complement in order to increase the return force F1 in the rest position where the cover 11 of the crown 1 is integral with the central barrel 2, and thus improve the friction forces without having to increase the contact surfaces.

[0025] It will be noted that the use of a cover 11 attached to the central barrel 2 allows the crown manufacturer to have a stock of such barrels and to use them with different covers 11 bearing different patterns or other elements. such as precious stones or the like, or having non-cylindrical external shapes, for example square, oval or any other particular geometric shape.

[0026] Although the claimed invention has been described mainly in relation to the non-limiting example of a crown 1, it will be understood that the claimed screw-in element could also consist for example of a valve, manual or automatic, a valve, a pusher, a corrector or even an adjustable bottom.

Claims (12)

1. Adjustable screw-on element comprising a cover (11) formed of a cover (112) secured to a side skirt (111), and a device for adjusting the angular orientation of said cover (11) relative to a watch middle, characterized in that said device for adjusting the angular orientation of said cover (11) comprises a first part provided with a first flat friction surface (231), a second part integral with said cover (11) provided a second flat friction surface (31) and return means, said cover (11) and said first part being movable axially relative to each other between a first position (P1) in which said cover ( 11) is integral in rotation with respect to said first part, and a second position (P2) in which the cover (11) is free to rotate around the axis of rotation (A-A) of said orientable screw element (1), said return means making said cover (11) and said first part integral in rotation in said first position (P1). 2. Adjustable screw element according to claim 1, said cover (112) and said side skirt (111) defining a central opening (115) arranged to accommodate a central barrel (2) integral with said first part. 3. Adjustable screw-on element according to claim 2, said first part provided with the first flat friction surface (231) being an interchangeable wear collar (23) around the central barrel (2). 4. Adjustable screw-on element according to one of the preceding claims, said second part integral with said cover (11) provided with the second flat friction surface (31) being an interchangeable annular wear part (3). 5. Adjustable element to be screwed according to one of the preceding claims, characterized in that said return means exert a force (F1) axial along the axis of rotation A-A of said element to be screwed, and oriented towards the inside of the middle part . 6. Adjustable screw element according to one of the preceding claims, characterized in that said return means consist of a flat spring (4) of an elastic material, or of a shape memory alloy so as to release the connection blocking rotation between said cover (11) and said first part by a temperature gradient. 7. Adjustable screw element according to claim 6, said flat spring (4) having a thickness (E1) of maximum 0.1mm and being disposed between a first shoulder (1141) of an interior surface (114) of the cover ( 112) of said cover (11), said shoulder (1141) having a depth (E2) of a maximum of 0.2 mm, and a second shoulder (232) of said first part. 8. Adjustable screw element according to one of the preceding claims, characterized in that said first and second friction surfaces (231,31) are magnetized to form the return means, or to form complementary return means. 9. Adjustable screw-on element according to one of the preceding claims, characterized in that it contains a piston (9) secured to a rod intended to be connected to the movement of a watch, said piston (9) being housed movable axially inside a central barrel (2), the stroke of said piston (9) being limited by a stop (22) of said central barrel (2). 10. Adjustable screw element according to claim 9, said piston (9) having a lower end (93) of hexagonal shape and said central barrel (2) an opening of corresponding shape. 11. Adjustable screw element according to one of claims 9 or 10, said central barrel (2) having peripheral gear profiles (24) for adjusting the orientation. 12. Adjustable screw element according to one of the preceding claims, characterized in that the passage from the first position (P1) to the second position (P2) requires the exercise of a force (F2) against the recall means with an intensity between 23 and 28 Newtons.