CH703096A2 - Articulated link bracelet for use in e.g. jewelry field, has axial blocking element formed of radially elastic split and non-split tubes that are integrated by their respective annular ends to preserve radial elasticity of split tube - Google Patents

Abstract

The bracelet has I-shaped links and H-shaped links, where each I-shaped link (10) has a male hinge part (11) provided with a through hole (12) and each H-shaped link (20) has a female hinge part (21) provided with two through holes (22, 23). The three through holes form an alignment when the male part is engaged in the female part. An axial blocking element (31) formed of a radially elastic split tube and a non-split tube is axially blocked in the through hole of the male part. The tubes are integrated by their respective annular ends to preserve radial elasticity of the split tube. The radially elastic split tube is formed of elastically deformable material i.e. braid.

Description

The present invention relates to the field of watchmaking and jewelery. It relates more precisely a link bracelet articulated between them using a pin.

Such bracelets are well known to those skilled in the art. They comprise a plurality of links, identical or paired, articulated in pairs in the manner of a hinge comprising a male part, a female part and a connecting pin. The links are, for example, elements in I alternating with elements in H between the branches to which they are engaged. They can also be elements of more complex shape, comprising on one side the male hinge part and on the other, the female part. They are traversed by holes forming an alignment when the male part is engaged in the female part, and in which pins are placed.

The assembly of the links using the pins meets specific requirements related to the use of the bracelet. It will first be noted that the pins must be locked axially inside the alignment of holes to avoid coming out, but free to rotate inside one of the male or female hinge parts, so not to hinder the linkage movement of the links. Furthermore, they must be removably mounted so as to remove or add a link during a possible adjustment in length of the bracelet.

When the links are metal, a solution to the different mounting constraints of the pins, is to chase them inside the male hinge portion and leave them free in the female part. This solution can not be adopted for ceramic links because of the fragile nature of this material. Indeed, the ceramic is not able to deform plastically, the links could break during the operation of driving the pins. In addition, the diameter of the through holes must be given with great precision so that it is possible to drive a pin there. However, in ceramics, drilling holes with low tolerance is difficult and expensive.

Thus, according to the state of the art, intermediate parts are used for assembling the pins with ceramic links. These parts consist of a first tube provided with a longitudinal slot, which consists of an elastically deformable material such as metal or plastic, and a second non-split tube. The relative radial and longitudinal dimensions of the various elements of the hinge are important for the operation of the joint. The male hinge part of the links is pierced with a through hole of diameter greater than that of the holes of the female hinge portion. The diameter of the pin is smaller than the diameters of the holes made in the male and female hinge parts. The outer diameter of the first and second tubes is greater than the diameter of the holes of the female hinge portion, but less than the diameter of the hole of the male portion. The inside diameter of the first split tube is slightly smaller than the diameter of the pin, while the inside diameter of the second tube is slightly greater. The latter is also less than the outside diameter of the first split tube. Finally, the total length of the first and second end-to-end tubes is substantially equal to the length of the hole of the male hinge portion, and the length of the pin is substantially equal to the sum of the lengths of the hole of the male hinge portion. and two holes in the female hinge portion.

The first and second tubes are arranged end to end within the male hinge portion of a first link. Their outer diameters being greater than the diameter of the holes of the female hinge portion, said tubes are locked axially in the male hinge hole. In addition, they can not slide into each other because of their relative inner and outer diameters. The pin is housed inside the first and second tubes, its ends being engaged in the holes of the female hinge portion of a link next to the first link, in which they are free to rotate. The inner diameter of the second tube being greater than the diameter of the pin, it is free inside the second tube. Conversely, the inside diameter of the first split tube being slightly smaller than the diameter of the pin, the latter is axially fixed and in rotation with the first tube, under the clamping action that it exerts on it. Note that the introduction of the pin in the first split tube is carried out by driving. As said tube is slotted, it is extended slightly radially under the action of driving, so that its initial diameter does not necessarily have to be given with great precision relative to the diameter of the pin.

The pin being secured to the first split tube, it is trapped inside the hole through the male hinge portion. In addition, it is blocked axially inside this hole by the second tube which occupies the other portion of the length of the hole and thus blocks any axial movement of the first split tube.

Thus positioned in the alignment of the holes of two adjacent links, the pin ensures the maintenance and articulation of these links. In addition, it can be removed easily links, to disassemble the bracelet, by hunting out of the first split tube. For this purpose, a rigid rod, slightly smaller in diameter than that of the pin, is used to drive the pin out of the split tube when it is itself actuated by means of a hammer.

The assembly of such an articulated bracelet is performed manually and essentially comprises the following steps: - Introduction of the first and second split tube in the through hole of the male hinge portion of a first link. - Engaging the male hinge portion of said first link in the female hinge portion of a second link so as to align the through holes. - Positioning a pin through the through holes by driving inside the first split tube after engagement in the second tube.

The length adjustment of such a bracelet comprises, in addition to the steps mentioned above, a first step of driving a pin out of the first split tube to separate two adjacent links.

The mounting steps thus described must be carried out meticulously. It is important, for example, to arrange the two types of tubes in the through hole of the male hinge part without confusing or reversing them. A confusion between a split tube and a non-split tube could, in the worst case, result in the untimely opening of the bracelet and the loss of the watch. It is also recommended to insert the pin into the through holes, starting with the second non-split tube, so as not to chase almost the entire length of the pin through the first split tube. Because of the small size of the parts and their similarity, the risk of error in assembly is important and potentially very embarrassing. Note also that the mounting of such a bracelet requires a considerable time, which has a significant impact on its final cost.

The present invention overcomes at least partially these various disadvantages, by providing an articulated link bracelet whose assembly is made simpler and faster thanks to the reduction in the number of parts. More specifically, the present invention relates to a link bracelet articulated in the manner of a hinge, comprising: first links having a male hinge portion pierced with a first through hole, second links provided with a female hinge portion pierced with a second and a third through hole, said first, second and third holes forming an alignment when a male hinge portion is engaged in a female hinge part, pins taking place in said alignments, and - Axially locking elements of said pins, formed of a first radially elastic tube and a second tube, mounted axially locked in said first through holes, said pins being mounted driven inside said first split tubes, characterized in that said first and second tubes comprise an annular end by which they are made integral so as to preserve the radial elasticity of said first tube.

With this feature, it is no longer necessary to introduce two but a piece inside the through holes of the male hinge portion, which simplifies and rationalizes the assembly of the bracelets.

In an advantageous embodiment, the first tube is provided with a longitudinal slot and said first and second tubes are integral on an angular portion less than 180 °, extending substantially opposite to said longitudinal slot. Other characteristics and advantages of the present invention will emerge more clearly from the following detailed description of an embodiment of an articulated link bracelet according to the invention, this example being given for purely illustrative and nonlimiting purposes only, in conjunction with the accompanying drawing in which: <tb> fig. 1 <sep> represents a view from above of an articulated link bracelet according to the invention, <tb> fig. 2 <sep> is an exploded view of three consecutive links of such a bracelet, <tb> fig. 3 <sep> is a sectional view in the plane of the links of the bracelet according to the invention, <tb> figs. 4 and 5 <sep> represent views, respectively in perspective and in cross-section, of an element of the bracelet according to the invention, and <tb> fig. 6 <sep> illustrates a variant of an embodiment of the bracelet according to the invention.

The articulated link bracelet shown in FIG. 1, and referenced as a whole 1, comprises first links 10, substantially I-shaped, intercalated with second links 20, substantially H-shaped, a link 10 forming I with a link 20 H, a step longitudinal development of the bracelet. For this purpose, each first link 10 at I is engaged partially between the branches of a second link 20 H disposed to its right, and partially between the branches of a second link 20 H disposed to its left, and so next to the ends of the bracelet.

As shown in FIG. 2 and 3, the first and second links 10, 20 are articulated in pairs in the manner of a hinge, the male portion 11 is formed by a longitudinal half of a first I-link 10 and the female portion 21 is formed by the branches of a second link 20 in H. The male hinge parts 11 of the links 10 are pierced longitudinally of a first through hole 12, while the female hinge parts 21 of the second links 20 are pierced by a second and a third through hole 22, 23, parallel to the middle branch of the H. For reasons which will appear later, the second and third through holes 22, 23 have a smaller diameter D2 than the diameter D1 of the first through holes 12. The holes 12,22, 23 are further arranged to form an alignment when the male hinge portion 11 is engaged in the female hinge portion 21. A pin 30 takes plac e within said alignment, to ensure the maintenance and articulation of two links 10, 20 neighbors. An axial locking element 31 of the pin 30 is mounted axially locked inside the first through hole 12 of the male hinge part 11.

The axial locking element 31 of the pin 30, shown in perspective in Figure 4, is formed of a first tube 40 provided with a longitudinal slot 45 and a second non-slotted tube 41. The first tube 40 is made of an elastically deformable material such as metal or plastic. The presence of the longitudinal slot 45 gives it a radial elasticity whose function will appear thereafter. Said tubes 40 and 41 have outer diameters, respectively De1, De2, greater than the diameter D2 of the second and third through-holes 22, 23, and smaller than the diameter D1 of the first through-holes 12. Thanks to this characteristic, the tubes 40 and 41 are axially locked within a first through hole 12, when the latter forms an alignment with a second and a third through-hole 22, 23. The cumulative length of a first and a second tube 40, 41 is substantially equal to the length of the first through hole 12, so that said tubes 40, 41 can not slide inside a through hole 12.

As illustrated in FIG. 3, the outer diameter D4 of a pin 30 is smaller than the inner diameter Di2 of a second non-split tube 41 in which it is freely engaged. On the other hand, the same outside diameter D4 is slightly greater than the inside diameter Di1 of a first split tube 40. Thanks to the radial elasticity property of a first tube 40 conferred by the longitudinal slot 45, the said first tube 40 exerts an clamping action on the pin 30 which is thus secured to it in rotation and in translation. The pin 30 being secured to a first split tube 40 and the latter being locked axially in the first through hole 12, the pin is itself mounted axially locked in the alignment formed by the first, second and third through holes 12 , 22, 23.

Referring now to FIG. 5 which represents a cross-section of the axial locking element 31. According to the invention, the first and second tubes 40 and 41 are provided with an annular end by which they are integral on an angular portion α less than 180 ° s' extending substantially opposite to the longitudinal slot 45. Said tubes 40, 41 are for example spot welded to the angular portion α. Thanks to this characteristic, the tubes 40 and 41 form a single axial locking element 31 of the pin 30 in place of the two distinct elements formed by the first and second tubes 40, 41. It will be noted that the angular portion α by which they are integral is less than 180 ° and opposite to the longitudinal slot 45 to maintain the radial elasticity of the first split tube 40. Indeed, this property is essential for the axial retention of the pin 30 within the l aligning the through holes 12, 22, 23 and disassembling it for the purpose, for example, of removing or adding a link. Tests show that beyond 180 °, the radial elasticity of the first split tube 40 is reduced, which can cause the solder to be transferred between the first and second tubes 40 and 41, and possibly reduce the elasticity of the first tube 40. Advantageously, the angular portion α is greater than 140 °, in order to achieve sufficient maintenance of the two tubes 40 and 41.

The assembly of articulated bracelets according to the invention is facilitated and made faster compared to the mounting of a bracelet according to the state of the art. An axial locking element 31 is introduced into a first through hole 12 of a first I-link 10 and then said first link 10 is engaged between the branches of a second link 20 H. A pin is driven into the element axial locking 31 through the alignment formed by the three holes 12, 22, 23. The two links 10 and 20 are assembled articulated manner. Any confusion between split tube and non-split tube is avoided, and the insertion time of the blocking element is halved.

Thus has been described a link bracelet articulated easy assembly and fast. Of course, the bracelet according to the invention is not limited to the embodiment which has just been described and various simple modifications and variants can be envisaged by those skilled in the art without departing from the scope of the invention as defined by the appended claims.

Note in the first place, that in the embodiment described above, the links are different and matched. Each has two male hinge parts or two female hinge parts. Alternatively, the links may be identical and each comprise a male hinge portion and a female hinge portion without the invention being modified. Such a type of bracelet is represented in FIG. 6.

It has been mentioned, moreover, that the axial locking elements 31 are formed of a first tube 40 provided with a longitudinal slot and a second non-slotted tube 41. Of course, this embodiment can be extended to any axial locking element comprising a first radially elastic tube and a second tube not having this property. It will be noted, for example, that the first tube may be made of an elastic material such as rubber. It may also be formed of a braid, metallic or other, able to extend radially. Such tubes are well known to those skilled in the art. As for the split tube, the welding between the two tubes must be done so as to preserve the radial elasticity of the first tube. This can be achieved, for example, by welding the two tubes at four separate points each of 90 °. Each angular portion located between two welding points retains its radial elasticity, and therefore the tube generally retains its property of radial elasticity. Of course, the welding can also be performed, as previously on an angular portion not exceeding 180 °.

Claims (11)

Hinge-like link bracelet comprising: - first links (10) provided with a male hinge portion (11) pierced with a first through hole (12), - second links (20) provided with a female hinge portion (21) pierced with a second and a third through hole (22,23), said first, second and third holes (12, 22, 23) forming an alignment when a male hinge portion (11) is engaged in a female hinge portion (21), pins (30) taking place in said alignments, and - Axially locking elements (31) of said pins (30) formed of a first tube (40) radially elastic (45) and a second tube (41), mounted axially locked in said first through holes (12) said pins (30) being mounted driven into said first slit tubes (40), characterized in that said first and second tubes (40, 41) comprise an annular end by which they are secured so as to preserve the radial elasticity of said first tube (40). 2. Bracelet according to claim 1, characterized in that said first tube (40) is provided with a longitudinal slot (45) and in that said first (40) and second (41) tubes are secured to an angular portion α less than 180 °, extending substantially opposite to said longitudinal slot (45). 3. Bracelet according to claim 2, characterized in that said angular portion α is greater than 140 °. 4. Bracelet according to one of claims 2 and 3, characterized in that the annular ends of said first and second tubes (40, 41) are spot welded to the angular portion α. 5. Bracelet according to one of claims 1 to 4, characterized in that said first tube (40) is formed of an elastically deformable material. 6. Bracelet according to claim 1, characterized in that said first tube (40) is formed of a braid. 7. Bracelet according to one of claims 1 to 6, characterized in that the internal diameter DM of said first tubes (40) is slightly smaller than the outer diameter D4 of said pins (30). 8. Bracelet according to one of claims 1 to 6, characterized in that the diameter D1 of the first through holes is greater than the diameter D2 of the second and third through holes and in that the outer diameters De1, De2 of said first and second tubes (40,41) are greater than the diameter D2 of said second and third through holes (22, 23) and smaller than the diameter D1 of said first through holes (12). 9. Bracelet according to one of claims 1 to 8, characterized in that said first and second links (10, 20) are different and matched. 10. Bracelet according to claim 9, characterized in that said first links (10) are shaped I, said male hinge portion (11) being formed by a longitudinal half of said link (10), and said second links (20) are H-shaped, said female hinge portion (21) being formed by the branches of H. 11. Bracelet according to one of claims 1 to 10, characterized in that said first and second links (10, 20) are identical.