CH717458A1 - Strand of bracelet, watch strap and watch. - Google Patents

Abstract

The invention relates to a bracelet strand (2) comprising a flexible band (11) at least in part made of a flexible polymer. This bracelet strand (2) further comprises at least one flexible reinforcing mesh (15) on which the flexible polymer is overmolded. The wristband strand (2) may comprise at least one flexible printed circuit (13), this flexible printed circuit (13) and the flexible reinforcing mesh (15) at least partially overlapping each other with or without a gap. between them. The invention also relates to a watch strap and a watch.

Description

Technical field of the invention

The present invention relates to the field of flexible polymer band bracelets, such as certain watch straps. More precisely, it concerns a strand of a bracelet, a watch strap and a watch.

State of the art

A bracelet is an accessory intended to be installed around a member of the body, for example around a wrist. In the field of watchmaking, it is known practice to equip a watch with a watch strap thanks to which the watch can be attached to the wrist. A watch associated with a watch strap is conventionally called a wristwatch.

[0003] Traditional watch straps generally comprise two strands made of leather bands sewn together. Materials other than leather are also used for making watch strap strands. In particular, it is known practice to produce watch strap strands from flexible polymer, for example from elastomer based on vulcanized rubber.

[0004] A watch strap is subjected to repeated mechanical stresses which can lead to damage.

Summary description of the invention

The invention is more particularly interested in bracelets and bracelet strands comprising a flexible band at least in part made of a flexible polymer: the invention at least aims to make such a bracelet strand and / or a component optionally attached to this strap strand less vulnerable to damage likely to result from mechanical stresses.

According to the invention, this object is achieved by means of a strap strand comprising, on the one hand, a flexible strip at least in part made of a flexible polymer and, on the other hand, at least one flexible mesh reinforcement on which the flexible polymer is overmolded.

[0007] The bracelet strand defined above can incorporate one or more other advantageous characteristics, individually or in combination, in particular from those defined below. It is explained here that the flexible strip has a length, as well as a width, which may or may not be constant.

Advantageously, the flexible reinforcing mesh comprises openings through which bridges of material made of the flexible polymer penetrate through the flexible reinforcing mesh.

Advantageously, the wristband strand comprises at least one flexible printed circuit, this flexible printed circuit and the flexible reinforcing mesh at least partially overlapping each other with or without a gap between them.

When this is the case, as the flexible polymer is molded onto the flexible reinforcing mesh, the flexible printed circuit is protected in particular in terms of elongation.

Advantageously, the flexible polymer is molded onto the flexible printed circuit.

Advantageously, the flexible printed circuit and the flexible reinforcing mesh are in contact over at least part of the width of the flexible strip and over at least part of the length of the flexible strip.

Advantageously, at least part of the bridges of material penetrating through the flexible reinforcing mesh are molded onto the flexible printed circuit.

Advantageously, the flexible reinforcing mesh is a first flexible reinforcing mesh, the strap strand comprising a second flexible reinforcing mesh, the flexible printed circuit located between the first and the second flexible reinforcing mesh, the printed circuit flexible and the second flexible reinforcing mesh at least partially overlapping each other with or without a gap between them.

Advantageously, at least in a direction parallel to the flexible reinforcing mesh, the flexible reinforcing mesh has a Young's modulus greater than the Young's modulus of the flexible polymer.

Advantageously, at least in a direction parallel to the flexible reinforcing mesh and substantially parallel to the length of the flexible strip, the flexible reinforcing mesh has a Young's modulus greater than the Young's modulus of the flexible polymer.

Advantageously, at least in two distinct directions parallel to the flexible reinforcing mesh, the flexible reinforcing mesh has a Young's modulus greater than the Young's modulus of the flexible polymer. Distinct directions are directions that are not parallel to each other.

Advantageously, the flexible reinforcing mesh extends over at least part of the length of the flexible strip and / or over at least part of the width of the flexible strip.

Advantageously, the flexible reinforcing mesh comprises elongated crisscrossing elements.

Advantageously, part of the elongated intersecting elements are substantially parallel to the length of the flexible strip.

Advantageously, at least part of the elongated crisscross elements are made of aramid or glass.

Advantageously, at least part of the elongated crisscross elements are fibers.

Advantageously, the elongated crisscrossed elements together form meshes.

Advantageously, at least one of the meshes delimits and surrounds one of the days.

Advantageously, the flexible reinforcing mesh is a nonwoven.

Advantageously, the flexible reinforcing mesh is a woven fabric.

Advantageously, the flexible reinforcing mesh is a one-piece grid.

Advantageously, at least part of the elongated elements of the flexible reinforcing mesh each have a Young's modulus greater than the Young's modulus of the flexible polymer.

A subject of the invention is also a watch strap, which comprises a strap strand as defined above.

A subject of the invention is also a watch, which comprises a watch strap as defined above.

Brief description of the drawings

Other advantages and characteristics will emerge more clearly from the following description of several embodiments of the invention given by way of non-limiting example and shown in the accompanying drawings, among which: FIG. 1 is a perspective view of a watch, the watch strap of which comprises two bracelet strands each according to a first embodiment of the invention; FIG. 2 is a perspective view of one of the two bracelet strands that the watch shown in FIG. 1 has; FIG. 3 is a partial view, in perspective and with cutaway, and represents the same bracelet strand according to a first embodiment of the invention as in FIG. 2; FIG. 4 is a perspective view of a component, namely a flexible printed circuit, present in the strap strand of FIGS. 2 and 3; FIG. 5 is a perspective view of a flexible reinforcing mesh present in the strap strand of FIGS. 2 and 3; Figure 6 is a partial and schematic perspective view and shows an enlarged portion of the flexible reinforcing mesh shown in Figure 5; FIG. 7 is a partial view, in longitudinal section along the plane P of FIG. 3; and FIG. 8 is a view similar to FIG. 7, in longitudinal section, and represents a portion of a bracelet strand according to a second embodiment of the invention.

Description of several preferred embodiments of the invention

In Figure 1, a watch according to one embodiment of the invention is shown alone. It comprises a watch strap 1 which comprises two bracelet strands 2 and 3. In the example shown, the bracelet strand 2 is a long strand, while the bracelet strand 3 is a short strand.

The watch shown in Figure 1 also comprises a watch case 4 and a watch movement, for example mechanical or electronic, which contains the watch case 4 and which is therefore hidden in Figure 1.

At its proximal end, each of the bracelet strands 2 and 3 comprises a transverse housing 7 provided to receive an attachment bar retained between two horns 5 of one of two pairs of horns that has the watch case 4 At its distal end, the bracelet strand 3 defines another transverse housing, referenced 8, for its part intended to receive the axis of an attachment loop.

The bracelet strand 2 is pierced with holes 9 successively over part of its length. Each of the holes 9 is provided for the passage of a member of the aforementioned buckle so that the latter can be attached to the strap strand 2 and thus close the watch strap 1.

The attachment means proposed above are only by way of example. Other means of attaching the watch strap to the watch case can be chosen without departing from the scope of the invention. Also, other means for attaching the free ends of the two bracelet strands can also be chosen without departing from the scope of the invention. In addition, the watch strap may consist only of a single strap strand without departing from the scope of the invention.

Each of the bracelet strands 2 and 3 is a flexible strand which can be bent parallel to a longitudinal plane P. In FIG. 2, the bracelet strand 2 is shown alone while it is flat. A flexible strip 11 forms part of the bracelet strand 2. The reference L designates the longitudinal direction that the flexible strip 11 has when the bracelet strand 2 is flat. The longitudinal plane P is parallel to this longitudinal direction L.

The bracelet strand 2 is according to a first embodiment of the invention.

As can be seen in Figure 3, the flexible strip 11 contains a flexible printed circuit 13 and a flexible reinforcing mesh 15, on which is molded the flexible polymer of the flexible strip 11. The flexible printed circuit 13 and the flexible reinforcing mesh 15 are substantially parallel to each other. Like the flexible strip 11, lying flat, they are substantially perpendicular to the longitudinal plane P, which is the plane of flexion of the strap strand 2.

In the bracelet strand 2 according to the first embodiment of the invention, the flexible strip 11 is made of a flexible polymer, such as an elastomer based on vulcanized rubber. The flexible strip 11 can also be made of several flexible polymers, in particular when it is produced by assembling several preforms by vulcanization in a mold. One or more portions of the flexible band 11 may also be made of a rigid polymer, which may in particular be the case with a portion located at the proximal end of the strand of the strap 2.

Preferably, the flexible polymer (s) of the flexible strip 11 are chosen from general elastomers. More preferably, the flexible polymer (s) of the flexible strip 11 are chosen from rubbers and synthetic elastomers.

The flexible printed circuit 13 and the flexible reinforcing mesh 15 overlap each other. They can overlap each other completely. They can also partially overlap each other, which is the case in the bracelet strand 2, as can be seen in Figure 3.

As can be seen in Figure 4, the flexible printed circuit 13 comprises a support sheet. A flexible printed circuit (called flex PCB in English) is a well-known type of electronic circuit, which has such a backing sheet. This support sheet is flexible or pliable and in particular carries the electrical connections between the electronic components. The flexible printed circuit 13 has the shape of a ribbon having the same longitudinal direction L as the flexible strip 11 in the wristband strand 2.

Like the flexible printed circuit 13, the flexible reinforcing mesh 15 has the shape of a ribbon having the same longitudinal direction L as the flexible strip 11 in the wristband strand 2, as can be seen at FIG. 5 which represents the flexible reinforcing mesh 15 alone. In order that the covering of the flexible printed circuit 13 by the flexible reinforcing mesh 15 is consistent, the flexible reinforcing mesh 15 has overall the same shape and the same dimensions as the flexible printed circuit 13.

The flexible reinforcing mesh 15 can be a one-piece grid, which is however not the case in the first embodiment of the invention (nor in the second embodiment which will be discussed later).

The flexible reinforcing mesh 15 can comprise elongated elements crossed, which is the case in the first embodiment of the invention. In FIG. 6, the references 16 and 17 designate these elongated crisscrossing elements of the flexible reinforcing mesh 15. The elongated elements 16 are parallel and spaced apart from one another. The same is true of the elongated elements 17. The elongated elements 16 are more precisely longitudinal elements, that is to say parallel to the length of the flexible strip 11. The elongated elements 17 are perpendicular to the elongated elements 16.

The elongated elements 16 are preferably fibers, which is the case in the flexible reinforcing mesh 15. The elongated elements 17 are preferably fibers, which is also the case in the flexible reinforcing mesh 15.

The elongated elements 16 may not all be made of the same material. Preferably, the elongated elements 16 are all made of the same material, which may be aramid or glass. The elongated elements 17 may not all be made of the same material. Preferably, the elongate elements 17 are all made of the same material, which may be aramid or glass. The elongated elements 16 and the elongated elements 17 can be made of the same material. It is also possible that the material constituting at least part of the elongated elements 16 is different from the material constituting at least part of the elongated elements 17.

In the flexible reinforcing mesh 15, the elongated elements 16 each have a Young's modulus greater than the Young's modulus of the flexible polymer of the flexible strip 11. Preferably, the same is true of the elongated elements 17.

It is also possible that only part of the elongated elements 16 and / or only part of the elongated elements 17 each have a Young's modulus greater than the Young's modulus of the flexible polymer of the flexible strip 11.

The longitudinal direction L is the direction of the elongated elements 16. The direction t parallel to the width of the bracelet strand 2 is the direction of the elongated elements 17. The longitudinal direction L and the direction t are two distinct directions parallel to the mesh flexible reinforcement 15. According to these two directions L and t, the flexible reinforcing mesh 15 has a Young's modulus greater than the Young's modulus of the flexible polymer of the flexible strip 11, since at least some of the elements elongated 16 and at least part of the elongated elements 17 each have a Young's modulus greater than the Young's modulus of the flexible polymer of the flexible strip 11.

The elongated elements 16 and the elongated elements 17 together form meshes, which are loose meshes each delimiting and surrounding a day 19. In the first embodiment of the invention, the days 19 are zones of absence of contact between the elongated elements 16 and 17 crisscrossed.

As can be seen in Figure 7, the flexible polymer of the flexible strip 11 enters the flexible reinforcing mesh 15, at the days 19. In other words, bridges of material 21 made. of the flexible polymer of the flexible strip 11 pass in the openings 19, through the flexible reinforcing mesh 15. The bridges of material 21 are hooked to the flexible reinforcing mesh 15, which increases the cohesion between the flexible strip 11 and the flexible reinforcing mesh 15 by adding to the bond resulting from the overmolding of the flexible polymer of the flexible strip 11 on the flexible reinforcing mesh 15.

The bridges of material 21 pass through the flexible reinforcing mesh 15 and are molded onto the flexible printed circuit 13. This leads to a robust assembly of the flexible printed circuit 13, the flexible reinforcing mesh 15 and the flexible strip 11.

When the strap strand 2 is stressed, the flexible reinforcing mesh 15 takes over a large part of the stresses, in particular tensile stresses, where it is present. Where the flexible reinforcing mesh 15 is present, the flexible strip 11 deforms little due to mechanical stresses. In particular, the elastic elongation and the elastic widening of the flexible strip 11 due to mechanical stresses are less where there is the flexible reinforcing mesh 15.

It has been found that the stresses transmitted to the flexible printed circuit 13 by the flexible strip 11 are less in the presence of the flexible reinforcing mesh 15.

In particular, when the strap strand 2 is subjected to traction in the longitudinal direction L, the resulting stresses are largely taken over by the elongated elements 16 where the flexible reinforcing mesh 15 is present.

In general, it has been found that the presence of the flexible reinforcing mesh 15 leads to a reduction in the stresses and deformations to which the flexible printed circuit 13 is subjected in the event of mechanical stresses applied to the strap strand 2. The mesh reinforcing hose 15 thus constitutes a protection reducing the risk of damage to the flexible printed circuit 13.

The flexible reinforcing mesh 15 also makes the strap strand 2 more robust and less likely to be damaged due to mechanical stresses. Indeed, in addition to protecting the flexible printed circuit 13, the flexible reinforcing mesh 15 reduces the stresses and deformations in the flexible polymer of the flexible strip 11, which is thus also protected.

The mechanical stresses to which the bracelet strand 2 is subjected can be repeated stresses liable to cause damage by fatigue.

In one possible way of proceeding to produce the bracelet strand 2, at least two elastomer preforms are used. One of the preforms, the flexible printed circuit 13, the flexible reinforcing mesh 15 and the other preform are stacked in the cavity of an assembly mold. In the stack thus produced, the flexible printed circuit 13 and the flexible reinforcing mesh 15 are sandwiched between the two preforms. Then, the assembly mold is closed and the stack is compression molded so as to cause vulcanization of the preforms, that is to say so that the two preforms crosslink. The two preforms crosslink on the flexible printed circuit 13 (overmolding), on the flexible reinforcing mesh 15 (overmolding) and one on the other (connection of the two preforms to one another).

The two preforms can also be made of a flexible polymer which is not an elastomer. Also in this case, the stack comprising the two preforms, as well as the flexible printed circuit 13 and the flexible reinforcing mesh 15 between these first and second preforms, are produced in a mold. This stack is then molded under pressure and temperature conditions that are functions of the thermoplastic polymer used, so that the latter conforms to the shape of the imprints of the assembly mold and is overmolded on the flexible printed circuit 13 and on the mesh. flexible reinforcement 15, and so that the preforms bond together. The polymer of the first preform and the polymer of the second preform can be different.

In Figure 8, a portion of a bracelet strand 102 according to a second embodiment is shown in section along a bending plane identical to the longitudinal plane P. In what follows, no description of the bracelet strand 102 than what distinguishes it from the bracelet strand 2.

The flexible reinforcing mesh 15 is a first reinforcing mesh in the strap strand 102, which comprises a second flexible reinforcing mesh, which is referenced 115. Preferably, the reinforcing mesh 115 is identical to the reinforcing mesh 15. It is also possible that the reinforcing mesh 115 is different from the reinforcing mesh 15.

In the wristband strand 102, the flexible printed circuit 13 is located between the reinforcing flexible mesh 15 and the reinforcing mesh 115. The flexible reinforcing mesh 115 and the flexible circuit 13 at least partially overlap the one another, with or without a gap between them.

When the bracelet strand 102 is mechanically stressed, the flexible printed circuit 13 of this bracelet strand 102 undergoes even less stresses and deformations, thanks to the flexible reinforcing mesh 115, compared to the flexible printed circuit 13 in the bracelet strand 2.

[0067] The flexible polymer of the flexible strip 11 enters the flexible reinforcing mesh 115 at days similar to the days 19. In other words, bridges of material 121 made of the flexible polymer pass through the flexible mesh of reinforcement 115. The bridges of material 121 are as if hooked to the flexible reinforcing mesh 115, which increases the cohesion between the flexible strip 11 and the flexible reinforcing mesh 115 by adding to the bond resulting from the overmolding of the flexible polymer of the flexible strip 11 on the flexible reinforcing mesh 115. The bridges of material 121 pass through the flexible reinforcing mesh 115 and are overmolded on the flexible printed circuit 13. This results in a robust assembly of the flexible reinforcing mesh 115, of the circuit. flexible print 13 and flexible tape 11.

To manufacture the bracelet strand 102, one can adapt the manufacturing process of the wristband strand 2. The adaptation of this process to obtain a manufacturing process of the wristband strand 102 consists in adding the flexible reinforcing mesh 115 in the stack produced in the assembly mold.

According to a third embodiment of the invention not shown, the bracelet strand is devoid of flexible printed circuit 13. A bracelet strand according to the third embodiment can be identical to the bracelet strand 2 except in that 'it does not have any flexible printed circuit 13. In a bracelet strand according to the third embodiment of the invention, the flexible reinforcing mesh can be identical to the flexible reinforcing mesh 15. In a bracelet strand according to the third embodiment embodiment of the invention, this flexible reinforcing mesh supports a large number of stresses, which results in a reduction of the stresses and deformations in the flexible strip 11 which, as a result, is less likely to be damaged due to mechanical stress.

The bracelet strand 3 can be according to the first embodiment of the invention. The bracelet strand 3 can also be according to the second embodiment. According to another possibility, the bracelet strand 3 may be according to the third embodiment of the invention. It is also possible that the bracelet strand 3 does not incorporate the invention.

The bracelet strand 3 can have the same constitution as the bracelet strand 2. The bracelet strand 3 can also have a different constitution from that of the bracelet 2. For example, it is possible that the bracelet strand 2 is according to the first embodiment of the invention, while the bracelet strand 3 is according to the second or the third embodiment of the invention.

Claims (15)

1. Bracelet strand, comprising a flexible strip (11) at least partly made of a flexible polymer, characterized in that it comprises at least one flexible reinforcing mesh (15) on which the flexible polymer is molded. 2. Bracelet strand according to claim 1, characterized in that the flexible reinforcing mesh (15) comprises openings (19) through which bridges of material (21) made of the flexible polymer penetrate through the flexible reinforcing mesh ( 15). 3. Bracelet strand according to any one of the preceding claims, characterized in that it comprises at least one flexible printed circuit (13), this flexible printed circuit (13) and the flexible reinforcing mesh (15) overlapping each other. less partially each other with or without a gap between them. 4. Bracelet strand according to claim 3, characterized in that the flexible polymer is molded onto the flexible printed circuit (13). 5. Bracelet strand according to claim 2 and any one of claims 3 and 4, characterized in that at least part of the bridges of material (21) penetrating through the flexible reinforcing mesh (15) are molded onto the flexible printed circuit (13). 6. Bracelet strand according to any one of claims 3 to 5, characterized in that the flexible reinforcing mesh (15) is a first flexible reinforcing mesh (15), the bracelet strand comprising a second flexible reinforcing mesh (115), the flexible printed circuit (13) lying between the first and the second flexible reinforcing mesh, the flexible printed circuit (13) and the second flexible reinforcing mesh (115) at least partially overlapping each other. 'other with or without a gap between them. 7. Bracelet strand according to any one of the preceding claims, characterized in that, at least in a direction (L) parallel to the flexible reinforcing mesh (15), the flexible reinforcing mesh (15) has a modulus of Young greater than the Young's modulus of the flexible polymer. 8. Bracelet strand according to any one of the preceding claims, characterized in that, at least in a direction (L) parallel to the flexible reinforcing mesh (15) and substantially parallel to the length of the flexible strip (11), the flexible reinforcing mesh (15) has a Young's modulus greater than the Young's modulus of the flexible polymer. 9. Bracelet strand according to any one of the preceding claims, characterized in that, at least in two distinct directions (L, t) parallel to the flexible reinforcing mesh (15), the flexible reinforcing mesh (15) has a Young's modulus greater than the Young's modulus of the flexible polymer. 10. Bracelet strand according to any one of the preceding claims, characterized in that the flexible reinforcing mesh (15) extends over at least part of the length of the flexible strip (11) and / or over at least part of the width of the flexible strip. 11. Bracelet strand according to any one of the preceding claims, characterized in that the flexible reinforcing mesh (15) comprises elongated intersecting elements (16, 17). 12. Bracelet strand according to claim 11, characterized in that a portion of the elongated intersecting elements (16, 17) are substantially parallel to the length of the flexible strip (11). 13. Bracelet strand according to any one of claims 11 and 12, characterized in that at least part of the elongated elements (16, 17) intersecting are made of aramid or glass. 14. Watch strap, characterized in that it comprises a strap strand (2, 3; 102) according to any one of the preceding claims. 15. Watch, characterized in that it comprises a watch strap (1) according to claim 14.