BRACELET CLASP

Abstract

A bracelet clasp (1) including a strip (2), a first end (20) whereof is hinged to a first end (30) of a first bracelet strand (3), and the second end (21) of the strip (2) is free, said strip (2) having a cut-out (5) forming at least a rigid portion (22) and two opposing deformable portions (23, 24), each including a hook (6, 6′) arranged to engage with a hole (40) in a second bracelet strand (4) and to lock the clasp on said second strand (4), simultaneous pressures exerted on the deformable portions (23, 24) resulting in the unlocking of the clasp.

Claims

1. A bracelet clasp (1) comprising a strip (2), a first end (20) whereof is hinged to a first end (30) of a first bracelet strand (3), and the second end (21) of the strip (2) is free, said strip (2) having a cut-out (5) forming at least a rigid portion (22) and two opposing deformable portions (23, 24), each comprising a hook (6, 6′) arranged to engage with a hole (40) in a second bracelet strand (4) and to lock the clasp on said second strand (4), simultaneous pressures exerted on the deformable portions (23, 24) resulting in the unlocking of the clasp.

2. The bracelet clasp according to claim 1, wherein the strip (2) comprises a loop (7) for guiding the second bracelet strand, the loop (7) being placed in the immediate vicinity of the free end (21) of the strip.

3. The bracelet clasp according to claim 1, wherein the strip (2) comprises machined edges to form push-pieces (26) and facilitate the deformation of the deformable portions.

4. The bracelet clasp according to claim 1, wherein the rigid portion (22) of the strip comprises a pin (8) arranged to engage with a further hole (41) in the second strand (4).

5. The bracelet clasp according to claim 1, wherein the strip is made of a material selected from: plastic materials, metals and metal alloys, bioceramics, and composite materials.

6. The bracelet clasp according to claim 5, wherein the strip is made of two materials selected from: plastic materials, metals and metal alloys, bioceramics, and composite materials.

7. The bracelet clasp according to claim 6, wherein the strip (2) comprises protruding edges (25) arranged to guide the second bracelet strand, said protruding edges (25) being positioned in the vicinity of the first end (20) of the strip (2).

8. A wristwatch including a bracelet provided with a bracelet clasp according to claim 1.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0014] Other features and advantages of the invention will be better understood upon reading the following description given of a non-limiting specific embodiment of the invention, provided for illustration purposes with reference to the accompanying figures, in which:

[0015] FIG. 1 is a perspective view of a clasp according to a first embodiment of the invention;

[0016] FIG. 2 is a perspective view of a clasp according to a second embodiment of the invention;

[0017] FIGS. 3 and 4 are perspective views of a clasp according to a third embodiment of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0018] A clasp for a bracelet will now be described hereinbelow with joint reference to FIGS. 1, 2, 3 and 4.

[0019] As shown in FIG. 1, the clasp 1 comprises a strip 2, a first end 20 whereof is hinged to a first end 30 of a first bracelet strand 3 via an arbor or a shaft passing through the strand, and the second end 21 of the strip 2 is free. According to yet another alternative embodiment, the strip can be clipped onto the strand via pins integral with the strip, the pins being formed at the same time as the strip during the manufacture thereof. The strip and the first strand 3 could also conceivably be formed at the same time, using different materials via a bi-injection method, and form one and the same piece.

[0020] As shown in FIG. 1, the first end 20 can have cut-outs to receive cylindrical portions of the end 30 of the first bracelet strand 3. Such a construction allows for a stronger and more rigid hinge.

[0021] According to the invention, said strip 2 comprises a cut-out 5 so as to form at least one rigid portion 22, located in the vicinity of the first end 20, and two opposite deformable portions 23, 24 located in the vicinity of the free end 21. The cut-out can take different shapes, such as a T or Y shape for example, or a logo shape.

[0022] As shown in FIG. 1, the two deformable portions each comprise, on the side facing the bracelet strand or on the bottom side, a pin 6 provided with a hook 6′ arranged to engage with a hole 40 in a second bracelet strand 4 and to lock the clasp on the second strand 4. The height of the pin 6 is designed to be slightly greater than the thickness of the bracelet strand so that the hook 6′ rests against the surface of the second strand 4 when the clasp is in the locked position. Similarly, the distance separating the two pins 6 is equivalent to the width of the hole 40 in the second strand 4 so that the clasp provides a good hold and lock once the hooks 6′ are in position. The pins 6 and the hooks 6′ thus form a locking mechanism arranged to hold the clasp with the second strand 4 when the watch is being worn.

[0023] Advantageously, the strip 2, the pins 6 and the hooks 6′ form an element that is made in one piece.

[0024] The strip 2 can have additional means for holding the second bracelet strand, such as a peg 8 as shown in FIG. 2 so as to provide an additional holding point for the second bracelet strand. Advantageously, this peg 8 can also be used as an aid for positioning the clasp on the second bracelet strand. The peg 8 is disposed on the bottom side of the rigid portion of the strip 2 and is arranged to engage with an additional hole 41 in the second strand 4.

[0025] The peg 8 thus acts as a safety device preventing the second strand 4 of the strip 2 from being unhooked, leading to the unexpected unlocking of the clasp in the event of an impact for example. Advantageously, the peg 8 is formed at the same time as the strip so that the assembly forms a one-piece element.

[0026] The deformable portions 23 and 24 of the strip 2 have machined edges to form push-pieces 26 and facilitate the gripping of the clasp for the deformation of the deformable portions.

[0027] According to one embodiment of the invention, the strip 2 comprises protruding edges 25 arranged to guide the second bracelet strand 4, the protruding edges 25 being positioned in the vicinity of the first end 20 of the strip 2, and oriented facing the bracelet strands.

[0028] According to another embodiment of the invention, shown in FIGS. 3 and 4, the strip 2 comprises a loop 7 for guiding the second bracelet strand 4, the loop 7 being placed in the immediate vicinity of the first end 20 which is hinged to the first end 30 of the first bracelet strand 3, the second bracelet strand 4 passing beneath the first strand 3 and then through the loop 7.

[0029] The strip 2 of the clasp 1 is made of a material selected from: plastic materials, metals and metal alloys, and composite materials, via moulding, injection, machining, stamping, 3D printing, or a combination of these methods. A strip can also be made of two materials. The strip 2 can, for example, be made of plastic material and metal, for example the deformable portions can be made of plastic material and the remainder can be made of metal.

[0030] According to yet another embodiment (not shown in the figures), the second bracelet strand comprises locking means arranged to engage with said strip.

[0031] The positioning of the clasp and how it is released from the second strand 4 will now be described.

[0032] In FIG. 3, pressure is applied simultaneously to the push-pieces 26 to move the deformable portions 23, 24 and thus reduce the distance separating the pins and bring them closer together before inserting them into a hole 40 in the second bracelet strand 4.

[0033] The pins 6 are inserted into the hole 40 until the hooks 6′ protrude from the hole 40. The wearer can then release pressure on the push-pieces 26, which causes the deformable portions 23, 24 to return to the rest position and consequently the hooks also to engage with the second bracelet strand, which causes the clasp to lock on the second bracelet strand.

[0034] To open the clasp, simultaneous pressure must be exerted on the push-pieces 26 to cause the hooks 6′ to be released from the hole 40 and the clasp to open.

[0035] It goes without saying that the present invention is not limited to the example shown but that various alternatives and modifications that may be apparent to a person skilled in the art can be made thereto.