EP2057914A1 - Bracelet with articulated links - Google Patents

Abstract

This articulated link bracelet, especially for a watch, comprises at least three rows side by side of links offset from one row adjacent to the other, in which at least one friction surface (3, 13, 23-163) of each articulation is in a material whose hardness is> 800HV. This bearing surface (3, 13, 23-163) is in contact with at least one hinge member (5, 15, 25-165) having at least one friction surface of a second material selected from the following materials: ceramic, ceramic-metal mixture, amorphous carbon, nickel-free stainless steel, cobalt alloy, gold or gold alloy, platinum or platinum alloy, platinoid or platinum alloy, titanium or titanium alloy, capable of reducing wear by friction with the friction surface (3, 13, 23-163).

Description

The present invention relates to an articulated link bracelet, in particular for a watch, comprising at least three longitudinal rows side by side of links offset longitudinally from one row adjacent to the other, in which at least one friction surface of each articulation is a first material whose hardness is> 800HV.

The problem of wear of joints of link bracelets, especially watchbands is a recurring problem since the appearance of this type of bracelets. Wear increases the play at the joints, giving a depreciative impression to the bracelet. This wear does not only attack the axes of joints, but also the links of the bracelet when it comes to metal links, particularly, in the case of bracelets with several rows of links side by side, the game of joints can finally allow to form notches in their adjacent side faces, thus detracting from the aesthetics of the bracelet.

It has already been proposed to remedy this defect in the EP 0 243 315 by interposing ruby bearings between the links and the hinge pins.

Contrary to what is stated in this document, the fact of producing very hard articulation elements, in this case, ruby bearings, does not by itself solve the problem of wear of the joints. This wear can be as important, or even more, depending on the case. In addition, the choice of ruby in the form of crystal poses reliability problems, given its relative fragility. However, the articulation elements of a bracelet are likely to be subject to severe constraints that can go until the breakage of the ruby joint elements, which can then cause damage difficult to repair.

Regardless of this risk, you should know that a bracelet is exposed to abrasive dust, as well as corrosive substances (seawater, perspiration, in particular). Depending on the material of the counter-bearing surface which rubs against the ruby bearing element, these dusts and corrosive substances can cause wear of this counter-surface at least as great as in the absence of the element of Ruby bearing, as shown by long-term wear tests carried out on simulation devices in different atmospheres.

The object of the present invention is to reduce the wear of the friction surfaces of the joints of metal link bracelets.

For this purpose, the subject of the invention is an articulated metal link bracelet according to claim 1.

Advantageously, the hinge surface is that of a ceramic element sintered or deposited on a substrate, or a ceramic-metal mixture sintered or deposited on a substrate in the form of alternating ceramic metal layers.

Alternatively, a hinge surface is that of a substrate coated with amorphous carbon.

Long-term wear simulation tests in corrosive and abrasive atmospheres have shown a marked reduction in wear between the hinge surfaces according to the invention and the state of the art.

The accompanying drawings illustrate, schematically and by way of example, various embodiments of the articulated metal link bracelet object of the present invention.

The figure 1 is an exploded perspective view with sectional portions of a first embodiment;

the figure 2 is an exploded perspective view of a second embodiment;

the figure 3 is an exploded perspective view of a third embodiment;

the figure 4 is an exploded perspective view of a fourth embodiment;

the Figures 5 and 6 are exploded perspective views of two variants of the figure 4 ;

the figure 7 is a sectional view along the axes of articulation of the links of the bracelet;

the figure 8 is an exploded perspective view of a fifth embodiment;

the figure 9 is an exploded perspective view of a variant of the figure 8 ;

the figure 10 is an exploded perspective view of a sixth embodiment;

the figure 11 is an exploded perspective view of a variant of the figure 10 ;

the figure 12 is an exploded perspective view of a seventh embodiment;

the figure 13 is an exploded perspective view of a variant of the figure 12 ;

the figure 14 is an exploded perspective view of an eighth embodiment;

the figure 15 is a sectional view along the axes of articulation of the links of the bracelet, a ninth embodiment;

the Figures 16A, 16B are respectively an exploded perspective view and a sectional view along the axes of articulation of the links of the bracelet, a tenth embodiment;

the Figures 17A, 17B are respectively an exploded perspective view and a sectional view along the axes of articulation bracelet links, an eleventh embodiment;

the figure 18 is a comparative diagram of wear of different pairs of materials.

Many embodiments of the present invention are possible. All these forms of execution have one thing in common, however, to allow friction between materials identified for their compatibility to rub against each other with a minimum of wear, even in the presence of abrasive and corrosive agents. , as is the case of an articulated link wristwatch, worn in all circumstances, without any protection of its hinge elements is possible. All the illustrated embodiments represent only segments of link bracelets, the formation of complete bracelets being obtained by the addition of links or sets of integral links, identical to those illustrated, until obtaining a desired length of strand. The connecting elements of the strands of bracelets to the watch case, as well as the clasp which serves to connect the two strands to one another and which, in the case of this type of bracelet is generally a clasp said "to folding clasp ", do not form part of the invention. Also, they were not represented. This obviously does not prevent the joint surfaces between the links of the bracelet and the adjacent elements of the clasp can use the pairs of materials according to the present invention, it relates to all the joints of the different elements of a bracelet link, including its articulation with the clasp and possibly the watch case.

In the embodiment illustrated by the figure 1 two center links MC and four edge links MB are shown forming two sets of integral links. articulated to each other. In this example, these links are of a material that is not likely to reduce wear when it rubs against a surface whose hardness is> 800HV, such as a ceramic surface or a ceramic-metal mixture.

The center links MC are offset in the longitudinal direction of the bracelet relative to the two rows of edge links MB, so that one center link MC is astride two edge links MB of each row. A center link MC has three transverse passages, two of which each receive a connecting element 1 constituted by a rod whose two end portions of smaller diameters protrude on each side of the center link MC. The protruding parts of the connecting elements 1 are intended to be driven into blind holes 2 of two links of edges MB which face each other. As a result, a center link MC forms a unitary assembly with the two edge links MB in which the projecting ends of the connecting elements 1 are driven out.

The joint is thus made between two sets of adjacent integral links, each having a center link MC offset longitudinally with respect to two MB edge links aligned transversely to the bracelet.

The center link MC of this set of integral links comprising a center link MC and two edge links MB is articulated to two edge links of the same set of adjacent integral links. For this purpose, an insert bearing element, in this example, formed by a sintered ceramic tube 3 or a sintered metal ceramic mixture is engaged inside the third transverse passage 4 of the center link MC. The ceramic chosen will advantageously be zirconia. An axis 5 is freely engaged in this tube 3 and its ends are driven in two blind holes 6 of the two edge links MB of the adjacent integral link assembly.

If the bracelet is made of a standard steel for a bracelet, such as 316L steel, it is necessary that the tube 3, made of sintered ceramic or in a sintered metal ceramic mixture, be fixed to the center link MC, by driving or by gluing by example.

A second axis of articulation 5 or 5a if, as illustrated on the figure 1 the hinge pin 5a is an axis of which an end portion is a screw head and the other end portion is threaded to screw into an opening 6a of the adjusting edge link MB, while the opening 6b for the screw head passes through the adjusting edge link MB. These axes 5a and the adjusting edge links MB with openings 6a, 6b are intended to allow adjustment of the length of the bracelet by removal or addition of edge links MB and adjustment axes 5a. This is true for all forms of execution, so that this adjustment system, moreover conventional in this type of bracelet, will no longer be described. When it is not a question of allowing adjustment, the hinge axis 5a is replaced by a normal hinge axis 5.

If the axis of articulation is an axis 5, it is intended to be fixed in the openings 6 of the two opposite edge links MB for the articulation of a set of integral links MC, MB adjacent as shown.

The hinge pins 5, 5a are made of one of the materials which makes it possible to reduce the frictional wear with the sintered ceramic ceramic tubes or metal ceramic mixture 3. One of these materials is a cobalt alloy. Among the other materials capable of reducing frictional wear with the tube 3, under the conditions to which the wristbands of During their use, mention may be made of nickel-free stainless steels, gold and gold alloys, platinum and platinum alloys, titanium and titanium alloys, and all platinoids and their alloys. The choice of material is essentially based on the material or materials used to make links MB, MC.

In the embodiment illustrated by the figure 2 , the sintered ceramic tube 3 of the first embodiment is replaced here by two shorter bearing tubes 13 disposed on either side of the central portion of larger diameter of the hinge axis 15. The positions respective axial axes of these bearing tubes 13 are defined by the bearing surfaces between the central part of the hinge axis 15 and the adjacent parts on which the bearings 13 are mounted. The bearing tubes 13 are driven out or glued into the opening 14 of the center link MC leaving a very small clearance (a few hundredths of a millimeter) between the bearing tubes 13 and the bearing surfaces of the central part of the hinge pin 15 .

On their side, the ends of the hinge pin 15 are driven into the openings 16 of the edge links MB, so as to provide a clearance between the lateral faces of the edge links MB and the lateral faces of the link member. MC center. This game is chosen very slightly larger than the clearance between the bearing tubes 13 and the bearing surfaces of the central part of the hinge pin 15, so that the lateral faces of the links MB and MC can not touch each other and that the lateral friction only occurs between the ceramic bearing tubes 13 and the bearing surfaces of the central part of the hinge pin which, depending on the nature of the material of which the links MC, MB, are formed of cobalt alloy , in nickel-free stainless steel, in gold alloy, in platinum alloy or platinoid alloy or titanium alloy.

The diameter of the central part of the hinge axis 15 is obviously smaller than that of the opening 14 of the center link MC, so that the friction between the cylindrical surfaces occurs only between the inner faces of the bearing tubes and pivot shaft portions 15 which pass through the respective bearing tubes 13.

The form of execution illustrated by the figure 3 aims at the same goal as the previous one. However, in this case, the bearing tubes 23 are completely housed, fixed or not depending on the nature of the material of which the links are made, in the edge links MB. Unlike the execution form of the figure 2 the pivot axes 25 are not fixed in the edge links MB, but in the center link MC. Lateral friction occurs between one end of the bearing tube 23 and a bearing surface of the hinge pin 25 which is in one of the materials capable of reducing wear with the ceramic bearing tube or a sintered metal ceramic mixture. Alternatively, the bearing tube could be coated metal, amorphous carbon, also called DLC (diamond like carbon), ceramic or alternating layers of ceramic and metal deposited by PVD (Physical Vapor Deposition).

The form of execution of the figure 4 comprises a bearing tube 33 fixed in a center link MC. The hinge axis 35 is here divided into two parts. Each part of this hinge axis comprises a segment of larger diameter, driven in an edge link MB and a part of smaller diameter, freely engaged in the bearing tube 33, so that once assembled the distance between the segments of larger diameter is equal to the length of the tube increased by a functional game allowing the pivoting of the links. The bearing tube 33 is made of sintered ceramic, or a metal ceramic mixture, the hinge pin is in one of the abovementioned materials to reduce wear with the ceramic tube. As in the forms of executions of Figures 2 and 3 , the lateral friction is between the ends of the bearing tube 33 and the bearing between the segments of different diameters of the hinge axis 35 in two parts.

Alternatively, as illustrated by figure 5 the two pivotal half-axes can be replaced by an articulation pin 45 comprising a segment of larger diameter driven in an edge link MB and a segment of smaller diameter freely engaged in the bearing tube 43 and a sleeve 45a. driven in the edge link MB located opposite the edge link in which the larger diameter segment of the hinge axis 45 is driven. By adjusting the penetration of the hinge axis 45 and the bushing 45a, it can be ensured that the lateral friction occurs exclusively between the ends of the bearing tube 43 and the bearing surface of the hinge pin 45 on the one hand and the end of the sleeve 45a on the other hand.

In the variant of the figure 6 , the bearing tube 53 is divided into two half-tubes shorter to avoid the chase over the entire width of the MC center link.

The figure 7 illustrates a device for adjusting the length of the bracelet. For this purpose, the hinge axis 66 has a thread 66a at one end and a screw head 66b at the opposite end. To avoid lateral friction between the edge links MB and the center link MC, two small bearing tubes 65 are driven into the edge links MB. Lateral friction occurs between these bearing tubes 65 and the bearing tubes 63 driven into the center link MC.

In the form of execution of the figure 8 , the bearing tube (s) are replaced by balls 73 which are taken sandwiched between two bushes 75 driven in a center link MC and two bushes 75a driven respectively in the two links of adjacent edges MB. The edge links MB are assembled by driving the connecting elements 71 which hold the balls 73 in contact with the annular edges of the bushes 75, 75a which advantageously form frustoconical surfaces.

In the variant of the figure 9 there are two friction members in the form of lenses. One 83 is ceramic and is placed in a housing 84 formed in each side face of the center link MC of one of the integral assemblies. Its convex contact face protrudes from the lateral face of the center link (MC). The other lens-shaped member 85 is in one of the abovementioned materials chosen for its low frictional wear with the ceramic and is housed in a housing 84a formed in the inner side face of each edge link MB, with its domed surface projecting this side face to come into contact with the convex face of the ceramic member 83. The whole is maintained by the connecting elements 81 driven in the two links of edges. Depending on the material of which the links are formed, the lenses 83, 85 are fixed in their housing 84, 84a, for example by gluing.

In general, it is preferable that the bearing tube is integral with the link and can not rotate or translate therein. In the previous examples, we talked about chasing or gluing. Hunting a ceramic tube is not easy to perform. Also the forms of execution of Figures 10 to 14 are alternative means of attachment. The figure 10 relates to a bearing tube 93 provided with recessed surfaces 93a to cooperate with locking keys 90, preferably of plastic, engaged in adjacent openings 94a and communicating with a transverse passage 94 receiving the bearing tube 93, fitted tightly between the tube and the shaft 91.

Another way of securing the bearing tube 103 in the center link MC consists of producing a tube in the form of a sintered ceramic profile whose non-circular section has an outgrowth as illustrated by FIG. figure 11 . The section of this section 103 corresponds to a portion of the section of the passage 104 formed transversely to the center link MC. The protrusion of the section must be sufficient to come into contact with the links MB and thus block the translation of the profiled tube. The axis of articulation 105 is similar to the axes of joints of the Figures 5, 6 and 10 with a larger diameter end segment driven into an edge link MB on one side of the center link MC, a bushing 105a being driven into the edge link MB located on the other side of the center link MC. This bushing 105a and the span between the larger diameter segment and the smaller diameter segment of the hinge axis 105 serve for lateral friction with the ends of the profiled bearing tube 103, the length of which is slightly greater than the width of center link MC.

In the case of figure 12 , the center link MC is a hollow section in the transverse direction, in the opening 117 of which is introduced a sintered ceramic or ceramic ceramic insert 113, the section of which is exactly complementary, with the clearance, to that of the opening 117 of the hollow section forming the center link MC. The insert 113 has three passages 114, two for the connecting elements 111 whose ends are driven in the edge links MB of the two outer rows of the bracelet and a passage 114 for the hinge axis 115, identical to the axis of articulation of Figures 5, 6 , 10, 11 . As in all In the above embodiments, the material of the hinge pin 115 and the bushing 115a is made of one of the aforementioned materials for rubbing with the sintered ceramic or sintered metal ceramic insert. Advantageously, this hinge axis 115 and the sleeve 115a will be of the same metal or alloy as the links of the bracelet when the latter is a gold alloy, platinum or platinoid. It will preferably be made of nickel-free stainless steel if the links are made of steel, or if certain links are made of steel and others are made of gold alloy. It can also be made of a metal coated with amorphous carbon.

In the variant of the figure 13 , the inserts 123 are in two parts driven at both ends of the opening of the hollow section forming the center link MC, so as to favor contact with the bearing surfaces of the hinge pins 125 and 125a and the inserts. The rest of this variant is identical to the execution form of the figure 12 .

The variant of the figure 14 differs from the preceding essentially in that a spring 138 working in compression is interposed between the two inserts 133 sintered ceramic or sintered metal ceramic mixture, thus exerting a privileged contact between an insert 133 and the socket 135a driven into a link MB and which is coaxial with the hinge axis 135, and between the other insert 133 and the range between the larger diameter segment of the hinge pin 135 and its smaller diameter segment .

The form of execution illustrated by the figure 15 refers more specifically to a bracelet whose links are made of metal or alloy of precious metal. In this case, the hinge pins 145 are advantageously in the same metal or alloy as that of the links and are preferably brazed in the edge links MB. The bearings 143 are small sintered ceramic tubes, mounted free in the transverse passages 144 of the center links MC, since the friction between the ceramic and a gold or platinoid alloy is favorable from the point of view of the reduction of the wear.

We have shown on the figure 15 the case where a pivot axis is constituted by a screw 145a then allowing to add or remove links for adjustment of the length of the bracelet.

The Figures 16A, 16B illustrate a variant of a bracelet whose links and axes of articulation are made of gold alloy or platinoid. This bracelet has five rows with links alternately shifted from one row to another. This bracelet thus comprises two rows of MB edge links and three rows of center links MC, MC ₁ , MC ₂ . Two ceramic or metal ceramic mixture inserts 153 are housed in the center links MC ₁ , MC ₂ and have transverse passages 154 for the hinge pins 155.

For the same type of bracelet with five rows of alternating links, but made of steel, there are as many tubes 163 as the product of the number of links by the number of axes of joints 165, ie in the bracelet portion illustrated by the Figures 17A, 17B , ten tubes. The ends of the hinge pins 165 are fixed in the edge links MB. Here, one of the axes 165a is shown in the form of a screw to allow the adjustment of length by removal or addition of links.

The dimensions of the bearings 163 transverse to the strap are chosen so that the lateral friction between the links occurs exclusively between the end faces of the bearings 163, which are fixed in the links MB, MC, MC ₁ , MC ₂ . So all the friction is produced between these bearings 163 or between the bearings and the axes of joints 165 which are preferably made of a cobalt alloy. These axes could also be nickel-free stainless steel or another metal coated with amorphous carbon or ceramic.

Materials which can reduce frictional wear with a friction surface with a hardness> 800HV were studied using a tribometer with a disc made of one of the test materials against which an arm applies a ball in the other of the test materials, with a determined force. The difference in the diameter of the impression on the ball and the depth of the groove on the disc is measured and the total used volume of the two materials is calculated.

A series of comparative tests was carried out. The results of these tests are shown in the diagram of the figure 18 . On the abscissa, four comparative tests A, B, C, D have been represented, and the ordinate shows the volume used in μm ³ . The tests are performed by attempting to reproduce the actual conditions in which a watchband is used. For this purpose, the tests are carried out with a particular additive and under a controlled atmosphere. The additive consists of an abrasive (silica powder) in an organic oil matrix.

A ₁ corresponds to the frictional wear between an austenitic stainless steel disk with nickel, standard in the field of watchbands, such as 316L and a cobalt alloy ball

A ₂ corresponds to the frictional wear between the same cobalt alloy ball rubbing against a sintered zirconia disk.

A ₃ corresponds to the frictional wear between an 18k gold disc and a cobalt alloy ball.

B ₁ corresponds to the frictional wear of an 18k yellow gold ball against an austenitic stainless steel disk with nickel.

B ₂ corresponds to the frictional wear of an 18k yellow gold ball against a sintered zirconia disk.

B ₃ corresponds to the friction wear of an 18k yellow gold ball against an 18k yellow gold disc.

C ₁ corresponds to the friction wear of a titanium ball against an austenitic stainless steel disk with nickel.

C ₂ is the frictional wear of a titanium ball against a sintered zirconia disk.

D ₂ corresponds to the frictional wear of a platinum ball against a sintered zirconia disk.

D ₄ corresponds to the frictional wear of a platinum ball against a platinum disc.

Claims (18)

Articulated link bracelet, especially for a watch, comprising at least three longitudinal rows side by side of links (MB, MC) offset longitudinally from one row adjacent to the other, in which at least one friction surface (3, 13, 23-163; 5, 15, 25-165) of each hinge is made of a first material whose hardness is> 800HV, characterized in that at least one other friction surface of each hinge is made of a second material selected from the materials ceramic, ceramic-metal mixture, amorphous carbon, nickel-free stainless steel, cobalt alloy, gold, gold alloy, platinum, platinum alloy, platinoid, platinum alloy, titanium, titanium alloy capable of reducing wear between said friction surfaces. The bracelet of claim 1 wherein one of said friction surfaces (3, 13, 23., 163) is that of at least one sintered ceramic insert, or sintered ceramic-metal mixture. A bracelet according to claim 1 wherein one of said friction surfaces (3, 13, 23., 163) comprises a substrate coated with one of the following materials: ceramic, ceramic-metal, amorphous carbon. Bracelet according to one of the preceding claims, wherein the links are metal links. Bracelet according to one of the preceding claims, whose hinge pins (165) are in said second material, their ends being fixed in the edge links (MB), and passing through at least one bearing of said first material (163). Bracelet according to one of the preceding claims, in which two transversely aligned edge links (MB). and a longitudinally offset center link (MC) form a first assembly, articulated to a second same adjacent assembly, one of said friction surfaces being that of a hinge axis (15) whose ends are fixed to the two links of edges (MB) of the first set and whose central portion has a segment of larger diameter with two bearing surfaces, two bearing tubes (13), forming at least one other friction surface and wherein said hinge pin (15) is engaged , being fixed in a transverse passage through a longitudinally offset portion of the link (MC) of the central row of the second adjacent set, on either side of the central segment of larger diameter of said axis. Bracelet according to one of claims 1-4, wherein two transversely aligned edge links (MB) and a longitudinally offset center link (MC) form a first integral assembly, articulated to a second, adjacent integral assembly, one of said surfaces. friction is that of a hinge pin (15), whose central portion comprises a segment of larger diameter integral with the center link (MC) and providing two bearing surfaces, two bearing tubes (13), forming at least one another friction surface and in which said hinge axis (15) is engaged, being fixed in a transverse passage formed respectively in the two edge links (MB) of the second adjacent integral assembly, on either side of the central segment larger diameter of said axis, whose bearings serve as stops to said bearing tubes (13) to ensure lateral friction between the integral assemblies. Bracelet according to one of claims 1 to 5, wherein two transversely aligned edge links (MB) and a longitudinally offset center link (MC) form a first integral assembly articulated to a second one. adjacent integral assembly, one of said friction surfaces being that of a two-part hinge pin (35), each having a larger diameter segment, secured in an edge link MB of the first integral assembly and a further segment small diameter, freely engaged in a bearing tube (33) forming at least one other friction surface and transversely through the central link of the second integral assembly, the lateral friction being between the ends of the bearing tube (33) and the bearing between the segments of different diameters of the hinge axis (35) in two parts. Bracelet according to one of claims 1 to 5, wherein two transversely aligned edge links (MB) and a longitudinally offset center link (MC) form a first integral assembly, articulated to a second same adjacent integral assembly and wherein a said friction surfaces is that of a hinge axis (45) having a segment of larger diameter fixed in an edge link (MB) of the first integral assembly and a segment of smaller diameter freely engaged in a bearing tube ( 43, 53) forming at least one other friction surface and traversing transversely the center link of the second integral assembly, a sleeve (45a, 55a) forming at least one other friction surface being fixed in the other edge link (MB ) of the first integral assembly, wherein the lateral friction occurs between the ends of the bearing tube (43, 53) and the bearing surface of the hinge pin (45, 55) on the one hand and the extrusion emitted from the sleeve (45a, 55a) on the other hand. Bracelet according to one of claims 1 to 4, wherein two transversely aligned edge links (MB) and a longitudinally offset center link (MC) form a first integral assembly articulated to a second set adjacent, the friction surfaces of each joint comprising on the one hand balls (73) in one of the two materials, disposed between each lateral end of the projecting portion of the center link (MC) and the adjacent lateral faces of the edge links (MB) of the second adjacent integral assembly, each ball being taken between two respective annular friction surfaces of two hinge tubes of the other of said materials, respectively secured to two transverse passages opening in the respective lateral faces; the edge link (MB) of the adjacent integral assembly and the projecting portion of the center link (MC). Bracelet according to one of claims 1 to 4 wherein two transversely aligned edge links (MB) and a longitudinally offset center link (MC) form a first integral assembly, articulated to a second same adjacent integral assembly, each joint comprises two pairs of projecting contact surfaces, one (85) projecting from the inner side face of the portion of each edge link (MB) of the first integral assembly, adjacent to one of the two side faces of the center link (MC) of the second integral assembly, the other projecting from each of the lateral faces of the center link (MC). Bracelet according to one of claims 1 to 5, wherein one of said friction surfaces is a bearing surface formed by a tubular element (93) housed in a transverse passage (94) of the center link (MC) or edge ( MB) and whose cylindrical face is interrupted by a recessed surface cooperating with a key housed in an adjacent opening and communicating with the transverse passage (94) receiving the tubular element (93). Bracelet according to one of claims 1 to 5, wherein one of said friction surfaces is a surface of bearing formed in a profiled element (103) of non-circular section, housed in a passage (104) of which at least a portion of the section corresponds to that of said profiled element (103). Bracelet according to one of claims 1 to 5, wherein the center link (MC) is a hollow section in the transverse direction, in the opening (117) which is introduced an insert (113), the section is complementary of that of the opening (117) of the hollow section forming the center link (MC) and which comprises three transverse passages (114), two for connecting elements (111) whose ends are driven into the edge links ( MB) of the two outer rows of the first integral assembly and a passage (114) forming one of said friction surfaces for the hinge axis (115) having the other friction surface. Bracelet according to one of claims 1 to 5, wherein the center link (MC) comprises a passage of non-circular section (137) for freely receiving two inserts (133) whose section is complementary to that of said passage ( 137), these inserts (133) having transverse passages (134) forming one of said friction surfaces for receiving the hinge axis (135) forming another friction surface and an elastic member (138) working in compression interposed between said inserts. Bracelet according to one of claims 1 to 5 wherein two transversely aligned edge links (MB) and a longitudinally offset center link (MC) form a first set, articulated to a center link (MC) of a second one adjacent assembly and in which the links (MB, MC) and the axes of joints (145) are in said second material, the ends of the axes of joints (145) being fixed in the edge links (MB) of a first set and traversing at least one bearing in said first material (143) freely engaged in a transverse passage (144) of the center link (MC) of the second set . Bracelet according to one of claims 1 to 4, comprising five rows of links (MB, MC ₁ , MC, MC ₂ , MB) offset longitudinally, alternately from one row to another and in which the links (MB, MC ₁ , MC, MC ₂ , MB) and the hinge pins (145) are in said second material, the ends of the hinge pins (155) being fixed in the transversely aligned edge links (MB) and traversing two bearings (153) in said first material engaged in two transverse passages of two center links (MC ₁ , MC ₂ ) offset longitudinally with respect to the other three links (MB, MC, MB) ,. Bracelet according to one of the preceding claims, wherein said first material is based on zirconia.

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