EP4009118A1 - Device for assembling two watch components - Google Patents

Abstract

The subject of the present invention is a device for assembling two timepiece components comprising a first timepiece component (1) and a second timepiece component (2) intended to be assembled together by means of at least one assembly (3), the assembly member (3) being retained on the second component (2) and being arranged to cooperate with at least one assembly portion (12) provided on the first component (1) for the assembly of the first component (1) on the second component (2), the assembly member (3) comprising at least one elastic zone (31) intended to cooperate with the assembly portion (12) of the first component (1) and arranged to be deformable between a rest position and a maximum deformation position. The assembly member (3) is a piece attached to the second component (2).

Description

The subject of the present invention is a device for assembling two timepiece components. In particular, the present invention relates to a device for assembling the back or the bezel on the middle part of a watch case.

In watchmaking, the watch case is made up of a middle part, closed on the side of the bridges or the plate by a back, and on the side of the dial by the bezel and crystal. In general, the caseback and/or the bezel are screwed down, snap-fitted or held in place by screws on the caseband.

In a snap fit, one of the components includes a groove into which a second component snaps. One part of the fit should be slightly flexible to allow the second component to be forced into the groove. The groove has a triangular shape with two distinct slopes, one for the deformation of the flexible element and the other for the maintenance of the second component.

The notch adjustment has the advantage of allowing a more aesthetic final result since there are no screws or claw (screwed bottom) visible after assembly. However, the materials commonly used for a watch case, precious materials such as gold or platinum, lend themselves very poorly to deformation. Thus, it is difficult during the production of the parts to ensure a closing force to maintain the assembled components precise and regular on all the parts. This leads to a consequent reworking of the parts produced or even the scrapping of some whose quality is really too bad. Next, the closing force is not stable over time and will deteriorate with the multiple assembly/disassembly required by the checks and tests during assembly of the timepiece (more than ten openings/closings of the watch box are necessary for the realization of a striking watch) or after-sales service.

The object of the present invention is to produce a device for assembling two horological components, in particular a caseback/bezel and a caseband which is safe, efficient, easy to produce while limiting rework and scrap after manufacture, resistant over time by guaranteeing a closing force for the maintenance of the assembled components stable even after numerous assembly / disassembly while offering an aesthetic result, with an almost invisible device when the two components are assembled.

• Les figures annexées illustrent schématiquement et à titre d'exemple une forme d'exécution du dispositif d'assemblage selon l'invention.
• La figure 1 est une vue éclatée d'une forme d'exécution de l'invention illustrant l'assemblage d'une lunette sur une carrure d'une boîte de montre.
• La figure 2a illustre une vue en coupe de la carrure et de l'organe d'assemblage du dispositif d'assemblage selon la forme d'exécution de la figure 1 tandis que la figure 2b est un agrandissement d'une portion de la figure 2a.
• Les figures 3a et 3b illustrent l'organe d'assemblage de la forme d'exécution de la figure 1 en position libre, respectivement en position encastrée.
• Les figures 4a à 4c illustrent la séquence d'assemblage de la lunette sur la carrure.

The subject of the present invention is a device for assembling a first and a second horological component according to claim 1.

• The appended figures illustrate schematically and by way of example an embodiment of the assembly device according to the invention.
• The figure 1 is an exploded view of an embodiment of the invention illustrating the assembly of a bezel on a middle part of a watch case.
• The figure 2a illustrates a sectional view of the middle part and of the assembly member of the assembly device according to the embodiment of the figure 1 while the figure 2b is an enlargement of a portion of the figure 2a .
• The figures 3a and 3b illustrate the assembly member of the embodiment of the figure 1 in the free position, respectively in the recessed position.
• The figures 4a to 4c illustrate the assembly sequence of the bezel on the middle.

According to the illustrated embodiment, the assembly device according to the invention is intended to assemble a bezel on the middle part of a watch case.

To do this, the device illustrated comprises a bezel 1, a middle part 2 and an assembly member 3. Preferably, the device also comprises a seal 4.

In the illustrated embodiment, middle part 2 comprises a groove 22 over a large part of its inner periphery 21. Groove 22 forms a housing intended to receive assembly member 3 as will be seen later.

In the illustrated embodiment, the bezel 1 comprises, on the back side (that is to say on the side of the bezel intended to face the back of the watch case), a cylindrical portion 11 terminated by a shoulder 12. View in cross section, this cylindrical portion 11 therefore has the shape of a hook as illustrated in figure 4a to 4c . The shoulder 12 is characterized at its end by two distinct slopes: a first inclined flank 13 and a second inclined flank 14 of opposite inclination.

A groove 15 is formed between the shoulder 12, the lower wall 16 and the cylindrical portion 11 of the bezel 1. The seal 4 is housed in this groove 15.

According to the invention, the assembly device comprises an assembly member 3 comprising at least one elastic assembly zone 31. Preferably, the assembly member comprises at least three elastic assembly zones 31. even more preferred and as illustrated in the figures, the assembly member 3 comprises five elastic assembly zones 31.

The five elastic assembly zones 31 are each intended to cooperate with the shoulder 12 of the bezel 1.

In the illustrated embodiment, the five elastic assembly zones 31 are interconnected by four elastic blades 32, to form an assembly member 3 of quasi-circular and open shape ( picture 3a ). This allows a function command 5 (stem, pusher, etc.) to pass through the middle part 2, when the assembly member 3 is housed in the groove 22. Thus, in this embodiment the groove 22 does not extend over the entire inner periphery 21 of caseband 2 since there is a portion of this inner periphery 21 occupied by function control 5.

The elastic blades 32 are arranged to hold the assembly member 3 in the groove 22 solely by their elastic force. The picture 3a illustrates the assembly member 3 free, while the figure 3b illustrates the assembly member 3 forced into a recessed position that it occupies once housed in the groove 22.

In the illustrated embodiment, the five elastic assembly zones 31 are essentially identical. Each elastic assembly zone 31 comprises at least one but preferably two support points 311, placed at the ends of the zones in the illustrated embodiment. The assembly member 3 is arranged so that each bearing point 311 is in contact with the bottom of the groove 22 when said assembly member is in its recessed position in the groove 22 ( figure 2a ). Each elastic assembly zone 31 is also arranged to be able to deform radially towards the bottom of the groove 22 when the assembly member 3 is in its position embedded in said groove 22.

Finally, each elastic assembly zone 31 comprises two distinct slopes: a first inclined flank 313 and a second inclined flank 314 of opposite inclination and intended to cooperate respectively with the first and second inclined flanks 13, 14 of the shoulder 12 of the the bezel 1.

The assembly of the bezel 1 on the caseband 2 will now be described in detail with particular reference to the figures 4a to 4c .

We begin by embedding the assembly member 3 in the groove 22. In the illustrated embodiment, the assembly member 3 being open and elastic ( picture 3a ), it suffices to constrain the elastic blades 32 to reduce the diameter of the assembly member 3 (by hand or using a tool). Once constrained, it is possible to completely insert the assembly member 3 into the groove 22. By releasing the stress, the elastic blades 32 will push and hold the assembly member 3 in its recessed position in the groove 22 ( figure 2a and 3b ). In the recessed position of the assembly member 3, each fulcrum 311 of the elastic assembly zones 31 is in abutment in the bottom of the groove 22, under the action of the elastic blades 32.

In this embedded position of the assembly member 3 in the groove 22, the elastic assembly zones 31 are in a rest position and can be deformed radially in the direction of the bottom of the groove 22 under the action of a constraint.

The bezel 1 is then positioned (with the seal 4 housed in the groove 15) on the middle part 2. In the illustrated embodiment, it is not necessary to position the bezel 1 in a particular angular position by relative to the caseband 2, since the shoulder 12 extends over the entire circumference of the bezel 1 and is therefore capable of cooperating with the five elastic assembly zones 31 of the assembly member 3 whatever the position angle of the bezel 1 on the middle part 2. In this disassembled position of the bezel 1 relative to the middle part 2, the elastic assembly zones 31 of the assembly member 3 are in their rest position and the first blank inclined 13 of the shoulder 12 of the bezel 1 comes into abutment against the first inclined blank 313 of said elastic zones 31 ( figure 4a ).

From this position, a first force is exerted on the bezel 1 perpendicular to the plane of the bezel 1 and in the direction of the middle part 2. The shoulder 12 and the elastic assembly zones 31 are shaped so that, under the action of this first force, the first inclined flank 13 of the shoulder 12 cooperates with the first inclined flanks 313 of the elastic assembly zones 31 to deform said elastic zones 31 radially in a direction perpendicular to the first force in the direction of the bottom of the groove ( figure 4b ).

The first force is maintained on the bezel 1 and the first inclined flank 13 of the shoulder 12 cooperates with the first inclined flanks 313 of the elastic assembly zones 31 until said elastic zones 31 reach a position of maximum deformation in which they no longer block the bezel 1 ( figure 4b ).

At that moment, the bezel 1 can be pushed by maintaining the first force into its assembled position on the middle part 2 (lower wall 16 of the bezel 1 in abutment against the upper wall 23 of the middle part 2). Simultaneously, the elastic assembly zones 31 seek to resume their rest position and the second inclined flanks 314 of said elastic zones 31 come into contact with the second inclined flank 14 of the shoulder 12. Said second inclined flanks 14, 314 are arranged to that the elastic zones 31 by seeking to return to their rest position exert a force on the shoulder 12 which tends to bring and maintain the bezel 1 in its assembled position.

Thus, once the elastic zones 31 have returned to their rest position, they maintain the bezel 1 in its assembled position on the caseband 2 thanks to their second inclined flank 314 in abutment against the second inclined flank 14 of the shoulder 12 of bezel 1 ( figure 4c ).

As a variant, the elastic zones 31 could return to an intermediate position, between their position of maximum deformation and their position of rest. This intermediate position could be configured to maintain the bezel 1 in its assembled position and also prevent any rotation of the bezel 1 relative to the caseband.

Preferably, the second inclined sides 14 and 314 of the shoulder 12 and of the elastic zones 31 are parallel in the assembled position of the bezel 1 on the middle part 2. Thus, once assembled, there is no axial play and between bezel 1 and caseband 2.

Depending on the arrangement of the two inclined flanks on the elastic zones 31 and on the shoulder 12, it is possible to disassemble the bezel 1 from the middle part 2 as described below.

From the assembled position of bezel 1 on caseband 2 illustrated in figure 4c , it is necessary to exert a second force on the bezel 1 opposite to the first force, that is to say perpendicular to the plane of bezel 1 and directed towards the outside of the case. The second inclined sides 314, 14 of the elastic zones 31 and of the shoulder 12 will then cooperate and deform said elastic zones 31 from their rest position into their position of maximum deformation ( figure 4b ).

Once in their position of maximum deformation, the elastic zones 31 no longer cooperate with the second inclined flank 14 of the shoulder 12 and no longer retain the bezel 1 ( figure 4a ). The bezel 1 can be completely detached from the middle part 2 and the elastic zones 31 of the assembly member 3 return to their rest position.

The illustrated embodiment therefore allows very easy and reversible assembly of the bezel 1 on the middle part 2.

Preferably, the bezel 1 and the caseband 2 are made of a precious material such as gold or platinum, while the assembly member 3 can be made of steel or any other material suitable for the production of an elastic part. . In particular, it is possible to use materials such as steel, ceramics, glass or plastic, etc. which lend themselves better to deformation than gold or platinum, usually used for the manufacture of a watch case.

The closing force holding the bezel assembled on the middle part is determined by the elastic zones and it is therefore possible to choose the material, the shape and the other properties of these elastic zones to obtain a determined closing force.

The illustrated embodiment has the advantage of a very easy and quick assembly of the assembly member 3 in the groove 22, the assembly can even be done by hand without tools. As a variant, the five elastic assembly zones 31 could be connected by five elastic blades 32 to form a closed circular assembly member. In this case, it may be necessary to use a tool to compress the elastic blades and allow the assembly member to be embedded in the groove 22, which then extends over the entire inner periphery 21 of the middle part 2.

The present invention therefore makes it possible to ensure precise, rapid and aesthetic assembly of the bezel on the caseband. By making it possible to produce an assembly member in a more appropriate material than the precious materials making up a watch case, manufacturing is made more reliable and optimized with less scrap and less rework to ensure correct assembly strength. The stability of the assembly force over time is also easier to control with less risk of deterioration than with a gold or platinum elastic element. In addition, the assembly member can be easily replaced in the event of a problem without having to replace another element of the watch case in an expensive raw material. Finally, once the bezel is assembled on the middle, the result is as aesthetic as with a traditional notch adjustment, since the assembly component is completely hidden.

The present invention is not limited to the embodiment described. Other variants are possible and fall within the scope of the present invention.

In particular, the assembly member 3 could comprise only one elastic assembly zone 31. In this case, the bezel and the middle part also comprise means of embedding such as a lug on the middle part intended to come fit into a seat in the bezel (or vice versa).

In another variant, the elastic assembly zones could be different from each other by their shape, their material or their elastic properties and thus define a distinct closing force from each other. This can be particularly useful for components to be assembled which are not circular (square or elliptical watch case for example, with a separate closing force for each face).

Also as a variant, the shoulder could not extend over the entire inner periphery of the bezel but be divided into one or more hook zones which must be aligned during assembly with the corresponding elastic assembly zones of the assembly device. Means polarizers can for example be provided to allow the bezel to be positioned in the correct angular position relative to the caseband during assembly.

In the illustrated embodiment, the assembly member is in one piece and is held elastically in the groove. As a variant, the assembly member could be held in the groove by any appropriate means or even be formed of several elastic assembly zones that are not connected and held independently of each other in the groove. Similarly, the groove could not be continuous but formed of one or more independent groove portions each intended to house an elastic assembly zone.

In the illustrated embodiment, the second inclined flanks of the shoulder of the bezel and of the elastic zones of the assembly member are arranged to allow the bezel to be held and removed from the caseband. As a variant, the shoulder and the elastic zones could comprise only a first inclined flank each intended for assembly, while the second inclined flanks are arranged to allow only the maintenance of the bezel on the middle part, that is that is to say that they are arranged to cooperate with each other to retain the bezel in its assembled position on the middle part but without the possibility of disassembling said bezel by exerting a force opposite to the assembly force.

It is obvious that the groove in which the assembly member is housed could have been on the bezel and the shoulder on the caseband.

The assembly device according to the invention can also be applied to the mounting of a rotating bezel on the middle part or even to the mounting of the movement in the back of the case or to the mounting of the back on the middle part or to the mounting of the dial or replace other uses of a detent adjuster such as barrel cover adjustment.

In general, the device for assembling two timepiece components according to the invention comprises a first timepiece component and a second timepiece component intended to be assembled together by means of at least an assembly device. The assembly member is retained in a housing of the second component and is arranged to cooperate with at least one assembly portion provided on the first component for the assembly of the first component on the second component.

The assembly member comprises at least one elastic zone intended to cooperate with the assembly portion of the first component and arranged to be deformable between a rest position and a position of maximum deformation.

In the disassembled position of the first and second components, the elastic zone is in its rest position in which when the first component is brought into contact with the second component, said elastic zone comes into abutment against the assembly portion of the first component. In this disassembled position, by exerting a first force on the first component when the assembly portion of said first component is in contact with the elastic zone, the assembly portion then cooperates with the elastic zone to deform the latter from its position at rest in its position of maximum deformation. In this position of maximum deformation, the elastic zone no longer blocks the first component which, under the action of the first force, can return to its assembled position on the second component. Once in this assembled position, the elastic zone of the second component resumes its rest position or an intermediate position between said rest position and the position of maximum deformation and cooperates with the assembly portion of the first component to retain the latter in its assembled position on the second component.

According to the invention, the assembly member is a part attached to the second component. This makes it possible to choose the most appropriate material for the assembly member and its elastic zone, almost independently of the materials of the first and second components, which may have properties that are not compatible with elastic deformation.

Preferably, the elastic zone of the assembly member and the assembly portion of the first component are also shaped to allow disassembly of the first and second components. That is to say that once the first component is in its assembled position on the second component, by exerting a second force on the first component opposite to the first, the assembly portion then cooperates with the elastic zone to deform the latter from its rest position to its position of maximum deformation. In this position of maximum deformation, the elastic zone no longer blocks the first component which, under the action of the second force, can be disassembled from the second component. Once in this disassembled position, the elastic zone of the second component returns to its rest position.

Preferably, the elastic zone of the assembly member and the corresponding assembly portion of the first component each comprise first inclined flanks, intended to cooperate with each other so that, in the disassembled position, in exerting a first force on the first component to bring the assembly portion of said first component into contact with the elastic zone, the first inclined flank of the assembly portion then cooperates with the first inclined flank of the elastic zone to deform the latter ci from its rest position to its position of maximum deformation.

As a variant, the elastic zone of the assembly member and the corresponding assembly portion of the first component each comprise second inclined flanks, of opposite inclination to the first inclined flanks intended to cooperate with each other so that, once the first component is in its assembled position on the second component, by exerting a second force on the first component opposite to the first, the second inclined flank of the assembly portion then cooperates with the second inclined flank of the zone elastic to deform it from its rest position into its position of maximum deformation.

Preferably, the second inclined flanks of the assembly portion of the first component and of the elastic zone of the assembly member are arranged to be parallel once the first component is in its assembled position on the second component so reducing the axial play between said first and second components.

Preferably, the assembly member is arranged to be held elastically in the housing of the second component.

As a variant, the assembly member could only comprise a single elastic zone. The device then comprises means for embedding on the first component and the second component shaped to produce a rigid assembly of the first component on the second.

Preferably, the assembly member comprises at least three or five elastic zones intended to cooperate with one or more corresponding assembly portions of the first component.

Preferably, the first component is a bezel, rotating or not, while the second component is a middle part of a watch case. The housing on the middle part is a groove which extends over part or all of the inner periphery of the middle part, the corresponding assembly portion of the bezel also extending over all or part of the circumference of the bezel. Preferably, the assembly member is open to allow passage through the caseband of a control member.

Claims (14)

Device for assembling two timepiece components comprising a first timepiece component (1) and a second timepiece component (2) intended to be assembled together by means of at least one assembly member (3), the assembly member (3) being retained on the second component (2) and being arranged to cooperate with at least one assembly portion (12) provided on the first component (1) for the assembly of the first component ( 1) on the second component (2), the assembly member (3) comprising at least one elastic zone (31) intended to cooperate with the assembly portion (12) of the first component (1) and arranged to be deformable between a rest position and a position of maximum deformation;
the assembly portion (12) of the first component (1) and the elastic zone (31) of the second component (2) being arranged so that: • In the disassembled position of the first and second components (1, 2), the elastic zone (31) is in its rest position in which by bringing the first component (1) into contact with the second component (2), said elastic zone ( 31) abuts against the assembly portion (12) of the first component (1); and • In the disassembled position, by exerting a first force on the first component (1) when the assembly portion (12) of said first component (1) is in contact with the elastic zone (31) in the rest position, the portion of assembly (12) then cooperates with the elastic zone (31) to deform the latter from its rest position into its position of maximum deformation; • In its position of maximum deformation, the elastic zone (31) no longer blocks the first component (1) which, under the action of the first force, can return to its assembled position on the second component (2); and so that • once in the assembled position, the elastic zone (31) of the assembly member (3) resumes its rest position or an intermediate position between said rest position and the position of maximum deformation and cooperates with the portion of assembly (12) of the first component (1) to retain the latter in its assembled position on the second component (2);
said device being characterized in that the assembly member (3) is a piece attached to the second component (2). Device for assembling two timepiece components according to claim 1, characterized in that the elastic zone (31) of the assembly member (3) and the assembly portion (12) of the first component (1) are also shaped so that, once the first component (1) is in its assembled position on the second component (2), by exerting a second force on the first component (1) opposite to the first, the assembly portion (12) cooperates with the elastic zone (31) to deform the latter from its rest position into its position of maximum deformation, and that in this position of maximum deformation, the elastic zone (31) no longer blocks the first component (1) which under the action of the second force, can be disassembled from the second component (2). Device for assembling two timepiece components according to one of the preceding claims, characterized in that the elastic zone (31) of the assembly member (3) and the assembly portion (12) corresponding part of the first component (1) each comprise first inclined flanks (13, 313), intended to cooperate with each other so that, in the disassembled position, by exerting a first force on the first component (1) to bring the assembly portion (12) of said first component (1) into contact with the elastic zone (31), the first inclined flank (13) of the assembly portion (12) then cooperates with the first inclined flank ( 313) of the elastic zone (31) to deform the latter from its rest position into its position of maximum deformation. Device for assembling two timepiece components according to Claim 3, characterized in that the elastic zone (31) of the assembly member (3) and the corresponding assembly portion (12) of the first component (1) each comprise second inclined flanks (14, 314), of opposite inclination to the first inclined flanks intended to cooperate with each other so that, once the first component (1) in its assembled position on the second component (2), by exerting a second force on the first component (1) opposite to the first, the second inclined flank (14) of the assembly portion (12) then cooperates with the second inclined flank (314) of the zone elastic (31) to deform the latter from its rest position into its position of maximum deformation. Device for assembling two timepiece components according to Claim 4, characterized in that the second inclined flanks (14, 314) of the assembly portion (12) of the first component (1) and of the elastic zone (31) of the assembly member (3) are arranged to be parallel once the first component (1) is in its assembled position on the second component (2) so as to reduce play axial between said first and second components (1, 2) in their assembled position. Device for assembling two timepiece components according to one of the preceding claims, characterized in that the assembly member (3) comprises an elastic zone (31); and in that the device further comprises embedding means distributed over the first component (1) and the second component (2) and shaped to produce a rigid assembly of the first component on the second. Device for assembling two timepiece components according to one of the preceding claims, characterized in that the assembly member (3) comprises at least three and preferably five elastic zones (31) intended to cooperate with one or more corresponding assembly portions (12) of the first component (1). Device for assembling two timepiece components according to one of the preceding claims, characterized in that the assembly member (3) is arranged to be held elastically in a housing (22) of the second component (2). Device for assembling two timepiece components according to one of the preceding claims, characterized in that the assembly member (3) is in one piece. Device for assembling two timepiece components according to one of the preceding claims, characterized in that the assembly member (3) comprises at least two elastic zones interconnected by at least one elastic blade (32) arranged to allow the elastic retention of the assembly member in a housing (22) of the second component (2). Device for assembling two watch components according to one of the preceding claims, characterized in that the first component is a bezel (1) while the second component is a middle part (2) of a watch case; and in that the assembly member is housed in a groove (22) of the middle part (2) which extends over part or all of the inner periphery (21) of the middle part (2), the corresponding assembly portion (12) of the bezel also extending over all or part of the circumference of the bezel. Device for assembling two timepiece components according to the preceding claim, characterized in that the assembly member (3) is of quasi-circular shape and open to allow the passage of a control member (5) through the build. Watch case comprising an assembly device according to one of the preceding claims. Timepiece comprising a watch case according to claim 13 or an assembly device according to one of claims 1 to 12.

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