The invention concerns a first mechanical timepiece sub-assembly.
The invention concerns a second mechanical timepiece sub-assembly.
The invention concerns a third mechanical timepiece sub-assembly.
The invention also concerns a fourth mechanical timepiece sub-assembly.
The invention also concerns a fifth mechanical timepiece sub-assembly.
The invention also concerns a sixth mechanical timepiece sub-assembly.
The invention also concerns a seventh mechanical timepiece sub-assembly.
The invention also concerns an eighth mechanical timepiece sub-assembly.
The invention also concerns a mechanical timepiece movement including at least one mechanical timepiece sub-assembly of this type.
The invention also concerns a timepiece or watch including at least one mechanical movement of this type.
The invention also concerns a method of assembling mechanical sub-assemblies of this type.
The invention concerns the field of mechanical horology and more specifically the field of watches.
Modular timepieces are known. Although very widely known in electronic horology, they are less frequent in mechanical horology, where modular construction, generally devised to break down the same basic mechanical movement into several calibres with different functions or having a different appearance, is usually more expensive than the traditional method of manufacture. Only a few additional mechanisms, made on additional plates, are relatively widespread.
Modular construction conventionally imposes the constraint of machining high precision interfaces, because of the accumulation of assembly clearances between modules, which require very tight tolerances for each module, to ensure a satisfactory result for the entire unit.
Modular manufacture is also very often detrimental to the total thickness of the mechanical movement, and it is difficult to make ultra flat or even simply flat mechanical movements.
However, modular construction remains an interesting objective for timepiece manufacturers, since it allows assembling tasks to be split. In return for the tighter manufacturing tolerances required by the accumulation of clearances between modules, the final assembly operation can be carried out by less skilled personnel because it is less complicated. However, the final assembly operation still requires the knowledge and sensitivity of a watchmaker.
EP Patent Application No. 1 079 284 in the name of ETA discloses a watch with two main modules each of which contains half of the components.
EP Patent Application No. 0 862 098 in the name of VOSS discloses a modular watch with a timing mechanism forming an entire module.
EP Patent Application No 1 211 578 in the name of ETA discloses an ultra thin electromechanical movement with stacked modules, implementing tubular elements compensating for the variations in thickness of the assembly elements.
The invention proposes to overcome certain prior art problems by proposing a modular unit which can be assembled without using an operator, while ensuring the exactitude of the working parameters with tried and tested adjustments, and with a lower production cost than that of a traditional method of manufacture.
To this end, the invention concerns a first mechanical timepiece sub-assembly, characterized in that it includes at least one main plate on which is irreversibly fixed a gear train module which is irreversibly pre-adjusted by the irreversible securing of adjustment and/or assembly components, said gear train module including an input wheel set formed by an input pinion, arranged to cooperate with a drum of a motor module, and including a first output wheel set formed by a plate arranged to cooperate with an escapement pinion of an escapement mechanism or of a regulating module, said gear train module further including a second output wheel set formed by a display train cooperating with a display module which is irreversibly pre-adjusted by the irreversible securing of adjustment and/or assembly components, said display module is irreversibly fixed to said main plate and includes an output wheel set formed by at least one indicator arranged to cooperate with a complementary indicator or with a dial, said main plate including a bearing surface for receiving a time-setting module which is irreversibly pre-adjusted by the irreversible securing of adjustment and/or assembly components and including at least one pivot for cooperating with said time-setting module, which is irreversibly fixed to said main plate.
The invention also concerns a second mechanical timepiece sub-assembly, characterized in that it includes, irreversibly fixed to said first mechanical sub-assembly, at least one motor module which is irreversibly pre-adjusted by the irreversible securing of adjustment and/or assembly components, and which is a complete barrel including at least one barrel whose input wheel set is formed by a barrel arbor cooperating with a ratchet comprised in said second mechanical sub-assembly and which is arranged to be pivotally driven, either by said winding and time-setting mechanism or by a self-winding module, to wind at least one spring, in at least one drum forming the output wheel set of said motor module and which drives said input pinion of said gear train module.
The invention also concerns a third mechanical timepiece sub-assembly, characterized in that it includes, irreversibly fixed to said second mechanical sub-assembly, at least one frame-mounted self-winding device module including a barrel drive wheel guided, on the one hand, in a guide member of said first mechanical sub-assembly in proximity to said drum, and on the other hand, in a jewel comprised in a flange centred on two studs comprised in said frame-mounted self-winding device module.
The invention further concerns a fourth mechanical timepiece assembly, characterized in that it includes, irreversibly fixed to said third mechanical sub-assembly, a motion work train including a centre seconds arbor, a small seconds arbor and a pinion mounted on the side of said main plate opposite to the side where said gear train module is assembled, an intermediate wheel carried by a stud driven into said main plate, a cannon-pinion, and a minute wheel carried by a stud driven into said main plate, and an hour wheel.
The invention also concerns a fifth mechanical timepiece sub-assembly, characterized in that it includes, fixed to said fifth mechanical sub-assembly on said motion work train side, a holding plate or a dial, and hands.
The invention also concerns a sixth mechanical timepiece assembly, characterized in that it includes, irreversibly fixed to said fourth mechanical sub-assembly, or to the fifth mechanical sub-assembly, at least one date module including a date drive wheel, an intermediate date wheel pivoting on a stud driven into said main plate, a date corrector wheel meshing with a date control train comprised in said mechanical module comprising a stem, a date indicator bearing on a surface of said main plate, and a holding plate for the date indicator, which is centred by pins driven into said main plate.
The invention further includes a seventh mechanical timepiece sub-assembly, characterized in that it includes, irreversibly secured to said third mechanical sub-assembly, or to said fourth mechanical sub-assembly, or to the fifth mechanical sub-assembly, or to said sixth mechanical sub-assembly, at least a self-winding module including an oscillating weight whose guide member cooperates with a complementary guide member comprised in said bridge of said frame-mounted self-winding device module, and which is held in place by a fixing screw.
The invention further concerns an eighth mechanical timepiece sub-assembly, characterized in that it forms an autonomous mechanical timepiece movement, and includes, irreversibly secured to said third mechanical sub-assembly, or to said fourth mechanical sub-assembly, or to the fifth mechanical sub-assembly, or to said sixth mechanical sub-assembly, an escapement holder regulating module, which is a functional module for performing a particular timepiece function, irreversibly pre-adjusted by the irreversible securing of adjustment and/or assembly components comprised in said functional module after said particular timepiece function has been adjusted and function checked on the test bench, and said escapement holder regulating module includes a regulating assembly, whose input wheel set is formed by an escape wheel arranged to be moved by a small seconds wheel comprised in said gear train module, and whose output wheel set is formed by said same escape wheel, said escapement holder regulating assembly including a sprung balance assembly, an escapement, and a particular pallet lever.
The invention further concerns a mechanical timepiece movement including at least one mechanical timepiece sub-assembly of this type, characterized in that each functional module, comprised in said mechanical movement for performing a particular timepiece function, is irreversibly pre-adjusted by the irreversible securing of adjustment and/or assembly components comprised in said functional module after said particular timepiece function has been adjusted and function checked on the test bench.
The invention also concerns a timepiece or watch including at least one mechanical movement of this type.
The invention further includes a method of assembling these mechanical sub-assemblies, characterized in that said first mechanical sub-assembly is assembled by irreversibly securing said main plate and said irreversibly pre-adjusted modules comprised therein, and in that each higher order mechanical sub-assembly is assembled on the lower order mechanical sub-assembly by irreversibly securing said lower order mechanical sub-assembly and said irreversibly pre-adjusted modules comprised in said higher order mechanical sub-assembly.
Other features and advantages of the invention will appear upon reading the following detailed description, with reference to the annexed drawings, in which:
The invention concerns the field of mechanical horology and more specifically the field of watches.
The invention concerns a mechanical timepiece movement 100 in the form of a modular unit.
According to the invention, this mechanical movement 100 includes at least one functional module 1 for performing a particular timepiece function which is irreversibly pre-adjusted by the irreversible securing of adjustment and/or assembly components comprised in said functional module 1 after this particular timepiece function has been adjusted and function checked on the test bench.
This at least one pre-adjusted functional module 1 is irreversibly secured, either to a main plate 10 of mechanical movement 100 or of another pre-adjusted functional module 1 of mechanical movement 100, or it is irreversibly secured to another pre-adjusted functional module 1 of mechanical movement 100.
In a preferred embodiment of the invention, seen in the Figures, this mechanical timepiece movement 100 includes a plurality of these functional modules 1, each pre-adjusted to perform a particular timepiece function. These functional modules 1 are each mounted, or irreversibly secured, directly or indirectly relative to main plate 10, or sandwiched between functional modules 1 and/or components of mechanical movement 100, which are in turn irreversibly fixed, directly or indirectly with respect to main plate 10. Naturally, a functional module 1 can be sandwiched between main plate 10 and at least one other component or at least one other functional module 1.
Each functional module 1 is a mechanical module formed from a mechanical sub-assembly comprising all the components required to perform a particular timepiece function of transforming a mechanical movement between at least one input wheel set and at least one output wheel set.
This mechanical sub-assembly includes adjustment and/or assembly components which are irreversibly fixed after the particular timepiece function peculiar to the functional module concerned has been adjusted and function checked. The individual sub-assembly is adjusted and function checked on the test bench. The actual functional module 1 is thus a pre-adjusted module obtained from the transformation of a mechanical sub-assembly of this type, by irreversibly securing its adjustment and/or assembly components.
Preferably, each functional module 1 includes at least a first bearing surface, and a locating means for recognising and positioning module 1 relative to another element of mechanical movement 100, or relative to main plate 10. This positioning is achieved by the first bearing surface bearing on a complementary bearing surface comprised in said other element or plate 10. The notion of a “bearing surface” is understood in the broadest sense. A “bearing surface” may equally well be formed by a bore or arbor, or a flat surface or other element.
The locating means may be devised to locate with or without contact, and may take several forms, which may be combined with each other:
The invention is more specifically devised for the automated manufacture of mechanical movement 100 and endeavours to allow various modules and components to be set in place in a parallel direction to a single direction of insertion D, selected here to be parallel to the gear train axes, with the fewest possible turning-over movements or other movements apart from movements of translation.
In a preferred embodiment, the first bearing surface of each functional module 1 is flat and presented perpendicularly to this direction of insertion D.
Preferably, functional module 1 includes at least a second bearing surface parallel to the first bearing surface. This arrangement facilitates automated assembly by paraxial positioning relative to direction of insertion D, with certain components or modules stacked with their bearing surfaces perpendicular to the direction of insertion D in contact with each other?.
To ensure some of the cooperation between assembly components, particularly the gearing between toothed wheels, or between wheels and racks, ratchets or suchlike, or to set in place cams, jumper springs, clicks, fingers, pushers or suchlike, functional module 1 may also advantageously include at least one pivot guide member, for pre-assembling the module while allowing it a degree of freedom to pivot. It is therefore possible to ensure this cooperation in a final pivoting movement of module 1. In a preferred but non-limiting embodiment, this pivotal guiding is performed relative to a parallel direction to said direction of insertion D. This is the case of regulating module 16 in the mechanical movement set out in detail below.
In a variant, module 1 includes a guide means arranged to cooperate with a complementary guide means comprised in another module 1, or a component of mechanical movement 100 or plate 10, to achieve a similar cooperation by translation, or a parallel adjustment, in one plane, in the manner of a slide or a drawer. Preferably, these guide means are made in a perpendicular direction to direction of insertion D.
The Figures illustrate a mechanical movement 100, whose composition comprises functional modules 1 of this type and isolated components which combine to form functional mechanical sub-assemblies. The reduction in the number of objects to be handled during assembly of the movement, and especially the reduction or absence of any adjustment operations, are made possible by the concept of pre-adjusted functional units. It will be noted that, although some components are mounted individually here, this is essentially for the purpose of reducing or limiting the thickness of the mechanical movement, since it is also possible to secure these components, which participate in the same kinematic chain of one functional sub-assembly, to an additional plate, but this would then have a detrimental effect on the total thickness of the mechanical movement.
The mechanical movement described below requires only 21 objects to be handled in the basic version (a mechanical movement with no mechanically wound date mechanism), namely 5 pre-adjusted modules and 16 individual or pre-assembled components (for example arbors and wheels). All the mechanical assembly motions are translational motions parallel to each other, and only one pivoting motion is required for the gearing of a regulating module. Assembling the date mechanism requires 5 additional components to be set in place, whereas assembling the self-winding mechanism requires only 2 components to be set in place, i.e. a module and a screw.
The gearing cooperation can be achieved either with complementary guide tools, or by pivoting the head of the manipulator system.
In a preferred implementation, the assembly is carried out a by a robot controlled by a control means which cooperates with a shape recognition means, particularly a mechanical and/or optical means, which identifies the shape and position of locating means belonging to modules 1 and/or the retail components.
There are six functional modules used here.
A first type of functional module 10 is a motor module 11 and it is a complete barrel which comprises at least one barrel 110, whose input wheel set is formed by a barrel arbor 111, which cooperates with a ratchet 12, which may or may not be incorporated in said motor module 11, and which is arranged to be pivoted, either by a manual winding mechanism or by a winding and time-setting mechanism 15, or by a self-winding mechanism or by a self-winding module 18, to wind at least one spring (not shown in the Figures) in at least one drum 113 forming the output wheel set of said motor module 11. This drum 113 is arranged for driving an input pinion 131 of a gear train or a gear train module 13.
Another type of functional module 1 is a gear train module 13, the input wheel set of which is formed by an input pinion 131, arranged to cooperate with a drum 113, and a first output wheel set of which is formed by a fourth wheel arranged to cooperate with an escape pinion connected to an escape wheel comprised in an escape mechanism or a regulating module 16.
Advantageously, this gear train module 13 includes a second output wheel set which is formed by a display train arranged to cooperate, either with display means comprised in the gear train module 13, or with a display module 14 external to gear train module 13, or carried by the same plate, and comprising display means.
This display module 14 has an input wheel set formed by a display train comprised in a gear train mechanism or gear train module 13 and an output wheel set formed by at least one indicator arranged to cooperate with a complementary indicator or with a dial comprised either in display module 14 or mechanical movement 100 or a timepiece 1000 incorporating said movement.
Advantageously, this gear train module 13 or display module 14 includes a motion work mechanism, which is friction connected to the gear train disclosed in EP Patent Application No. 11177840 by the same Applicant, and includes a fourth wheel set pre-assembled on a centre tube, which is the subject of EP Patent Application No. 11177839 by the same Applicant.
Yet another type of functional module 1 is a time-setting module 15, the input wheel set of which is formed by a stem 150 arranged to be moved by a user, and a first input wheel set of which is formed by a motion work control train 151.
Preferably, this time-setting module 15 is also a time-setting and winding module, and includes a second output wheel set which is formed by a winding control train 152.
Advantageously, this module 15 is made with a winding stem mechanism according to EP Patent Application No. 11170180 by the same Applicant. It may also integrate a device for manual winding via pressure on the stem according to EP Patent Application No. 11177838 by the same Applicant.
Yet another type of functional module 1 is a regulating module 16 comprising a regulating unit, and the input wheel set thereof is formed by an escape wheel arranged to be moved by a fourth wheel comprised in a gear train or gear train module 13, and the output wheel set of which is formed by said same escape wheel.
This platform escapement regulating module 16 is advantageously made in accordance with the characteristics of EP Patent Application Nos. 11005713 and 11179181 by the same Applicant, and includes a sprung balance assembly, an escapement and a particular pallet lever.
A particular functional module 1 is a self-winding module 18, the input wheel set of which is formed by an oscillating weight 180 moved by the motions of a user or an external tool, and the output wheel set of which is formed by a drive train of a ratchet 12 comprised either in a motor mechanism, or a motor module 11, or a ratchet 12 which cooperates with a barrel comprised either in a motor mechanism or a motor module 11.
This oscillating weight 180 is advantageously made in accordance with the characteristics of EP Patent Application No. 11188261 by the same Applicant.
According to the invention, all the modules and components which form mechanical movement 100 can be inserted in a parallel direction to a direction of insertion D, which is parallel to the axes of the gear train here.
In a preferred and non-limiting embodiment of the invention, each mechanical sub-assembly formed of an assembly of plates, bars and pre-adjusted functional modules 1 according to the invention, is irreversibly fixed as soon as each additional one-piece module is set in place.
In this embodiment, this same plate 10 carries a display module 14 as described above.
Plate 10 has a bearing surface 135 for receiving a time-setting module 15 and a pivot 134 for cooperating with said module.
Two shouldered studs 201 and 138 are mounted to cooperate with a frame mounted self-winding device 20?
The gear train is not detailed here.
Counter-bores 130 are arranged around a centring bore 139, intended to receive a barrel arbor, to prevent a collision with a complete barrel, forming a motor module 11, during assembly.
Plate 10 further includes a bore 165 for receiving an arbor 162 of a regulating module 16.
Plate 10 further includes a bore 192 for the assembly (illustrated in
In proximity to said small seconds wheel 190, a guide member 205 is provided for receiving a barrel drive wheel 204, the assembly of which is shown in
In proximity to drum 113, a guide member 194 is provided for receiving a barrel drive wheel 193, the assembly of which is seen in
This bar 200 may be directly welded to plate 10 thereby sandwiching the already assembled components, or welded at the ends of studs 201 and 138 or suchlike.
A sliding gear return spring 203 is then mounted in abutment on raised portions of bar 200, as seen in
Two centring studs 218 and 217 position a flange 215, which includes jewels 213 and 214 for guiding the intermediate barrel drive wheel 204 and barrel drive wheel 193, and a top oblong hole 218 for guiding sliding gear 206.
At this stage, the mechanical sub-assembly thereby formed is ready to receive a regulating module 16, preferably carrying the sprung balance and the escapement, as explained above.
This regulating module 16 includes a stud 162 arranged to cooperate with bore 165 of the plate. It is easy to pre-position regulating module 16 by inserting it in the direction of insertion D, in abutment on plate 10 via a bottom bearing surface 101, in an angular orientation wherein the module projects outside plate 10. A pivoting motion in direction A allows said module to cooperate with the rest of the mechanical movement, as explained in EP Patent Application No. 11005713 by the same Applicant, in the position illustrated in
At this stage, the mechanical manual winding movement can function, and the assembled unit can be handled in any position without the loss or movement of any components.
An optional self-winding module 18 can be mounted at this stage, or later in the assembly sequence. However, since the mechanical sub-assembly has to be turned over for the final assembly of the motion work, it is preferable to postpone the assembly of oscillating weight 180 for as long as possible in the assembly sequence, since otherwise it would have to be held during manipulations.
Thus,
The stem mechanism module 15 controls the minute control train 151, which meshes with the motion work.
The centre seconds arbor 1300 is at the centre of mechanical movement 100 here. The small seconds arbor 191 and centre wheel arbor 131 are visible. They are preferably all pre-mounted at the stage of display module 14 which is formed on the back of main plate 10, while gear train module 13 is essentially mounted on the front side of said plate 10. The unit forms a single basic structural module here, but could also be split into two independent modules.
In
The cannon-pinion 105 is assembled in
At this stage, movement 100 can be closed, on the motion work side, by a holding plate or dial, not shown in the Figures, and the mechanical movement is completely operational as soon as the hands have been mounted.
In a non-limiting variant illustrated in
A guide member 181 for oscillating weight 180 cooperates with a guide member 220 comprised in frame-mounted self-winding device 20. Finally, a fixing screw 182 is set in place in
Self-winding mechanical movement 100 is then completely assembled and ready to operate.
The invention also concerns a timepiece 1000 including at least one such mechanical movement 100.
The invention has the advantage of combining, within one mechanical movement which forms a modular unit of this type, functional modules, which have each been pre-adjusted and pre-tested, and which do not require any subsequent adjustment during the final assembly of the mechanical movement.
Number | Date | Country | Kind |
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11193174 | Dec 2011 | EP | regional |
This application is a continuation of U.S. application Ser. No. 13/710,737 filed Dec. 11, 2012, which claims the benefit of priority from European Patent Application No. 11193174.7, filed Dec. 13, 2011; the entire contents of each of which are incorporated herein by reference.
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Number | Date | Country | |
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20140328145 A1 | Nov 2014 | US |
Number | Date | Country | |
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Parent | 13710737 | Dec 2012 | US |
Child | 14333138 | US |