This application claims priority to European Patent Application No. 19217598.2 filed Dec. 18, 2019, the entire contents of which are incorporated herein by reference.
The invention relates to a method for manufacturing at least two mechanical parts intended to be arranged in a timepiece mechanism comprising magnetised functional areas having antagonistic polarities.
The invention also relates to a timepiece mechanism comprising at least two mechanical parts obtained according to such a manufacturing method. These mechanical parts are, for example, micromechanical and/or timepiece parts, typically a wheel, a plate, an anchor lever, a balance or else an axis.
In the field of timepiece mechanisms such as mechanical movements implementing mechanical parts in frictional contact and in relative displacement, it is known that such parts, obviously with the exception of the balance, are in a stop position the majority of the time, about 95% of the time. In this context, when these parts are stressed during the operation of this movement, the energy mobilised to displace these parts must be sufficient to overcome a particular type of friction called static friction.
Such a static friction results from adhesion forces established between the parts of this movement, in particular at their contact surface, when they are stopped. These adhesion forces can come, for example, from intermolecular forces such as the forces called Van der Waals forces (London, Keesom and Debye) which are essentially electrostatic in nature and result in particular from the establishment of hydrogen bonds of a partially covalent nature between the antagonistic contact surfaces of these parts. These adhesion forces can also come from intramolecular forces, of greater intensity than that of intermolecular forces, which can moreover lead to degradation of the surfaces of these parts. Such intramolecular forces can result from chemical elements which have been adsorbed by the antagonistic contact surfaces and which are then at the origin of the establishment of covalent bonds between these contact surfaces under the effect of pressure or due to the presence of a catalyst.
It will be noted that on a more macroscopic scale, the adhesions between these antagonistic contact surfaces are generally seen as capillary effects (for example adsorbed water or presence of lubricant in the contact) or as adhesion effects (for example micro-welds of asperities under the effect of pressure).
Under these conditions, it is understood that there is a need to find a solution which allows to limit or even eliminate such static friction in order to improve the operation of such mechanisms.
The invention therefore has the purpose of providing a method for manufacturing at least two mechanical parts intended to be arranged in a timepiece mechanism and capable of cooperating with each other in relative displacement and which have the particularity of avoiding the establishment of a bond/adhesion between their antagonistic contact surface when they are stopped.
To this end, the invention relates to a method for manufacturing at least two mechanical parts intended to be arranged in a timepiece mechanism comprising magnetised functional areas having antagonistic polarities, said parts being intended to be arranged in a mechanism, in particular a timepiece mechanism to cooperate with each other in relative displacement, the method comprising a step of constructing a blank of each of the two parts including at least one functional area from which said parts are able to cooperate with each other and a step of obtaining each of the parts including a sub-step of transforming said at least one functional area of the blank of each of these parts into a magnetised functional area from which emanates a magnetic field at least one feature of which is configured so that this magnetic field participates in achieving a separation of the magnetised functional areas of the two parts when they are in a stop position in the mechanism.
Thanks to such features, this method allows mechanical parts to be obtained intended to cooperate with each other in relative displacement and the antagonistic contact surfaces of which are separated when they are stopped, thus participating in reducing the energy consumption necessary to resume their displacement/movement. In this context, such parts then participate in increasing the overall efficiency of a timepiece mechanism such as a movement.
In other embodiments:
The invention also relates to a timepiece mechanism comprising at least two mechanical parts intended to cooperate with each other and able to be obtained by this method.
Advantageously, said mechanical parts comprise magnetised functional areas having antagonistic polarities.
In particular, the magnetised functional area of each of these parts is capable of generating a magnetic field the intensity of which is configured to ensure a separation of the magnetised functional areas of the two parts when these two parts are stopped in the mechanism.
The purposes, advantages and features of the method for manufacturing a mechanical part according to the invention will become more apparent in the following description on the basis of at least one non-limiting embodiment illustrated by the drawings wherein:
Such a method comprises a step 10 of constructing a blank of each of these two parts 1a, 1b, this blank including at least one functional area 2a, 2b from which said parts are able to cooperate with each other. In other words, the first part 1a comprises the functional area 2a provided with the contact surface 3a which is able, during a relative displacement, to cooperate with the contact surface 3b of the functional area 2b of the second mechanical part 1b. This step 10 of the method comprises a sub-step 11 of building a body of said blank of each part 1a, 1b. Such a sub-step 11 can for example provide for the implementation of an etching process of layers/substrates based, for example, on a material such as silicon in a manner similar to the process implemented in document WO9815504A1. This sub-step 11 can also alternatively provide for the production of this blank body for these two parts according to a process for manufacturing this blank body from a reinforced silicon according to the technology described in document CH701499A2. In another alternative, this sub-step 11 can also provide for the implementation of a three-dimensional printing technology for the production of this blank body, such as for example that described in document WO2019106407A1. This blank body of each part 1a, 1b is preferably made of a non-magnetic material and/or has a low or even zero magnetic permeability index. This material can be in a non-limiting and non-exhaustive manner:
Such a blank body relating to each mechanical part 1a, 1b has the shape as well as all the other features of the mechanical part 1a, 1b which will be obtained with the exception of the arrangements/modifications provided for this blank body for transforming said at least one functional area 2a, 2b into a magnetised functional area 2a, 2b. Thus in this context, the method therefore comprises a step 12 of obtaining each of these two mechanical parts 1a, 1b including a sub-step 13 of transforming said at least one functional area of the blank of each of these mechanical parts 1a, 1b into a magnetised functional area from which emanates a magnetic field at least one feature of which is configured so that this magnetic field participates in achieving a separation between the magnetised functional area 2a of the first part 1a and the magnetised functional area 2b of the first part 1b of the two parts when these two parts 1a, 1b assembled in the mechanism, are stopped, that is to say that they no longer cooperate with each other in relative displacement/movement. It is therefore understood that the functional areas 2a, 2b of these parts are specifically defined to participate in ensuring a controlled repulsion of these two mechanical parts 1a, 1b when they are in a stop position in the mechanism, so as to ensure separation between the contact surface 3a of the first part 1a and the contact surface 3b of the second part 1b.
For this purpose, this sub-step 13 comprises a phase 14 of determining parameters of the magnetic field required for achieving said separation and which is able to be generated by said at least one functional area 2a, 2b of each part 1a, 1b, from the estimation of at least one feature relating to this magnetic field depending on separation criteria of said at least two parts 1a, 1b. Such a phase 14 aims at defining the feature(s) of the magnetic field of the functional area 2a, 2b of each of the parts 1a, 1b which is required for the specific performance of a function aiming at ensuring the separation of the respective contact surfaces 3a, 3b of the functional areas 2a, 2b of the two mechanical parts 1a, 1b when the latter are assembled in the mechanism and stopped.
The features of this magnetic field relate for example to the intensity of the magnetic field and the distribution of this intensity relative to the functional area 2a, 2b, in particular relative to the contact surface 3a, 3b. Such an intensity and its distribution are determined for each of the two parts 1a, 1b in particular depending on the separation criteria of the two parts 1a, 1b comprising in a non-limiting and non-exhaustive manner the following information:
Once the configuration phase 14 has been carried out, the transformation sub-step 13 comprises a phase 15 of producing at least one channel 5 in a portion of the blank body of each part 1a, 1b, this portion being located in said at least one functional area 2a, 2b below the functional contact surface 3a, 3b comprised in said at least one functional area 2a, 2b. Such a phase 15 comprises a sub-phase 16 for determining the specificities of said at least one channel 5 to be constructed in said at least one functional area 2a, 2b depending on the determined required parameters of the magnetic field estimated during the preceding phase 14. These specificities of said at least one channel comprise the shape, the value of one section or several sections of this channel 5 if it comprises different sections, the extent of this channel 5 in the functional area relative to the contact surface 3a, 3b in particular the direction and/or sense wherein the channel extends in the area relative to the contact surface 3a, 3b, the location of this channel 5 relative to the contact surface 3a, 3b, and/or the location of each portion constituting this channel 5 relative to this contact surface. It will be noted that the definition of the extent and the location of all or part of this channel relative to the contact surface 3a, 3b means that this extent and this location depend on the distance present between this contact surface 3a, 3b and the channel 5 and/or depend on the length and/or width and/or the extent of this contact surface 3a, 3b of the functional area 2a, 2b
It will be noted that the channel 5 which is made for each part 1a, 1b in the thickness e of a portion of this blank body where the functional area 2a, 2b is located, and preferably has a small dimension. By way of example, the section of such a channel 5 has a surface area less than 25,000 μm2, preferably less than 10,000 μm2.
This phase 14 can provide for the formation of such a channel 5 from a femtosecond pulse laser, according to a technology described in document WO2019106407A1. This channel 5 is defined in the thickness e of the blank body of each part below the contact surface 3a, 3b of the functional area 2a, 2b.
Such a channel 5 comprises an opening 8 which is defined in the lateral face of the blank body comprised in the functional area 2a, 2b or in the internal surface 4a, 4b of this functional area 2a, 2b, this opening 8 connects an enclosure of this channel 5 to the external environment of the blank body. This lateral face interconnects the internal 4a, 4b and contact 3a, 3b surfaces of the functional area 2a, 2b. In the present embodiment, where the mechanical parts 1a, 1b illustrated in
This transformation sub-step 13 then comprises a phase 17 of arranging in the enclosure of said at least one channel 5 an amount of material developing a magnetic field depending on the determined parameters of the magnetic field required during the preceding phase 14. During this phase 17, it is therefore understood that the amount of material arranged in this enclosure of the channel depends on the parameters of the magnetic field determined during phase 14. Such a material developing a magnetic field can comprise magnetic particles 7 comprised in a fluid 6 such as a polymer, such as for example Samarium-Cobalt or Neodymium-Iron-Boron or else ferromagnetic particles. This fluid 6 comprising these magnetic particles 7 is typically photosetting, thermosetting or else chemically setting. In other words, this fluid 6 can be a photosetting or thermosetting polymer, such as for example a crosslinkable epoxy resin. It will be noted that when the fluid 6 is chemically setting, then it comprises two components, a polymer such as epoxy resin and a polymerising agent, for example 1,4,7,10-tetraazadecane, for curing. In contact with these two components, a solid material, for example polyepoxide, is formed. This chemical curing works according to a principle similar to that of two-component adhesive Araldite™.
This phase 17 comprises a sub-phase 18 of inserting this fluid 6 comprising magnetic particles 7 into said at least one channel 5. During this sub-phase 18, the fluid 6 comprising these magnetic particles 7 is introduced via the opening 8 of said at least one channel 5 into the enclosure of the latter. Subsequently, this phase 17 comprises a sub-phase 19 of magnetising the magnetic particles 7 comprised in this fluid 6 and a sub-phase 20 of defining an orientation of the antagonistic polarity of the magnetic particles 7 comprised in said fluid 6. These two magnetisation 19 and definition 20 sub-phases are carried out from a permanent magnet which is then arranged near the functional area 2a, 2b comprising said channel 5 wherein the fluid 6 is comprised. By way of example, in this configuration, the permanent magnet can be arranged opposite the contact surface 3a, 3b. Thus, from this permanent magnet for one of the two parts, these magnetic particles 7 are then magnetised so that their polarity is oriented in a well-defined sense which is antagonistic to the sense of polarity of the other part. Antagonistic, should be understood here that the senses of polarity of the two parts 1a, 1b are such that they allow a repulsion of the latter to be ensured and in particular a separation of the contact surface 3a, 3b from their said at least one functional area 2a, 2b provided with magnetic particles 7. Then, the phase 17 comprises a sub-phase 21 of curing said fluid 6 comprising magnetic particles 7 magnetised and provided with an oriented antagonistic polarity. This curing sub-phase 21 consists of polymerisation by photo-crosslinking, thermo-crosslinking and/or by chemical crosslinking when the fluid 6 is a crosslinkable polymer. In other words, the crosslinking is carried out thermally by passage through an oven, heating by laser or else via electromagnetic radiation provided that the material constituting the blank body wherein said at least one channel 5 has been produced is transparent to the considered wavelengths. It is also possible to consider a chemical crosslinking via the use of two components such as a two-component adhesive operating according to the principle of the two-component adhesive Araldite™. It is also possible, depending on the choice of the resin used, for a natural crosslinking to be sufficient in the case, for example, where this resin comprises a solvent. Indeed, a brief moment in the open air is sufficient for the solvent to evaporate and for the resin to cross-link “by itself”.
It will be noted that the magnetisation 19, definition 20 and curing 21 sub-phases are carried out simultaneously or substantially simultaneously.
In a variant of the method, the arrangement phase 17 may provide, as a replacement for the fluid 6 insertion 18, magnetisation 19, definition 20 and curing 21 sub-phases, the following phases:
During this insertion sub-phase 22, said at least one permanent magnet which is here a solid magnet, is arranged/placed/driven in the channel 5 so as to have a polarity oriented in a defined sense which is antagonistic, for one of the two parts, to the sense of polarity of the other part. During the mechanical holding sub-phase 23, said at least one permanent magnet is mechanically fastened to a wall of the enclosure of the channel 5 by gluing, welding, etc.
It will be noted that these two insertion 22 and mechanical holding 23 sub-phases can be carried out simultaneously as soon as this arrangement phase 17 is implemented by a three-dimensional printing process of said permanent magnet on the internal wall of the enclosure of the channel 5, for example using the technology known under the trademark Femtoprint™ described in document WO2019106407A1.
In another variant of the method, the transformation sub-step 13 can only comprise a phase 24 of applying a fluid comprising magnetic particles on the internal surface 4a, 4b of said at least one functional area 2a, 2b, arranged substantially opposite a functional contact surface 3a, 3b of this area 2a, 2b of each of the two parts 1a, 1b. This fluid is typically photosetting, thermosetting or else chemically setting. In other words, this fluid can be a photosetting or thermosetting polymer, such as for example a crosslinkable epoxy resin. It will be noted that when the fluid is chemically setting, then it comprises two components a polymer such as the epoxy resin and a polymerising agent, for example 1,4,7,10-tetraazadecane, for curing. In contact with these two components, a solid material, for example polyepoxide, is formed. This chemical curing works according to the principle of the two-component adhesive Araldite™. This application phase 24 can provide a sub-phase 25 of projecting at least one collimated or localised beam of fluid comprising magnetic particles on the internal surface 4 of the functional area 2a, 2b. This sub-phase 25 can be carried out in the form of a projection of a single beam of fluid on the internal surface 4. The beam is for example configured to project onto the internal surface 4a, 4b a continuous/discontinuous and localised bead of this fluid. Alternatively, the sub-phase 25 can be carried out in the form of a projection on the internal surface 4a, 4b of two collimated or localised beams. The first beam comprises the fluid containing the magnetic particles and the second beam comprises a liquid material selected so as to cause solidification of the fluid when it is contacted with the latter. As already mentioned previously, this is the principle of the two-component adhesive Araldite™, consisting of an epoxy resin comprising the magnetic particles 7 and a material such as a polymerising agent, 1,4,7,10-tetraazadecane. In contact with these two components, a polyepoxide is formed.
Thus, the invention allows at least two mechanical parts 1a, 1b to be obtained, the functional area 2a, 2b of which is magnetised while having antagonistic polarities. These functional areas 2a, 2b of these two parts 1a, 1b provided to cooperate together in the mechanism, are configured to generate a magnetic field which aims at ensuring a separation of the contact surfaces 3a, 3b of these areas 2a, 2b when these two parts 1a, 1b are stopped in this mechanism. Such a configuration of these contact surfaces when the two parts are stopped contributes in reducing the energy consumption of this mechanism when these parts 1a, 1b resume movement.
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