Patent Application
20160071645
The present invention relates to inductive electrotechnical equipment such as inductors, transformers or electric motors. It relates more particularly to the production of the coils used in these components.
In order to create a magnetic field, the coils must be formed from conductive wires coated with a layer of insulating material. Any failure of this insulating material would result in short-circuiting the turns and therefore reducing the inductance of the coil.
The coils are usually formed from copper wire. Currently, the insulation of the wires is produced with thermosetting polymer materials such as polyester, polyamide, polyepoxide or polyimide varnishes, according to the specified requirements for resistance to temperature. Once the insulating wire coils have been produced, they are additionally impregnated with another layer of resin. These solutions make it possible to produce compact coils that are satisfactory for normal applications.
Aeronautical applications require optimisation of these solutions in terms of mass and volume. A first way consists of optimising the proportion of the volume of conductor to the total volume of the insulated coil. The use of copper wires with a rectangular cross section, for example, meets this objective by limiting the interstices compared with wires with a circular cross section.
However, in order to further save in weight, aluminium is used in place of copper. In fact, the use of aluminium strips for manufacturing coils combines the advantage of compact geometry and a low-density conductive material.
In addition, the use of anodising for electrically insulating aluminium is a very mature solution that also has the advantage of having a resistance to temperature very much greater than current solutions.
Consequently, anodised aluminium coils that can be used for producing electrotechnical components are currently being sold. They are supplied to the dimensions of the component and all that remains to be done then is to integrate them in the latter with, in particular, additional impregnation with resin.
However, the use of these coils has several drawbacks:
The aim of the invention is to remedy the aforementioned defects.
It relates to a method for manufacturing a strip of impregnated anodised aluminium, intended to be used in a coil of an electrotechnical component, said coil comprising an interstitial material providing the functions of cohesion and dielectric isolation, said interstitial material being obtained from a precursor mixture able to cross-link, said method comprising:
This method is distinctive in that the anodised aluminium has not undergone sealing of the pores of the alumina formed by anodising before application of the precursor mixture of said interstitial material.
In a known manner, cross-linking of the precursor mixture consists of forming, by chemical reactions between its components when this mixture is subjected to certain physical conditions, molecular structures organised in a lattice.
Replacing the operation of sealing with hot water with that of impregnation of the precursor mixture of interstitial material able to cross-link makes it possible to create ideal adhesion conditions on the surface of the anodised aluminium with this same interstitial material when it will be used for manufacturing the coil in the electrotechnical component. This is because, since the porous alumina created at the end of anodising is impregnated with the interstitial material, the interface therewith will thus be very close and therefore durable.
Preferably, the precursor mixture used in the method comprises a resin and a hardener. Generally, it is said that this resin is thermosetting since cross-linking of the precursor mixture takes place.
Advantageously, so that the resin has the required properties of resistance to voltage and dielectric isolation under the operating conditions of aeronautical components, at least one component chosen from polyepoxides, polyamides or silicones forms part of its formulation.
In a preferred variant, when the interstitial material is thermosetting resin, strips of anodised aluminium pre-impregnated by the initial method, in which the cross-linking step is incomplete, are manufactured.
Merely starting the cross-linking step makes it possible to store these pre-impregnated anodised aluminium strips, preferably at low temperature, in order to reuse them later.
In a variant embodiment, the interstitial material is a material used by a sol-gel method. Although the chemical reactions transforming the precursor mixture are very different through their nature and their temperature cycle from those of a thermosetting resin, they perform a kind of cross-linking resulting in a material having a structure in space that did not exist in the precursor mixture. Sol-gel methods have the advantage of making it possible to obtain various materials, some, for example, having better resistance to temperature than resins.
In fact, the invention also relates to a method for manufacturing an electrotechnical component comprising at least one coil, said coil comprising a strip of anodised aluminium wound in turns and an interstitial material fulfilling the functions of cohesion and dielectric isolation, characterised in that:
In such a configuration, some of the electrical insulation between the windings of the coil is provided by the anodised aluminium layer on the strips. The interstitial material for its part fulfils the function of protection and cohesion in order to maintain the coil in the specified form. It also provides additional dielectric isolation between the aluminium strips. In addition, the method thus makes it possible to have a single material enveloping the aluminium strips in the coil and eliminates undesirable interfaces between various materials.
Advantageously, when the interstitial material is resin, the method for manufacturing the electrotechnical component described above is adapted using the strip of pre-impregnated anodised aluminium, which is then formed to the dimensions of the coil and undergoes the definitive cross-linking step.
The invention also concerns the pre-impregnated anodised aluminium strips and the electrotechnical components obtained by the aforementioned methods.
The invention will now be presented in more detail for a few embodiments.
Anodising aluminium is a controlled oxidation of the surface of the part, here the aluminium strip. For example, according to a known method, the creation of the anodic layer is the result of passing a current through an electrolyte. The anodising tank contains, for example but in a non-limiting manner, a phosphoric acid solution in which the aluminium strip is placed. A direct current is applied for a given period in order to create the anodic layer of specified thickness, of approximately ten microns.
The layer of alumina thus created is an excellent electrical insulator. It also has good mechanical properties. However, it has a honeycomb structure, with micropores, which allows impurities to pass, leading to corrosion of the aluminium strip over time.
For this reason, anodised aluminium products, in particular when they must be stored, undergo a so-called sealing operation. This operation consists of a hydration of the anodic layer, the result of which is causing the walls of the cells to swell and obstructing the holes therein. This operation is generally performed by soaking the anodised aluminium in hot water, controlling the temperature and the duration.
Unfortunately for the application sought, the anodised aluminium thus sealed has lost its surface properties. In particular, the honeycomb alumina is more able to bind with an adhesive material than the coating of hydrate obtained after sealing.
A first use of the invention consists in a transposition of the concept of pre-impregnation used in the industry of composite materials comprising an organic matrix in the case where the matrix is an unsealed anodised aluminium strip, and the impregnation material is the resin that ultimately will be used to manufacture the coil in the component.
In fact, the thermosetting resin, which is a mixture of polymers and other ingredients, for which there exist a plurality of known formulations according the type of application, will, during the steps of the method, be in several states. In its final state, as the coil cohesion material, the resin is a solid material, having suitable properties of mechanical strength. However, this solid state is obtained from a malleable fluid form, by a so-called cross-linking method. Generally this method is a heat treatment. It organises the molecular structure of the polymer in a lattice in order to give it its solid form. In the present document, the resin in its fluid state before cross-linking will be referred to hereinafter as the precursor mixture. In a known manner, this precursor mixture contains a resin belonging to the following group: polyimide, polyepoxide, polyamide, polyamide-imide, polyester, polyesterimide, silicone, phenolic or polyurethane. In a known manner, it also contains a hardener which reacts with the resin in order to cause the cross-linking. It may contain additives assisting the overall process, such as solvents and catalysts. In the case of known thermosetting resins, this cross-linking may be done in an incomplete manner. This makes it possible to give a first gelled form to the resin and thus to store it in order then to resume and complete the cross-linking process. During the final cross-linking process, two pretreated resin layers can thus be welded together as if they had formed only a single element.
The first step of the process of producing the coil of the component is therefore the manufacture of the unsealed anodised aluminium strip. Next, the production of the pre-impregnated aluminium strip comprises three important steps.
A first step consists of depositing, on the aluminium strip that has just been anodised and not sealed, a layer of precursor mixture of the resin that will be used for manufacturing the coil in the electrotechnical component. Preferably, the precursor comprises at least one solvent that gives it the rheological properties necessary for being deposited evenly and penetrating the pores of the anodised aluminium layer, in order to bind closely with the latter. Known methods, by spraying or dipping, exist for providing a uniform deposition of precursor mixture and good penetration through the pores of the anodised layer.
A second step, of incomplete cross-linking, consists of an intermediate heat treatment that starts the cross-linking and gels the polymer. In the gelled state, the resin and hardener have reacted sufficiently to begin a three-dimensional lattice and to enable the product to adhere to the anodised aluminium. On the other hand, the rigidity of the material is still very low. This state is advantageous since it makes it possible to form a protective layer adhering correctly to the anodised aluminium strip in order to store it before integrating it with a component and, especially, as will be seen later, to resume the cross-linking process in order to ensure cohesion of the product.
Finally, a third step of storage at low temperature (−20° C. in general) is necessary for stabilising the material and dispatching the pre-impregnated anodised aluminium strip to the place of production of the final part. In a first variant, the pre-impregnated aluminium strips are formed in coils having the dimensions of the electrotechnical component to be produced before being stored. In a second variant, said coils are not preformed and it is the pre-impregnated strip that will be used as required.
The production of the coil of the electrotechnical component from such a pre-impregnated anodised aluminium strip also comprises three main steps.
In a first step, the pre-impregnated anodised aluminium strip is heated to ambient temperature in order to be able to be placed in the electrotechnical component. According to the variant chosen for storage, it is the completely ready coil that is installed. Otherwise the pre-impregnated aluminium strip at ambient temperature is previously wound to the dimensions of the coil of the electrotechnical component.
In a second step of complete impregnation, the entire component is coated with resin, including the coil or coils that make it up.
The last step consists of a complete heat treatment that results in a final cross-linking of the resin around the unsealed anodised aluminium strips, wound according to the form of the coil of the component.
In this step, the gelled resin layers of two superimposed pre-impregnated strips fuse together and with the resin that coats the component, by virtue of the fact that their incomplete molecular lattice allows recombination with the adjacent material. Therefore the only interface remaining is that between the resin and the unsealed anodised aluminium, the adhesion characteristics of which were provided as from pre-impregnation.
In order to implement this invention, it is important for the resin to have:
Resins based on polyepoxide, polyimide or silicone are preferably used in order to have the necessary properties in the operating temperature range as well as the voltage levels envisaged for electrotechnical applications in on-board aeronautics. Resins of this type are already used in the manufacture of inductive coils according to the prior art. Moreover, the cross-linking temperature of resins of this type makes it possible to use them for components where the windings experience temperatures of approximately 250° C.
The rheological properties necessary for the resin for application to anodised aluminium are obtained by means of dilution in organic solvents. The proportion of solvent adjusting the viscosity level of the resin is defined by experimentation for each aforementioned resin formulation.
A variant of the invention consists of replacing the resin with a material used by sol-gel method. The sol-gel method makes it possible, by a polymerisation of molecular precursors in solution, to obtain vitreous materials without passing through the fusion step. It is in particular possible to obtain mineral solid materials having the required dielectric properties from organo-mineral sol-gel mixtures.
Although the chemical processes are different from the case of the cross-linking of a thermosetting resin, the coating of an unsealed anodised aluminium strip with a material via a sol-gel method is done in a similar manner in two steps:
For use in the invention, a precursor mixture of the type comprising water, acetic acid, methanol, isopropanol and an organosilane material is for example used. Complementary components such as aluminium hydrates make it possible to obtain the required dielectric properties.
Advantageously, use is also made of inorganic polymers for obtaining ceramics, in a known manner, with a sol-gel method. Ceramics have mechanical and thermal properties that make it possible to use the coils obtained by the method in components wherein the temperatures may reach 250° C. and the operating electrical voltage 2 kV.
In the case of the use of the sol-gel method, the process does not involve use of a pre-impregnated or pretreated strip. This is because, in the case of the sol-gel method, the “cross-linking” process, once started, must be completed. There is no intermediate “gelled” state that would have useful plastic properties. The steps of manufacturing the coil of the component are therefore:
| Number | Date | Country | Kind |
|---|---|---|---|
| 1353146 | Apr 2013 | FR | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/FR2014/050810 | 4/3/2014 | WO | 00 |
