The present invention relates to a method for producing an annular casing for an aircraft turbine engine.
The technical background comprises in particular the documents US-A1-2009/022579 and US-A1-2015/239181.
An aircraft turbine engine comprises several annular casings. To lighten a casing, it is known to make it out from a composite material. In the present application, a composite material is defined as a material comprising fillers such as fibres embedded in a polymeric matrix. The polymeric matrix is usually a resin.
A fan casing can be made from composite material, for example. This casing surrounds the fan of the turbine engine and must meet the specifications necessary for its certification, in particular with regard to its fire resistance.
The resin used to produce the fan casing is chosen for its mechanical properties but is flammable in the current art and it is therefore necessary to cover the upper surface of the casing with a fire-resistant layer.
Solutions exist but are not entirely satisfactory, in particular because they are long and complex to implement.
The invention proposes to remedy this drawback.
The invention thus proposes a method for producing an annular casing for an aircraft turbine engine, this casing comprising an annular body made from a composite material based on a first resin, and a fire-resistant external layer which covers an external annular surface of the body and which is made from a composite material based on a self-extinguishing second resin, characterised in that it comprises:
a) a step of preparing a strip of a fabric pre-impregnated with said second resin, said strip having an elongated shape along an axis of elongation and a width at least equal to and preferably greater than a width of said body measured along its axis of revolution, this strip comprising fibres woven and oriented in directions perpendicular to one another and inclined by an angle of about 45° with respect to said axis of elongation, and
b) a step of applying the strip on the external surface of the body, so as to cover the entirety of this surface in a single pass of the strip around the body.
The invention proposes to use a self-extinguishing resin and to pre-impregnate a fabric strip with this resin which is then deposited all around the body of the casing.
The strip is made by weaving glass or carbon fibres for example. These fibres are oriented in particular directions that will facilitate the shifting of the strip when it is placed on the body.
Indeed, the external surface of the body of the casing may have a marked relief. When applying the strip, it is important that the strip follows this relief without creating air bubbles for example. The fibres oriented at 90° to each other and at 45° to the elongation axis of the strip will slide more easily over each other and will facilitate the shifting of the strip.
The body is advantageously surrounded by a single strip. This strip extends all around the body and is advantageously at least as wide as the body. Alternatively, the strip could be formed by several adjacent annular sections, in particular if the surface of the external surface of the casing has a double curvature or is of the bi-conical type.
The invention also allows to help to fight against the galvanic corrosion of the casing when it is made in a composite/metal assembly.
The method according to the invention may comprise one or more of the following characteristics, taken independently or in combination with each other:
The method according to claim 5, wherein a plurality of compaction rolls are distributed along the axis of revolution of the body and have profiles complementary to the relief of the external surface of the body;
Further characteristics and advantages of the invention will become apparent from the following detailed description, for the understanding of which reference is made to the attached drawings in which:
This casing is for example a fan casing.
The method essentially comprises two steps, namely a step a) of preparing a strip of pre-impregnated fabric 10 (
The first step a) of producing the strip 10 can be divided into several successive sub-steps. It can comprise a first sub-step a1) of producing the fabric strip. For this purpose, a loom can be used, for example, to make the fabric strip from fibres, preferably glass. The glass fibres form weft and warp threads of the fabric and are intended to be oriented at 90° from each other and at about 45° to an axis of elongation A of the strip, as schematically illustrated in
The strip 10 has a width e and a length L and its length (largest dimension) extends along the elongation axis A.
The first step a) can comprise another sub-step a2) of impregnating the strip with a self-extinguishing resin which is for example the M26T® resin marketed by the company Hexcel. The first step a) can comprise another sub-step a3) of placing a protective film on each of the faces of the strip. Finally, in another sub-step a4), the strip 10 can be wound on itself or on an axis to form a roll 16 that is easier to handle (
Similarly, the second step b) may comprise several successive sub-steps.
The first sub-step b1) is to rotate the body 12 of the casing, as shown in
The body 12 of the casing is rotated by means of rollers in
In the present application, the terms internal and external or inner and outer are understood to mean positions relative to the axis B of revolution of the casing or of its body 14.
During the second step b), the strip roll 16 is arranged next to the rotatable body 12. The roll 16 is itself rotated (sub-step b2)) about its axis to unwind the strip 10 and apply it with some tension to the external surface 14 of the body 12. The roll 16 is mounted on a motorized unwinder so as to control its rotation speed.
As can be seen in the drawings, the width e of the strip 10 is preferably greater than the width of the body 12. It is therefore understood that a single pass of the strip 10 around the body 12 is sufficient to cover the entire external surface 14 of the body.
In the example shown, the body 12 of the casing and the roll 16 rotate in opposite directions.
In the example shown in
The unwound strip 10 extends from the roll 16 to the external surface 14 of the body 12 of the casing and is pressed onto this surface by means of compaction rolls 24.
Advantageously, the compaction rolls 24 extend along the axis B and have profiles complementary to the relief of the external surface 14 of the body 12 (
The pressures F exerted by the rolls 24 on the strip 10 and the body 12 are preferably managed and adjusted independently of each other (sub-step b3)). The compaction rolls 24 each comprise at least one external annular layer of foam. The foam layers of at least some of the rolls 24 preferably have different stiffnesses.
The foams allow the rolls 24 to adapt to the changing shape of the body 12 and to the resulting rate of shifting. They are, for example, shaped like the radii of the flanges 18 at both ends of the body 12 to allow draping into the bottom of the radii of these flanges. The parameters of tension of the strip 10 and contact pressure of the compaction rolls 24 can be controlled.
Infrared lamps 26, 28 are arranged upstream and downstream of the compaction rolls, with respect to the winding direction of the strip 10 on the body 12. The upstream lamp 26 allows to heat the strip 10 before it is placed and the downstream lamp 28 allows to heat the strip 10 and the body 12 simultaneously. This allows to facilitate the adhesion of the strip to the external surface 14 of the body 12 (sub-step b4)).
Film unwinders 30 are arranged under and on top of the strip 10 as it is unwound. These unwinders 30 are configured to remove the protective films present on both faces of the strip, prior to its application to the body 12 of the casing (sub-step b5)).
Number | Date | Country | Kind |
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FR1909462 | Aug 2019 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FR2020/051493 | 8/24/2020 | WO |