METHOD FOR PRODUCING A DOUBLE-WALLED THERMOSTRUCTURAL MONOLITHIC COMPOSTE PART, AND PART PRODUCED

Abstract

A fibrous preform (1) is produced, provided with a sandwich structure comprising an intermediate flexible core (4) and two outer fibrous frames (2, 3), respectively arranged on opposing outer faces of said flexible core (4) and assembled by sections of wire (8, 9) passing through said fibrous frames (2, 3), said preform (1) being impregnated with resin. Said preform is then hardened and the core (4) is removed, preferably by pre-densification with chemical vapour infiltration, and the structure produced is then densified with liquid-phase infiltration.

Claims

1. A method for producing a thermostructural monolithic fibres/matrix composite part (10), comprising two skins (11, 12) of composite material which are spaced apart from one another and interconnected by a plurality of thread-like spacers (13) of composite material, said method comprising at least: A/ producing a fibrous preform (1) provided with a sandwich structure comprising an intermediate flexible core (4) and two outer fibrous frames (2, 3) arranged on opposed outer faces of said flexible core (4) and joined by thread portions (8, 9) that pass through said fibrous frames (2, 3), said preform (1) being impregnated with resin; B/ curing said preform and removing said core (4); and C/ densifying the resulting structure, wherein, in step C/, said structure is densified by liquid-phase infiltration.

2. The method according to claim 1, wherein, in step B/, pre-densification is carried out by gas-phase infiltration so as to pre-densify said preform (1) and thus said thread through-portions (8, 9) intended for forming said spacers (13).

3. The method according to claim 2, wherein, in an intermediate step between steps B/ and C/, the preform that was pre-densified in step B/ is machined.

4. The method according to claim 3, wherein, in said intermediate step, threaded holes and/or bores are machined.

5. The method according to claim 4, wherein, at least during the densification step, step C/, plugs (15) are arranged in said threaded holes and said bores.

6. The method according to claim 1, wherein, in step C/, in order to achieve liquid-phase densification, silicon is introduced in liquid paste form and spreads out under the effect of heat and pressure in a densification furnace.

7. The method according to claim 1, wherein, in step A/, a fibrous preform having variable thickness is produced.

8. The method according to claim 1, wherein, in step A/: a) a flexible sandwich structure (1) is formed that comprises an intermediate flexible core (4), which is made of a material that is capable of being penetrated by a needle and is impervious to the resin having to create the matrix, and two outer flexible fibrous frames (2, 3) arranged on opposed outer faces of said flexible core (4); b) said fibrous frames (2, 3) and said core (4) of said sandwich structure (1) are joined by stitching by means of a thread (5) forming stitches that include thread portions (8, 9) that pass through said fibrous frames (2, 3) and said core (4), said stitching thread (5) consisting of a roving comprising a plurality of filaments that are not linked together, said thread portions (8, 9) that pass through said fibrous frames (2, 3) and said core (4) having, following said stitching operation, longitudinal channels in said core that are provided between said filaments and extend from one of said fibrous frames to the other; and c) said sandwich structure (1) is impregnated with said resin, said impregnation operation being carried out such that said curable resin is made to penetrate said longitudinal channels of said thread through-portions (8, 9) in order to form, at the location of each of said portions, a resin bridge, of which the opposed ends are in contact with the resin impregnating said flexible fibrous frames (2, 3).

9. A monolithic fibres/matrix composite part (10) which comprises two skins (11, 12) of composite material which are spaced apart from one another and interconnected by a plurality of thread-like spacers (13) of composite material, and is produced by carrying out the method according to claim 1.

10. The monolithic fibres/matrix composite part according to claim 9, wherein at least one coating is applied on the outside of at least one of said skins (11, 12).

Description

[0031] The figures of the accompanying drawings will give a clear understanding of how the invention can be implemented. In these drawings, identical reference numerals refer to similar elements.

[0032] FIG. 1 is a schematic and partial view of a preform that is produced and used when carrying out the present invention.

[0033] FIG. 2 is a schematic and partial view of a composite part produced from the preform from FIG. 1.

[0034] FIG. 3 is a perspective view of a monolithic part produced in panel form and provided with plugs for a liquid-phase infiltration step.

[0035] The present invention relates to a method for producing a thermostructural monolithic fibres/matrix composite part 10, comprising two skins 11 and 12 of composite material which are spaced apart from one another and interconnected by a plurality of thread-like spacers 13 of composite material. A monolithic composite part 10 of this kind, which is intended for forming thermal protection means for example, and is shown in a partial and schematic view in FIG. 2, has to be able to withstand very high internal and/or external pressures.

[0036] Said production method comprises:

[0037] A/ forming, in the usual manner, a fibrous preform 1 provided with a sandwich structure comprising an intermediate flexible core 4 and two outer fibrous frames 2 and 3. Said fibrous frames 2 and 3 are arranged on opposed outer faces of said flexible core 4 and are joined by thread portions 8 and 9 that pass through said fibrous frames 2 and 3, as is shown in FIG. 1 and as described below, said preform 1 being impregnated with resin;

[0038] B/ curing said preform 1 and removing said core 4; and

[0039] C/ densifying the resulting structure.

[0040] According to the invention, the structure is densified by liquid-phase infiltration in step C/ such that a layer that is rich in SiC is applied.

[0041] LSI liquid-phase infiltration (liquid silicon infiltration, of this kind, as described below, which in particular allows the silicon used to penetrate the centre of the preform, results in densification that is easy to control.

[0042] Moreover, this liquid-phase densification has other advantages, in particular: [0043] a reduced cost; and [0044] improved performance.

[0045] In a preferred embodiment, pre-densification is carried out in step B/ by CVI gas-phase infiltration (chemical vapour infiltration) so as to pre-densify said preform 1 and thus said thread through-portions 8 and 9 (intended for forming said spacers 13). This pre-densification makes it possible to produce a carbon-carbon (C—C) structure. R-CVI rapid infiltration (rapid chemical vapour infiltration) is preferably used; this type of infiltration is advantageous in terms of cost, implementation time and performance.

[0046] By means of this pre-densification, said thread through-portions 8 and 9 are provided with a carbon layer, which makes it possible in particular to protect said portions during the liquid-phase densification carried out in step C/.

[0047] Therefore, this preferred embodiment is based on the cooperation between the pre-densification step (step B/) and the densification step (step C/) which makes it possible to create a C—C/SIC structure. Indeed, pre-densification makes it possible to carry out densification without damaging the thread portions 8 and 9 intended for forming the spacers 13 (which contribute to making the monolithic composite part 10 rigid), while densification has the aforementioned advantages and makes it possible to form a ceramic structure.

[0048] In a preferred embodiment, in order to carry out step A/, the following operations are carried out, as is described in particular in FR-2 836 690:

[0049] a) a flexible sandwich structure 1 is formed that comprises an intermediate flexible core 4, which is of a material that is both capable of being penetrated by a needle and impervious to the resin having to create said matrix. Said flexible sandwich structure 1 also comprises two outer flexible fibrous frames 2, 3 arranged on opposed outer faces of said flexible core 4;

[0050] b) said fibrous frames 2, 3 and said core 4 of said sandwich structure 1 are joined by stitching by means of a thread 5 forming stitches that include thread portions 8, 9 that pass through said fibrous frames 2, 3 and said core 4, as shown in FIG. 1. Said stitching thread 5 consists of a roving comprising a plurality of filaments that are not linked together. After said stitching operation, the thread portions 8, 9 that pass through said fibrous frames 2, 3 and the core 4 have longitudinal channels in said core that are provided between said filaments and extend from one of said fibrous frames to the other; and

[0051] c) said sandwich structure 1 is impregnated with a resin. Said impregnation operation is carried out such that said curable resin is made to penetrate said longitudinal channels of said thread through-portions 8, 9 in order to form, at the location of each of said portions, a resin bridge of which the opposed ends are in contact with the resin impregnating the flexible fibrous frames 2, 3.

[0052] It should be noted that: [0053] the flexible core 4, which is shown as being plate-shaped, can, in reality, be of any shape having two opposed faces, for example a cylinder, a cone or a prism. Said core is made of a material which is capable of being penetrated by a needle, such as a polyurethane foam, a polypropylene or, preferably, a polystyrene. Moreover, this material is impervious to the resin used to impregnate the flexible fibrous frames 2 and 3; and [0054] each of the flexible fibrous frames 2 and 3 has a fibrous structure that can be produced in any known manner. Said frames 2 and 3 are each in the form of a layer of carbon fibres or of any other material that is capable of forming high-strength fibres. Moreover, said frames 2 and 3 can have different and varied thicknesses and shapes.

[0055] As is shown in FIG. 1, it is advantageous for the frames 2 and 3 to be parallel to one another and for the thread through-portions 8 and 9 to be orthogonal to said frames. In FIGS. 1 and 2, for the purpose of clarity, a large distance is shown between the two thread portions for each stitch; however, in reality, said thread portions can of course be very close to one another.

[0056] It should be noted that the sandwich structure 1 joined by the threads 5 and 6 is flexible and may possibly undergo changes of shape. Furthermore, at this stage of the method, the dimensions of the structure 1 are preferably checked.

[0057] Following stitching, the sandwich structure 1 is impregnated with the curable resin. Impregnation is preferably carried out under vacuum pressure such that said resin penetrates not only the fibrous frames 2 and 3, but also the longitudinal channels of the thread 5.

[0058] During this impregnation operation, the core 4 is not impregnated because it is impervious to the resin. The impregnated resin is then cured, for example by increasing the temperature, possibly in conjunction with applying pressure (of a few bars).

[0059] According to the invention, in order to form the C—C carbon matrix of the sandwich structure 1, said structure is pre-densified (aforementioned step B/) by gas-phase infiltration as indicated above, and this makes it possible to also remove the core 4.

[0060] The resulting structure is then subject to other operations indicated hereinafter, and is then densified in step C/ with the aim of producing a ceramic matrix.

[0061] The monolithic composite part 10 from FIG. 2 is ultimately produced and comprises two skins 11 and 12 of composite material (from the flexible frames 2 and 3) which are spaced apart from one another and interconnected by a plurality of thread-like spacers 13 which are made of composite material (from the through-thread portions 8 and 9) and are orthogonal to said skins 11 and 12. In a preferred application, the space 14 between the two skins 11 and 12 is intended to have a coolant flowing therethrough in particular so as to make the monolithic composite part 10 capable of withstanding high temperatures. The two skins 11 and 12 forming the space 14 are kept at a distance from one another by means of thread-like spacers 13 which, in an application of this type, provide the shape of the structure, ensure that the coolant is resistant to pressure and enhance convective heat transfer.

[0062] Moreover, in a preferred embodiment, non-destructive testing is performed, in an intermediate step between aforementioned steps B/ and C/, on the preform that was pre-densified in step B/.

[0063] Said pre-densified preform is then machined. It is possible to machine the pre-densified preform (C—C) using standard means, but this machining would be very difficult to perform on the final material (C—C/SiC) which becomes very hard following densification.

[0064] This intermediate step is preferably a step of low-thickness mechanical machining which is used to prepare the structure for liquid-phase densification and to give said structure its desired final geometry.

[0065] Moreover, in this intermediate step, threaded holes and/or bores are machined if the part 10 requires threaded holes and/or bores therein in order to install a coolant supply means on the part 10, for example. This machining operation can be carried out by means of ultrasound for example.

[0066] Plugs 15 are then arranged in said threaded holes and said bores, as shown for the part 10 from FIG. 3, which is produced as a plate 16 and in the shoulders of which threaded holes are provided. Said plugs 15 are used at least during the densification step, step C/, in order to prevent the threaded holes and bores from getting clogged (such that they are in the final part).

[0067] In a preferred embodiment, in step C/, in order to achieve liquid-phase densification, silicon is introduced in liquid paste form (slurry) and spreads out in the part under the effect of heat and pressure in a densification furnace by capillary action and by gas being transported on the walls that are not initially covered with paste. Siliconising can be achieved by a suitable form of heat treatment. In a preferred embodiment, the method described in WO2008/106932 is used to carry out this densification.

[0068] At this stage of the method, the dimensions of the part 10 are generally checked (using non-destructive testing).

[0069] It should be noted that the method according to the invention can be used to produce a part 10 having variable thickness, as shown by way of example by the edges 17A and 17B of the panel 16 from FIG. 3. In order to do this, a fibrous preform 1 is produced in step A/ that has a suitable shape and suitable dimensions and may be provided with stiffeners for example.

[0070] Furthermore, it is also possible to cover the outer face of at least one of said skins 11 or 12 of the part 10 with at least one coating, for example using a sealing material that is used as standard to create impermeability.