Turbine blade having a structural reinforcement with enhanced adherence

Abstract

A turbine engine blade having an aerodynamic surface extending a first direction between a leading edge and a trailing edge and in a second direction, perpendicular to the first direction, between a root of the blade and a tip of the blade, the aerodynamic surface being made of a fiber-reinforced organic matrix composite material, and a metallic structural reinforcement bonded by an adhesive joint to the leading edge whose shape it follows and which has over its entire height a substantially V-shaped section with a base extended by two lateral flanks having a thinned profile at free ends directed toward the trailing edge, the adhesive joint being locally supplemented below the free ends of the lateral flanks by an elastomeric polymer introduced in the form of solid particles into the adhesive joint and adhered to the aerodynamic surface and/or the free ends of the lateral flanks during a polymerization phase.

Claims

1. A turbine engine blade comprising an aerodynamic surface extending in a first direction between a leading edge and a trailing edge and in a second direction, substantially perpendicular to said first direction, between a blade root and a blade tip, said aerodynamic surface being made of a fiber-reinforced organic matrix composite material, the blade further comprising a metallic structural reinforcement bonded by an adhesive joint to said leading edge whose shape it follows and having over its entire height a substantially V-shaped section with a base extended by two lateral flanks having a thinned profile at free ends directed toward said trailing edge, wherein said adhesive joint is locally supplemented under a trailing edge tip of said free ends of said lateral flanks by an elastomeric polymer introduced in the form of solid particles into said adhesive joint and adhered to said aerodynamic surface and/or said free ends of said lateral flanks during a polymerization phase.

2. The blade as claimed in claim 1, wherein said elastomeric polymer has the following properties at 23° C.: Young's modulus E≈10 MPa; stress at break σ.sub.b>10 MPa; strain at break ε.sub.b>80%.

3. The blade as claimed in claim 1, wherein said elastomeric polymer is present over a length comprised between greater than 0% and 25% of a total length from each of said free ends of each of said lateral flanks.

4. The blade as claimed in claim 1, wherein said structural reinforcement is a titanium-based metal of the TA6V type.

5. The blade as claimed in claim 1, constituting a turbine engine fan blade.

6. A turbine engine having at least one blade as claimed in claim 5.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Other features and advantages of the present invention will emerge from the description made below, with reference to the appended drawings which illustrate an example embodiment devoid of any limiting character and on which:

(2) FIG. 1 represents a turbine engine fan blade in side view;

(3) FIG. 2 illustrates a partial section of the blade of FIG. 1 showing a metallic structural reinforcement of the leading edge bonded to the composite material blade in accordance with the invention; and

(4) FIGS. 3, 4A, 4B, 4C and 5 show several distinct example embodiments of the assembly structure of the elastomeric polymer connecting the blade to the metallic structural reinforcement.

DETAILED DESCRIPTION OF AN EMBODIMENT

(5) FIG. 1 is a side view of a blade, for example a fan blade of a turbine engine (not shown), having a leading edge metallic structural reinforcement according to the invention.

(6) The blade 10 comprises an aerodynamic surface or blade 12 integral with a root 14 and extending in a first axial direction 16 between a leading edge 18 and a trailing edge 20 and in a second radial direction 22 substantially perpendicular to the first direction 16 between this root 14 and a tip of the blade 24. The lateral surfaces of the blade 12 which connect the leading edge 18 to the trailing edge 20 constitute the upper 26 and lower 28 surfaces of the blade.

(7) Conventionally, the blade 12 is made of a fiber-reinforced organic matrix composite material. By way of example, the composite material used can be composed of an assembly of woven carbon fibers and an epoxy resin matrix, the whole being formed by molding by means of a resin injection process of the resin transfer molding (RTM) type.

(8) The blade 10 also has a structural reinforcement 30 bonded to the leading edge 18 of the blade and extending both in the first direction 16 beyond this leading edge and in the second direction 22 between the root 14 and the tip 24 of the blade.

(9) As shown in FIG. 2, the structural reinforcement 30 follows the shape of the leading edge 18 of the blade 12 of the blade 10 which it extends to form the leading edge of the blade 32. Conventionally, this structural reinforcement 30 is advantageously a one-piece part comprising an approximately V-shaped section having a base or nose 34 whose external profile forms the leading edge of the blade 32 and the rounded internal profile is able to follow the rounded shape of the leading edge 18 of the blade 12. This base is extended by two lateral flanks or fins 36A and 36B following the lower 26 and upper 28 surfaces of the blade and presenting a tapered or thinned profile at the free ends 37A, 37B directed toward the trailing edge of the blade. The structural reinforcement 30 is metallic and preferably based on TA6V type titanium. Indeed, this material has a high impact energy absorption capacity.

(10) As FIG. 2 also shows, the structural reinforcement 30 is bonded to the blade 12 by means of an adhesive joint 38 of known properties recalled in the preamble of the present application, which adhesive joint is, according to the invention, locally supplemented under the free ends 37A, 37B of the fins 36A, 36B of an elastomeric polymer 40 adhered to the blade and/or to these free ends during a polymerization phase and whose properties at 23° C. are as follows: Young's modulus E≈10 MPa; stress at break σ.sub.b>10 MPa; strain at break ε.sub.b>80%. An example of such an elastomeric polymer is known as 23HP90 from the firm ITC.

(11) This additional adhesion can be obtained at these free ends as a total replacement of the adhesive joint or in addition to the adhesive joint. In the absence of an adhesive joint, the surface of the reinforcement or that of the composite is degreased and sanded before receiving an adhesion primer. The elastomer is then adhered to the surface during its vulcanization (or polymerization) in a specific tooling known per se, for example at a temperature of 180° C. under a pressure of 3 bars and for 60 minutes. In the presence of an adhesive joint, the same polymerization process can be used to adhere all the elements (reinforcement, composite, elastomer and adhesive joint) together. It is also possible to polymerize the elastomer on the reinforcement or on the composite and then to place the reinforcement on the composite by interposing the adhesive joint and then to polymerize the assembly thus formed.

(12) The elastomeric polymer can be present over a length comprised between 0% and 25% of the total length of the fin from its free end. The skilled person knows how to adapt it according to the criticality of the area located at a given height of the blade. This makes it possible to have an adhesive joint with mechanical properties optimized by zone according to need, like what is achieved with conventional composite materials. Indeed, since elastomeric polymers generally have a low stiffness, the intensity and singularity of the stresses induced by edge effects in the elastomeric polymer are considerably reduced compared to a conventional epoxy adhesive. In addition, elastomeric polymers have very high strains at break and stresses at break that increase with the impact speed. The addition of an elastomeric polymer at the fin tip thus ensures the dual function of i) attenuating the stresses generated in this critical zone and ii) dissipating the mechanical energy of the impact without damaging itself.

(13) FIG. 3 illustrates, on a detail of the assembly structure, the elastomeric polymer 40 adhered by polymerization to the blade 12 and to the fin tips 37A, 37B and replacing at this location (i.e. locally) the adhesive joint between this blade and these fin tips.

(14) FIG. 4A illustrates, on a detail of the assembly structure, the elastomeric polymer 40 forming a homogeneous layer, applied for example by projection of molten particles on the tip of the fin 37A, 37B, before application of the adhesive joint 38 between this layer and the blade 12. In FIG. 4B, it is envisaged that this layer is applied to the blade 12 and not to the tip of the fins, and in FIG. 4C that it is applied to both the blade 12 and the tips of fins 37A, 37B, an intermediate adhesive joint 38 then ensuring the bond between these two layers of elastomeric polymer 40A, 40B.

(15) Finally, FIG. 5 illustrates, on a detail of the assembly structure, the elastomeric polymer introduced in the form of solid particles 42 in the adhesive 38. In this case, the solid particles are sprinkled onto the raw adhesive beforehand and are dispersed in the thickness of the adhesive joint during the polymerization phase which involves a decrease in viscosity and the creep of the adhesive.

(16) If the aforementioned description has been illustrated by a turbine engine fan blade, it should be noted that the invention is also applicable to the production of a metallic structural reinforcement intended to reinforce the leading edge of any other type of turbine engine blade, whether for land vehicles or for aircraft, and in particular a helicopter turboshaft engine or an aircraft turbojet engine, but also of propellers such as the propellers of non-veined counter-rotating double fans.