阅读说明：本技术 带金属加强件的复合叶片及其制造方法 (Composite blade with metal reinforcement and method of manufacturing the same ) 是由 D·弗洛蒙特尔 A·达洛 于 2019-07-30 设计创作，主要内容包括：一种复合叶片(100),包括在内端(110b)和外端(110a)之间在纵向方向(D<Sub>L</Sub>)上延伸的叶片本体(110)以及连接到叶片本体的内端或外端的至少一个紧固件基部(140、150)。叶片(100)包括与有机基质(300)相关联的金属加强件(200)。金属加强件(200)整体地限定为在叶片本体的内端和外端(110b、110a)之间延伸的纵向芯部(210)以及紧固件基部(140、150)的单个部件,纵向芯部具有包覆成型在其上的有机基质(300),有机基质限定叶片的外部形状。(A composite blade (100) comprising a longitudinal direction (D) between an inner end (110b) and an outer end (110a) L ) An upper extending blade body (110) and at least one fastener base (140, 150) connected to an inner or outer end of the blade body. The blade (100) comprises a metal reinforcement (200) associated with an organic matrix (300). The metal reinforcement (200) is integrally defined as a single piece of a longitudinal core (210) extending between the inner and outer ends (110b, 110a) of the blade body and a fastener base (140, 150), the longitudinal core having an organic matrix (300) overmoulded thereon, the organic matrix defining the outer shape of the blade.)

1. A composite blade comprising a blade body extending in a longitudinal direction between an inner end and an outer end and at least one fastener base connected to the inner end or the outer end of the blade body, the blade comprising a metal reinforcement associated with an organic matrix, wherein the metal reinforcement is integrally defined as a single part of the at least one fastener base and a longitudinal core extending between the inner end and the outer end of the blade body, the longitudinal core having an organic matrix overmoulded thereon, the organic matrix defining an outer shape of the blade, the composite blade further comprising at least one inner platform or outer platform formed from the organic matrix.

2. The blade of claim 1, wherein the metal reinforcement further comprises a protective portion forming a leading edge of the blade, the protective portion being integrally formed with the longitudinal core and the at least one fastener base.

3. The blade of claim 1, wherein the longitudinal core comprises one or more openings.

4. The blade of claim 1, comprising an inner fastener base connected to the inner end of the blade body and an outer fastener base connected to the outer end of the blade body, both defined by the metal stiffener and made integral with the longitudinal core.

5. A method of manufacturing a composite blade comprising a blade body extending in a longitudinal direction between an inner end and an outer end and at least one fastener base connected to the inner end or the outer end, the blade comprising a metal reinforcement associated with a metal matrix, wherein the method comprises making the metal reinforcement integrally defined as a single part of a longitudinal core extending between the inner end and the outer end and at least one fastener base connected to the inner end or the outer end of the longitudinal core, and overmolding an organic matrix on the metal reinforcement to define an outer shape of the blade.

6. The method of claim 5, wherein fabricating the metal stiffener further comprises forming a protective portion of a leading edge of the blade, the protective portion being integrally formed with the longitudinal core and the at least one fastener base.

7. The method of claim 5, wherein the longitudinal core comprises one or more openings.

8. The method of claim 5, wherein fabricating the metal stiffener includes forming an inner fastener base connected to the inner end of the longitudinal core and an outer fastener base connected to the outer end of the longitudinal core, the inner and outer fastener bases being integrally formed with the longitudinal core.

9. The method of claim 5, comprising forming at least one inner platform or at least one outer platform during overmolding of the organic matrix on the metal reinforcement.

10. Use of the method according to claim 5 for the manufacture of an outlet guide vane, an inlet guide vane or a variable guide vane.

Technical Field

The present invention relates to the general field of blades for gas turbine aeroengines and to a method for manufacturing them.

Background

Such blades can be fitted to any type of turbine engine, whether land or aeronautical, and by way of example to an aircraft turbojet or helicopter turboshaft engine. In particular, the vanes may be Outlet Guide Vanes (OGVs), Inlet Guide Vanes (IGVs) or Variable Stator Vanes (VSVs).

In the field of turbine engines, blades may be made of metal or composite materials. Document US2016/153295 describes the production of a composite blade having a metal core associated with an organic matrix, which forms the pressure side or suction side surface of the blade. Although such composite blades have the advantage of being lighter in weight than blades made entirely of metal, they need to be designed with special care since they are not as strong as metal blades. In particular, one or more portions of the blade for fastening it to the turbine engine need to exhibit good mechanical strength, since these portions transmit the aerodynamic forces to which the blade is subjected.

Disclosure of Invention

The main object of the present invention is therefore to provide a composite blade which is relatively light in weight, while still exhibiting good mechanical strength to accommodate aerodynamics, and exhibiting reliable fastening.

According to the invention, this object is achieved by a composite blade comprising a blade body extending in a longitudinal direction between an inner end and an outer end and at least one fastener base connected to the inner end or the outer end of the blade body, the blade comprising a metal reinforcement associated with an organic matrix, the blade being characterized in that the metal reinforcement is integrally defined as a single part of the at least one fastener base and a longitudinal core extending between the inner end and the outer end of the blade body, the longitudinal core having the organic matrix overmoulded thereon, the organic matrix defining the outer shape of the blade.

The metal reinforcement provides both stiffness for the blade and mechanical strength for its fastening. Thus, the metal reinforcement serves to substantially structure the composite blade, and in doing so the overall weight of the blade can be well controlled. In particular, the metallic material is only used to form the skeleton for imparting the desired structural function, wherein the remaining volume of the blade is occupied by the organic matrix, which essentially serves to define the aerodynamic profile of the blade and which presents a density lower than that of the metallic material.

According to a first particular feature of the blade according to the invention, the metal reinforcement further comprises a protection portion forming the leading edge of the blade, the protection portion being made integral with the longitudinal core and with said at least one fastener base. By integrating the leading edge in a metal reinforcement, the leading edge portion of the composite blade is reinforced, while the manufacturing of the blade is greatly simplified, in particular compared to manufacturing solutions comprising fitting metal sheets on a composite preform.

According to a second feature of the blade according to the invention, the longitudinal core comprises one or more openings. The openings serve to form anchor points for the organic matrix, thereby enhancing its mechanical retention on the reinforcement.

According to a third particular feature of the blade according to the invention, the blade comprises an inner fastener base connected to the inner end of the blade body and an outer fastener base connected to the outer end of the blade body, both the inner and outer fastener bases being defined by a metal reinforcement and being made integral with the longitudinal core.

According to a fourth particular feature of the blade according to the invention, the blade further comprises at least one inner or outer platform formed by the organic matrix.

The invention also provides a method of manufacturing a composite blade comprising a blade body extending in a longitudinal direction between an inner end and an outer end and at least one fastener base connected to the inner end or the outer end, the blade comprising a metal reinforcement associated with a metal matrix, the method being characterised in that it comprises making the metal reinforcement integrally defined as a single part of a longitudinal core extending between the inner end and the outer end and the at least one fastener base connected to the inner end or the outer end of the longitudinal core, and overmolding an organic matrix on the metal reinforcement to define an outer shape of the blade.

As mentioned above, the metal reinforcement provides rigidity to the blade. Thus, the shape of the stiffener can be optimized according to the characteristics of the metal material used and the desired operating conditions of the blade (such as the forces it will be subjected to, the vibration level, its resonant frequency, etc.).

The organic matrix used to define the outer shape of the blade serves to complete the manufacture of the composite blade while controlling its overall weight.

According to a first particular feature of the method according to the invention, the making of the metal reinforcement also comprises a protection portion forming the leading edge of the blade, the protection portion being integral with the longitudinal core and with the at least one fastener base. By making the leading edge directly from a metal reinforcement, the manufacture of the blade is greatly simplified, in particular compared to manufacturing solutions involving fitting of metal sheets on a composite preform.

According to a second particular feature of the method according to the invention, the longitudinal core comprises one or more openings. This serves to improve the retention of the matrix on the reinforcement.

According to a third particular feature of the invention, the making of the metal reinforcement comprises forming an inner fastener base connected to the inner end of the longitudinal core and an outer fastener base connected to the outer end of the longitudinal core, the inner and outer fastener bases being integrally formed with the longitudinal core.

According to a fourth particular feature of the method according to the invention, the method comprises forming at least one inner platform or at least one outer platform during the overmoulding of the organic matrix on the metal reinforcement.

The invention also provides the use of the method of the invention for producing composite blades for producing outlet guide blades, inlet guide blades or variable guide blades.

Drawings

Further features and advantages of the invention appear from the following description, given with reference to the accompanying drawings, which show embodiments without limiting features. In the drawings:

figures 1A and 1B are schematic perspective views of an outlet guide vane in an embodiment of the invention;

figures 2A and 2B are schematic perspective views of the metal reinforcement of the composite blade of figure 1;

figure 3 is a schematic perspective view showing the metal reinforcement of figures 2A and 2B in place in an injection mould;

figure 4 is a schematic perspective view showing the metal reinforcement of figures 2A and 2B in a closed injection mould;

figure 5 is a schematic perspective view showing the resin injected into the mould of figure 4; and

figure 6 is a cross-sectional view of the mould of figure 5 on the section VI-VI of figure 5.

Detailed Description

The invention is suitable for manufacturing composite blades for gas turbine aircraft engines.

Non-limiting examples of such vanes specifically include Outlet Guide Vanes (OGV), Inlet Guide Vanes (IGV), and Variable Stator Vanes (VSV), among others.

The method according to the invention has been described with reference to the manufacture of a composite outlet guide vane such as the vane 100 shown in fig. 1A and 1B, which vane comprises a longitudinal direction D between an inner end 110B and an outer end 110a _LUpper, transverse direction D between leading edge 111 and trailing edge 112 _TAn upper extending blade body 110. The blade body 110 also has a pressure side surface 113 and a suction side surface 114. The blade 100 also has an inner platform 130 connected to the inner end 110b of the blade body 110 and an outer platform 120 connected to the outer end 110a of the blade body 110. The blade 100 also has an inner fastener base 150 present in the inner platform 130, the inner fastener base 150 including fastener elements that enable the blade 100 to be fastened to an inner radial portion of an engine. By way of example, these fastener embodiments are two holes 151 and 152 for receiving fasteners, such as nut and bolt types. The blade 100 also has an outer fastener base 140 residing in the outer platform 120, the outer fastener base 140 including fastener elements that enable the blade 100 to be fastened to the outer radial portion of the engine. By way of example, these elements are two holes 141 and 142 for receiving fasteners, such as nuts and bolts.

According to the invention, the blade 100 comprises a metal reinforcement 200 integrally defined as a single piece of the longitudinal core 210, and the inner fastener base 150 is connected to an inner end 210b of the core 210 coinciding with the inner end 110b of the blade body 110, while the outer fastener base 140 is connected to an outer end 210a of the core 210 coinciding with the outer end 110a of the blade body 110. In the presently described example, the longitudinal core 210 is in the longitudinal direction D _LExtend upwards and comprise a central spar 211 connected to the inner 150 and outer 140 fastener bases, in the longitudinal direction D _LAnd a transverse direction D _TA curved portion 212 extending from the central spar 211 and defining a first opening 213, and a longitudinal directionD _LAn upwardly extending leading edge or projection 214. The leading edge portion 214 is connected to the central spar 211 at three points 214a, 214b and 214c so as to define a second opening 215 and a third opening 216. The leading edge portion 214 forms the leading edge 111 of the blade 100.

The number of openings may vary depending on the size of the blade and the loads to which it is subjected in operation.

Still according to the invention, the metal reinforcement 200 has an organic matrix 300 overmoulded thereon, the matrix in this example defining the aerodynamic shape of the blade 100, i.e. the pressure side surface 113 and the suction side surface 114 thereof, as well as the final shape of the inner platform 130 and the outer platform 120.

The method of manufacturing the composite blade 100 begins with the fabrication of a metal stiffener 200 as shown in fig. 2A and 2B. The metal reinforcement can be made using various known techniques, such as in particular: casting, molding and welding, electroerosion, or additive manufacturing. In particular, the metal reinforcement may be made of aluminum, titanium and alloys thereof or steel.

The method of manufacturing a composite blade continues by placing the metal reinforcement 200 in an injection mould, as shown in fig. 3. The injection mould 50 comprises a first housing 51 having a first cavity 511, the first cavity 511 corresponding to a part of the shape and size of the blade to be made, the cavity 511 being surrounded by a first contact plane 512. The first housing 51 further includes an injection port 510 for enabling the organic substrate to be injected. The mould 50 further comprises a second shell 52, the second shell 52 comprising in its centre a second cavity 521, the second cavity 521 corresponding to a portion of the shape and dimensions of the blade to be made, the second cavity 521 being surrounded by a second contact plane 522, the second contact plane 522 cooperating with the first contact plane 512 of the first shell 51. The second housing further comprises at least one vent 520 placed opposite the injection point for the purpose of venting gas during injection. The first and second housings may in particular be made of a metallic material, such as for example aluminium or steel.

The metal reinforcement 200 is initially positioned in the cavity 511 of the first housing 51, and then the second housing 52 is placed on the first housing 51 so as to close the injection mold 50, as shown in fig. 4. In this configuration, the first cavity 511 and the second cavity 521 together define an internal volume 53, the internal volume 53 having the shape of the blade to be made and in which the reinforcement 200 is present. In the presently described example, cavity 511 is used to form the pressure side of the blade, while cavity 521 is used to form the suction side of the blade. Cavities 511 and 521 also include portions to form the inner and outer platforms of the blade. Once the mold 50 has been closed, the resin 530 is injected into the interior volume 53 via the injection port 510 of the first housing 51, as shown in fig. 5. The vent 520 serves to discharge the gas gradually replaced by the resin 530. As can be seen in fig. 6, once the resin 530 is injected into all the internal volume 53, it fills all the remaining part of the internal volume 53 not yet occupied by the reinforcement 200, so as to define the aerodynamic profile of the blade and the inner and outer platforms.

The resin used may be chosen in particular from: thermoplastic polymer families such as Polyaryletherketones (PAEKs); thermoplastic polyimides such as Polyetherimide (PEI); the family of semi-aromatic polyamides; or the family of polyamides. The temperature rating and/or chemistry of the resin is selected based on the thermomechanical stress to which the component is to be subjected. Once the resin is injected throughout the internal volume 53, the resin is subjected to a thermal treatment at a temperature and for a duration determined in a known manner according to the nature of the resin used. This results in the blade 100 shown in fig. 1A and 1B.

The metal reinforcement may be coated in a bond primer layer prior to placement in the injection mold to improve adhesion of the organic matrix on the reinforcement. The adhesion primer may be a liquid or suspension deposited by means of a brush, a spray gun or any other technique suitable for forming a primer layer of a few microns in thickness on the surface of the metal reinforcement. By way of example, the one offered by the supplier Dow Corning can be used "

OFS6032 silane "primer.

In the presently described example, composite bucket 100 has an inner platform 130 and an outer platform 120. However, the composite blade of the present invention may have only a single platform, which may be an inner platform or an outer platform. In addition, the inner platform may be overmolded with a damping material such as polyurethane, particularly when the blade is small in size and is fastened to the turbine engine only via its outer fastener base. In this case, the inner platform of the blade is subjected to vibrations and movements damped by the material.

The blade of the invention may be provided with only an outer fastener base or only an inner fastener base.