FR2964427A1 - CARTRIDGE OF TURBOJET AND TURBOJET RECEIVING SUCH CARTERS - Google Patents

Abstract

Turbojet casing adapted to receive a plurality of blades, comprising means for hooking an end of each blade on the casing (21, 30), characterized in that the attachment means extend on one face of the housing opposite to the blades, the casing has orifices (26) to let the ends of the blades so that they can cooperate with the attachment means of the housing. Turbeactor comprising such a housing.

Description

The present invention relates to a turbojet casing adapted to receive a plurality of blades and a turbojet incorporating such casings. BACKGROUND OF THE INVENTION Annular housings comprising fastening means intended to cooperate with the ends of a blade are known. Various attachment means have been proposed. For example, the document US2009 / 0317246 recommends ends having a cylindrical platform forming a portion of the outer casing and carrying two fixing flanks, which leads to complex shapes to manufacture. The document US2009 / 0317246 recommends the joining of the blades together by means of a circular ring before mounting the assembly thus formed in the housing. This is a cumbersome solution to implement, requiring assembly tools. OBJECT OF THE INVENTION The object of the invention is therefore to propose a turbojet casing that is simple to produce and easy to assemble. BRIEF DESCRIPTION OF THE INVENTION To this end, there is provided a turbojet engine housing adapted to receive a plurality of blades, comprising means for attaching an end of each blade to the housing. According to the invention, the attachment means extend on one face of the housing opposite the blades, the casing has orifices for passing the ends of the blades so that they can cooperate with the attachment means of the housing. Such an arrangement makes it possible to obtain a casing that is simple to produce and easy to assemble. According to a preferred embodiment, the attachment means comprise an annular member extending around the housing, the casing comprising long fibers and thermoplastic resin, and the annular member being obtained by pultrusion and impregnated with a thermoplastic resin. weldable with the thermoplastic resin of the housing, the assembly being assembled by hot compaction. This gives the whole a strong cohesion. The invention also relates to a turbojet comprising at least one housing according to the invention and a plurality of blades each having an end connected to the housing. Preferably, in this turbojet engine, each of the blades comprises: an elongate one-piece front portion cut into a pultruded section comprising fibers bound by resin and forming a leading edge; an elongate, one-piece rear portion cut into a pultruded section comprising fibers bound by resin and forming a trailing edge; a skin cut from a resin-impregnated fiber fabric extending to cover side faces of the core and covering at least areas of the leading edge and the trailing edge contiguous to the central portion; at least one of the leading edge or the trailing edge has extensions which project from the web at least on one side of the blade, to carry hooking means cooperating with the means attachment of the turbojet casing. BRIEF DESCRIPTION OF THE DRAWINGS Other features and advantages of the invention will appear on reading the following description of particular embodiments of the invention in relation to the attached figures among which: FIG. 1 is a view top of a blade to be fixed to a housing according to the invention; - Figure 2 is a perspective view of the blade of Figure 1, the skin covering the soul of the blade being partially cut away; - Figure 3 is a perspective view of a first mode of attachment of the blade to a housing according to the invention; FIG. 4 is a perspective view of a second mode of fixing the blade to the casing according to the invention. DETAILED DESCRIPTION OF THE INVENTION Referring to Figures 1 and 2, the blade 1 which is illustrated here is a stator blade, intended to extend behind the fan of a turbojet engine. The blade 1 comprises a leading edge 2 which is here in the form of an elongate monobloc structure. The blade 1 further comprises a trailing edge 3 which is also in the form of an elongate monobloc structure. The leading edge 2 and the trailing edge 3 are cut in profiles obtained by pultrusion, preferably with placement of oblique fibers (so-called "pullbraiding" process). The profiles comprise fibers, for example carbon fibers, substantially disposed along a longitudinal axis to form an elongated body. Ideally, substantially 80% of the fibers are disposed along the longitudinal axis of the leading edge X and leakage Y and 20% of the fibers are disposed at an inclination of about 60 degrees to the longitudinal axis. These proportions and the arrangement of the fibers are given by way of example. The fibers are here impregnated with thermoplastic resin.

Between the leading edge 2 and the trailing edge 3 4 extends a core 4. A skin 5 here comprising two webs 5A, 5B obtained by cutting in a fiber fabric pre-impregnated with thermoplastic resin, extends from on both sides of the core 4 to cover the latter as well as zones 6, 7 of the leading edge 2 and the trailing edge 3 contiguous to the core 4. The faces of the core 4 not covered by the webs 5A, 5B forming free ends of the core 4 are here protected and reinforced by means of a mixture 22 of short fibers and resin inserted in a cavity defined by the webs 5A, 5B and the free edge of the web. 4. The leading edge 2 and the trailing edge 3 comprise extensions 10, 11, 12, 13 which protrude from the core 4 on each side of the blade 1.

The assembly of the various components of the blade 1 between them is made by hot compaction so as to secure the assembly. This type of assembly confers a great resistance to the whole of the blade 1. Finally, one carries out in the extensions 10, 11, 12, 13 orifices 14, 15, 16, 17 so as to transform these extensions into means hooking the blade 1 intended to cooperate with means of complementary attachment of a turbojet engine casing, as will now be detailed in connection with FIGS. 3 and 4. FIG. 3 represents a first method of attachment of the dawn 1 to an annular housing 20 of turbojet. (There is shown here the outer casing of the turbojet engine made of long fibers impregnated with thermoplastic resin). The housing 20 has orifices 26 for the passage through the casing 20 of the extensions 10, 12 of the leading edge 2 and the trailing edge 3. The orifices 26 are illustrated as being sufficiently extended to allow the extensions of the edges of the casing to pass. attack and escape through the same orifice. However, it will be possible alternatively to make the orifices in two parts, including an upstream orifice and a downstream orifice for passing respectively the leading edge and the trailing edge.

The casing 20 is equipped with fastening means leading edges which comprise a peripheral rail 21 which extends around the casing, on a face thereof opposite the blade. The rail 21 defines a housing adapted to receive the heads 24 of fasteners 23 in the general shape of T or L. One of these elements is here illustrated. The fastener 23 has an opposite end 25 opposite the head 24 which is cut to accommodate the extension of the leading edge. The fastening between the fastening element 23 and the extension 10 is here made by broaching. For this purpose, the end 25 has an orifice, not visible here, located opposite the orifice 14 of the extension 10 of the leading edge 2, to receive a fixing pin 27. The attachment of the extension 12 of the edge of 3 is similarly made by means of a second rail 21 ', in which a second fastening element 23' is engaged to cooperate with the extension 12 of the trailing edge 3, the whole being stitched with the aid of a pin 27 '. According to a preferred embodiment, the rails 21, 21 'and the fixing elements 23, 23' are made by pultrusion and are impregnated with thermoplastic resin thus allowing the assembly to be joined together by a single operation of hot compaction to the casing. 20. Figure 3 represents, moreover, only half of the blade 1. Here the end portions 11, 13 not visible are attached to an inner housing in a manner identical to that which has just been described. However, if the dawn has no structural function, the dawn may be fixed to only one of the housings. FIG. 4 illustrates a second mode of attachment of the blade 1 to a turbojet casing 20. Here, the attachment means comprise a peripheral angle 30 extending around the housing. The angle 30 extends on an opposite face of the housing 20 relative to the blade 1. The housing 20 has through holes 26 allowing the extensions of the leading and trailing edges of the blade to pass through the housing 20 to extend facing the angle 30. Preferably, the angle 30 is made by pultrusion and is impregnated with thermoplastic resin.

The angle 30 has an L-shaped section, a first face 28 is here fixed to the housing 20 by hot compaction and a second face 29 is fixed to the extension 10 by broaching. For this purpose, the face 29 of the angle 30 is pierced with an orifice coming opposite the orifice 114 formed in the extension 10 of the leading edge. It will be noted moreover that the orifice 114 is pierced perpendicularly to the orifice 14 of the previous embodiment. It will also be noted that the extension 10 has been machined to present an upright face bearing against the facing face of the wing 29. As in the previous example, the various elements of the housing are joined together by thermocompaction.

Furthermore, the extensions 11, 12, 13 of the leading edge 2 and the trailing edge 3, not shown, are fixed identically to a similar angle. The operation of fixing the blade 1 to the angle 30 is repeated as many times as blades are available.

In addition to their role in fixing the vanes by their extension of leading edge or trailing edge, it will be noted that the rails and angles also contribute to stiffening the turbojet engine casing.

Of course, the invention is not limited to the embodiments described above and are capable of variants that will occur to those skilled in the art without departing from the scope of the invention as defined by the claims.

In particular, the materials used for the production of the various elements 2, 3, 4, 5 of the blade 1 and the attachment means 21, 23, 27 can be composite materials as well as metallic materials or a combination both.

Similarly, the reinforcements 22, visible in Figure 2, capping the free ends of the core 4 may be replaced or supplemented by a folding of the skin of one or more webs 5A, 5B. In this case, the size of the webs 5A, 5B will be adjusted to provide a flap from covering the free end of the core. Similarly, the attachment means of the housing and those of the leading edge and leak can be joined together by hot compaction operations, welding, gluing or using screw / nut or any other solution ensuring the maintenance of these elements between them. In addition, the blades may have a different structure from that described and for example a monobloc structure.

Finally, although FIGS. 3 and 4 suggest identical fixing means to each of the extensions 10, 11, 12, 13 of the leading edge 2 and the trailing edge 3 according to two different embodiments, it is not necessary to contrary to the invention that each extension is fixed to the casing 20 according to one or other of the fixing means independently. Although here the attachment means comprise an annular member in the form of a rail or a peripheral angle extending around the housing, other attachment means could be envisaged, such as mounting brackets on which are fixed the ends of the blades after passing through the housing.

Claims (7)

REVENDICATIONS1. Turbojet casing adapted to receive a plurality of vanes, comprising means for attaching an end of each vane to the casing (21, 30), characterized in that the attachment means extend over one face of the vane housing opposite to the blades, the casing has orifices (26) to let the ends of the blades so that they can cooperate with the attachment means of the housing. 2. The housing of claim 1 wherein the attachment means comprises an annular member (21, 30) extending around the housing. 3. Carter according to claim 2, wherein the annular member comprises at least one rail (21) peripheral in which are inserted ends (24) of fasteners (23) of the ends of the blades. 4. Carter according to claim 2, wherein the annular member comprises a peripheral angle (30) on which are directly fixed the ends of the blades. 5. Carter according to claim 2, the latter being made of long fiber associated with a thermoplastic resin, while the annular member (21, 30) is obtained by pultrusion and impregnated with a thermoplastic resin weldable with the thermoplastic resin of the housing , the assembly being assembled by hot compaction. 6. Turbojet comprising at least one housing according to one of the preceding claims, and a plurality of blades each having an end connected to the housing. 7. Turbojet engine according to claim 6, wherein each of the blades comprises: - an elongate front portion (2) cut into a pultruded section comprising resin-bonded fibers and forming a leading edge; - An elongated rear portion (3) elongate cut in a pultruded section comprising resin-bonded fibers forming a trailing edge; - a central portion (4) forming a soul extending between the leading edge (2) and the trailing edge (3); a skin (5) cut from a resin-impregnated fiber fabric extending to cover lateral faces of the core (4) and covering at least areas (6, 7) of the leading edge (2) and trailing edge (3) contiguous to the central portion (4); at least one of the leading edge (2) or the trailing edge (3) has extensions (10, 11, 12, 13) which project from the web (4) at least one side of the blade (1), for carrying hooking means (14, 15, 16, 17) of the blade (1) cooperating with the fastening means of the housing (20) of the turbojet engine. 10 15