TURBOFAN ENGINE COMPRISING AN OUTLET CONE COOLED BY ITS SECONDARY FLOW

Abstract

A turbofan engine including an exhaust casing traversed by a primary flow and surrounded by a secondary flow and an outlet cone carried by this exhaust casing, the exhaust casing and the outlet cone together defining an internal space. The exhaust casing includes a hollow radial arm traversing the primary flow in order to convey part of the secondary flow so as to form a cooling flow for supplying the internal space, and the outlet cone is terminated by an opening for discharging the cooling flow.

Claims

1-7. (canceled)

8. A turbofan engine including an exhaust casing (21) through which passes a primary flow (FP) and surrounded by a secondary flow (FS) both circulating from upstream (AM) to downstream (AV) of the turbofan engine during operation, and an outlet cone (23) having an upstream end (25) carried by this exhaust casing (21), the outlet cone (23) delimiting an inner space (E), wherein the exhaust casing (21) includes a hollow radial arm (38) crossing the primary flow (FP) which conveys part of the secondary flow (FS) in order to form a cooling flow (Fr) to cool down one or several component(s) located in the inner space (E), and in that the outlet cone (23) terminates in an opening (S) for discharging the cooling flow (Fr).

9. The turbofan engine according to claim 8, wherein the outlet cone (23) includes a main wall (41) and an inner lining wall (42) which runs along the main wall (41) while being spaced therefrom so as to delimit, together with this main wall (41), an inter-wall space (Ei), and wherein a portion of the cooling flow (Fr) passes through the inter-wall space (Ei) before being discharged by the outlet opening (S).

10. The turbofan engine according to claim 8, wherein the radial arm (38) terminates in a scoop soaking in the secondary flow (FS) to promote sampling of the cooling flow (Fr).

11. The turbofan engine according to claim 8, wherein the outlet (S) is formed by a cylindrical extension of the cone (23).

12. The turbofan engine according to claim 9, wherein the outlet (S) is formed by a cylindrical extension (43) of the main wall (41) and by a cylindrical extension (44) of the lining wall (42) which extends inside the cylindrical extension (43) of the main all (41).

13. The turbofan engine according to claim 8, comprising a low-pressure turbine (19) driving a central shaft (AC) via a planetary or epicyclic reduction gear (22), and wherein this reduction gear (22) is located in the inner space (E).

14. The turbofan engine according to claim 8, comprising a central shaft (AC) and a bearing (34) for holding this central shaft (AC) which is located in the inner space (E).

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0015] FIG. 1 is a longitudinal sectional view of a known turbofan engine;

[0016] FIG. 2 is a general schematic longitudinal sectional view of a turbofan engine architecture in which the invention is implemented;

[0017] FIG. 3 is a schematic longitudinal sectional view of a downstream portion of the turbofan engine architecture in which the invention is implemented;

[0018] FIG. 4 is a schematic longitudinal sectional view of cooling of the outlet cone according to the invention.

DETAILED DISCLOSURE OF PARTICULAR EMBODIMENTS

[0019] As schematically represented in FIG. 2, the engine according to the invention comprises a fan 13 at its upstream portion AM followed by a low-pressure compressor 14 which are driven by a central shaft AC, the fan being crossed by the entirety of the flow entering this engine comprising a central primary flow FP and a secondary flow FS surrounding the primary flow.

[0020] As it should now be clear, the upstream AM and downstream AV directions are defined with respect to the direction of circulation of the flow in the engine along its longitudinal axis AX, in accordance with usual conventions. Similarly, the inner and outer radial directions or positions are defined with respect to a central longitudinal axis AX of the engine.

[0021] In this engine, a high-pressure compressor 16 located immediately downstream AV of the low-pressure compressor 14 compresses the fluid of the primary flow having passed therethrough, before getting in a non-represented combustion chamber located downstream.

[0022] After having passed through the combustion chamber, the fluid expands in a high-pressure turbine 17 which drives the high-pressure compressor 16, this compressor 16 and the turbine 17 being carried by a high-pressure spool CH which surrounds the central shaft AC while being rotatably independent thereof.

[0023] After having passed through the high-pressure turbine 17, the fluid transits in an inter-turbine casing bearing the reference numeral 18 in FIG. 3, before passing through a low-pressure turbine 19, and is then discharged through an exhaust casing 21. This low-pressure turbine 19 is rotatably connected to the central shaft by an epicyclic reduction gear 22 located downstream AV, and thanks to which it rotates faster than the fan 13.

[0024] As shown in FIG. 3, the exhaust casing 21 carries an outlet cone 23 which closes the downstream region of the engine located radially inward of the primary flow path, that is to say the flow path within which the primary flow FP circulates, this outlet cone 23 extending downstream from an upstream end 25 by which it is carried by the casing 21.

[0025] The reduction gear 22 is located inside an inner space E delimited by the outlet cone 23 extending this casing 21, while being connected to the central shaft AC and to a rotor RB carrying the low-pressure turbine.

[0026] This rotor RB which surrounds the central shaft AC extends from a middle portion by which it carries the low-pressure turbine 19, up to a downstream portion by which it is coupled to the reduction gear 22. This rotor RB includes in its central region a radially-flexible element 24 which is soft according to the radial direction to enable off-centring of the upstream portion of the rotor RB with respect to its downstream portion while ensuring a torque transmission.

[0027] The low-pressure rotor RB is held by an upstream bearing 26 located upstream of the low-pressure turbine 19 and by a downstream bearing 27 located between this low-pressure turbine 19 and the flexible element 24. The rotor upstream bearing 26 is carried by the inter-turbine casing 18, and the rotor downstream bearing 27 is carried by the exhaust casing 21. At least one of the two rotor bearings 26 and 27 is a thrust bearing, that is to say taking up the axial thrust force generated by the low-pressure turbine to transfer it to the structure of the engine.

[0028] The reduction gear 22 includes planet pinions 28 surrounding an inner crown 29 and surrounded by an outer crown 33 while each of them meshes with these two crowns, these pinions 28 being carried by a planet carrier 32.

[0029] In this instance, the reduction gear 22 is of the epicyclic type, that is to say the planet carrier 32 is rotatably movable while being carried by the central shaft AC. In turn, the inner crown 29 is rigidly secured to the low-pressure rotor RB while the outer crown 33 is rigidly secured to the exhaust casing 21 while being carried thereby. This reduction gear 22 may also consist of a planetary reduction gear, wherein the planet carrier is carried by the exhaust casing, the outer crown then being carried by the central shaft.

[0030] The central shaft AC is carried by an upstream bearing, not shown in FIG. 3 and located at the upstream portion of the engine, and by a central shaft downstream bearing 34 located downstream of the reduction gear 22, while being carried by the exhaust casing 21, this downstream bearing 34 being located in the inner space E of the outlet cone 23.

[0031] In this general architecture, the reduction gear 22 as well as the downstream bearing 34 of the central shaft, which are installed in the space E, generate a significant amount of heat. To limit heating up of these components, this heat is dissipated thanks to the advantageous design of the exhaust casing 21 and of the outlet cone 23 carried thereby.

[0032] Thus, as shown in FIG. 4, at least one of the radial arms 38 of the exhaust casing 21, crossing the primary flow path within which the primary flow FP circulates, is hollow. This radial arm 38 is arranged so as to convey fresh air originating from the secondary flow FS which circulates within the secondary flow path towards the inner space E.

[0033] The cooling flow, denoted Fr, which is sampled in the secondary flow path, flows radially within the arm 38 towards the inner space E to ventilate it so as to dissipate the heat generated by the components such as the reduction gear 22 and the shaft bearing 34, the flow that ventilates this inner space being discharged by an outlet S at the downstream end of the cone 23. This outlet S is an opening formed at the central end of the cone 23.

[0034] To promote sampling of the cooling flow Fr in the secondary flow FS, the radial arm 38 advantageously terminates in a scoop 39 which projects radially from an outer face of the exhaust casing 21 in the secondary flow path, this scoop 39 including an opening directed upstream AM to collect air conveyed by the radial arm towards the inner space E.

[0035] To improve cooling, the cone 23 includes an outer main wall 41 and an inner lining 42, that is to say another wall that runs along its inner face while being at a short distance therefrom, in order to delimit an inter-wall space Ei within which part of the cooling flow Fr circulates. As shown in FIG. 4, the inner lining 42 runs along the inner face of the main wall 41 parallel thereto and over most of its surface.

[0036] More particularly, once the cooling flow Fr has covered the radial arm 38 and reached the cone 23, it is split into a first flow f1 directed towards the inner space E to ventilate it, and a second flow f2 which circulates in the inter-wall space Ei. These two flows f1 and f2 meet at the outlet S during their discharge out of the cone 23.

[0037] The inner lining 42 extends along most of the inner face of the main wall 41, and the flow f2 is injected at the upstream end AM of the cone 23 so as to run along most of the main wall 41 that is exposed to the hot primary flow FP, before being discharged by the outlet S. This circulation allows limiting, and evening suppressing, heating up of the components located in the inner space E by the primary flow FP coming out of the exhaust casing, which tends to heat up the main wall 41 by convection and by radiation.

[0038] In the example of FIG. 4, the outlet S is formed by a cylindrical extension 43 of the main wall 41, which extends at the downstream end AV of the cone 23. In turn, the lining wall 42 also terminates in a cylindrical extension 44 with a smaller diameter which extends inside the cylindrical extension 43. This arrangement ensures that the discharges of the flows f1 and f2 do not disturb each other.

[0039] In the example of the figures, the system for cooling the inner space E is intended to discharge heat generated by the downstream bearing 34 and/or by the reduction gear 22, but it may be adapted to optimise cooling of any other type of components installed in this inner space.