Classifications

• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
  • F02K—JET-PROPULSION PLANTS
  • F02K1/00—Plants characterised by the form or arrangement of the jet pipe or nozzle; Jet pipes or nozzles peculiar thereto
  • F02K1/04—Mounting of an exhaust cone in the jet pipe
• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
  • F02C—GAS-TURBINE PLANTS; AIR INTAKES FOR JET-PROPULSION PLANTS; CONTROLLING FUEL SUPPLY IN AIR-BREATHING JET-PROPULSION PLANTS
  • F02C7/00—Features, components parts, details or accessories, not provided for in, or of interest apart form groups F02C1/00 - F02C6/00; Air intakes for jet-propulsion plants
  • F02C7/28—Arrangement of seals
• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F05—INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
  • F05D—INDEXING SCHEME FOR ASPECTS RELATING TO NON-POSITIVE-DISPLACEMENT MACHINES OR ENGINES, GAS-TURBINES OR JET-PROPULSION PLANTS
  • F05D2260/00—Function
  • F05D2260/96—Preventing, counteracting or reducing vibration or noise
  • F05D2260/963—Preventing, counteracting or reducing vibration or noise by Helmholtz resonators

Definitions

• TITLE Ejection cone for aircraft turbine engine
• This document concerns an aircraft turbomachine cone, in particular an exhaust cone with a sealed acoustic box.
• This presentation concerns an assembly located at the rear, at the level of a downstream end, of an aircraft turbojet engine to optimize the flow of air expelled by the turbojet engine. More specifically, this presentation concerns the connection between what is often referred to as the exhaust cone and, located just upstream of the exhaust cone, a turbojet casing, for example a turbojet gas outlet casing.
• FIG. 1 represents an assembly for an aircraft turbojet, comprising a central gas ejection element, annular around a longitudinal axis X and adapted so that gas is ejected by the turbojet around it, from upstream (AM ) downstream (AV), said assembly being connected to a metal outlet of a turbojet.
• the aforementioned longitudinal axis X is the longitudinal axis, or axis of rotation, of the turbomachine, in particular of the fan 20 and of the moving blades of the engine 12.
• the central gas ejection element may correspond to the cone of ejection, marked 1 below, or at least at the upstream part 1a below.
• the aircraft gas turbojet engine 10 includes a central portion, forming the gas turbine engine 12, mounted within an engine nacelle assembly 14, as is typical of an aircraft designed for subsonic operation. , such as a turboprop or turbofan engine.
• the nacelle assembly 14 generally includes an engine nacelle 16 and a fan nacelle 18 surrounding a fan 20 located axially upstream of the engine 12.
• the engine 12 comprises, axially in the downstream part, at least one turbine which may be a low pressure turbine and, still in the downstream part, a metallic exhaust casing 22 and comprising an internal annular shroud 22a and an external annular shroud 22b delimiting between they are a downstream part of the primary annular vein 24 in which the combustion gases from the combustion chamber of the engine 12 circulate.
• at least one turbine which may be a low pressure turbine and, still in the downstream part, a metallic exhaust casing 22 and comprising an internal annular shroud 22a and an external annular shroud 22b delimiting between they are a downstream part of the primary annular vein 24 in which the combustion gases from the combustion chamber of the engine 12 circulate.
• the inner annular shroud 22a is connected, at its downstream end, to the ejection cone 1, which may comprise an upstream part 1a, of substantially cylindrical shape, and a downstream part 1b of conical shape.
• the inner annular shroud 22a is aligned with the outer wall of the ejection cone 1 to form a homogeneous air flow vein at the outlet of the engine 12.
• an acoustic box can be arranged inside the ejection cone, comprising acoustic partitions interposed between the outer wall of the ejection cone 1 and an internal annular wall of the outer wall, forming a cavity.
• the assembly of the acoustic partitions and the internal and external walls lacks sealing.
• a clearance exists between the partitions and the internal wall and/or the external wall.
• This clearance coupled with a pressure differential between the acoustic partitions creates an acceleration of the air around the acoustic partitions which generates a thermal gradient in the walls and limits their mechanical strength.
• the play must be less than 1 mm to respect the acoustic attenuation.
• This document relates to an exhaust cone for an aircraft turbine engine, extending along a longitudinal axis, said cone comprising a radially internal annular wall and a radially external skin delimiting a flow path for a primary flow of gas hot and surrounding the said internal annular wall, and partitions mounted radially between the external skin and the internal annular wall and intersecting so as to delimit with them acoustic boxes, characterized in that the said exhaust cone comprises at least one joint sealing arranged between a radial end of one of the partitions and at least one of the parts constituting the internal annular wall or the external skin.
• the seal limits the infiltration of air from the primary flow into the acoustic boxes. This improves the acoustic attenuation of the noise emitted by the turbomachine.
• the seal can be inserted between a radially outer end of the partition and the outer annular wall.
• the seal may be interposed between a radially inner end of the partition and the inner annular wall. This arrangement makes it possible to constrain the seal by the partition more effectively, in particular by the weight of the partition. This ensures better sealing of the acoustic box.
• the partitions can be fixed to the external skin or to the internal annular wall, for example by welding, by brazing or by screwing.
• the radially inner end can be arranged with radial play relative to the inner annular wall.
• the seal may comprise an O-ring part connected to a fastening strip.
• the fastening strip can be fixed to a downstream face of the partition and the toroidal part can be arranged at least in part against an upstream face of said partition.
• the O-ring part can thus be placed on the side where the maximum pressure is applied, which ensures the sealing of the seal on the internal annular wall.
• the fixing strip may have a thickness less than the radial play to allow the passage of the fixing strip between the radially inner end of the partition and the inner annular wall.
• the diameter of the toroidal part can be greater than the radial play to prevent the toroidal part from passing between the partition and the internal annular wall.
• the seal obstructs the radial play between the partition and the internal annular wall and thus makes it possible to seal the acoustic box.
• the fastening strip can be fixed to the partition by a locking wire passing through the orifices provided in said partition and said fastening strip.
• Small diameter holes can be made in the partition and the locking wire can pass on either side of the partition and the band like a seam.
• a button can be provided at the level of the upstream face of the partition to receive the locking wire and hold it in the locking position. This arrangement makes it possible to limit air leakage in the acoustic boxes if the holes have too large a diameter.
• the fastening strip can be fixed to the partition by riveting or by screwing, washers can be provided at the level of the rivets and/or the screws.
• the seal may comprise an upstream O-ring part and a downstream O-ring part.
• the upstream toroidal part can be arranged in contact with the upstream face of the partition and the downstream toroidal part can be arranged in contact with the downstream face of said partition.
• the diameter of the upstream toroidal part and/or the diameter of the downstream toroidal part may be less than the radial play.
• the upstream O-ring part and the downstream O-ring part can be connected by a brake wire passing through holes provided in the partition maintaining said seal.
• the seal can be arranged between the radially inner end of the partition and the inner wall.
• the upstream toric part and the downstream toric part of said seal can be connected by a connecting strip arranged under the radially inner end of the partition.
• the connecting strip can be held against the internal wall by said partition.
• the O-ring part(s) of the seal can be made by weaving or braiding ceramic and/or metal fibers.
• the upstream and downstream toric parts of the seal can be made by weaving or braiding ceramic and/or metallic fibers
• the seal may comprise an envelope made of high-temperature material produced by weaving, braiding or winding ceramic fibers or high-temperature metal fibers.
• the seal may comprise a central body surrounded by the casing made of the same material as the casing or of a strand of high-temperature fibers, for example refractory or silica fibers.
• the acoustic boxes can be formed by longitudinal partitions and circumferential partitions.
• the longitudinal partitions and the circumferential partitions can be mutually perpendicular.
• the longitudinal partitions and the circumferential partitions can be perpendicular to the internal annular wall.
• At least one, in particular each, of the acoustic boxes can be equipped with a seal, part of which extends along a side face of one of the longitudinal partitions forming said acoustic box and an upstream face of the downstream circumferential partition forming said acoustic box.
• This document also relates to a turbine engine for an aircraft comprising an ejection cone as mentioned above.
• FIG. 1 represents a sectional view of a turbomachine according to the prior art.
• FIG. 3 shows a sectional view of the upstream part of the discharge cone of figure 2.
• FIG. 4 shows an enlarged view of one end of one of the partitions of the acoustic structure of figures 2 and 3.
• FIG. 5 shows a front view of a first acoustic box of the acoustic structure of Figures 2 to 4.
• FIG. 6 shows a perspective view of the seal fitted to the first acoustic box in figure 5.
• FIG. 7 shows a front view of a second acoustic box of the acoustic structure of Figures 2 to 4.
• FIG. 8 shows a perspective view of a first seal fitted to the second acoustic box of figure 7.
• FIG. 9 shows a perspective view of a second seal fitted to the second acoustic box in figure 7.
• FIG. 10 shows an enlarged view of one end of one of the partitions of the acoustic structure equipped with a second embodiment of the seal.
• FIG. 11 shows an enlarged view of one end of one of the partitions of the acoustic structure equipped with a third embodiment of the seal.
• FIG. 12 shows an enlarged view of one end of one of the partitions of the acoustic structure equipped with a fourth embodiment of the seal.
• FIG. 2 represents an upstream part of an ejection cone which may be the ejection cone 1 of FIG. 1.
• FIG. 3 represents a sectional view of the upstream part of FIG. 2.
• This upstream part comprises a outer skin 102 annular around the longitudinal axis X.
• the outer skin 102 is made of ceramic matrix composite and surrounds an inner annular wall 104 which is also made of ceramic matrix composite.
• the outer skin 102 and/or the inner wall 104 are connected upstream to an exhaust casing, for example the exhaust casing 22, and downstream to a conical wall of the ejection cone by a flange connection 114.
• the outer skin 102 is fixed at its downstream part to the exhaust cone and is free at its upstream part and only the inner wall 104 is fixed upstream to the exhaust casing.
• Longitudinal partitions 106 and circumferential partitions 108 are arranged between the outer skin 102 and the inner wall 104.
• the partitions 106 and 108 extend substantially perpendicular to the inner wall 104.
• the longitudinal partitions 106 are also substantially perpendicular to the circumferential partitions 108 and form a honeycomb structure, comprising acoustic boxes 110 provided to attenuate the noise in the turbomachine.
• the longitudinal partitions 106 are fixed to the internal wall 104 by screws 130 through retaining brackets 132 which are also fixed to said longitudinal partitions.
• Each circumferential partition 108 is interposed circumferentially between two consecutive longitudinal partitions and said circumferential partition 108 is fixed on either side to said two consecutive longitudinal partitions.
• the assembly of the partitions to the internal wall 104 does not ensure sealing of the acoustic boxes because a radial play remains between a radially internal end 107 of the partitions 108, 106 and the internal wall 104. Part of the flow F of air passing through the turbomachine can infiltrate the acoustic boxes 110 through this radial play. Of moreover, this clearance impacts noise attenuation because the acoustic waves are no longer correctly channeled in the cell.
• a seal 112 is fitted to fill the radial play.
• Figure 4 shows the arrangement of the seal 112 with respect to the circumferential partition 108 but this arrangement may be applicable to the longitudinal partition 106.
• the seal 112 comprises an O-ring part 118 connected to a fastening strip 116
• the fixing strip 116 may have a rectangular section and is fixed to the downstream face of the circumferential partition 108 for example by rivets 120.
• the fixing strip 116 has a thickness less than the radial clearance between the end 107 and the wall internal 104.
• the end 107 of the circumferential 108 is in abutment against the toric part 118, in particular at the level of the junction between the toric part 118 and the fixing strip 116.
• the toric part 118 is arranged against the upstream face of the circumferential partition 108.
• the toroidal part 118 has a diameter greater than the radial clearance, so it is held in place.
• a first acoustic box 110 is shown in Figure 5 and includes a seal 112A, similar to the seal 112 of Figure 6.
• the first acoustic box 110 is formed by two longitudinal partitions 106 and a downstream circumferential partition 108 attached to each of the longitudinal partitions 106 at its circumferential ends.
• the 112A seal is made in a single part.
• the fixing strip 116 of the seal 112A has a shape complementary to the downstream surface of the circumferential partition 108 and part of the longitudinal partition 106.
• a first toric part 1181 of the seal 112 has a shape complementary to the upstream surface of the circumferential partition 108.
• a second O-ring part 1182 of the seal 112 is arranged at the level of the longitudinal partition 106.
• a second acoustic box 110 is represented in FIG. 7 and comprises the seal 112A of FIG. 8.
• the second acoustic box 110 is formed laterally by two longitudinal partitions 106.
• the second acoustic box 110 is formed upstream by a downstream circumferential partition 108 fixed to each of the longitudinal partitions 106 at its circumferential ends.
• the second acoustic box 110 is also formed upstream by a first circumferential partition 1081 and a second circumferential partition IO82 fixed to each other by a fixing to the internal wall 104 and to the longitudinal partitions.
• the first circumferential partition IO81 is equipped with the seal 112B and the second circumferential partition IO82 is equipped with the seal 112A.
• the gasket 112A is formed from a single gasket sector on which a specific cutout has been made to accommodate the geometry of the walls 1082 and 106.
• the gasket 112A when mounted in the acoustic box 110, has a shape complementary to the second circumferential partition IO82 and the longitudinal partition 106 adjacent to said second circumferential partition IO812.
• the seal 112A comprises a cutout 111A of the toric part 118 and thus allows the insertion of the seal 112A in the second acoustic box 110.
• the seal 112B is shown in Figure 9.
• the seal 112B comprises a single sector without cutting and which has a shape complementary to the downstream surface of the first circumferential partition 1081, when the seal 112B is mounted in the acoustic box 110.
• the seal 112, 112A or 112B comprises an envelope made of high temperature material produced by weaving, braiding or winding ceramic fibers and/or high temperature metal fibers.
• This casing surrounds a central body of the seal 112 made of the same material as the casing or of a strand of high-temperature fibers, for example refractory fibers or silica.
• a second example of a seal 212 is shown in FIG. 10.
• the seal 212 comprises a first O-ring part 214 arranged against an upstream face of the circumferential partition 108 and a second O-ring part 216 arranged against a downstream face of the circumferential partition 108.
• the first and second toric parts 214 and 216 each have a diameter greater than the radial clearance between the end 107 and the internal wall 104.
• the seal 212 comprises an envelope made of high temperature material produced by weaving , braiding or winding of ceramic fibers and/or high temperature metal fibers. This casing surrounds a central body of the seal 212 made of the same material as the casing or of a strand of high-temperature fibers, for example refractory fibers or silica.
• the first toric part 214 is connected to the second toric part 216 by a connecting strip 218 having a rectangular section.
• the connecting strip 218 is arranged between the end 107 and the internal wall 104.
• the connecting strip 218 has a thickness less than the radial play.
• gasket 212, gasket 312, and gasket 412 are described in relation to circumferential bulkhead 108 but may be arranged at a longitudinal bulkhead.

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• Engineering & Computer Science (AREA)
• Chemical & Material Sciences (AREA)
• Combustion & Propulsion (AREA)
• Mechanical Engineering (AREA)
• General Engineering & Computer Science (AREA)
• Gasket Seals (AREA)
• Exhaust Silencers (AREA)

Applications Claiming Priority (2)

Publications (1)

Family

ID=82196596

Family Applications (1)

Country Status (5)

Family Cites Families (9)

• 2022
  • 2022-03-02 FR FR2201806A patent/FR3133216B1/fr active Active
• 2023
  • 2023-03-02 WO PCT/FR2023/050282 patent/WO2023166266A1/fr not_active Ceased
  • 2023-03-02 US US18/843,154 patent/US20250188887A1/en active Pending
  • 2023-03-02 EP EP23714224.5A patent/EP4486986A1/de active Pending
  • 2023-03-02 CN CN202380025710.7A patent/CN118829784A/zh active Pending

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