阅读说明：本技术 用于冷却飞行器涡轮喷气发动机的系统 (System for cooling an aircraft turbojet engine ) 是由 朱利安·科宾 让-尼古拉·布乔特 卡洛琳·当 于 2020-03-26 设计创作，主要内容包括：本发明涉及一种用于包括润滑剂(H)的涡轮喷气发动机类型的机舱(100),所述机舱包括冷却系统,所述冷却系统包括：-至少一个交换器(14),称为冷源交换器,位于传热流体(C)和空气(F)之间,-进入冷源交换器(12)的传热流体入口导管(18),-离开所述冷源交换器(12)的传热流体出口导管(20),入口导管(18)和出口导管(20)用于在冷源交换器(14)和位于传热流体与润滑剂之间的被称为热源交换器(12)的热交换器之间形成再循环回路,冷源交换器(14)相对于热源交换器布置在机舱的可移动表面上,并且传热流体入口导管和出口导管是可延伸的和/或柔性的,以允许容纳两个交换器之间的相对移动。(The invention relates to a nacelle (100) for a turbojet engine of the type comprising a lubricant (H), comprising a cooling system comprising: -at least one exchanger (14), called cold source exchanger, located between the heat transfer fluid (C) and the air (F), -a heat transfer fluid inlet conduit (18) entering the cold source exchanger (12), -a heat transfer fluid outlet conduit (20) leaving said cold source exchanger (12), the inlet conduit (18) and the outlet conduit (20) being intended to form a recirculation loop between the cold source exchanger (14) and a heat exchanger, called hot source exchanger (12), located between the heat transfer fluid and the lubricant, the cold source exchanger (14) being arranged on a movable surface of the nacelle with respect to the hot source exchanger, and the heat transfer fluid inlet conduit and the outlet conduit being extensible and/or flexible to allow the accommodation of the relative movement between the two exchangers.)

1. A nacelle (100) for a turbojet engine of the type comprising a lubricant (H), the nacelle (100) comprising an outer structure (103) and an inner structure (105) defining an annular flow path for the flow of a so-called secondary cold air flow, the outer structure (103) comprising an outer fairing defining an outer aerodynamic surface and an inner fairing defining an inner aerodynamic surface, the outer and inner fairings being connected upstream by a leading edge wall forming an air intake lip, the nacelle comprising a cooling system comprising:

-at least one heat exchanger (14), called cold source heat exchanger, located between the heat transfer fluid (C) and the air (F),

-a heat transfer fluid inlet conduit (18) into the cold source heat exchanger (12),

-a heat transfer fluid outlet conduit (20) leaving the cold source heat exchanger (12),

the inlet conduit (18) and the outlet conduit (20) are used to form a recirculation circuit between the cold source heat exchanger (14) and a heat exchanger, called hot source heat exchanger (12), located between the heat transfer fluid and the lubricant, the cold source heat exchanger (14) being arranged on a movable surface of the nacelle with respect to the hot source heat exchanger (12), and the heat transfer fluid inlet conduit (18) and heat transfer fluid outlet conduit (20) being extendable and/or flexible to allow accommodating the relative movement between the two heat exchangers (12, 14).

2. Nacelle (100) according to claim 1, wherein the cold source heat exchanger (14) is a surface heat exchanger.

3. Nacelle (100) according to claim 1 or 2, wherein said heat transfer fluid inlet duct (18) and said heat transfer fluid outlet duct (20) comprise at least one deployable device (22, 22', 22 ", 220) for accommodating a relative movement between said two heat exchangers (12, 14).

4. Nacelle (100) according to claim 3, wherein said deployable device is a telescopic tube (22').

5. Nacelle (100) according to claim 4, wherein said telescopic tube (22') is a telescopic tube comprising a plurality of stages.

6. Nacelle (100) according to claim 4, wherein said telescopic tube (22') is a telescopic tube comprising one single stage.

7. Nacelle (100) according to claim 3, wherein said deployable device is a bellows device (22 ").

8. Nacelle (100) according to claim 7, wherein the nacelle comprises a guiding system (32) for guiding the movability of the bellows arrangement.

9. Nacelle (100) according to claim 8, wherein the guide system (32) is a tube comprising at least two parts (32', 32 ") designed to slide into each other.

10. Nacelle (100) according to claim 8, wherein said guide system (32) is of the rail/slide type.

11. Nacelle (100) according to claim 3, wherein said deployable means are flexible conduits (220) adapted to be wound on themselves and to be deployed to accommodate the relative movement between said two heat exchangers (12, 14).

12. Nacelle (100) according to any of the preceding claims, wherein the nacelle comprises at least one thrust reverser and the cooling system comprises a first heat exchanger, called heat source heat exchanger, between a heat transfer fluid and a lubricant for the turbojet engine, a second heat exchanger, corresponding to the heat sink heat exchanger, between the heat transfer fluid and the air, the second heat sink heat exchanger being movable with respect to the first heat source heat exchanger, and the heat transfer fluid inlet duct and the heat transfer fluid outlet duct being extendable and/or flexible to allow accommodation of the relative movement between the two heat exchangers, the heat sink heat exchanger being arranged in the thrust reverser.

13. The nacelle (100) of claim 12, wherein said heat sink heat exchanger is a structural heat exchanger integral to said nacelle.

Technical Field

The present invention relates to the field of systems for cooling aircraft turbojet engines.

Background

The aircraft is propelled by one or more propulsion units, each of which comprises a turbojet engine housed in a nacelle. Each propulsion unit is connected to the aircraft by a pylon, which is usually located below or above a wing or at the height of the fuselage of the aircraft.

A nacelle generally has a tubular structure comprising an upstream section comprising an air intake upstream of the turbojet engine, an intermediate section intended to surround a fan of the turbojet engine, a downstream section adapted to house thrust reversal means and to surround a combustion chamber of the turbojet engine, and generally terminates in a nozzle, the outlet of which is located downstream of the turbojet engine.

Furthermore, the nacelle generally comprises an outer structure comprising a fixed part and a movable part (thrust reversal means), and an Inner Fixed Structure (IFS) concentric with the outer structure. The internal fixed structure surrounds the core of the turbojet engine at the rear of the fan. These external and internal structures define an annular flow path, also called secondary flow path, for guiding a so-called secondary cold air flow circulating outside the turbojet engine.

The outer structure includes an outer cowl defining an outer aerodynamic surface for contact with an outer airflow and an inner cowl defining an inner aerodynamic surface for contact with a secondary airflow. The inner and outer cowls are connected upstream by a leading edge wall forming an air inlet lip.

The thrust reverser allows redirecting all or part of the cold airflow circulating in the secondary flow path of the nacelle in front of the propulsion unit to generate a reverse thrust that participates in braking the aircraft.

Thrust reversal means should be understood as thrust reverser.

Such thrust reverser comprises thrust reversal movable structures, usually two thrust reversal movable structures, carried by the nacelle to move between a closed position (direct injection) in which the thrust reverser is inactive and an open position (reverse injection) in which the thrust reverser is active, that is to say it returns at least a portion of the cold air flow in the opposite direction to the flow generated by the turbojet engine. In particular, the movable structure of the known thrust reverser is translationally displaced along the axial direction of the turbojet engine during its transition to the open position. Such thrust reversers are known as cascade thrust reversers.

In the reverse injection position, the thrust reverser returns at least a portion of the cold airflow in the reverse direction of the airflow generated by the turbojet engine.

Generally, a turbojet engine comprises a set of blades (compressor and possibly an unducted fan or propeller) driven in rotation by a gas generator through a set of transmissions.

A lubricant distribution system is provided in the turbojet engine to ensure proper lubrication of these transmissions and to cool them.

The lubricant consists of oil. In the following description, the terms lubricant and oil will be used interchangeably.

A cooling system comprising at least one heat exchanger allows cooling of the lubricant.

There are cooling systems comprising an air/oil heat exchanger which cools the oil of the turbojet engine using cold air sampled in the secondary flow path of the nacelle or in one of the first compressor stages. This heat exchanger consists of a finned heat exchanger. It includes fins in the cold air stream that interfere with the flow of the air stream in the secondary flow path or in the compressor, which leads to a pressure drop (thrust) and therefore to a loss of performance of the aircraft in terms of fuel consumption (FB (fuel burn) parameter).

There are also cooling systems comprising an air/oil heat exchanger using cold air sampled from the outside of the nacelle or from inside the secondary flow path through vents provided respectively on the outside or inside cowlings of the nacelle, the cold air being guided to circulate through the heat exchanger and, once heated by the lubricant, being usable for deicing the nacelle by circulating in a duct arranged in contact with the wall of the external structure of the nacelle, for example at the level of the air intake lip. Such cooling systems allow a better control of the heat energy of the exchangers, but the presence of vents in the outer or inner cowls of the nacelle leads, in the same way as a finned heat exchanger, to a loss of aerodynamic performance and therefore of performance of the aircraft in terms of fuel consumption (FB (fuel burn) parameters).

A known solution for limiting the disturbances in the air flow, which disturbances produce performance losses in terms of fuel consumption of the aircraft, consists in providing a cooling system comprising a so-called heat source heat exchanger between a heat transfer fluid and engine oil, and a so-called heat sink heat exchanger between the heat transfer fluid and the air. Such cooling systems include a heat transfer fluid circulation conduit in a closed loop. More particularly, the heat transfer fluid circulation conduit comprises a portion arranged in the nacelle comprising a portion arranged in the nacelle in contact with the outer and/or inner cowls, said portion forming the heat sink heat exchanger. This is called a surface heat exchanger. Even more specifically, the portion arranged in the nacelle in contact with the inner and/or outer fairing comprises a plurality of channels arranged in parallel, said channels being formed by the double walls of the inner and/or outer fairing. This is the so-called structured heat exchanger.

Usually, the heat exchanger of the heat sink is located on a fixed part of the outer and/or inner structure of the nacelle and/or on a fixed part of the turbojet engine of the aircraft, for example on the cowling of the turbojet engine or on the air intake of the nacelle. In order to optimize the cooling performance of the turbojet engine, it is desirable to use other heat exchange surfaces to cool the heat transfer fluid, for example the surfaces of the movable parts. For example, it is advantageous to use a trailing edge located at the rear of the movable structure of the thrust reverser.

Disclosure of Invention

It is therefore an object of the present invention, inter alia, to provide a nacelle comprising a cooling system adapted to follow the relative movement of a movable surface with respect to a fixed surface.

To this end, the object of the invention is a nacelle for a turbojet engine of the type comprising a lubricant, the nacelle comprising an outer structure and an inner structure defining an annular flow path for the flow of a so-called secondary cold air flow, the outer structure comprising an outer fairing defining an outer aerodynamic surface and an inner fairing defining an inner aerodynamic surface, the outer and inner fairings being connected upstream by a leading edge wall forming an air intake lip, the nacelle comprising a cooling system comprising:

at least one heat exchanger, called cold source heat exchanger, located between the heat transfer fluid and the air,

-a heat transfer fluid inlet conduit into the cold source heat exchanger,

-a heat transfer fluid outlet conduit leaving the cold source heat exchanger,

the inlet and outlet conduits are used to form a recirculation loop between a cold source heat exchanger, which is arranged on a movable surface of the nacelle with respect to the heat source heat exchanger, and a heat exchanger between the heat transfer fluid and the lubricant (referred to as heat source heat exchanger), and the heat transfer fluid inlet and outlet conduits are extendable and/or flexible to allow accommodation of relative movement between the two heat exchangers.

Thanks to the nacelle according to the invention, the heat transfer fluid inlet and outlet conduits are adapted to enable relative movement between two heat exchangers arranged on surfaces opposite each other. The heat source heat exchanger may thus be arranged on a so-called fixed surface of the nacelle or turbojet engine, while the heat sink heat exchanger is arranged on a so-called movable surface of the nacelle, for example a thrust reverser.

A movable surface of the nacelle is understood to be a surface adapted to be displaced with respect to a so-called fixed surface of the nacelle and/or with respect to a so-called fixed surface of the turbojet engine.

According to other features of the invention, the nacelle of the invention comprises one or more of the following optional features, considered alone or according to any possible combination.

According to one feature, the cold source heat exchanger is a surface heat exchanger, for example constituted by a portion of a heat transfer fluid circulation conduit, arranged in contact with the inner and/or outer cowling of the nacelle.

According to one feature, the heat transfer fluid inlet and outlet conduits comprise at least one deployable device for accommodating relative movement between the two heat exchangers.

According to one embodiment, the expandable device is a telescopic tube.

The bellows ensure both a dynamic sealing function with respect to the circulation of the heat transfer fluid and a guiding function of the circulation conduit.

According to one feature, the telescopic tube is a telescopic tube comprising several stages.

Alternatively, the telescopic tube is a telescopic tube comprising one single stage. This is called a one stage telescoping tube.

According to one feature, the telescopic tube is rigid.

According to one feature, the telescopic tube is made of a metallic material, such as stainless steel, Inconel, aluminum or titanium.

According to one feature, the telescopic tube is made of a polymer material, such as Polyetheretherketone (PEEK), Polytetrafluoroethylene (PTFE) or a thermoplastic material.

In another embodiment, the expandable device is a bellows device.

A bellows arrangement is to be understood as a telescopic arrangement which ensures a sealing of the heat transfer fluid without the aid of parts which are movable relative to each other.

The bellows arrangement ensures a sealing function without the need for dynamic sealing with respect to the circulation of the heat transfer fluid. Furthermore, the bellows arrangement is only sensitive to misalignment between the fixed and movable structures.

According to one feature, the bellows arrangement is flexible.

According to one feature, the bellows arrangement is flexible.

According to one feature, the bellows arrangement is made of a metallic material, such as stamped stainless steel.

According to one feature, the bellows arrangement is made of a polymer material, such as Polyetheretherketone (PEEK), Polytetrafluoroethylene (PTFE), rubber or a thermoplastic material.

Advantageously, the nacelle comprises a guiding system intended to guide the movability of the bellows arrangement.

The presence of the guide means allows to avoid buckling of the bellows.

According to one feature, the guide system is a tube comprising at least two portions designed to slide into each other. The tube may be arranged inside the bellows arrangement or outside the bellows arrangement.

In one variant, the guide system is of the rail/slide type.

A rail/slide type guide system includes a rail and a slide that fit together.

In another embodiment, the expandable device is a flexible device adapted to be wound upon itself and adapted to expand to accommodate relative movement between the two heat exchangers. The deployable device is wound by the winding device.

According to one feature, the coiled catheter is flexible.

According to one feature, the coiled conduit is flexible.

According to a featureThe coiled catheter is made of a polymeric material, such as Polytetrafluoroethylene (PTFE). The catheter may be covered with a braided sheath made of a metallic material, such as stainless steel, or of a non-metal, such asThe woven sheath is made.

According to one feature, the nacelle comprises at least one thrust reverser and the cooling system comprises a first heat exchanger, called heat source heat exchanger, between the heat transfer fluid and the lubricant of the turbojet engine, a second heat exchanger, corresponding to the heat sink heat exchanger and between the heat transfer fluid and the air,

the second heat sink heat exchanger is movable relative to the first heat source heat exchanger, and the heat transfer fluid inlet and outlet conduits are extendable and/or flexible to allow accommodation of relative movement between the two heat exchangers, the heat sink heat exchanger being disposed in the thrust reverser.

According to one feature, the heat sink heat exchanger is a structural heat exchanger integral with the nacelle.

By structural heat exchanger is understood a heat exchanger integral with the nacelle, that is to say with a heat transfer fluid circulation duct formed by the double walls of the inner and/or outer cowling of the nacelle.

A double wall of the fairing is understood to mean that at least a part of the wall of the heat transfer fluid circulation conduit is formed by an outer or inner fairing of the nacelle.

Drawings

Further features and advantages of the invention will become apparent from reading the following non-limiting description and from the accompanying drawings, which schematically show several embodiments of the tubular structure according to the invention.

FIG. 1 is a schematic perspective view of a propulsion unit having a thrust reverser including a cooling system according to the present disclosure;

fig. 2 is a schematic view of a system for cooling a turbojet engine according to the invention;

FIG. 3 is a schematic view of a first embodiment of a deployable device of the cooling system of the present invention in a retracted position according to a first variation;

FIG. 4 is a schematic view of the deployable device of FIG. 3 in a deployed position;

FIG. 5 is a schematic longitudinal cross-sectional view of a first embodiment of a deployable device of the cooling system of the present invention in a retracted position according to a second variation;

FIG. 6 is a schematic longitudinal cross-sectional view of the deployable device of FIG. 5 in a deployed position;

FIG. 7 is a schematic longitudinal cross-sectional view of a second embodiment of a deployable device of the cooling system of the present invention;

FIG. 8 is a schematic longitudinal cross-sectional view of the second embodiment of the deployable device of FIG. 7 in a retracted position including a guide according to a first variation;

FIG. 9 is a schematic longitudinal cross-sectional view of the second embodiment of the deployable device of FIG. 8 in a deployed position;

FIG. 10 is a schematic longitudinal cross-sectional view of the second embodiment of the deployable device of FIG. 7 in a retracted position including a guide according to a second variation;

FIG. 11 is a schematic longitudinal cross-sectional view of the second embodiment of the deployable device of FIG. 10 in a deployed position;

FIG. 12 is a schematic longitudinal cross-sectional view of the second embodiment of the deployable device of FIG. 7 in a retracted position including a guide according to a third variation;

FIG. 13 is a schematic longitudinal cross-sectional view of the second embodiment of the deployable device of FIG. 12 in a retracted position;

FIG. 14 is a schematic longitudinal cross-sectional view of a third embodiment of a deployable device of the cooling system in accordance with the invention.

Detailed Description

For simplicity, like elements have like reference numerals throughout the drawings.

Fig. 1 shows an aircraft propulsion unit 1. The propulsion unit 1 comprises a nacelle 100, a reactor pylon 102 and a turbojet engine (not shown) housed inside the nacelle 100. The reactor pylon 102 is for fastening to a wing (not shown) or a fuselage (not shown) of an aircraft.

Nacelle 100 has a tubular structure comprising an upstream section 104 provided with a lip 106 forming an air intake, a middle section 108 intended to surround a turbojet engine fan (not shown), a downstream section 110 comprising a thrust reverser 112 and intended to surround the combustion chamber of the turbojet engine (not shown), and a jet nozzle 114 the outlet of which is located downstream of the turbojet engine (not shown).

Furthermore, the nacelle 100 comprises an outer structure 103, an inner structure 105, called Inner Fixed Structure (IFS), concentric with the outer structure 103. These outer structure 103 and inner structure 105 define an annular flow path for guiding a so-called secondary cold air flow (not shown) circulating outside the turbojet engine.

Thrust reverser 112 is shown in the direct injection position. The thrust reverser includes a sliding cowl that is translatable between a direct-injection position and a reverse-injection position (fig. 3-14).

Nacelle 100 includes a system 10 for cooling a turbojet engine (not shown). The cooling system 10 comprises a first heat exchanger 12, called heat source heat exchanger, between the heat transfer fluid C (fig. 2) and the lubricant H (fig. 2) of the turbojet, a second heat exchanger 14, called heat sink heat exchanger, between the heat transfer fluid C (fig. 2) and the air F, and a heat transfer fluid C circulation conduit 16 (fig. 2).

The heat sink heat exchanger 14 is disposed on the sliding housing of the thrust reverser 112 and the heat source heat exchanger 12 is disposed on the intermediate section 108. Accordingly, the cold source heat exchanger 14 may move relative to the hot source heat exchanger 12.

According to an embodiment not shown, the heat source heat exchanger 12 may be arranged on the surface of the turbojet engine.

The heat sink heat exchanger 14 consists of a structural surface heat exchanger integrated with the sliding housing of the thrust reverser 112. It comprises a plurality of ducts (not shown) formed by the double walls of the sliding cowl of the thrust reverser 112.

As shown in fig. 2, the circulation duct 16 is extendable to accommodate relative movement between the two heat exchangers 12, 14 during the transition of the sliding 1 enclosure from the direct injection position to the reverse injection position.

The extendable circulation conduit 16 is designed to perform a translational stroke between 300mm and 1000 mm.

The cooling system 10 is designed to withstand operating pressures comprised between 0 bar and 10 bar.

Fig. 2 shows a cooling system 10 comprising a heat source heat exchanger 12 between a heat transfer fluid C and a lubricant H, a heat sink heat exchanger 14 between the heat transfer fluid C and air F, and a heat transfer fluid C circulation conduit 16.

The heat transfer fluid C circulation conduit 16 is a closed loop. It includes an inlet conduit 18 for the heat transfer fluid C entering the cold source heat exchanger 14 and an outlet conduit 20 for the heat transfer fluid C exiting the cold source heat exchanger 14. The inlet conduit and the outlet conduit form a recirculation loop between the cold source heat exchanger and the hot source heat exchanger.

The heat transfer fluid inlet conduit 18 and the heat transfer fluid outlet conduit 20 include at least one deployable device 22 for accommodating relative movement between the two heat exchangers 12, 14.

The cooling circuit 10 comprises at least one circulation pump 40 for circulating the heat transfer fluid C.

The cooling circuit 10 further comprises an expansion vessel 50 for accommodating volume changes of the heat transfer fluid C due to temperature effects.

The expansion vessel 50 is a closed tank. Thus, the pressure within the expansion vessel 50 is directly related to the volume occupied by the heat transfer fluid within the expansion vessel. This feature advantageously allows controlling the maximum and/or minimum pressure in some parts of the circulation conduit 16 of the heat transfer fluid by acting only on the capacity (volume) of the expansion vessel 50.

Fig. 3 and 4 show a deployable device 22' according to a first variant of the first embodiment. In this first embodiment, the deployable device 22 'is a telescopic tube, more specifically in this first variant, the telescopic tube 22' has a single stage between the intermediate section 108 and the sliding cowl of the thrust reverser 112 of the nacelle in the retracted position (fig. 3) and in the deployed position (fig. 4).

Bellows 22' includes a first channel 24 and a second channel 26, one of the ends of first channel 24 being fastened to intermediate section 108 by mechanical fastener 222, and one of the ends of second channel 26 being fastened to the sliding hood of thrust reverser 112 by mechanical fastener 222. The mechanical fastener 222 may consist of a ball and socket joint or a universal joint. The first channel 24 has a larger cross-section s than the cross-section of the second channel 26, such that the second channel 26 is adapted to be retracted into the first channel 24.

In operation, according to the spacing d formed by the displacement of the sliding cowl of the thrust reverser 112, when the thrust reverser 112 is in the direct-injection position (fig. 3), the second channel 26 is retracted into the first channel 24, and when the thrust reverser 112 is in the reverse-injection position (fig. 4), the second channel 26 is expanded out of the first channel 24. Second channel 26 is movable in translation along the direction of arrow a, corresponding to the direction of translation of thrust reverser 112. The cooling system 10 thus accommodates the displacement of the cold source heat exchanger 14 with respect to the hot source heat exchanger 12 and enables the heat transfer fluid C to circulate in the bellows 22' during the change of position of the thrust reverser.

Fig. 5 and 6 show an expandable device 22 'according to a second variant of the first embodiment, wherein the expandable device 22' is a telescopic tube having several stages. In this example, the deployable device 22' is a telescopic tube having three stages between the intermediate segment 108 and the sliding cowl of the thrust reverser 112 of the nacelle in the retracted position (fig. 5) and in the deployed position (fig. 6).

The extension tube includes: a first channel 24' having one of its ends fastened to the intermediate section 108 by a mechanical fastener 222; the second 26' and third 28 channels, one of their ends, are fastened to the sliding cowl of the thrust reverser 112 by mechanical fasteners 222. The mechanical fastener 222 may consist of a ball and socket joint or a universal joint. The first channel 24' has a section S ' larger than the section S ' of the second channel 26' such that the second channel 26' is adapted to be retracted into the first channel 24', and the second channel 26' has a section S ' larger than the section e of the third channel 28 such that the third channel 28 is adapted to be retracted into the second channel 26 '.

In operation, according to the spacing d formed by the displacement of the movable cowl of the thrust reverser 112, when the thrust reverser 112 is in the direct-injection position (fig. 5), the second channel 26 'is retracted into the first channel 24' and the third channel 28 is retracted into the second channel 26', and when the thrust reverser 112 is in the reverse-injection position (fig. 6), the second channel 26' is deployed out of the first channel 24 'and the third channel 28 is deployed out of the second channel 26'. The second and third channels 26', 28 are movable in translation along the direction of the arrow a corresponding to the direction of translation of the thrust reverser 112. The cooling system 10 thus accommodates the displacement of the cold source heat exchanger 14 relative to the hot source heat exchanger 12 and enables the heat transfer fluid C to circulate in the bellows during the change of position of the thrust reverser.

Fig. 7 shows a deployable device 22 "according to a second embodiment. In this second embodiment, the deployable device 22 "is a bellows device.

The bellows arrangement 22 "has an accordion-like structure including a plurality of segments 30. One end of bellows arrangement 22 "is fastened to intermediate section 108 by way of mechanical fastener 222, and the opposite end of bellows arrangement 22" is fastened to the sliding cowl of thrust reverser 112 by way of mechanical fastener 222.

The bellows arrangement 22 "has an axis of axial symmetry a.

In operation, bellows arrangement 22 "is retracted when thrust reverser 112 is in the direct-injection position, and deployed when thrust reverser 112 is in the reverse-injection position.

The deployment of bellows device 22 "follows a translational displacement along the direction of the arrow a corresponding to the translational direction of thrust reverser 112.

Fig. 8 and 9 show a bellows device 22 "and a guide device 32 according to a first variant.

The guide device 32 allows for guiding the deployment and retraction of the bellows device 22 "and prevents buckling of the bellows device during the transition of the thrust reverser to the direct injection position. The guide 32 is a tube comprising at least two portions, called first portion 32' and second portion 32 ", designed to slide into each other.

The first portion 32 'has one end secured to the sliding cowl of the thrust reverser 112 by mechanical fasteners 320 and an opposite end slidably secured to the second portion 32'.

The second portion 32 "has one end secured to the movable cowl of the thrust reverser 112 by mechanical fasteners 320 and an opposite end slidably secured to the first portion 32'.

Thus, the first portion 32' and the second portion 32 "are designed to slide into each other.

In this first variant, the bellows arrangement 22 "is arranged inside the tube 32.

In a second variant, the tube 32 as previously described is arranged inside the bellows device 22 "(fig. 10 and 11).

Fig. 12 and 13 show a bellows arrangement 22 "and a guide arrangement 32 according to a third variant. In this variant, the guide means 32 comprise a slide 326 and a guide rail 325.

Each segment 30 of bellows arrangement 22 "is coupled to a slide 326. According to the spacing d formed by the displacement of the movable cowl of the thrust reverser 112, the slide 326 is retracted into the guide track 325 when the thrust reverser 112 is in the direct-injection position (fig. 12), and the slide 326 is deployed out of the guide track 325 when the thrust reverser 112 is in the reverse-injection position (fig. 13). The bellows means and the guide means extend translationally along the arrow direction a corresponding to the translational direction of the thrust reverser.

In a variant not shown, only some of the segments 30 of bellows arrangement 22 "are coupled to slide 326.

Fig. 14 shows a deployable device 220 according to a third embodiment. In this third embodiment, the expandable device 220 is a flexible conduit adapted to be wound upon itself and adapted to expand to accommodate relative movement between the two heat exchangers 12, 14.

In operation, when thrust reverser 112 is in the direct-jet position, flexible conduit 220 is coiled, and when thrust reverser 112 is in the reverse-jet position, flexible conduit 220 is uncoiled. The flexible conduit 220 is wound by a winding device 221. Guiding of the flexible conduit 220 is ensured by tensioning the flexible conduit 220 at the height of the winding device 221, and during conversion of the thrust reverser into direct injection, an optimal winding of the flexible conduit 220 can be achieved. In the various embodiments just described, the nacelle has extendable inlet and outlet ducts that allow accommodating the relative movement of the movable surface with respect to the fixed surface.

In a variant not shown, the circulation duct is flexible to accommodate the relative movement between the two heat exchangers during the transition of the sliding cowl from the direct injection position to the reverse injection position.

Of course, the invention is not limited to the examples just described, and many modifications may be made to these examples without departing from the scope of the invention. In particular, the different features, shapes, variants and embodiments of the invention can be associated with each other according to various combinations, as long as these are not incompatible or mutually exclusive.