阅读说明：本技术 短舱、旁通式涡轮喷气发动机和飞行器 (Nacelle, bypass turbojet and aircraft ) 是由 斯里康德·加纳帕蒂拉朱 伯努瓦·奥特乌 洛朗·卡佐 奥列弗·德努伊 于 2020-02-17 设计创作，主要内容包括：本发明涉及短舱、旁通式涡轮喷气发动机和飞行器,短舱包括：固定结构,固定结构具有固定整流罩；可移动整流罩,可移动整流罩能在关闭位置与打开位置之间以平移的方式移动,在打开位置,管道与外部之间打开开口；阻挡门,阻挡门能在可移动整流罩上在收起位置与展开位置之间以旋转的方式移动；及展开系统,展开系统包括：臂,臂具有铰接在阻挡门上的第一端部以及承载止挡件的第二端部；滑动件,滑动件固定到臂；线性引导系统,线性引导系统固定在固定结构上并且引导滑动件；及凸块,止挡件被布置成当可移动整流罩从关闭位置到达中间位置时抵靠凸块,且当可移动整流罩从中间位置移动到打开位置时被凸块以如下方式引导,即,以便驱动臂绕滑动件旋转。(The invention relates to a nacelle, a bypass turbojet and an aircraft, the nacelle comprising: a fixed structure having a fixed cowl; a movable cowl movable in translation between a closed position and an open position, in which an opening is opened between the duct and the outside; a blocking door rotatably movable on the movable cowl between a stowed position and a deployed position; and a deployment system, the deployment system comprising: an arm having a first end hinged on the stop door and a second end carrying a stop; a slider fixed to the arm; a linear guide system fixed to the fixed structure and guiding the slide; and a cam against which the stop is arranged to abut when the movable cowl reaches the intermediate position from the closed position and is guided by the cam when the movable cowl moves from the intermediate position to the open position in such a manner as to drive the arm to rotate about the slider.)

1. A nacelle (102) for a bypass turbojet engine (100), the nacelle (102) comprising:

-a fixed structure (101) comprising a fixed fairing (206);

-a movable cowl (207) movable in translation with respect to the fixed cowl (206) in a translation direction parallel to the longitudinal axis X between a closed position, in which it is close to the fixed cowl (206), and an open position, in which it is distanced towards the rear from the fixed cowl (206), so as to define an opening (210) between the movable cowl and the fixed cowl, the opening being located between a duct (202) for a secondary flow (208) and the outside of the nacelle (102);

-drive means designed to move said movable cowling (207) from said closed position to an intermediate position and then to said open position and vice versa,

-a blocking door (104) mounted so as to be movable in rotation about an axis of rotation (50) on said movable cowling (207) between a stowed position in which it is positioned outside said duct (202) and a deployed position in which it crosses said duct (202); and

-a deployment system (150, 650) arranged to coordinate and delay the transition of the barrier door (104) from the stowed position to the deployed position with respect to the transition of the movable cowl (207) from the closed position to the open position, and vice versa, the deployment system (150, 650) comprising:

-an arm (162) comprising a first end mounted in an articulated manner on the blocking door (104) and a second end carrying a stop (154);

-a slider (156) fixed to the arm (162);

-a linear guide system (152) fixed on the fixed structure (101) and guiding the slide (156) parallel to the translation direction; and

-a cam (158, 658), wherein the stop (154) is arranged to abut against the cam (158, 658) when the movable cowl (207) reaches the intermediate position from the closed position, and to be guided by the cam (158, 658) when the movable cowl (207) moves from the intermediate position to the open position, in such a way as to drive the arm (162) in rotation about the slide (156) about a deployment axis (160) parallel to the rotation axis (50).

2. A nacelle (102) according to claim 1, wherein the guiding system (152) is a groove in which the slide (156) moves, the groove being closed at its rear end, and the position of the closed rear end being defined in such a way that the slide (156) comes to abut against the closed rear end at the same time as the stop (154) comes to abut against the cam (158, 658).

3. A nacelle (102) according to one of claims 1 or 2, wherein the articulation of the arm (162) on the blocking door (104) is arranged on the rear face of the blocking door (104).

4. A nacelle (102) according to any of claims 1 to 3, wherein the projection (158) is mounted fixed to the fixed structure (101) and comprises a groove in the form of a circular arc.

5. A nacelle (102) according to any of claims 1 to 3, wherein the projection (658) is mounted so as to be movable in a rotary manner on the fixed structure (101) about a swing axis (660) parallel to the rotation axis (50) between a first position corresponding to the stowed position and a second position corresponding to the deployed position, and the projection (658) has a first groove (662) in the form of an L, a first branch of which is generally parallel to the longitudinal axis X and a second branch of which is generally radial with respect to the longitudinal axis X.

6. A nacelle (102) as claimed in claim 5, wherein the deployment system (650) further comprises a return element (664) urging the tab (658) to the first position.

7. A nacelle (102) according to one of claims 5 or 6, wherein the bump (658) further comprises a second groove (667) in the form of an arc of a circle centred on the deployment axis (660), and the slide (156) is arranged to move in the second groove (667) when the bump (658) is pivoted from the first position to the second position.

8. A bypass turbojet engine (100) comprising an engine and a nacelle (102) surrounding the engine according to one of the preceding claims and wherein the duct (202) is defined between the nacelle (102) and the engine.

9. An aircraft (10) comprising at least one bypass turbojet engine (100) according to the preceding claim.

Technical Field

The present invention relates to a nacelle of a bypass turbojet engine comprising at least one blocker door and a deployment system, to a bypass turbojet engine comprising such a nacelle and an engine, and to an aircraft comprising at least one such bypass turbojet engine.

Background

The aircraft comprises a fuselage, and wings are fixed on two sides of the fuselage. At least one bypass turbojet is suspended below each wing. Each bypass turbojet is fixed under the wing by means of a suspension pylon fixed between the structure of the wing and the structure of the bypass turbojet.

A bypass turbojet engine comprises an engine, a nacelle fixed around the engine, and a secondary duct located between the engine and the nacelle and allowing the secondary flow to pass through.

The nacelle comprises a fixed cowl and a movable cowl aft of the fixed cowl and movable in translation between a closed position and an open position. In the closed position, the movable cowl is adjacent to the fixed cowl and forms an aerodynamic continuity. In the open position, the movable cowl is moved away from the fixed cowl toward the rear and opens an opening between the secondary duct and the outside.

The nacelle also includes at least one blocker door movable between a stowed position in which the blocker door is positioned outside the secondary duct in a manner that does not obstruct the secondary flow, and a deployed position in which the blocker door is positioned across the secondary duct in a manner that obstructs the secondary flow so as to direct the secondary flow radially across the opening toward the exterior of the nacelle.

Conventionally, the blocking doors are mounted so as to be movable in a rotating manner on the structure of the nacelle and the deployment system moves the blocking doors from the stowed position to the deployed position and vice versa when the movable cowling is transferred from the closed position to the open position. The deployment system may include a connecting rod disposed in the secondary duct that requires a cut-out in the blocking door to allow the connecting rod to pass through as the blocking door moves.

Although the deployment system of such a barrier door is entirely satisfactory, it is desirable to find different deployment systems, and in particular to find deployment systems that are less bulky and do not include connecting rods in the secondary ducts.

Disclosure of Invention

The object of the present invention is to propose a nacelle comprising at least one blocking door and a deployment system.

To this end, a nacelle for a bypass turbojet engine is proposed, said nacelle comprising:

-a fixed structure comprising a fixed fairing;

-a movable cowl movable in translation with respect to the fixed cowl in a translation direction parallel to the longitudinal axis X between a closed position, in which the movable cowl is close to the fixed cowl, and an open position, in which the movable cowl is distanced from the fixed cowl towards the rear, so as to define an opening between the movable cowl and the fixed cowl, the opening being located between the duct for the secondary flow and the outside of the nacelle;

-drive means designed to move said movable cowling from said closed position to an intermediate position and then to said open position and vice versa;

-a blocking door mounted so as to be movable in rotation about an axis of rotation on the movable cowl between a stowed position in which it is positioned outside the duct and a deployed position in which it crosses the duct; and

-a deployment system arranged to coordinate and delay the transition of the barrier door from the stowed position to the deployed position and vice versa with respect to the transition of the movable cowl from the closed position to the open position, the deployment system comprising:

-an arm comprising a first end mounted in an articulated manner on the blocking door and a second end carrying a stop;

-a slide fixed to the arm;

-a linear guide system fixed on the fixed structure and guiding the slide parallel to the direction of translation; and

-a cam, wherein the stop is arranged to abut against the cam when the movable cowl reaches the intermediate position from the closed position and is guided by the cam when the movable cowl moves from the intermediate position to the open position in such a way as to drive the arm in rotation about the slide about a deployment axis parallel to the rotation axis.

This arrangement makes it possible to dispense with a connecting rod in the duct, thereby reducing its overall bulk. Furthermore, deployment of the blocking doors is delayed relative to movement of the movable cowling.

Advantageously, the guide system is a groove in which the slider moves, the groove having a closed rear end, and the position of the closed rear end being defined in such a way that the slider comes to abut against the closed rear end at the same time as the stop comes to abut against the cam.

Advantageously, the articulation of the arm on the blocking door is arranged on the rear face of the blocking door.

Advantageously, said projection is mounted fixed on said fixed structure and comprises a groove in the form of a circular arc.

Advantageously, the lug is mounted so as to be movable in a rotary manner on the fixed structure about an axis of oscillation parallel to the axis of rotation between a first position corresponding to the stowed position and a second position corresponding to the deployed position, and has a first groove in the form of an L, a first branch of which is generally parallel to the longitudinal axis X and a second branch of which is generally radial with respect to the longitudinal axis X.

Advantageously, the deployment system further comprises a return element urging the tab in the first position.

Advantageously, the lug further comprises a second groove in the form of an arc of a circle centred on the deployment axis, and the slider is arranged to move in the second groove when the lug pivots from the first position to the second position.

The invention also proposes a bypass turbojet engine comprising an engine and a nacelle surrounding the engine according to one of the preceding variants, and in which the duct is defined between the nacelle and the engine.

The invention also proposes an aircraft comprising at least one bypass turbojet according to the previous variant.

Drawings

The above-mentioned and other features of the invention will become more apparent upon reading the following description of exemplary embodiments, which description is given with reference to the accompanying drawings, in which:

figure 1 is a side view of an aircraft comprising a nacelle according to the invention,

figure 2 is a side and cross-sectional view of a nacelle according to the invention in a closed position and a stowed position,

figure 3 is a view similar to the view of figure 2 but in an open position and a deployed position,

figure 4 is an enlarged view of the deployment system according to the first embodiment of the invention and corresponding to detail IV in figure 2,

figure 5 is an enlarged view of the deployment system according to the first embodiment of the invention and corresponding to detail V in figure 3,

FIG. 6 is an enlarged view similar to the enlarged view of FIG. 4 of a deployment system in accordance with a second embodiment of the invention in a stowed position, and

FIG. 7 is an enlarged view of a deployment system according to a second embodiment of the present invention in a deployed position.

Detailed Description

In the following description, the terms referring to position are referenced to an aircraft in a forward travel position as shown in fig. 1.

Fig. 1 shows an aircraft 10 comprising a fuselage 12 to both sides of which are fixed wings 14 carrying at least one bypass turbojet 100 according to the invention. The bypass turbojet 100 is fixed under the wing 14 by means of a pylon 16.

In the following description, and by convention, X denotes a longitudinal axis of the bypass turbojet engine 100, which is parallel to the longitudinal axis of the aircraft 10 and is oriented positively in the direction of forward movement of the aircraft 10, Y denotes a transverse axis of the bypass turbojet engine 100 which is horizontal when the aircraft is on the ground, and Z denotes a vertical axis when the aircraft is on the ground, these three directions X, Y and Z being orthogonal with respect to each other. In the rest of the description, the terms "front" and "rear" will be considered with respect to the direction of movement of the aircraft, represented in fig. 1 by the arrow Av.

Fig. 2 and 3 show a bypass turbojet engine 100 comprising a nacelle 102 and an engine housed inside nacelle 102. The bypass turbojet 100 has a duct 202 between the nacelle 102 and the engine through which a secondary flow 208 circulates.

The engine is embodied here by its flow guide 103.

Nacelle 102 includes at least one blocker door 104. In particular, there may be two blocking doors 104 arranged facing each other, or four blocking doors 104 regularly distributed on the circumference of the nacelle 102. Each blocker door 104 makes it possible to reverse the thrust of the bypass turbojet engine 100 according to its position.

In the following description, the present invention is described more specifically for the case of one barrier gate 104, but when there are a plurality of barrier gates, the present invention is applied to each barrier gate 104 in the same manner.

For each blocker door 104, the nacelle 102 has an opening 210 (FIG. 3) that opens between the duct 202 and the exterior of the nacelle 102.

Nacelle 102 has a fixed fairing 206 delimiting an opening 210 in front with respect to longitudinal axis X and mounted to be fixed on fixed structure 101 of nacelle 102.

The nacelle 102 has a movable cowl 207 delimiting an opening 210 at the rear with respect to the longitudinal axis X. The movable cowl 207 is mounted so as to be movable in translation on the fixed structure 101 and therefore with respect to the fixed cowl 206, in a translation direction generally parallel to the longitudinal axis X. Translation is achieved by any suitable means, such as a slide.

Fixed fairing 206 and movable fairing 207 each have an outer surface that forms the outer skin of nacelle 102 and an inner surface that forms the outer wall of duct 202. The flow guide 103 of the engine constitutes the inner wall of the conduit 202.

The movable cowl 207 is movable between a closed position (fig. 2), in which it is close to the fixed cowl 206, and an open position (fig. 3), in which it is distanced from the fixed cowl 206 towards the rear in such a way as to enlarge the opening 210. The direction of movement from the closed position to the open position is shown by arrow 52.

The nacelle 102 also comprises drive means for moving the movable cowling 207 from the closed position to the open position and vice versa, and which may for example comprise a ram, a ball screw, a motor or any other suitable means for moving the elements in a translational manner. The drive means are commanded by a control unit of the processor type which, for example, extends and shortens the rams according to the requirements of the aircraft 10.

The blocking doors 104 are mounted so as to be movable on the movable cowl 207 in a rotating manner about the rotation axis 50 between a stowed position (fig. 2) and a deployed position (fig. 3), in which case the thrust reversal is most effective. In the embodiment of the invention shown in fig. 2 and 3, the axis of rotation 50 is perpendicular to the longitudinal axis X. Here, the axis of rotation 50 is at the front edge of the blocker door 104. The direction of rotation between the stowed and deployed positions is shown by arrow 54.

The rotation axis 50 lies in a plane substantially perpendicular to the radial direction with respect to the longitudinal axis X.

In the stowed position, the blocker doors 104 are positioned outside of the duct 202. In the open position, the movable cowl 207 is moved toward the rear to facilitate maneuvering the blocker doors 104 from the stowed position to the deployed position.

When the blocker doors 104 are in the deployed position, the blocker doors 104 traverse the duct 202 and deflect at least a portion of the secondary flow 208 outward through the opening 210. In the deployed position, the free edge of the blocker door 104 is adjacent to the engine's deflector 103. In FIG. 3, blocker door 104 is lowered in the deployed position.

The transition of the blocker doors 104 from the stowed position to the deployed position is coordinated and delayed with respect to the transition of the movable cowling 207 from the closed position to the open position, and vice versa.

Upon transitioning from the stowed position to the deployed position, blocker door 104 begins to rotate as moveable cowl 207 passes through an intermediate position between the closed position and the open position. Conversely, when transitioning from the deployed position to the stowed position, blocker door 104 stops rotating as moveable cowl 207 returns from the open position toward the closed position past the intermediate position.

This coordination and this bias is provided by the deployment system 150, 650. Fig. 4 and 5 illustrate a deployment system 150 according to a first embodiment of the present invention, and fig. 6 and 7 illustrate a deployment system 650 according to a second embodiment of the present invention.

In both embodiments, the deployment system 150, 650 comprises:

an arm 162 comprising a first end mounted in a hinged manner on the blocking door 104 and a second end carrying the stop 154;

a slide 156 fixed to the arm 162;

a linear guide system 152 fixed on the fixed structure 101 and guiding the slide 156 parallel to the direction of translation; and

-a knob 158, 658, wherein the stop 154 is arranged to abut against the knob 158, 658 when the movable cowl 207 reaches the intermediate position from the closed position, and to be guided by said knob 158, 658 when the movable cowl 207 moves from the intermediate position to the open position, in such a way as to drive the arm 162 in rotation about the slider 156 about the deployment axis 160 parallel to the rotation axis 50.

Throughout manipulation from the closed/stowed position to the open/deployed position, the slider 156 is still guided by the guide system 152, and vice versa.

Thus, the deployment system 150, 650 remains outside the conduit 202.

The deployment system 150, 650 is arranged aft of the rotation axis 50 and the blocking door 104 and facing outward with respect to the duct 202, i.e. generally in the movable cowl 207.

Here, the guide system 152 is a groove in which the slider 156 moves, and here, the groove is closed at its rear end to prevent the slider 156 from exiting, and thus facilitate rotation when the slider 156 reaches the closed rear end. The position of the closed rear end is thus defined such that the slide 156 comes to abut against the closed rear end at the same time as the abutment stop 154 comes to abut against the projections 158, 658.

The articulation of the arm 162 on the blocker door 104 is arranged on the rear face of said blocker door 104 (i.e. the face oriented towards the rear when the blocker door 104 is in the deployed position).

As the movable cowl 207 moves from the closed position to the open position, the slide 156 is guided by the guide system 152 and the blocker door 104 remains stationary as long as the stop 154 does not come into contact with the bumps 158, 658. When the stop 154 reaches contact with the tabs 158, 658, the tabs force the stop 154 to move, which drives the arm 162 to rotate about the slider 156 and drive the blocker door 104 to deploy toward the deployed position. Therefore, there is a delay in the swing of the blocker door 104.

Conversely, when the movable cowl 207 moves from the open position to the closed position, the stop 154 again follows the projections 158, 658 but in the opposite direction in such a way as to return the arm 162 to the initial position, and the blocker door 104 to its stowed position, by rotation about the slider 156. The stop 154 is then released from the tabs 158, 658 and the slide 156 moves along the guide system 152 to return to the closed position.

Here, the intermediate position corresponds to the moment when the stop 154 reaches contact with the projections 158, 658 or comes out of contact with the projections 158, 658.

In the first embodiment of the invention, the projection 158 is mounted fixed on the fixed structure 101 and comprises a groove in the form of a circular arc, generally centred on the deployment axis 160 when the stop 154 comes to rest against the projection 158.

In the second embodiment, the projection 658 is mounted so as to be movable in rotation on the fixed structure 101 about an axis of oscillation 660 parallel to the axis of rotation 50. The tab 658 has a first groove 662 in the form of an L, a first branch of which is generally parallel to the longitudinal axis X and a second branch of which is generally radial with respect to the longitudinal axis X.

During the movement from the closed position to the intermediate position, the stop 154 first moves outside the first groove 662, then moves along the first branch and reaches contact with the second branch (fig. 6), and the continued translational movement of the movable cowling 207 towards the open position rocks the tab 658 about its axis of oscillation 660 and moves the stop 154 along the second branch (fig. 7), which rotates the arm 162 about the slide 156 and moves the blocker door 104 to the deployed position. The tab 658 is then transitioned from a first position (fig. 6), corresponding to the stowed position, to a second position (fig. 7), corresponding to the deployed position. The reverse movement allows return to the closed/stowed position.

The deployment system 650 further includes a return element 664 that urges the tab 658 to a first position corresponding to the stowed position. Here, the return element 664 is a traction spring fixed between the fixed structure 101 and the projection 658. Return element 664 facilitates return of tab 658 to the first position when moving from the open position toward the closed position.

To stop tab 658 in the first position, tab 658 abuts fixed structure 101 at bearing surface 666.

Here, the deployment axis 660 is at the lateral and posterior portions of the second branch.

The tab 658 further comprises a second groove 667 in the form of an arc centred on the deployment axis 660, and the slider 156 is arranged to move in the second groove 667 when the tab 658 is pivoted between a first position (from the intermediate position) and a second position corresponding to the deployed position. Insertion of the slider 156 into the second recess 667 also prevents withdrawal of the arm 162.