The present invention relates to an assembly for an aircraft turbojet engine.
Known from the prior art, and in particular from document FR 2 916 426, is an assembly for a turbojet engine, comprising a pylon and a nacelle supported by said pylon, said nacelle comprising a grid thrust reverser comprising an integral cowl slidingly mounted on rails positioned on either side of said pylon between a direct jet position and a thrust reversal position.
“Integral cowl” refers to a cowl with a quasi-annular shape, extending from one end of the pylon to the other without interruption. Such a cowl is often designated using the Anglo-Saxon term “O-duct,” in reference to the shroud shape of such a cowl, as opposed to a “D-duct,” which in fact comprises two half-cowls each extending over a half-circumference of the nacelle.
In both cases, it is the withdrawal of the cowl by sliding along rails integral with the pylon that makes it possible to free the thrust reversal grids, and thus to implement the thrust reversal function.
It is of course crucial for such a sliding movement not to be able to occur at an inopportune time: such an opening would in fact be fatal during a flight phase.
For these reasons, safety bolts are provided at different locations of the thrust reverser to block unwanted opening of the cowl.
In a “D-duct” reverser, three safety bolts are traditionally provided for each half-cowl: two bolts acting directly on two actuating cylinders of each half-cowl, and a third bolt inserted between the so-called “six o'clock” beam (i.e. positioned in the lower portion of the nacelle and on which the two half-cowls are slidingly mounted) and the concerned half-cowl.
Independent power sources are provided for these bolts, so as to increase the reliability of the safety device.
The remote location of the third bolt relative to the other two offers increased security relative to a duct burst or a vane loss: in such a case, only one or two bolts may be destroyed, but not all of them.
In an “O-duct” reverser, by definition there is no six o'clock beam: the installation of a third bolt, as in a “D-duct” reverser, is therefore not possible.
The present invention therefore aims to allow the installation of the third safety bolts in an “O-duct” reverser that provides the same degree of reliability and safety as that of a “D-duct” reverser.
This aim of the invention is achieved with an assembly for a turbojet engine which includes a pylon and nacelle supported by said pylon, said nacelle including a grid thrust reverser including an integral cowl mounted so as to slide on rails, which are arranged on both sides of said pylon, between a direct jet position and a thrust reversal position, said propulsion assembly being remarkable in that it includes means for locking the sliding movement of the cowl on the rails, said means being inserted between the pylon and the cowl.
The presence of these locking means in the interface area between the cowl and the pylon makes it possible to perform locking that is mechanically and geographically independent of that done in the actuating cylinders of the cowl, thereby offering the desired degrees of reliability and security.
According to other optional features of this assembly according to the invention:
Other features and advantages of the present invention will appear upon reading the following description, and in reference to the appended drawings, in which:
In reference to
As is known in itself, said nacelle 3 typically comprises an upstream cowl 5 and a downstream cowl 7, upstream and downstream being understood relative to the flow of air passing through the nacelle.
In the particular case illustrated, the upstream cowl 5 also forms an air intake 9 of the nacelle.
The downstream cowl 7 is slidingly mounted between the position shown in
The thrust reverser shown in
The appended
In
These two figures also show the inner structure 17 surrounding the turbojet engine, defining the cold air tunnel 19.
The short rail 13 allows the thrust reversal grids 21 to slide between a usage position shown in
The long rail 15 and its counterpart positioned on the other side of the pylon 1 allow the cowl 7 to slide between its “direct jet” position and its thrust reversal position in which it frees the thrust reversal grids 21, allowing part of the air flow circulating in the tunnel 19 to be oriented toward the front of the nacelle.
A bolt 23 is mounted inside the pylon 1, a hatch 25 formed on the side 11a of the pylon 1 making it possible to access said bolt 23.
In reference to
The body 27 fixed on the inner surface of the side 11a of the pylon 1 and the strike 29 pass through the wall forming said side 11a to cooperate with a locking member 31 secured to said sliding cowl 7.
In
In
The sliding cowl 7 is in the thrust reversal position, i.e. withdrawn toward the back of the nacelle, this movement being allowed by the pivoting of the strike 29 of the bolt 23 toward the pylon 1, making it possible to release the locking member 31 of the sliding cowl.
As shown in
More specifically, play J (see
The operating mode advantages of the propulsion assembly described above result from the preceding.
In direct jet operation, the thrust reversal grids 21 and the sliding cowl 7 are therefore in the upstream position on their respective rails 13 and 15, as shown in
When one wishes to actuate the thrust reverser, during landing of an aircraft, one first pivots the strike 29 toward the side 11 a of the pylon 1, so as to bring it into the position shown in
This thrust reversal position also makes it possible to perform the maintenance operations of the engine located inside the nacelle.
To that end, it is also necessary to slide the thrust reversal grids 21 in the downstream direction of their rails 13, so as to bring them into the position shown in
Owing to the play J that exists between the crosshead 33 of these grids and the strike 29 in the unlocked position, this sliding movement of the grids 21 can be done without blocking by the bolts 23.
It should also be noted that the radial stepping (i.e. in direction F1 of
The circumferential stepping (arrow F2 in
Of course, with the aim of obtaining the maximum effective surface for the thrust reversal grids 21, it is desirable to minimize the distance between the crossheads 33 and the side 11 a of the pylon 1, and the locking member 31 and the associated fitting 37 connecting to the cowl 7 will in particular be sized so that said fitting is situated as close as possible to the side 11 a of the pylon 1.
The embodiment just described makes it possible to obtain a third bolt positioned in the sliding zone of the cowl 7 relative to the pylon 1, remote from the bolts acting on the actuating cylinders of the cowl 7, and which can be powered by a completely independent power source.
In this way, excellent security and reliability are obtained relative to a risk of untimely opening of the sliding cowl.
The locking member 31 and its associated fitting 37 are fixed on the side 11a of the pylon 1.
As before, play J is provided between the strike 29 in the open position and the locking member 31.
Inasmuch as, in that case, the bolt 23 moves with the sliding cowl 7, it is necessary to provide that the electric power cables 41 of that bolt, connected to a stationary part of the nacelle, have an excess length, as shown in
According to one alternative shown in
In fact, the need to be able to actuate the bolts 23 only occurs when the sliding cowl 7 is in the direct jet position, such a need disappearing once the unlocking has been done and the cowl moves toward its thrust reversal position.
For each of the embodiments described above, it is possible to consider means for prohibiting the movement of the strike of the bolt 23, which can in particular comprise a blocking pin 43 whereof the head 45 is positioned so as to remain visible from the outside.
In the first embodiment, as shown in
In the second embodiment, as shown in
Of course, the present invention is in no way limited to the embodiments described and illustrated, which are provided only as examples.
Number | Date | Country | Kind |
---|---|---|---|
09 05687 | Nov 2009 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/FR2010/052537 | 11/25/2010 | WO | 00 | 5/22/2012 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2011/067520 | 6/9/2011 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5735557 | Harvey | Apr 1998 | A |
6021636 | Johnson et al. | Feb 2000 | A |
6584763 | Lymons et al. | Jul 2003 | B2 |
7484356 | Lair | Feb 2009 | B1 |
20040231317 | Dehu et al. | Nov 2004 | A1 |
20060101806 | Ahrendt | May 2006 | A1 |
Number | Date | Country |
---|---|---|
1286037 | Feb 2003 | EP |
1298309 | Apr 2003 | EP |
2914700 | Oct 2008 | FR |
2916426 | Nov 2008 | FR |
Entry |
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International Search Report issued May 25, 2011 by European Patent Office re: PCT/FR2010/052537, pp. 3; citing: FR 2 916 426 A1, EP 1 286 037 A1, EP 1 298 309 A1, FR 2 914 700 A1, U.S. Pat. No. 7,484,356 B1. |
Number | Date | Country | |
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20120228403 A1 | Sep 2012 | US |