• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    In order to reduce the size of the means for fastening aircraft engines (2) in a secondary vein, the invention provides a first fuselage frame (6a) having two engine support side portions (34a) each associated with the one of the two partially buried side engines, these portions (34a) being inwardly curved so as to surround and follow the profile of the outer shell (26) of an intermediate casing (14), the lateral portion (34a) being fixed on this shell (26) by first and second fastening means (40-1, 40-2) spaced circumferentially from one another, these means being configured to allow the recovery of torsion moment forces in a longitudinal direction (X) of the engine.
    公开号:FR3060531A1
    申请号:FR1662918
    申请日:2016-12-20
    公开日:2018-06-22
    发明作者:Eric Bouchet;Esteban Martino-Gonzalez;Jerome Colmagro;Fernando INIESTA LOZANO;Julien MOULIS;Antoine ABELE
    申请人:Airbus Operations SL;Airbus Operations SAS;
    IPC主号:
    专利说明:

    Holder (s): AIRBUS OPERATIONS Simplified joint-stock company, AIRBUS OPERATIONS SL.
    Extension request (s)
    Agent (s): BREVALEX Limited liability company.
    REAR PART OF AIRCRAFT COMPRISING A FUSELAGE FRAME SUPPORTING TWO PARTIALLY BURIED ENGINES.
    FR 3 060 531 - A1 (5 /) In order to reduce the size of the means for fixing aircraft engines (2) in a secondary stream, the invention provides a first fuselage frame (6a) having two lateral portions of motor support (34a) each associated with one of the two partially buried lateral motors, these portions (34a) being curved inwards so as to surround and follow the profile of the outer shell (26) of an intermediate casing (14), the lateral portion (34a) being fixed to this ferrule (26) by first and second fixing means (40-1, 40-2) spaced circumferentially from one another, these means being configured to allow the recovery of the forces associated with the torsional moment in a longitudinal direction (X) of the motor.

    32a
    REAR PART OF AIRCRAFT COMPRISING A FUSELAGE FRAME
    SUPPORTING TWO PARTIALLY UNDERGROUND MOTORS
    DESCRIPTION
    TECHNICAL AREA
    The present invention relates to the field of aircraft comprising a rear part equipped with two motors partially buried in the fuselage, so as to be able to ingest a part of the boundary layer. These engines are also called propulsion engines by ingestion of the boundary layer, or BLI engines (from the English "Boundary Layer Ingestion"). In known manner, the propulsion by ingestion of the boundary layer corresponds to an ingestion by the engines of a flow of air with low kinetic energy, circulating around the rear portion of the fuselage. This technique reduces the kinetic energy spent on propulsion as well as the drag of the aircraft, with the consequence of a reduction in fuel consumption.
    STATE OF THE PRIOR ART
    It is known to bring back, in the rear part of the fuselage, propulsion engines by ingestion of the boundary layer. These are, for example, two partially or semi-buried engines, projecting laterally from the rear part of the fuselage.
    These engines are conventionally attached to the fuselage using hanging masts of the type of those usually encountered for suspending the engines under the wings of the aircraft. Such a mast comprises a box arranged in the secondary vein of the engine, as well as voluminous engine fasteners connecting the box to the engine. In particular, the rear attachment has a sufficiently large dimensioning to ensure the resumption of the forces associated with the torsional moment in the longitudinal direction of the engine. Because of this large dimensioning of the rear attachment, the fairing which surrounds it also takes up considerable space in the secondary vein, which causes significant drag.
    Thus, there is a need for optimization aimed at reducing the drag caused by the engine attachment systems partially buried in the fuselage.
    STATEMENT OF THE INVENTION
    To respond at least partially to this need, the invention relates to a rear part of an aircraft comprising:
    a fuselage comprising fuselage frames oriented in transverse planes of the rear part of the aircraft;
    - two motors located on either side of a rear vertical median plane, each motor being partially buried in the fuselage so as to be able to ingest a part of the boundary layer, and comprising a fan casing extended towards the 'rear by an outer shell of an intermediate casing.
    According to the invention, among said fuselage frames, a first of them has two lateral engine support portions arranged on either side of the vertical median plane, each lateral portion being associated with one of the two engines and curved inwards so as to surround and follow the profile of one of said engine elements from among the fan casing and the outer shell of one of the two engines, the lateral engine support portion being fixed to said element motor by first and second fixing means spaced circumferentially from one another, the first and second fixing means being configured to allow the recovery of the forces associated with the torsional moment in a longitudinal direction of the motor.
    The invention is thus remarkable in that it breaks with the prior art of implanting a box-type attachment pylon between a partially buried engine, and the fuselage. Indeed, one of the fuselage frames here participates directly in the engine support, and the fixing means used for the recovery of the moment in the longitudinal direction of the engine are arranged on the lateral portion of the frame which surrounds and follows the profile of the fan casing, or the outer shell of the intermediate casing. Therefore, the possible fixing means which remain between the rear of the engine and the fuselage are necessarily less bulky, because they are no longer dedicated to the resumption of the forces associated with the torsional moment in a longitudinal direction of the engine. Therefore, their presence in the secondary vein causes reduced drag, helping to improve the overall performance of the aircraft.
    The invention also provides for the implementation of the following optional characteristics, taken individually or in combination.
    Preferably, among said fuselage frames, a second of them has two lateral engine support portions arranged on either side of the vertical median plane, each lateral portion being associated with one of the two engines and fixed to a casing arranged at the rear of the intermediate casing:
    - by a third fixing means configured to ensure the recovery of the weight of the engine; and
    - By a fourth fixing means comprising at least one connecting rod for thrust forces.
    Preferably, the first and second fixing means each comprise at least one shear axis oriented in the longitudinal direction, as well as at least one yoke crossed by the shear axis.
    Preferably, at least one of the first and second fastening means comprises at least one shackle traversed by the shear axis and received in the yoke, said shackle preferably being arranged substantially tangentially relative to said motor element.
    Preferably, the first and second fixing means are arranged respectively at the opposite ends of the curved lateral portion.
    Preferably, each curved lateral portion being over an angular sector between 45 and 120 °.
    Preferably, the first fuselage frame comprises a transverse frame crossing the hollow of the frame and connecting the two lateral engine support portions, and each lateral portion is fixed to said associated engine element by a fifth emergency fixing means, this the latter being active only in the event of failure of one of the first and second attachment means.
    Preferably, the fourth fixing means comprises a single connecting rod for taking up the thrust forces, or else two connecting rods for taking up the thrust forces arranged in a V, in parallel, or concentrically.
    Preferably, the third attachment means comprises a fitting connecting the engine to the lateral portion of the second fuselage frame, or a plurality of rear connecting rods connecting the engine to the lateral portion of the second fuselage frame, the connecting rods being arranged in the plane of the second fuselage frame, and preferably oriented so that their axes are substantially intersecting at a longitudinal axis of the engine, and / or substantially tangent to said fuselage.
    Preferably, the second fuselage frame comprises a transverse reinforcement reinforcement crossing the hollow of the frame and connecting the two lateral engine support portions.
    Preferably, the two lateral portions of the second fuselage frame are each curved inwards so as to follow the profile of a secondary vein of the engine.
    Preferably, the rear part of the aircraft comprises an aerodynamic cowling enclosing the third and fourth fixing means, said aerodynamic cowling having a rear end situated upstream from an outlet plane of a primary flow of the engine.
    Alternatively, the rear part of the aircraft comprises an aerodynamic casing containing the fourth fixing means, as well as aerodynamic casings each containing a rear connecting rod of the third fixing means.
    Finally, the invention also relates to an aircraft comprising such a rear part, the aircraft preferably being of the commercial type.
    Other advantages and characteristics of the invention will appear in the detailed non-limiting description below.
    BRIEF DESCRIPTION OF THE DRAWINGS
    This description will be made with reference to the accompanying drawings, among which;
    - Figure 1 shows a perspective view of an aircraft according to the invention;
    - Figure 2 shows an enlarged perspective view of a rear part of the aircraft, specific to the present invention;
    - Figure 2a is a perspective view of one of the two engines fitted to the rear part of the aircraft shown in the previous figure;
    - Figures 3 to 5 are sectional views along the transverse planes P3, P4 and P5 of Figure 2;
    - Figure 6 is a perspective view similar to that of Figure 2a, with the engine equipped with means ensuring its attachment to the fuselage;
    - Figure 7 is a rear view of that of Figure 6;
    - Figure 8 is a top view of the rear part of the aircraft, showing one of the aerodynamic fairings containing means for fixing the engine to the fuselage;
    - Figure 9 is a perspective view of that of Figure 8;
    - Figure 10 is a perspective view similar to that of Figure 6, showing an alternative embodiment;
    - Figure 11 is a cross-sectional view of the fourth fastening means;
    - Figures 11a and 11b are cross-sectional views similar to that of Figure 11, showing alternative embodiments; and
    - Figure 12 is a view similar to that of Figure 9, showing an alternative embodiment.
    DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS
    Referring firstly to FIG. 1, there is shown an aircraft 100 of the commercial type, comprising a rear part 1 provided with two motors 2 partially buried in a fuselage 4 produced from fuselage frames 6 oriented parallel in planes transverse of the aircraft, and covered with an outer fuselage skin. The two motors 2, capable of ingesting part of the limit layer of air flowing over the fuselage, are located laterally on the fuselage, on either side of a median vertical plane PI of the rear part 1.
    Figures 2 and 2a show one of the two motors 2, it being specified that since they both have an identical or similar design, only one of them will be described below.
    The engine 2 is here a turbofan engine, centered on a longitudinal axis 8. In this regard, it is noted that in the following description, the terms "front" and "rear" are to be considered in relation to a direction advancement 10 of the aircraft following the thrust generated by the engines 2, while the terms “upstream” and “downstream” are to be considered in relation to a direction opposite to the direction 10. In addition, by convention, the direction X corresponds to the longitudinal direction of the turbojet engine 2, parallel to the longitudinal axis 8. On the other hand, direction Y corresponds to the direction oriented transversely with respect to the engine 2, while direction Z corresponds to the vertical direction or height. These three directions X, Y and Z are orthogonal to each other and form a direct trihedron.
    The turbojet engine 2 powered by ingestion of the boundary layer comprises, from front to rear, a fan surrounded by a fan casing 12, an intermediate casing 14, and a gas generator 16 enclosed in a central casing 18, itself extended to the rear by a gas ejection casing 20.
    The intermediate casing 14 comprises a hub 22 centered on the axis 8, as well as an outer shroud 26 located in the downstream continuity of the fan casing 12. Structural arms 24 oriented radially connect the hub 22 to the outer shroud 26. These structural arms are also called OGV arms (from the English “Outlet Guide Vanes”). Thus, in addition to their structural function, they also serve to straighten the secondary flow of air within a secondary stream 28 of the turbojet engine.
    With reference now to FIGS. 3 to 5, the specific principle of the invention will be described, aiming at an optimized integration of the motors 2 on the fuselage.
    For this integration, it is planned to judiciously use the fuselage frames, which directly carry the two engines.
    FIG. 3 represents one of the fuselage frames 6 of the rear part of the aircraft, located at the front thereof. This frame 6 has a regular shape of the circular or ovalized type, as conventionally encountered in the prior art. On the other hand, the two fuselage frames 6a, 6b shown in FIGS. 4 and 5 are two frames located further back, each participating in the support of the engines. Moreover, they respectively define two transverse planes of force recovery between the fuselage and each engine.
    The main force recovery plane is that defined by the first fuselage frame 6a, shown in FIG. 4. This transverse plane passes through the intermediate casing 14, and in particular the arms 24 as well as the outer shell 26. Alternatively, the frame 6a could be arranged in a more upstream plane passing through the fan casing 12, without departing from the scope of the invention. Nevertheless, the fact of placing the first fuselage frame 6a in the plane of the intermediate casing 14 makes it possible to benefit from a healthier recovery of the forces which pass through the structural arms 24.
    The first frame 6a has an upper portion 30a and a lower portion 32a of conventional shapes, curved upward and downward respectively. To connect these two portions, the first frame 6a comprises two lateral portions 34a of engine support, each lateral portion 34a being dedicated to the support of one of the engines 2. Since the cooperation between each lateral portion 34a and its engine 2 is the same for both engines, only one of them will be described below. It should nevertheless be understood that the two lateral portions 34a are symmetrical with respect to the median vertical plane PI, as are the means making it possible to fix the motors on these portions.
    Each lateral portion of engine support 34a has an inwardly curved shape, so as to surround a part of the outer shell 26, following the geometrical profile of the latter. For optimized integration, the lateral portion 34a is located as close as possible to the outer surface of the ferrule 26, a spacing distance of only a few centimeters can be retained.
    At the opposite ends of the lateral support portion, there is respectively provided a first fixing means 40-1 as well as a second fixing means 40-2 of the lateral portion 34a on the outer ring 26. These two means, circumferentially spaced one of the other, are configured to allow the recovery of the forces associated with the torsional moment in the longitudinal direction X of the motor.
    Thanks to their location at the level of a large diameter ferrule, especially when the dilution rate of the engine is high, the two fixing means 40-1, 40-2 can be very far from each other and form therefore a substantial lever arm. This makes it possible to reduce the intensity of the efforts passing through these means, with the consequence of a reduction in weight and size. To distance these two fixing means 40-1, 40-2 at most, the lateral support portion 34a can extend over an angular sector comprised between 45 and 120 °, and centered on the axis
    8. More preferably, this angular sector is close to 90 °.
    In addition, the invention no longer employs box type attachment masts, which makes it possible to bring the engine as close as possible to the fuselage frames, and to reduce the overhang accordingly. The forces passing through the fasteners are also advantageously reduced due to this reduction in the overhang, here again with the consequence of reducing the overall mass.
    Also, the first and second fixing means 40-1, 40-2 used for the resumption of the moment in the longitudinal direction X are arranged on the outer shell 26 of the intermediate casing, and no longer at the rear in the secondary stream as in the prior art. The other means of attachment remaining between the rear of the engine and the fuselage, which will be described below, then necessarily have a smaller bulk. Thus, their presence in the secondary vein 28 causes reduced drag, helping to improve the overall performance of the aircraft.
    The secondary force recovery plan is that defined by the second fuselage frame 6b, shown in FIG. 5 and located at the rear of the first frame 6a. This transverse plane preferably passes through the gas ejection casing 20, or else a rear part of the central casing. The second frame 6b has an upper portion
    30b and a lower portion 32b of conventional shapes, curved respectively upwards and downwards. To connect these two portions, the second frame 6b comprises two lateral portions 34b of engine support, each lateral portion 34b being dedicated to the support of one of the engines 2. Here again, since the cooperation between each lateral portion 34b and its motor 2 is the same for the two motors, only one of them will be described below. It must nevertheless be understood that the two lateral portions 34b are symmetrical with respect to the median vertical plane PI, as are the means allowing the motors to be fixed on these portions.
    Each lateral portion of engine support 34b has an inwardly curved shape, so as to follow the aerodynamic profile of the secondary vein 28. Consequently, the spacing distance between the lateral portion 34b and the ejection casing 20 is greater than the distance between the lateral portion 34a and the outer shell 26 of the intermediate casing.
    To connect the lateral portion 34b to the ejection casing 20, a third fixing means 40-3 is provided, located in the plane of the second fuselage frame 6b. This third means 40-3 is configured to ensure at least the recovery of the weight of the engine, and also possibly other forces than those of gravity, as will be detailed below. As mentioned previously, the forces to be taken up on this rear recovery plane being reduced, the size of the third fixing means 40-3 remains small. In addition, it can be placed axially towards the rear with respect to the prior art, in an area facilitating the management of the risk of bursting of the turbine blades, also known as UERF risk (from the English “ Uncontained Engine Rotor Failure ”)
    In addition, the lateral portion 34b carries a fourth fixing means 40-4 which comprises at least one connecting rod for taking up the thrust forces, in the direction X.
    The first and second fuselage frames 6a, 6b which have been described above, of overall shape curved due to the side walls curved inward, can be made in one piece, or using several integral parts to each other.
    Figures 6 and 7 show exemplary embodiments of the aforementioned fixing means.
    First of all, as regards the first fixing means 40-1, it comprises a first yoke 44 integral with the upper end of the lateral portion 34a, on which the end of a shackle or of a link 46. The other end of this shackle 46 is articulated on a second yoke 48 secured to the outer ring 26 of the intermediate casing. Shear axes 50 oriented in the direction X make it possible to connect the shackle 46 to the two yokes 44, 48. In addition, the shackle 46 is preferably oriented substantially tangentially with respect to the outer shell 26. The shear axes 50 described here above are preferentially ball-jointed, just like those which will be mentioned below.
    The second fastening means 40-2 comprises for its part a yoke 49 integral with the lower end of the lateral portion 34a, and articulated on a fitting 52 of the outer shell 26, via a shear axis 50 oriented in the direction X .
    In the embodiment shown in Figures 6 and 7, the frame 6a incorporates a safety function called "Fail Safe", by providing a straight transverse frame 56 crossing the hollow of the frame. This straight frame 56, preferably located in a median plane of the motor 2, connects the two lateral portions 34a. In addition, on each end of this frame, at the associated lateral portion 34a, there is provided a fifth emergency fixing means 40-5 between the frame 6a and the engine. This fifth fixing means 40-5 is arranged between the two means 40-1, 40-2, and fixed on the outer shell 26. It is also produced using one or more shear axes, but which are mounted with clearance so that this fifth means 405 is only active in the event of failure of one of the first and second fixing means, in order to ensure with the remaining means the resumption of the moment in the direction X.
    For the manufacture of the frame 6a, only half of which is visible in FIGS. 6 and 7, three parts may be provided fixed to each other, namely an upper part and a lower part connected by the frame 56. Each of the parts lower and upper then comprises, in addition to the upper portion 30a / the lower portion 32a, a half-length of each of the two lateral portions 34a.
    However, this concept of a three-part framework is only given as an example. Indeed, a monobloc frame could also be offered, or a two-part frame.
    As regards the second fuselage frame 6b, its third fastening means 40-3 is connected centered on the lateral portion 34b in the circumferential direction, using a first fitting 60 integral with this portion. This first fitting 60 is connected to a second triangular fitting 62 by means of shearing axes 50 oriented in the direction X. It has a top which cooperates with a yoke 64 of the ejection casing 20, via another shearing axis 50 also oriented in the direction X. The two fittings 60, 62 are in the plane defined by the second fuselage frame 6b.
    Still in this same embodiment, the fourth fixing means 40-4 is produced using two connecting rods for thrust forces, arranged in V symmetrically with respect to a diametral plane of the engine. One of the ends of the connecting rods is articulated on the first fitting 60, while the other end is articulated further forward on the central casing 16 or the hub 22 of the intermediate casing.
    The first fitting 60 is located in the lateral extension of a transverse reinforcing frame 69 of the second fuselage frame 6b. This frame 69, located in the same median plane as the frame 56 of the first frame 6a, crosses the hollow of the frame 6b and connects the two lateral portions 34b.
    In this configuration, the four fixing means 40-1 to 40-4 constitute an isostatic force recovery system between the fuselage and the engine. The thrust forces in the direction X are taken up by the connecting rods 40-4, while the forces in the direction Z are taken up by the third means 40-3 as well as by the second means 40-2. In addition, the forces in the direction Y are taken up by the fourth means 40-4 as well as by the second means 40-2. The forces linked to the moment in the direction X are taken up jointly by the first and second means 40-1, 40-2, while the forces linked to the moment in the direction Z and the moment in the direction Y are taken up jointly by the second and fourth pleas 40-2, 40-4.
    Figures 8 and 9 show that the same aerodynamic cowling 66, also called aerodynamic fairing, contains the two fixing means 40-3, 40-4 within the secondary stream 28. The aerodynamic cowling 66 has a rear end 66a located upstream of a plane 68 of output from a primary flow 70 of the engine. In other words, there is no longer the need to provide an APF type fairing at the outlet of the primary flow, which in addition to reducing the drag, reduces the overall mass.
    FIG. 10 represents an alternative embodiment in which the third means 40-3 comprises a plurality of rear connecting rods 74 connecting the engine to the lateral portion 34a of the second frame 6b. More specifically, these are two connecting rods 74 arranged symmetrically with respect to a diametral plane of the engine, with one of the ends articulated on the ejection casing 20, and the other end articulated on one end of the lateral portion. 34b. These connecting rods 74, arranged in the plane of the frame 6b, are preferably oriented so that their axes are substantially intersecting at a point 76 at a longitudinal axis 8. In addition, for better introduction of the forces into the frame 6b, these axes are substantially tangent to the fuselage, and more precisely tangent to the upper and lower portions 30b, 32b of the frame 6b.
    Optionally, a third safety link 77 can be provided in the same plane as the other two, and also in the plane of symmetry of these two links 74. This safety link 77 is arranged to be active only in the event of failure of one of the two rear connecting rods 74.
    In this same embodiment of FIG. 10, it is shown that the fourth means 40-4 only comprises a single connecting rod for taking up thrust forces, which limits the size of this means in the secondary stream. Alternatively shown in Figure 11, it could be two close links arranged in parallel. A solution with concentric connecting rods such as that shown in FIG. 11a can also be envisaged, just as a solution where the connecting rod is produced by two half-connecting rods, as shown in FIG. 11b. In these solutions of FIGS. 11 to 11b, the single connecting rod is doubled for security reasons, in order to confer a “Fail Safe” function on the arrangement.
    Finally, Figure 12 shows that instead of fairing the third and fourth means with the same rollover, independent aerodynamic rollovers can be implemented. Consequently, an aerodynamic cowling 66-1 contains the fourth fixing means, while two other aerodynamic cowling 66-2 each contain one of the two rear connecting rods of the third fixing means.
    Of course, various modifications can be made by those skilled in the art to the invention which has just been described, only by way of nonlimiting examples. In particular, the embodiments which have been described above are not mutually exclusive, but can on the contrary be combined with one another. In addition, for safety reasons "Fail Safe", each structural element described above can be doubled, namely be made by two separate elements pressed against each other so that in case of failure of the one, the other can ensure the transmission of forces for at least a determined period. This principle can for example apply to the first and second fuselage frames.
    权利要求:
    Claims (14)
    [1" id="c-fr-0001]
    1. Rear part (1) of an aircraft comprising:
    - a fuselage (4) comprising fuselage frames (6, 6a, 6b) oriented in transverse planes of the rear part of the aircraft;
    - two motors (2) located on either side of a vertical median plane (PI) of the rear part, each motor being partially buried in the fuselage (4) so as to be able to ingest a part of the boundary layer, and comprising a fan casing (12) extended rearwards by an outer ring (26) of an intermediate casing (14);
    characterized in that among said fuselage frames, a first of them (6a) has two lateral engine support portions (34a) arranged on either side of the median vertical plane (PI), each lateral portion (34a ) being associated with one of the two motors and curved inwardly so as to surround and follow the profile of one of said motor elements among the fan casing (12) and the outer shroud (26) of the one of the two motors, the lateral motor support portion (34a) being fixed to said motor element by a first (40-1) and a second fixing means (40-2) spaced circumferentially from each other , the first and second fixing means (40-1, 40-2) being configured to allow the recovery of the forces associated with the torsional moment in a longitudinal direction (X) of the motor.
    [2" id="c-fr-0002]
    2. rear part of an aircraft according to claim 1, characterized in that among said fuselage frames, a second of them (6b) has two lateral engine support portions (34b) arranged on either side of the vertical median plane (PI), each lateral portion (34b) being associated with one of the two motors (2) and fixed on a casing (16, 20) arranged at the rear of the intermediate casing (14):
    - by a third fixing means (40-3) configured to ensure the recovery of the weight of the engine; and
    - By a fourth fixing means (40-4) comprising at least one connecting rod for taking up the thrust forces.
    [3" id="c-fr-0003]
    3. rear part of an aircraft according to claim 1 or claim 2, characterized in that the first and second fixing means (40-1, 40-2) each comprise at least one shear axis (50) oriented according to the longitudinal direction (X), as well as at least one yoke (44, 48, 49) crossed by the shear axis (50).
    [4" id="c-fr-0004]
    4. Rear part of an aircraft according to claim 3, characterized in that at least one of the first and second fixing means (40-1, 40-2) comprises at least one shackle (46) through which the shear axis (50) and received in the yoke (44, 48), said shackle preferably being arranged substantially tangentially relative to said motor element (12, 26).
    [5" id="c-fr-0005]
    5. rear part of an aircraft according to any one of the preceding claims, characterized in that the first and second fixing means (40-1, 40-2) are arranged respectively at the opposite ends of the curved lateral portion (34a) .
    [6" id="c-fr-0006]
    6. rear part of an aircraft according to any one of the preceding claims, characterized in that each curved lateral portion (34a) having an angular sector of between 45 and 120 °.
    [7" id="c-fr-0007]
    7. rear part of an aircraft according to any one of the preceding claims, characterized in that the first fuselage frame (6a) comprises a transverse frame (56) passing through the hollow of the frame and connecting the two lateral portions (34a) of motor support, and in that each lateral portion (34a) is fixed to said associated motor element (12, 26) by a fifth emergency fixing means (40-5), the latter being active only in the event of failure one of the first and second fixing means (40-1, 40-2).
    [8" id="c-fr-0008]
    8. rear part of an aircraft according to any one of the preceding claims combined with claim 2, characterized in that the fourth fixing means (40-4) comprises a single connecting rod for taking up the thrust forces, or else two connecting rods resumption of thrust forces arranged in V, parallel or concentrically.
    [9" id="c-fr-0009]
    9. rear part of an aircraft according to any one of the preceding claims combined with claim 2, characterized in that the third fixing means (40-3) comprises a fitting (62) connecting the engine (2) to the portion lateral (34b) of the second fuselage frame (6b), or a plurality of rear connecting rods (74, 77) connecting the engine (2) to the lateral portion (34b) of the second fuselage frame (6b), the connecting rods being arranged in the plane of the second fuselage frame, and preferably oriented so that their axes are substantially intersecting at a longitudinal axis of the engine (8), and / or substantially tangent to said fuselage.
    [10" id="c-fr-0010]
    10. Rear part of an aircraft according to any one of the preceding claims combined with claim 2, characterized in that the second fuselage frame (6b) comprises a transverse reinforcement frame (69) passing through the hollow of the frame and connecting the two lateral engine support portions (34b).
    [11" id="c-fr-0011]
    11. rear part of an aircraft according to any one of the preceding claims combined with claim 2, characterized in that the two lateral portions (34b) of the second fuselage frame (6b) are each curved inwards so as to follow the profile of a secondary vein (28) in the engine.
    [12" id="c-fr-0012]
    12. Rear part of an aircraft according to any one of the preceding claims combined with claim 2, characterized in that it comprises an aerodynamic cowling (66) containing the third (40-3) and the fourth fixing means (40 -4), said aerodynamic cowling (66) having a rear end (66a) located upstream of an outlet plane (68) of a primary flow (70) of the engine.
    [13" id="c-fr-0013]
    13. rear part of an aircraft according to any one of claims 1 to 11 combined with claim 9, characterized in that it comprises an aerodynamic cowling (66-1) containing the fourth fixing means (40-4), as well as
    5 aerodynamic cowlings (66-2) each containing a rear connecting rod (74) of the third fixing means (40-3).
    [14" id="c-fr-0014]
    14. Aircraft (100) comprising a rear part (1) according to any one of the preceding claims.
    S.61728
    1/7
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    EP3489147A1|2019-05-29|Assembly for aircraft comprising a mounting strut primary structure attached to a wing box by fasteners partially embedded in the primary structure
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    同族专利:
    公开号 | 公开日
    FR3060531B1|2019-05-31|
    CN108216558A|2018-06-29|
    US20180170563A1|2018-06-21|
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    法律状态:
    2017-12-21| PLFP| Fee payment|Year of fee payment: 2 |
    2018-06-22| PLSC| Publication of the preliminary search report|Effective date: 20180622 |
    2019-12-19| PLFP| Fee payment|Year of fee payment: 4 |
    2020-12-23| PLFP| Fee payment|Year of fee payment: 5 |
    2021-12-24| PLFP| Fee payment|Year of fee payment: 6 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1662918A|FR3060531B1|2016-12-20|2016-12-20|REAR AIRCRAFT PART COMPRISING A FUSELAGE FRAME SUPPORTING TWO PARTIALLY BITTED ENGINES|
    FR1662918|2016-12-20|FR1662918A| FR3060531B1|2016-12-20|2016-12-20|REAR AIRCRAFT PART COMPRISING A FUSELAGE FRAME SUPPORTING TWO PARTIALLY BITTED ENGINES|
    US15/845,330| US20180170563A1|2016-12-20|2017-12-18|Rear portion of an aircraft comprising a fuselage frame supporting two partly buried engines|
    CN201711383459.4A| CN108216558A|2016-12-20|2017-12-20|Aircraft aft part including being used for the fuselage ring for supporting two engines|
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