• 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:
    - The aerodynamic element (1) is provided with at least one set (E1, E2) of protruding elements (12), each of the protruding elements (12) is designed as an elongate and profiled rib, protruding to a surface (S1, S2) of the aerodynamic element (1), and said protruding elements (12) are arranged on the surface (S1, S2) of the aerodynamic element (1), next to one another, by being oriented substantially parallel to each other so that each of them generates a vortex, the set of vortices thus generated to mitigate instability of a transverse air flow.
    公开号:FR3076540A1
    申请号:FR1850114
    申请日:2018-01-08
    公开日:2019-07-12
    发明作者:Mathias Farouz-Fouquet
    申请人:Airbus Operations SAS;
    IPC主号:
    专利说明:

    TECHNICAL AREA
    The present invention relates to an aerodynamic element of an aircraft, provided with a set of protruding elements.
    STATE OF THE ART
    Although not exclusively, said aerodynamic element may correspond to a wing of the aircraft, for example a transport aircraft. It can also be another aerodynamic element (or surface) (tail, flap, etc.) of the aircraft, as specified below.
    In the case in particular of a so-called laminar wing of the aircraft, that is to say of a wing making it possible to maintain a luminous flux over a considerable distance, it is known that it is generally not possible to increase the deflection of the wing beyond 20 ° (at the leading edge of the wing).
    A wing deflection beyond 20 ° at the leading edge, in fact creates an instability of the transverse air flow (“crossflow” in English), in particular for laminar wings where the pressure gradient is kept weak, i.e. less than or equal to 0, over a long portion of the wing chord. This instability of transverse air flow is the main limitation to the increase in the wing deflection. This phenomenon is characterized by the appearance of a transverse air flow Se along the wingspan, accompanied by vortices which move along the wingspan of the wing. This prevents the maintenance of laminar flow. However, an increase in its deflection would increase the cruising flight speeds of the aircraft, without increasing drag and fuel consumption.
    The object of the present invention is to improve its flow conditions on an aerodynamic element of an aircraft, such as a wing, in order in particular, in particular in the case of a laminar type wing, to prevent the appearance of a transverse air flow instability even if the wing has a high deflection.
    STATEMENT OF THE INVENTION
    To do this, the present invention relates to an aerodynamic element of an aircraft.
    According to the invention, said aerodynamic element is provided with at least one set of protruding elements, each of said protuberant elements is produced in the form of an elongated and profiled rib projecting from a surface of the aerodynamic element, and said protruding elements of said assembly are arranged on the surface of the aerodynamic element, one beside the other, being oriented substantially parallel to each other.
    Thus, each of the protruding elements generates, due to its particular shape and its particular orientation, as specified above, a vortex and a single one. This vortex combines with a vortex (located in the same place) of an instability of transverse air flow so as to dampen. Consequently, thanks to the combined effect of all of these protruding elements, the instability of transverse air flow is reduced, and its flow conditions are improved on the aerodynamic element.
    In a first embodiment, at least some of said protruding elements are curved, longitudinally.
    Furthermore, in a second embodiment, at least some of said protuberant elements are rectilinear, longitudinally.
    Furthermore, advantageously, at least some (but preferably all) of said protruding elements are oriented in an inclined direction at a given angle relative to a direction of a transverse air flow flowing along the aerodynamic element.
    Furthermore, advantageously, the aerodynamic element has a leading edge and a first set of protruding elements, said first set of protruding elements being arranged along the leading edge on a first face of the element. aerodynamic leading to said leading edge, said protruding elements of said first set being oriented transversely to said leading edge.
    In addition, advantageously, the aerodynamic element comprises a second set of protruding elements, said second set of protruding elements being arranged along the leading edge on a second face of the aerodynamic element ending at said leading edge , said protruding elements of said second assembly being oriented transversely to said leading edge.
    Furthermore, in a preferred embodiment, each of said protruding elements has at least one of the following characteristics (or dimensions): - a length of between 1 millimeter and 30 millimeters; - a thickness less than or equal to 0.5 millimeter; and - a height between 5 and 50 micrometers.
    In addition, advantageously, the protruding elements are spaced from each other by a distance of between 2 and 8 millimeters, and preferably equal to 5 millimeters.
    In the context of its present invention, said aerodynamic element which is provided with said protuberant elements can correspond to at least part of one of the following elements of the aircraft: - a wing; - a section ; - a vertical tailplane; - a horizontal tail; - part of the fuselage; - an engine nacelle.
    The present invention also relates to an aircraft, in particular a transport aircraft, which comprises at least one aerodynamic element provided with protruding elements, such as that described above.
    BRIEF DESCRIPTION OF THE FIGURES
    The appended figures will make it clear how the invention can be implemented. In these figures, identical references designate similar elements. More particularly: - Figure 1 is a schematic perspective view of an aircraft to which the present invention is applied; - Figures 2 and 3 are schematic views, respectively in perspective and in front view, of a leading edge of a wing portion of an aircraft, provided with sets of protruding elements; - Figures 4 and 5 schematically illustrate in perspective views, respectively two different embodiments of a protruding element; - Figures 6 and 7 schematically show air flows generated around a protruding element; - Figure 8 is a schematic perspective view of a leading edge of a wing portion of an aircraft, provided with sets of protruding elements, on which flow d has been highlighted 'air generated; and - Figure 9 is a diagram for showing the combination, between on the one hand, vortices generated by protruding elements, and on the other hand, vortices of an instability of a transverse air flow, generating a reduction in the instability of the transverse air flow.
    DETAILED DESCRIPTION
    FIG. 1 schematically shows an AC aircraft, in particular a transport aircraft, which is provided with at least one aerodynamic element (not shown specifically), such as that shown in FIG. 2.
    In the context of the present invention, the aerodynamic element 1 (FIG. 2) can correspond to one of the following elements (or surfaces) or part of one of the following elements (or surfaces) of the aircraft AC, shown in Figure 1: - a wing 2, 3; - a vertical tail 4; - a horizontal tail 5, 6; - part of the fuselage 7; - a nacelle 8, 9 of a motor 10, 11; or - a section (not shown specifically). By way of illustration (not limiting), the aerodynamic element 1 considered in the following of its description corresponds to a part (or section) of one of the wings 2, 3 of the aircraft AC.
    According to the invention, this aerodynamic element 1 is provided, as shown in particular in FIGS. 2 and 3, with at least one set E1, E2 of protruding elements 12. Each of said protruding elements 12 is produced in the form of a rib 13, 14 (FIGS. 4 and 5) elongated (in a so-called longitudinal direction) and profiled, and it is arranged so as to project relative to a surface S1, S2 of the aerodynamic element 1. In addition, the protruding elements 12 of said assembly E1, E2 are arranged on the surface S1, S2 of the aerodynamic element 1, one beside the other, being oriented substantially parallel with respect to each other.
    Thus, each of the protruding (or prominent) elements 12 generates, due to its particular relief shape and its orientation, as specified below, a vortex which will participate in reducing the instability of air flow. transverse on the aerodynamic element 1.
    The protruding elements 12 can be produced in different ways.
    In a first embodiment, all of the protruding elements 12 are produced, in each case, in the form of a profiled rib 13. As shown in FIG. 4, this rib 13 is curved longitudinally (that is to say in its longitudinal direction), in the plane of the surface of the aerodynamic element on which it is arranged.
    In addition, in a second embodiment, all of the protruding elements 12 are produced, in each case, in the form of a profiled rib 14. As shown in FIG. 5, this rib 14 is rectilinear longitudinally (that is to say in its longitudinal direction), in the plane of the surface of the aerodynamic element on which it is arranged.
    Furthermore, in a third embodiment, the aerodynamic element 1 may comprise on at least a first part (or section) of the protruding elements 12 produced in the form of the rib 13 and on at least a second part (or section) of the protruding elements 12 produced in the form of the rib 14.
    In a preferred embodiment, each of said protruding elements 12 has at least one and preferably all of the following characteristics (or dimensions), represented in FIGS. 4 and 5: - a length L1, L2 of between 1 millimeter and 30 millimeters; - a thickness e1, e2 less than or equal to 0.5 millimeter; and - a height h1, h2 of between 5 and 50 micrometers, and preferably substantially equal to 15 micrometers.
    Each of said protruding elements 12 is characterized by a length ratio (“aspect ration” in English) greater than 1. The orientation of the protruding elements 12 on the aerodynamic element 1 is defined in direct relation to the direction of a flow d along the aerodynamic element 1, as specified below.
    Furthermore, in the example shown in FIGS. 2 and 3, the aerodynamic element 1, in particular a wing, comprises a leading edge 15 with a fastening line 16 and two surfaces S1 and S2 on either side other from this leading edge 15.
    In this example, the aerodynamic element 1 is provided with a first set E1 of protruding elements 12. The set E1 of protruding elements 12 is arranged along the leading edge 15 on its surface (or face) S1 of the aerodynamic element 1, which terminates at said leading edge 15 from above. The protruding elements 12 of said assembly E1 are oriented transversely to the leading edge 15, as specified below.
    In addition, in this example of FIGS. 2 and 3, the aerodynamic element 1 also comprises a second set E2 of protruding elements 12. This set E2 of protruding elements 12 is arranged along the leading edge 15 on the surface (or face) S2 of the aerodynamic element 1, which ends at the leading edge 15 from below. The protruding elements 12 of said assembly E2 are also oriented transversely to the leading edge 15.
    The protruding elements 12 are arranged downstream of the attachment sign 16 (in the direction shown by an arrow B in FIG. 8) at approximately 1% of the cord of the aerodynamic element 1 forming a wing, and they are spaced Its from each other (along the attachment sign 16) with a distance D (Figure 3) of between 2 and 8 millimeters, and preferably equal to 5 millimeters. The orientation of the protruding elements 12 is therefore determined in direct relation to the direction of the air flow on the aerodynamic element 1. The flow arriving from and near its attachment line 16 describes a trajectory curve, as illustrated by arrows F in Figures 6 and 7.
    The protruding elements 12 are oriented by being inclined at a given angle β relative to the direction of the transverse air flow, illustrated by the arrows F in FIGS. 6 and 7, flowing along the element aerodynamics 1, substantially transversely to the attachment line 16, in the direction shown by its arrow B in its figure 8. The orientation and arrangement of the protruding elements 12, whose longitudinal direction locally forms an angle β with the flow F, are such that a vortex T1 and only one is created downstream (relative to the direction indicated by its arrow B) of each protruding element 12, as shown in FIG. 8. As this vortex T1 is unique (only one T1 vortex by protruding element 12), it cannot become turbulent by being mixed with a second vortex.
    In addition, each protruding element 12 is oriented so that the vortex T1 generated by this protruding element 12 rotates in a direction C1 which is opposite to the direction C2 (of rotation) of a vortex T2 of the air flow instability transverse. Thus, locally, downstream of each protruding element 12, the two vortices T1 and T2 combine and attenuate (or cancel each other out) mutually.
    In other words, the vortices T1 generated by the protruding elements 12 dampen its vortices T2 from the instability of the transverse air flow, as illustrated in FIG. 9,
    This instability of the transverse air flow which has negative effects on the flow on the aerodynamic element 1, in particular by limiting the laminar flow, is therefore reduced (or even canceled) by the protruding elements 12. Thus, the if necessary, the laminar boundary layer is maintained on the aerodynamic element 1.
    In the example of an aerodynamic element 1 at the leading edge 15, representing a wing 2, 3, the orientation of the protruding elements 12 with respect to the flow F around the nose radius of the leading edge 15 is such that each individual T1 vortex (by protruding element 12) rotates clockwise on a right wing 2, and in the opposite direction clockwise on a left wing 3.
    The protruding elements 12, as described above, are not vortex generators. Indeed, a vortex generator takes, in a usual way, kinetic energy in Se flows above the boundary layer of the surface on which it is arranged, and it brings this energy down in the boundary layer for provide it with energy and avoid detachment from the air flow. The protruding elements 12 individual T1 vortex generators, described above, have a completely different action and a different purpose. The protruding elements 12 remain at a low height in the laminar boundary layer and do not take air from the flow outside the boundary layer. The set E1, E2 of protruding elements 12, as described above, has many advantages. In particular: - it allows a laminar flow to be maintained above a wing which has an arrow φ (FIG. 8) at the leading edge 15, greater than 20 °; - it allows higher cruising speeds for the aircraft; - it allows the provision of light fluxes on its wings of long-haul aircraft; - it allows a reduction in its drag even at Mach numbers above 0.77, and thus a reduction in its fuel consumption; - it can be tested very simply, Using a digital fluid mechanics study of CFD type (for "Computational Fluid Dynamics") and / or Using wind tunnel tests and / or flight; - it is passive type and requires no energy or mechanical device; - it can be easily integrated into a molded or possibly printed leading edge; and - it does not generate substantially any additional mass.
    The protruding elements 12, as described above, can therefore, in particular, be mounted: - on its wings 2, 3 of the aircraft AC (FIG. 1); - on flaps of the AC aircraft; - on the vertical tail 4 of the aircraft AC; -on the horizontal tail 5, 6 of AC aircraft; on the fuselage 7 of the aircraft AC; or - on nacelle 8, 9 of an engine 10, 11 of the aircraft AC.
    These protruding elements 12 can be manufactured in different ways.
    According to a first manufacturing method, which is simple, the protruding elements are molded directly into the aerodynamic element 1, for example in the leading edge of a wing.
    According to a second manufacturing method, the protruding elements are etched by electroerosion in the die of the tool.
    In addition, according to a third manufacturing method, cylindrical inserts (or inserts) are attached to the aerodynamic element 1. These inserts (or inserts) are flush with its surface of the aerodynamic element. On the outside surface of these inserts, the shape of the protruding elements is in relief.
    In an alternative embodiment, the protruding elements are attached by gluing to a strip applied to the aerodynamic element, that is to say that the adhesive strip (encompassing a large part of the leading edge of the aerodynamic element) is printed with the shapes of the protruding elements.
    权利要求:
    Claims (10)
    [1" id="c-fr-0001]
    1. aerodynamic element of an aircraft, characterized in that it is provided with at least one set (E1, E2) of protruding elements (12), in that each of said protruding elements (12) is produced in the form an elongated and profiled rib (13, 14) projecting from a surface (S1, S2) of the aerodynamic element (1), and in that said protruding elements (12) of said assembly (E1, E2) are arranged on the surface (S1, S2) of the aerodynamic element (1), one next to the other, being oriented substantially parallel to each other.
    [2" id="c-fr-0002]
    2. Aerodynamic element according to claim 1, characterized in that at least some of said protruding elements (12) are curved, longitudinally.
    [3" id="c-fr-0003]
    3. Aerodynamic element according to one of claims 1 and 2, characterized in that at least some of said protruding elements (12) are rectilinear, longitudinally.
    [4" id="c-fr-0004]
    4. aerodynamic element according to any one of the preceding claims, characterized in that at least some of said protuberant elements (12) are oriented in a direction inclined by a given angle (β) relative to a direction of flow transverse air (F) flowing along the aerodynamic element (1).
    [5" id="c-fr-0005]
    5. aerodynamic element according to any one of the preceding claims, characterized in that it comprises a leading edge (15) and a first set (E1) of protruding elements (12), said first set (E1) d protruding elements (12) being arranged along the leading edge (15) on a first face of the aerodynamic element (1) terminating at said leading edge (15), said protruding elements (12) of said first assembly ( E1) being oriented transversely to said leading edge (15).
    [6" id="c-fr-0006]
    6. aerodynamic element according to claim 5, characterized in that it comprises a second set (E2) of protruding elements (12), said second set (E2) of protruding elements (12) being arranged along the edge d attack (15) on a second face of the aerodynamic element (1) leading to said leading edge (15), said protruding elements (12) of said second assembly (E2) being oriented transversely to said leading edge (15) .
    [7" id="c-fr-0007]
    7. aerodynamic element according to any one of the preceding claims, characterized in that each of said protuberant elements (12) has at least one of the following characteristics: - a length (L1, L2) of between 1 millimeter and 30 millimeters; - a thickness (e1, e2) less than or equal to 0.5 millimeter; and - a height (h1, h2) of between 5 and 50 micrometers.
    [8" id="c-fr-0008]
    8. Aerodynamic element according to any one of the preceding claims, characterized in that the protruding elements (12) are spaced from each other by a distance (D) between 2 and 8 millimeters.
    [9" id="c-fr-0009]
    9. aerodynamic element according to any one of the preceding claims, characterized in that it corresponds to at least part of one of the following elements of the aircraft (AC): - a wing (3, 4); - a section ; - a vertical tail (4); - a horizontal tail (5, 6); - a fuselage part (7); - an engine nacelle (8, 9) (10,11).
    [10" id="c-fr-0010]
    10. Aircraft, characterized in that it comprises at least one aerodynamic element (1) according to any one of the preceding claims.
    类似技术:
    公开号 | 公开日 | 专利标题
    EP3508416A1|2019-07-10|Aerodynamic element of an aircraft, provided with a set of protruding elements
    FR3065441B1|2019-07-05|AIRCRAFT ASSEMBLY COMPRISING A PRIMARY STRUCTURE OF A COUPLING MAT FIXED TO A SAILBOX USING A BOLT CONNECTION
    EP1535837A1|2005-06-01|Engine suspension attcchment device of an engine to an aircraft wing
    FR2948628A1|2011-02-04|AIRPLANE WITH LACET CONTROL BY DIFFERENTIAL TRAINING
    FR2583374A1|1986-12-19|ARRANGEMENT OF TURBULENCE GENERATORS AND BOUNDARY LAYER DEFLECTORS
    FR2930235A1|2009-10-23|SUSPENSION MAT FOR TURBOMOTOR.
    EP2019775B1|2009-10-21|Aircraft wing arrangement comprising an engine attachment pylon defining, in the forward region, a lateral airflow channel
    CA2872207A1|2015-06-05|Air ejection device including an aerodynamic profile equipped with a flexible strip for sealing the slit
    FR2968272A1|2012-06-08|IMPROVED STRUCTURE ELEMENT OF A GIRAVION TO DECREASE AERODYNAMIC TRAINING.
    EP3505439B1|2020-04-15|Assembly for aircraft comprising a mounting strut primary structure attached to a wing box by compact fasteners in the leading edge area
    WO2013083937A1|2013-06-13|Method for creating a connecting element positioned between two components of a structure, connecting element and bypass turbojet engine comprising such a connecting element
    FR2894558A1|2007-06-15|Wing for aircraft, has airfoil and winglet defining airfoil zone, winglet zone and connecting zone of winglet and airfoil, where flattened portion in part of connecting zone is central portion of upper surface of profile
    EP3521173B1|2020-07-29|Assembly for aircraft comprising a mounting strut primary structure attached to a wing box by means of a bolted connection
    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
    EP3505448B1|2021-10-13|Assembly for aircraft comprising a mounting strut primary structure attached to a wing box by compact fasteners in the leading edge area
    FR3038583A1|2017-01-13|AIRCRAFT AND METHOD FOR COUNTERBALANCING AERODYNAMIC EFFECTS OF PROPELLER WAKE
    EP3540205A1|2019-09-18|Aircraft drive unit in which the nacelle is linked by a pivot to the drive shaft of its fan
    EP2496472B1|2014-03-05|Engine pylon comprising a vortex generator, and method for the production thereof
    FR3081830A1|2019-12-06|AIRCRAFT AIRCRAFT WALL COMPRISING AT LEAST ONE TOURBILLON GENERATOR AND AIRCRAFT COMPRISING SAID AIRCRAFT WALL
    WO2016132073A1|2016-08-25|Aircraft propulsion unit comprising an unducted-fan turbine engine and an attachment pylon
    FR3099460A1|2021-02-05|Assembly of an aerodynamic wall of an aircraft and a vortex generator comprising at least one spacer plate
    EP3037684B1|2019-02-06|Cap with pocket and/or relief
    FR3081831A1|2019-12-06|AIRCRAFT AIRCRAFT WALL COMPRISING AT LEAST ONE TOURBILLON GENERATOR AND AIRCRAFT COMPRISING SAID AIRCRAFT WALL
    EP2639153A1|2013-09-18|Aircraft including fairings to correct the lateral dissymmetry or asymmetry thereof
    FR2704513A1|1994-11-04|Improvements to aero- and hydro-dynamic profiles known as NLF profiles |
    同族专利:
    公开号 | 公开日
    EP3508416A1|2019-07-10|
    US20190210714A1|2019-07-11|
    FR3076540B1|2021-04-16|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US4907765A|1985-09-26|1990-03-13|Messerschmitt-Boelkow-Blohm Gmbh|Wall with a drag reducing surface and method for making such a wall|
    WO1995011160A1|1993-10-18|1995-04-27|The Secretary Of State For Defence|Sub boundary layer vortex generators|
    US6345791B1|2000-04-13|2002-02-12|Lockheed Martin Corporation|Streamwise variable height riblets for reducing skin friction drag of surfaces|
    WO2009000703A1|2007-06-25|2008-12-31|Politecnico Di Milano|Method for reducing the viscous friction between a fluid and an object|
    WO2012082667A2|2010-12-13|2012-06-21|3M Innovative Properties Company|Article including airfoil or hydrofoil and method of making the same|
    US20110262705A1|2011-03-30|2011-10-27|General Electric Company Global Research|Microstructures for reducing noise of a fluid dynamic structure|
    WO2014026246A1|2012-08-16|2014-02-20|Adelaide Research & Innovation Pty Ltd|Improved wing configuration|
    EP2982599A1|2014-08-01|2016-02-10|The Boeing Company|Drag reduction riblets integrated in a paint layer|
    US4650138A|1985-09-30|1987-03-17|Internorth, Inc.|Cascaded micro-groove aerodynamic drag reducer|
    FR2947313B1|2009-06-26|2015-02-20|Inst Francais Du Petrole|SYSTEM AND METHOD FOR REDUCING TRAINING WITH STRUCTURED SURFACES OF EVOLUTIVE FORM|
    DE102011106763A1|2011-07-05|2013-01-10|Eads Deutschland Gmbh|A method of manufacturing a surface of a reduced airflow resistance component and a reduced airflow resistance component|
    FR3053074B1|2016-06-28|2018-06-15|Safran Aircraft Engines|PIECE AND METHOD FOR MANUFACTURING A REDUCED ROLLED ROLLED PIECE|CN110539882B|2019-07-16|2021-07-16|中国航空研究院|Method and device for optimizing flow at junction of leading edge bending flap and leading edge slat|
    FR3108950A1|2020-04-01|2021-10-08|Safran Aircraft Engines|DOUBLE-FLOW TURBOMACHINE FOR AN AIRCRAFT|
    法律状态:
    2019-01-24| PLFP| Fee payment|Year of fee payment: 2 |
    2019-07-12| PLSC| Publication of the preliminary search report|Effective date: 20190712 |
    2020-01-21| PLFP| Fee payment|Year of fee payment: 3 |
    2021-01-21| PLFP| Fee payment|Year of fee payment: 4 |
    2022-01-19| PLFP| Fee payment|Year of fee payment: 5 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1850114|2018-01-08|
    FR1850114A|FR3076540B1|2018-01-08|2018-01-08|AERODYNAMIC ELEMENT OF AN AIRCRAFT, PROVIDED WITH A SET OF PROTUBERANT ELEMENTS.|FR1850114A| FR3076540B1|2018-01-08|2018-01-08|AERODYNAMIC ELEMENT OF AN AIRCRAFT, PROVIDED WITH A SET OF PROTUBERANT ELEMENTS.|
    EP18213032.8A| EP3508416A1|2018-01-08|2018-12-17|Aerodynamic element of an aircraft, provided with a set of protruding elements|
    US16/239,730| US20190210714A1|2018-01-08|2019-01-04|Aerodynamic element of an aircraft, comprising a set of protruding elements|
    [返回顶部]