• 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 invention relates to a structural element (100) of an aircraft comprising a portion (110) of a primary mast structure. According to the invention, the primary pylon structure portion is at least partially covered by a protective assembly (140) comprising a firewall layer (130) and a thermally insulating layer (120), the heat layer insulator (120) being located between the firewall layer (130) and the primary pole structure portion (110).
    公开号:FR3015431A1
    申请号:FR1363046
    申请日:2013-12-19
    公开日:2015-06-26
    发明作者:Wolfgang Brochard;Sebastien Alby;David Ewens
    申请人:Airbus Operations SAS;
    IPC主号:
    专利说明:

    [0001] PRIMARY STRUCTURE OF REINFORCED ATTACHING MAST. TECHNICAL FIELD The present invention relates to the field of primary structures of attachment pylon on an aircraft. STATE OF THE PRIOR ART The attachment pylon designates an attachment device that makes it possible to connect an aircraft engine to the rest of the aircraft. The attachment mast forms a connection between an engine, in particular a turbojet engine (also known as the "turbofan") or a CROR (for the English "Counter-Rotating Open Rotor"), and an element of the aircraft such as as the wing, the fuselage, or the empennage.
    [0002] The attachment pylon makes it possible to transmit to the structure of the aircraft the forces generated by the engine. It is sometimes referred to by the acronym EMS, for the English "Engine Mounting Structure". The attachment mast comprises: a secondary structure comprising fairings, serving in particular to give it an aerodynamic shape; and a rigid structure, called primary structure, directly connected to the engine and intended to ensure the transfer of forces from the engine and to be transmitted to the rest of the aircraft.
    [0003] An object of the present invention is to propose means for securing the connection between an engine of an aircraft and the rest of the aircraft, for example a connection between an engine of an aircraft and the wing of the latter.
    [0004] SUMMARY OF THE INVENTION This object is achieved with a portion of the primary structure of the attachment mast at least partially covered by a protective assembly comprising a fire barrier layer and a thermally insulating layer, the thermally insulating layer being situated between the firewall layer and the primary structure portion of the pylon. Advantageously positioning the protection assembly on the side of a primary structure portion facing an engine of the aircraft. The thermally insulating layer then forms a thermal barrier between the primary structure and the motor. Thus, during normal engine operation, the primary structure portion covered by the thermally insulating layer is maintained at a substantially constant temperature. In the event of a fire in the engine, the thermally insulating layer slows the temperature rise of said primary structure portion. Due to the thermal conductivity of the primary structure, the entire primary structure is protected against strong temperature gradients. Thus, regardless of the state of the engine, the primary structure is maintained at the lowest possible temperature. This strengthens the strength of the primary structure by limiting the temperature rises and thus reduces the risk of rupture. The firewall layer provides protection of the primary structure with respect to fire. The firewall layer is disposed above the thermally insulating layer. It therefore also protects the thermally insulating layer with respect to direct contact with the fire. Thus, even if the thermally insulating layer is fire sensitive, it continues to function as a thermal barrier between the primary structure and a fire in the engine.
    [0005] An aircraft structural element is thus produced in which a primary structure portion exhibits excellent mechanical integrity over time, in particular in the event of a motor anomaly such as an engine fire caused by a hydraulic fluid and / or fuel. The invention thus makes it possible to secure the connection between an engine and another element of the aircraft, for example its wing, in particular during an engine fire. The invention also makes it possible to use a wide variety of materials for the primary structure, while complying with the current legislation concerning fire resistance in the event of engine fire (fireproof structure, CS25 specification).
    [0006] The legislation relating to an aviation environment imposes a fire resistance for 15 minutes, but it can be noted that it is possible to increase this duration, by increasing the thickness of the firewall layer and / or the thermally insulating layer. .
    [0007] Said portion of the primary structure of the attachment mast is advantageously made of composite material. The firewall layer may be metallic. Alternatively, the firewall layer may be of composite material. The firewall layer advantageously has a thickness determined according to a desired duration of fire resistance. The thermally insulating layer advantageously has a thickness determined according to a desired duration of fire resistance. The thermally insulating layer may comprise a thermally insulating material.
    [0008] According to a first advantageous embodiment, the thermally insulating material is encapsulated inside an envelope. The firewall layer and the envelope may be affixed to each other by an intumescent glue or an intumescent adhesive interlayer.
    [0009] In a variant, said envelope may comprise the layer forming a firewall, made by an excess thickness of the envelope. According to a second advantageous embodiment, the thermally insulating material is encapsulated between the firewall layer and a cover layer. The structural element according to the invention advantageously comprises supports arranged between the protection assembly and the primary structure portion of the attachment pylon, so as to maintain a space between the protection assembly and the primary structure portion of the structure. mast attachment.
    [0010] The space can be filled by a thermally insulating gas. In a variant, the protection assembly extends directly over the primary structure portion of the attachment pylon. BRIEF DESCRIPTION OF THE DRAWINGS The present invention will be better understood on reading the description of exemplary embodiments given purely by way of indication and in no way limiting, with reference to the appended drawings in which: FIG. 1 schematically illustrates a first embodiment embodiment of an aircraft structural element according to the invention; FIGS. 2A to 2C schematically illustrate a second embodiment of an aircraft structural element according to the invention; and FIGS. 3A to 3C illustrate an example of application of the invention in a known aircraft architecture.
    [0011] DETAILED DESCRIPTION OF PARTICULAR EMBODIMENTS FIG. 1 schematically illustrates, in a sectional view, a first embodiment of a structural element 100 according to the invention.
    [0012] The structural element 100 comprises a portion 110 of primary structure of the attachment mast. This portion 110 of primary structure of the attachment mast is covered by a thermally insulating layer 120, itself covered by a layer forming a firewall 130. The thermally insulating layer 120 and the layer forming a firewall 130 together form an assembly 140. The thermally insulating layer 120 and the firewall layer 130 are superimposed on each other, preferably in direct contact with each other over their entire extent. The protection assembly 140 generally has no function of transferring force from the engine to the rest of the aircraft, for example the wing. It simply forms a protection of the primary structure portion 110, with respect to direct contact with the fire, and with respect to the temperature gradients. The protective assembly 140 forms a boundary between a zone 150 called "fire zone" in direct contact with the fire in case of fire on a motor 300, and a zone 160 called "adjacent fire zone" which is then protected from the traffic light. The fire zone 150 is located on the side of the protection assembly 140 where the aircraft engine 300 is located. The adjacent fire zone 160 is on the side of the protection assembly 140 opposite the engine 300. protection assembly 140 places the primary structure portion 110 out of the fire zone 150.
    [0013] The portion 110 of primary structure is protected against fire by the firewall layer 130. It is also protected against high temperatures through the thermally insulating layer 120. It is all the better protected with regard to the high temperatures that the thermally insulating layer 120 is protected from fire by this same layer forming a firewall 130.
    [0014] The firewall layer 130 is a fire-proofing layer (standard): it is flame-proof, and if appropriate the gas generated by the flames, for a desired duration, for example at least 15 minutes. In other words, the firewall layer 130 has a mechanical stability such that it remains fireproof for a desired time, for example at least 15 minutes. In practice, the term "fireproofness" is used to designate such fireproofness (ref CS25). The firewall layer 130 is for example made of metal, typically titanium, steel, or an alloy of titanium and steel. Its thickness is for example between 0.40 mm and 3 mm. A fire-resistant layer made of steel and fireproof for 15 minutes has a thickness of at least 0.40 mm. A titanium fire-resistant layer, fire-resistant for 15 minutes, has a thickness of at least 0.45 mm. Alternatively, the firewall layer is made of composite material. It is then about fibers, such as carbon or metal fibers, embedded in a matrix. The composite material is, for example, a ceramic matrix composite material, a metal matrix composite material, or an organic matrix composite material such as Carbon Fiber Reinforced Polymer (CFRP). One could even use a mineral matrix.
    [0015] The firewall layer of composite material has for example a thickness of between 1 mm and 5 mm. It tends to degrade in contact with fire, so we will provide a thicker all the more important that the duration during which it is desired that it provides a firewall function is important.
    [0016] Depending on the material used, and the desired duration for maintaining the fireproofness, the skilled person will adjust the thickness of the firewall layer 130. The thermally insulating layer 120, or thermal insulation blanket comprises insulating material 141. This insulating material 141 is encapsulated inside an envelope 142. The envelope 142 is advantageously made of a metal such as aluminum or steel (stainless steel), but it will also be possible to produce an envelope made of a composite material as described above. The envelope 142 is for example made by a sheet which has a thickness of between 0.2 and 0.3 mm. The insulating material is for example a microporous or airgel type material. For example, a thickness of insulating material of between 5 mm and 20 mm is provided. The insulating material may contribute to the maintenance of the fireproofness, for example when the firewall layer is damaged. The thickness of insulating material increases (rapidly) with a duration during which it is desired that it also fulfill a fire-tight function. In the example shown in FIG. 1, the envelope 142 and the firewall layer 130 are two distinct layers and fixed to one another, typically using an intumescent glue or a strip intumescent adhesive. An intumescent material thickens as the temperature increases. This creates, in case of fire in the engine, a second thermal barrier. This second thermal barrier is located between the firewall layer 130 and the thermally insulating layer 120. According to a variant not shown, the thermally insulating material 141 is encapsulated between the firewall layer 130, and a cover layer. The cover layer is attached to the firewall layer for example with an intumescent glue. In other words, the cover layer and the firewall layer 130 together form an envelope within which the insulating material is housed.
    [0017] The protective assembly 140 is attached to the primary structure portion 110 via supports 170, called fix supports, preferably made of metal. Each support 170 is connected on one side to the protection assembly 140, and on the other to the primary structure 110. These connections are made by fasteners 180, preferably made of metal, which extend through the support 170 and the protective structure 140, respectively through the support 170 and the primary structure 110. The shape of the support may be C, or I, or X or any other shape having a body and two parallel bases l to one another and separated by the body. The two bases allow the fasteners to pass through and hold them together with the assembly 140 or the structure 110. The body makes it possible to maintain a gap between the assembly 140 and the structure 110. The thickness of the thermally insulating layer 120 is much lower at the supports 170, to allow the installation of the attachment to the support 170. For example, for each support 170, the thickness of insulating material 141 decreases progressively approaching the support 170, to become zero in view of this support. The opposite walls 121, 125 of the envelope 142 (or in the variant described above, the firewall layer and the cover layer) are therefore in direct contact with each other, at the level of this support 170. The wall 121 of the envelope 142, facing the primary structure 110, remains substantially flat near the support 170. The firewall layer 130 then describes, at the level of the support, a hat-like shape, with a flat top facing the support 170, for example a shape in c) or any other curved shape towards the primary structure 110. The supports 170 maintain a space 190 between the protection assembly 140 and the primary structure 110. This space advantageously has a thickness e of the order of one centimeter. This space is for example an air space, which also contributes to the creation of a thermal barrier between the primary structure 110 and the engine. This space could also be filled with another type of gas, for example a gas having better thermal insulation properties. In the example shown in FIG. 1, a corner 143 of the protection assembly 140 surrounds a corner 111 of the primary structure 110. The insulating material 141 extends everywhere in this corner 143. It will be possible for the assembly of protection 140 completely surrounds the primary structure 110.
    [0018] However, and in order to limit the bulk and the weight of the structural element according to the invention, it advantageously has the protective assembly 140 only on portions of primary structure 110 that may be exposed to high temperatures, or likely to be in direct contact with a fire. Advantageously, a fire seal is produced between the protection assembly and a primary structure portion not covered by the protection assembly, or between the protection assembly and another part of the aircraft. For example, FIG. 1 shows a fire-resistant seal 210 between the protective assembly 140 and a metal foil 220. The seal 210 can be replaced by a metal splint. In a variant, a connection is made between the edges of the protection assembly and the edges of the primary structure portion covered by this same assembly. There is then direct contact between the protection assembly 140 and the primary structure portion 110, at this link. Orifices may be provided in the protection assembly 140, in order to allow fasteners (for example nacelle hood catch hooks) to pass through, and / or systems (for example electrical power supply cables, hydraulic cables, kerosene, etc.). These orifices are advantageously equipped with fire-resistant seals in order to maintain a fire-tightness of the protective assembly 140. The portion 110 of the primary structure of the attachment pylon is advantageously made of metal, for example titanium, steel , or an alloy of titanium and steel.
    [0019] Alternatively, the primary structure portion 110 is made of a composite material as described above, for example CRFP. The invention is then particularly advantageous in that it allows the connection between the engine and the rest of the aircraft is not affected by any sensitivity of the material of the primary structure with respect to fire or high temperatures .
    [0020] FIG. 2A schematically illustrates, in a sectional view, a second embodiment of a structural element 100 according to the invention. The embodiment shown in FIG. 2A differs from the embodiment shown in FIG. 1 in that the protection assembly 140 is directly in contact with the primary structure portion 110, over the entire primary structure extent that he covers. This embodiment allows a gain in volume, and also in weight thanks to the suppression of the supports 170.
    [0021] The embodiment shown in FIG. 2A is also different from the embodiment shown in FIG. 1 in that the envelope 142 comprises the firewall layer 130, this layer being formed by a simple extra thickness of the envelope, the opposite side to the primary structure 110. A real coupling is thus achieved firewall functions and thermal insulation, these two functions being provided by an assembly made in one piece from its conception. In the embodiment shown in FIG. 2A, a corner 143 of the protection assembly 140 surrounds a corner 111 of the primary structure 110. The protection assembly is made flat and then folded around the corner 111. In order to facilitate the folding and limiting the mechanical stresses on the envelope 142, the thickness of insulating material 141 decreases as one approaches a corner edge 143. When the protective assembly 140 is disposed flat, the face 121 of the envelope then has a section of curved shape towards the layer forming a firewall 130, for example V-shaped, the two branches 122, 123 form between them an angle a (see Figure 2B) . The protective assembly 140 is then folded over to form the wedge 143 forming an angle (3 = na (see FIG. 2C). At this wedge 143, two branches 122, 123 then face each other. and for illustrative purposes, a space F between the surfaces 122, 123 when a wedge 143 is formed is deliberately exaggerated.An example of a particularly advantageous application of the invention in an architecture of the present invention will now be described. FIG 3A illustrates a first sectional view of this architecture according to the prior art, FIG. 3A shows a motor 300 surrounded by a nacelle comprising two half-shells 401, 402. Each half -coquille is articulated to a portion 110 of primary structure by a respective pivot connection 411, 412 parallel to a longitudinal axis of the nacelle.On the portion 110 of primary structure, there is a lower beam 111, motor side, an upper spar 1 12 on the opposite side to the lower spar, and two side panels 113, 114. The side faces of the portion 110 of primary structure are formed of two side panels, connected to each other by means of transverse stiffening ribs (not shown). In the event of fire at the engine 300, the side panels 113, 114 are protected from the fire by seals 441, 442, arranged along the side panels and as close as possible to the engine 300. The seals 441, 442 block the passage flames between a side panel and a half-shell nacelle, thus protecting the primary structure. These are, for example, joints made of silicone filled with fibers. Figure 3B illustrates a second sectional view of the aircraft architecture shown in Figure 3A. Figure 3B differs from Figure 3A in that the seals are replaced by metal foils 511, 512 disposed along the side panels, and above the pivot links 411, 412. These are then these metal foils that block the passage flames between a side panel and a half-shell nacelle, thus protecting the primary structure portion located above the foils.
    [0022] According to the prior art, the primary structure portion located under the metal foils 511, 512 is therefore directly in contact with the flames in the event of engine fire. This primary structure portion must be formed by a suitable material, particularly fire resistant. The invention makes it possible to protect the primary structure portion located beneath the metal foils 511, 512 by virtue of a protective assembly 140 according to the invention. A structural element 100 according to the invention is thus produced. It is then possible to relax the stresses on the material forming this primary structure portion.
    [0023] Figure 3C schematically illustrates, in front view, the side panel 113 shown in Figures 3A and 3B. The seal 442 and the metal foil 512 are shown in bold lines. In the zone 301 is the engine. Figure 3A corresponds to a section along the axis BB '. The seal 442 extends well along the lower end of the side panel 113.
    [0024] Figure 3B corresponds to a section along the axis AA '. The metal foil 512 extends on the side of the upper end of the side panel 113. The primary structure 110 is covered by a protective assembly according to the invention, in a zone 133 of the side panel 113, located under the metal foil 512 at the zone 301 side. The zone 133 is shown hatched in FIG. 3C. For various practical reasons (related for example to the passage of hydraulic and / or electrical systems), it may be advantageous for portions of the primary structure not to benefit from fire protection by a gasket or metal foil .
    [0025] By covering these portions with a protective assembly according to the invention, it is ensured that they are nevertheless perfectly protected against fire and high temperatures. It is thus possible to relax certain constraints concerning these portions of primary structure (choice of materials for example), without creating new design constraints, as could be the case if it were desired for the seal 442 to extend on the edge. bottom of the side panel 113 along the entire panel. One could also consider using the protection assembly according to the invention to cover not a portion of primary structure, but an electrical system, hydraulic or kerosene.
    权利要求:
    Claims (14)
    [0001]
    REVENDICATIONS1. Structural element (100) of an aircraft comprising at least a portion (110) of a primary mast structure, characterized in that the portion of primary structure of the suspension pylon is at least partially covered by an assembly shield (140) comprising a firewall layer (130) and a thermally insulating layer (120), the thermally insulating layer (120) being located between the firewall layer (130) and the portion (110) of primary structure of attachment mast.
    [0002]
    2. Structural element (100) according to claim 1, characterized in that said portion (110) primary structure of the attachment mast is made of composite material.
    [0003]
    3. Structural element (100) according to claim 1 or 2, characterized in that the firewall layer (130) is metallic.
    [0004]
    4. Structural element (100) according to claim 1 or 2, characterized in that the firewall layer (130) is made of composite material.
    [0005]
    5. Structural element (100) according to any one of claims 1 to 4, characterized in that the firewall layer (130) has a thickness determined according to a desired duration of fire resistance of the assembly protection (140).
    [0006]
    6. Structural element (100) according to any one of claims 1 to 5, characterized in that the thermally insulating layer (120) has a thickness determined according to a desired duration of fire resistance of the protective assembly (140). 25
    [0007]
    7. Structural element (100) according to any one of claims 1 to 6, characterized in that the thermally insulating layer (120) comprises a thermally insulating material (141).
    [0008]
    8. Structural element (100) according to claim 7, characterized in that the thermally insulating material (141) is encapsulated within an envelope (142).
    [0009]
    9. Structural element (100) according to claim 8, characterized in that the firewall layer (130) and the envelope (141) are fixed to one another by an intumescent glue or an adhesive interlayer intumescent.
    [0010]
    10. Structural element (100) according to claim 8, characterized in that said envelope comprises the firewall layer (130), made by an excess thickness of the envelope (141).
    [0011]
    The structural member (100) of claim 7, characterized in that the thermally insulating material (141) is encapsulated between the firewall layer (130) and a cover layer.
    [0012]
    12. Structural element (100) according to any one of claims 1 to 11, characterized in that it comprises supports (170) disposed between the protective assembly (140) and the portion (110) of primary structure of anchoring mast, so as to maintain a space (190) between the protection assembly (140) and the primary structure portion (110) of the attachment pylon.
    [0013]
    13. Structural element (100) according to claim 12, characterized in that the space (190) is filled by a thermally insulating gas.
    [0014]
    14. Structural element (100) according to any one of claims 1 to 11, characterized in that the protective assembly (140) extends directly on the portion (110) primary structure of the attachment pylon.
    类似技术:
    公开号 | 公开日 | 专利标题
    FR3015431A1|2015-06-26|PRIMARY STRUCTURE OF REINFORCED ATTACHING MAT.
    EP2190739B1|2011-02-02|Lower rear aerodynamic fairing for an aircraft engine attachment device
    EP2146898B1|2010-12-08|Rear lower aerodynamic fairing for the attachment device of an aircraft engine
    EP2303696B1|2012-03-28|Avionic equipement comprising a system for dissipating a lightning current generated by a thunderstorm discharge on an aircraft
    EP2393712B1|2013-07-10|Suspension assembly for an aircraft turbojet engine
    EP2222563B1|2018-02-28|Anti-lightning system and aircraft comprising such a system
    EP2583900B1|2016-03-30|Rear aerodynamic fairing for an aircraft engine attachment device, comprising a heat shield capable of expanding freely
    FR2924687A1|2009-06-12|AIRCRAFT AND AIRCRAFT SYSTEM COMPRISING SUCH A SYSTEM
    FR2905930A1|2008-03-21|TOURBILLON GENERATOR IN HOT GAS OUTPUT
    CA2781013C|2017-08-22|Rear aerodynamic fairing of a linking strut for an aircraft engine
    FR2977567A1|2013-01-11|METHOD FOR COOLING A THERMAL PROTECTION FLOOR OF AERODYNAMIC REAR FITTING OF A FITTING MAT OF A PROPELLANT AIRCRAFT ASSEMBLY
    FR2918036A1|2009-01-02|Leading edge forming device for e.g. wing of aircraft, has rigid elements, external and internal walls forming metallic lattice, where rigid elements are extended between walls and connected directly/indirectly to walls
    EP2045409A1|2009-04-08|Fire resistant panel and building or mobile construction with at least one such panel
    FR2960519A1|2011-12-02|Aerodynamic fairing i.e. rear lower aerodynamic fairing, for hooking device i.e. hooking strut, of turbo-jet engine in aircraft, has stiffener including pressed flange extending along stiffener direction
    EP3271243B1|2021-07-14|Method and device for fireproofing a composite material part
    EP0282361A1|1988-09-14|Reusable thermal protection device for vehicles for the replacement of the normal outer cladding
    FR3012111A1|2015-04-24|AIRCRAFT FUSELAGE COMPRISING EXTERNAL INSULATION
    EP3831719B1|2022-02-16|Rear fairing for an aircraft engine strut with a multi-layer heat shield
    FR2966803A1|2012-05-04|Sealing joint for use between rear secondary structure and aft pylon fairing of e.g. turbojet engine mounting structure of aircraft, has junction zone with section shrunk with respect to connection zone section to permit folding of joint
    EP2877396B1|2018-05-09|Aircraft wing with a protection device for a wing front spar and at least an equipment located in said wing
    EP1389815A1|2004-02-18|Supporting apparatus also protecting at least one linear device against aerothermal stress
    FR3076859A1|2019-07-19|DETACHABLE THERMAL INSULATION JOINT
    Sivolella2014|The Orbiter’s skin: the thermal protection system
    同族专利:
    公开号 | 公开日
    US9868545B2|2018-01-16|
    US20150175272A1|2015-06-25|
    FR3015431B1|2017-12-15|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    FR2127472A6|1971-02-25|1972-10-13|Lindberg John|
    US4801496A|1986-06-24|1989-01-31|The Boeing Company|Composite member with integrated thermal protection|
    DE29622647U1|1996-09-27|1997-05-15|Gruenzweig & Hartmann Montage|High temperature insulation system|
    WO2009040864A1|2007-09-27|2009-04-02|Aeronautical Service S.R.L.|Flame resistant panel for airplanes, ships, ground vehicles, and related locking systems|
    FR2946621A1|2009-06-15|2010-12-17|Aircelle Sa|METHOD OF ASSEMBLING THERMAL PROTECTION ON A FIXED INTERNAL STRUCTURE OF TURBOELECTOR NACELLE|FR3100468A1|2019-09-06|2021-03-12|Safran|MANUFACTURING PROCESS OF AN AIRCRAFT TURBOMACHINE PART|US3222017A|1964-03-30|1965-12-07|Gen Electric|Engine mounting|
    US3357657A|1966-04-27|1967-12-12|Mc Donnell Douglas Corp|Fire barrier|
    GB1291939A|1970-11-30|1972-10-04|Rolls Royce|Flame shield for a gas turbine engine|
    US3818469A|1971-02-25|1974-06-18|J Lindberg|Fire-wall and burn-through protection system|
    US4044973A|1975-12-29|1977-08-30|The Boeing Company|Nacelle assembly and mounting structures for a turbofan jet propulsion engine|
    US4767656A|1984-01-09|1988-08-30|The Boeing Company|Composite material structure with integral fire protection|
    US4821980A|1987-09-29|1989-04-18|The Boeing Company|Vibration isolating engine mount|
    US5065959A|1989-11-21|1991-11-19|The Boeing Company|Vibration damping aircraft engine attachment|
    US5443229A|1993-12-13|1995-08-22|General Electric Company|Aircraft gas turbine engine sideways mount|
    US5524846A|1993-12-21|1996-06-11|The Boeing Company|Fire protection system for airplanes|
    GB2312251B|1996-04-18|1999-10-27|Rolls Royce Plc|Ducted fan gas turbine engine mounting|
    US5910094A|1996-09-10|1999-06-08|The Boeing Company|Aircraft labyrinth fire seal|
    ES2213422B1|2001-07-23|2005-06-01|Gamesa Desarrollos Aeronatuticos, S.A.|FIREPLACE PLATE TO COVER AIRCRAFT ENGINES.|
    US20030178525A1|2002-03-25|2003-09-25|Krr Enterprises, Inc.|Thrust vector adjustment device|
    US6983912B2|2002-04-30|2006-01-10|The Boeing Company|Hybrid exhaust heat shield for pylon mounted gas turbine engines|
    US6802479B2|2002-05-16|2004-10-12|The Boeing Company|Flammable fluid line shroud|
    US7093666B2|2003-02-20|2006-08-22|Pratt & Whitney Canada Corp.|Apparatus and method for providing fireproofing to an aircraft auxiliary power unit|
    FR2862045B1|2003-11-12|2006-05-05|Snecma Moteurs|TURBOREACTOR INTENDED TO BE FIXED ON THE FUSELAGE OF AN AIRCRAFT AND ESPECIALLY ON ITS REAR PART|
    US7040576B2|2003-12-18|2006-05-09|Pratt & Whitney Canada Corp.|Fire shield apparatus and method|
    EP1561997A1|2004-01-27|2005-08-10|Siemens Aktiengesellschaft|Heat Shield|
    US7104306B2|2004-06-14|2006-09-12|The Boeing Company|Cast unitized primary truss structure and method|
    GB0418454D0|2004-08-19|2004-09-22|Rolls Royce Plc|An engine mounting assembly|
    FR2883256B1|2005-03-18|2008-10-24|Airbus France Sas|ENGINE ATTACHMENT OF A MOUNTING SYSTEM INTERPOSED BETWEEN A COUPLING MACHINE AND AN AIRCRAFT ENGINE|
    FR2887851B1|2005-06-29|2007-08-17|Airbus France Sas|ENGINE ATTACHING MAT FOR AN AIRCRAFT|
    FR2891244B1|2005-09-26|2009-04-03|Airbus France Sas|ENGINE ATTACHING MAT FOR AN AIRCRAFT|
    FR2891243B1|2005-09-26|2009-04-03|Airbus France Sas|ENGINE ATTACHING MAT FOR AN AIRCRAFT|
    FR2891252B1|2005-09-28|2007-10-26|Airbus France Sas|MAT TO MONOLITHIC BODY|
    GB2434836B|2006-02-04|2008-12-10|Rolls Royce Plc|Mounting system for use in mounting a gas turbine engine|
    GB0607991D0|2006-04-22|2006-05-31|Rolls Royce Plc|Aeroengine mounting|
    FR2903383B1|2006-07-10|2009-05-15|Airbus France Sas|APPARATUS FOR CONNECTING AN AIRCRAFT ENGINE COMPRISING TWO DUAL REAR MECHANICAL REINFORCING RETRACTORS|
    FR2915175B1|2007-04-20|2009-07-17|Airbus France Sa|ENGINE ATTACHING MACHINE FOR AN AIRCRAFT HAVING A REAR ENGINE ATTACHMENT BEAM DEPORTEE FROM THE HOUSING|
    FR2915176B1|2007-04-20|2009-07-10|Airbus France Sa|ENGINE ATTACHING MACHINE FOR AN AIRCRAFT HAVING A REAR ENGINE ATTACHMENT HAVING A BARREL NUT|
    FR2917712B1|2007-06-20|2009-09-25|Airbus France Sas|ENGINE ATTACHING MACHINE FOR AN AIRCRAFT HAVING A REAR ENGINE ATTACHMENT BEAM FORMING A PALONNIER.|
    ES2341514B1|2007-10-03|2011-04-18|Airbus España S.L.|STRUCTURAL CONFIGURATION FOR THE ASSEMBLY OF AN ENGINE ON THE STRUCTURE OF AN AIRCRAFT.|
    US8205825B2|2008-02-27|2012-06-26|Spirit Aerosystems, Inc.|Engine pylon made from composite material|
    US8056953B2|2008-06-13|2011-11-15|Itt Manufacturing Enterprises, Inc.|Thermal barrier system|
    FR2935953B1|2008-09-18|2010-10-29|Airbus France|REAR AIRCRAFT PART COMPRISING TWO SEMI-STRUCTURES SUPPORTING ENGINES REPORTED ON ONE ANOTHER WITHIN A AIRCRAFT INTERIOR SPACE.|
    US8222165B2|2008-10-27|2012-07-17|Pratt & Whitney Canada Corp.|Composite fire shield|
    FR2939102B1|2008-12-01|2011-01-21|Airbus France|RIGID STRUCTURE OF AIRCRAFT MAT EQUIPPED WITH A RIB EXTENSION FOR THE RESUMPTION OF THE MOMENT ACCORDING TO THE LONGITUDINAL DIRECTION|
    FR2939409B1|2008-12-08|2011-02-11|Airbus France|FIXING SYSTEM BETWEEN TWO COMPONENTS SUCH AS AN AIRCRAFT ENGINE AND ITS ATTACHING MACHINE|
    FR2941673B1|2009-02-04|2011-01-14|Aircelle Sa|SUSPENSION ASSEMBLY FOR AIRCRAFT TURBOJET ENGINE|
    FR2942165B1|2009-02-16|2016-01-29|Airbus France|METHOD FOR MANUFACTURING A RAIDI PANEL IN COMPOSITE MATERIAL|
    FR2950322B1|2009-09-22|2012-05-25|Airbus Operations Sas|AIRCRAFT ENGINE FITTING ELEMENT, AIRCRAFT ASSEMBLY COMPRISING THE AIRCRAFT ELEMENT AND ASSOCIATED AIRCRAFT|
    US8353476B2|2009-11-23|2013-01-15|Spirit Aerosystems, Inc.|Truss-shaped engine pylon and method of making same|
    DE102009054568A1|2009-12-11|2011-06-16|Rolls-Royce Deutschland Ltd & Co Kg|Device for suspending a jet engine on a support structure|
    FR2961172B1|2010-06-14|2012-07-27|Snecma|SUSPENSION OF A TURBOMOTOR OR THE LIKE TO AN AIRCRAFT PYLON WITH INTEGRATED SAFETY.|
    FR2965549B1|2010-10-01|2013-07-05|Airbus Operations Sas|ROPE RESTRAINT DEVICE FOR AN AIRCRAFT ENGINE HITCHING MACHINE, INTEGRATING THREE ALIGNED ROTORS|
    US9027875B2|2010-10-28|2015-05-12|Spirit Aerosystems, Inc.|Pylon arrangement for open structure|
    FR2970700B1|2011-01-20|2013-10-11|Airbus Operations Sas|DEVICE FOR ATTACHING AN AIRCRAFT ENGINE TO A MAT|
    US8844643B2|2011-03-08|2014-09-30|Honeywell International Inc.|Fireproof systems with local heat shields for aircraft engines|
    FR2972709B1|2011-03-18|2013-05-03|Airbus Operations Sas|ENGINE ATTACHING MAT FOR AN AIRCRAFT|
    FR2976914B1|2011-06-23|2014-12-26|Snecma|STRUCTURE FOR ATTACHING A TURBOMACHINE|
    FR2979829B1|2011-09-09|2013-09-27|Astrium Sas|PERFECTION FLAME SHIELD|
    FR2981636B1|2011-10-19|2013-12-27|Airbus Operations Sas|AERODYNAMIC REAR FITTING FOR AN AIRCRAFT ENGINE HANDLING DEVICE, COMPRISING A THERMAL SHIELD CAPABLE OF FREE DILATION|
    EP2620360A1|2012-01-24|2013-07-31|EADS Construcciones Aeronauticas, S.A.|Fire protection device for aircraft|
    EP2631180B1|2012-02-27|2014-04-02|Airbus Operations |An engine attachment pylon|
    US20130232768A1|2012-03-12|2013-09-12|United Technologies Corporation|Turbine engine case mount and dismount|
    FR2994941B1|2012-09-06|2015-08-07|Airbus Operations Sas|PROPULSIVE ASSEMBLY FOR AIRCRAFT COMPRISING A STRUCTURAL CARENAGE.|
    FR2994942B1|2012-09-06|2015-08-07|Airbus Operations Sas|LATERAL PROPULSIVE ASSEMBLY FOR AIRCRAFT COMPRISING A SUPPORT ARM OF A TURBOMOTEUR.|
    FR2996823B1|2012-10-15|2014-11-21|Snecma|DETACHABLE THERMAL PROTECTION IN LINE FOR A SUSPENSION ROLL OF A TURBOMACHINE|
    JP6114042B2|2013-01-25|2017-04-12|三菱航空機株式会社|Aircraft firewalls, pylons and aircraft|
    FR3014841B1|2013-12-17|2017-12-08|Airbus Operations Sas|AIRCRAFT ASSEMBLY COMPRISING A PART ATTACHED ENGINE BODY MADE OF A SINGLE PIECE WITH AN INNER RIB OF A RIGIDIFICATION OF A HOUSING MAT SUBSTATION|
    FR3014840B1|2013-12-17|2017-10-13|Airbus Operations Sas|AIRCRAFT ASSEMBLY COMPRISING A MOTOR ATTACHING BODY EQUIPPED WITH AT LEAST ONE MANILITY SUPPORT BRACKET PENETRATING IN THE HOUSING OF THE ATTACHING MAT|
    FR3015433B1|2013-12-23|2016-02-12|Airbus Operations Sas|AIRCRAFT ASSEMBLY COMPRISING AN INTEGRATED PLATFORM LOADING MACHINE AND REAR PARTLY FUSELING AGENCY|FR2991228B1|2012-05-29|2015-03-06|Airbus Operations Sas|METHOD AND DEVICE FOR MAKING A SELF-RAIDI COMPOSITE PANEL|
    FR3014841B1|2013-12-17|2017-12-08|Airbus Operations Sas|AIRCRAFT ASSEMBLY COMPRISING A PART ATTACHED ENGINE BODY MADE OF A SINGLE PIECE WITH AN INNER RIB OF A RIGIDIFICATION OF A HOUSING MAT SUBSTATION|
    FR3014840B1|2013-12-17|2017-10-13|Airbus Operations Sas|AIRCRAFT ASSEMBLY COMPRISING A MOTOR ATTACHING BODY EQUIPPED WITH AT LEAST ONE MANILITY SUPPORT BRACKET PENETRATING IN THE HOUSING OF THE ATTACHING MAT|
    FR3015433B1|2013-12-23|2016-02-12|Airbus Operations Sas|AIRCRAFT ASSEMBLY COMPRISING AN INTEGRATED PLATFORM LOADING MACHINE AND REAR PARTLY FUSELING AGENCY|
    JP6419437B2|2014-02-28|2018-11-07|三菱航空機株式会社|Aircraft engine pylon and aircraft|
    US10337408B2|2016-06-08|2019-07-02|Mra Systems, Llc|Thermal insulation blanket and thermal insulation blanket assembly|
    FR3053957B1|2016-07-12|2018-08-31|Safran Nacelles|TURBOREACTOR NACELLE REAR ASSEMBLY COMPRISING A FIRE PROTECTION SEALING DEVICE|
    FR3083213B1|2018-06-29|2020-10-02|Safran Aircraft Engines|IMPROVED FIRE RESISTANCE DEVICE INTENDED TO BE INTERPOSED BETWEEN AN AIRCRAFT TURBOMACHINE HANGING MAST END, AND A TURBOMACHINE COVER DELIMING AN INTER-VEIN COMPARTMENT|
    EP3932801A4|2020-06-30|2022-01-05|Airbus Helicopters Deutschland GmbH|A rotary wing aircraft with a firewall arrangement|
    EP3957880A1|2020-08-20|2022-02-23|AIRBUS HELICOPTERS DEUTSCHLAND GmbH|A tightness seal for door|
    法律状态:
    2015-12-21| PLFP| Fee payment|Year of fee payment: 3 |
    2016-12-22| PLFP| Fee payment|Year of fee payment: 4 |
    2017-12-21| PLFP| Fee payment|Year of fee payment: 5 |
    2019-12-19| PLFP| Fee payment|Year of fee payment: 7 |
    2021-09-10| ST| Notification of lapse|Effective date: 20210805 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1363046A|FR3015431B1|2013-12-19|2013-12-19|PRIMARY STRUCTURE OF REINFORCED ATTACHING MAT.|FR1363046A| FR3015431B1|2013-12-19|2013-12-19|PRIMARY STRUCTURE OF REINFORCED ATTACHING MAT.|
    US14/573,447| US9868545B2|2013-12-19|2014-12-17|Primary structure for an attachment pylon with firewall and thermal layers|
    [返回顶部]