Panel for an air intake of an aircraft nacelle that ensures optimized acoustic treatment and frost treatment
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B64C-023/00
B64D-015/04
B64D-033/02
F02C-007/045
F02C-007/047
출원번호
US-0968562
(2010-12-15)
등록번호
US-8960589
(2015-02-24)
우선권정보
FR-09 58973 (2009-12-15)
발명자
/ 주소
Porte, Alain
Chelin, Frédéric
Dida, Stéphane
Hormiere, Arnaud
출원인 / 주소
Airbus Operations SAS
대리인 / 주소
Young & Thompson
인용정보
피인용 횟수 :
1인용 특허 :
11
초록▼
An acoustic treatment panel includes an acoustically resistive layer that defines a surface of an aircraft that is in contact with an aerodynamic stream, a reflective layer (50) between which are arranged at least one alveolar structure (52) with a number of cells dedicated to the acoustic treatment
An acoustic treatment panel includes an acoustically resistive layer that defines a surface of an aircraft that is in contact with an aerodynamic stream, a reflective layer (50) between which are arranged at least one alveolar structure (52) with a number of cells dedicated to the acoustic treatment, and de-icing cavities (58) in which hot air circulates in contact with the acoustically resistive layer to ensure a frost treatment, characterized in that it includes holes for supplying de-icing cavities (58) with hot air and in that the capacity to treat the frost is adjusted along the zones by modifying the open surface ratio that results from the holes.
대표청구항▼
1. An acoustic treatment panel, comprising: an acoustically resistive layer that defines an outer surface of an aircraft that is in contact with an aerodynamic stream;a reflective layer; andat least one alveolar structure located between the acoustically resistive layer and the reflective layer, the
1. An acoustic treatment panel, comprising: an acoustically resistive layer that defines an outer surface of an aircraft that is in contact with an aerodynamic stream;a reflective layer; andat least one alveolar structure located between the acoustically resistive layer and the reflective layer, the at least one alveolar structure comprising a plurality of cells configured for acoustic treatment,the cells being formed of elongated strips extending parallel to one another, each of the strips being delimited by two opposite side partitions and each of the strips being spaced apart from one another to form elongated de-icing cavities extending in between adjacent strips such that, during operation, hot air circulates through the de-icing cavities in contact with said acoustically resistive layer for frost treatment,wherein a rear wall, extending from opposite facing side partitions of the adjacent strips and enclosing each of the de-icing cavities between the strips, includes holes in communication with each de-icing cavity for supplying each de-icing cavity with hot air, andwherein along an entire length of the rear wall over any one de-icing cavity, a ratio of open space formed by the holes to a closed area of the rear wall along the length varies irregularly to delimit zones having differing communication with the hot air for differing capacities for frost treatment. 2. The acoustic treatment panel according to claim 1, wherein dimensions of any one de-icing cavity varies in a lengthwise direction in order to vary a capacity to treat frost. 3. The acoustic treatment panel according to claim 2, wherein, along the length of the rear wall over any one de-icing cavity, at least one of size and spacing of the holes vary with respect to each other. 4. The acoustic treatment panel according to claim 2, along the length of any one de-icing cavity, a distance separating the rear wall from the acoustically resistive layer varies in order to vary a capacity to treat frost. 5. The acoustic treatment panel according to claim 1, wherein, along the length of the rear wall over any one de-icing cavity, at least one of size and spacing of the holes vary with respect to each other. 6. The acoustic treatment panel according to claim 5, along the length of any one de-icing cavity, a distance separating the rear wall from the acoustically resistive layer varies in order to vary a capacity to treat frost. 7. The acoustic treatment panel according to claim 1, wherein, along the length of any one de-icing cavity, a distance separating the rear wall from the acoustically resistive layer varies in order to vary a capacity to treat frost. 8. An air intake of an aircraft nacelle comprising: a pipe that extends over a circumference of said air intake and configured to be supplied with hot air for treating frost; andan acoustic treatment panel according to claim 1. 9. The air intake of an aircraft nacelle according to claim 8, wherein a capacity to treat the frost varies in accordance with a variable “s” in a longitudinal plane so as to increase the capacity of de-icing at a level of an inner side of the air intake and to reduce an effect of centrifugal force. 10. The air intake of an aircraft nacelle according to claim 9, wherein a capacity to treat the frost varies in accordance with an angular variable theta (θ) along a circumference of the air intake. 11. The air intake of an aircraft nacelle according to claim 9, wherein, for a given longitudinal plane, the ratio of open surface of the holes to a remaining closed surface along the length of the rear wall over any one de-icing cavity is larger on an inner side of the nacelle relative to an outer side of the nacelle. 12. The air intake of an aircraft nacelle according to claim 8, wherein a capacity to treat the frost varies in accordance with an angular variable theta (θ) along a circumference of the air intake. 13. The air intake of an aircraft nacelle according to claim 12, wherein, for a given longitudinal plane, the ratio of open surface of the holes to a remaining closed surface along the length of the rear wall over any one de-icing cavity is larger on an inner side of the nacelle relative to an outer side of the nacelle. 14. The air intake of an aircraft nacelle according to claim 8, wherein, for a given longitudinal plane, the ratio of open surface of the holes to a remaining closed surface along the length of the rear wall over any one de-icing cavity is larger on an inner side of the nacelle relative to an outer side of the nacelle. 15. An acoustic treatment panel, comprising: an acoustically resistive layer provided as an outer surface of an aircraft to be in contact with an aerodynamic stream;a reflective layer facing opposite a surface of the acoustically resistive layer; andat least one alveolar structure, comprising a plurality of elongated strips sandwiched between the acoustically resistive layer and the reflective layer and extending parallel to one another to form cells configured for acoustic treatment,each of the strips extending in a lengthwise direction and having a U-shaped cross section comprising two branches extending from opposite ends of a connecting element spanning a distance between the two branches, each of the two branches having an end connected to the acoustically resistive layer to form a chamber inside the strip,each of the strips being spaced apart from each other to form de-icing pipes within gaps between adjacent strips, each of the de-icing pipes extending along the lengthwise direction and delimited by opposite-facing branches of adjacent strips, the acoustically resistive layer, and a rear wall spanning between each of the adjacent strips to enclose the de-icing pipes within the gaps between the adjacent strips,wherein the rear wall has holes in communication with the de-icing pipes for passage of hot air to a surface of the acoustically resistive layer inside the de-icing pipes for frost treatment, andwherein, for any one de-icing pipe, a ratio of an area of the open space formed by the holes through the rear wall to a closed area of the rear wall between the holes varies irregularly along a longitudinal length of the de-icing pipe to delimit zones within the de-icing pipe having differing capacities for frost treatment. 16. The acoustic treatment panel according to claim 15, wherein each of the ends of the branches of the strips comprises a dropped edge flattened against the acoustically resistive layer. 17. The acoustic treatment panel according to claim 15, wherein the reflective layer is located directly on top of the connecting elements of each of the strips. 18. The acoustic treatment panel according to claim 15, wherein dimensions of any one de-icing pipe varies along the lengthwise direction. 19. The acoustic treatment panel according to claim 15, wherein, along a length of the rear wall over any one de-icing cavity, the holes vary with respect to one another in terms of any one of size and spacing. 20. The acoustic treatment panel according to claim 15, wherein, along a length of the rear wall over any one de-icing cavity, the holes vary with respect to one another in terms of size and spacing.
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이 특허에 인용된 특허 (11)
Cook Leonard J. (Canoga Park CA) Rosenthal Herman A. (San Diego CA), Aircraft anti-icing plenum.
Diepenbrock ; Jr. James L. (Wichita KS) Nelsen M. Dean (Goddard KS) Harp Marlyn F. (Winfield KS), Method of making a cellular core with internal septum.
Lalane, Jacques; Menier, Christophe; Bossis, Jean-Christophe; Poignonec, Jean-Marc, Process for the production of an acoustically resistive structure, the acoustically resistive structure thus obtained, and coating using such a structure.
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