PANEL FOR AN AIR INTAKE OF AN AIRCRAFT NACELLE THAT ENSURES OPTIMIZED ACOUSTIC TREATMENT AND FROST TREATMENT

Abstract

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.

Description

This invention relates to a panel that is more particularly suited for an air intake of an aircraft nacelle that ensures optimized acoustic treatment and frost treatment.

In a known manner, as illustrated in FIG. 1, a propulsion system 10 of an aircraft, for example connected under the wing by means of a mast 12, comprises a nacelle 14 in which a power plant that drives a fan 16 is arranged in an essentially concentric manner. The longitudinal axis of the nacelle is referenced 18.

The nacelle 14 comprises an inside wall 20 that delimits a pipe with an air intake 22 at the front.

To limit the impact of noise pollution close to airports, techniques have been developed to reduce the noise emitted by an aircraft, and in particular the noise that is emitted by a propulsion system, by arranging, at the walls of the pipes, panels, coverings or structures whose purpose is to absorb a portion of the sound energy, in particular by using the principle of Helmholtz resonators. In a known manner, a panel for the acoustic treatment comprises—from the outside to the inside—an acoustically resistive porous layer, at least one alveolar structure, and a reflective or impermeable layer.

For the moment, because of various constraints, for example shaping or compatibility with other equipment, the coverings are provided in particular at the inside wall of the nacelle in a limited zone that is distant from the air intake and the air discharge.

To increase the effectiveness of the acoustic treatment, one solution consists in expanding the surfaces that are covered by the acoustic covering and in extending it at the level of the air intake 22. However, at the air intake or the lip of the nacelle, the acoustic treatment should not affect the operation of systems that make it possible to prevent the formation and/or the accumulation of ice and/or frost that are necessary in these zones.

These systems are divided into two families, the first called defrosting systems that make it possible to limit the formation of ice and/or frost, and the second called de-icing systems that limit the accumulation of ice and/or frost and that act once the ice and/or frost is formed. Hereinafter, a frost treatment system is defined as a defrosting system or a de-icing system, the term frost encompassing frost or ice.

This invention relates more particularly to a frost treatment process that consists in using the hot air that is taken from the engine and fed back at the inside wall of the leading edges.

According to an embodiment that is known and illustrated in FIG. 2, a nacelle 14 comprises, on the inside, a partition that is called a front frame 24 that with the air intake 22 delimits a pipe 26 that extends over the entire circumference of the nacelle and that has an essentially D-shaped cross-section.

This pipe 26 is supplied with hot air by a system of nozzles or a feed pipe 28 that is located at a point. This hot air makes a 360° passage around the leading edge, and besides a centrifugal effect, the hot air circulates on the outer side of the leading edge as illustrated in FIG. 3B, on which the de-icing capacity was shown as a function of s, with s=0 corresponding to the top part of the air intake as illustrated in FIG. 2, the value of s being positive and increasing on the outer side of the nacelle based on distance from point 0 and the value of s being negative and increasing by absolute value on the inner side of the nacelle based on distance from point 0.

If hot air is injected at a point that is located at 180° (0 corresponding to the highest point of the nacelle), a de-icing capacity is obtained that is not homogeneous over the circumference that quickly expands to reach a maximum value at 220°, and then a gradual reduction over the remainder of the circumference, as illustrated in FIG. 3B. Thus, a discontinuity of frost treatment at the lowest level is noted.

However, as illustrated in FIGS. 4A and 4B, the zone that requires the most significant frost treatment is located at the inside edge of the air intake over the entire circumference to limit the risk for the power plant of ingesting ice particles.

In the case of an acoustic treatment at the air intake, as illustrated in FIG. 2, an acoustic treatment panel 30 is to be placed at the level of the inner side of the nacelle that is also the zone that should be treated most effectively relative to the frost.

However, the acoustic treatment panel 30 that consists of air-containing cells acts as a thermal insulator that limits the effect of the frost treatment. One solution then consists in increasing the temperature of the air of the frost treatment so as to effectively treat the air intake. However, to withstand significant temperatures, it is advisable to use materials whose mass is higher than that of composite materials; this tends to increase the on-board mass and therefore the energy consumption of the aircraft.

So as to attempt to make acoustic and frost treatments compatible, one solution described in the documents EP-1,103,462 and U.S. Pat. No. 5,841,079 provides holes in the reflective wall so that the hot air penetrates into the cells of the acoustic covering.

However, this solution is not satisfactory for the following reasons:

The cells of the alveolar structure that comprise one or more holes at the reflective layer are less capable in terms of acoustic treatment, with the waves dissipating less well in said cells. To reduce this alteration, one solution consists in reducing the cross-sections of holes. In this case, the air volume at a constant flow rate is reduced, making the de-icing less effective. Furthermore, these holes with reduced cross-sections can be plugged more easily, which eliminates the de-icing function in the corresponding zone.

The document EP-1,232,945 describes an acoustic treatment that comprises an acoustically resistive porous layer, a reflective layer, and, between the two, an alveolar structure that comprises a number of clusters of cells. Thus, according to this document, the acoustic treatment is performed at cell clusters, and the frost treatment enters the cell clusters.

According to one embodiment, the clusters come in the form of strips of cells that are parallel to one another and perpendicular to the longitudinal axis 18 of the nacelle, whereby each strip is delimited by two lateral partitions. With the strips being spaced apart, a passage that is bordered by the side walls of the strips is obtained between two adjacent strips. According to a first variant, a reflective layer that is common to all of the strips and scoops for introducing air into the passages is provided. According to another variant, each strip comprises a reflective layer, a bent part being provided to cover several strips.

Even if it makes it possible to make an acoustic treatment co-exist with a frost treatment, this solution does not make it possible to optimize the frost treatment in the most sensitive zones.

According to another significant constraint, the alveolar structures should be relatively airtight between two points that are spaced apart in the longitudinal direction so as not to create an air flow between these two points inside the acoustic treatment panel that can generate a perturbed stream at the aerodynamic surface.

Also, the purpose of this invention is to remedy the drawbacks of the prior art by proposing an acoustic treatment panel that is more particularly suitable for an air intake of an aircraft nacelle that ensures optimized acoustic treatment and frost treatment.

For this purpose, the invention has as its object an acoustic treatment panel that comprises an acoustically resistive layer that defines a surface of an aircraft that is in contact with an aerodynamic stream, a reflective layer between which are arranged at least one alveolar structure with a number of cells dedicated to the acoustic treatment, and de-icing cavities in which hot air circulates in contact with said acoustically resistive layer to ensure a frost treatment, characterized in that it comprises holes for supplying de-icing cavities in hot air and in that the capacity to treat the frost is adjusted in the zones by modifying the open surface ratio that is associated with the holes.

Other characteristics and advantages will emerge from the following description of the invention, a description that is provided only by way of example, relative to the accompanying drawings, in which:

FIG. 1 is a perspective view of an aircraft nacelle,

FIG. 2 is a cutaway along a longitudinal plane of the front of a nacelle,

FIG. 3A is a diagram that illustrates the capacity to treat the frost according to the prior art in a longitudinal plane of a nacelle,

FIG. 3B is a diagram that illustrates the capacity to treat the frost according to the prior art along the circumference of an air intake of a nacelle,

FIG. 4A is a diagram that illustrates the frost treatment requirements in a longitudinal plane of a nacelle,

FIG. 4B is a diagram that illustrates the frost treatment requirements along the circumference of an air intake of a nacelle,

FIG. 5 is a cutaway along a longitudinal plane of the front of a nacelle according to the invention,

FIG. 6 is a cutaway that illustrates in detail the acoustic treatment panel according to the invention,

FIG. 7 is a cutway that illustrates a first means for adjusting the distribution of the capacity to treat the frost according to the invention,

FIG. 8 is a view of the reflective layer that illustrates a second means for adjusting the distribution of the capacity to treat the frost according to the invention,

FIG. 9 is a cutaway that illustrates an acoustic treatment panel that illustrates a third means for adjusting the distribution of the capacity to treat the frost according to the invention,

FIG. 10 is a cutaway that illustrates an acoustic treatment panel that illustrates a fourth means for adjusting the distribution of the capacity to treat the frost according to the invention,

FIG. 11 is a cutaway along a longitudinal plane of an acoustic treatment panel according to one embodiment,

FIG. 12 is a cutaway along the line XII-XII of the acoustic treatment panel illustrated in FIG. 11, and

FIG. 13 is a diagram that illustrates the capacity to treat the frost in a longitudinal plane of a nacelle.

This invention is now described applied to an air intake of a propulsion system of an aircraft. However, it is not limited to this application and may be suitable for other zones of an aircraft comprising an acoustic treatment panel that is to co-exist with a frost treatment that uses hot air.

FIG. 5 shows an air intake 32 of an aircraft nacelle.

The air intake makes it possible to channel an air stream referenced by the arrow 34 to the power plant.

The front part 36 of the air intake 22 describes an essentially circular shape that extends in a plane that can be essentially perpendicular to the longitudinal axis, or not perpendicular, with the front part that is located just before 12 o'clock. However, other forms of air intake can be considered.

According to the dimensions of the nacelle, the air intake can comprise a first small curvature radius that corresponds essentially to the radius of the inside pipe of the nacelle in a plane that is perpendicular to the longitudinal direction as well as a second small curvature radius in a longitudinal plane.

Hereinafter, aerodynamic surface is defined as the shell of the aircraft that is in contact with the aerodynamic stream.

As illustrated in FIG. 5, the intersection between a longitudinal plane and the front part 36 corresponds to the point s=0, whereby the value of s is positive and increases on the outer side 38 of the nacelle based on distance to point s=0, and the value of s being negative and increasing in absolute value on the inner side 40 of the nacelle based on distance to point s=0.

The invention relates more particularly to a frost treatment that consists in using the hot air that is sampled at the power plant.

According to one embodiment, a nacelle comprises a partition that is called a front frame 42 that with the air intake 22 delimits a pipe 44 that is called a D-shaped pipe that extends over the entire circumference of the nacelle and that has a D-shaped cross-section.

According to one embodiment, this D-shaped pipe 44 is supplied with hot air by a system of nozzles or a feed pipe 46 that is located at one point.

However, the invention is not limited to this type of pipe or to this type of hot air supply.

To limit the impact of pollution, an acoustic treatment panel 48 whose purpose is to absorb a portion of the sound energy, in particular by using the principle of Helmholtz resonators, is provided at the level of the aerodynamic surfaces of the inner side 40 of the air intake in the D-shaped pipe 44. In a known manner, this acoustic treatment panel 48, also called an acoustic panel, comprises—from the inside to the outside—a reflective layer 50, an alveolar structure 52, and an acoustically resistive layer 54.

As a variant, the structure for the acoustic treatment 48 can comprise several alveolar structures that are separated by acoustically resistive layers that are called a septum.

The invention is not limited to an air intake. It relates to all of the acoustic treatment panels that are arranged at an aerodynamic surface that has to be treated on the plane of the frost by using hot air.

According to an embodiment that is illustrated in FIG. 6, the alveolar structure comprises strips 56 that are spaced apart in such a way as to delimit—between two adjacent strips—a passage that is in contact with the aerodynamic surface that is to be de-iced. According to this embodiment, each strip comprises at least two elements, a first element 60 that with the acoustically resistive layer 54 delimits a chamber 62 into which walls are placed in such a way as to form cells. Advantageously, the first element comes in the form of a section with a U-shaped cross-section of which the ends of the branches are made integral with the acoustically resistive layer 54. To improve the sealing between the strips, the ends of the U each comprise a dropped edge 64 that is flattened against the acoustically resistive layer 54. According to this configuration, the base of the U ensures the function of the reflective layer.

At least one rear wall 66 is provided to delimit—with the strips and the acoustically resistive layer—a de-icing pipe 58 that is in contact with the aerodynamic wall to be de-iced.

According to the variants, a rear wall 66 can be provided for several de-icing pipes 58 as illustrated in FIG. 6, or a rear wall 66 is provided for each de-icing pipe 58 as illustrated in FIG. 9.

According to another embodiment that is illustrated in FIGS. 11 and 12, the acoustic treatment panel comprises a reflective layer 50′, at least one alveolar structure 52′, and at least one acoustically resistive layer 54′. According to this embodiment, the de-icing pipes 58′ are delimited by a partition 68 that comes in the form of a section with a U-shaped, V-shaped, or omega-shaped cross-section or the like of which the branches are made integral with the acoustically resistive layer 54′. Preferably, the ends of the branches of the section comprise a fallen edge to ensure a tight connection with the acoustically resistive layer. The alveolar structure 52′ comprises suitable cutaways for housing the de-icing pipes 58′.

According to another embodiment, the alveolar structure can comprise a cell from a first family or a group of cells from the first family dedicated to the frost treatment in which the hot air circulates, whereby said cell or said group of cells is isolated from the other cells of a second family that is dedicated to the acoustic treatment, with the cells from the first family or the groups of cells from the first family able to be connected to one another or respectively connected to one another in such a way as to allow the circulation of the hot air in the cells of the first family dedicated to the frost treatment.

In a general manner, the acoustic panel comprises a reflective layer, at least one acoustically resistive layer in contact with an aerodynamic air stream, between which are arranged at least one alveolar structure with cells that are dedicated to the acoustic treatment and so-called de-icing cavities in which the hot air circulates, isolated from the cells that are dedicated to the acoustic treatment.

Hereinafter, de-icing cavity is defined as a pipe, a cell, a group of cells, or another hollow form that is in contact with the acoustically resistive layer, itself in contact with the aerodynamic stream.

According to these variants, it is noted that the de-icing cavities 58, 58′ are isolated from the cells that are provided for the acoustic treatment and that thus the frost treatment does not interfere with the acoustic treatment.

Advantageously, when the de-icing cavities come in the form of de-icing pipes, the latter are oriented perpendicular to the longitudinal axis of the nacelle. According to this configuration, when the cells that are provided for the acoustic treatment are partitioned in the U-shaped strips as illustrated in FIG. 6, the risk of leakage inside the nacelle between two points that are spaced apart is limited in the longitudinal direction of the alveolar structure, and therefore the risk of generating a stream that is perturbed at the aerodynamic surface is limited.

As a variant, as illustrated in FIG. 11, the de-icing pipes can be arranged in a longitudinal direction or with an acute angle relative to this longitudinal direction.

Supply means are provided for supplying the de-icing cavities 58, 58′. In the case of the configuration that is illustrated in FIGS. 11 and 12, hot air is supplied at one end of each de-icing pipe 58′, for example by means of a collector.

In the case of the configuration that is illustrated in FIGS. 5 and 6, hot air is also supplied by the ends of the pipes.

According to another embodiment, the acoustic treatment panel can be arranged in a cavity or a chamber that contains hot air. In this case, hot air is supplied via holes 70 in the wall(s) that isolate the de-icing cavities 58 from the chamber that contains the hot air.

According to the invention, the capacity to treat the frost is not constant over the entire surface of the acoustic panel. Thus, certain zones of the acoustic treatment panel can have a capacity to treat the frost that is larger than others. The capacity to treat the frost at a given point varies in at least one direction. Thus, the capacity to treat the frost at a given point is adapted based on the variable s and/or based on the angular variable θ, θ varying in a plane that is perpendicular to the longitudinal axis from 0 to 360°, with 0 corresponding to the highest position.

Thus, as illustrated in FIG. 13, there is a tendency to increase the capacity to treat the frost on the inner side 40 of the nacelle so as to make the actual curve 72 of the de-icing capacity correspond to the curve 74 of the de-icing requirements. In addition, relative to the solution of the prior art that corresponds to the curve 76 of the de-icing capacity, the capacity to treat the frost on the outer side 38 of the nacelle is considerably reduced.

It is noted that the surface inside the curve 72 is considerably less than the surface inside the curve 76, which corresponds to a lower total de-icing capacity according to the invention relative to the prior art and therefore to a reduction in power that is necessary. This reduction in power results from a more targeted action of the frost treatment that is performed in the most sensitive zones.

The de-icing capacity is modulated according to a given zone by modifying the dimensions of the de-icing cavity and/or by modifying the open surface ratio that results from the holes 70 as illustrated in FIG. 8 and/or by modifying the distance that separates the holes 70 of the acoustically resistive layer to be treated on the frost plane.

In the case of de-icing pipes, the de-icing capacity is modulated by modifying the cross-section of at least one de-icing pipe as illustrated in FIG. 9, or by modulating its height or its width. Thus, the side walls of the pipe (perpendicular to the acoustically resistive layer) cannot be parallel, and their spacing can vary depending on the zone and the de-icing capacity requirements of said zone.

As illustrated in FIG. 10, the cross-section of the de-icing pipe cannot be constant over the entire length of the pipe.

According to the configuration that is illustrated in FIGS. 11 and 12, it is possible to adjust the capacity to treat the frost by modulating the cross-section of the de-icing pipes 58′.

The open surface ratio that results from the holes 70 can vary by adjusting the density of the holes 70 and/or by adjusting the diameter of the holes 70.

According to a characteristic of the invention, in a given longitudinal plane, the open surface ratio that results from the holes 70 is greater for the zone that corresponds to s<0 relative to the zone that corresponds to s>0.

Preferably, the variant with holes 70 in the partition(s) that separate(s) the de-icing pipes 58 from the remainder of the D-shaped pipe 44 for supplying said pipes will be preferred. Actually, this solution makes it possible to obtain—for each hole 70—a jet 78 (visible in FIG. 7) that impacts the inner surface of the wall that is to be treated. This solution makes it possible to obtain a heat exchange coefficient that is larger than a stream that flows parallel to the wall that is to be treated.

According to this configuration, it is possible to adjust the surface distribution of the capacity to treat the frost by varying D—the diameter of the hole 70—and/or H—the distance separating the hole 70 from the wall that is to be treated.

Thus, the capacity to treat the frost increases when the diameter D increases and/or the height H decreases.

Claims

1. Acoustic treatment panel that comprises an acoustically resistive layer (56) 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 said acoustically resistive layer to ensure a frost treatment, characterized in that it comprises holes (70) for supplying de-icing cavities (58) with hot air and in that the capacity to treat the frost is adjusted according to the zones by modifying the open surface ratio that results from the holes (70).

2. Acoustic treatment panel according to claim 1, wherein the capacity to treat the frost is adjusted according to the zones by modifying the dimensions of the de-icing cavities (58, 58′).

3. Acoustic treatment panel according to claim 1, wherein the open surface ratio that results from the holes is adjusted by making the diameter of the holes (70) and/or the density of the holes (70) vary.

4. Acoustic treatment panel according to claim 1, wherein the capacity to treat the frost is adjusted according to the zones by modifying the distance that separates the holes (70) of the acoustically resistive layer (56) defining the surface of an aircraft that is in contact with the aerodynamic stream.

5. Air intake of an aircraft nacelle that comprises, on the one hand, a pipe that extends over the circumference of said air intake and that is supplied with hot air, and, on the other hand, an acoustic treatment panel according to claim 1.

6. Air intake of an aircraft nacelle according to claim 5, wherein the capacity to treat the frost varies based on a variable s in a longitudinal plane so as to increase the capacity of de-icing at the level of the inner side of the air intake and to reduce the effect of the centrifugal force.

7. Air intake of an aircraft nacelle according to claim 5, wherein the capacity to treat the frost varies based on an angular variable θ along the circumference of the air intake.

8. Air intake of an aircraft nacelle according to claim 5, wherein for a given longitudinal plane, the open surface ratio that results from the holes (70) is larger on the inner side (40) of the nacelle relative to the outer side (38) of the nacelle.

9. Acoustic treatment panel according to claim 2, wherein the open surface ratio that results from the holes is adjusted by making the diameter of the holes (70) and/or the density of the holes (70) vary.

10. Acoustic treatment panel according to claim 2, wherein the capacity to treat the frost is adjusted according to the zones by modifying the distance that separates the holes (70) of the acoustically resistive layer (56) defining the surface of an aircraft that is in contact with the aerodynamic stream.

11. Acoustic treatment panel according to claim 3, wherein the capacity to treat the frost is adjusted according to the zones by modifying the distance that separates the holes (70) of the acoustically resistive layer (56) defining the surface of an aircraft that is in contact with the aerodynamic stream.

12. Air intake of an aircraft nacelle according to claim 6, wherein the capacity to treat the frost varies based on an angular variable θ along the circumference of the air intake.

13. intake of an aircraft nacelle according to claim 6, wherein for a given longitudinal plane, the open surface ratio that results from the holes (70) is larger on the inner side (40) of the nacelle relative to the outer side (38) of the nacelle.

14. Air intake of an aircraft nacelle according to claim 7, wherein for a given longitudinal plane, the open surface ratio that results from the holes (70) is larger on the inner side (40) of the nacelle relative to the outer side (38) of the nacelle.