EP2764510A1

EP2764510A1 - Structural acoustic attenuation panel

Info

Publication number: EP2764510A1
Application number: EP12775807.6A
Authority: EP
Inventors: Guy Bernard Vauchel; Eric Pillon; Christophe MAHU
Original assignee: Aircelle SA
Current assignee: Safran Nacelles SAS
Priority date: 2011-10-04
Filing date: 2012-10-02
Publication date: 2014-08-13
Also published as: RU2014117115A; WO2013050694A1; BR112014006561A2; FR2980902A1; CA2848248A1; US20140326536A1; FR2980902B1; CN103858159A

Abstract

The invention relates to an acoustic attenuation panel (100) which includes the following main elements: a resistive skin (110) having acoustic holes; a solid skin (120); an acoustic structure (130) including a sound-absorbing material and arranged between the resistive skin (110) and the solid skin (120), characterised in that the solid skin (120) is structural and is configured in order to form at least one transverse spacer (121, 122) between the solid skin (120) and the resistive skin (110) of the acoustic attenuation panel (100).

Description

Structural acoustic attenuation panel

The present invention relates to an acoustic attenuation panel for a turbojet engine nacelle, to nacelle elements provided with such panels and to associated manufacturing processes.

The use of acoustic attenuation panels in the nacelles of turbojet engines to reduce the noise emissions of a jet engine including, by trapping noise, is known from the state of the art.

These panels usually comprise a structural honeycomb-type acoustic absorption material (commonly called "honeycomb" structure) or porous material structure.

This acoustic absorption material is coated on its underside, that is to say not in contact with the air flow inside the nacelle, an inner skin impervious to air, called " full "whose role is that of acoustic reflector.

In addition, it is coated on its opposite upper face, that is to say in contact with the air flow inside the nacelle, with a perforated outer skin permeable to air, called " resistive "or" acoustic ", whose role is to dissipate acoustic energy.

Such acoustic panels, beyond their primary function must, in addition, have sufficient mechanical properties to transfer the forces, including aerodynamic they receive to the structural links of the nacelle, otherwise the risk of degrading the qualities of acoustic attenuation it offers.

Acoustic attenuation panels in particular are known in which stiffeners and / or spacers are placed between the two skins of the panels concerned and / or one of the skins and the acoustic structure to ensure good structural strength of the panels. .

These spacers and / or stiffeners are most often distributed within the acoustic structure along the panel.

An example of such a panel is known from document FR 2 933 224 in which the spacers are present within the acoustic structure and, moreover, they are associated with mechanical fastening means passing through the acoustic structure of both sides. another to connect the two skins of the panel.

Although the different embodiments of the panels described in document FR 2 933 224 reduce the docking defects of the acoustic structures on the inner and outer skins of the panel, the fact remains that the In this case, the spacers mu m ply the risks of the tolerances and the outcropping of the constituent elements of the panel, penalizing the acoustic qualities of the latter.

Such defects are all the more present when the acoustic structure is complex, formed of one or more stacked and / or juxtaposed alveolar core blocks.

The presence of the spacers within the acoustic structure affect the effective acoustic surface of the panels and the mass of the latter.

It is the same for any mechanical means of fixation placed within the acoustic structure, along the latter.

Such panels are, incidentally, laborious to manufacture, which increases the production costs and associated maintenance costs.

Document FR 2 933 224 discloses, in addition, a panel in which a skin, not in contact with the acoustic structure, is autoraidie to ensure good structural strength of the panels.

Such a solution does not deprive the panel of the use of stiffeners and / or spacers between the two skins, this to ensure the good structural strength of the panel as a whole.

If stiffeners are applied internally to the structure, the acoustic surface is reduced as well.

An object of the present invention is therefore to provide an acoustic attenuation panel whose effective acoustic surface is optimized while respecting the structural properties to which such a panel must respond.

It is also desirable to provide an acoustic attenuation panel with a mass saving, simple and fast to manufacture and repair if necessary.

Another object of the present invention is to provide an acoustic attenuation panel which makes it possible to absorb the stacking tolerances of complex acoustic structures.

Another object of the present invention is to provide an acoustic attenuation panel that provides anti-corrosion protection to the acoustic structure that constitutes it, in a simple and effective manner.

For this purpose, the subject of the present invention is an acoustic attenuation panel comprising the following main elements:

a resistive skin with acoustic holes, - a full skin,

an acoustic structure comprising an acoustic absorption material and disposed between the resistive skin and the solid skin,

remarkable in that the solid skin is structural and is configured to form at least one transverse spacer between the solid skin and the resistive skin of the sound attenuation panel.

Spacer means an element suitable for:

- ensure a link between the two skins,

- play a reinforcing role in the acoustic attenuation panel, - maintain a constant gap between the two skins of the panel.

Thanks to the present invention, it eliminates any spacer or reinforcement embedded in the acoustic structure, which promotes an increase in the effective acoustic surface of the panel relative to a sound attenuation panel of the prior art of the same dimensions.

In addition, the acoustic structure is provided with a skin whose structural properties are sufficient to eliminate any use of structuring acoustic structure.

In embodiments in which there is no bonding of the components of the acoustic structure or expansive foam, acoustic holes are no longer clogging. It remains only to control the good peripheral bonding of the resistive skin on the shell with lower levels of requirement than in the prior art since the resistive skin is not considered as structural, hence a reduction of non conformities.

Advantageously, the acoustic panel of the present invention makes it easier to mount the acoustic structure and the resistive skin on the solid skin, which ensures a good industrial feasibility, namely a speed of execution, a reduction in costs. of production to the extent that the assembly steps of the panel are extremely small compared to the prior art but also ease of maintenance and repair due to simplification of assembly of the panel concerned.

According to other features of the invention, the acoustic attenuation panel of the invention comprises one or more of the following optional features considered alone or according to all the possible combinations: - The solid skin is configured to form a transverse spacer between the solid skin and the resistive skin on either side of the acoustic structure, forming a receiving shell in the concavity of which is housed the acoustic structure;

- The full skin forms an impression of the acoustic structure that it receives.

the solid skin comprises at least one return running along at least part of the periphery of the acoustic structure towards the resistive skin;

this return is prolonged, moreover, on the resistive skin;

- the full skin is monolithic;

- full skin incorporates reinforcements;

- The solid skin is formed at least in part by a double wall in which is formed a reinforcing structure;

- The inner surface of the skin, facing the acoustic surface, has a roughness;

the acoustic structure is housed in the concavity of the shell by embedding;

the acoustic structure is housed in the concavity of the shell, by compression, by means of elastic means and / or by means of mechanical fixing means;

at least part of the elastic means comprises means for anchoring the acoustic structure;

these anchoring means comprise a corrugated acoustic structure and / or an acoustic structure having teeth on one and / or the other of these faces;

at least part of the elastic means comprises drainage means at the interface between the acoustic structure and the solid skin, able to compress in the thickness;

at least part of the elastic means comprises dampers extending from the surface of the acoustic structure facing a bearing surface of the solid skin and / or the resistive skin;

- The dampers are in the form of point bulbs of elastic material reported on the surface of the acoustic structure;

at least part of the mechanical fastening means is adapted to fix the solid skin and the resistive skin at the interface of the two skins. According to a second aspect, the present invention relates to a nacelle element comprising an acoustic panel according to the invention.

The invention will be better understood on reading the following nonlimiting description, with reference to the appended figures in which:

- Figures 1a to 1d are sectional views of a method of manufacturing a panel according to a first embodiment of the present invention;

FIGS. 2a to 2b, 3a to 3b, 4a, 5a, 6a, 6c, 7a to 7b, 8 are sectional views of other embodiments of the panel according to the present invention;

FIGS. 4b, 5b, 6b are enlarged views, respectively zones A, B, C of FIGS. 4a, 5a, 6a. ;

Fig. 9 is a sectional view of a solid skin of a panel according to another embodiment of the present invention. With reference to FIGS. 1a to 1d, an acoustic attenuation panel

100 includes:

a resistive skin having acoustic holes,

- a full skin 120,

an acoustic structure 130 comprising an acoustic absorption material and disposed between the resistive skin 1 10 and the full skin 120.

The acoustic structure 130 may comprise a cellular structure formed of cells with cellular core or NIDA, as illustrated in these figures.

In an alternative embodiment, it may comprise a porous material having acoustic absorption qualities to replace the nida.

This porous material has an open structure, that is to say open cells able to absorb the energy of acoustic waves.

There may be mentioned, for example, a foam-type material or in expanded form.

This acoustic structure 130 may be acoustically distributed or not. It may comprise a single or multiple resonator, be formed of several layers of alveolar / porous or not, separated or not by septa.

In the nonlimiting example illustrated in FIGS. 1a to 1d, the acoustic structure 130 is formed of a distributed acoustic structure comprising a first and a second layer 131, 132 of superimposed cellular cells separated by a septum 133. cells of the two layers 131, 132 being identical or not. The resistive skin 1 10 in contact with the aerodynamic flow is, in turn, perforated multiple holes 1 1 1 positioned in a defined arrangement according to the desired acoustic attenuation.

According to the invention, the solid skin 120, not in contact with the air flow, is structural and is configured to form at least one transverse spacer 121 between the solid skin 120 and the resistive skin 1 10 of the acoustic attenuation panel 100.

Preferably, the full skin 120 is configured to form a spacer 121, 122 transverse between the solid skin 120 and the resistive skin 1 10 on either side of the acoustic structure 130, thus forming a shell 123 for receiving the structure acoustic 130.

More particularly, the two spacers are formed by two set return interfaces 121, 122 on either side of the acoustic structure 130, at least partly along the periphery of the acoustic structure 130 towards the resistive skin 1 10 with which he is in punctual contact or not.

In the illustrated embodiment, these returns 121, 122 each have an inverted L shape, one of the branches 121a, 122a interfaces with the acoustic structure 130 and is extended by the other branch 122b, 123b which makes the interface with the resistive skin 1 10.

Thus, the acoustic structure 130 is held in place by the returns

121, 122 of the hull 123.

Moreover, as illustrated in FIGS. 1a to 1d, the shell 123 forms an impression of the acoustic structure 130 that it houses and more particularly, the concavity of the shell 123 has a shape and dimensions adapted to receive the structure 130 associated acoustics.

Thus, in this nonlimiting example, the shell bottom 123 comprises an internal return 124, in the direction of the acoustic structure 1 30, defining two depth levels for the corresponding shell 123, each respectively to the first and second layers 131, 132 of the corresponding acoustic structure 130.

Advantageously, such a shell 123 makes it possible to absorb the stacking tolerances of the various layers of the complex acoustic structures 130.

Furthermore, in an alternative embodiment, this full shell 123 is monolithic.

It has structural properties and forms a rigid structural layer adapted to receive all the forces to which the panel 100 and passing them to other structural connections of the nacelle element of which they are constitutive, without deformation of the acoustic structure 130 nor of the resistive skin 1 10.

The acoustic structure 130 and the resistive skin 1 10 are, for their part, non-structuring.

The full skin 120 or shell 123 is, therefore, formed by a thermosetting material of composite type for example, by a thermoplastic material which can be reinforced or not or by a metallic material.

Furthermore, the shell 123 may have an inner surface, in its concavity, smooth or rough depending on the material in which it is formed.

In an alternative embodiment, a surface treatment of the shell 123 may be provided before placing the acoustic structure 130 in its concavity.

For a shell 123 formed of composite material, a fabric to be delaminated may be removed at the time of installation of the acoustic structure 130, to obtain a gross internal surface of attachment of said structure 130.

In other embodiments, it is possible to envisage any other mechanical process such as sanding, sanding or a method of chemical surface treatment with an agent, attacking the inner surface of the shell 123.

In another variant embodiment illustrated in FIG. 9, this hull

123 full is auto stiffened all or in part.

It incorporates reinforcements on all or part of its structure. More particularly, it may be formed at least in part by a double wall 126,126 'forming a space i in which a reinforcing structure 125 is put in place.

The space i formed extends over a portion of the outer face of the shell portion 123 forming a bottom, opposite the concavity of the shell 123.

In a non-limiting example, this reinforcing structure 125 may be a honeycomb core structure.

An alternative embodiment may also provide for reinforcing, in a similar manner, all or part of one or more returns 121, 122, 124 of the shell 123.

The acoustic structure 123 is housed in the concavity of the shell 123, by compression, using:

- elastic means and / or

- mechanical means of fixation and / or - by embedding and simple contact.

In this context, a first method of manufacturing the panel illustrated in Figures 1a to 1d is as follows.

In this variant embodiment, the acoustic structure 130 is put in place in the receiving shell 120, either by embedding or by deformation of the acoustic structure 130 or without deformation of the acoustic structure 130 in the event of fitting without play between the shell 123 and the acoustic structure 130.

As illustrated in FIGS. 1a and 1b in the context of a deformation embedding, the respective length d, e of the first 131 and the second 132 layers of the acoustic structure 130 is greater than the length f, g of the housing. of the hull 123 intended to receive it, respectively, in its concavity, this in order to embed and block the different layers of the acoustic structure 130 in the shell 123.

With reference to FIG. 1a, the acoustic structure 130 can be in simple contact with the shell 123 or, if necessary, in contact by a mechanical means of fixing such as adhesive deposition.

The glue used may be any type of glue known to those skilled in the art.

More particularly, at least one ply 1 of glue may be deposited on the surface of the shell bottom 123 and / or the surface of the first layer 131 of the acoustic structure 130 in contact with this shell bottom 123 may be pre-glued and / or crosslinked.

Referring to Figure 1b, the establishment of a septum 133, where appropriate, can be achieved by any suitable means.

Preferably, it can be achieved by pre-gluing the surface of the first layer 131 of the acoustic structure 130 in contact with the septum 133, followed by crosslinking.

The establishment of the second layer 132 of the acoustic structure

130 may be made similarly to the first layer 131.

Thus, at least one ply of glue 2 can be deposited on the surface of the shell bottom 123 remained free after the establishment of the first layer 131 if necessary, and / or the surface of the second layer 132 of the acoustic structure 130 in contact with this bottom and septu m 133 where appropriate or the first acoustic layer 131.

For the establishment of the resistive skin 1 10 illustrated in Figure 1 c, an adhesive deposit can be made on the surface of the second acoustic layer 132 facing the skin 1 10, in association or not with a glue deposit on the surface of the returns 121 b122b of the shell 123 opposite said resistive skin 1 10.

In an alternative embodiment, it is possible to provide an adhesive deposit on the surface of the resistive skin 1 10.

More generally, the bonding is performed so as not to obstruct the acoustic holes, in order to avoid any limitation of the sound absorption.

With reference to FIG. 1 d, pressure is then exerted on the entire panel 100 and, more particularly, on the external surface of the shell 123, in order to make all the collages.

The pressure can be exerted by any known device and can be gaseous or mechanical.

Moreover, it can be exerted punctually on the returns 121, 122 interface with the resistive skin 1 10 only or on the entire shell 123.

In addition, these collages under pressure can be made, if necessary hot in an oven, or even cold.

Another embodiment is illustrated in Figures 2a and 2b.

In this context, the acoustic assembly formed by the acoustic structure 130 and the resistive skin 1 10 may be preassembled, in particular but not exclusively as described previously with reference to FIGS. 1a to 1d, before any installation of the structure acoustic 130 in the hull 123.

Such an assembly is then put in place by embedding in the shell 123.

In an alternative embodiment, it can be provided that the acoustic structure and the shell have complementary shapes and dimensions allowing the fit-free fit of the acoustic structure 130 in the concavity of the shell 123 to be set without play, without deformation of the acoustic structure 130 .

Furthermore, preferably, before arrangement of the acoustic assembly in the shell 123, drainage means 10 of the acoustic panel 100 are placed in the bottom of the shell 123, thanks to the presence of a clearance between the acoustic set and hull bottom 123.

These creasing means 1 0 also have elastic properties.

They are able to compress in the thickness, thus forming an elastic carpet for the acoustic structure 130. More particularly, these drainage means 10 may include, but are not limited to, one or more perforated rabbets, one or more embossed meshes, or one or more fibrous assemblies having entangled fibers, such as a felt.

The drainage means 10 of the acoustic panel 100 are preferably used in a temperature environment of less than 100 ° C, they can be made in commercially available materials at low cost.

A felt, in particular, may be formed from a material chosen from felt materials incorporating as required by the person skilled in the art at least: the porosity of the felt, the tortuosity of the fibers, the aspect ratio, the average size of the fibers, the entanglement rate, which provides good elasticity in the thickness of the felt.

This felt must have properties of resistance to water and fluids of any kind encountered in the aeronautics.

Typically, the thickness of the felt is compatible with the desired compression value.

The drainage means 10 are preferably placed in simple contact with the bottom of the shell 123 and the acoustic structure 130.

However, other types of elastic or mechanical fastening can be envisaged.

The acoustic assembly and the drainage means 10 being placed in the shell 123, a pressure on the outer surface of the shell is exerted similarly to the embodiment of Figure 1 d, this in order to achieve all the collages .

The presence of the drainage means 10 allow pressure contact of the acoustic assembly on the shell 123.

This provides a good quality of bonding of the acoustic structure 130 on the skins of the panel 100.

It is also advantageous to eliminate the drainage caps on the acoustic structure 130, due to the presence of the drainage means 10 at the bottom of the shell 123.

Three other embodiments are illustrated in FIGS. 3a to 5b. In these embodiments, the acoustic structure 130 is made and recessed with play or without play in the shell 123 by simple contact. More particularly, no glue deposit takes place between the acoustic structure 130 and the shell 123, or between the different elements constituting the acoustic structure 130, namely between the different acoustic layers 131, 132 and between the different acoustic layers 131 , 132 and 133, where applicable.

Gluing is replaced by anchoring means 20 by simple contact of the acoustic structure 130 in the shell 123.

In the absence of bonding, it is possible to reduce the risk of sealing the perforations of the resistive skin 1 10 and septa 133 if necessary.

Furthermore, the operating conditions for the manufacture of acoustic panels 100 are simplified by eliminating controlled atmosphere environments, protective clothing and reducing manufacturing steps, in the absence of the adhesive crosslinking steps.

More precisely, with reference to FIGS. 3a to 3c, a first variant of the anchoring means 20 comprises an acoustic structure whose various acoustic layers 131, 132 are corrugated.

Each corrugated acoustic structure 130 must correspond, at least, to the following characteristic: the deformation force of the acoustic structure 130 must be less than the stiffness of the corresponding acoustic panel 100, while ensuring an effective jamming of the acoustic structure 130 in the hull 123 of the panel.

The characteristics of the corrugation, namely in particular the length, the height, the deflection, the amplitude, the configuration of the undulation, are defined according to the desired shaping force, in particular by tests, experiments and / or calculations. .

Preferably, the arrow and the height of the acoustic structure 130 are defined so that a residual deformation remains of the acoustic structure 130 once the resistive skin 1 reported on said structure 130.

It ensures, therefore, an optimal docking of the acoustic structure 130 between the resistive skin 1 10 and the shell 123.

The assembly of the panel is as follows.

The corrugated acoustic first layer 131 is successively put in place, the septum 133 if appropriate, the second corrugated acoustic layer 132 (FIG. 3a) and the resistive skin 11 in and against the shell 123 (FIG. 3b).

As illustrated in FIG. 3c, a pressure (illuminated by arrows) is then exerted on the reinforcements 121, 122 of the shell 123 at the interface with the resistive skin 1 10 is on the entire shell 123, similar to the other embodiments described above.

Referring to Figures 4a and 4b, a second variant of the anchoring means 20 comprises an acoustic structure in which at least the face of the acoustic structure facing the shell 123 has teeth 21, in order to improve the anchoring of the acoustic structure 130 on this shell 123.

These teeth 21 may be provided on the entire face or only on one or more parts thereof.

It can also be envisaged that the walls of the acoustic layers, and in particular cells with a cellular core opposite a septum 133 and / or resistive skin 1, 10 are also dentated.

The teeth 21 are more or less marked, according to the choice of the skilled person and the desired adhesion of the acoustic structure 130 on the skins 1 10,120 opposite.

Preferably, the teeth 21 are shaped so as to minimize their contact surface with their bearing surface, namely, a skin 120, 10, a septum 133 or other.

FIGS. 4a to 4b and 5a to 5b show two embodiments of the same embodiment of a toothed acoustic structure 21, the teeth of the embodiment of FIGS. 56a to 5b being thinner and sharper than those of FIG. embodiment of FIGS. 4a to 4b.

The mounting of the panel 100 of the embodiments 4a and 5a is identical to that of Figures 3a to 3c.

It should be noted that the pressure exerted on the shell 123 puts elastic stress in the acoustic structure 130 by deformation of the teeth 21, or even cells in the framework of alveolar acoustic structure 130.

Moreover, as illustrated in FIG. 4a, it is possible to arrange, in addition, drainage means 10 at the bottom of the shell 123 before any acoustic structure 130 with teeth is placed in place.

Such a possibility is also possible for corrugated acoustic structures 130.

These drainage means 10 may be similar to those described in relation to FIGS. 2a to 2b.

In this context, the walls of the acoustic layers 131, 132 facing the drainage means 10 may have teeth 21. According to another embodiment illustrated in FIGS. 6a to 6c, the acoustic structure 130 comprises at least one surface facing the inner surface of the shell bottom 123 provided with elastic means 30.

These elastic means 30 may be provided on the entire surface, only on one or more parts of the latter or punctually along the latter.

It can also be envisaged that the walls of the acoustic layers 131, 132 and in particular cells with a cellular core facing a septum 133 and / or resistive skin 1 10 are also provided with elastic means.

These elastic means have a low amplitude elasticity which ensure the contact of the acoustic structure 130 under a slight stress at its interface with the shell 123 and, where appropriate, a septum 133 or the resistive skin 1 10.

These elastic means 30 may comprise a deposit of elastic material such as the rubber, as shown in Figures 6a and 6b, or any other suitable elastic means reported or formed on the corresponding faces of the layers 131, 132 of the acoustic structure 130.

The number, shape and arrangement of said elastic means are adapted by those skilled in the art, in particular to promote uniform contact of the acoustic structure 130 on these different supports.

In the example illustrated in FIGS. 6a to 6c, each acoustic layer comprises, on each of these faces, point deposits or bulbs 31 of elastic rubber on each of the cellular cells.

This deposit can be achieved by dipping the acoustic structure 30 before forming the latter.

It can be achieved, moreover, by crosslinking or any other suitable method for reporting an elastic bulb at the end of alveolar cells.

Preferably, each deposit of elastic material is adapted to allow crushing of the acoustic structure 130 under pressure of a few tenths of a mm.

Such deposits offer, advantageously, a coherent contact surface between the acoustic structure 130 and the support concerned, notmmanet the acoustic skin 1 10, which results in insulation cells alveolar, where appropriate and ensures a performance optimal acoustics by eliminating any leakage between each cell and acoustic skin 1 10. In addition, advantageously, such deposits form a protection against corrosion of the acoustic structure 130 of metal material, for example, by providing a seal to the faces of the latter on which they are present.

The mounting of such an acoustic panel 100 is identical to that of Figures 3a to 3c.

It should be noted that the pressure exerted on the shell 123 puts elastic stress in the acoustic structure 130 by deformation of the bulbs 31, or even cells in the framework of cellular acoustic structure.

In this context, the thickness of the acoustic structure 130 added to that of the elastic bulbs 31 must be greater than the depth of the shell 123 receiving the structure 130.

An alternative embodiment can provide several types of elastic elements on the same face of the acoustic structure 130 or from one face to the other of the acoustic structure 130.

Another embodiment is illustrated, in two variants, in FIGS. 7a and 7b.

The acoustic structure 130 is kept in contact on the resistive skin 1 10 and in the shell 123, by compression, by means of mechanical fixing means 40.

In this embodiment, the fixing means are adapted to fix, between them, the shell 123 and the resistive skin 1 10, at the level of the lateral returns 121, 122 of the shell 123.

Advantageously, an acoustic attenuation panel 100 is obtained, the acoustic effective surface of which is optimized by transferring to the shell interface 123 / resistive skin interface 1 10, the fixing links. Any obstruction of the acoustic holes of the acoustic structure 130 by the fastening means is avoided.

By eliminating the collages of the constituent elements of the panel, it also facilitates the repairs of the panels 100 and their maintenance and the replacement of component parts, if necessary.

According to an alternative embodiment shown in FIG. 7a, the mechanical fastening means 40 comprise rivets 41 or bolts, fixing the resistive skin 1 to the branch 121 a, 122 b or 121 b, 122 b of the return 121, 122 of FIG. interface of the hull 123 facing. These rivets 41 cooperate with orifices provided on the returns and the resistive skin 1 10 adapted to be travsersés by the rivets 41.

According to the embodiment variant shown in FIG. 7b, provision can be made for a peripheral return 11.1 13 of the resistive skin 1 10 in the direction of the acoustic structure 130, extending opposite a return 121 a, 122 a of the shell 123 defining the interface of the shell 123 and the acoustic structure 130, on the thickness of the acoustic structure 130.

The return 1 12.1 13 peripheral is thus perpendicular to the base plane of the resistive skin 1 10.

The resistive skin 1 10 and the shell 123 are thus fixed by their reinforcements placed side by side with a layer of the acoustic structure.

Preferably, the mechanical fixing means are formed by a material that is not necessarily structural as a function of the loadings and the temperature, it may be optionally of synthetic material or aluminum base.

Moreover, as illustrated in each of the variants, resilient means 30 may be associated with the mechanical fixing means 40.

One can thus provide, without limitation, to use an acoustic structure 130 provided with elastic bulbs 31 on one and / or the other of these faces, as described in relation with Figures 6a to 6c.

It is also possible to provide elastic means of felt or other type between the bottom of the shell 123 and the acoustic structure 130.

Another variant embodiment is shown in FIG. 8. In this variant embodiment, the mechanical fixing means comprise an expansive foam bonding of the acoustic structure 123 in the shell 123.

In this variant embodiment, the acoustic assembly, with acoustic structure 130 and resistive skin 1 10, is formed by any suitable means, prior to the installation of the acoustic structure 130 in the receiving envelope that forms the hull 123.

More particularly, the various acoustic layers 131, 132 and the septa 133, if any, are precoated on the resistive skin 1 10.

Subsequently, an expansive foam deposit 50 is made at the periphery of the acoustic structure 130.

Therefore, the acoustic assembly formed in the concavity of the shell 123 is placed. It should be noted that, in this frame, the dimensions of the acoustic structure 130 have been adapted to leave a clearance between the reinforcements 121, 122 of the cock 1 23 and the acoustic structure 1 30, this game is filled. by the expansive foam 50.

The panel is subsequently polymerized by any suitable means. During the polymerization, the foam 50 is extended against the returns of the shell 123 and in the surrounding cells alveolar if the acoustic structure is nest egg.

At this stage, an acoustic panel is obtained in which the resistive skin 1 10 is glued to the shell and to the acoustic structure.

This variant embodiment exists but it has some disadvantages with regard to the other embodiments of the present invention.

Indeed, it affects the mass of the panel 100 and may reduce the effective acoustic surface compared to other modes proposed.

Although the invention has been described with particular embodiments, it is obvious that it is not limited thereto and that it includes all the technical equivalents of the means described and their combinations if they fall into the scope of the invention.

Thus, it is possible to envisage a panel 100, the embodiment of which would be a combination of the various embodiments described with reference to the figures illustrated.

Claims

1. Acoustic attenuation panel (1 00) comprising the following main elements: - a resistive skin (1 10) having acoustic holes,

- a full skin (120),

an acoustic structure (130) comprising an acoustic absorption material and disposed between the resistive skin (1 10) and the solid skin (120), characterized in that the solid skin (120) is structural and is configured to form at least one spacer (121, 122) transverse between the solid skin (120) and the resistive skin (1 10) of the acoustic attenuation panel (100).

2. Panel according to claim 1 characterized in that the solid skin (120) is configured to form a transverse spacer between the solid skin (120) and the resistive skin (1 10) on either side of the acoustic structure ( 130), receiving shell (123) in the concavity of which is housed the acoustic structure (130);

3. Panel according to one of claims 1 to 2 characterized in that the solid skin (120) forms an imprint of the acoustic structure that it receives.

4. Panel according to one of claims 1 to 3 characterized in that the solid skin comprises at least one return (121, 122) along at least a portion of the periphery of the acoustic structure (130) towards the resistive skin .

5. Panel according to claim 4 characterized in that this return (121, 122) is further extended on the resistive skin (1 10).

6. Panel according to one of claims 1 to 5 characterized in that the solid skin is monolithic.

7. Panel according to one of claims 1 to 5 characterized in that the full skin incorporates reinforcements.

8. Panel according to claim 7 characterized in that the solid skin is formed at least in part by a double wall in which is formed a reinforcing structure.

9. Panel according to one of claims 1 to 8 characterized in that the inner surface of the solid skin (120), facing the acoustic surface, has a roughness.

10. Panel according to claim 2 characterized in that the acoustic structure (130) is housed in the concavity of the shell (123) by embedding.

1 1. Panel according to claim 2 characterized in that the acoustic structure (130) is housed in the concavity of the shell (123), by compression, by means of elastic means (10, 20, 30) and / or at the using mechanical means of fixation (40)

12. Panel according to claim 1 1 characterized in that at least a portion of the resilient means comprises anchoring means (20) of the acoustic structure.

13. Panel according to claim 12 characterized in that these anchoring means (20) comprise a corrugated acoustic structure and / or an acoustic structure having teeth on one and / or the other of these faces.

14. Panel according to claim 12 characterized in that at least a portion of the resilient means comprises drainage means at the interface between the acoustic structure and the solid skin, able to compress in the thickness.

15. Panel according to claim 12 characterized in that at least a portion of the resilient means comprises dampers (30,31) in extension of the surface of the acoustic structure (130) facing a bearing surface of the full skin and / or resistive skin.

16. Panel according to claim 15 characterized in that the dampers are in the form of bulbs (31) point of elastic material reported on a surface of the acoustic structure (130).

17. Panel according to claim 1 1 characterized in that at least a portion of the mechanical fastening means is adapted to fix the solid skin (120) and the resistive skin (1 10) at the interface of the two skins.

18. Nacelle element comprising an acoustic panel according to one of the preceding claims.