The present invention relates to the field of the noise reducing in an aircraft engine.
The gas turbine engines, such as those powering the aircrafts, typically comprise structures for suppressing the noise, in particular the fan noise. These structures are generally composed of a plurality of cellular structures formed by partitions defining cavities. These cells are often arranged in a network, such as a network resembling a plurality of “honeycomb” cells.
These structures are typically located in the nacelle of the engine, downstream of the fan.
In the scope of the development of thin and short nacelles, the surfaces available for a possible acoustic treatment are becoming increasingly smaller. This means that there is less and less space to install the equipment, in particular the acoustic panels used to attenuate the noise of the fan. Thus, the volume and the integration of the equipment become major issues, in particular the installation of acoustic panels in the secondary duct of the engine.
Technically, in order to make an effective acoustic insulation, the implementation must respect the so-called “mass/spring/mass” principle: two masses are separated by a spring, for example a blade and an insulator. The spring between the two masses attenuates the energy of the sound and is thus used as a noise damper.
The present invention aims in particular at providing an acoustic treatment equipment allowing to reduce the thickness of the acoustic panels while maintaining the same efficiency.
This is made, in accordance with the invention, by means of a noise reducing device for an aircraft turbine engine, this device having a structure in the form of a stack of layers, such that a first and a second skin made of composite material form a first and a second outer layers, the first and second outer layers being substantially parallel to one another, the first and second outer layers enclosing a central layer having a honeycomb structure comprising partitions extending transversely from the first outer layer to the second outer layer, so as to form cavities. This device is characterized in that the partitions of the honeycomb structure of the central layer are made of viscoelastic material, and in that said partitions form, with the first and second outer layers, an acute angle of inclination, for example comprised between 10 degrees and 80 degrees.
Thus, the thickness of the acoustic panels is reduced while maintaining the same efficiency. By reducing the thickness of the acoustic panels, the diameters of the casings are reduced. The reduction of these diameters allows to reduce the diameter of the nacelle as a whole. All of these diameter reductions allow an overall weight saving for the entire engine.
The device according to the invention may comprise one or more of the following characteristics, taken alone or in combination with each other:
The invention also relates to an outer fan module casing comprising a device as defined above, for example, intended to be arranged immediately upstream or immediately downstream of the fan, considering the upstream and the downstream with respect to the air flow passing through a turbine engine provided with a fan.
The invention also relates to a method for manufacturing a device according to any of the preceding claims, characterized in that it comprises a step in which the cavities are made in the central layer by piercing a solid panel of viscoelastic material.
The method according to the invention may comprise one or more of the following characteristics, taken alone or in combination with each other:
The method further comprises the following steps:
Further characteristics and advantages of the invention will become apparent from the following detailed description, for the understanding of which reference is made to the attached drawings in which:
As shown in
An acoustic treatment area Z1, Z2 mainly comprises an acoustic panel forming a noise reducing device 18 (see
The main criteria allowing an optimal acoustic treatment are the surface area and the distance travelled by the sound wave to be attenuated in a cavity.
The targeted frequency range extends typically from 400 to 4 KHz for an engine of the “Ultra High By Pass Ratio”(UHBR) type typically used by the applicant.
As illustrated in
The device 18 being integrated into the nacelle of the aircraft, the first outer layer (inner skin) 22 is in contact with the air flowing inside the secondary duct 16 and the second outer layer (outer skin) 24 is in contact with the air circulating around the nacelle.
In order to associate the desired acoustic function (reduction of noise) with the device 18 and to allow the air circulating in the secondary duct 16 to penetrate the central layer 20, perforations are made in the inner skin 22. These openings typically have a diameter D of 5 mm.
In order to obtain good acoustic performance, it is conventional to opt fora perforation rate of the inner skin 22 comprised between 5 and 12%. This rate is preferably in the order of 10%. The air is thus driven into the central layer 20 and the sound produced is reduced. Indeed, the partitions 26 form the is cavities 28 called resonant cavities. Under the effect of the passage of the air, the partitions 26 of said cavities 28 vibrate and, if the dimensions are well calculated, enter into resonance.
The frequency tuning, i.e. the optimization which allows to reach a maximum dissipation of the frequencies to be attenuated, is done mainly by modulation of the volume of the resonant cavities 28. The geometric characteristics of the partitions 26 are therefore defined according to the targeted acoustic performance.
Classically, in the prior art, the cavities 28 have a depth P of the order of 40 mm for the targeted application, as seen in
The invention proposes to reduce the thickness of the acoustic treatment areas Z1, Z2. As seen in
It is apparent that any acute angle α between the first face of the partition 26 and the outer layers 22, 24 implies the presence of an obtuse angle β between the second face of the partition 26 and the outer layers 22, 24, as visible in
The partitions 26 of the central layer 20 thus all have the same angle of inclination α with the first and the second outer layers 22, 24. This angle of inclination α is acute, for example being comprised between 10 degrees and 80 degrees. Good results are obtained by considering, for example, an acute angle between 10 degrees and 50 degrees. The angle values closer to 10 degrees than 50 degrees are preferred.
Each partition 26 of the central layer 20 has a thickness comprised between 3 and 7 mm, and preferably 5 mm. As seen in
The honeycomb structure of the central layer 20 is made of viscoelastic material. This viscoelastic material can, for example, be an organic foam or a metallic foam.
This inclined honeycomb structure is obtained by means of a method applied to a solid panel of viscoelastic material (e.g. organic or metallic foam).
This solid panel has two surfaces that are substantially parallel to one another. The height of the solid panel is approximately 25 mm. The solid panel is intended to form the central layer 20.
The method here comprises five steps listed below:
The piercing of the solid panel is obliquely made so that each cavity 28 to has a height forming part of a plane which is not perpendicular to the surfaces of the panel.
The piercing step can be made by means of piercing barrels which can be used as a guide in order to respect the angle of inclination α chosen.
The depth P of the piercing made is based on the length equivalent to the performance of the expected application, in this case 40 mm.
Thus, with this method for piercing foam, the person skilled in the art has a very large degree of freedom in the choice of both the angle of inclination α and the length of the partitions 26. Indeed, once the acoustic model has been modelled, the piercing of the panel can be easily made with a satisfactory accuracy. The method according to the present invention allows to get rid of the difficulties related to the assembly of an inclined honeycomb structure. All that remains is to add the outer layers 22, 24 and to perforate the inner outer layer 22 and the device 18 is functional. Thus, in addition to the space saving due to the height of the panels, the weight saving due to the reduced diameter of the outer casing, the weight and drag saving of the aircraft due to the reduction of the outer surfaces of the nacelle, there is a time saving during the manufacturing of the device 18.
Number | Date | Country | Kind |
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1900548 | Jan 2019 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FR2020/050078 | 1/22/2020 | WO | 00 |