The invention relates to noise attenuation structures for aircraft, and more particularly relates to a linear acoustic liner for aircraft engine nacelles and the like.
Acoustic attenuation panels are known for lining the walls of nacelles of aircraft jet engines. Such acoustic structures often are referred to as acoustic liners. Generally, acoustic liners include a cellular core, such as a honeycomb structure, covered on its exterior side by an acoustically resistive front skin, and, on the opposite side, with a reflective back skin. Such a structure is known as a single degree of freedom (SDOF) acoustic liner. Other acoustic liners include a pair of superimposed honeycomb cores separated by a second acoustically resistive layer (or septum), an acoustically resistive front skin, and a reflective back skin, and are known as double degree of freedom (DDOF) liners. Generally, SDOF acoustic liners can be preferable to DDOF acoustic liners because SDOF liners generally are less costly to produce, and are lighter in weight than DDOF liners. Linear SDOF acoustic liners can be preferable because they are capable of attenuating noise across a broader range of frequencies and operating conditions than non-linear SDOF liners.
An acoustically resistive layer is a porous structure that at least partially dissipates acoustic energy by at least partially transforming incident acoustic energy into heat. Often, the acoustically resistive layers used in acoustic liners include continuous thin sheets of material having a plurality of spaced openings or perforations, a sheet of porous layer, or a combination of both. In acoustic liners like those described above, the cells of the honeycomb structure covered by the acoustically resistive face skin form resonant cavities that contribute to the dissipation of incident acoustic energy by canceling acoustic reflected waves and or converting acoustic energy into heat, such as by Helmholtz resonance.
One example of the construction of a prior art SDOF acoustic liner is shown in
The SDOF acoustic liner shown in
A second construction of a prior art SDOF linear acoustic liner 20 is shown in
Though both of the linear acoustic liners 10, 20 described above can effectively attenuate acoustic energy over relatively wide bandwidths and operating conditions, the porous layer layers 18 of such liners 10, 20 sometimes can at least partially separate from the perforate face sheet 16 and/or honeycomb core 14. For example, the bond between a stainless steel wire layer and an aluminum face sheet or aluminum core may eventually corrode, resulting in unwanted separation of the face sheet from the core. Because such separation of layers is undesirable, there is a need for an improved SDOF linear acoustic liner that is simple in construction, and has enhanced structural durability as compared to the liners 10, 20 described above.
A linear acoustic liner for an aircraft can include a cellular core having a first surface and an opposed second surface. A substantially imperforate back skin can cover the first surface of the core. A perforate face skin can cover the second surface of the core, and include an outer face skin layer having a first plurality of spaced openings extending therethrough. The perforate face skin can further include an inner face skin layer having a second plurality of spaced openings extending therethrough, and a porous layer disposed between the outer face skin layer and the inner face skin layer. Each of the first plurality of spaced openings can be substantially aligned with one of the second plurality of spaced openings.
A method of producing a linear acoustic liner can include placing a release layer between at least one outer composite layer and at least one inner composite layer, and restraining the outer and inner composite layers in a desired configuration. The method can further include curing the outer and inner composite layers in the restrained configuration, and forming a plurality of spaced openings through the cured outer and inner composite layers. In addition, the method can include separating the cured outer composite layer and the cured inner composite layer from the release layer, inserting a porous layer and a first adhesive material between the cured outer and inner layers, and realigning the spaced openings in the outer and inner composite layers. The method can further include placing the assembled inner and outer composite layers and porous layer over a first face of an open cell core with a second adhesive material therebetween, placing at least one imperforate composite layer over a second face of the open cell core, and curing the first and second adhesive materials and the back skin to form a bonded assembly.
These and other aspects of the invention will be understood from a reading of the following description together with the drawings.
In one embodiment, the porous layer 118 is a sheet of fine woven stainless steel wire having a thickness of about 0.006 inch and a flow resistance of about 20 CGS Rayls (centimeter-gram-second system of units) to about 60 CGS Rayls. Alternatively, the porous layer 118 can be a fine woven polyaryletherketone (PAEK) layer, or any other thin porous material that is durable and has desired acoustic properties. For example, the porous layer 118 can be a micro-perforated polymeric film, a metallic fibrous felt, or any of a number of various other fibrous materials, including graphite, nylon, polyetheretherketone (PEEK), or the like. The outer perforated layer 116, inner perforated layer 130, and back skin layers 112 can be sheets of a composite material of a type well known in the art. For example, the perforated layers 116, 130, and back skin 112 can be comprised of carbon epoxy composite sheets.
As shown in
As also shown in
The honeycomb core 114 can be constructed of a metallic or a composite material of a type well known in the art. For example, the core 114 can be a fiberglass honeycomb core having a cell size from about 3/16 inch to about ¾ inch, and a core depth from about 0.5 inch to about 2 inches. A cellular core 114 having other cell shapes, cell sizes, cell depths, and material of construction also can be used
As described in detail below, the perforated outer face skin 116 and perforated inner face skin 130 can be bonded to the porous layer 118 by an adhesive 160 of a type known in the art. For example, the face skins 116, 130 can be bonded to the porous layer 118 by a low-flow or no-flow adhesive system, such as nitride phenol adhesive, or the like.
As shown in
As shown in
The outer skin layers 116, 130 can be prepared 240 for final assembly by applying a spray adhesive 160 to those surfaces of the skins 116, 130 that will contact the porous layer. As shown in
One embodiment of a final lay-up sequence of the liner 100 is shown in
The assembled layers and the form tool 199 can be bagged 255 for curing in a manner known in the art. The assembly and tool 199 can be heated to an elevated temperature and maintained at the elevated temperature for a sufficient time to cure the composite materials and bond the layers together. For example, the composite materials may be cured at about 355 degrees Fahrenheit at a pressure of about 70 pounds per square inch (PSI) for about 120 minutes. Other temperatures, pressures and times also may be used depending upon the cure requirements for the composite materials selected.
Once cooled, the cured liner assembly 100 can be removed 265 from the form tool 199. The cured assembly then can be trimmed 270 to complete production of the acoustic liner 100.
In an alternative embodiment of a lay-up sequence, the opposed faces of the perforated outer face skin 116 and the perforated inner face skin 130 can be sprayed with layers of adhesive 160A, 160B, and the porous layer 118 assembled therebetween. Again, one or more alignment pins 190 can be inserted into the tooling holes 192 to establish and maintain the alignment between the first and second openings 117, 137. The assembled layers 116, 118 and 130 then can be bagged and cured in a conventional manner. After the perforated face skin 102 is cured and trimmed, the face skin 102 and the back skin layers 112 can be bonded to the core 114 using a suitable forming tool and conventional composite material bonding techniques.
Various aspects and features of the invention have been described above with reference to various specific embodiments. Persons of ordinary skill in the art will recognize that certain changes and modifications can be made to the described embodiments without departing from the scope of the invention. All such changes and modifications are intended to be within the scope of the appended claims.
This application claims priority to U.S. provisional application Ser. No. 60/956,043 filed Aug. 15, 2007.
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