This application relates to a method of making a composite structure and structures made by the method.
Current designs of many structural components require load-bearing panels. These may be formed of composites or metal.
In composite manufacture, such elements may be used as beam elements.
The current methods for manufacturing such components involve multiple labor intensive processes and steps. This can result in relatively high manufacturing costs. In addition, the distinct method steps can often result in a variation across several parts.
A method of forming a composite structure includes passing a web that is impregnated with an uncured resin in an assembly direction. Foam is forced about opposed sides of the web with the web including corrugations at least after this step. Outer skins of a fiber mat are attached onto outer sides of the web and foam. The fiber mat is impregnated with a resin. The combination of the fiber mats, the foam and the web is thermoformed in a mold to provide a shape for a structure.
These and other features may be best understood from the following drawings and specification.
As shown in
Extrusion dies 146 extrude foam 30, which is forced onto sides of the corrugations 37 by rollers 147 and 148. In addition, outer skins 35 are formed onto a composite panel at 151. Rollers 147 and 148 urge the foam cores 30 to fill the corrugation 37 and simultaneously urge the skins 35 to cover the corrugations 37 and the foam core 30.
The skins 35 are formed of a fiber felt or mat and may be impregnated with a resin. Generically, the material of the skins may be called a mat, even if formed of felt. A cutting tool 150 cuts sections 155 of an intermediate product.
From roller 135 to cutting tool 150, the material moves along an assembly direction A.
The sections 155 may be then placed in a thermoforming mold 165 and formed to a shape as shown at 167. In the thermoforming step 165, the impregnated resins in the web 25 and skins 35 are thermoset all in a single step. In addition, as shown at 160, a final shaped structure is achieved. As will be understood, appropriate motors are provided to drive rollers 135, 130, 147 and 148.
The structure 160 may have any number of applications, however, in one anticipated application, it will have use in the aerospace industry. As an example, material may be shaped to form nacelles, nacelle components, fuselage panels and structural components, turbine blades, propellers, other airfoils, or any number of other structures where high-load bearing and/or impact resistant performance is needed at reduced weight, with the latter requirement not being a limiting case for the disclosed applications and structures.
The web 25 may be a polymer, carbon, fiberglass, quartz, or aramid-fiber composite or combinations of those several materials. The web 25 and its corrugation form a load distribution and bearing element in the final structure 160 or 260.
The foam 30 may be a low density polymer foam, such as a thermoplastic polymer foam, including polyetherimide (PEI) foam, polyphenylsulfone (PPSU) foam, polysulfone (PSU) foam, polyether ether ketone (PEEK) foam, and polyethersulfone (PES) foam, among others. The foam may have the density ranging from 500-10 kg/m3. The foams can be unfilled or filled with a carbon or glass fibers.
While
The foam layers 602 may be preformed into the shape, and may be a thermoplastic or a thermoset polymer foam. Thermoset polymer foams include structural polyurethane foams, and may have densities ranging from 200-500 kg/mg3.
The web 606 may be impregnated with additional resin, as an adhesive, to secure the layers, and may be assembled in a vacuum bag or mandrel. A worker of ordinary skill in this art would recognize various alternatives given the disclosure of this application.
The skin 35 may be formed of a carbon fiber or organic fiber or fiberglass felt or mat. The skins 35 provide outer mechanical support to the final structures 160, 260.
The web 25 and skins 35 will be impregnated by a polymer resin and, in one disclosed embodiment, a thermoset polymer. Upon curing in the thermoforming stage, the web 25, skin 35 and foam core 30 are all bonded together.
Any number of polymer thermosetting resins can be utilized, including epoxies, phenolics, BMI (bismaleimides) and cyanates.
While the thermoforming step 165 is disclosed as fully curing the structure 160 or 260, partial curing may also be performed. A final curing or post-curing stage can then be used to complete the manufacture. A sequential partial cure followed by a final cure may be beneficial to control thermal or mechanical stresses in the structure.
A height D or thickness across the material may be controlled as may be a spacing S between corrugations 37. These variables can be controlled to achieve desirable characteristics for the final structure 160 and 260.
The depth of the corrugation or thickness of the component D and a peak to peak distance S may be targeted for mechanical demands and can be selectively tuned to desired values, designed and optimized to the targeted final product.
The depth D and a profile of the web 25 can be tuned along a machine direction or a cross-direction of the web. If a machine-direction profiling is used, several full width corrugated pre-impregnated sheets may be laid into the thermoforming mold (such as shown in
As shown in
Although an example method and product are disclosed, a worker of ordinary skill in this art would recognize that certain modifications would come within the scope of this invention. For that reason, the following claims should be studied to determine the true scope and content of this invention.
This application claims priority to U.S. Provisional Application No. 61/718,365, which was filed Oct. 25, 2012.
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Number | Date | Country | |
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20140120317 A1 | May 2014 | US |
Number | Date | Country | |
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61718365 | Oct 2012 | US |