1. Field
This disclosure generally relates to the placement of plies on a substrate, and deals more particularly with a method and apparatus for placing plies on a curved substrate that avoids wrinkling or bridging of the ply.
2. Background
Composite structures may be fabricated by laying up a number of plies comprising woven or knitted fabric pre-impregnated with a carrier, such as a synthetic resin. During hand layup, successive plies are laid up by hand over a tool, and the fabric may be swept by hand in order to reduce possible wrinkling and bridging of the fabric. In some cases, where unacceptable wrinkling or bridging may occur in spite of sweeping, the plies must be lifted and reapplied in order to reduce the wrinkling/bridging. Plies may also be lifted and reapplied to shift the ply to meet ply placement tolerances.
To reduce dependency on hand layup and increase manufacturing flow rate, automated techniques have been devised for controlled placing of the plies during layup which substantially avoids wrinkling and bridging, and thus eliminates the need for rework. For example, automated equipment and methods for placing plies are disclosed in U.S. Pat. Nos. 7,004,219 and 7,213,629, and US Patent Publication number US 2006/0260751 A1, all owned by The Boeing Company, the entire disclosures of which are incorporated by reference herein.
U.S. Pat. No. 7,213,629 referred to above discloses a vacuum assisted ply placement shoe that may be used to place plies on a substantially flat substrate. The shoe includes a pair of straight edge seals respectively engaging the substrate and the ply to form an enclosed area in which a partial vacuum may be drawn. The partial vacuum draws the ply onto the substrate, and in combination with the ply seal, essentially eliminates wrinkling and bridging of the ply. While this placement shoe provides satisfactory results when used to place plies on flat substrates, it may not be effective for use with curved substrates because of the difficulty in maintaining a vacuum between the ply and curved substrate. In addition, wrinkling and/or bridging of the ply may occur because the ply is fed across a straight edge seal onto the curved substrate.
Accordingly, there is a need for a method and apparatus for placing plies on curved substrates that employs vacuum assisted ply placement with high accuracy while eliminating wrinkles or bridging of the ply. Embodiments of the disclosure are intended to satisfy this need.
In accordance with the disclosed embodiments, a method and apparatus provide for vacuum assisted placement of plies on curved substrates, without wrinkling or bridging of the plies. The apparatus employs a curved guide edge and a guide surface that cooperate to conform the ply to the curvature of the substrate as the ply is fed during the placement process. The shape of the curved guide edge and guide surface may be adjusted to accommodate substrates of different curvatures.
According to one disclosed embodiment, apparatus is provided for placing a ply on a curved substrate, comprising: a substrate seal providing an essentially gas impermeable interface with the substrate; a curved guide edge for producing an essentially gas impermeable ply seal with the ply, the curved guide edge extending laterally relative to the ply and having a curvature related to the curvature of the substrate; and, a vacuum manifold adapted to be coupled with a vacuum source for drawing the ply down onto the substrate. The apparatus may further include a guide surface contiguous with the curved edge of the ply seal for guiding the ply toward the curved edge. Means may be provided for changing the curvature of the curved guide edge, including at least one motor member and a programmed controller for controlling the motor member. The curvature of the curved guide edge generally matches the curvature of the substrate.
According to another disclosed embodiment, apparatus is provided for placing a flexible ply on a curved substrate, comprising: a guide surface over which the ply may be guided onto the substrate as the apparatus and the substrate are moved relative to each other. The guide surface terminates in a guide edge over which the ply passes as the ply is placed on the curved substrate. The guide surface has a curvature generally matching the contour of the ply as the ply passes over the guide edge and is placed onto the substrate. The apparatus further includes a suction device for drawing the ply down over the guide edge and onto the curved substrate. The apparatus may further comprise a substrate seal providing an essentially gas impermeable interface with the substrate, wherein the suction device is coupled between the substrate seal and the guide edge to reduce air pressure beneath the ply. The guide surface may comprise a flexible material or a plurality of individually adjustable, rigid segments having a shape that may be reconfigured to match a particular substrate curvature.
According to a disclosed method embodiment, a ply may be placed on a curve substrate by the steps comprising: feeding the ply over a curved edge of a guide surface onto the substrate; and, adjusting the inclination of the guide surface until the curvature of the curved edge generally matches the curvature of the curved substrate. The method may further include drawing the ply down onto the curved substrate by reducing the ambient air pressure between the ply and the curved substrate.
According to still another method embodiment, a ply is placed on a curved substrate by the steps comprising: moving a vacuum assisted ply placement device over the curved substrate; adjusting the curvature of a curved guide edge on the device to generally conform to the curvature of the substrate; and, feeding the ply over the curved guide edge onto the curved substrate. The method may also include determining the curvature of the curved substrate. The curvature of the curved guide edge may be adjusted by altering the inclination of the device relative to the curved substrate. The curvature of the curved guide seal may also be adjusted by either displacing individual portions of the curved guide edge or by deforming portions of the curved guide edge.
Other features, benefits and advantages of the disclosed embodiments will become apparent from the following description of embodiments, when viewed in accordance with the attached drawings and appended claims.
Referring first to
The device 20 broadly includes a ply guide 22, a substrate seal 40 and a vacuum manifold 38. The ply guide 22 guides the ply 24 onto the substrate surface 28 and is spaced slightly above the substrate surface 28 to form a gap 42. The ply guide 22 includes a curved guide edge 32 that engages the bottom face of the ply 24 and forms a substantially gas impermeable ply seal 33 (
Depending upon the construction of the ply 24, it may be necessary or desirable to apply a backing on the top of the ply 24 which is gas impermeable so that air is not drawn through the ply 24 in the area of the gap 42, thus maintaining the requisite suction force. The ply 24 may be drawn from the feed roll 34 and trained around guide roller 48 before being fed onto the ply guide 22. Depending upon the application, a pressure foot 46 may be needed to press the ply 24 against the curved guide edge 32 and/or the substrate surface 28. The device 20 may include various other features not shown in the drawings. For example, the device 20 may include a ply cutoff device (not shown), a ply heater (not shown), edge seal devices (not shown) and various sensors (not shown) for sensing physical parameters, such as the location of ply edges, the current location of the device 20 and the curvature of the substrate surface 28. Further details of these additional features may be found in U.S. Pat. No. 7,213,629 previously mentioned.
Referring now also to
The shape of the guide surface 30 and guide edge 32 may be calculated using two relationships. First, the distance on the ply 24 from line “1” to line “2” shown in
Equations (1)-(8) set out below may be used to calculate the shape of the guide surface 30 and the curvature of the guide edge 32.
A+B=C+D (1)
A+B cos θ=C+D cos φ (2)
B sin θ=D sin φ+h (3)
h=R−½√{square root over (4R2−w2)} (4)
Using selected values for C, D, R, φ, and w, the unknown values A, B, θ and h may be calculated using the following equations:
tan(θ/2)=(1−cos θ)/sin θ (5)
θ=2 tan−1[D(1−cos φ)/(D sin φ+h)] (6)
B=(D sin φ+h)/sin θ (7)
A=C+D−B (8)
Lines 1 and 2 represent lines on the ply 24 that extend perpendicular to the centerline “CL” of the ply guide 22 and whose positions may be arbitrarily selected such that line 1 lies on the ply 24 in the area where the ply 24 is planar before reaching the ply guide 22, and line 2 lies on the ply 24 after the ply 24 has been placed on the substrate surface 28. At any perpendicular distance on the ply 24 from the ply guide centerline CL, distance A comprises the distance from line 2 to the guide edge 32, and distance B comprises the distance from line 1 to the curved guide edge 32, and Φ comprises the angle or slope of the guide surface 30. At any point along the centerline CL, distance C comprises the distance from line 2 to the curved guide edge 32 and distance D comprises the distance from line 1 to the curved guide edge 32. R is the radius for the substrate surface 28, and Θ comprises the angle or slope of the guide surface 30 at the centerline CL. w comprises the distance from the line of length A on the substrate surface 28 on line 2 to its mirror image on the other side of the centerline CL. h is the height of the arc created by w. The values of C, D and Φ may be arbitrarily selected, and w is the incrementally increasing width of the arc up to the width of the particular ply 24 that has been selected. The values of A, B, Θ and h may be calculated for each value of w to provide points for generating the curved guide edge 32.
Equations (1)-(4) describe the trigonometric relationships which can be used to develop the solution equations (5)-(8). Equations (5)-(8) allow the calculation of points on the guide edge 32 from which the appropriate curve can be generated. The guide surface 30 may be generated as a ruled surface between the guide edge 32 and a straight line representing the top edge 35 of the guide surface 30. The inclination angle Φ of the substrate surface 28, the curvature of the edge curve 32 and the shape of guide surface 30 may vary, within limits, from nominal calculated values without compromising the functionality of the device, depending upon the particular application. The height of the gap 42 may be selected based on empirical knowledge, vacuum strength, stiffness of ply and other variables. In one satisfactory embodiment, gap 42 may be between approximately ⅛ and ¼ inches.
In one embodiment, the ply guide 22 may comprise a substantially rigid material such as, without limitation, metal or plastic that may be fabricated by a variety of techniques, such as without limitation, NC machining, injection molding, sterolithography or other common fabrication techniques. When assembling the device 20, the ply guide 22 may be positioned such that the centerline CL relative to the substrate surface 28 matches the angle Φ that is calculated using the equations (5)-(8) for a particular application. Also, the guide edge 32 may be positioned a short distance above the substrate surface 28 in order to form the gap 42, which causes the ply 24 to be subjected to the vacuum between the guide edge 32 and the substrate seal 40. In order to enhance adhesion of a composite prepreg ply 24 to the substrate surface 28, heat 43 may be applied to the ply 24 just prior to the ply 24 contacting the substrate surface 28. This heating process increases the tackiness of the ply 24, thereby assuring that the ply 24 adheres to the substrate surface 28 without subsequent bridging or wrinkling.
Referring now also to
The method and apparatus of the disclosed embodiments may be employed to layup (place) plies 24 onto tapered conical or compound curved substrate surfaces 54. For example, as shown in
The method and apparatus of the disclosed embodiments may be employed to layup (place) plies 24 onto cylindrical, tapered conical or compound curved substrate surfaces at any angle to the axis of the substrate 26. For example, and without limitation, the device 20 may be oriented to travel at 45° or any other helical angle on a cylindrical substrate. The inclination angle Φ of the ply guide 22 may be continuously varied, as required, to match the changing shape of tapered conical or compound curved substrate surfaces 28. For example, a tapered ply course 57 extending in a cross pattern partially around the fuselage 50 would have a radius that varies along its length and may be placed using the method and apparatus of the disclosed embodiments. The equations described previously for calculating the device edge curvature 32 and guide surface 30 may still apply since the helical path merely changes the radius R of the substrate surface 28 (
The shape of the guide surface 30 and guide edge 32 may be varied to match the contour of the fuselage 50 by using an alternate embodiment 20a of the ply placement device shown in
Attention is now directed to
The controller 66 may control a machine drive 68 which drives the device 20 over the substrate 26. For example, the machine drive 68 may drive the frame 56 along the guide rails 58, as shown in
Attention is now directed to
Embodiments of the disclosure may find use in a variety of potential applications, particularly in the transportation industry, including for example, aerospace and automotive applications. Thus, referring now to
Each of the processes of method 96 may be performed or carried out by a system integrator, a third party, and/or an operator (e.g., a customer). For the purposes of this description, a system integrator may include without limitation any number of aircraft manufacturers and major-system subcontractors; a third party may include without limitation any number of vendors, subcontractors, and suppliers; and an operator may be an airline, leasing company, military entity, service organization, and so on.
As shown in
Apparatus and methods embodied herein may be employed during any one or more of the stages of the production and service method 96. For example, components or subassemblies corresponding to production process 102 may be fabricated or manufactured in a manner similar to components or subassemblies produced while the aircraft 98 is in service. Also, one or more apparatus embodiments, method embodiments, or a combination thereof may be utilized during the production stages 102 and 104, for example, by substantially expediting assembly of or reducing the cost of an aircraft 98. Similarly, one or more of apparatus embodiments, method embodiments, or a combination thereof may be utilized while the aircraft 98 is in service, for example and without limitation, to maintenance and service 110.
Although the embodiments of this disclosure have been described with respect to certain exemplary embodiments, it is to be understood that the specific embodiments are for purposes of illustration and not limitation, as other variations will occur to those of skill in the art.
This application is a divisional of application Ser. No. 11/941,931, filed Nov. 17, 2007, status allowed. This application is related to U.S. patent application Ser. No. 11/116,222 filed Apr. 28, 2005 and published Nov. 23, 2006 as Publication No. US 2006/0260751 A1, the entire contents of which are incorporated by reference herein.
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Entry |
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Number | Date | Country | |
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20110192541 A1 | Aug 2011 | US |
Number | Date | Country | |
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Parent | 11941931 | Nov 2007 | US |
Child | 13091503 | US |