Adhesive bonding and miscellaneous chemical manufacture – Methods – Surface bonding and/or assembly therefor
Reexamination Certificate
2001-11-19
2004-01-13
Aftergut, Jeff H. (Department: 1733)
Adhesive bonding and miscellaneous chemical manufacture
Methods
Surface bonding and/or assembly therefor
C156S091000, C156S166000, C029S525070, C411S904000
Reexamination Certificate
active
06676785
ABSTRACT:
TECHNICAL FIELD
The present invention relates to an improvement in the field of composite laminate structures known as sandwich structures formed with outside skins of a polymer matrix composite and an internal core of either foam, end-grain balsa wood, or honeycomb, and more specifically to the field of these sandwich structures which additionally have some type of Z-axis fiber reinforcement through the composite laminate and normal to the plane of the polymer matrix composite skins.
BACKGROUND ART
There is extensive use in the transportation industry of composite laminate structures due to their lightweight and attractive performance. These industries include aerospace, marine, rail, and land-based vehicular. The composite laminate structures are made primarily from skins of a polymer matrix fiber composite, where the matrix is either a thermoset or thermoplastic resin and the fiber is formed from groupings of fiber filaments of glass, carbon, aramid, or the like. The core is formed from end-grain balsa wood, honeycomb of metallic foil or aramid paper, or of a wide variety of urethane, PVC, or phenolic foams, or the like.
Typical failures in laminate structure can result from core failure under compressive forces or in shear or, most commonly, from a failure of the bond or adhesive capability between the core and the composite skins (also known as face sheets). Other failures, depending on loading may include crimpling of one or both skins, bending failure of the laminate structure, or failure of the edge attachment means from which certain loads are transferred to the laminate structure.
Certain patents have been granted for an art of introducing reinforcements that are normal to the planes of the skins, or at angles to the normal (perpendicular) direction. This is sometimes called the “Z” direction as it is common to refer to the coordinates of the laminate skins as falling in a plane that includes the X and Y coordinates. Thus the X and Y coordinates are sometimes referred to as two-dimensional composite or 2-D composite. This is especially appropriate as the skins are many times made up of fiber fabrics that are stitched or woven and each one is laid on top of each other forming plies or layers of a composite in a 2-D fashion. Once cured these 2-D layers are 2-D laminates and when failure occurs in this cured composite, the layers typically fail and this is known as interlaminar failure.
The patents that have been granted that introduce reinforcements that are normal to the X and Y plane, or in the generally Z-direction, are said to be introducing reinforcements in the third dimension or are 3-D reinforcements. The purpose of the 3-D reinforcement is to improve the physical performance of the sandwich structure by their presence, generally improving all of the failure mechanisms outlined earlier, and some by a wide margin. For example, we have shown that the compressive strength of a foam core laminate structure with glass and vinyl ester cured skins can be as low as 30 psi. By adding 16 3-D reinforcements per square inch, that compressive strength can exceed 2500 psi. This is an 83 times improvement.
Childress in U.S. Pat. No. 5,935,680, Boyce et al in U.S. Pat. No. 5,741,574 as well as Boyce et al in U.S. Pat. No. 5,624,622 describe Z-directional reinforcements that are deposited in foam by an initial process and then secondarily placed between plies of fiber fabric and through heat and pressure, the foam crushes or partially crushes forcing the reinforcements into the skin. Practically, these reinforcements are pins or rods and require a certain stiffness to be forced into the skin or face layers. Although Boyce et al describes “tow members” as the Z-directional reinforcement, practically, these are cured tow members, or partially cured tow members that have stiffness. As Boyce et al describes in U.S. Pat. No. 5,624,622, compressing the foam core will “drive” the tow members into the face sheets. This cannot be possible unless the Z-directional or 3-D reinforcements are cured composite or metallic pins.
A standard roll of fiberglass roving from Owens Corning, typically comes in various yields (of yards per pound weight) and a yield of 113 would contain on a roll or doft 40 lbs. of 113 yield rovings. In the uncured state, these rovings are multiple filaments of glass fiber, each with a diameter of less than 0.0005 inches. The roving, uncured as it comes from Owens Corning, is sometimes called a “tow”, contains hundreds of these extremely small diameter filaments. These hundreds of filaments shall be referred to as a “grouping of fiber filaments.” These groupings of fiber filaments can sometimes be referred to, by those skilled in the art, as tows. It is impossible to drive a virgin glass fiber tow, or grouping of fiber filaments, as it is shipped from a glass manufacturer such as Owens Coming, through a face sheet. The grouping of fiber filaments will bend and kink and not be driven from the foam carrier into the skin or face sheets as described by Boyce et al. Therefore, the “tow” described by Boyce et al must be a rigid pin or rod in order for the process to work as described. It will be shown that the present invention allows easily for the deposition of these groupings of fiber filaments, completely through the skin-core-skin laminate structure, a new improvement in this field of 3-D reinforced laminate structures.
This issue is further verified by an earlier patent of Boyce et al, U.S. Pat. No. 4,808,461, in which the following statement is made: “The material of the reinforcing elements preferably has sufficient rigidity to penetrate the composite structure without buckling and may be an elemental material such as aluminum, boron, graphite, titanium, or tungsten.” This particular referenced patent depends upon the core being a “thermally decomposable material”. Other US Patents that are included herein by reference are: Boyce et al, U.S. Pat. No. 5,186,776; Boyce et al U.S. Pat. No. 5,667,859; Campbell et al U.S. Pat. No. 5,827,383; Campbell et al U.S. Pat. No. 5,789,061; Fusco et al. 5,589,051.
None of the referenced patents indicate that the referenced processes can be automatic and synchronous with pultrusion, nor do they state that the processes could be synchronous and in-line with pultrusion. Day describes in U.S. Pat. Nos. 5,589,243 and 5,834,082 a process to make a combination foam and uncured glass fabric core that is later molded. The glass fiber in the core never penetrates the skins of the laminate and instead fillets are suggested at the interface of the interior fiber fabric and the skins to create a larger resin fillet. This is a poor way to attempt to tie the core to the skins, as the fillet will be significantly weaker than if the interior fiber penetrated the skins. Day has the same problem that Boyce et al have as discussed earlier. That is, the interior uncured fabric in Day's patent is limp and cannot be “driven” into the skins or face sheets without being rigid. Thus the only way to take preinstalled reinforcements in foam, and then later mold these to face sheets under pressure, and further have the interior fiber forced into the skins, is to have rigid reinforcements, such as rigid pins or rods or, as in Day's case, rigid sheets.
Boyce et al in U.S. Pat. No. 5,186,776 depends on ultrasound to insert a fiber through a solid laminate that is not a sandwich structure. This would only be possible with a thermoplastic composite that is already cured and certain weaknesses develop from remelting a thermoplastic matrix after the first solidification. Ultrasound is not a requirement of the instant invention as new and improved means for depositing groups of fiber filaments are disclosed. U.S. Pat No. 5,869,165 describes “barbed” 3-D reinforcements to help prevent pullout. The instant invention has superior performance in that the 3-D groups of fiber filaments are extended beyond the skins on both sides of the composite laminate, such that a riveting, or clinching, of the ends of the filaments occurs when the ends of the filaments are en
Garrett Scott A.
Hook James M.
Johnson David W.
Moyers Steven G.
Aftergut Jeff H.
Ebert Composites Corporation
Procopio Cory Hargreaves & Savitch LLP
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