Patent Description:
Carbon fiber reinforced plastic materials (CFRPs) have utility in structures including, without limitation, vehicles including, without limitation, aircraft. CFRPs comprise a fiber material (e.g. carbon fibers, etc.) impregnated with a resin material (e.g. epoxy resin, acrylic resin, etc.) to make so-called prepregs. Prepregs are partially cured layers that can be manufactured into rolls that can yield unrolled sheets for use in composite material manufacture. Prepreg material, or "prepregs" can then be "laid-up" or "stacked" into multi-layered "stacks" that can be shaped on forming mandrels or other tooling, followed by curing or partially curing the shaped material to produce a composite material that, if desired, adopts desired and predetermined shapes and dimensions imparted by the tool, with the composite material having desired weight and strength. Alternately, prepregs may be oriented into a stack that is trimmed and cured to form a solid stack for use as a composite material structure or other type of composite component.

CRFPs can be used as structural components in aircraft (e.g. stringers, spars, ribs, etc.). Over time, a composite material, such as those comprising CFRPs, may experience fissures or cracks, requiring repair or replacement. Such repair or replacement is time-consuming and costly as the larger structure comprising the composite material must be taken out of service. Attempts to protect components comprising CFRPs and other composite materials can include an overwrap, or other layer, for example, a cured fabric layer, to afford a compressive force to, and otherwise reinforce and protect the composite material. However, at times, protective overwrap materials, such as, for example, curable fabric material shells, etc., may possess characteristics that can contribute to the degradation of the underlying composite material. For example, if an overwrap shell material has a different coefficient of thermal expansion (CTE), and/or a different Young's modulus as compared with the CTE and modulus of the composite material the overwrap material may not afford the composite material adequate protection from damage or degradation, and may contribute to such degradation. For the purpose of the present disclosure, the term "modulus" is used equivalently and is therefore interchangeable with the term "Young's modulus", unless explicitly stated otherwise.

A mismatch in the CTE and/or modulus of the composite stack and the shell material overwrapping the composite stack can cause damage to the composite stack of the stacked-up prepreg ply assembly (e.g. the composite material "stack") shrinks or expands to a greater extent as compared to the overwrap shell. As a result, curing and "wrapping" stages during manufacture of the composite component, as well as conditions experienced by the wrapped composite material in use, may result in thermo-stress and cause fissures, cracks, and/or microcracks at the edges of the composite material stack. Such cracks often initiate at the composite material edge. If detected upon component inspection, such composite material damage results in the rejection of such a composite component or part, creating material waste and increased manufacturing cost. If damage occurs to a composite component that has been installed in a larger structure and is "in service", repair or replacement of the damaged composite part may be required, also resulting in material waste, and increased cost while the larger structure comprising the composite component is taken out of service for repair.

Further, composite components made from composite materials may be used in the manufacture of larger structures (e.g. aircraft). Such structures may encounter electromagnetic effects (EMEs) including, for example, and without limitation, lightning strikes. When a structure encounters an EME, the charge delivered to the structure travels throughout any conductive path, and can cause damage to exposed dielectric materials, including composite materials. The electrical damage to composite materials from EMEs can be exacerbated if the edges of the composite material comprise exposed carbon fibers.

<CIT>, according to its abstract, states that a method for manufacturing a fibre composite component includes providing a semi-finished textile product; injecting a matrix material into the semi-finished textile product so as to form an infiltrated semi-finished product, wherein the matrix material includes a thermoplastic film having particles dispersed therein; and curing the infiltrated semi-finished product.

<CIT>, according to its abstract, states that laminated composites made with layers of fiber reinforced thermosetting resin prepregs and with thermoplastic film interleaf layers are made by using thermoplastic film coated with thermosetting adhesive as the interleaf layer. In composites having a honeycomb core with thermosetting prepreg skins, the thermoplastic film is a moisture barrier to exclude water vapor from the honeycomb cavities.

<CIT>, according to its abstract, states that an interleaf-containing, fiber-reinforced epoxy resin prepreg, comprises a fiber-reinforced epoxy resin matrix and an interleaf composed of a polyimide film subjected to a corona discharge treatment and/or a matting treatment. This prepreg is suitable for the production of a composite material having mechanical strength characteristics such as interlaminar shear strength and flexural breaking strength and having a high toughness.

<CIT>, according to its abstract, states for toughened composite materials and methods for manufacturing thereof, at least one interleaf toughing particle and at least one polymer veil are used to synergistically increase the toughness of a fiber/polymer composite. The at least one interleaf toughening particle and at least one polymer veil can be located in the interlaminar sections of the composite material.

<NPL>, states that compositional differences of bis F and phenol novolac epoxy resins have effects on their performance.

According to one aspect of the disclosure not claimed herein, the present disclosure is directed to a method for making a coated composite component comprising a composite material which comprises a plurality of prepreg plies to form a prepreg ply stack, and a coating which is proximate to the prepreg ply stack and which comprises a thermoplastic film, the method comprising positioning a plurality of prepreg plies to form a prepreg ply stack; coating the prepreg ply stack with a thermoplastic film, with the thermoplastic film comprising a thermoplastic film first surface and a thermoplastic film second surface, and with the thermoplastic film first surface located proximate to the prepreg ply stack; and curing the prepreg ply stack and the thermoplastic film to make a coated composite component,.

In another aspect not claimed herein, before the step of coating the prepreg ply stack with a thermoplastic film, the method further comprises plasma treating at least the first surface of the thermoplastic film.

In a further aspect not claimed herein, in the step of coating the prepreg ply stack with a thermoplastic film, said thermoplastic film comprises a polyether ether ketone or a polyether ketone ketone.

In another aspect not claimed herein, in the step of curing the prepreg ply stack and the thermoplastic film, the prepreg ply stack and the thermoplastic film are cured at a temperature ranging from <NUM>°F to <NUM>°F (<NUM> to <NUM>).

In another aspect not claimed herein, the plurality of prepreg plies comprises a resin-containing component and a fiber-containing component.

In another aspect not claimed herein, the plurality of prepreg plies comprises an epoxy-containing resin component and a fiber-containing component.

In a further aspect not claimed herein, the plurality of prepreg plies comprises an epoxy-containing resin component and a fiber-containing component, with the fiber-containing component comprising carbon fibers, glass fibers, boron fibers, aramid fibers, or combinations thereof.

In another aspect not claimed herein, the plurality of prepreg plies each comprises a B-stage epoxy-resin.

In a further aspect not claimed herein, the plurality of prepreg plies comprises an epoxy-resin-containing component comprising diglycidyl ethers of bisphenol A; diglycidyl ethers of bisphenol F; N,N,N',N'-tetraglycidyl-<NUM>,<NUM>'-diaminophenylmethane; p-amino phenol triglycidyl ether; epoxy phenol novolac resins; epoxy cresol novolac resins; <NUM>,<NUM>,<NUM>- triglycidyl isocyanurate; tris(<NUM>,<NUM>-epoxypropyl)isocyanurate (and isocyanurates); glycerol diglycidyl ether; trimethylolpropane triglycidyl ether, or combinations thereof.

According to a non-claimed example, a further aspect is directed to a composite material comprising a plurality of prepreg plies configured into a prepreg ply stack, with the prepreg ply stack comprising a thermoplastic film, and with the thermoplastic film comprising a thermoplastic film first surface and a thermoplastic film second surface, with the thermoplastic film first surface located proximate to the prepreg ply stack; and wherein said thermoplastic film has a coefficient of thermal expansion ranging from <NUM> to <NUM> ppm/°F (<NUM> to <NUM> ppm/°C) at a temperature ranging from <NUM>°F to <NUM>°F (<NUM> to <NUM>) and the co-cured thermoplastic film comprises a polyether ether ketone or a polyether ketone ketone.

In other aspects of this non-claimed example:.

A further aspect of the present disclosure, as defined in appended claim <NUM>, is directed to a composite component comprising a composite material comprising a plurality of prepreg plies to form a prepreg ply stack; and a coating proximate to the prepreg ply stack, with the coating comprising a thermoplastic film, and with the thermoplastic film comprising a first a coefficient of thermal expansion ranging from about <NUM> to about <NUM> ppm/°F (about <NUM> to about <NUM> ppm/°C) at a temperature ranging from about <NUM>°F to about <NUM>°F (about <NUM> to about <NUM>) and the thermoplastic film is configured to apply a compressive preload to the composite material ranging from <NUM> psi to <NUM> psi (<NUM>,<NUM> Pa to <NUM>,<NUM> Pa).

In another aspect, not claimed herein, the thermoplastic film comprises a polyether ether ketone or a polyether ketone ketone.

In a further aspect, not claimed herein, the prepreg ply stack comprises a resin-component and a fiber-containing component, with the fiber-containing component comprising carbon fibers, glass fibers, boron fibers, aramid fibers, or combinations thereof.

In another aspect, not claimed herein, the cured prepreg ply stack experiences an amount of interlaminar stress tension that is less than an amount of interlaminar stress tension required to introduce cracks in the prepreg ply stack.

In another aspect, not claimed herein, the cured composite material experiences an amount of interlaminar stress tension that is less than an amount of interlaminar stress tension required to introduce cracks in the composite material.

In another aspect, not claimed herein, the thermoplastic film material comprises a coefficient of thermal expansion value that is greater than the coefficient of thermal expansion value of the composite material.

Non-claimed examples are further directed to structures comprising a composite component comprising a composite material, with the composite material comprising a plurality of prepreg plies configured into a prepreg ply stack, with the prepreg ply comprising a thermoplastic film, and with the thermoplastic film comprising a thermoplastic film first surface and a thermoplastic film second surface, with the thermoplastic film first surface located proximate to the prepreg ply stack; and wherein the thermoplastic film has a coefficient of thermal expansion ranging from <NUM> to <NUM> ppm/°F, (i.e. <NUM>×<NUM>-<NUM>/in/in/°F to <NUM>×<NUM>-<NUM>/in/in/°F, i.e. <NUM> to <NUM> ppm/°C) at a temperature ranging from <NUM>°F to <NUM>°F (<NUM> to <NUM>).

According to further aspects of these non-claimed examples:.

Another aspect of the present disclosure, as defined in appended claim <NUM>, is directed to a vehicle comprising a composite component as defined above by reference to appended claim <NUM>.

According to a further aspect the vehicle is an aircraft.

In another aspect, the vehicle is selected from the group consisting of a manned aircraft, an unmanned aircraft, a manned spacecraft, an unmanned spacecraft, a manned rotorcraft, an unmanned rotorcraft, a satellite, a rocket, a manned terrestrial vehicle, an unmanned terrestrial vehicle, a manned surface water borne vehicle, an unmanned surface water borne vehicle, a manned sub-surface water borne vehicle, an unmanned sub-surface water borne vehicle, and combinations thereof.

In a further aspect, the thermoplastic film is configured to apply a compressive preload to the composite material, with the compressive preload ranging from <NUM> psi to <NUM> psi (<NUM>,<NUM> Pa to <NUM>,<NUM> Pa).

According to aspects of the present disclosure, methods for making composite laminate materials comprising composite "stacks" are disclosed, as well as the composite materials made according to such methods, and structures comprising such composite materials.

Aspects of the present disclosure relate to methods for manufacturing composite materials where composite material edge cracking due to factors including, for example, CTE mismatch between the composite material and an overwrapping material is reduced or substantially eliminated.

Aspects of the present disclosure comprise providing a composite material overwrap comprising a thermoplastic material film. The thermoplastic material film comprises a coefficient of thermal expansion ranging from <NUM> to <NUM> ppm/°F (<NUM> to <NUM> ppm/°C) at a temperature ranging from <NUM>°F to <NUM>°F (<NUM> to <NUM>), and a Young's modulus that is lower than the modulus of the composite material.

The thermoplastic film comprises a polyether ether ketone (PEEK) or a polyether ketone ketone (PEKK).

Polyether ether ketone (PEEK) is an organic thermoplastic in the polyaryletherketone (PAEK) family, with PEEK having the general formula:
<CHM>.

PEEK has a coefficient of thermal expansion value (depending upon grade) ranging from of about <NUM> to about <NUM> ppm/°F (i.e. about <NUM> to about <NUM> × <NUM>-<NUM> in/in/°F, i.e. about <NUM> to about <NUM> ppm/°C), a Young's modulus value of about <NUM> GPa and a tensile strength ranging from about <NUM> MPa to about <NUM> MPa. PEEK is highly resistant to thermal degradation as well as attack by both organic and aqueous environments (e.g. environments including, without limitation, those environments coming into contact with fuels and fuel systems, etc.) , and has a high resistance to biodegradation.

Polyether ketone ketone (PEKK) is a semi-crystalline thermoplastic in the PAEK family, with PEKK having the general formula:
<CHM>.

PEKK has a coefficient of thermal expansion value (depending upon grade) of about <NUM> to about <NUM> ppm/°F (i.e. about <NUM> to about <NUM> × <NUM>-<NUM> in/in/°F, i.e. about <NUM> to about <NUM> ppm/°C), a Young's modulus value of about <NUM> GPa and a tensile strength of about <NUM> MPa. PEKK is also highly resistant to thermal degradation as well as attack by both organic and aqueous environments (e.g. environments including, without limitation, those environments coming into contact with fuels and fuel systems, etc.), and has a high resistance to biodegradation.

As contemplated by the present disclosure, the CFRPs used to make the composite material stacks typically have a coefficient of thermal expansion (CTE) value ranging from of about <NUM> to about <NUM> ppm/°F (about <NUM> to about <NUM> ppm/°C). A disparity in CTE value between thermoplastic film overwraps used to cover the CFRPs, means that, upon CFRP curing, or during use as a wrapped composite component, the contemplated thermoplastic films can shrink more than the CRFP (e.g. composite material) stack, resulting in the thermoplastic film applying a compressive force, or preload, on the CRFP stack that reduces, or substantially eliminate cracks or fissures from initiating in the CFRP stack, particularly at the edges (e.g. edge cracking).

As a result, the thermoplastic coatings according to the present disclosure afford the composite material stack, and components comprising the composite material, improved EME protection, as the continuous thermoplastic film provides a barrier to and otherwise covers exposed carbon fiber ends at the edges of the CFRPs. This level of EME protection afforded the CFRPs by the presence of the thermoplastic film coating, or overwrap, therefore provides superior corrosion protection (e.g. protection from galvanic corrosion that would otherwise occur without the presence of the thermoplastic film) of the CRFPs and metal components that are located proximate to the CFRP stacks. Contemplated thicknesses of the thermoplastic film range from about <NUM> to about <NUM> mils thick (about <NUM> to about <NUM>), and preferably ranges from about <NUM> to about <NUM> mils thick (about <NUM> to about <NUM>); a thickness that is significantly less than conventional CFRP wrappings made from fabric (e.g. about <NUM> mils thick, i.e. about <NUM>).

In addition, the density of the contemplated thermoplastic film materials (e.g. contemplated thermoplastic film densities ranging from about <NUM> to about <NUM>/cc) is also lower than the density of the fabrics presently used to cover, or "wrap", composite material stacks. This reduction in material density and film thickness yields a measurable weight reduction. For example, over the area of an aircraft, such weight reduction can reach or exceed about <NUM> pounds (about <NUM>), representing a substantial cost savings in terms of fuel consumption.

If desired, according to further contemplated aspects, the thermoplastic film may be tailored to possess various characteristics (e.g. physical, chemical, thermal, etc.) by providing additives to the thermoplastic. For example, the contemplated thermoplastic films can be tailored to achieve a desired surface resistivity ranging from about <NUM><NUM> to <NUM><NUM> ohm/m<NUM>. Components made from the composite materials disclosed herein may find particular utility in components used in the manufacture of vehicles, including aircraft, (e.g. ribs, spars, stringers, etc.) as well as structural components used in the manufacture of fuel tanks on such vehicles.

In addition, the contemplated thermoplastic films offer significantly greater processing advantages in terms of material handling and storage compared with fabric overwrap that may, for example, require cool storage, thus further reducing facility space, processing complexity, and overall cost. In addition, aspects of the present disclosure contemplate the use of thermoplastic wraps or coatings to afford greater protection from moisture, thereby acting as an enhanced moisture barrier as compared to the fabric overwraps presently in use.

In a further aspect, the prepreg plies to make the composite materials comprise an epoxy-containing resin component and a fiber-containing component, with the fiber-containing component comprising carbon fibers, glass fibers, boron fibers, aramid fibers, etc. or combinations thereof.

In another aspect, the prepreg ply stacks comprise a B-stage epoxy-resin.

In a further aspect, the prepreg ply stacks comprise an epoxy-resin-containing component comprising diglycidyl ethers of bisphenol A; diglycidyl ethers of bisphenol F; N,N,N',N'-tetraglycidyl-<NUM>,<NUM>'-diaminophenylmethane; p-amino phenol triglycidyl ether; epoxy phenol novolac resins; epoxy cresol novolac resins; <NUM>,<NUM>,<NUM>- triglycidyl isocyanurate; tris(<NUM>,<NUM>-epoxypropyl)isocyanurate (and isocyanurates); glycerol diglycidyl ether; trimethylolpropane triglycidyl ether, or combinations thereof. The present disclosure further contemplates that the prepreg plies (e.g. the composite material comprising the prepreg ply stacks that in turn comprise the prepreg plies), may be based on a system other than an epoxy resin-based system including, without limitation, an acrylate resin-based system, a composite system comprising benzoazine, etc..

As shown in <FIG>, prepreg stack 10a comprises a plurality of laid-up prepreg plies <NUM>. Coated composite component 10b shows an aspect of the present disclosure, where the prepreg stack 10a comprises a plurality of laid-up prepreg plies <NUM> and a thermoplastic coating <NUM> applied to the exterior to substantially completely cover the coated composite component 10b.

<FIG> shows a perspective elevated view of the coated composite material according to aspects of the present disclosure, at various stages during its manufacture. At stage 20a, composite prepreg ply stack 22a has thermoplastic film 24a brought into a position proximate to the composite prepreg ply stack 22a. At stage 20b, the thermoplastic film 24b is oriented into a final position relative to composite prepreg ply stack 22b. Stage 20c illustrates a composite prepreg ply stack 22c comprising the thermoplastic film 24c.

<FIG> shows a perspective elevated view of a composite component <NUM> with cured composite material <NUM> covered by thermoplastic film <NUM>. <FIG> are flowcharts outlining aspects of the present disclosure. <FIG> outlines a method (<NUM>) comprising (<NUM>) positioning a plurality of prepreg plies to form a prepreg ply stack; (<NUM>) coating the prepreg ply stack with a thermoplastic film, said thermoplastic film comprising a thermoplastic film first surface and a thermoplastic film second surface, said thermoplastic film first surface located proximate to the prepreg ply stack; and (44a) curing the prepreg ply stack comprising the thermoplastic film to make a coated composite component wherein the thermoplastic film has a coefficient of thermal expansion ranging from <NUM> to <NUM> ppm/°F (<NUM> to <NUM> ppm/°C) at a temperature ranging from <NUM>°F to <NUM>°F (<NUM> to <NUM>).

<FIG> outlines a method (<NUM>) comprising (<NUM>) plasma treating at least the first surface of a thermoplastic film: (<NUM>) positioning a plurality of prepreg plies to form a prepreg ply stack; (<NUM>) coating the prepreg ply stack with the thermoplastic film, said thermoplastic film comprising a thermoplastic film first surface and a thermoplastic film second surface, said thermoplastic film first surface located proximate to the prepreg ply stack; and (44a) curing the prepreg ply stack comprising the thermoplastic film to make a coated composite component wherein the thermoplastic film has a coefficient of thermal expansion ranging from <NUM> to <NUM> ppm/°F (<NUM> to <NUM> ppm/°C) at a temperature ranging from <NUM>°F to <NUM>°F (<NUM> to <NUM>).

<FIG> outlines a method (<NUM>) comprising (<NUM>) positioning a plurality of prepreg plies to form a prepreg ply stack; (<NUM>) coating the prepreg ply stack with a thermoplastic film comprising said thermoplastic film comprising a polyether ether ketone or a polyether ketone ketone, said thermoplastic film comprising a thermoplastic film first surface and a thermoplastic film second surface, said thermoplastic film first surface located proximate to the prepreg ply stack; and (44a) curing the prepreg ply stack comprising the thermoplastic film to make a coated composite component wherein the thermoplastic film has a coefficient of thermal expansion ranging from <NUM> to <NUM> ppm/°F (from <NUM> to <NUM> ppm/°C) at a temperature ranging from <NUM>°F to <NUM>°F (<NUM> to <NUM>).

<FIG> outlines a method (<NUM>) comprising (<NUM>) positioning a plurality of prepreg plies to form a prepreg ply stack; (<NUM>) coating the prepreg ply stack with a thermoplastic film, said thermoplastic film comprising a thermoplastic film first surface and a thermoplastic film second surface, said thermoplastic film first surface located proximate to the prepreg ply stack; and (<NUM>) curing the prepreg ply stack comprising the thermoplastic film at a temperature ranging from <NUM>°F to <NUM>°F (<NUM> to <NUM>) to make a coated composite component wherein the thermoplastic film has a coefficient of thermal expansion ranging from <NUM> to <NUM> ppm/°F (<NUM> to <NUM> ppm/°C) at a temperature ranging from <NUM>°F to <NUM>°F (<NUM> to <NUM>).

Further aspects of the present disclosure contemplate methods for treating the thermoplastic film before applying the thermoplastic film to the composite prepreg ply stack. Such treatments include, without limitation, plasma treating the thermoplastic film to activate the at least one surface of the thermoplastic film. "Plasma treatment", also referred to equivalently herein as "plasma surface activation", predictably alters the surface of a polymer by attaching polar or functional groups to the polymer. Such plasma treatment is especially useful when attempting to bond a chemically inert polymer that may not bond easily to other materials. Plasma-treated surfaces may remain active for several months. According to known plasma treatment methods, radiation (e.g. ultraviolet, etc.) and active oxygen species from a produced plasma break up a material surface allowing active oxygen species (e.g. radicals) from the plasma to bind to the active sites created on the treated material surfaces, thus creating a material surface that is highly active to bonding to other material surfaces.

The following example outlines a general method for providing a PEEK or PEKK thermoplastic wrap or coating for a co-curable composite (e.g. CFRP) stack. A PEEK or PEKK thermoplastic film is plasma treated to increase the surface reactivity of the thermoplastic film. For example, PEEK films may be treated at <NUM>" (<NUM>) height and <NUM>"/min (<NUM>/min) at predetermined ion density levels. The PEEK or PEKK thermoplastic film is oriented onto the co-curable composite stack as a co-curable thermoplastic over-wrap. The stack with thermoplastic over-wrap is co-cured in an autoclave that is programmed for suitable vacuum and pressurization as usual. A progressive heating cycle is established for the autoclave at : <NUM>) <NUM>°F/min (<NUM>/min) until a temperature of <NUM>°F (<NUM>) is achieved, based on air temperature; <NUM>) <NUM> °F/min (<NUM>/min) to <NUM>°F (<NUM>), based on air temperature; <NUM>) <NUM>°F/min (<NUM>/min) to <NUM>°F (<NUM>), based on air temperature, while observing the lagging thermocouple. When the lagging thermocouple reached <NUM>°F (<NUM>), observe a <NUM> minute hold. The co-curing thermoplastic film and stack are allowed to cool at <NUM>°F/min (<NUM>/min), based on air temperature. When the leading thermocouple registers a temperature of less than <NUM>°F (<NUM>), pressure is reduced to complete the cycle. For the purpose of this specification, when referring to the PEEK and/or PEKK thermoplastic film, the terms "wrap", "over-wrap", "wrapping", and "coating" are equivalent terms and may be used interchangeably. The present disclosure therefore contemplates a thermoplastic film applied to an uncured composite material comprising a prepreg ply stack. In this aspect, the thermoplastic film is subjected to the curing process for the composite material as outlined in the Example set forth immediately above. According to aspects of the present disclosure, the thermoplastic film is provided to the uncured or partially-cured composite material as a wrap. The thermoplastic film then becomes bonded to the composite material as the composite material with the thermoplastic film proceeds through the composite material curing process. While it is recognized that the chemical structure of the thermoplastic film is not changed during the curing process, for the purposes of the present disclosure the process may be equivalently referred to as a "curing" process or a "co-curing" process, with the terms being used interchangeably.

Further aspects of the present disclosure contemplate structural and other components for vehicles including, without limitation, aircraft (e.g. spars, ribs, stringers, etc.), with such components finding utility in connection with vehicle fuel tanks and fuel tank systems. Such vehicles may be selected from the group consisting of a manned aircraft, an unmanned aircraft, a manned spacecraft, an unmanned spacecraft, a manned rotorcraft, an unmanned rotorcraft, a satellite, a rocket, a manned terrestrial vehicle, an unmanned terrestrial vehicle, a manned surface water borne vehicle, an unmanned surface water borne vehicle, a manned sub-surface water borne vehicle, an unmanned sub-surface water borne vehicle, and combinations thereof.

Claim 1:
A composite component (10b, 20c, <NUM>) comprising:
a composite material comprising a plurality of prepreg plies (<NUM>) to form a prepreg ply stack (10a, 22a, 22b, 22c); and
a coating proximate to the prepreg ply stack, said coating comprising:
a thermoplastic film (<NUM>, 24a, 24b, 24c, <NUM>), said thermoplastic film comprising a thermoplastic film first surface and a thermoplastic film second surface, said thermoplastic film having a coefficient of thermal expansion ranging from <NUM> to <NUM> ppm/°C at a temperature ranging from <NUM> to <NUM>,
wherein the thermoplastic film is configured to apply a compressive preload to the composite material ranging from <NUM>,<NUM> Pa to <NUM>,<NUM> Pa.