The present disclosure relates to carbon fibers having an internal cavity and methods of producing the same.
Composite panels are commonly used to manufacture structural and body panels for vehicles and in other products. Composite panels are typically made of polymeric resins that are reinforced with carbon fibers, glass fibers, natural fibers, or the like which are dispersed in the matrix. Composite panels are typically strong, light weight and may be used in a wide variety of product applications.
According to one aspect of this disclosure, a reinforcing fiber is provided comprising a carbon fiber having a length and outer and inner surfaces defining a wall. The wall has a first cross section which defines an outer diameter and an inner diameter and a wall thickness. The wall thickness of the cylindrical carbon fiber tube is greater than or equal to 2 um.
According to other aspects of this disclosure, the present invention includes a reinforcing fiber comprising a carbon fiber having a length and outer and inner surfaces defining a tube and a first cross section defining an outer diameter and an inner diameter wherein the outer diameter and the inner diameter are varying along the length.
According to another aspect of this disclosure, a method is provided for forming a polymer precursor from a polymer material. The polymer precursor has a length and outer and inner surfaces defining a cylindrical tube. The tube has a cross section defining an outer and inner diameter and a wall thickness. The wall thickness is greater than or equal to 2 um.
As required, detailed embodiments of the present invention are disclosed herein; however, it is to be understood that the disclosed embodiments are merely exemplary of the invention that may be embodied in various and alternative forms. The figures are not necessarily to scale; some features may be exaggerated or minimized to show details of particular components. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a representative basis for teaching one skilled in the art to variously employ the present invention.
Carbon fiber (CF) reinforced polymeric composites are gaining increasing interest in the automotive industry as a promising light weight material to meet governmental corporate average fuel economy (CAFE) requirements and to meet customer expectations for fuel economy. To meet the economical requirements of high volume production of automotive composites, low cost manufacturing processes and low cost materials are being developed.
Incorporation of carbon fiber into composite structures has been met with challenges because carbon fiber process methods are labor intensive and yield porous carbon fibers and are not suited to automotive production volumes. Such labor intensive process methods include vacuum bag autoclaving of pre-impregnated carbon fiber composite laminates. Some attempts have been made to adapt the processing methods of composites that were developed around glass fiber reinforcements to that of carbon fiber reinforcements. These attempts have been met with challenges. The diameter of carbon fiber is typically half that of glass fiber. Accordingly, for an equivalent fiber volume loading, four times as many carbon fibers may be required to fill the same volume as compared to when using glass fiber. Particularly for random fiber composites, an increase in fiber quantity adds complexity to chopping processes due to the intimate interaction of the fibers and sizing formulation (thin layer of polymer coating) developed for carbon fibers. This fiber interaction may make the fibers clump during processing and result in inadequate dispersion of fibers. This will cause degradation in load transfer of the fibers and greatly reduce the composite mechanical properties. Hollow carbon fibers produced by a partial sulfonation process have graphene structure only near the fiber outer surface. Most of the content of the fibers produced by sulfonation are amorphous carbon, and are porous. This low crystallinity and high porosity may lead to lower strength and modulus than required for carbon reinforcing fibers.
Referring now to
The specific tensile strength for the fibers of this disclosure may range from 5×104 m to 50×104 m, more preferably from 10×104 m to 40×104 m, and most preferably 20×104 m to 30×104 m. The specific tensile modulus is the tensile modulus divided by density and acceleration of gravity (g). The specific tensile modulus for the fibers of this disclosure may range from 5×106 m to 20×106 m, and more preferably from 10×106 m to 18×106 m, and most preferably 12×106 m to 15×106 m.
One or more embodiments provide a relatively low cost material and manufacturing process for carbon fiber reinforced materials that are crystalline and are not porous. Other embodiments of this disclosure may provide a hollow carbon fiber that is a non-cylindrical shape, for example a shape having a square or oblong cross section, or any other suitable profile.
The outer and inner diameters 12 and 18 of the hollow carbon fibers 10 may vary along the length. The wall thickness 14 and cross sectional area 16 may also vary. Referring to
The carbon fiber may be in a shape defining a hollow structure other than a tube or cylinder. The cross section of the hollow structure may be a square, oblong, rectangular or other shape. A first cross section taken at a first position along the length of the hollow carbon fiber and a second cross section taken at a second position along the length have cross sectional areas that are substantially the same or may vary 80%, 50%, 20%, 6% or 0.5%.
CFs are manufactured from their polymer precursors via a series of tensioning, stabilization, carbonization processing etc. The precursor shrinks over these processing by about half. One or more embodiments provides CF precursors that have the same hollow design but with all the dimensions doubled. The benefits of this design include material savings and lower fiber density. The hollow core design can save a substantial amount of material and make the fiber even lighter.
One or more embodiments involve different manufacturing methods for producing the hollow polymer precursor for the hollow carbon fiber. The embodiments may be continuous processes so as to meet the demand of high volume manufacturing for automotive and other applications. Once the polymer precursor is formed, the hollow polymer precursor is oxidized and stabilized at 200° C. to 300° C. for ˜2 hours at atmospheric pressure. The polymer precursor is then carbonized at 1200° C. to 2900° C. depending on the grade of the carbon fiber. The diameter of the polymer precursor decreases during the carbonization process. The outer diameter of the polymer precursor may vary from 100 um to 10 um to form the hollow carbon fiber.
Referring now to
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The method of forming the polymer precursor for the hollow carbon fiber may utilize mating of two sections, or partial tubes, having unequal size. A polymer precursor is formed on a tooling plate sized to produce a portion of the polymer precursor having a cross section that is more than half the cross section to be formed, with a portion that is less than half of the final cross section. The complete cross sectional shape is then formed by joining partial tubes that are not each half of the carbon fiber to be formed. The method of forming the carbon fiber may include tooling plates and bushings shaped to produce polymer precursors of different cross sectional shapes such as square or rectangular hollow fibers.
Referring now to
While exemplary embodiments are described above, it is not intended that these embodiments describe all possible forms of the invention. Rather, the words used in the specification are words of description rather than limitation, and it is understood that various changes may be made without departing from the spirit and scope of the invention. Additionally, the features of various implementing embodiments may be combined to form further embodiments of the invention.