Hybrid metallic/composite arrangement for torque, bending, shear, and axial loading

What is claimed is: 1. A structural component, comprising: a metallic inner tube; a first lobe extending from the metallic inner tube; a second lobe extending from the metallic inner tube, and a composite outer tube surrounding the metallic inner tube, the first lobe, and the second lobe; wherein a first end of the metallic inner tube extends from the composite outer tube and a second end of the metallic inner tube extends from the composite outer tube the metallic inner tube comprises a first constant diameter portion, a tapered portion, and a second constant diameter portion, an outer diameter of the first constant diameter portion is greater than an outer diameter of the second constant diameter portion; the second constant diameter portion is disposed axially inward from the tapered portion, and the tapered portion is disposed axially inward from the first constant diameter portion; the composite outer tube comprises a first wall thickness at the first constant diameter portion, the composite outer tube comprises a second wall thickness at the second constant diameter portion, and the first wall thickness is less than the second wall thickness; and the second constant diameter portion is disposed at a midpoint of the metallic inner tube. 2. The structural component of claim 1 , wherein the metallic inner tube, the first lobe, and the composite outer tube are concentric. 3. The structural component of claim 2 , wherein the first lobe mechanically locks the composite outer tube to the metallic inner tube. 4. The structural component of claim 1 , wherein the first lobe is disposed at the first end of the metallic inner tube and the second lobe is disposed at the second end of the metallic inner tube. 5. The structural component of claim 1 , wherein the metallic inner tube and the first lobe are comprised of a single piece of metal. 6. A hybrid metallic/composite arrangement, comprising: a metallic inner tube; a first lobe extending from the metallic inner tube; a second lobe extending from the metallic inner tube; and a composite outer tube surrounding the metallic inner tube, wherein an inner diameter surface of the composite outer tube conforms to an outer diameter surface of the metallic inner tube; wherein a first end of the metallic inner tube extends from the composite outer tube and a second end of the metallic inner tube extends from the composite outer tube; the metallic inner tube comprises a first constant diameter portion, a tapered portion, and a second constant diameter portion, an outer diameter of the first constant diameter portion is greater than an outer diameter of the second constant diameter portion; the second constant diameter portion is disposed axially inward from the tapered portion, and the tapered portion is disposed axially inward from the first constant diameter portion; the composite outer tube comprises a first wall thickness at the first constant diameter portion, the composite outer tube comprises a second wall thickness at the second constant diameter portion, and the first wall thickness is less than the second wall thickness; and the second constant diameter portion is disposed at a midpoint of the metallic inner tube. 7. The hybrid metallic/composite arrangement of claim 6 , wherein the metallic inner tube, the first lobe, the second lobe, and the composite outer tube are concentric. 8. The hybrid metallic/composite arrangement of claim 7 , wherein the first lobe and the second lobe mechanically lock the composite outer tube to the metallic inner tube. 9. The hybrid metallic/composite arrangement of claim 6 , further comprising a third lobe and a fourth lobe extending from the metallic inner tube. 10. A method for forming a structural component, comprising: forming a metallic inner tube comprising at least one lobe; and disposing a composite layer about the metallic inner tube to form a composite outer tube; wherein the composite outer tube surrounds the metallic inner tube and the at least one lobe; the metallic inner tube comprises a first constant diameter portion, a tapered portion, and a second constant diameter portion, an outer diameter of the first constant diameter portion is greater than an outer diameter of the second constant diameter portion; the second constant diameter portion is disposed axially inward from the tapered portion, and the tapered portion is disposed axially inward from the first constant diameter portion; the composite outer tube comprises a first wall thickness at the first constant diameter portion, the composite outer tube comprises a second wall thickness at the second constant diameter portion, and the first wall thickness is less than the second wall thickness; and the second constant diameter portion is disposed at a midpoint of the metallic inner tube. 11. The method of claim 10 , wherein the composite layer is disposed about the metallic inner tube using at least one of a composite layup process or a fiber-wound fabrication process, and the composite layer comprises a polymer matrix composite reinforced by fibers.