Hybrid metal composite structures, rocket motors including hybrid metal composite structures, and related methods

What is claimed is: 1. A hybrid metal composite (HMC) structure, comprising stacked tiers comprising: first tiers comprising a fiber composite material, within each of the first tiers the fiber composite material comprising: a fiber platform comprising a single, wound tow comprising fibers substantially aligned with one another in a single direction; and matrix material surrounding the fiber platform; and second tiers directly adjacent to and longitudinally alternating with the first tiers, the second tiers comprising metallic structures and additional fiber composite material directly adjacent to first lateral sides and second, opposing lateral sides of the metallic structures, the first tiers substantially devoid of additional metallic structures, and the metallic structures physically separated from longitudinally neighboring metallic structures by the fiber composite material along an entirety of the metallic structures, the first lateral sides of each of the metallic structures laterally offset from corresponding first lateral sides of a longitudinally neighboring one of the metallic structures most longitudinally proximate thereto, and the second, opposing lateral sides of the metallic structures substantially laterally aligned with one another through a thickness of the HMC structure. 2. A hybrid metal composite (HMC) structure, comprising stacked tiers comprising: first tiers comprising a fiber composite material, within each of the first tiers the fiber composite material comprising: a fiber platform comprising a single, wound tow comprising fibers substantially aligned with one another in a single direction; and matrix material surrounding the fiber platform; and second tiers directly adjacent to and longitudinally alternating with one of the first tiers, the second tiers comprising metallic structures and the fiber composite material directly adjacent first lateral sides and second, opposing lateral sides of the metallic structures, the first tiers substantially free of the metallic structures, and the metallic structures physically separated from longitudinally neighboring metallic structures by the fiber composite material of the one of the first tiers along an entirety of the metallic structures, the first lateral sides of each of the metallic structures laterally offset from corresponding first lateral sides of a longitudinally neighboring one of the metallic structures most longitudinally proximate thereto, and the second, opposing lateral sides of at least some of the metallic structures are substantially the same distance from lateral ends of the first tiers. 3. The HMC structure of claim 2 , further comprising: metal plates overlying and underlying the stacked tiers; and one or more fasteners longitudinally extending through each of the metal plates, the metallic structures, and the fiber composite material, the one or more fasteners comprising a material composition different than a material composition of the metallic structures. 4. The HMC structure of claim 3 , wherein the second, opposing lateral sides of at least some of the metallic structures are substantially the same distance from one of the fasteners. 5. The HMC structure of claim 2 , wherein the metallic structures constitute from about 25 percent to about 45 percent of a volume of the stacked tiers of the HMC structure and comprise one or more of titanium, a titanium-containing alloy, a nickel-containing alloy, and a stainless steel. 6. The HMC structure of claim 2 , wherein the fiber composite material comprises carbon fibers individually having a diameter within a range of from about 5 μm to about 10 μm. 7. The HMC structure of claim 2 , wherein the fiber composite material comprises ceramic fibers embedded in the matrix material, the ceramic fibers comprising one or more of alumina fibers, alumina-silica fibers, and alumina-boria-silica fibers. 8. The HMC structure of claim 7 , wherein at least the matrix material of the fiber composite material exhibits a coefficient of thermal expansion within a range of from about 45×10 −6 /K to about 65×10 −6 /K at about 25° C. 9. The HMC structure of claim 2 , wherein each of the metallic structures individually exhibits a thickness of about 0.01 inch, the first lateral sides and the second, opposing lateral sides of the metallic structures laterally offset by a distance of about 0.1 inch from the corresponding first lateral sides and corresponding second, opposing lateral sides of a longitudinally neighboring one of the metallic structures. 10. The HMC structure of claim 2 , wherein each of the metallic structures exhibits substantially the same lateral width as each other of the metallic structures, the metallic structures individually comprising: a lateral center offset in a lateral direction from another lateral center of another of the metallic structures most longitudinally proximate thereto and substantially aligned with an additional lateral center of at least one other of the metallic structures; and lateral ends defined by the first lateral sides and the second, opposing lateral sides, the lateral ends offset in the lateral direction from corresponding additional lateral ends of the another of the metallic structures and substantially aligned in the lateral direction with corresponding further lateral ends of the at least one other of the metallic structures. 11. A method of forming a hybrid metal composite (HMC) structure comprising stacked tiers, the method comprising: forming an uncured fiber composite material comprising a single tow of fibers substantially aligned with one another in a single direction by infiltrating the single tow of the fibers with an uncured matrix material during at least one filament winding process; forming first tiers using the at least one filament winding process, the first tiers comprising portions of the uncured fiber composite material; forming second tiers using the at least one filament winding process, the second tiers directly adjacent to and longitudinally alternating with one of the first tiers, the second tiers comprising metallic structures and additional portions of the uncured fiber composite material directly adjacent first lateral sides and second, opposing lateral sides of the metallic structures, the first tiers substantially free of the metallic structures, and the metallic structures physically separated from longitudinally neighboring metallic structures by the fiber composite material of the one of the first tiers along an entirety of the metallic structures, the first lateral sides of each of the metallic structures laterally offset from corresponding first lateral sides of a longitudinally neighboring one of the metallic structures most longitudinally proximate thereto, and the second, opposing lateral sides of at least some of the metallic structures are substantially the same distance from lateral ends of the first tiers; and subjecting the first tiers and the second tiers to at least one curing process to form a fiber platform of the first tiers comprising a single, wound tow of the fibers and a matrix material surrounding the fiber platform. 12. The method of claim 11 , further comprising: trimming portions of one or more of the metallic structures; and extending one or more fasteners longitudinally through each of the metallic structures and metal plates overlying and underlying the metallic structures. 13. The method of claim 11 , further comprising selecting the uncured fiber composite material to comprise polymeric fibers comprising one or more of polyetherketone (PEK) fibers, polyetheretherketone (PEEK) fibers, polyaryletherketone (PAEK) fibers, polyet