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A metallic-composite joint is formed by inserting a metallic member into a slot of a pi-shaped composite preform. The preform is formed from woven carbon fiber in a binder of resin and may or may not be cured prior to assembly. An inert compliant layer is located between the legs of the preform and

A metallic-composite joint is formed by inserting a metallic member into a slot of a pi-shaped composite preform. The preform is formed from woven carbon fiber in a binder of resin and may or may not be cured prior to assembly. An inert compliant layer is located between the legs of the preform and the metallic member. The resin binder or an adhesive is used to bond the compliant layer to the preform. The compliant layer has a coefficient of thermal expansion that more closely matches that of the preform. The properties of the compliant layer also avoid galvanic corrosion between the carbon in the preform and the metallic member.

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What is claimed is: 1. A method of fabricating a joint, comprising: (a) providing a preform having a base and two legs defining between them a slot, the preform being formed of a woven fiber composite material; (b) joining a composite member to the base of the preform; (c) providing an aluminum mem

What is claimed is: 1. A method of fabricating a joint, comprising: (a) providing a preform having a base and two legs defining between them a slot, the preform being formed of a woven fiber composite material; (b) joining a composite member to the base of the preform; (c) providing an aluminum member having two oppositely-facing sides, (d) adhering a single layer of titanium to each of the sides of the aluminum member to form a sub assembly; and (e) bonding the sub-assembly in the slot of the preform with the titanium being between the legs of the preform and the aluminum member and separating the aluminum member from contact with the preform, the titanium having a coefficient of thermal expansion that is similar to that of the preform to reduce a risk of separation therebetween when subjected to thermal stresses, such that the titanium acts as a ductile layer to absorb a greater thermal expansion of the aluminum member against a lesser thermal expansion of the composite member as thermal energy is applied thereto. 2. A method according to claim 1, wherein the layer of titanium is in contact with the aluminum member. 3. A method according to claim 1, further comprising forming the layer of titanium as a sleeve that is contoured to an outer surface of the aluminum member and an inner surface of the slot in the preform. 4. A method according to claim 1, wherein step (d) comprises depositing the layer of titanium as a coating on at least a portion of the aluminum member. 5. A method according to claim 1, wherein the subassembly is bonded to the preform with a material selected from a resin binder and an adhesive. 6. A method according to claim 1, further comprising providing a sealant between the layer of titanium and the aluminum member, preventing any contact of the layer of titanium with the aluminum member. 7. A method according to claim 1, further comprising providing at least one gap in the slot wherein the layer of titanium is not located between the aluminum member and the perform, and filling said at least one gap with a material selected from the group consisting of sealants and adhesives. 8. A method of fabricating a joint, comprising: (a) providing a preform having a slot, and forming the preform from a composite material with a pi-shaped cross-section having a base and legs projecting from the base to define the slot therebetween; (b) joining a composite member to the base of the preform; (c) positioning a compliant member on a metallic member to form a sub-assembly by depositing the compliant member as a coating directly on and in contact with at least a portion of the metallic member; and (d) locating the sub-assembly in the slot of the preform such that the compliant member is located between the preform and the metallic member, separating the metallic member from contact with the preform, the compliant member having a coefficient of thermal expansion that is similar to that of the preform to reduce a risk of separation therebetween when subjected to thermal stresses, such that the compliant member acts as a ductile layer to absorb a greater thermal expansion of the metallic member against a lesser thermal expansion of the composite member as thermal energy is applied thereto. 9. A method according to claim 8, further comprising bonding the compliant member to the preform with a material selected from a resin binder and an adhesive. 10. A method according to claim 8, further comprising forming the compliant member from an inert material that is a barrier to galvanic corrosion that might otherwise occur between carbon in the preform and the metallic member. 11. A method according to claim 8, further comprising: forming the metallic member from aluminum, and forming the composite member as an aircraft frame member; and forming the compliant member from titanium, and the preform from woven carbon fiber in a binder of resin. 12. A method according to claim 8, further comprising: providing at least one gap in the slot wherein the compliant member is not located between the metallic member and the preform, and filling said at least one gap with a material selected from the group consisting of sealants and adhesives. 13. A method of fabricating a joint, comprising: (a) providing a preform of woven carbon fiber and having a slot; (b) joining a composite member to a part of the preform other than the slot; (c) positioning a compliant member on a metallic member to form a sub-assembly, forming the compliant member from a single layer of an inert material that is a barrier to galvanic corrosion that might otherwise occur between carbon fiber in the preform and the metallic member, and providing a sealant between the compliant member and the metallic member, preventing contact of the compliant member with the metallic member; and (d) locating the sub-assembly in the slot of the preform such that the compliant member is located between the preform and the metallic member, preventing contact of the preform with the metallic member, the compliant member having a coefficient of thermal expansion that is similar to that of the preform to reduce a risk of separation therebetween when subjected to thermal stresses, such that the compliant member acts as a ductile layer to absorb a greater thermal expansion of the metallic member against a lesser thermal expansion of the composite member as thermal energy is applied thereto. 14. A method according to claim 13, further comprising: forming the preform from a composite material with a pi-shaped cross-section having a base and legs projecting from the base to define the slot therebetween; forming the compliant member as a sleeve that is contoured to an outer surface of the metallic member and an inner surface of the slot in the preform; and bonding the compliant member to the preform with a material selected from a resin binder and an adhesive. 15. A method according to claim 13, further comprising: forming the compliant member from titanium. 16. A method according to claim 13, further comprising providing at least one gap in the slot wherein the compliant member is not located between the preform and the metallic member, and filling said at least one gap with a material selected from the group consisting of sealants and adhesives.