Induction welding of thermoplastic with metallic strips

What is claimed is: 1. A method of joining a first workpiece to a second workpiece, the method comprising: induction welding the first workpiece to the second workpiece, wherein a first side of the second workpiece at least partially overlays a first side of the first workpiece, wherein the first workpiece is a first thermoplastic composite structure, wherein the second workpiece is a second thermoplastic composite structure, wherein the induction welding comprises: locating a non-ferrous metallic strip proximate a second side of the second workpiece, wherein the non-ferrous metallic strip is configured to conduct heat uniformly at a welding region between the first side of the second workpiece and the first side of the first workpiece, wherein the non-ferrous metallic strip comprises at least one of copper, aluminum, gold, or silver, and wherein the non-ferrous metallic strip is a mesh; locating an induction welding tool proximate the non-ferrous metallic strip; and locating a coil proximate a second side of the first workpiece, wherein the induction welding is at the welding region, and wherein the induction welding further comprises: operating an induction welding tool at the welding region, wherein the induction welding tool comprises an induction welding tool surface; and energizing the coil proximate the first workpiece, wherein the coil is configured to energize with an electric current, wherein the energized coil is configured to generate an electromagnetic field that induces the electric current which heats the first workpiece and the second workpiece at the welding region, wherein the heat generated by the coil is configured to weld, by the induction welding tool, the second workpiece to the first workpiece at the welding region. 2. The method of claim 1 , wherein the first thermoplastic composite structure further comprises a skin and wherein the skin is configured to weld to the second workpiece. 3. The method of claim 2 , wherein the induction welding the first thermoplastic composite structure to the second workpiece further comprises induction welding the first thermoplastic composite structure to a stiffener. 4. The method of claim 3 , wherein the induction welding the first thermoplastic composite structure to the stiffener further comprises the stiffener comprising: a stiffener cap; a stiffener web; and a stiffener flange, wherein the stiffener flange is configured to weld to the first thermoplastic composite structure. 5. The method of claim 4 , wherein the induction welding the stiffener flange to the first thermoplastic composite structure further comprises the stiffener flange at least partially overlaying the skin of the first thermoplastic composite structure, wherein the stiffener flange is configured to weld to the skin of the first thermoplastic composite structure at the welding region. 6. The method of claim 5 , wherein the induction welding the stiffener flange to the skin further comprises energizing the coil, wherein the coil is configured to generate the electromagnetic field, wherein the electromagnetic field is configured to induce the electric current which heats the stiffener flange and the skin at the welding region, wherein the heat generated by the coil is configured to weld, by the induction welding tool, the stiffener flange to the skin at the welding region. 7. A method of joining a first workpiece to a second workpiece, the method comprising: induction welding the first workpiece to the second workpiece, wherein a first side of the second workpiece at least partially overlays a first side of the first workpiece, wherein the first workpiece is a first thermoplastic composite structure, wherein the second workpiece is a second thermoplastic composite structure, wherein a polymer tape at least partially overlays a second side of the second workpiece, wherein the polymer tape is disposed between the second side of the second workpiece and a non-ferrous metallic strip for conducting heat uniformly at a welding region between the first side of the second workpiece and the first side of the first workpiece, wherein the non-ferrous metallic strip comprising at least one of copper, aluminum, gold, and silver, wherein the metallic strip is a mesh, and wherein the induction welding is at the welding region, wherein the induction welding further comprises: operating an induction welding tool at the welding region, wherein the induction welding tool comprises an induction welding tool surface, wherein the induction welding tool surface is located proximate the non-ferrous metallic strip; and energizing a coil located proximate a second side of the first workpiece, wherein the coil is configured to energize with an electric current, wherein the energized coil is configured to generate an electromagnetic field that induces the electric current which heats the first workpiece and the second workpiece at the welding region, wherein the heat generated by the coil is configured to weld, by the induction welding tool, the second workpiece to the first workpiece at the welding region; and removing the polymer tape from the second workpiece after induction welding. 8. The method of claim 7 , wherein the first thermoplastic composite structure further comprises a skin and wherein the skin is configured to weld to the second workpiece. 9. The method of claim 8 , wherein the induction welding the first thermoplastic composite structure to the second workpiece further comprises induction welding the first thermoplastic composite structure to a stiffener. 10. The method of claim 9 , wherein the induction welding the thermoplastic composite structure to the stiffener further comprises the stiffener comprising: a stiffener cap; a stiffener web; and a stiffener flange, wherein the stiffener flange is configured to weld to the first thermoplastic composite structure. 11. The method of claim 10 , wherein the induction welding the stiffener flange to the first thermoplastic composite structure further comprises the stiffener flange at least partially overlaying the skin of the first thermoplastic composite structure, wherein the stiffener flange is configured to weld to the skin of the first thermoplastic composite structure at the welding region. 12. The method of claim 11 , wherein the induction welding the stiffener flange to the skin at the welding region further comprises disposing the polymer tape at the welding region, wherein the polymer tape at least partially overlays the stiffener flange. 13. The method of claim 12 , wherein the induction welding the stiffener flange to the skin at the welding region further comprises energizing the coil, wherein the coil is configured to generate the electromagnetic field, wherein the electromagnetic field is configured to induce the electric current which heats the stiffener flange and the skin at the welding region, wherein the heat generated by the coil is configured to weld, by the induction welding tool, the stiffener flange to the skin at the welding region. 14. The method of claim 13 , wherein the induction welding the stiffener flange to the skin at the welding region further comprises the non-ferrous metallic strip, wherein the mesh is fixed to the induction welding tool surface. 15. The method of claim 14 , wherein the induction welding the stiffener flange to the skin at the welding region further comprises the polymer tape, wherein the polymer tape is disposed between the stiffener flange and the mesh, wherein the polymer tape is configured to be removed from the stiffener flange after induction welding. 16. An inductio