Spin-welded electrical ground and spin welding methods

What is claimed is: 1. A method for making a ground, comprising the steps: rotating an aluminum alloy weld nut having an outer wall at a predetermined speed; lowering the outer wall into contact with an alloy substrate to generate a frictional force for a friction time based on a friction-induced size reduction of the outer wall; arresting the rotation of the nut; and applying an axial forging force to the outer wall and the substrate for a forging time, wherein a spin-welded, metallurgical joint is formed by solid state diffusion at an elevated temperature without melting between the outer wall and the substrate based on the rotating, lowering, arresting and applying steps, and further wherein the predetermined speed is set between about 15000 rpm to 18000 rpm, the axial forging force is set between about 3 and 6 bars and the frictional force is set between 3 and 4 bars. 2. The method of claim 1 , wherein the lowering step further comprises lowering a bolt bore of the weld nut into a clearance hole of the alloy substrate. 3. The method of claim 1 , wherein the friction and forging times are predetermined to form the joint with mechanical properties suitable for use in a vehicular, electrical ground component. 4. The method of claim 2 , further comprising the step: threading a grounding bolt into the bolt bore of the weld nut after the applying an axial forging force step. 5. A method for making a ground, comprising the steps: lowering an outer wall of an aluminum alloy weld nut into contact with an alloy substrate; rotating the nut at a predetermined speed to generate a frictional force between the outer wall and the substrate for a friction time based on a friction-induced size reduction of the outer wall; arresting the rotation of the nut; and applying an axial forging force to the outer wall and the substrate for a forging time, wherein a spin-welded, metallurgical joint is formed by solid state diffusion at an elevated temperature without melting between the outer wall and the substrate based on the rotating, lowering, arresting and applying steps, and further wherein the predetermined speed is set between about 15000 rpm to 18000 rpm, the axial forging force is set between about 3 and 6 bars and the frictional force is set between 3 and 4 bars. 6. The method of claim 5 , wherein the lowering step further comprises lowering a bolt bore of the weld nut into a clearance hole of the alloy substrate. 7. The method of claim 5 , wherein the friction and forging times are predetermined to form the joint with mechanical properties suitable for use in a vehicular, electrical ground component. 8. The method of claim 7 , further comprising the step: threading a grounding bolt into the bolt bore of the weld nut after the applying an axial forging force step. 9. A method for making a ground, comprising: rotating an aluminum alloy nut between about 15000 and 18000 rpm; lowering the rotating nut into contact with an alloy substrate at a frictional force between 3 and 4 bars; arresting the rotation of the nut; and applying an axial forging force between about 3 and 6 bars to the nut and substrate to form a joint by solid state diffusion at an elevated temperature without melting. 10. The method of claim 9 , wherein the lowering step further comprises lowering a bolt bore of the weld nut into a clearance hole of the alloy substrate. 11. The method of claim 9 , wherein the friction and forging times are predetermined to generate a spin-welded, metallurgical joint between the outer wall of the weld nut and the substrate having mechanical properties suitable for use in a vehicular, electrical ground component. 12. The method of claim 10 , further comprising the step: threading a grounding bolt into the bolt bore of the weld nut after the applying an axial forging force step. 13. A method for making a ground, comprising: lowering an aluminum alloy nut into contact with an alloy substrate; rotating the nut between 15000 and 18000 rpm at a frictional force of 3 to 4 bars between the nut and substrate; arresting the rotation of the nut; and applying an axial forging force between 3 and 6 bars to the nut and substrate to form a joint by solid state diffusion at an elevated temperature without melting. 14. The method of claim 13 , wherein the lowering step further comprises lowering a bolt bore of the weld nut into a clearance hole of the alloy substrate. 15. The method of claim 13 , wherein the friction and forging times are predetermined to generate a spin-welded, metallurgical joint between the outer wall of the weld nut and the substrate having mechanical properties suitable for use in a vehicular, electrical ground component. 16. The method of claim 14 , further comprising the step: threading a grounding bolt into the bolt bore of the weld nut after the applying an axial forging force step.