Method and apparatus to form a workpiece employing vibration welding

The invention claimed is: 1. A method for joining a shape-memory alloy (SMA) cable to a substrate employing a vibration welding system, the method comprising: positioning a portion of the SMA cable onto a surface of the substrate; interposing an aluminum cover piece overtop of the portion of the SMA cable; placing the substrate, the portion of the SMA cable and the cover piece onto an anvil of the vibration welding system such that the cover piece is interposed between the SMA cable and a sonotrode of the vibration welding system; and applying, via the sonotrode of the vibration welding system, vibration energy onto the cover piece, the portion of the SMA cable and the substrate; wherein applying the vibration energy mechanically joins the substrate, the SMA cable and the cover piece. 2. The method of claim 1 , further comprising: forming a channel on the surface of the substrate; and positioning the portion of the SMA cable in the channel formed on the surface of the substrate. 3. A method for mechanically joining a cable to a substrate employing a vibration welding system, wherein the vibration welding system includes an anvil and a sonotrode, the method comprising: positioning a portion of the cable onto a surface of the substrate; interposing a cover piece overtop of the portion of the cable; placing the substrate, the portion of the cable and the cover piece onto the anvil of the vibration welding system such that the cover piece is interposed between the cable and the sonotrode of the vibration welding system wherein the cable comprises a single strand formed from a shape-memory alloy; and applying, via the sonotrode of the vibration welding system, vibration energy onto the cover piece, the portion of the cable and the substrate; wherein applying the vibration energy mechanically joins the substrate, the cable and the cover piece. 4. The method of claim 3 , further comprising forming a hook portion on an end portion of the cable; wherein positioning the portion of the cable onto the surface of the substrate comprises positioning the hook portion on the end portion of the cable onto the surface of the substrate. 5. The method of claim 4 , further comprising inducing, via the sonotrode of the vibration welding system, a compressive force on the substrate, the portion of the cable and the cover piece placed on the anvil prior to applying, via the sonotrode of the vibration welding system, the vibration energy. 6. The method of claim 3 , further comprising forming a channel onto the surface of the substrate, and wherein positioning the portion of the cable onto the surface of the substrate comprises positioning the portion of the cable onto the channel formed onto the surface of the substrate. 7. The method of claim 6 , further comprising inducing, via the sonotrode of the vibration welding system, a compressive force on the substrate, the portion of the cable and the cover piece placed on the anvil prior to applying, via the sonotrode of the vibration welding system, the vibration energy. 8. The method of claim 3 , wherein the cover piece comprises a tubular sheath having a hollow portion, wherein interposing the cover piece overtop of the portion of the cable comprises inserting the cover piece into the hollow portion of the tubular sheath. 9. The method of claim 3 , further comprising inducing, via the sonotrode of the vibration welding system, a compressive force on the substrate, the portion of the cable and the cover piece placed on the anvil prior to applying, via the sonotrode of the vibration welding system, the vibration energy. 10. The method of claim 3 , further comprising: wherein the cover piece comprises a device having a thickness that is selected to prevent mechanical damage to the cable during the applying of the vibration energy via the sonotrode of the vibration welding system. 11. The method of claim 3 , wherein the substrate and the cover piece are fabricated from aluminum. 12. The method of claim 3 , wherein the substrate and the cover piece are fabricated from copper. 13. The method of claim 3 , wherein the substrate and the cover piece are fabricated from a thermoplastic polymer. 14. A method for mechanically joining a cable to a substrate, the method comprising: positioning a portion of the cable onto a surface of the substrate; wherein the cable comprises multiple strands, wherein each strand is formed from a shape-memory alloy; interposing a cover piece overtop of the portion of the cable; placing the substrate, the portion of the cable and the cover piece onto an anvil of a vibration welding system such that the cover piece is interposed between the cable and a sonotrode of the vibration welding system; inducing, via the sonotrode of the vibration welding system, a compressive force on the substrate, the portion of the cable and the cover piece placed on the anvil; and applying, via the sonotrode of the vibration welding system, vibration energy onto the cover piece, the portion of the cable and the substrate; wherein applying the vibration energy mechanically joins the substrate, the cable and the cover piece. 15. The method of claim 14 , further comprising forming a hook portion on an end portion of the cable; wherein positioning the portion of the cable onto the surface of the substrate comprises positioning the hook portion on the end portion of the cable onto the surface of the substrate. 16. The method of claim 14 , further comprising forming a channel onto the surface of the substrate; wherein positioning the portion of the cable onto the surface of the substrate comprises positioning the portion of the cable onto the channel formed onto the surface of the substrate. 17. The method of claim 14 , wherein the cover piece comprises a device having a thickness that is selected to prevent mechanical damage to the cable during the applying of the vibration energy via the sonotrode of the vibration welding system.