Harmonic metal manufacturing wire reciprocation

What is claimed is: 1. A welding torch comprising: a wire guide configured to guide welding wire fed from a wire feeder to a first end of the torch to deliver welding wire to a welding application, the wire guide defining a clearance zone within which the welding wire oscillates when a force transverse to a travel path of the welding wire is applied to the welding wire within the clearance zone, wherein the wire guide comprises a plurality of rollers, the clearance zone comprises a spacing between successive rollers, and a length of the clearance zone is adjustable by adjusting the spacing by adding or removing rollers; and an actuator configured to apply the force to the welding wire in at least one direction transverse to the travel path of the welding wire within the clearance zone at a first frequency to oscillate welding wire within the clearance zone. 2. The welding torch of claim 1 , further comprising a linkage having an aperture through which the welding wire is routed, wherein the actuator is configured to apply the force to the linkage to oscillate the welding wire within the clearance zone. 3. The welding torch of claim 2 , wherein the first frequency is based at least in part on a mass of the linkage. 4. The welding torch of claim 2 , wherein the actuator is a coil configured to produce a magnetic field, and wherein the linkage comprises a magnet. 5. The welding torch of claim 1 , wherein a resonant oscillation frequency of welding wire within the clearance zone is at least 25 hertz. 6. The welding torch of claim 1 , wherein the first frequency is a resonant oscillation frequency of the welding wire within the clearance zone. 7. The welding torch of claim 1 , wherein the wire guide comprises at least one sprag clutch along the length of the wire guide before the clearance zone, wherein the clutch allows the welding wire to move in a forward direction towards the first end of the torch and restricts the welding wire from moving in a backward direction away from the first end. 8. The welding torch of claim 7 , wherein oscillation of welding wire within the clearance zone is configured to cause the welding wire to provide a reciprocating movement at the first end of the torch at a frequency twice the first frequency. 9. The welding torch of claim 1 , wherein the actuator is a motor configured to apply the force directly to the welding wire within the clearance zone. 10. The welding torch of claim 1 , wherein the clearance zone comprises a guide configured to restrict movement of welding wire within the clearance zone to a single plane. 11. A welding torch comprising: a wire guide configured to guide welding wire fed from a wire feeder to a first end of the torch to deliver welding wire to a welding application, the wire guide defining a clearance zone within which the welding wire may oscillate when a force transverse to a travel path of the welding wire is applied to welding wire within the clearance zone; an actuator configured to apply the force in at least one direction to welding wire within the clearance zone at a first frequency to oscillate welding wire within the clearance zone; and control circuitry configured to determine the first frequency based on the type of welding wire, the diameter of the welding wire, a length of the clearance zone as defined by the endpoints of the clearance zone, and a mass of material to be oscillated within the clearance zone, and to control the actuator based on the determined first frequency. 12. The welding torch of claim 11 , wherein the control circuitry determines the frequency via determining a spring constant of the welding wire based on the type of welding wire, the diameter of the welding wire, and the length of the clearance zone. 13. The welding torch of claim 11 , wherein the determined first frequency is a resonant frequency of the welding wire within the clearance zone. 14. The welding torch of claim 1 , wherein the actuator is a rotary motor that drives a cam. 15. A welding torch comprising: a wire guide configured to guide welding wire fed from a wire feeder to a first end of the torch to deliver welding wire to a welding application, the wire guide defining a clearance zone within which the welding wire may oscillate when a force transverse to a travel path of the welding wire is applied to welding wire within the clearance zone, wherein the wire guide comprises a freewheeling guide wheel and a unidirectional guide wheel, wherein the clearance zone is between a first contact point between the freewheeling guide wheel and the welding wire and a second contact point between the unidirectional guide wheel and the welding wire; and an actuator configured to apply the force in at least one direction to welding wire within the clearance zone at a first frequency to oscillate welding wire within the clearance zone. 16. The welding torch of claim 1 , wherein the torch is a gas metal arc welding (GMAW) torch. 17. The welding torch of claim 15 , further comprising a linkage having an aperture through which the welding wire is routed, wherein the actuator is configured to apply the force to the linkage to oscillate the welding wire within the clearance zone. 18. The welding torch of claim 15 , wherein the first frequency is a resonant oscillation frequency of the welding wire within the clearance zone. 19. The welding torch of claim 15 , wherein the actuator is a motor configured to apply the force directly to the welding wire within the clearance zone. 20. The welding torch of claim 15 , wherein the clearance zone comprises a guide configured to restrict movement of welding wire within the clearance zone to a single plane.