Hotwire deposition material processing system and method

The invention claimed is: 1. A material processing method, comprising: advancing an electrode toward a workpiece via a material processing torch to initiate a hotwire process; measuring enthalpy of the electrode; regulating enthalpy of the electrode during the hotwire process to maintain a desired first rate of enthalpy change of the electrode using a first linear relationship between a temperature of the electrode and the enthalpy; determining a fusion transition temperature of the electrode based on a second rate of enthalpy change of the electrode using a second linear relationship between the temperature of the electrode and the enthalpy; and regulating the enthalpy of the electrode to maintain a desired third rate of enthalpy change of the electrode using a third linear relationship between the temperature of the electrode and the enthalpy above the fusion transition temperature of the electrode, wherein the enthalpy is regulated by regulating current applied to the electrode based in part upon the determined fusion transition temperature or a determined electrode extension error. 2. The method of claim 1 , wherein the current is regulated based upon a proportional gain value. 3. The method of claim 1 , wherein the enthalpy is controlled to maintain a generally constant enthalpy of the electrode. 4. The method of claim 1 , wherein the enthalpy is controlled based upon known characteristics of the electrode selected for the hotwire process. 5. The method of claim 4 , wherein the characteristics are determined based upon an operator input of the selected electrode into a system power supply and/or a wire feeder. 6. The method of claim 1 , wherein the enthalpy is controlled based at least in part upon the relationship: EE*λ* I 2 =(((π( D w ) 2 τρ w )/4)*( H f −H o )), wherein EE is electrode extension, I is material processing current, D w is the diameter of the electrode, τ is linear flow rate of the electrode, ρ w the density of the electrode at a known temperature, H f is a desired enthalpy of the electrode and H o is an initial enthalpy of the electrode. 7. The method of claim 1 , wherein a wire feed speed of the electrode is regulated based upon the determined electrode extension error. 8. The system of claim 1 , wherein the electrode extension error is determined by comparing an actual electrode extension (EE actual ) with an ideal electrode extension (EE ideal ), wherein: EE actual =(( IV ) feedback )/( I 2 λ), and EE ideal =(π( D w ) 2 τρ w ( H f −H o ))/(4 I 2 λ), where EE actual is an actual electrode extension, EE ideal is an ideal electrode extension, (IV) feedback is feedback of voltage and current, I is material processing current, λ is linear impedance in units of ohm/length, D w is the diameter of the electrode, τ is linear flow rate of the electrode, ρ w is the density of the electrode at a known temperature, H f is a desired enthalpy of the electrode and H o is an initial enthalpy of the electrode. 9. The system of claim 8 , wherein the regulated current is controlled at least in part by: ΔI=(EE actual −EE ideal )k p , wherein k p is a gain factor. 10. A material processing method, comprising: advancing an electrode toward a workpiece via a material processing torch to initiate a hotwire process; during the hotwire process, heating the electrode at a first location using a heat source external to the material processing torch; measuring enthalpy of the electrode; regulating enthalpy of the electrode by regulating a wire feed speed of the electrode using a first linear relationship between a temperature of the electrode and the enthalpy; determining a fusion transition temperature of the electrode based on a second rate of enthalpy change of the electrode using a second linear relationship between the temperature of the electrode; and regulating the enthalpy of the electrode by regulating the wire feed speed of the electrode to maintain a desired third rate of enthalpy change of the electrode using a third linear relationship between the temperature of the electrode and the enthalpy above the fusion transition temperature of the electrode. 11. The method of claim 10 , wherein a wire feed speed of the electrode is regulated based upon the determined electrode extension error. 12. The method of claim 10 , wherein the temperature is controlled to maintain a generally constant temperature of the region of the electrode. 13. The method of claim 10 , wherein the temperature is controlled based upon known characteristics of the electrode selected for the hotwire process. 14. The method of claim 13 , wherein the characteristics are determined based upon an operator input of the selected electrode into a system power supply and/or a wire feeder. 15. A material processing system comprising: a power supply configured to provide power for a hotwire process; a wire electrode feeder configured to advance a wire electrode during the hotwire process; and a control system configured to: measure enthalpy of the electrode; regulate enthalpy of the wire electrode during the hotwire process to maintain a desired first rate of enthalpy change of the electrode using a first linear relationship between a temperature of the electrode and the enthalpy; determine a fusion transition temperature of the electrode based on a second rate of enthalpy change of the electrode using a second linear relationship between the temperature of the electrode and the enthalpy; regulate the enthalpy of the electrode to maintain a desired third rate of enthalpy change of the electrode using a third linear relationship between the temperature of the electrode and the enthalpy above the fusion transition temperature of the electrode; and regulate the enthalpy by regulating a current applied to the electrode based in part upon the determined fusion transition temperature or a determined electrode extension error. 16. The system of claim 15 , comprising a current sensor connected to detect current applied to the wire electrode, wherein the control system is configured to regulate enthalpy by regulating current applied to the wire electrode based upon feedback from the current sensor. 17. The system of claim 15 , wherein the current is regulated based upon a proportional gain value. 18. The system of claim 15 , wherein the enthalpy is controlled to maintain a generally constant enthalpy of the wire electrode. 19. The system of claim 15 , wherein a wire feed speed of the electrode is regulated based upon the determined electrode extension error.