System and method to detect droplet detachment

What is claimed is: 1. A process for detecting detachment of a droplet from a wire during a welding operation that uses a shielding gas comprising the steps of: providing a welding signal to a welding electrode in a succession of welding cycles during a spray or pulsed spray welding process, each said welding cycle including a pulsed output comprised of a background output condition with a superimposed high output pulse condition during which the welding electrode heats up to a molten droplet and is pinched off and separates from the end of the electrode; measuring at least one welding parameter during said welding process to determine a start time for the measurement of the at least one welding parameter; calculating a derivative over time of said at least one welding parameter; during said high output pulse condition, identifying droplet detachment from the wire by detecting a peak signature in the absence of a short circuit condition within said derivative of at least one welding parameter during an arc of the welding operation to determine an end time for the measurement of the at least one welding parameter, a difference between the start time and end time being a time duration; and returning to said background output condition by reducing a magnitude of at least one welding parameter of said pulsed output used with said welding process based on said step of detecting the peak signature within said derivative, and using the time duration to modify a subsequent welding cycle. 2. The process of claim 1 wherein said at least one welding parameter is selected from the group consisting of current, voltage, resistance, and power. 3. The process of claim 1 wherein said peak signature is a positive peak or a negative peak. 4. The process of claim 1 wherein said peak signature is based on a type of material used in the welding process. 5. The process of claim 1 which further comprises the step of applying said time duration as a threshold value for a next cycle of said pulse. 6. The process of claim 5 which further comprises the step of terminating a next cycle of said pulse based on said step of applying, and wherein said time duration is a threshold value for said next cycle of said pulse. 7. The process of claim 1 which further comprises the step of applying said time duration as input for an adaptive control of the welding process for a next cycle. 8. The process of claim 1 which further comprises the step of applying said time duration as an indicia of consistency of a droplet size. 9. The process of claim 1 which further comprises the step of detecting a wire feed speed during said duration of time. 10. The process of claim 9 which further comprises the step of generating at least one action to correct a wire feed speed inconsistency based upon said step of detecting. 11. The process of claim 9 wherein said action applies said wire feed speed for a next cycle of said pulse. 12. The process of claim 1 which further comprises the step of modifying said welding signal in said welding process based on said step of reducing. 13. A process for detecting droplet detachment and a droplet detachment point from a wire during a welding operation that uses a shielding gas comprising the steps of: providing a welding signal to a welding electrode in a succession of welding cycles during a spray or pulsed spray welding process, each said welding cycle a pulsed output comprised of a background output condition with a superimposed high output pulse condition during which the welding electrode heats up to a molten droplet and is pinched off and separates from the end of the electrode; measuring at least one welding parameter associated with the welding signal to determine a start time for the measurement of the at least one welding parameter; calculating a derivative over time of the at least one welding parameter associated with the welding signal selected from the group consisting of voltage, current, resistance, and power during said welding process; during said high output pulse condition, identifying droplet detachment from the wire by detecting a peak signature in the absence of a short circuit condition within said step of calculating during an arc of the welding operation to determine an end time for the measurement of the at least one welding parameter, a difference between the start time and the end time being a time duration; returning to said background output condition based on detecting the peak signature in the derivative; and modifying said pulsed output used with said welding process based on said step of detecting the time duration. 14. The process of claim 13 which further comprises the steps of using said time duration as a threshold value for a next cycle of said pulse; and terminating said next cycle of said pulse based on said detecting the peak signature. 15. The process of claim 13 which further comprises the steps of detecting a wire feed speed during said time duration; and using said wire feed speed for a next cycle to correct a wire feed speed inconsistency. 16. The process of claim 13 which further comprises the step of changing at least one parameter of said welding signal in said welding process based on said step of modifying. 17. A process for detecting droplet detachment and a droplet detachment point from a wire during a welding operation that uses a shielding gas comprising the steps of: providing a welding signal to a welding electrode in a succession of welding cycles during a spray or pulsed spray welding process, each said welding cycle including a pulsed output comprised of a background output condition with a superimposed high output pulse condition during which the welding electrode heats up to a molten droplet and is pinched off and separates from the end of the electrode; measuring at least one welding parameter during an arc of said pulse welding process; calculating a derivative over time of said at least one welding parameter; during said high output pulse condition, identifying droplet detachment from the wire by identifying a peak signature time in the absence of a short circuit condition within said derivative over time of said at least one welding parameter during an arc of the welding operation to determine an end time for a cycle; returning to said background output condition by reducing a magnitude of at least one welding parameter of said pulsed output used with said pulse welding process based on said step of identifying the peak signature within said derivative; monitoring a duration of time from a start of said pulsed output to said end time; and using said duration of time as input for an adaptive control of said pulse welding process for a next cycle of said pulsed output. 18. The process of claim 17 wherein said at least one welding parameter is selected from the group consisting of current, voltage, resistance, and power.