Method and system for additive manufacturing using high energy source and hot-wire

We claim: 1. An additive manufacturing system, comprising: an energy source which irradiates a surface of a workpiece with an energy discharge from said energy source to create a molten puddle on said surface of said workpiece; a wire feeder which feeds a wire to said puddle; a power supply that is configured to supply a heating signal to said wire where said heating signal comprises a plurality of current pulses and where each of said current pulses creates a molten droplet on a distal end of said wire which is deposited into said puddle; and a controller operatively connected to said power supply and said wire feeder, said controller configured to: control said wire feeder such that said wire feeder causes said distal end of said wire to contact said puddle, control said power supply such that each of said current pulses reaches a peak current level after said contact between said distal end of said wire and said puddle, control said power supply such that said heating signal has no current in between said plurality of said current pulses, control a movement of said wire, via said wire feeder, such that said distal end of said wire is not in contact with said puddle between subsequent peak current levels of said current pulses, and control said heating signal, via said power supply, such that no arc is created between said wire and said workpiece during said current pulses. 2. The additive manufacturing system of claim 1 , wherein said energy source is a laser. 3. The additive manufacturing system of claim 1 , wherein said energy source turns off said energy discharge in between each of said current pulses. 4. The additive manufacturing system of claim 1 , wherein said power supply uses an arc generation voltage current threshold and maintains said peak current levels below said arc generation current threshold. 5. The additive manufacturing system of claim 1 , wherein said power supply provides an open circuit voltage to said wire prior to said distal end of said wire making contact with said puddle. 6. The additive manufacturing system of claim 1 , wherein said power supply monitors a voltage of said heating signal when said wire is in contact with said puddle and compares said voltage to an arc detection voltage level. 7. The additive manufacturing system of claim 6 , wherein said power supply turns off said heating signal after it is detected that said voltage exceeds said arc detection voltage level. 8. The additive manufacturing system of claim 1 , wherein each of said energy discharge and an advancing wire feed speed for said wire are at peak levels during at least a portion of each of said peak current levels. 9. The additive manufacturing system of claim 1 , wherein said wire feeder retracts said wire after each of said droplets is deposited into said puddle. 10. The additive manufacturing system of claim 9 , wherein said current pulses include a burnback current level which is provided during retraction. 11. The additive manufacturing system of claim 1 , wherein the power supply includes a circuit that monitors a rate of change of at least one of an output voltage, the heating current signal, or an output power with respect to time and turns off said heating signal if the rate of change exceeds a predetermined threshold value. 12. An additive manufacturing system, comprising: an energy source which irradiates a surface of a workpiece with an energy discharge from said energy source to create a molten puddle on said surface of said workpiece; a wire feeder which feeds a wire to said puddle; a power supply that is configured to supply a heating signal to said wire where said heating signal comprises a first portion and a second portion, said first portion comprising at least one current pulse where said at least one current pulse creates a molten droplet on a distal end of said wire which is deposited into said puddle, said second portion providing a heating current to said wire, and where said first portion follows a first current path and said second portion follows a second current path that is different from the first current path; and a controller operatively connected to said power supply and said wire feeder, said controller configured to: control said wire feeder such that said wire feeder causes said distal end of said wire to contact said puddle, control said power supply such that said at least one current pulse reaches a peak current level after said contact between said distal end of said wire and said puddle, control a movement of said wire, via said wire feeder, such that said distal end of said wire is not in contact with said puddle between subsequent peak current levels of subsequent current pulses, control said heating signal, via said power supply, such that no arc is created between said wire and said workpiece during said current pulses, and control said power supply to switch said heating signal between said first portion and said second portion. 13. The additive manufacturing system of claim 12 , further comprising a switch which switches from said first current path to said second current path. 14. The additive manufacturing system of claim 12 , wherein said heating current of said second portion maintains said wire a temperature in the range of 40 to 90% of a melting temperature of said wire. 15. The additive manufacturing system of claim 12 , wherein the power supply includes a circuit that monitors a rate of change of at least one of an output voltage, an output current, or an output power with respect to time and turns off said heating signal if the rate of change exceeds a predetermined threshold value. 16. An additive manufacturing system, comprising: an energy source which irradiates a surface of a workpiece with an energy discharge from said energy source to create a molten puddle on said surface of said workpiece; a wire feeder which feeds a wire to said puddle; a power supply that is configured to supply a heating signal to said wire where said heating signal comprises a plurality of current pulses and where each of said current pulses creates a molten droplet on a distal end of said wire which is deposited into said puddle; and a controller operatively connected to said power supply and said wire feeder, said controller configured to: control said wire feeder such that said wire feeder causes said distal end of said wire to contact said puddle, control said power supply such that each of said current pulses reaches a peak current level after said contact between said distal end of said wire and said puddle, control said power supply such that said heating signal has no current in between said plurality of said current pulses, control a movement of said wire, via said wire feeder, such that said distal end of said wire is not in contact with said puddle between subsequent peak current levels of said current pulses, and control said heating signal, via said power supply, such that no arc is created between said wire and said workpiece during said current pulses, wherein at least some of said energy discharge is directed to said wire by said energy source to aid in the creation of said droplets. 17. The additive manufacturing system of claim 16 , wherein the power supply includes a circuit that monitors a rate of change of at least one of an output voltage, an output current, or an output power with respect to time and turns off said heating signal if the rate of change exceeds a predetermined threshold value.