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

We claim: 1. An additive manufacturing system, comprising: a high energy device which irradiates a surface of a workpiece with a high energy discharge to create first and second molten puddles on a surface of said workpiece; a first power supply which supplies a first heating signal to a first wire where said first heating signal comprises a plurality of first current pulses and where each of said first current pulses of said first heating signal creates a molten droplet on a distal end of said first wire which is deposited into said first puddle; and a second power supply which supplies a second heating signal to a second wire where said second heating signal comprises a plurality of second current pulses and where each of said second current pulses of said second heating signal creates a molten droplet on a distal end of said second wire which is deposited into said second puddle; and wherein each of said first current pulses reaches a peak current level after said distal end of said first wire contacts said first puddle, wherein said first heating signal has no current in between said plurality of said first current pulses; wherein said first wire is retracted such that said distal end of said first wire is not in contact with said first puddle between subsequent peak current levels of said first current pulses; wherein said first power supply controls said first heating current such that no arc is created between said first wire and said work piece during said first current pulses; and wherein said first and second molten puddles are distinct molten puddles. 2. The system of claim 1 , wherein each of the distinct molten puddles are adjacent to each other on the workpiece. 3. The system of claim 1 , wherein said first and second wires are positioned in line in a travel direction and wherein said second wire trails said first wire and said second wire is positioned such that it is deposited onto a layer created by said first wire. 4. The system of claim 1 , wherein said first wire has a different composition than said second wire. 5. The system of claim 1 , wherein said first wire has a first wire feed speed and said second wire has a second wire feed speed which is different than said first wire feed speed. 6. The system of claim 1 , further comprising a first contact tip for said first wire and a second contact tip for said second wire, where said first and second contact tips deliver said first and second heating signals, respectively, to said first and second wires, and wherein said first and second contact tips are movable relative to each other. 7. The system of claim 1 , further comprising a first contact tip for said first wire and a second contact tip for said second wire, where said first and second contact tips deliver said first and second heating signals, respectively, to said first and second wires, and wherein said first wire has a first stick out distance which is a different from a second stick out distance for said second wire. 8. The system of claim 1 , further comprising a first contact tip for said first wire and a second contact tip for said second wire, where said first and second contact tips deliver said first and second heating signals, respectively, to said first and second wires, and a contact tip assembly which couples said first and second contact tips to each other, wherein said contact tip assembly is rotatable relative to a travel direction of said first and second wires. 9. The system of claim 1 , wherein said first power supply monitors a voltage of said first heating signal when said first wire is in contact with said first puddle and compares said voltage to an arc detection voltage level. 10. The system of claim 1 , wherein each of said second current pulses reaches a peak current level after said distal end of said second wire contacts said second puddle, wherein said second wire is retracted such that said distal end of said second wire is not in contact with said second puddle between subsequent peak current levels of said second current pulses. 11. An method of additive manufacturing, comprising: irradiating a surface of a workpiece with a high energy discharge to create first and second molten puddles on a surface of said workpiece; supplying a first heating signal to a first wire where said first heating signal comprises a plurality of first current pulses and where each of said first current pulses of said first heating signal creates a molten droplet on a distal end of said first wire which is deposited into said first puddle; and supplying a second heating signal to a second wire where said second heating signal comprises a plurality of second current pulses and where each of said second current pulses of said second heating signal creates a molten droplet on a distal end of said second wire which is deposited into said second puddle; and wherein each of said first current pulses reaches a peak current level after said distal end of said first wire contacts said first puddle, wherein said first heating signal has no current in between said plurality of said first current pulses; wherein said first wire is retracted such that said distal end of said first wire is not in contact with said first puddle between subsequent peak current levels of said first current pulses; wherein said first heating current is controlled such that no arc is created between said first wire and said workpiece during said first current pulses; and wherein said first and second molten puddles are distinct molten puddles. 12. The method of claim 11 , wherein each of the distinct molten puddles are adjacent to each other on the workpiece. 13. The method of claim 11 , wherein said first and second wires are positioned in line in a travel direction and wherein said second wire trails said first wire and said second wire is positioned such that it is deposited onto a layer created by said first wire. 14. The method of claim 11 , wherein said first wire has a different composition than said second wire. 15. The method of claim 11 , wherein said first wire is fed at a first wire feed speed and said second wire is fed at a second wire feed speed which is different than said first wire feed speed. 16. The method of claim 11 , further comprising passing said first wire through a first contact tip and passing said second wire through a second contact tip, where said first and second contact tips deliver said first and second heating signals, respectively, to said first and second wires, and moving said first and second contact tips relative to each other. 17. The method of claim 11 , further comprising passing said first wire through a first contact tip and passing said second wire through a second contact tip, where said first and second contact tips deliver said first and second heating signals, respectively, to said first and second wires, and wherein said first wire is maintained at a first stick out distance which is a different from a second stick out distance for said second wire. 18. The method of claim 11 , further comprising passing said first wire through a first contact tip and passing said second wire through a second contact tip, where said first and second contact tips deliver said first and second heating signals, respectively, to said first and second wires, and rotating said second contact tip relative to said first contact tip during said additive manufacturing. 19. The method of claim 11 , further comprising monitoring a voltage of said first heating signal when said first wire is in contact with s