System and method for depositing a metal to form a three-dimensional part

We claim: 1. A system for printing a three-dimensional (3D) metallic part, comprising: a metal feedstock including a wire positioned through an electrical contact tube and is in contact with a workpiece that is electrically conductive, wherein a diameter of the wire is in a range of 0.003 to 0.010 inch; a power supply that is controllable connected to the electrical contact tube and supplies a current of a controllable amount through the electrical contact tube, to pass the current through the wire and to the workpiece, with the current returning to the power supply, such that the current is insufficient to melt the wire, and is less than 10 amperes, and the current produces heat energy via an ohmic heating to preheat the wire and the workpiece, wherein the current is an electrical current open circuit voltage below 18 volts that is insufficient to either, create, strike or maintain an arc, in a local atmosphere to the workpiece while printing; a deposit of a melt of the wire is deposited on the workpiece; a continuous electrical path that includes the wire, the electrical contact tube, the power supply, and the workpiece, the continuous electrical path being uninterrupted while the power supply is supplying the current; a laser beam is focused at a melt region located at a proximal end of the wire and the workpiece, wherein an energy of the laser beam coordinated with the ohmic heating produced by the current from the power supply in combination, heat the wire and a surface of the workpiece, while the wire is exposed to one of a natural convection or a forced convection cooling in an area located after the wire passes through the electrical contact tube, to before the wire contacts the workpiece, while the workpiece in the melt region is not cooled convectively; devices are extending the wire to the workpiece, the devices extending the wire to contact the workpiece to form the continuous electrical path before the power supply starts to supply the current; wherein the power supply supplies the current after the proximal end of the wire is in contact with a region of a surface of the workpiece and is heated to reach a melting temperature of both the wire and the region of the surface of the workpiece to create a weld pool, such that the ohmic heating and the energy of the laser beam are controlled to uninterruptedly maintain the continuous and uninterrupted electrical path through the weld pool on the workpiece, to create a section of the deposit of the melt of the wire on the workpiece; and wherein the power supply stops the current before the devices interrupt the continuous electrical path by retracting the wire from the deposit at the end of the section of the deposit. 2. The system of claim 1 , wherein the wire is positioned between the devices and the devices are drive rollers, such that upon movement of the drive rollers, the wire moves through the electrical contact tube and into contact with the workpiece. 3. The system of claim 2 , wherein the wire is in electrical contact with the electrical contact tube and the proximal end of the wire is in electrical contact with the workpiece. 4. The system of claim 3 , wherein moving the wire, the laser beam, controlling the energy of the laser beam and the current used for the ohmic heating, are controlled independently, such that the controlling of the ohmic heating and an amount of power for the laser beam are controlled to maintain a stable weld pool on the workpiece while the wire is fed into the weld pool, wherein the weld pool is established and maintained by the combination of the laser beam and the ohmic heating. 5. The system of claim 4 , wherein the controlled ohmic heating current and the amount of power for the laser beam and an amount of speed of the drive rollers are controlled in coordination by the system, such that the coordination is controlled to optimize the fusion of the wire to the workpiece and prior deposited metal while minimizing vaporization and spattering of melted metal. 6. The system of claim 1 , wherein the produced heat energy via the ohmic heating heats the wire and the workpiece, so a total system deposit time for depositing wire on the workpiece is at a kilogram per hour or less, resulting in an amount of total depositing time for printing the 3D metallic part that is less than an amount of total system depositing time for depositing wire on a workpiece using a laser-only or electron-beam only heating for printing a same 3D metallic part. 7. The system of claim 1 , wherein the wire is positioned between the devices, the devices are drive rollers, such that the drive rollers include motor-driven rollers. 8. The system of claim 1 , wherein relative motions of the wire, the laser beam, and an amount of power for the laser beam power are coordinated independently by a constant-voltage via the controllable power supply that supplies the wire fed by a motor, to optimize fusion of the wire to the workpiece, and to minimize vaporization of the wire and the workpiece, and to minimize spatter. 9. A method for depositing a metal to form a three-dimensional (3D) part, comprising steps: positioning a metal wire through an electrical contact tube and into contact with a workpiece that is electrically conductive; supplying a current of a controllable amount via a power supply which is controllable to the electrical contact tube, wherein the current passes through a continuous electrical path that includes the wire, the electrical contact tube, the power supply, and the workpiece, such that the current is insufficient to melt the wire, and the current produces heat energy via an ohmic heating to preheat the wire and the workpiece, wherein the current is an electrical current open circuit voltage below 18 volts that is insufficient to either, create, strike or maintain an arc, in a local atmosphere to the workpiece while printing; focusing a laser beam at a melt region located at an intersection of a proximal end of the wire and the workpiece, wherein a combination of an energy of the laser beam with the ohmic heating produced by the current from the power supply increase a bulk temperature of the wire and a surface of the workpiece, while the wire is exposed to one of a natural convection or a forced convection cooling in an area located after the wire passes through the electrical contact tube to before the wire contacts the workpiece, while the workpiece in the melt region is not cooled convectively; using drive rollers to extend the wire to the workpiece such that the wire contacts the workpiece and forms the continuous electrical path before the power supply starts to supply the current; supplying the current with the power supply such that the proximal end of the wire in contact with a region of a surface of the workpiece is heated to reach a melting temperature of both the wire and the region of the surface of the workpiece to create a weld pool, such that the ohmic heating and the energy of the laser beam are controlled to uninterruptedly maintain the continuous and uninterrupted electrical path through the weld pool on the workpiece; depositing a melt of the wire on the workpiece creating a section of a deposit of the wire on the workpiece; and stopping the current from the power supply before the drive rollers interrupt the continuous electrical path by retracting the wire from the deposit at the end of the section of the deposit. 10. A system for printing a three-dimensional (3D) metallic part, comprising: a metal feedstock including a wire positioned between drive rollers, wherein the drive rollers move the wire through an electrical contact tube and into contact with a workpiece that is electrically conductive, wherein a diameter of the w