Dual twin-saw wire cladding

The invention claimed is: 1. A system for cladding a workpiece, the system comprising: a first twin submerged arc welding (“SAW”) head configured to receive a first leading wire and a first trailing wire along a first cladding line; a second twin SAW head configured to receive a second leading wire and a second trailing wire along a second cladding line, the second twin SAW head arranged behind the first twin SAW head along a welding direction; and a flux hopper configured to apply a conductive electroslag flux to the workpiece, wherein the conductive electroslag flux facilitates resistive heating of the first leading wire, the first trailing wire, the second leading wire, and the second trailing wire to melt the conductive electroslag flux without generating an arc and form a molten slag pool, and the conductive electroslag flux electrically couples at least the first leading wire and the first trailing wire to one another to facilitate heat transfer to encourage formation of a thick cladded deposit on the workpiece via the molten slag pool; wherein the second cladding line is offset from the first cladding line in a direction perpendicular to the first cladding line. 2. The system of claim 1 , wherein a separation distance between the first trailing wire and the second leading wire is set to deposit a single layer of NiCrMo3 with less than 5% iron content, wherein a thickness of the single layer meets a desired cladding thickness. 3. The system of claim 2 , wherein the separation distance is less than 10 mm. 4. The system of claim 1 , wherein the flux hopper is configured to apply the conductive electroslag flux to the workpiece adjacent to the first twin SAW head. 5. The system of claim 1 , comprising a power source configured to direct one or more currents to the first leading wire, the first trailing wire, the second leading wire, the second trailing wire, or any combination thereof, wherein the molten slag pool formed by melting the conductive electroslag flux receives the one or more currents and generates heat via resistive heating. 6. A system for cladding a workpiece, the system comprising: a first twin submerged arc welding (“SAW”) head arranged proximal to a second twin SAW head, the first twin SAW head configured to: direct at least two first consumable wires toward a surface of the workpiece; and introduce a first current to the at least two first consumable wires for melting the at least two first consumable wires via resistive heating when they contact a molten slag pool formed on the workpiece; and the second twin SAW head configured to: direct at least two second consumable wires toward the surface of the workpiece; and introduce a second current to the at least two second consumable wires for melting the at least two second consumable wires via resistive heating when they contact the molten slag pool formed on the workpiece; and a flux hopper configured to apply a conductive electroslag flux to the surface of the workpiece, wherein the conductive electroslag flux facilitates resistive heating of the at least two first consumable wires and the at least two second consumable wires to melt the conductive electroslag flux without generating an arc and form the molten slag pool, and the conductive electroslag flux electrically couples the at least two first consumable wires to one another to facilitate heat transfer to encourage formation of a thick cladded deposit on the workpiece via the molten slag pool; wherein the first and second twin SAW heads are configured to translate together to form the thick cladded deposit across the surface of the workpiece. 7. The system of claim 6 , wherein the at least two first consumable wires comprise a first leading wire and a first trailing wire and the first current comprises a direct current. 8. The system of claim 7 , wherein the at least two second consumable wires comprise a second leading wire and a second trailing wire and the second current comprises an alternating current. 9. The system of claim 6 , wherein the molten slag pool comprises the conductive electroslag flux and is configured to receive the first current and/or the second current to generate heat via resistive heating. 10. The system of claim 6 , wherein the conductive electroslag flux is configured to: conduct the first current between the at least two first consumable wires and the molten slag pool to facilitate resistive heating; and conduct the second current between the at least two second consumable wires and the molten slag pool to facilitate resistive heating. 11. The system of claim 6 , wherein the thick cladded deposit comprises NiCrMo3 with less than 5% iron content. 12. The system of claim 11 , wherein the first and second twin SAW heads are further configured to deposit the thick cladded deposit at a rate of about 25 to 36 kg/hour.