Systems and methods for using fluorine-containing gas for submerged arc welding

The invention claimed is: 1. A submerged arc welding system, comprising: a fluorine-containing gas that is carbon tetrafluoride; a gas supply system coupled to a welding torch assembly, wherein the gas supply system stores the fluorine-containing gas and provides the fluorine-containing gas as a fluorine-containing gas flow to the welding torch assembly; a wire supply system coupled to the welding torch assembly that provides welding wire to the welding torch assembly; a flux supply system coupled to the welding torch assembly that provides a flow of granular flux to the welding torch assembly; and the welding torch assembly comprising: a welding torch body comprising a gas conduit fluidly coupled to the gas supply system; a contact tip coupled to the welding torch body, wherein the contact tip comprises: a central welding wire conduit that receives the welding wire provided by the wire supply system and delivers the welding wire near a workpiece to form a weld pool; a plurality of gas conduits disposed around the central welding wire conduit and fluidly coupled to the gas conduit of the welding torch body, wherein the plurality of gas conduits receives the fluorine-containing gas flow provided by the gas supply system and delivers the fluorine-containing gas flow near the weld pool; and a flux delivery component coupled to the welding torch body and disposed around the contact tip, wherein the flux delivery component receives the flow of granular flux from the flux supply system and mixes, near the weld pool, the flow of granular flux with the fluorine-containing gas flow delivered by the plurality of gas conduits of the contact tip before depositing the granular flux to form a flux bed over the weld pool. 2. The submerged arc welding system of claim 1 , wherein the fluorine-containing gas flow and the granular flux both at least partially provide a local atmosphere near the weld pool, and wherein the fluorine-containing gas flow reduces an amount of hydrogen in the weld pool. 3. The submerged arc welding system of claim 1 , wherein the fluorine-containing gas flow comprises argon, helium, carbon dioxide, oxygen, nitrogen, hydrogen or a combination thereof. 4. The submerged arc welding system of claim 1 , wherein the fluorine-containing gas flow comprises between approximately 0.01% and approximately 10% by volume fluorine-containing gas. 5. The submerged arc welding system of claim 1 , wherein the granular flux comprises aluminate rutile (AR), aluminate basic (AB), aluminate fluoride basic (AF), fluoride basic (FB), or calcium silicate (CS) flux. 6. The submerged arc welding system of claim 1 , comprising a controller coupled to a plurality of sensors that are configured to measure parameters of the submerged arc welding system and parameters of the welding environment, wherein the controller is configured to control the gas supply system, the wire supply system, the flux supply system based, at least in part, on measurements received from the plurality of sensors. 7. The submerged arc welding system of claim 1 , wherein the gas supply system comprises a flow control system that receives the fluorine-containing gas flow from a gas source and provides the fluorine-containing gas flow to the welding torch assembly, wherein the flow control system controls a flow rate of the fluorine-containing gas flow, a composition of the fluorine-containing gas flow, or a combination thereof. 8. A submerged arc welding system, comprising: a fluorine-containing gas that is carbon tetrafluoride; a gas supply system that stores the fluorine-containing gas and provides the fluorine-containing gas as a fluorine-containing gas flow; and a welding torch assembly, comprising: a contact tip coupled to a welding torch body that is fluidly coupled to the gas supply system to receive the fluorine-containing gas flow, wherein the contact tip comprises: a central welding wire conduit that receives welding wire from a welding wire conduit of the welding torch body and delivers the welding wire to a surface of a workpiece to form a weld pool; and a plurality of gas conduits disposed around the central welding wire conduit and fluidly coupled to a gas conduit of the welding torch body, wherein the plurality of gas conduits receives the fluorine-containing gas flow from the gas conduit of the welding torch body and delivers the fluorine-containing gas flow near the weld pool; and a flux delivery component attached to the welding torch body and disposed around the contact tip, wherein the flux delivery component receives from a flux supply system and mixes, near the weld pool, a granular flux with the fluorine-containing gas flow delivered by the plurality of gas conduits of the contact tip before forming a bed of the granular flux over the weld pool. 9. The submerged arc welding system of claim 8 , wherein the plurality of gas conduits delivers the fluorine-containing gas flow at a low pressure, at a low gas flow rate, or a combination thereof, to not disturb the bed of the granular flux formed over the weld pool. 10. The submerged arc welding system of claim 8 , wherein the welding torch assembly is a submerged arc welding torch or a hybrid submerged arc welding torch. 11. The submerged arc welding system of claim 8 , comprising a flow control system coupled to at least one fluorine-containing gas source and to the welding torch assembly, wherein the flow control system receives the fluorine-containing gas flow from the at least one fluorine-containing gas source and outputs the fluorine-containing gas flow to the welding torch assembly, wherein the flow control system controls a flow rate of the fluorine-containing gas flow, a composition of the fluorine-containing gas flow, or a combination thereof. 12. The submerged arc welding system of claim 11 , wherein the flow control system controls a flow rate of the fluorine-containing gas flow to prevent the fluorine-containing gas flow from disturbing a flux bed over the weld pool. 13. The submerged arc welding system of claim 8 , wherein the welding torch body comprises: a gas conduit that enables the fluorine-containing gas flow to pass through the welding torch body to reach the contact tip; and a welding wire conduit that enables welding wire to pass through the welding torch body to reach the contact tip. 14. A hybrid submerged arc welding (HSAW) system, comprising: a fluorine-containing gas that is carbon tetrafluoride; a gas supply system that stores the fluorine-containing gas and provides the fluorine-containing gas as a fluorine-containing gas flow; and a HSAW welding torch assembly, comprising: a welding torch body comprising a gas conduit fluidly coupled to the gas supply system to receive the fluorine-containing gas flow; a flux delivery component attached to the welding torch body and coupled to a flux delivery system, wherein the flux delivery component receives a flow of granular flux from the flux delivery system and forms a flux bed over a weld pool; and a contact tip coupled to the welding torch body and surrounded by the flux delivery component, wherein the contact tip comprises: a central welding wire conduit that delivers welding wire to form the weld pool; a plurality of gas conduits disposed around the central welding wire conduit and fluidly coupled to the gas conduit of the welding torch body, wherein the plurality of gas conduits receives the fluorine-containing gas flow from the gas conduit of the welding torch body, and delivers the fluorine-containing gas flow near the weld pool to displace air and moisture near the weld pool and to displace air and moisture in the g