Electrode metal preheating for arc start improvement

What is claimed is: 1. A submerged arc welding system, the system comprising: a welding power supply configured to supply at least a preheating current level and a welding current level; a welding torch; a wire feeder configured to feed a consumable welding electrode to the welding torch; and a controller configured to communicate with and control, via computer-executable instructions executed by at least one processor of the controller, at least the welding power supply and the wire feeder to perform the ordered steps of: (a) advance the consumable welding electrode through the welding torch and toward a workpiece via the wire feeder and stop advancement of the consumable welding electrode, via the wire feeder, in response to determining, via sense leads, when a tip of the consumable welding electrode makes contact with the workpiece, (b) provide the preheating current level, via a same welding circuitry of the welding power supply that is used for providing the welding current level, through a portion of the consumable welding electrode proximate the workpiece while the tip of the consumable welding electrode is in contact with the workpiece during a preheating period of time to preheat the portion of the consumable welding electrode without establishing an arc, (c) retract the consumable welding electrode, via the wire feeder, from the workpiece and increase the preheating current level to the welding current level, via the welding power supply, over an arc establishment period of time to establish the arc between the tip of the consumable welding electrode and the workpiece, and (d) begin to form a weld by advancing the consumable welding electrode toward the workpiece again, via the wire feeder, once the welding current level is reached, resulting in melting the tip of the consumable welding electrode and depositing molten metal onto the workpiece. 2. The system of claim 1 , further comprising a robot configured to move the welding torch across the workpiece under an arc condition to continue to form the weld at the welding current level provided by the welding power supply until the weld is complete, without having to further preheat the consumable welding electrode at the preheating current level provided by the welding power supply. 3. The system of claim 1 , wherein the preheating period of time is based on an established relationship, electronically stored within the controller, between the preheating period of time and at least one of a material of the consumable welding electrode, a material of the workpiece, a diameter of the consumable welding electrode, and a stickout distance of the consumable welding electrode. 4. The system of claim 3 , further comprising a user interface configured to allow the preheating period of time to be subsequently manually adjusted by a user. 5. The system of claim 4 , wherein the controller is configured to, via the computer-executable instructions executed by the at least one processor, automatically reestablish a new relationship between the preheating period of time and the at least one of the material of the consumable welding electrode, the material of the workpiece, the diameter of the consumable welding electrode, and the stickout distance of the consumable welding electrode in response to the preheating period of time being subsequently manually adjusted by the user. 6. The system of claim 1 , wherein the preheating current level is based on an established relationship, electronically stored within the controller, between the preheating current level and at least one of a material of the consumable welding electrode, a material of the workpiece, a diameter of the consumable welding electrode, and a stickout distance of the consumable welding electrode. 7. The system of claim 6 , further comprising a user interface configured to allow the preheating current level to be subsequently manually adjusted by a user. 8. The system of claim 7 , wherein the controller is configured to, via the computer-executable instructions executed by the at least one processor, automatically reestablish a new relationship between the preheating current level and the at least one of the material of the consumable welding electrode, the material of the workpiece, the diameter of the consumable welding electrode, and the stickout distance of the consumable welding electrode in response to the preheating current level being subsequently manually adjusted by the user. 9. The system of claim 1 , further comprising a flux supply configured to deposit a flux material over the tip of the consumable welding electrode proximate the workpiece once the arc is established. 10. The system of claim 1 , further comprising the sense leads, operatively connected to at least one of the wire feeder or the welding power supply, and configured to sense when the tip of the consumable welding electrode makes contact with the workpiece.