Submerged arc is a common welding process that is Often used in industries such as structural and vessel construction. Also known as Sub-Arc or SAW, this process uses a blanket of granular fusible flux, roomates beneath both the weld and the arc zone are protected or "submerged." This flux blanket guards against atmospheric contamination, stabilizes the arc during welding, prevents splatter and sparks from flying about, and suppresses radiation and fumes that are typical of the shielded metal arc welding process.
Throughout the submerged arc welding process, the flux has to be a continuously-fed consumable solid or tubular electrode. This fusible flux may Consist of lime, silica, manganese oxide, calcium fluoride, and other compounds. In a molten or melted state, the flux Becomes conductive. This Allows it to supply a constant current between the electrode and the welding work.
Usually the SAW process is automated; however, there are semi-automated systems available, too.
Material applications of SAW include carbon steels, low alloy steels, stainless steels, nickel-based alloys, and surfacing applications (wear-facing, buildup, and corrosion-resistant overlay of steels). SAW is frequently used in heavy structural construction. It is also used in the pressure vessel industry, chemical plants, and shipbuilding. Properly performed Sub-Arc welding should consistently result in mechanical properties that are at least equal to that of the base metal. Ductility and impact resistance should be good, and should be uniform bead appearance.
Throughout the submerged arc welding process, the flux has to be a continuously-fed consumable solid or tubular electrode. This fusible flux may Consist of lime, silica, manganese oxide, calcium fluoride, and other compounds. In a molten or melted state, the flux Becomes conductive. This Allows it to supply a constant current between the electrode and the welding work.
Usually the SAW process is automated; however, there are semi-automated systems available, too.
Material applications of SAW include carbon steels, low alloy steels, stainless steels, nickel-based alloys, and surfacing applications (wear-facing, buildup, and corrosion-resistant overlay of steels). SAW is frequently used in heavy structural construction. It is also used in the pressure vessel industry, chemical plants, and shipbuilding. Properly performed Sub-Arc welding should consistently result in mechanical properties that are at least equal to that of the base metal. Ductility and impact resistance should be good, and should be uniform bead appearance.
Advantages of Submerged Arc Welding
Some of the advantages of submerged arc welding include:
- Strong, sound welds are readily made
- Minimal welding fume is emitted
- Minimal arc light is emitted
- SAW is suitable for both indoor and outdoor works
- Less distortion
- Deep penetration weld
- Minimal edge preparation
- High deposition rates are possible
- Thick materials may be welded
- At least half or more of the flux is recoverable
Disadvantages of Submerged Arc Welding
There are a few limitations with submerged arc welding. One issue is that welding can normally be performed only in the flat position. The use of a granular flux and the fluidity of the molten weld pool mean that welding is limited to positions 1F, 1G, and 2F. Another disadvantage of SAW is that welding is normally limited to long, straight seams or rotated vessels or pipes. Flux handling systems can be quite bothersome, as well.
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