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A technical guide to TIG (GTAW) welding covering fundamentals, equipment configuration, tungsten electrodes, shielding gases, operating modes, common defects, advantages and industrial applications.
Tungsten Inert Gas (TIG) welding — formally Gas Tungsten Arc Welding (GTAW) — is the most precise arc welding process. It uses a non-consumable tungsten electrode to create the arc, with optional filler rod addition, and relies on an inert shielding gas (typically high-purity argon) to protect the arc and weld pool from atmospheric contamination. The absence of flux and the clean shielding environment mean no slag, minimal spatter, and excellent metallurgical integrity.
Because TIG focuses heat input tightly and allows independent control of filler, it is chosen when joint quality and appearance are critical — aerospace components, pharmaceutical and food-grade stainless pipework, nuclear and chemical processing equipment, precision automotive and motorsport fabrications.
The TIG arc is established between a sharpened tungsten tip and the workpiece. Tungsten’s melting point (~3,422 °C) ensures the electrode does not melt into the pool; the arc supplies heat to fuse the base metal. Autogenous welds fuse joint edges without filler and are common on thin stainless or titanium. Where reinforcement, gap filling, or tailored properties are needed, a matching filler rod is added manually to the pool’s leading edge, always inside the gas envelope.
Arc length is typically controlled within 1–3 mm; excessive length causes arc wandering, oxidation, and porosity. Torch angle of ~10–15° in the travel direction improves visibility and gas coverage. Dipping the tungsten into the pool or touching the filler to the electrode contaminates the tip, destabilising the arc and risking tungsten inclusions.
TIG requires a constant-current (CC) power source with a drooping volt–ampere characteristic: current remains stable despite small changes in arc length. Most sets provide DC, AC, or AC/DC. DC electrode negative (DCEN) concentrates ~70% of heat into the workpiece; AC alternates polarity to clean oxide films and penetrate, essential for aluminium and magnesium.
Arc initiation is achieved via high-frequency (HF) start (non-contact) to avoid tungsten contamination, or lift-arc where HF is unavailable. Controls (foot pedal or torch-mounted) allow real-time current modulation for crater fill, variable thickness, or position changes. Torches are air-cooled for light/medium duty or water-cooled for high current and long duty cycles. Gas lenses and appropriately sized nozzles improve shielding.
Choice of tungsten influences arc start, stability, and life:
Tip geometry is critical: a ground cone produces a narrow, concentrated arc (DCEN steels/stainless), while a slightly balled tip is used for AC aluminium.
Supplied in cut lengths (typ. 1.6–3.2 mm). Composition generally matches the base metal with alloying to tune toughness/corrosion resistance (e.g., ER70S-2 carbon steel, ER308L stainless, ER5356 aluminium-magnesium). Feed the rod to the pool’s leading edge within the gas shroud; remove surface oxides and oils prior to welding.
Argon (Ar) is the universal first choice: easily ionised, smooth arcs, good cleaning and coverage at modest flow rates. Helium (He) raises arc voltage and heat input, increasing penetration and travel speed on thick sections (higher flow rates required). Ar/He blends combine stability with heat for aluminium and copper alloys. Ar/H2 (1–5%) improves surface finish and penetration on austenitic stainless and Cu-Ni alloys, but must not be used on hydrogen-sensitive materials.
Set flow to achieve laminar coverage: too low risks oxidation/porosity; too high creates turbulence and entrains air. Use post-flow to protect hot tungsten and fresh weld metal until dull red/black, preventing oxidation and colouration.
Typical discontinuities and how to address them:
TIG delivers the highest weld quality with excellent surface finish, no slag and virtually no spatter. Independent control of heat and filler metal allows fine control on thin material, reactive alloys (Ti, Zr), and code-critical joints. Pulsed capability widens usability to positional and thin-gauge work. Compact torches and gas lenses improve access and shielding in confined geometries.
Common applications include aerospace (titanium/nickel alloy structures and engine parts), pharmaceutical and food-grade stainless pipework, nuclear and chemical pressure systems, motorsport and performance automotive fabrications (exhausts, roll cages, alloy tanks), and general fabrication of thin sheet or prototypes where aesthetics and integrity are paramount.
Use lanthanated or thoriated for DC welding of steels and nickel alloys; pure or lanthanated for AC aluminium/magnesium. Choose diameter based on current; grind a longitudinal cone for DCEN, form a slight ball for AC aluminium.
Typical starting points are 6–10 L/min for argon with standard cups; increase for larger nozzles, gas lenses, or helium blends. Avoid excessive flow that causes turbulence and air entrainment.
Use pulsed TIG on thin stainless, titanium, or heat-sensitive joints to reduce overall heat input and stabilise a small weld pool. It improves out-of-position control and helps manage distortion.
Colouring indicates oxidation due to inadequate shielding or too short a post-flow. Increase post-flow, ensure the cup is correctly sized, reduce arc length, and shield the rear of the joint when required (e.g., purge for stainless pipe).
No. Autogenous TIG is suitable for close-fitting joints on thin materials. Use filler when gaps exist, reinforcement is required, or to tailor mechanical/corrosion properties.
TIG welding is the benchmark for precision fabrication: clean, slag-free welds, fine control of heat and filler, and compatibility with a wide range of materials including reactive alloys. While slower and more skill-intensive than MIG or MMA, it delivers the weld integrity demanded by aerospace, nuclear, pharmaceutical, and high-spec manufacturing.
Explore ESAB’s AC/DC TIG power sources, precision torches, tungsten electrodes, and filler rods to achieve code-compliant, repeatable quality.
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