Welding duplex stainless steel is a highly technical topic. Due to its unique dual-phase (ferrite + austenite) microstructure, special care is required during welding to maintain its excellent mechanical properties and corrosion resistance.
一. Core Objective: Maintaining Phase Balance
The performance advantages of duplex stainless steel derive from a phase balance of approximately 50% ferrite (α) and 50% austenite (γ). The welding process, a rapid heating and cooling thermal cycle, can disrupt this balance, resulting in:
① Excessive cooling: Excessive ferrite content in the weld metal and heat-affected zone (HAZ). This can lead to:
▶ Reduced toughness
▶ Reduced corrosion resistance (especially resistance to chloride stress corrosion cracking)
② Excessively slow cooling or prolonged dwelling in a specific temperature range:
▶ Precipitation of brittle phases such as σ phase, χ phase, α’ phase (brittle at 475°C), and nitrides. These precipitates can significantly degrade toughness and corrosion resistance.
Therefore, the ultimate goal of all welding processes is to control heat input and interpass temperature to ensure sufficient austenite formation in the weld metal and heat-affected zone during cooling, while avoiding the precipitation of harmful phases.
二. Key Welding Techniques
1. Welding Material Selection:
Principle: Select welding materials with a higher alloying content (especially nickel and nitrogen) than the base metal.
① Reason: Alloying elements (such as nitrogen) burn off during welding, and rapid cooling inhibits austenite formation. A higher content of austenite-forming elements (Ni, N) promotes sufficient austenite precipitation in the weld metal during cooling, thereby balancing the phase ratio.
② Common Matches:
▶ Welding 2205 (S32205/S31803): ER2209 wire/electrode is typically used.
▶ Welding super-duplex steel (such as S32750): ER2594 wire/electrode is used.
▶ Welding economical duplex steels (such as S32101/S32304): Use ER2209 or specialized welding consumables.
2. Heat Input Control: Heat input must be within a “suitable window,” neither too high nor too low.
① Too Low Heat Input:
▶ Too rapid cooling prevents austenite from precipitating, resulting in excessively high ferrite content.
② Too High Heat Input:
▶ Too slow cooling results in severely coarse grains in the heat-affected zone (HAZ), and the steel tends to remain in the precipitation-sensitive temperature range (e.g., 600-1000°C) for extended periods, forming harmful phases such as σ phase.
③ Recommended Range: Typically controlled between 0.5 and 2.5 kJ/mm. Specific recommended values should be referenced by the base material and welding consumable suppliers.
④ Calculation formula: Heat input (kJ/mm) = (Current I x Voltage V x 60) / (Welding speed mm/s x 1000)
3. Interpass temperature control: This is one of the most important parameters for welding duplex steel and requires the most stringent control.
① Requirements: Must be strictly controlled, typically ≤ 100°C (for standard duplex steel); super duplex steel has even stricter requirements, sometimes requiring ≤ 80°C.
② Cause: Excessively high interpass temperatures are equivalent to high-temperature heat treatment of the previous weld pass, which can promote the precipitation of harmful phases and coarsen grains. This also leads to a cumulative heat input effect in subsequent weld passes, slowing cooling.
③ Action: During welding, a thermometer (such as a thermometer pen or infrared thermometer gun) must be used to continuously monitor the workpiece temperature to ensure it cools below the specified temperature before proceeding to the next weld pass.
4. Shielding gas:
① TIG/MIG welding: Pure argon (Ar) is typically used for shielding.
② For the root pass: To improve root pass formation and austenitization, ~2% nitrogen (N₂) can be added to the argon gas. This compensates for nitrogen burn-off and promotes austenite formation.
③ Note: Pure argon + hydrogen mixtures are generally not recommended, as hydrogen can cause porosity and hydrogen embrittlement.
5. Preheating and Postheating:
① Preheating: Generally not required. Unless the workpiece temperature is below 0°C, a slight preheating to 15-25°C may be performed to prevent moisture. High-temperature preheating is detrimental.
② Postheating: Postweld heat treatment (PWHT) is not recommended. This is because the standard stress relief temperature (~580-600°C) is in the sensitive temperature range for σ phase precipitation, which can severely degrade properties.
③ The only exception is if σ phase precipitation is confirmed, in which case solution annealing (water quenching at approximately 1040-1100°C) is required, but this is usually performed at the fabricator, not on-site.
三. Common Welding Methods: Almost all arc welding methods can be used for duplex stainless steel, but the above key points must be adhered to.
1. Tungsten Inert Gas Welding (TIG/GTAW):
▶Application: The preferred method for root passes, thin plates, and critical welds. High control precision and excellent quality.
▶Requirements: Ensure good gas shielding, and preferably use argon or an argon-nitrogen mixture for the back root pass.
2. Metal Inert Gas Welding (MIG/GMAW):
▶Application: Filling and cap welding, high efficiency.
▶Mode: Pulsed MIG is recommended for better heat input control and reduced spatter.
3. Stick Metal Arc Welding (SMAW):
▶Application: On-site installation and difficult-to-access areas.
▶Requirements: Use a basic electrode, strictly maintain a short arc, and control arc energy. High welder skills are required.
4. Submerged Arc Welding (SAW):
▶ Applications: Longitudinal and circumferential welds in thick-walled materials, highly efficient.
▶ Requirements: Neutral flux must be used to prevent alloying element burnout. Heat input and interpass temperature must be strictly controlled.
四. Welding Procedure Qualification: Before actual production welding, a welding procedure qualification (WPQ) must be conducted to develop a qualified welding procedure specification (WPS). Qualification testing should include at least:
① Nondestructive Testing (NDT): RT radiography or UT ultrasonic testing.
② Destructive Testing:
▶ Macrometallography: Inspect weld bead formation, fusion, and defects.
▶ Micrometallography: This is a must-check! The ferrite content of the weld metal (WM) and heat-affected zone (HAZ) must be assessed, typically between 30-60% (optimally 35-55%). Also check for harmful precipitates such as sigma phase.
③ Mechanical properties tests: tensile, flexural, and impact toughness (Charpy V impact tests at -40°C or -50°C are usually required).
④ Corrosion testing: For critical components, pitting corrosion resistance tests (such as ASTM G48 Method A) are required to ensure that corrosion resistance meets standards.
五. Summary: Practical Operation
1. Preparation: Select the correct and compatible welding consumables; thoroughly clean the groove and both sides of the groove from oil, dirt, water, and oxides.
2. Gas: Use pure argon shielding; consider Ar + 2% N₂ for critical root passes.
3. Control: Strictly follow WPS requirements, controlling heat input and interpass temperature (≤100°C).
4. Techniques: Use low current and a relatively fast welding speed to avoid large fluctuations.
5. Monitoring: Measure the interpass temperature with a temperature gun at all times.
6. Inspection: Perform NDT testing according to standards after welding, and perform metallographic and corrosion inspections as necessary.
Finally, it is emphasized that the success of duplex stainless steel welding depends greatly on rigorous process specifications and the strict compliance of welders/operators. Before starting any important project, be sure to conduct process assessment and consult the material supplier for advice.