<p>A 12-mm-thick AISI 316L(N) steel plate was welded using a hybrid technique that combines hot wire tungsten inert gas (HWTIG) and activated tungsten inert gas (A-TIG) processes. The microstructure and mechanical properties of the hybrid joint were systematically compared with those of multi-pass HWTIG and single-pass A-TIG welds. The hybrid weld metal contained 7% delta ferrite, sufficient to suppress hot cracking susceptibility. The average hardness values of the weld metal were 170 VHN for HWTIG, 175 VHN for A-TIG, and 180 VHN for the hybrid joint. The cross-weld tensile strength of the hybrid weld joint (580&#xa0;MPa) closely matches that of the HWTIG (605&#xa0;MPa) and A-TIG (575&#xa0;MPa) joints, indicating that all three welding techniques achieve similar strength levels under tensile loading. Charpy impact toughness values were also similar across the three processes (HWTIG: 155&#xa0;J, A-TIG: 140&#xa0;J, Hybrid: 150&#xa0;J). Fracture toughness of the hybrid joint was appreciable at both room temperature (410&#xa0;kJ·m⁻<sup>2</sup>) and 550&#xa0;°C (155&#xa0;kJ·m⁻<sup>2</sup>), aligning closely with HWTIG (400, 170&#xa0;kJ·m⁻<sup>2</sup>) and A-TIG (395, 165&#xa0;kJ·m⁻<sup>2</sup>). Overall, the HWTIG + A-TIG hybrid welding technique produced joints with acceptable microstructure and mechanical performance, demonstrating its potential for application in welding thick sections of nuclear reactor components.</p>

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Microstructure and mechanical property assessment of hot wire TIG and activated TIG hybrid weld joint of AISI 316L(N) stainless steel

  • Gopa Chakraborty,
  • Shashank Dutt B.,
  • Deepak Kumar Gupta,
  • Nani Babu M.,
  • Hemant Kumar,
  • C. R. Das,
  • A. Moitra,
  • Vasudevan M.

摘要

A 12-mm-thick AISI 316L(N) steel plate was welded using a hybrid technique that combines hot wire tungsten inert gas (HWTIG) and activated tungsten inert gas (A-TIG) processes. The microstructure and mechanical properties of the hybrid joint were systematically compared with those of multi-pass HWTIG and single-pass A-TIG welds. The hybrid weld metal contained 7% delta ferrite, sufficient to suppress hot cracking susceptibility. The average hardness values of the weld metal were 170 VHN for HWTIG, 175 VHN for A-TIG, and 180 VHN for the hybrid joint. The cross-weld tensile strength of the hybrid weld joint (580 MPa) closely matches that of the HWTIG (605 MPa) and A-TIG (575 MPa) joints, indicating that all three welding techniques achieve similar strength levels under tensile loading. Charpy impact toughness values were also similar across the three processes (HWTIG: 155 J, A-TIG: 140 J, Hybrid: 150 J). Fracture toughness of the hybrid joint was appreciable at both room temperature (410 kJ·m⁻2) and 550 °C (155 kJ·m⁻2), aligning closely with HWTIG (400, 170 kJ·m⁻2) and A-TIG (395, 165 kJ·m⁻2). Overall, the HWTIG + A-TIG hybrid welding technique produced joints with acceptable microstructure and mechanical performance, demonstrating its potential for application in welding thick sections of nuclear reactor components.