Kjell Hurtig scite author profile

This is a study of the effect of repetitive TIG (tungsten inert gas) welding passes, melting and remelting the same material volume on microstructure and corrosion resistance of 2507 (EN 1.4410) super duplex stainless steel. One to four weld passes were autogenously (no filler added) applied on a plate using two different arc energies and with pure argon shielding gas. Sensitization testing showed that multipass remelting resulted in significant loss of corrosion resistance of the weld metal, in base material next to the fusion boundary, and in a zone 1 to 4 mm from the fusion boundary. Metallography revealed the main reasons for sensitization to be a ferrite-rich weld metal and precipitation of nitrides in the weld metal, and adjacent heat affected zone together with sigma phase formation at some distance from the fusion boundary. Corrosion properties cannot be significantly restored by a post weld heat treatment. Using filler metals with higher nickel contents and nitrogen containing shielding gases, are therefore, recommended. Welding with a higher heat input and fewer passes, in some cases, can also decrease the risk of formation of secondary phases and possible corrosion attack. Trollh€ attan (Sweden) Innovatum AB., Trollh€ attan, SE-461 29 Trollh€ attan (Sweden)

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Wire-arc additive manufacturing of a duplex stainless steel: thermal cycle analysis and microstructure characterization

Hosseini

Högström

Hurtig

et al. 2019

Weld World

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The evolution of microstructures with thermal cycles was studied for wire-arc additive manufacturing of duplex stainless steel blocks. To produce samples, arc energy of 0.5 kJ/mm and interlayer temperature of 150°C were used as low heat input-low interlayer temperature (LHLT) and arc energy of 0.8 kJ/mm and interlayer temperature of 250°C as high heat input-high interlayer temperature (HHHT). Thermal cycles were recorded with different thermocouples attached to the substrate as well as the built layers. The microstructure was analyzed using optical and scanning electron microscopy. The results showed that a similar geometry was produced with 14 layers-4 beads in each layer-for LHLT and 15 layers-3 beads in each layer-for HHHT. Although the number of reheating cycles was higher for LHLT, each layer was reheated for a shorter time at temperatures above 600°C, compared with HHHT. A higher austenite fraction (+ 8%) was achieved for as-deposited LHLT beads, which experienced faster cooling between 1200 and 800°C. The austenite fraction of the bulk of additively manufactured samples, reheated several times, was quite similar for LHLT and HHHT samples. A higher fraction of secondary phases was found in the HHHT sample due to longer reheating at a high temperature. In conclusion, an acceptable austenite fraction with a low fraction of secondary phases was obtained in the bulk of wire-arc additively manufactured duplex stainless steel samples (35-60%), where higher austenite fractions formed with a larger number of reheating cycles as well as longer reheating at high peak temperatures (800-1200°C).

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Control Design for Automation of Robotized Laser Metal-wire Deposition

Heralic

Christiansson

Hurtig

et al. 2008

IFAC Proceedings Volumes

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Kjell Hurtig

Nitrogen loss and effects on microstructure in multipass TIG welding of a super duplex stainless steel

Influence of multiple thermal cycles on microstructure of heat-affected zone in TIG-welded super duplex stainless steel

Effect of multipass TIG welding on the corrosion resistance and microstructure of a super duplex stainless steel

Wire-arc additive manufacturing of a duplex stainless steel: thermal cycle analysis and microstructure characterization

Control Design for Automation of Robotized Laser Metal-wire Deposition

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