Habib Hamed Zargari scite author profile

Tandem-pulsed gas metal arc welding (TP-GMAW) simultaneously uses two wire-electrodes to enhance the material deposition rate, leading to the generation of a finger-shaped penetration as one of the arcs penetrates deeper than the other. On the other hand, workpiece vibration is one of the techniques used to control the microstructure of weld metal and a heat-affected zone. It is incidentally found that a specific vibration condition changes the finger-shaped penetration into pan-bottom shaped penetration in the TP-GMAW even though the vibration energy is much lower than the arc energy. Microstructure observation and elemental analysis are carried out for the welds fabricated without vibration and with three kinds of vibration modes, namely sine, random, and shock. The specific sine-mode vibration exhibits pan-bottom. The other modes of vibration in the same welding conditions exhibited invariable finger-shaped penetration. The Si atoms as a tracer distribute uniformly in the sine-mode. However, Si atoms segregate at the bottom of the finger-shaped weld metal with the random-mode and shock-mode workpiece vibrations. The weld pool shape change is prominent at a specific frequency. A resonance phenomenon between the droplet flow pattern and the molten material flow in the weld pool is likely to play a vital role in the change.

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Cold rolling and intercritical annealing of C-Mn steel sheets with different initial microstructures

Karimi

Nedjad

Shirazi

et al. 2018

Materials Science and Engineering: A

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A unique CEL numerical method on material flow in a molten pool of workpiece vibration assisted welding

Zargari

Ito

Mikami

et al. 2020

QUARTERLY JOURNAL OF THE JAPAN WELDING SOCIETY

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Microstructure and Mechanical Properties of Mn-Containing Maraging Steels

Zargari

Nedjad

2015

J. of Materi Eng and Perform

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An attempt to the modification of the microstructure and mechanical properties of affordable, Mn-containing maraging alloys is reported. These alloys have demonstrated strong age hardening but suffered with premature intergranular brittleness despite their potential applications in tooling, dies, and machinery industries. An Fe-10Ni-6Mo-3Mn-1Ti (wt.%) alloy was prepared by vacuum melting and processed by homogenization (1250°C/48 h), cold rolling, solution annealing (950°C/1 h), and aging treatments (500°C/4 h). It presented tensile strength of about 2.65 GPa, a few percent of tensile elongation and a mixed ductile-brittle fracture mode. Transmission electron microscopy (TEM) revealed the precipitation of a nearly spherical phase. Crystal symmetry of the second phase precipitates was identified hexagonal closepacked corresponding reasonably to the Fe 2 Mo Laves phase having lattice parameters of a = 0.4745 and c = 0.7754 nm. Precipitation of a Mo-enriched second-phase particle was occasionally found at prior austenite grain boundaries but the pronounced grain boundary precipitation was never identified. Energyfiltering transmission electron microscopy using the Mo-M 4,5 post edge revealed remarkable segregation of Mo at grain boundaries.

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