Mattia Spezzapria scite author profile

Electrically assisted manufacturing is based on the electro-plastic effect induced by electricity on the material flow during deformation and represents an alternative method for forming materials. Several studies have pointed out the real effectiveness of this technique, but no relations among microstructure, electrical resistivity, crystal structure and deformation-mode have been revealed. In the present work, the stacking fault energy (SFE) was taken into account and three FCC materials possessing different SFEs were strained in electrically assisted uniaxial tension under continuous current application. The results showed an advantageous electric contribution only in the highest SFE material, whereas no enhancements in formability were revealed in the investigated low- and intermediate-SFE metals

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Effect of Prior Microstructure and Heating Rate on the Austenitization Kinetics of 39NiCrMo3 Steel

Spezzapria

Settimi

Pezzato

et al. 2016

steel research int.

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The formation of austenite from three different prior microstructures is studied in a 39NiCrMo3 steel, which, indeed, is widely used in the industry, especially for induction heating treatments, due to its resistance to thermal cracking. The starting microstructure of sorbite with fine carbides, sorbite with coarse carbides and stress-relieved martensite is examined in detail by optical microscopy, scanning electron microscopy, and Vickers microhardness measurements. Dilatometric tests are performed employing different heating rates spanning in the 100-800 8C s À1 range in order to assess the kinetics of the austenitic transformation. The experimental results are compared and critically linked in order to determine the fundamental factors governing the austenite formation when using high heating rates. The formation of austenite from sorbite with coarse and fine carbides is observed to occur in two consecutive stages: (i) cementite dissolution and (ii) ferrite to austenite transformation. The start and finish temperature of austenitic transformation increase with heating rate. For stress-relieved martensitic microstructure, instead, the a' to g transformation can take place through two different mechanisms: diffusive at low heating rates and displacive at high heating rate. Critical points of austenite formation initially increase with heating rate, reach a maximum and then decrease at high heating rate.

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Mattia Spezzapria

Numerical Simulation of Solid–Solid Phase Transformations During Induction Hardening Process

Influence of stacking fault energy in electrically assisted uniaxial tension of FCC metals

Effect of Prior Microstructure and Heating Rate on the Austenitization Kinetics of 39NiCrMo3 Steel

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