Details

Autor(en) / Beteiligte

• Samantaray, Dipti
• Mandal, Sumantra
• Kumar, Vinod
• Albert, S.K.
• Bhaduri, A.K.
• Jayakumar, T.

Titel

Optimization of processing parameters based on high temperature flow behavior and microstructural evolution of a nitrogen enhanced 316L(N) stainless steel

Ist Teil von

• Materials science & engineering. A, Structural materials : properties, microstructure and processing, 2012-08, Vol.552, p.236-244

Ort / Verlag

Kidlington: Elsevier B.V

Erscheinungsjahr

2012

Link zum Volltext

Quelle

Access via ScienceDirect (Elsevier)

Beschreibungen/Notizen

• ► High temperature flow behavior of a nitrogen enhanced 316L(N) has been studied. ► Experimental stress–strain data have been generated using hot compression tests. ► Experimental data is used to develop processing map and activation energy map. ► The domains of the processing map have been validated using optical micrographs. ► Activation energy map has been used to finalize the optimum hot working parameters. The flow behavior of a high nitrogen grade 316L(0.14N) has been studied in a range of temperatures (1073–1423K) and strain rates (0.001–10s−1). The material exhibits two-slope behavior in the stress–strain rate relationship at ≤1223K. It exhibits local negative strain rate sensitivity (LNSRS) in the regime bounded by 1073–1123K and 0.1–1s−1. In the LNSRS domain, material shows inhomogeneous flow, reduced ductility and cracks under tensile loading. The experimental data has been used to develop processing map and activation energy map. The material exhibits a wide stable domain below 0.1s−1 spanning over 1073–1423K, whereas the domain above 0.1s−1 is demarcated as unsafe for processing. The stable domain consists of four peaks with efficiency of 35%, 45%, 50% and 45%, respectively. The activation energy for these peaks has been found to vary between 100 and 200kJ/mol. The localization of heavily deformed grains and random bimodal distribution of grains have been identified as the signatures of instability. Based on the processing map, activation energy map and microstructural evolution, the optimum window for hot deformation has been identified as 1350–1423K and 0.001–0.05s−1 with peak efficiency of 50% and activation energy of 150kJ/mol.