RT Journal Article
T1 Serrated flow in powder metallurgy Al-5%Mg-1.2%Cr alloy processed by equal channel angular pressing
A1 Eddahbi, Mohamed Ou Lahcen
A1 Monge Alcázar, Miguel Ángel
A1 Muñoz Castellanos, Ángel
A1 Pareja Pareja, Ramiro
AB The microstructure, texture and mechanical behavior of the powder metallurgy Al-5 wt.%Mg-1.2 wt.%Cr alloy subjected to equal channel angular pressing (ECAP) has been investigated. The material processed by ECAP, as well as in the homogenized condition, exhibited room temperature serrated flow (SF) up to fracture. The critical stress for the serration onset decreased with increasing strain rate or ECAP temperature. The results indicated that this SF was induced by shear banding. The stress oscillations were attributed to the interaction between shear bands (SBs) and obstacles like second phase particles, and dislocation locks produced by strain hardening. The early stages of the stress-strain sigma-epsilon curves of the ECAP processed samples showed a transition from type B serrations with continuous strain hardening to type B serrations superimposed on a succession of constant stress plateaus when the tensile strain rate was increased from 10⁻4 s⁻1 to 10⁻3 s⁻1.  The plateaus in sigma-epsilon curves obtained at a strain rate of 10⁻3 s⁻1 were ascribed to the nucleation of a band at one end of the sample gauge region and subsequent propagation towards the opposite end. At a low strain rate of 10⁻4 s⁻1 the sites for band nucleation should be randomly distributed along the sample gauge region. The disappearance of the plateaus in the sigma-epsilon curves are attributed to the activation of a new moving band before the completion of the deformation banding cycle of the preceding band.
PB Elsevier
SN 1044-5803
YR 2012
FD 2012-11
LK https://hdl.handle.net/10016/19679
UL https://hdl.handle.net/10016/19679
LA eng
NO The experimental work has been carried out at the LMNM(LM 290) laboratory supported by Madrid Community throughthe project TECHNOFUSION (S2009/ENE 1679) and Spanish Ministry of Science and Innovation (contract ENE2008 06403 C06 04).
DS e-Archivo
RD 1 may. 2024