Influence of composition, grain size and iron oxide particles on the strength of consolidated ball-milled iron
Document typeConference lecture
Rights accessOpen Access
In this paper iron powders with two oxygen content (0.2 and 0.6% wt.) have been mechanically milled and consolidated by hot static pressing at different temperatures to obtain different grain sizes. At lower temperatures the grain size was in the nanostructured and ultrafine range and with increasing temperature abnormal grain growth was observed for both compositions. This led to the development of bimodal grain size distributions. In the samples with lower oxygen content the grain size and the percentage of coarse grain areas were larger than in the case of high oxygen content. The strength and ductility have been determined by tensile tests. For low oxygen content, the presence of large coarse grains allowed plastic strain in some cases, and for the samples consolidated at higher temperatures, yield strength of 865 MPa with a 8% total strain were obtained. For the samples with high oxygen content plastic deformation was no possible in any case. The observed stress for both compositions was analysed by two approaches, one based exclusively in grain boundary strengthening and the other one based in two effects acting at the same time: grain boundary and particle strengthening. Whereas grain boundary strengthening seems to fit with the strength of the samples in the nanostructured range, when coarse ferrite grains appear the addition of particle strengthening help to get better results. This indicates that the presence of oxides dissolved inside the large grains reinforce the structure of ball-milled iron.
CitationBenito, J.; casas, C.; Cabrera, J. Influence of composition, grain size and iron oxide particles on the strength of consolidated ball-milled iron. A: The 6th international conference on nanomaterials by severe plastic deformation. "IOP Conf. series: Materials Science and Engineering 63 (2014) 012024. 6th International conference on nanomaterials by severe plastic deformation". Metz: 2014.