Chen Dengming

Strain-Induced Diffusion of Nickel in Nanocrystalline Fe Produced by High Energy Shot Peening

Abstract A nanocrystalline surface layer without oxidation, porosity or contamination was obtained by high energy shot peening (HESP) to a pure iron cylinder. The thickness of the nanocrystalline surface layer was more than 100 μm and the average grain size was about 50 nm. The pulse pressure diffusion (PPD) and constant pressure diffusion (CPD) were used to diffuse nickel into nanocrystalline iron at 850 °C on Gleeble 1500. Results show that the diffusion coefficient of Ni in the nanocrystalline Fe is 1 order of magnitude higher than that in coarse-grained Fe and 1 order of magnitude higher than that using CPD. The enhanced diffusivity of Ni may originate from the following three reasons: (1) pulse pressure can break the metallic compound formed during diffusing which may block the diffusion of Ni to inner nanocrystalline Fe; (2) a considerable amount of triple junctions and (3) a large volume fraction of non-equilibrium grain boundaries (GBs) in the present nanocrystalline Fe sample processed by the HESP technique.

The Directional Solidification Process Optimization of Al-Ni-Co-Ti Alloys Based on the Numerical Simulation Technology

The ratio of the temperature gradient at solidification front to the solidification rate of solid-liquid interface plays a great role for columnar grain growth. Transient temperature fields of directional solidification of Al-Ni-Co-Ti alloys were studied based FEM. The effect of molten steel pouring temperature, heat flux and mould temperature on the ratio was analyzed. The results show that molten steel pouring temperature has an effect on the ratio greatly and the individual ratio soars up in the initial stage of solidification in all situations, when the solidification front reaches 5-6cm, the ratio plunges down rapidly and even tends to be closed to each other. The simulation result is consistent with the production reality.