Abstract:The deformation and densification behaviors of pure Al powders during 1-4 passes equal channel angular pressing and torsion (ECAPT) under route A at 200 ℃ were investigated using numerical simulation and experiment investigation. In addition, both grain refinement mechanism and the evolution of microstructure and mechanical properties were deeply discussed. The bulk ultrafine-grained pure aluminum with fine microstructure and enhanced mechanical properties was fabricated. The results show that with the increasing pass number of ECAPT, the imposed strain increases. Due to the work hardening, the peak load also increases. As the hydrostatic pressure increases under multi-pass ECAPT, residual porosities in the powder consolidates are effectively shrunk and closed, which contributes to the improvement of deformation uniformity and density of the compacts. During ECAPT process, continuous dynamic recrystallization occurs. As the number of ECAPT passes increases, grains are further refined and mechanical properties are largely enhanced. After 4 passes of ECAPT, the microstructure consists of homogeneous ultrafine grains of 600 nm in size and equiaxed in shape with high angle grain boundaries. Moreover, the tensile strength reaches 123.3 MPa.

Key words: ultrafine grained material (UFG); equal channel angular pressing and torsion (ECAPT); multi-pass deformation; microstructure; property