Evaluating High-Pressure Torsion Scale-Up

Increasing sample dimensions in high-pressure torsion (HPT) processing affects load and torque requirements, deformation distribution, and heating. Finite-element modeling (FEM) and experiments are used to investigate the effect of technical parameters on the scaling up of HPT. Simulations confirm that axial load and torque requirements are proportional to the square and the cube of the sample radius, respectively. The temperature rise also displays a pronounced dependency on the radius. Decreasing the diameter-to-thickness ratio can cause heterogeneity in strain distribution along the thickness direction at the edges of the sample. Such heterogeneity is governed by friction conditions between the material and the lateral wall of the anvil depression. Simulation of HPT processing of ring-shaped samples shows that it is possible to reach more homogeneous distribution of strain and flow stress in the processed material. Experiments using magnesium confirm a tendency for strain localization in the early stage of HPT processing but increasing the number of turns increases the homogeneity of the material. The embodied energy in HPT processing is discussed. Finite-element modeling is used to evaluate scaling up samples in high-pressure torsion. It is shown that the sample aspect ratio and friction conditions affect deformation localization. Real experiments confirm the occurrence of deformation localization but increasing the number of turns improves homogeneity. The effect of sample diameter, thickness, and aspect ratio on homogeneity, torque requirements, and embodied energy is discussed.image (c) 2024 WILEY-VCH GmbH