Evaluation and mathematical modeling of asymmetric tensile and compressive creep in aluminum alloy ZL109

Abstract

This study investigates the effects of tension/compression asymmetry during creep deformation under different conditions. The asymmetry is found to be dependent on stress and temperature. At high temperatures (350°C, 70MPa) or high levels of stress (250°C, 130MPa), the ratio between the tensile and compressive creep rates can be as large as 10. This ratio is smaller at lower temperatures (200°C, 90MPa) and lower levels of stress (300°C, 30MPa). Scanning electron microscopy (SEM) visualization of different microdefects indicates that the size and volume of microcavities are dependent on the level of stress applied. Similarly, transmission electron microscopy (TEM) is used to visualize dislocations and twinning. The differences in microcavity size and volume in tensile and compressive creep appear to be larger under higher temperature and stress, but no difference in dislocation is observed and no twinning crystals are found. Cavity nucleation appears to be the cause of the asymmetry in creep behavior, which is determined by temperature and stress. A new mathematical model for creep is constructed and validated considering the different asymmetric mechanisms of tensile and compressive creep.