Deformation Behavior, a Flow Stress Model Considering the Contribution of Strain and Processing Maps in the Isothermal Compression of a Near-α Ti-3.3Al-1.5Zr-1.2Mo-0.6Ni Titanium Alloy

In the present study, isothermal compression tests are conducted for a near-alpha Ti-3.3Al-1.5Zr-1.2Mo-0.6Ni titanium alloy at deformation temperatures ranging from 1073 K to 1293 K and strain rates ranging from 0.01 s(-1) to 10 s(-1) on a Gleeble-3500 thermomechanical compressor. The results show that, in the initial stage of the compression, the flow stress rapidly increases to a peak value because of elastic deformation, and then the alloy enters the plastic deformation stage and the flow stress slowly decreases with the increase in strain and tends to gradually stabilize. In the plastic deformation stage, the flow stress significantly decreases with the increase in the deformation temperature and the decrease in strain rate. A flow stress model considering the contribution of the strain is established, and the relative error between the calculated and the experimental values is 3.72%. The flow stress model has higher precision and can efficiently predict the flow behavior in the isothermal compression of the alloy. Furthermore, the processing map of the Ti-3.3Al-1.5Zr-1.2Mo-0.6Ni alloy is drawn. Based on the processing map, the influence of process parameters on power dissipation efficiency and stability parameters is analyzed, and the optimized hot working process parameters are pointed out.

Automated summary

In this study, isothermal compression tests were conducted on a near-alpha titanium alloy using a Gleeble-3500 thermomechanical compressor. The results showed that the alloy exhibited elastic deformation and plastic deformation during compression, with the flow stress being influenced by deformation temperature and strain rate. A flow stress model was established to accurately predict the flow behavior of the alloy, and a processing map was drawn based on the model.