Disc turbine impeller serves as a vital component of stirred-tank bioreactors and plays crucial role in optimizing their performance. This research integrates Computational Fluid Dynamics (CFD) with Taguchi experimental method to analyze the effects of blade curvature, asymmetry, and radial bending angles on disc turbine impeller performance. The designed P-0.1-T15B20-AM30° impeller maximizes the objective function [Formula: see text], balancing volumetric oxygen transfer coefficient [Formula: see text] and power input per unit volume [Formula: see text]. Statistical analysis revealed that blade curvature significantly affected [Formula: see text] and [Formula: see text], blade asymmetry substantially impacted [Formula: see text] and [Formula: see text], and the radial bending angle exhibited a notable influence on [Formula: see text], [Formula: see text], and [Formula: see text]. The P-0.1-T15B20-AM30° impeller sustains an average oxygen transfer efficiency of 52.3% equivalent to that of the Rushton turbine (RT) impeller and 68.9% akin to the CD-6 impeller, while its average energy consumption is merely 31.2% and 46.1% of the RT and CD-6 impellers, respectively. The average [Formula: see text] of the P-0.1-T15B20-AM30° impeller is enhanced by 12.4% and 8% in comparison to the RT and CD-6 impellers, respectively. Conclusively, these results demonstrate that the P-0.1-T15B20-AM30° impeller offers economic and practical advantages in aerobic bioprocesses and presents new perspectives for advancing impeller design.