This study provides a comprehensive comparative analysis of Conventional Friction Stir Welding (CFSW) and Bobbin Tool Friction Stir Welding (BTFSW) for AA6061-T6 aluminum alloy plates. A factorial experimental design was employed to systematically investigate the effects of rotational speed, feed rate, tilt angle or pinching gap, plunge depth, and tool pin profile on joint performance. Regression models for ultimate tensile strength (UTS) and Vickers micro-hardness (HV) were developed and validated through analysis of variance (ANOVA), with all models exhibiting excellent fit (R² > 0.99) and strong predictive capability. The results demonstrate that both CFSW and BTFSW can achieve high-quality, defect-free welds, with CFSW yielding a maximum UTS of 241.52 MPa and BTFSW achieving comparable strength and superior hardness (up to 101.26 HV with a threaded pin). ANOVA revealed rotational speed and tool profile as the most significant factors for UTS, while feed rate and pin geometry predominantly governed hardness. Response surface analysis identified pronounced interaction and quadratic effects, highlighting the importance of simultaneous optimization of multiple process parameters. BTFSW outperformed CFSW in terms of process flexibility, hardness, and defect mitigation, attributed to its symmetrical heat input and elimination of the backing plate. The study delivers validated predictive equations and detailed process maps to guide industrial practitioners in optimizing Friction Stir Welding (FSW) parameters for AA6061-T6, ultimately enabling the tailored achievement of superior mechanical properties and weld integrity.

Highlights

• This study systematically compares the mechanical performance and process response of Conventional FSW and Bobbin Tool FSW configurations for AA6061-T6 aluminum alloy, using identical experimental protocols and advanced statistical modeling.

• Regression models validated by ANOVA and diagnostic plots (R² > 0.99) accurately predict ultimate tensile strength and hardness based on key process variables, providing a reliable framework for process optimization.

• Results reveal that BTFSW offers superior hardness, process flexibility, and defect mitigation over CFSW, while both methods achieve comparable peak tensile strengths when optimally configured.

• Optimized process maps and validated models are provided as practical tools for industry practitioners to achieve tailored mechanical properties and high-quality welds in AA6061-T6, supporting flexible implementation in advanced manufacturing.