The assembly quality of high-torque nuts in the deep cavity (95mm-diameter, 800mm-deep) of aero-engine low-pressure rotors directly determines engine operational reliability. Key technical challenges include meeting the 1900–2100 N m torque requirement, 0. 2^ angular accuracy demand, and stable preload control under thermal-centrifugal coupling conditions. To address these issues, this study proposes an optimization method integrating fractal contact mechanics and multi-physics coupling, and develops a visual tightening system that combines visual monitoring with servo control. Utilizing the W-M (Weierstrass-Mandelbrot) fractal function and Hertz theory, the research reveals that a surface roughness of Ra=1. 6 m limits the real contact area to 12%–18% of the nominal area. A thread stiffness model is established, with the calculated overall stiffness of 5. 06 10⁵ N/mm showing a relative error of less than 1% compared to experimental results. ANSYS simulations quantify preload attenuation under thermal-centrifugal coupling conditions. The developed system achieves an angular positioning accuracy of 0. 18^. Experimental verification on 20 aero-engines test dummy shows that the developed system achieves an angular positioning accuracy of 0. 18^, controls preload error within 8\% (relative to the 200 kN design preload), reduces single assembly time from 4 to 2. 6 h (35% efficiency improvement), and effectively avoids part collisions during the assembly process. These results fully meet the high-reliability assembly requirements of aero-engines.
Liu et al. (Mon,) studied this question.
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