Aiming at the problems of high reliance on manual labor and insufficient precision in the flexible material cutting process of the textile and garment industry, this paper proposes a driving control technology for a high-speed, high-precision and intelligent flexible material cutting system. By integrating multi-field coupling modelling, multi-objective electromagnetic optimization design and thrust fluctuation suppression technology, the thrust performance and temperature rise characteristics of the motor are optimized. Furthermore, a dual-motor synchronous control system was developed based on the deviation coupling and fuzzy PID algorithm, reducing the synchronous error to the sub-micron level and improving the control accuracy. This research achievement is of great significance in promoting the transformation of the textile and garment industry towards small-batch, high-precision and flexible production.

Bin Zhou, Tiesheng Liu, Zongwang Cai, Shufeng Zhang. Research on Driving and Controlling Technology of High Speed and High Precision Based Flexible Material Cutting System. International Journal of Engineering Exploration and Construction (2025), Vol. 4, Issue 1: 1-9. https://doi.org/10.38007/IJEEC.2025.040101.

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