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基于机器学习与非支配排序遗传算法-II的超声滚压复合加工多目标工艺参数优化

Multi-Objective Process Parameter Optimization of Ultrasonic Rolling Combining Machine Learning and Non-Dominated Sorting Genetic Algorithm-II.

作者信息

Chen Junying, Yang Tao, Chen Shiqi, Jiang Qingshan, Li Yi, Chen Xiuyu, Xu Zhilong

机构信息

College of Marine Equipment and Mechanical Engineering, Jimei University, Xiamen 361000, China.

出版信息

Materials (Basel). 2024 Jun 3;17(11):2723. doi: 10.3390/ma17112723.

DOI:10.3390/ma17112723
PMID:38893987
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11173437/
Abstract

Ultrasonic rolling is an effective technique for enhancing surface integrity, and surface integrity is closely related to fatigue performance. The process parameters of ultrasonic rolling critically affect the improvement of surface integrity. This study proposes an optimization method for process parameters by combining machine learning (ML) with the NSGA-II. Five ML models were trained to establish relationships between process parameters and surface residual stress, hardness, and surface roughness by incorporating feature augmentation and physical information. The best-performing model was selected and integrated with NSGA-II for multi-objective optimization. Ultrasonic rolling tests based on a uniform design were performed, and a dataset was established. The objective was to maximize surface residual stress and hardness while minimizing surface roughness. For test specimens with an initial surface roughness of 0.54 µm, the optimized process parameters were a static pressure of 900 N, a spindle speed of 75 rpm, a feed rate of 0.19 mm/r, and rolling once. Using optimized parameters, the surface residual stress reached -920.60 MPa, surface hardness achieved 958.23 HV, surface roughness reduced to 0.32 µm, and contact fatigue life extended to 3.02 × 10 cycles, representing a 52.5% improvement compared to untreated specimens and an even more significant improvement over without parameter optimization.

摘要

超声滚压是一种提高表面完整性的有效技术,而表面完整性与疲劳性能密切相关。超声滚压的工艺参数对表面完整性的改善起着关键作用。本研究提出了一种将机器学习(ML)与NSGA-II相结合的工艺参数优化方法。通过结合特征增强和物理信息,训练了五个ML模型,以建立工艺参数与表面残余应力、硬度和表面粗糙度之间的关系。选择性能最佳的模型并与NSGA-II集成进行多目标优化。基于均匀设计进行了超声滚压试验,并建立了数据集。目标是在最小化表面粗糙度的同时最大化表面残余应力和硬度。对于初始表面粗糙度为0.54 µm的试样,优化后的工艺参数为静压900 N、主轴转速75 rpm、进给速度0.19 mm/r,滚压一次。使用优化后的参数,表面残余应力达到-920.60 MPa,表面硬度达到958.23 HV,表面粗糙度降至0.32 µm,接触疲劳寿命延长至3.02×10次循环,与未处理试样相比提高了52.5%,与未进行参数优化相比有更显著的提高。

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