基于Swin-IMSA的外圆磨削过程中粗糙度在机预测方法

doi:10.3901/JME.2025.23.373

机械工程学报 ›› 2025, Vol. 61 ›› Issue (23): 373-380.doi: 10.3901/JME.2025.23.373

• 制造工艺与装备 • 上一篇

扫码分享

基于Swin-IMSA的外圆磨削过程中粗糙度在机预测方法

赵阳¹, 王中任¹, 史铁林², 谭孟¹, 张文¹, 李文喜³

1. 湖北文理学院机械工程学院襄阳 441053;
2. 华中科技大学机械科学与工程学院武汉 430074;
3. 襄阳博亚精工装备股份有限公司襄阳 441004

收稿日期:2024-12-15 修回日期:2025-07-04 发布日期:2026-01-22
作者简介:赵阳,男,2000 年出生。主要研究方向为机器视觉、表面缺陷检测。E-mail:zhaoyang@hbuas.edu.cn
王中任(通信作者),男,1974 年出生,博士,教授,博士研究生导师。主要研究方向为智能制造、智能焊接、机器人与机器视觉。E-mail:wzrvision@hbuas.edu.cn
基金资助:
湖北省自然科学基金联合基金(2022CFD080);湖北文理学院研究生创新计划(YCX202411)资助项目

Surface Roughness Prediction Methods for Precision Mill Roll Cylindrical Grinding

ZHAO Yang¹, WANG Zhongren¹, SHI Teilin², TAN Meng¹, ZHANG Wen¹, LI Wenxi³

1. School of Mechanical Engineering, Hubei University of Arts and Sciences, Xiangyang 441053;
2. School of Mechanical Science and Engineering, Huazhong University of Science and Technology, Wuhan 430074;
3. Xiangyang Boya Precision Industrial Equipments Co., Ltd., Xiangyang 441004

Received:2024-12-15 Revised:2025-07-04 Published:2026-01-22

摘要/Abstract

摘要： 传统的机器学习方法进行粗糙度预测时需要采集不同模态的机床信号，且针对不同磨削阶段需要设计不同的预测模型，过程繁琐且预测精度不高。因此，针对外圆磨床磨削过程提出一种基于Swin-IMSA的表面粗糙度预测方法。首先建立磨床在机视觉采集系统获取磨削表面显微图像，通过Fast GLCM计算灰度共生矩阵得到纹理特征图；其次根据粗糙度等级将特征图分为不同的类别，并经过数据增强以提升模型的泛化能力；最后使用改进的Swin-IMSA粗糙度预测网络从纹理特征中提取特征用于训练模型。实验结果表明，该模型在Ra值为0.1 μm至1.2 μm的范围内，在测试集上的预测准确率为97.56%，在磨削辊轴样件预测中的平均误差为0.035 μm，证明了该方法的有效性。

关键词: 磨削表面, 粗糙度, 精密辊轴, 深度学习, 纹理特征

Abstract: Traditional machine learning methods for roughness prediction require the collection of various modalities of machine tool signals, and different predictive models must be designed for different grinding stages, making the process cumbersome and resulting in low prediction accuracy. Therefore, a surface roughness prediction method based on Swin-IMSA is proposed for the grinding process of external cylindrical grinding machines. Firstly, a machine vision system is established to capture microscopic images of the ground surface, from which texture feature maps are derived using fast gray-level co-occurrence matrix (GLCM) calculations. Secondly, these feature maps are classified into distinct categories according to roughness levels and subjected to data augmentation techniques to enhance the model's generalization capabilities. Finally, an improved Swin-IMSA roughness prediction network extracts relevant features from the texture characteristics for model training. Experimental results indicate that this model achieves a prediction accuracy of 97.56% on the test set within a Ra value range of 0.1 μm to 1.2 μm, with an average prediction error of 0.035 μm in assessing ground roll samples, thereby validating the efficacy of this approach.

Key words: grinding surface, roughness, precision roller, deep learning, textural features

中图分类号:

TG502
TP319

赵阳, 王中任, 史铁林, 谭孟, 张文, 李文喜. 基于Swin-IMSA的外圆磨削过程中粗糙度在机预测方法[J]. 机械工程学报, 2025, 61(23): 373-380.

ZHAO Yang, WANG Zhongren, SHI Teilin, TAN Meng, ZHANG Wen, LI Wenxi. Surface Roughness Prediction Methods for Precision Mill Roll Cylindrical Grinding[J]. Journal of Mechanical Engineering, 2025, 61(23): 373-380.

参考文献

[1] 朱挺,陈兆祥,周笛,等. 基于Bayesian-LSTM神经网络的热轧轧辊剩余寿命预测及不确定性评估[J]. 机械工程学报,2024,60(11):181-190. ZHU Ting, CHEN Zhaoxiang, ZHOU Di, et al. Bayesian-LSTM neural network-based remaining useful life prediction and uncertainty estimation of rollers in a hot strip mill[J]. Journal of Mechanical Engineering, 2024,60(11):181-190.
[2] 姜春,汪圣涵,唐健,等. 基于双层排线探头的轧辊表面微裂纹检测方法[J]. 仪器仪表学报,2023,44(6):188-196. JIANG Chun, WANG Shenghan, TANG Jian,et al. Micro-crack detection method on roll surface based on double-layer parallel cables probe[J]. Chinese Journal of Scientific Instrument,2023,44(6):188-196.
[3] 史丽晨,杨培东,王海涛. 基于小波包变换-残差网络的表面粗糙度预测[J]. 计算机集成制造系统,2023, 29(10):3249. SHI Lichen,YANG Peidong,WANG Haitao. Prediction of surface roughness based on wavelet packet transform-residual network[J]. Computer Integrated Manufacturing System,2023,29(10):3249.
[4] 杨赫然,张培杰,孙兴伟,等. 利用改进卷积神经网络的螺杆砂带磨削表面粗糙度预测[J]. 中国机械工程, 2025,36(2):325-332. YANG Heran,ZHANG Peijie,SUN Xingwei,et al. Surface roughness prediction for screw belt grinding based on improved convolutional neural network[J]. China Mechanical Engineering,2025,36(2):325-332.
[5] 袁尚勇,陈根余,戴隆州,等. 电火花机械磨削修整粗粒度成形砂轮试验研究[J].中国机械工程,2023,34(10):1164-1171. YUAN Shangyong, CHEN Genyu, DAI Longzhou, et al. Experimental research of coarse-grained forming grinding wheel dressed by EDDG[J]. China Mechanical Engineering,2023,34(10):1164-1171.
[6] YANG H, ZHENG H, ZHANG T. A review of artificial intelligent methods for machined surface roughness prediction[J]. Tribology International,2024,199:109935.
[7] LI S, LI S, LIU Z, et al. Roughness prediction model of milling noise-vibration-surface texture multi-dimensional feature fusion for N6 nickel metal[J]. Journal of Manufacturing Processes,2022,79:166-176.
[8] ESER A, AŞKAR AYYILDIZ E, AYYILDIZ M, et al. Artificial intelligence - based surface roughness estimation modelling for milling of AA6061 alloy[J]. Advances in Materials Science and Engineering,2021, 2021(1):5576600.
[9] RIFAI A P, AOYAMA H, THO N H, et al. Evaluation of turned and milled surfaces roughness using convolutional neural network[J]. Measurement,2020,161:107860.
[10] 王帅,易怀安,陈永伦,等. 基于深度神经网络的粗糙度分类检测[J]. 机床与液压,2023,51(6):7-11. WANG Shuai, YI Huaian, CHEN Yonglun, et al. Classification detection of roughness based on deep neural network[J]. Machine Tool & Hydraulics,2023,51(6):7-11.
[11] HUANG J, YI H, SHU A, et al. Visual measurement of grinding surface roughness based on feature fusion[J]. Measurement Science and Technology,2023,34(10):105019.
[12] 严永奇,李政民卿,于晓峰,等.小样本磨削表面粗糙度测量方法研究[J]. 机床与液压,2023,51(19):1-8. YAN Yongqi,LI Zhengminqing,YU Xiaofeng,et al. Research on measurement method of grinding surface roughness for small samples[J]. Machine Tool & Hydraulics,2023,51(19):1-8.
[13] 路恩会,刘坚,王卫芳,等. 粗糙度关联的图像特征指标性能评价方法研究[J]. 仪器仪表学报,2017,38(8):2022-2029. LU Enhui, LIU Jian, WANG Weifang, et al. Study on the performance assessment method of image indices associated with roughness[J]. Chinese Journal of Scientific Instrument, 2017,38(8):2022-2029.
[14] 易怀安,赵欣佳,唐乐,等. 基于彩色图像奇异值熵指标的磨削表面粗糙度视觉测量方法[J]. 中国机械工程, 2021,32(13):1577-1583. YI Huaian,ZHAO Xinjia,TANG Le,et al. Vision measurement method for ground surface roughness based on color image singular value entropy[J]. China Mechanical Engineering,2021,32(13):1577-1583.
[15] GADELMAWLA E S. A vision system for surface roughness characterization using the gray level cooccurrence matrix[J].NDT & E International,2004, 37(7):577-588.
[16] CHEN F, WEI J, XUE B, et al. Feature fusion and kernel selective in Inception-v4 network[J]. Applied Soft Computing,2022,119:108582.
[17] TERVEN J, CÓRDOVA-ESPARZA D M, ROMERO-GONZÁLEZ J A. A comprehensive review of yolo architectures in computer vision:From YOLOv1 to YOLOv8 and YOLO-NAS[J]. Machine learning and knowledge extraction, 2023,5(4):1680-1716.
[18] KARADAL C H,KAYA M C,TUNCER T,et al. Automated classification of remote sensing images using multileveled MobileNetV2 and DWT techniques[J]. Expert Systems with Applications, 2021,185:115659.
[19] WU Z,SHEN C,VAN DEN HENGEL A. Wider or deeper:Revisiting the resnet model for visual recognition[J]. Pattern recognition,2019,90:119-133.

基于Swin-IMSA的外圆磨削过程中粗糙度在机预测方法

Surface Roughness Prediction Methods for Precision Mill Roll Cylindrical Grinding

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	王祺, 叶仁传, 马国杰, 马佩珏, 范杰, 杨文龙. 钢材表面缺陷轻量化识别算法研究[J]. 机械工程学报, 2025, 61(8): 18-31.
[2]	秦飞红, 袁懋诞, 祝端阳, 刘晓睿, 李明, 纪轩荣. 基于多层特征融合目标检测网络的超声全聚焦钢板焊缝缺陷自动检测研究[J]. 机械工程学报, 2025, 61(4): 55-66.
[3]	陈其怀, 林添良, 马荣华, 温建和, 缪骋, 任好玲. 基于多模态的履带式挖掘机自动驾驶决策网络[J]. 机械工程学报, 2025, 61(4): 380-388.
[4]	黄思翰, 陈建鹏, 徐哲, 阎艳, 王国新. 基于大语言模型和机器视觉的智能制造系统人机自主协同作业方法[J]. 机械工程学报, 2025, 61(3): 130-141.
[5]	刘翰儒, 陈桂映, 许泽林, 彭世通, 郭嘉楠, 刘伟嵬, 王奉涛. 基于SERepVGG-A2的轻量化卷积神经网络在熔池状态识别中的应用[J]. 机械工程学报, 2025, 61(3): 440-448.
[6]	战庆亮, 刘鑫, 白春锦, 葛耀君. 三维高分辨率流场重构的深度学习方法[J]. 机械工程学报, 2025, 61(16): 338-346.
[7]	彭飞, 张彦彬, 崔歆, 刘明政, 梁晓亮, 徐培明, 周宗明, 李长河. 基于磨削机理的表面形貌和粗糙度预测模型研究进展[J]. 机械工程学报, 2025, 61(13): 327-359.
[8]	郭江, 杨哲, 徐海俊, 李琳光, 王东周, 张鹏飞. 铌酸锂原子级抛光缺陷形貌演化机理研究[J]. 机械工程学报, 2025, 61(13): 474-482.
[9]	肖宏, 王阳, 刘秀波, 崔旭浩, 张智海, 金锋. 钢轨波磨检测原理、方法及装置研究进展[J]. 机械工程学报, 2025, 61(10): 191-214.
[10]	余智祺, 徐洋, 王元飞, 盛晓伟. 基于多尺度标准化流模型的布匹缺陷检测[J]. 机械工程学报, 2025, 61(10): 241-249.
[11]	李路兴, 魏超, 胡乐云, 随淑鑫, 徐扬, 钱歆昊. 多模态多序列高效越野可行驶区域检测[J]. 机械工程学报, 2025, 61(10): 276-287.
[12]	隗雨欣, 宋洪侠, 张园, 薛冠鸣, 康仁科, 鲍岩, 董志刚. 超声辅助钻削1J22软磁合金表面完整性研究[J]. 机械工程学报, 2025, 61(1): 345-359.
[13]	刘鑫, 张俊, 徐斌斌, 刘弘光, 赵万华. 激光辅助铣削过程的预热温度场调控方法研究[J]. 机械工程学报, 2024, 60(9): 218-228.
[14]	朱少禹, 张向军, 孙军, 王大刚. 粗糙表面轴承微极流体润滑的平均流量模型[J]. 机械工程学报, 2024, 60(7): 203-211.
[15]	方从富, 李弘扬, 沈剑云, 吴贤. 融合磨粒特征和工艺参数的粗糙度智能预测研究[J]. 机械工程学报, 2024, 60(7): 224-235.