Research on Grinding Burn Identification of Nickel-based Superalloy Blades Based on Deep Learning

被引：0

作者：

Liu C. ^{[1
]}

Wang H. ^{[3
]}

Chen L. ^{[2
]}

Liang X. ^{[2
]}

Jin T. ^{[3
]}

机构：

[1] AECC South Industry Co. ，Ltd, Zhuzhou

[2] Hunan South General Aviation Engine Co，Ltd, Zhuzhou

[3] College of Mechanical and Vehicle Engineering, Hunan University, Changsha

来源：

Hunan Daxue Xuebao/Journal of Hunan University Natural Sciences | 2024年 / 51卷 / 04期

关键词：

burn; deep learning; grinding; image identification; nickel alloy;

D O I：

10.16339/j.cnki.hdxbzkb.2024175

中图分类号：

学科分类号：

摘要：

A deep learning-based recognition and classification model named Tenon Grinding Burn Net (TenonGBNet)is proposed to address the issues of misdiagnosis and missed detection in visual inspection of grinding burns on nickel-based Superalloy blades. The K4125 nickel-based superalloy blades are chosen as the target,and through grinding burn tests and specimen organization inspection,a set of classification standards and corresponding image collection for different degrees of blade tenon grinding burns are obtained. Then,ODConv dynamic convolution is employed to fuse Inception V2 modules and the Coordinate Attention mechanism to enhance the model's feature extraction capability while ensuring the model is lightweight. Finally,a fully connected layer is employed for identification and classification. Experimental results indicate that,compared with four other classical classification models,TenonGBNet achieves an average classification accuracy of 96.50% while maintaining a minor model complexity and parameter count. Additionally,the classification accuracy for each burn level exceeds 95%. © 2024 Hunan University. All rights reserved.

引用

页码：99 / 104

页数：5

共 19 条

[1] JIN T, HE X, WANG Q R, Et al., Development of high performance grinding processes to challenge physical limitations: application prospects in aeronautical manufacture engineering, Aeronautical Manufacturing Technology, 65, 9, pp. 20-33, (2022)
[2] HE B F, WEI C E, SHI Z Y., Researching status and developing direction of gear grinding burn detection methods, Chinese Journal of Scientific Instrument, 38, 8, pp. 1889-1900, (2017)
[3] CHEN R Y, ZUO D W., Feasibility of evaluation for machining burn on work surface based on CCD image, Journal of Soochow University(Engineering Science Edition), 25, 4, pp. 48-52, (2005)
[4] WANG L, TIAN X L, LIU Q, Et al., Grinding burn evaluation for 20CrMnTi steel based on binary images and neural network[J], The International Journal of Advanced Manufacturing Technology, 93, 9, pp. 4033-4042, (2017)
[5] HUBNER H B, DUARTE M A V, DA SILVA R B., Automatic grinding burn recognition based on time-frequency analysis and convolutional neural networks, The International Journal of Advanced Manufacturing Technology, 110, 7, pp. 1833-1849, (2020)
[6] SUN W Z, CHENG L S, ZHOU J., Research on grinding surface burn degree identification based on support vector machine, Computer & Digital Engineering, 49, 8, pp. 1682-1686, (2021)
[7] ZHOU G H, LU W Z, ZHANG Q Z, Et al., Image recongnition with respect to grinding burn of TC4 titanium alloy based on transfer learning, Machine Building & Automation, 51, 2, pp. 111-115, (2022)
[8] ZHANG Z H, LIU Y J, WANG Z D, Et al., Influence behavior and mechanism of γ-́or γ'' -precipitated phase types on damage resistance of heterogeneous interface in nickel-based superalloys[J], Journal of Alloys and Compounds, 924, (2022)
[9] CHEN Y L, LI B, LIANG H, Et al., Research on sonar image few-shot classification based on deep learning, Journal of Northwestern Polytechnical University, 40, 4, pp. 739-745, (2022)
[10] LI C, ZHOU A, YAO A., Omni-dimensional dynamic convolution

← 1 2 →