TY - JOUR
T1 - An Advanced Approach for Predicting Workpiece Surface Roughness Using Finite Element Method and Image Processing Techniques
AU - Chen, Taoming
AU - Li, Chun
AU - Zou, Zhexiang
AU - Han, Qi
AU - Li, Bing
AU - Gu, Fengshou
AU - Ball, Andrew D.
N1 - Funding Information:
This research was supported in part by the 2023 Guangdong Province Science and Technology Innovation Strategy (Climbing Plan Project) Special Fund (No. pdjh2023a0609), in part by the Special Projects in Key Areas in Fundamental and Foundational Applied Research of Guangdong Provincial Department (No. 2021ZDZX1072), and in part by the Guangdong Basic and Applied Basic Research Fund Offshore Wind Power Scheme\u2014General Project, under Grant 2022A1515240042.
Publisher Copyright:
© 2024 by the authors.
PY - 2024/11/20
Y1 - 2024/11/20
N2 - Workpiece surface quality is a critical metric for assessing machining quality. However, due to the complex coupling characteristics of cutting factors, accurately predicting surface roughness remains challenging. Typically, roughness is measured post-machining using specialized instruments, which delays feedback and hampers timely problem detection, ultimately resulting in cutting resource wastage. To address this issue, this paper introduces a predictive model for workpiece surface roughness based on the finite element (FE) method and advanced image processing techniques. Initially, an orthogonal turning experiment was designed, and an FE cutting model was constructed to assess the distribution of cutting forces and temperatures under varying cutting parameters. Image processing methods (including mesh calibration, edge extraction, and contour fitting) were then applied to extract surface characteristics from the FE simulation outputs, yielding preliminary estimates of surface roughness. By employing range and regression analyses methods, this study quantitatively evaluates the interdependencies among cutting parameters, forces, temperatures, and roughness, subsequently formulating a multivariate regression model to predict surface roughness. Finally, a turning experiment under actual working conditions was conducted, confirming the model’s capacity to predict the (Formula presented.) trend with an accuracy of 85.07%. Thus, the proposed model provides a precise predictive tool for surface roughness, offering valuable guidance for optimizing machining parameters and supporting proactive control in the turning process, ultimately enhancing machining efficiency and quality.
AB - Workpiece surface quality is a critical metric for assessing machining quality. However, due to the complex coupling characteristics of cutting factors, accurately predicting surface roughness remains challenging. Typically, roughness is measured post-machining using specialized instruments, which delays feedback and hampers timely problem detection, ultimately resulting in cutting resource wastage. To address this issue, this paper introduces a predictive model for workpiece surface roughness based on the finite element (FE) method and advanced image processing techniques. Initially, an orthogonal turning experiment was designed, and an FE cutting model was constructed to assess the distribution of cutting forces and temperatures under varying cutting parameters. Image processing methods (including mesh calibration, edge extraction, and contour fitting) were then applied to extract surface characteristics from the FE simulation outputs, yielding preliminary estimates of surface roughness. By employing range and regression analyses methods, this study quantitatively evaluates the interdependencies among cutting parameters, forces, temperatures, and roughness, subsequently formulating a multivariate regression model to predict surface roughness. Finally, a turning experiment under actual working conditions was conducted, confirming the model’s capacity to predict the (Formula presented.) trend with an accuracy of 85.07%. Thus, the proposed model provides a precise predictive tool for surface roughness, offering valuable guidance for optimizing machining parameters and supporting proactive control in the turning process, ultimately enhancing machining efficiency and quality.
KW - finite element method (FEM)
KW - image processing
KW - multivariate linear regression analysis (MLRA)
KW - surface roughness
KW - turning process
UR - http://www.scopus.com/inward/record.url?scp=85210157532&partnerID=8YFLogxK
U2 - 10.3390/machines12110827
DO - 10.3390/machines12110827
M3 - Article
AN - SCOPUS:85210157532
VL - 12
JO - Machines
JF - Machines
SN - 2075-1702
IS - 11
M1 - 827
ER -