Optimization of an aerostructural machining process using physics-guided Bayesian stability modelling

Aaron Cornelius; Jaydeep Karandikar; Judy Burns; Robert Burns; David Burns; Julia Daugherty; Clint Farrow; Matthew Yurescko; Kevin Kim; Jackob Mekelburg; Richard Grant; Thomas Delio; Clay Dosmann; Chris Kantner; Zhigang Wang; Tony Schmitz

doi:10.1016/j.procir.2025.02.109

Optimization of an aerostructural machining process using physics-guided Bayesian stability modelling

Aaron Cornelius, Jaydeep Karandikar, Judy Burns, Robert Burns, David Burns, Julia Daugherty, Clint Farrow, Matthew Yurescko, Kevin Kim, Jackob Mekelburg, Richard Grant, Thomas Delio, Clay Dosmann, Chris Kantner, Zhigang Wang, Tony Schmitz

Advanced Machining and Machine Tools Res

Research output: Contribution to journal › Conference article › peer-review

Abstract

Existing algorithms for predicting milling chatter have not been widely adopted in industry since they require specialized instruments to measure the stability inputs. This study describes how the machining process for a meter-scale aluminum aerostructure was optimized using a physics-guided Bayesian stability model. The study was performed in collaboration with an industrial partner on production machines to evaluate the practicality of the proposed method under real-world conditions. For each cutting tool, the Bayesian approach automatically selected a small number of cutting tests, which were monitored using a microphone to observe the chatter frequency. The algorithm learned the system dynamics, cutting forces, and stability map from these test results. A novel algorithm for predicting tool bending stress was incorporated into the test selection algorithm to avoid tool breakage. On average, each set of optimized cutting parameters required less than six tests to identify and were 97% more productive than baseline parameters from the cutting tool manufacturer. The machining program was then further optimized using commercial feedrate scheduling software to remove cutting force spikes and reduce air cutting time. Five components were machined using the optimized process. These results demonstrate the potential for physics-guided Bayesian models to improve productivity in industrial settings.

Original language	English
Pages (from-to)	638-643
Number of pages	6
Journal	Procedia CIRP
Volume	133
DOIs	https://doi.org/10.1016/j.procir.2025.02.109
State	Published - 2025
Event	20th CIRP Conference on Modeling of Machining Operations in Mons, CIRP CMMO 2025 - Mons, Belgium Duration: May 22 2025 → May 23 2025

Funding

This study was funded by the Department of Energy under grant DE-EE0009400. The funder played no role in study design, data collection, analysis and interpretation of data, or the writing of this manuscript.

Keywords

Machine tool
Modelling
Monitoring
Optimization

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10.1016/j.procir.2025.02.109

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Cornelius, A., Karandikar, J., Burns, J., Burns, R., Burns, D., Daugherty, J., Farrow, C., Yurescko, M., Kim, K., Mekelburg, J., Grant, R., Delio, T., Dosmann, C., Kantner, C., Wang, Z., & Schmitz, T. (2025). Optimization of an aerostructural machining process using physics-guided Bayesian stability modelling. Procedia CIRP, 133, 638-643. https://doi.org/10.1016/j.procir.2025.02.109

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title = "Optimization of an aerostructural machining process using physics-guided Bayesian stability modelling",

abstract = "Existing algorithms for predicting milling chatter have not been widely adopted in industry since they require specialized instruments to measure the stability inputs. This study describes how the machining process for a meter-scale aluminum aerostructure was optimized using a physics-guided Bayesian stability model. The study was performed in collaboration with an industrial partner on production machines to evaluate the practicality of the proposed method under real-world conditions. For each cutting tool, the Bayesian approach automatically selected a small number of cutting tests, which were monitored using a microphone to observe the chatter frequency. The algorithm learned the system dynamics, cutting forces, and stability map from these test results. A novel algorithm for predicting tool bending stress was incorporated into the test selection algorithm to avoid tool breakage. On average, each set of optimized cutting parameters required less than six tests to identify and were 97% more productive than baseline parameters from the cutting tool manufacturer. The machining program was then further optimized using commercial feedrate scheduling software to remove cutting force spikes and reduce air cutting time. Five components were machined using the optimized process. These results demonstrate the potential for physics-guided Bayesian models to improve productivity in industrial settings.",

keywords = "Machine tool, Modelling, Monitoring, Optimization",

author = "Aaron Cornelius and Jaydeep Karandikar and Judy Burns and Robert Burns and David Burns and Julia Daugherty and Clint Farrow and Matthew Yurescko and Kevin Kim and Jackob Mekelburg and Richard Grant and Thomas Delio and Clay Dosmann and Chris Kantner and Zhigang Wang and Tony Schmitz",

note = "Publisher Copyright: {\textcopyright} 2025 The Authors.; 20th CIRP Conference on Modeling of Machining Operations in Mons, CIRP CMMO 2025 ; Conference date: 22-05-2025 Through 23-05-2025",

year = "2025",

doi = "10.1016/j.procir.2025.02.109",

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pages = "638--643",

journal = "Procedia CIRP",

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Cornelius, A, Karandikar, J, Burns, J, Burns, R, Burns, D, Daugherty, J, Farrow, C, Yurescko, M, Kim, K, Mekelburg, J, Grant, R, Delio, T, Dosmann, C, Kantner, C, Wang, Z & Schmitz, T 2025, 'Optimization of an aerostructural machining process using physics-guided Bayesian stability modelling', Procedia CIRP, vol. 133, pp. 638-643. https://doi.org/10.1016/j.procir.2025.02.109

TY - JOUR

T1 - Optimization of an aerostructural machining process using physics-guided Bayesian stability modelling

AU - Cornelius, Aaron

AU - Karandikar, Jaydeep

AU - Burns, Judy

AU - Burns, Robert

AU - Burns, David

AU - Daugherty, Julia

AU - Farrow, Clint

AU - Yurescko, Matthew

AU - Kim, Kevin

AU - Mekelburg, Jackob

AU - Grant, Richard

AU - Delio, Thomas

AU - Dosmann, Clay

AU - Kantner, Chris

AU - Wang, Zhigang

AU - Schmitz, Tony

PY - 2025

Y1 - 2025

N2 - Existing algorithms for predicting milling chatter have not been widely adopted in industry since they require specialized instruments to measure the stability inputs. This study describes how the machining process for a meter-scale aluminum aerostructure was optimized using a physics-guided Bayesian stability model. The study was performed in collaboration with an industrial partner on production machines to evaluate the practicality of the proposed method under real-world conditions. For each cutting tool, the Bayesian approach automatically selected a small number of cutting tests, which were monitored using a microphone to observe the chatter frequency. The algorithm learned the system dynamics, cutting forces, and stability map from these test results. A novel algorithm for predicting tool bending stress was incorporated into the test selection algorithm to avoid tool breakage. On average, each set of optimized cutting parameters required less than six tests to identify and were 97% more productive than baseline parameters from the cutting tool manufacturer. The machining program was then further optimized using commercial feedrate scheduling software to remove cutting force spikes and reduce air cutting time. Five components were machined using the optimized process. These results demonstrate the potential for physics-guided Bayesian models to improve productivity in industrial settings.

AB - Existing algorithms for predicting milling chatter have not been widely adopted in industry since they require specialized instruments to measure the stability inputs. This study describes how the machining process for a meter-scale aluminum aerostructure was optimized using a physics-guided Bayesian stability model. The study was performed in collaboration with an industrial partner on production machines to evaluate the practicality of the proposed method under real-world conditions. For each cutting tool, the Bayesian approach automatically selected a small number of cutting tests, which were monitored using a microphone to observe the chatter frequency. The algorithm learned the system dynamics, cutting forces, and stability map from these test results. A novel algorithm for predicting tool bending stress was incorporated into the test selection algorithm to avoid tool breakage. On average, each set of optimized cutting parameters required less than six tests to identify and were 97% more productive than baseline parameters from the cutting tool manufacturer. The machining program was then further optimized using commercial feedrate scheduling software to remove cutting force spikes and reduce air cutting time. Five components were machined using the optimized process. These results demonstrate the potential for physics-guided Bayesian models to improve productivity in industrial settings.

KW - Machine tool

KW - Modelling

KW - Monitoring

KW - Optimization

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U2 - 10.1016/j.procir.2025.02.109

DO - 10.1016/j.procir.2025.02.109

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SN - 2212-8271

VL - 133

SP - 638

EP - 643

JO - Procedia CIRP

JF - Procedia CIRP

T2 - 20th CIRP Conference on Modeling of Machining Operations in Mons, CIRP CMMO 2025

Y2 - 22 May 2025 through 23 May 2025

ER -

Optimization of an aerostructural machining process using physics-guided Bayesian stability modelling

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