Applied Mathematics and Mechanics >
An electromagnetic semi-active dynamic vibration absorber for thin-walled workpiece vibration suppression in mirror milling
Received date: 2024-04-03
Online published: 2024-07-31
Supported by
the National Natural Science Foundation of China(12172248);the National Natural Science Foundation of China(12021002);the National Natural Science Foundation of China(12302022);the National Natural Science Foundation of China(12132010);the Tianjin Research Program of Application Foundation and Advanced Technology of China(22JCQNJC00780);IoT Standards and Application Key Laboratory of the Ministry of Industry and Information Technology of China(202306);Project supported by the National Natural Science Foundation of China (Nos. 12172248, 12021002, 12302022, and 12132010), the Tianjin Research Program of Application Foundation and Advanced Technology of China (No. 22JCQNJC00780), and IoT Standards and Application Key Laboratory of the Ministry of Industry and Information Technology of China (No. 202306)
Copyright
As critical components of aircraft skins and rocket fuel storage tank shells, large thin-walled workpieces are susceptible to vibration and deformation during machining due to their weak local stiffness. To address these challenges, we propose a novel tunable electromagnetic semi-active dynamic vibration absorber (ESADVA), which integrates with a magnetic suction follower to form a followed ESADVA (follow-ESADVA) for mirror milling. This system combines a tunable magnet oscillator with a follower, enabling real-time vibration absorption and condition feedback throughout the milling process. Additionally, the device supports self-sensing and frequency adjustment by providing feedback to a linear actuator, which alters the distance between magnets. This resolves the traditional issue of being unable to directly monitor vibration at the machining point due to space constraints and tool interference. The frequency shift characteristics and vibration absorption performance are comprehensively investigated. Theoretical and experimental results demonstrate that the prototyped follow-ESADVA achieves frequency synchronization with the milling tool, resulting in a vibration suppression rate of approximately 47.57%. Moreover, the roughness of the machined surface decreases by 18.95%, significantly enhancing the surface quality. The results of this work pave the way for higher-quality machined surfaces and a more stable mirror milling process.
Jianghua KONG, Bei DING, Wei WANG, Zhixia WANG, Juliang XIAO, Hongyun QIU . An electromagnetic semi-active dynamic vibration absorber for thin-walled workpiece vibration suppression in mirror milling[J]. Applied Mathematics and Mechanics, 2024 , 45(8) : 1315 -1334 . DOI: 10.1007/s10483-024-3132-7
| 1 | DEL SOL, I., RIVERO, A., DE LACALLE, L. N. L., and GAMEZ, A. J. Thin-wall machining of light alloys: a review of models and industrial approaches. Materials, 12 (12), 2012 (2019) |
| 2 | DONG, H. Q., JI, Y. L., WANG, X. Z., and BI, Q. Z. Stability analysis of thin-walled parts end milling considering cutting depth regeneration effect. International Journal of Advanced Manufacturing Technology, 113 (11-12), 3319- 3328 (2021) |
| 3 | DU, J. A., and LONG, X. H. Chatter suppression for milling of thin-walled workpieces based on active modal control. Journal of Manufacturing Processes, 84, 1042- 1053 (2022) |
| 4 | WAN, M., DANG, X. B., ZHANG, W. H., and YANG, Y. Chatter suppression in the milling process of the weakly-rigid workpiece through a moving fixture. Journal of Materials Processing Technology, 299, 117293 (2022) |
| 5 | MAHMUD, A., MAYER, J. R. R., and BARON, L. Determining the minimum clamping force by cutting force simulation in aerospace fuselage pocket machining. International Journal of Advanced Manufacturing Technology, 80 (9-12), 1751- 1758 (2015) |
| 6 | BAO, Y., WANG, B., HE, Z. X., KANG, R. K., and GUO, J. Recent progress in flexible supporting technology for aerospace thin-walled parts: a review. Chinese Journal of Aeronautics, 35 (3), 10- 26 (2022) |
| 7 | WANG, S. Q., HE, C. L., LI, J. G., and WANG, J. Vibration-free surface finish in the milling of a thin-walled cavity part using a corn starch suspension. Journal of Materials Processing Technology, 290, 116980 (2021) |
| 8 | SHENG, X. J., and ZHANG, X. Fuzzy adaptive hybrid impedance control for mirror milling system. Mechatronics, 53, 20- 27 (2018) |
| 9 | ZHANG, S., BI, Q., JI, Y., and WANG, Y. Real-time thickness compensation in mirror milling based on modified Smith predictor and disturbance observer. International Journal of Machine Tools & Manufacture, 144, 103427 (2019) |
| 10 | TIAN, Y., XIAO, J. L., LIU, S. J., MA, S. J., LIU, H. T., and HUANG, T. Vibration and deformation suppression in mirror milling of thin-walled workpiece through a magnetic follow-up support fixture. Journal of Manufacturing Processes, 99, 168- 183 (2023) |
| 11 | LIU, S. J., XIAO, J. L., TIAN, Y., MA, S. J., LIU, H. T., and HUANG, T. Chatter-free and high-quality end milling for thin-walled workpieces through a follow-up support technology. Journal of Materials Processing Technology, 312, 117857 (2023) |
| 12 | DENG, H. X., and GONG, X. L. Adaptive tuned vibration absorber based on magnetorheological elastomer. Journal of Intelligent Material Systems and Structures, 18 (12), 1205- 1210 (2007) |
| 13 | SUN, S. S., CHEN, Y., YANG, J., TIAN, T. F., DENG, H. X., LI, W. H., DU, H., and ALICI, G. The development of an adaptive tuned magnetorheological elastomer absorber working in squeeze mode. Smart Materials and Structures, 23 (7), 075009 (2014) |
| 14 | YUAN, L., SUN, S., PAN, Z., DING, D., GIENKE, O., and LI, W. Mode coupling chatter suppression for robotic machining using semi-active magnetorheological elastomers absorber. Mechanical Systems and Signal Processing, 117, 221- 237 (2019) |
| 15 | KWAK, M. K., YANG, D. H., and SHIN, J. H. Active vibration control of structures using a semi-active dynamic absorber. Noise Control Engineering Journal, 63 (3), 287- 299 (2015) |
| 16 | MCDAID, A. J., and MACE, B. R. A self-tuning electromagnetic vibration absorber with adaptive shunt electronics. Smart Materials and Structures, 22 (10), 105013 (2013) |
| 17 | CHANG, Y., ZHOU, J., WANG, K., and XU, D. Theoretical and experimental investigations on semi-active quasi-zero-stiffness dynamic vibration absorber. International Journal of Mechanical Sciences, 214, 106892 (2022) |
| 18 | MENG, K., GU, Y., LIU, Y., and MA, T. Transmissibility characteristics of semi-active vibration isolator based on controllable electro-magnetic negative stiffness. Journal of Vibration and Shock, 41 (7), 228- 234 (2022) |
| 19 | WANG, Q., ZHOU, J., WANG, K., LIN, Q., XU, D., and WEN, G. A compact quasi-zero-stiffness device for vibration suppression and energy harvesting. International Journal of Mechanical Sciences, 250, 108284 (2023) |
| 20 | WANG, Q., ZHOU, J., WANG, K., GAO, J., LIN, Q., CHANG, Y., XU, D., and WEN, G. Dual-function quasi-zero-stiffness dynamic vibration absorber: low-frequency vibration mitigation and energy harvesting. Applied Mathematical Modelling, 116, 636- 654 (2023) |
| 21 | MOFIDIAN, S. M. M., and BARDAWEEL, H. A dual-purpose vibration isolator energy harvester: experiment and model. Mechanical Systems and Signal Processing, 118, 360- 376 (2019) |
| 22 | MOFIDIAN, S. M. M., and BARDAWEEL, H. Theoretical study and experimental identification of elastic-magnetic vibration isolation system. Journal of Intelligent Material Systems and Structures, 29 (18), 3550- 3561 (2018) |
| 23 | CAI, Q., and ZHU, S. The nexus between vibration-based energy harvesting and structural vibration control: a comprehensive review. Renewable and Sustainable Energy Reviews, 155, 111920 (2022) |
| 24 | XIE, L., LI, J., LI, X., HUANG, L., and CAI, S. Damping-tunable energy-harvesting vehicle damper with multiple controlled generators: design, modeling and experiments. Mechanical Systems and Signal Processing, 99, 859- 872 (2018) |
| 25 | YAN, B., WANG, K., KANG, C. X., ZHANG, X. N., and WU, C. Y. Self-sensing electromagnetic transducer for vibration control of space antenna reflector. IEEE/ASME Transactions on Mechatronics, 22 (5), 1944- 1951 (2017) |
| 26 | GRIFFITHS, D. J. Introduction to Electrodynamics, Pearson Education, New York (2014) |
| 27 | NGUYEN, H. T., DENTCHO, G., and HAMZEH, B. Mono-stable and bi-stable magnetic spring based vibration energy harvesting systems subject to harmonic excitation: dynamic modeling and experimental verification. Mechanical Systems and Signal Processing, 134, 106361 (2019) |
| 28 | NGUYEN, H. T., GENOV, D. A., and BARDAWEEL, H. Vibration energy harvesting using magnetic spring based nonlinear oscillators: design strategies and insights. Applied Energy, 269, 115102 (2020) |
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