Modal Matching of Key Components in the Launching System Based on Response Surface Method
DOI:
https://doi.org/10.53469/jrse.2024.06(11).17Keywords:
Response Surface Method, Modal Analysis, Harmonic Response Analysis, Modal MatchingAbstract
This chapter adopts Response Surface Methodology (RSM) combined with dynamic simulation and statistical analysis to deeply investigate the impact of modal matching of the inherent frequencies of key components of the launching system on the disturbances at the launch box opening during firing. Through experimental design, a polynomial fitting response surface model is established between design parameters and response objectives. The ultimate goal is to find the optimal design scheme that minimizes the initial disturbance, thereby achieving effective modal matching between the main components of the launching device. This research aims to provide a theoretical basis for improving firing accuracy and system stability.
References
Zeng Shengyu. Optimization Design Technology for Anti-Ship Missiles Based on Response Surface Approximation in Parallel Subspace [D]. Northwestern Polytechnical University, 2004.R. Caves, Multinational Enterprise and Economic Analysis, Cambridge University Press, Cambridge, 1982. (book style)
Che Wenkan, Li Lixin, Wang Feng. Experimental Study on the Optimization of the Inner Ring Structure of Riveted Hub Bearing Units Based on Response Surface Method [J/OL]. Electromechanical Engineering, 1-10 [2024-11-14].
Wang Yugang, Xiu Shichao. Multi-Objective Optimization Design of Motor Brackets Using Response Surface Method [J]. Mechanical Design and Manufacture, 2021(10): 42-44. K. Deb, S. Agrawal, A. Pratab, T. Meyarivan, “A Fast Elitist Non-dominated Sorting Genetic Algorithms for Multiobjective Optimization: NSGA II,” KanGAL report 200001, Indian Institute of Technology, Kanpur, India, 2000. (technical report style)
He H, Zhou J, Xu L, et al. Optimization of a novel lateral energy dissipation system for cable-stayed bridge with short piers based on seismic vulnerability analysis [J]. Structures, 2024,70107700-107700.
Yue, J. (2016). Modal Matching Analysis and Optimization of a Certain Naval Gun (Master's thesis). Nanjing University of Science and Technology.
Cai, J., Liu, Z., Wang, G., et al. (2024). Optimization Design of the Auxiliary Tail Rope Device for the Winch Based on Response Surface Method. Journal of Engineering Design, 31(02),
Song, Z. (2022). Research on Robust Design of Turbomachinery Engine Dynamics Based on Higher-Order Response Surface Method [Master’s Thesis]. Nanjing University of Aeronautics and Astronautics.DOI:10.27239/d.cnki.gnhhu.2022.000210.
Zuo, Y. (2022). Vibration Characteristics Analysis and Modal Matching Study of Key Components of Large-Caliber Naval Guns [Master’s Thesis]. Harbin Engineering University. DOI: 10.27060/ d.cnki.ghbcu.2022.001811.
Li, X., Wang, S., & Zhao, S. (2019). Study on the Influence of Solid Element Types on Simulation Results. Journal of Dalian Jiaotong University, 40(02), 76-79. DOI: 10.13291/j.cnki.djdxac.2019.02.017.
Yang, J. (2020). Principles for Selecting Finite Element Mesh Elements. Henan Science and Technology, (17), 35-37.
Fu, W., Lou, L., Gao, Z., et al. (2017). Theoretical Model of Normal Contact Stiffness and Damping for Mechanical Joints. Journal of Mechanical Engineering, 53(09), 73-82.
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Copyright (c) 2024 Yue Ma, Qilin Shu, Yuekang Yue
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.
