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A Hybrid Finite Element Method – Kirchhoff Approximation Method for Modeling Acoustic Scattering from an Underwater Vehicle Model with Alberich Coatings with Periodic Internal Cavities

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Anechoic tiles can significantly reduce the echo intensity of underwater vehicles, thereby increasing the difficulty of detecting such vehicles. However, the computational efficiency of conventional methods such as the finite element method (FEM) and the boundary element method (BEM) has its limitations. A fast hybrid method for modeling acoustic scattering from underwater vehicles with anechoic tiles with periodic internal cavities, is developed by combining the Kirchhoff approximation (KA) and FEM. The accuracy and rapidity of the KA method were validated by FEM. According to the actual situation, the reflection coefficients of rubber materials with two different structures under rigid backing are simulated by FEM. Using the KA method, the acoustic scattering characteristics of the underwater vehicle with anechoic tiles are obtained by inputting the reflection coefficients and the target’s geometric grid. Experiments on the monostatic target strength (TS) in the frequency range of 1 to 20 kHz and time domain echo characteristics of acoustic scattering on a benchmark scale model with anechoic tiles are conducted. The research results indicate that the TS values and echo characteristic curves of the KA solutions closely approximate the experimental results, which verifies the accuracy of the KA method in calculating the TS and echo characteristics of underwater vehicles with anechoic tiles.
Rocznik
Strony
209--219
Opis fizyczny
Bibliogr. 26 poz., fot., rys., tab., wykr.
Twórcy
autor
  • School of Energy and Power, Jiangsu University of Science and Technology Zhenjiang, China
autor
  • School of Energy and Power, Jiangsu University of Science and Technology Zhenjiang, China
  • PLA Unit 92578 Beijing, China
autor
  • Systems Engineering Research Institute Beijing, China
autor
  • PLA Unit 92578 Beijing, China
autor
  • PLA Unit 92578 Beijing, China
Bibliografia
  • 1. Abawi A.T. (2016), Kirchhoff scattering from nonpenetrable targets modeled as an assembly of triangular facets, The Acoustical Society of America, 140(3): 1878-1886, doi: 10.1121/1.4962735.
  • 2. Chen X., Luo Y. (2018), Simulation of scattering acoustic field of underwater target in low frequency based on ANSYS and SYSNOISE [in Chinese], Journal of Ordnance Equipment Engineering, 39(5): 103-107, doi: 10.11809/bqzbgcxb2018.05.022.
  • 3. Esfahani I.C., Ji S., Sun H. (2023), A drop-onmicropillars (DOM) based acoustic wave viscometer for high viscosity liquid measurement, IEEE Sensors Journal, doi: 10.1109/JSEN.2023.3309757.
  • 4. Esfahani I.C., Sun H. (2023), A droplet-based micropillar-enhanced acoustic wave (μPAW) device for viscosity measurement, Sensors and Actuators A: Physical, 350: 114121, doi: 10.1016/j.sna.2022.114121.
  • 5. Fan J., Tang W.L. (1999), The planar element method for computing target strength (TS) of sonar [in Chinese], Proceedings of the Acoustical Society of China 1999 Youth Conference, pp. 40-41.
  • 6. Fan J., Tang W.L., Zhuo L.K. (2012), Planar elements methods for forecasting the echo characteristics from sonar targets, Ship Mechanics, 16(1-2): 171-180, doi: 10.3969/j.issn.1007-7294.2012.01.020.
  • 7. Fan J., Zhuo L.K. (2006), Graphical acoustics computing method for echo characteristics calculation of underwater targets, Acta Acustica, 31(6): 511-516, doi: 10.3321/j.issn:0371-0025.2006.06.006.
  • 8. Feng X.L., Chen N.R., Li X.W., Li J. (2018), Analyzing the target strength of Benchmark submarine by boundary element method at low and middle frequencies [in Chinese], Technical Acoustic, 37(05): 418-424, doi: 10.16300/j.cnki.1000-3630.2018.05.003.
  • 9. Huang L.Z., Xiao Y., Wen J.H., Yang H.B., Wen X.S. (2015), Analysis of decoupling mechanism of an acoustic coating layer with horizontal cylindrical cavities [in Chinese], Acta Physica Sinica, 64(15): 154301, doi: 10.7498/aps.64.154301.
  • 10. Lavia E., Gonzalez J.D., Blanc S. (2018), Modelling high-frequency backscattering from a mesh of curved surfaces using Kirchhoff Approximation, Journal of Theoretical and Computational Acoustics, 27(04): 17, doi: 10.1142/S2591728518500573.
  • 11. Lee K., Seong W. (2009), Time-domain Kirchhoff model for acoustic scattering from an impedance polygon facet, The Acoustical Society of America, 126(1): 14-21, doi: 10.1121/1.3141887.
  • 12. Liu B. (2020), Research on acoustic scattering characteristics of typical structures of MUUV [in Chinese], Shanghai Jiao Tong University, doi: 10.27307/d.cnki.gsjtu.2020.002589.
  • 13. Liu H., Peng Z.L., Fan J., Wu K. (2019), Numerical and experimental research on acoustic scattering time-frequency characteristics of dock landing ship [in Chinese], Technical Acoustics, 38(02): 147-152, doi: 10.16300/j.cnki.1000-3630.2019.02.006.
  • 14. Liu J.W., Peng Z.L., Fan J., Liu Y., Kong H.M. (2023), Acoustic scattering prediction method of underwater vehicles based on slice-parameterized multihighlight model, Acta Armamentarii, 44(02): 517-525, doi: 10.12382/bgxb.2021.0764.
  • 15. Lu D. (2014), Researches on acoustic scattering of elastic target on finite element methods [in Chinese], Harbin Engineering University.
  • 16. Marston P.L., Sun N.H. (1995), Backscattering near the coincidence frequency of a thin cylindrical shell: Surface wave properties from elasticity theory and an approximate ray synthesis, The Acoustical Society of America, 92(6): 777-783, doi: 10.1121/1.412124.
  • 17. Nell C.W., Gilroy L.E. (2003), An improved BASIS model for the BeTSSi submarine, DRDC Atlantic TR, Technical report.
  • 18. Pignier J.N., O’Reilly J.C., Boij S. (2015), A Kirchhoff approximation-based numerical method to compute multiple acoustic scattering of a moving source, Applied Acoustics, 96: 108-117, doi: 10.1016/j.apacoust.2015.03.016.
  • 19. Tong Y.Z., Fan J., Wang B. (2020), Application of Floquet-Bloch theory in dipersion curve calculation [in Chinese], Technical Acoustics, 39(01): 11-14, doi: 10.16300/j.cnki.1000-3630.2020.01.002.
  • 20. Wang W.H.,Wang B., Fan J., Zhou J. (2021), An iterative planar elements method for calculating multiple acoustic scattering from concave targets, Proceedings of the 18th Symposium on Underwater Noise of Ships, pp. 121-126, doi: 10.26914/c.cnkihy.2021.056714.
  • 21. Wei K.N., Li W., Lei M., Chai Y.B. (2013), Simulation research on acoustic scattering characteristics of underwater targets based on boundary element method [in Chinese], Proceedings of the Fourteenth Symposium on Underwater Noise of Ships, pp. 452-462.
  • 22. Witos F. (2019), Properties of amplitude distributions of acoustic emission signals generated in pressure vessel during testing, Archives of Acoustics, 44(3): 493-503, doi: 10.24425/aoa.2019.129264.
  • 23. Xu H.T., An J.Y., Liu C.F. (2004), Acoustic characteristics of anechoic coatings containing air cavities in water [in Chinese], Technical Acoustics, 23(z1): 345-347, doi: 10.3969/j.issn.1000-3630.2004.z1.101.
  • 24. Xu Z.C., Zhang M.M., Wang L. (2015), Numerical simulation of acoustic scattering at low frequency for the BeTSSi submarine [in Chinese], Computer & Digital Engineering, 43(04): 551-553+575, doi: 10.3969/j.issn1672-9722.2015.04.003.
  • 25. Yao X.L., Zhang Y., Qian D.J., Huang C., Zhang H.H. (2007), Characteristics analysis of acoustic insulation and decoupled tiles by FEM and experiment [in Chinese], Chinese Journal of Ship Research, 2(6): 9-15, doi: 10.3969/j.issn.1673-3185.2007.06.003.
  • 26. Zheng G.Y., Fan J., Tang W.L. (2011), A modified planar elements method considering occlusion and secondary scattering [in Chinese], Acta Acustica, 36(4): 377-383, doi: 10.15949/j.cnki.0371-0025.2011.04.010.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-25f22634-0321-4b53-b596-a01c749a7377
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