Bandgap adjustment of a sandwich-like acoustic metamaterial plate with a frequency-displacement feedback control method

doi:10.1007/s10483-024-3167-8

Abstract

Abstract:

Several types of acoustic metamaterials composed of resonant units have been developed to achieve low-frequency bandgaps. In most of these structures, bandgaps are determined by their geometric configurations and material properties. This paper presents a frequency-displacement feedback control method for vibration suppression in a sandwich-like acoustic metamaterial plate. The band structure is theoretically derived using the Hamilton principle and validated by comparing the theoretical calculation results with the finite element simulation results. In this method, the feedback voltage is related to the displacement of a resonator and the excitation frequency. By applying a feedback voltage on the piezoelectric fiber-reinforced composite (PFRC) layers attached to a cantilever-mass resonator, the natural frequency of the resonator can be adjusted. It ensures that the bandgap moves in a frequency-dependent manner to keep the excitation frequency within the bandgap. Based on this frequency-displacement feedback control strategy, the bandgap of the metamaterial plate can be effectively adjusted, and the vibration of the metamaterial plate can be significantly suppressed.

Key words: acoustic metamaterial, Hamilton principle, electromechanical coupling, vibration control, local resonance

2010 MSC Number:

74H45
35B34

Jianing LIU, Jinqiang LI, Ying WU. Bandgap adjustment of a sandwich-like acoustic metamaterial plate with a frequency-displacement feedback control method. Applied Mathematics and Mechanics (English Edition), 2024, 45(10): 1807-1820.

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References 48

1	YANG, T., ZHOU, S., FANG, S., QIN, W., and INMAN, D. J. Nonlinear vibration energy harvesting and vibration suppression technologies: designs, analysis, and applications. Applied Physics Reviews, 8 (3), 031317 (2021)
2	LU, Z. Q., LIU, W. H., DING, H., and CHEN, L. Q. Energy transfer of an axially loaded beam with a parallel-coupled nonlinear vibration isolator. Journal of Vibration and Acoustics, 144 (5), 051009 (2022)
3	QIN, Y., TANG, X., JIA, T., DUAN, Z., ZHANG, J., LI, Y., and ZHENG, L. Noise and vibration suppression in hybrid electric vehicles: state of the art and challenges. Renewable and Sustainable Energy Reviews, 124, 109782 (2020)
4	YAN, G., ZOU, H. X., WANG, S., ZHAO, L. C., WU, Z. Y., and ZHANG, W. M. Bio-inspired vibration isolation: methodology and design. Applied Mechanics Reviews, 73 (2), 020801 (2021)
5	YUAN, H., WU, X., and ZHANG, J. Cutting failure behavior of foam core sandwich plates. International Journal of Solids and Structures, 303, 113009 (2024)
6	WANG, X., CONG, H., JIANG, G., LIANG, X., LIU, L., and HE, H. A review on PVDF nanofibers in textiles for flexible piezoelectric sensors. ACS Applied Nano Materials, 6 (3), 1522- 1540 (2023)
7	LU, M., DOU, Z., LI, J. W., QIU, X., SHEN, B., ZHANG, D., and WANG, K. Piezoelectric materials and sensors for structural health monitoring: fundamental aspects, current status, and future perspectives. Sensors, 23 (1), 543 (2023)
8	HABIB, M., LANTGIOS, I., and HORNBOSTEL, K. A review of ceramic, polymer and composite piezoelectric materials. Journal of Physics D: Applied Physics, 55 (42), 423002 (2022)
9	LIU, C., JING, X., DALEY, S., and LI, F. Recent advances in micro-vibration isolation. Mechanical Systems and Signal Processing, 56, 55- 80 (2015)
10	LU, Z., WANG, Z., ZHOU, Y., and LU, X. Nonlinear dissipative devices in structural vibration control: a review. Journal of Sound and Vibration, 423, 18- 49 (2018)
11	ZHANG, C., MOUSAVI, A. A., MASRI, S. F., GHOLIPOUR, G., YAN, K., and LI, X. Vibration feature extraction using signal processing techniques for structural health monitoring: a review. Mechanical Systems and Signal Processing, 177, 109175 (2022)
12	GAO, N., ZHANG, Z., DENG, J., GUO, X., CHEN, B., and HOU, H. Acoustic metamaterials for noise reduction: a review. Advanced Materials Technologies, 7 (6), 2100698 (2022)
13	MA, G., and SHENG, P. Acoustic metamaterials: from local resonances to broad horizons. Science Advances, 2 (2), e1501595 (2016)
14	FLOQUET, G. Sur les équations différentielles linéaires à coefficients périodiques. Annales Scientifiques de l'École Normale Supérieure, 12, 47- 88 (1883)
15	BLOCH, F. Über die quantenmechanik der elektronen in kristallgittern. Zeitschrift für Physic, 52 (7), 555- 600 (1929)
16	BRILLOUIN, L. Les électrons libres dans les métaux et le role des réflexions de Bragg. Journal de Physique et du Radium, 1 (11), 377- 400 (1930)
17	SIGALAS,M., and ECONOMOU, E. N. Band structure of elastic waves in two dimensional systems. Solid State Communications, 86 (3), 141- 143 (1993)
18	KUSHWAHA, M. S., HALEVI, P., DOBRZYNSKI, L., and DJAFARI-ROUHANI, B. Acoustic band structure of periodic elastic composites. Physical Review Letters, 71 (13), 2022- 2025 (1993)
19	MARTÍNEZ-SALA, R., SANCHO, J., SÁNCHEZ, J. V., GÓMEZ, V., LLINARES, J., and MESEGUER, F. Sound attenuation by sculpture. nature, 378, 241 (1995)
20	DE ESPINOSA, F. M., JIMENEZ, E., and TORRES, M. Ultrasonic band gap in a periodic two-dimensional composite. Physical Review Letters, 80 (6), 1208- 1211 (1998)
21	LIU, Z., ZHANG, X., MAO, Y., ZHU, Y. Y., YANG, Z., CHAN, C. T., and SHENG, P. Locally resonant sonic materials. Science, 289 (5485), 1734- 1736 (2000)
22	ZHU, R., LIU, X. N., HU, G. K., SUN, C. T., and HUANG, G. L. A chiral elastic metamaterial beam for broadband vibration suppression. Journal of Sound and Vibration, 333 (10), 2759- 2773 (2014)
23	PENG, H., and PAI, P. F. Acoustic metamaterial plates for elastic wave absorption and structural vibration suppression. International Journal of Mechanical Sciences, 89, 350- 361 (2014)
24	GAO, N., and LU, K. An underwater metamaterial for broadband acoustic absorption at low frequency. Applied Acoustics, 169, 107500 (2020)
25	LI, J., FAN, X., and LI, F. Numerical and experimental study of a sandwich-like metamaterial plate for vibration suppression. Composite Structures, 238, 111969 (2020)
26	XUE, Y., LI, J., LI, F., and SONG, Z. Flutter and thermal buckling properties and active control of functionally graded piezoelectric material plate in supersonic airflow. Acta Mechanica Solida Sinica, 33, 692- 706 (2020)
27	ZHANG, Y., FAN, X., LI, J., LI, F., YU, G., ZHANG, R., and YUAN, K. Low-frequency vibration insulation performance of the pyramidal lattice sandwich metamaterial beam. Composite Structure, 278, 114719 (2021)
28	XUE, Y., LI, J., WANG, Y., and LI, F. Tunable nonlinear band gaps in a sandwich-like meta-plate. Nonlinear Dynamics, 106, 2841- 2857 (2021)
29	FAN, X., LI, J., ZHANG, X., and LI, F. Multi-bandgaps metamaterial plate design using complex mass-beam resonator. International Journal of Mechanical Sciences, 236, 107742 (2022)
30	LI, J., ZHANG, Y., FAN, X., and LI, F. Multi bandgaps design of sandwich metamaterial plate with embedded membrane-type resonators. Journal of Sandwich Structures & Materials, 25 (3), 311- 329 (2023)
31	XUE, Y., LI, J., WANG, Y., and LI, F. Broadband vibration attenuation in nonlinear meta-structures with magnet coupling mechanism: theory and experiments. Communications in Nonlinear Science and Numerical Simulation, 127, 107543 (2023)
32	WANG, Q., LI, J., ZHANG, Y., XUE, Y., and LI, F. Bandgap properties in metamaterial sandwich plate with periodically embedded plate-type resonators. Mechanical Systems and Signal Processing, 151, 107375 (2021)
33	HU, G., AUSTIN, A. C., SOROKIN, V., and TANG, L. Metamaterial beam with graded local resonators for broadband vibration suppression. Mechanical Systems and Signal Processing, 146, 106982 (2021)
34	WANG, Z., MA, Z., GUO, X., and ZHANG, D. A new tunable elastic metamaterial structure for manipulating band gaps/wave propagation. Applied Mathematics and Mechanics (English Edition), 42 (11), 1543- 1554 (2021) doi: 10.1007/s10483-021-2787-8
35	LU, Z. Q., ZHAO, L., DING, H., and CHEN, L. Q. A dual-functional metamaterial for integrated vibration isolation and energy harvesting. Journal of Sound and Vibration, 509, 116251 (2021)
36	ZHAO, L., LU, Z. Q., DING, H., and CHEN, L. Q. Experimental observation of transverse and longitudinal wave propagation in a metamaterial periodically arrayed with nonlinear resonators. Mechanical Systems and Signal Processing, 170, 108836 (2022)
37	LIN, L. F., LU, Z. Q., ZHAO, L., ZHENG, Y. S., DING, H., and CHEN, L. Q. Vibration isolation of mechatronic metamaterial beam with resonant piezoelectric shunting. International Journal of Mechanical Sciences, 254, 108448 (2023)
38	WANG, B., LIU, J., SOH, A. K., and LIANG, N. On band gaps of nonlocal acoustic lattice metamaterials: a robust strain gradient model. Applied Mathematics and Mechanics (English Edition), 43 (1), 1- 20 (2022) doi: 10.1007/s10483-021-2795-5
39	YANG, F., MA, Z., and GUO, X. Bandgap characteristics of the two-dimensional missing rib lattice structure. Applied Mathematics and Mechanics (English Edition), 43 (11), 1631- 1640 (2022) doi: 10.1007/s10483-022-2923-6
40	LI, Z., WANG, Y., and WANG, Y. Tunable three-dimensional nonreciprocal transmission in a layered nonlinear elastic wave metamaterial by initial stresses. Applied Mathematics and Mechanics (English Edition), 43 (2), 167- 184 (2022) doi: 10.1007/s10483-021-2808-9
41	QUE, W., YANG, X., and ZHANG, W. Tunable low frequency band gaps and sound transmission loss of a lever-type metamaterial plate. Applied Mathematics and Mechanics (English Edition), 43 (8), 1145- 1158 (2022) doi: 10.1007/s10483-022-2890-9
42	LIU, B., HAO, Y., and CHEN, P. Effect of geometrical parameters and additional mass on the acoustic and vibration control of the bilayer resonant metamaterials. International Journal of Aeroacoustics, 22(3-4), 238- 260 (2023)
43	LI, C., CHEN, Z., and JIAO, Y. Vibration and bandgap behavior of sandwich pyramid lattice core plate with resonant rings. Materials, 16 (7), 2730 (2023)
44	YI, J., WU, Z., XIA, R., and LI, Z. Reconfigurable metamaterial for asymmetric and symmetric elastic wave absorption based on exceptional point in resonant bandgap. Applied Mathematics and Mechanics (English Edition), 44 (1), 1- 20 (2023) doi: 10.1007/s10483-023-2949-7
45	GENG, Q., ZHAO, G., YANG, X., SHAO, Z., and LI, Y. Flexural vibration suppression behavior of sleeved phononic crystal pipes in thermal environment. Engineering Structures, 309, 118011 (2024)
46	LI, J., XUE, Y., and LI, F. Active band gap control of magnetorheological meta-plate using frequency feedback control law. Journal of Sound and Vibration, 567, 118076 (2023)
47	XUE, Y., LI, J., WANG, Y., SONG, Z., and KRUSHYNSKA, A. O. Widely tunable magnetorheological metamaterials with nonlinear amplification mechanism. International Journal of Mechanical Sciences, 264, 108830 (2024)
48	LI, J., and NARITA, Y. Analysis and active control for wind induced vibration of beam with ACLD patch. Wind and Structures, 17 (4), 399- 417 (2013)

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