Mechanics of Solids
A Journal of Russian Academy of Sciences

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Print ISSN 0025-6544
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Issues > Archive of Issues > 2025-2 > pp.1208-1223

Archive of Issues

Total articles in the database:		13205
In Russian (Изв. РАН. МТТ):		8140
In English (Mech. Solids):		5065

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G.B. He and Z.J. Gao, "Sound Wave Propagation in Multilayered Two-dimensional Quasicrystal Cylindrical Shells with Internal and External Airflow," Mech. Solids. 60 (2), 1208-1223 (2025)
Year	2025	Volume	60	Number	2	Pages	1208-1223
DOI	10.1134/S0025654424607067
Title	Sound Wave Propagation in Multilayered Two-dimensional Quasicrystal Cylindrical Shells with Internal and External Airflow
Author(s)	G.B. He (Hubei International Scientific and Technological Cooperation Base of Intelligent Fluid Engineering and Equipment, Three Gorges University, Yichang, 443000 China, 1404950929@qq.com) Z.J. Gao (Hubei International Scientific and Technological Cooperation Base of Intelligent Fluid Engineering and Equipment, Three Gorges University, Yichang, 443000 China, 570186276@qq.com)
Abstract	We present an analytical solution of sound transmission through a quasicrystal cylindrical shell to model the transmission of airborne sound into the aircraft interior. A state-space approach is employed to derive the governing equations of each layer. The propagator matrix is obtained by propagating the solution in each layer from the bottom of the layered plate to the top using the continuity conditions of the field variables across the interfaces. We make use of the imperfect interface conditions to capture the discontinuity of physical quantities across the interface, from which the displacements and stresses are further converted into the interface propagator matrix. The global propagator relation is assembled by propagating the solutions in each layer and each interface. The external and internal fluid mediums of the shell are used to simulate the air inside and outside the cabin and move with constant velocities. The Bessel and Hankel functions are introduced to characterize specific acoustic wave equations, and further to couple with the shell equations. An exact solution of the transmission loss is presented in a series form under satisfying the fluid-structure interaction boundary conditions. The numerical examples indicate that the flight altitude h, Mach number M, and incidence angle α change the distributions of transmission loss by influencing the axial and radial wave numbers during acoustic wave propagation. Other parameters have little effect on transmission loss.
Keywords	Sound wave propagation, quasicrystal cylindrical shell, state-space model, imperfect interfaces, transmission loss
Received	16 December 2024	Revised	22 February 2025	Accepted	26 February 2025
Link to Fulltext	https://link.springer.com/article/10.1134/S0025654424607067
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