Journal
SCIENCE CHINA-PHYSICS MECHANICS & ASTRONOMY
Volume 63, Issue 2, Pages -Publisher
SCIENCE PRESS
DOI: 10.1007/s11433-019-9437-x
Keywords
heat flux manipulation; bandgap; anisotropic structure; thermal stress; spiral-multilayered structure
Categories
Funding
- National Natural Science Foundation of China [11772251, 11802220]
- 111 Project [B18040]
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This study presents a two-dimensional phononic crystal with heat flux manipulation and wide bandgaps of out-of-plane modes within the low-frequency range. The anisotropic matrix made of spiral-multilayered materials with different thermal conductivities, and the coating layer inserted with metal are designed for heat flux manipulation. Rubber-coated metal cylinders are periodically embedded in the anisotropic matrix to obtain the low-frequency bandgaps of out-of-plane modes. Numerical simulation is carried out to validate the heat and elastic characteristics of the spiral-multilayered anisotropic structure and reveal the effects of the laying angle and temperature on the bandgaps. Subsequently, a spiral-multilayered plate with periodic structures is studied, which shows an obvious vibration attenuation in the frequency ranges of the bandgaps and a deflected heat flux from the initial propagation direction. In the experimental investigation, the multi-phase spiral-multilayered anisotropic plate is simplified to a single-phase anisotropic plate made of aluminum. The characteristics of this type of anisotropic phononic crystal structure may pave the way for the design of a new kind of thermo-acoustic metamaterial serving in combined thermal and acoustic environments.
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