Solutions of dynamic and acoustic responses of a clamped rectangular plate in thermal environments

Abstract

This work presents an investigation of vibration and acoustic response characters of a clamped rectangular thin plate in thermal environments. The general form of governing equation of plate flexural vibration with considering thermal loads is established, and the influence of uniform temperature change on response characters is studied in detail. A set of double sinusoidal mode shape functions for fully clamped boundaries is used to describe the displacement distribution. The governing equation is solved with Fourier series expansion to discuss the natural vibration and dynamic responses of a clamped plate in thermal environments. Accordingly, acoustic radiation characteristics are obtained based on Rayleigh integral. Results show that natural frequencies decrease with the increment of plate temperature, and the first natural frequency is much more sensitive to thermal environment changes. Response curves of plate vibration and radiated sound power shift toward lower frequency range, and the response amplitudes of the first resonant peak of the two responses present opposite variation tendencies. These phenomena are verified with finite element and boundary element simulations. Thermal loads reduce the radiation efficiency of the plate obviously below the critical frequency, but the maximum value almost remains unchanged.