Your search keyword '"Mahdi Alaei Varnosfaderani"' showing total 2 results

1. Active transient elasto-acoustic response damping of a thick-walled liquid-coupled piezolaminated cylindrical vessel

Author

Vahid Rabbani, Seyyed M. Hasheminejad, and Mahdi Alaei-Varnosfaderani

Subjects

Engineering, General Mathematics, Acoustics, Aerospace Engineering, Ocean Engineering, Context (language use), 02 engineering and technology, Orthotropic material, Displacement (vector), 0203 mechanical engineering, Civil and Structural Engineering, business.industry, Mechanical Engineering, Structural engineering, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Wave equation, Transfer matrix, Vibration, 020303 mechanical engineering & transports, Mechanics of Materials, Automotive Engineering, Transient (oscillation), 0210 nano-technology, business, Actuator

Abstract

The linear 3D piezoelasticity theory in conjunction with the versatile transfer matrix approach and the wave equation for the internal acoustic domain are employed for active non-stationary vibroacoustic response control of an arbitrarily thick, tri-laminate, fluid-filled, simply supported, piezocomposite cylindrical tank, excited by arbitrary (non-axisymmetric) time-dependent on-surface mechanical loads. The smart structure is composed of a supporting core layer of functionally graded orthotropic material perfectly bonded to inner and outer spatially distributed radially polarized functionally graded piezoceramic sensor and uniform force actuator (FGPM) layers. Active vibration damping is implemented by transferring the accumulated voltage on the sensor layer to the piezoelectric actuator layer in context of proportional and derivative control laws. Durbin's numerical inverse Laplace transform scheme is utilized to calculate the time response histories of the relevant interface displacement/stres...

Published

2015

2. Vibroacoustic response and active control of a fluid-filled functionally graded piezoelectric material composite cylinder

Author

Mahdi Alaei-Varnosfaderani and Seyyed M. Hasheminejad

Subjects

Materials science, business.industry, Mechanical Engineering, Structural engineering, Orthotropic material, Functionally graded material, Piezoelectricity, Cylinder (engine), law.invention, Vibration, Stress (mechanics), law, Fluid–structure interaction, General Materials Science, Composite material, Axial symmetry, business

Abstract

The linear three-dimensional piezoelasticity theory in conjunction with the versatile transfer matrix approach is employed to investigate the steady-state nonaxisymmetric fluid–structure-coupled vibrations of an arbitrarily thick bilaminate simply supported hollow cylinder of finite length, composed of an inner layer of orthotropic functionally graded material perfectly bonded to an outer layer of radially/axially/circumferentially polarized functionally graded piezoceramic material. The cylinder is filled with a compressible nonviscous fluid and may be subjected to arbitrary time-harmonic on-surface mechanical drives. The analytical results are illustrated with numerical examples in which water-filled homogeneous PZT4–steel composite cylinders are driven by harmonic external concentrated or distributed radial surface loads. When the outer piezoelectric layer is operating in the receiving (sensing) mode, the frequency spectrums of the induced voltage, stress components, and on-axis acoustic pressure are calculated and discussed for the selected loading configurations. Also, when the piezolayer operates in the active vibration mode, the effects of polarization direction and number of control modes on the voltage required for partial or complete cancellation of the on-axis internal pressure are investigated. Limiting cases are considered, and the validity of results is established by comparison with the data in the existing literature as well as with the aid of a commercial finite element package.

Published

2012