Power dissipation and temperature distribution in piezoelectric ceramic slabs.

A method is presented to determine power dissipation in one-dimensional piezoelectric slabs with internal losses and the resulting temperature distribution. The length of the slab is much greater than the lateral dimensions. Losses are represented using complex piezoelectric coefficients. It is shown that the spatially non-uniform power dissipation density in the slab can be determined by considering either hysteresis loops or the Poynting vector. The total power dissipated in the slab is obtained by integrating the power dissipation density over the slab and is shown to be equal to the power input to the slab for special cases of mechanically and electrically excited slabs. The one-dimensional heat equation that includes the effect of conduction and convection, and the boundary conditions, are then used to determine the temperature distribution. When the analytical expression for the power dissipation density is simple, direct integration is used. It is shown that a modified Fourier series approach yields the same results. For other cases, the temperature distribution is determined using only the latter approach. Numerical results are presented to illustrate the effects of internal losses, heat conduction and convection coefficients, and boundary conditions on the temperature distribution.

[1]  Hyun-Kyo Jung,et al.  Analysis of temperature rise for piezoelectric transformer using finite-element method , 2006, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[2]  Jiashi Yang,et al.  Piezoelectric transformer structural modeling - a review , 2007, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[3]  E. Jaynes,et al.  Kramers–Kronig relationship between ultrasonic attenuation and phase velocity , 1981 .

[4]  Yuan-Ping Liu,et al.  Analyses of the Heat Dissipated by Losses in a Piezoelectric Transformer , 2009, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[5]  Kenji Uchino,et al.  Heat generation in multilayer piezoelectric actuators , 1996 .

[6]  C. Rogers,et al.  Heat Generation, Temperature, and Thermal Stress of Structurally Integrated Piezo-Actuators , 1995 .

[7]  R. Holland,et al.  Representation of Dielectric, Elastic, and Piezoelectric Losses by Complex Coefficients , 1967, IEEE Transactions on Sonics and Ultrasonics.

[8]  C. Biateau,et al.  Finite element modeling of the temperature rise due to the propagation of ultrasonic waves in viscoelastic materials and experimental validation. , 2008, The Journal of the Acoustical Society of America.

[9]  D. D. Ebenezer,et al.  Non-uniform heat generation in rods with hysteretic damping , 2007 .

[10]  Shankar,et al.  An acoustic/thermal model for self-heating in PMN sonar projectors , 2000, The Journal of the Acoustical Society of America.

[11]  Junhui Hu,et al.  Analyses of the temperature field in a bar-shaped piezoelectric transformer operating in longitudinal vibration mode. , 2003, IEEE transactions on ultrasonics, ferroelectrics, and frequency control.

[12]  Kim C. Benjamin,et al.  Transducers for Sonar Systems , 2008 .

[13]  The use of complex material constants to model losses in piezoelectric , 1999 .

[14]  J. C. Snowdon Representation of the Mechanical Damping Possessed by Rubberlike Materials and Structures , 1963 .

[15]  K. Uchino,et al.  Loss mechanisms in piezoelectrics: how to measure different losses separately , 2001, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.