• Title of article

    FEM simulation of a sono-reactor accounting for vibrations of the boundaries

  • Author/Authors

    Louisnard، نويسنده , , O. and Gonzalez-Garcia، نويسنده , , J. and Tudela، نويسنده , , I. and Klima، نويسنده , , J. Fernandez-Saez، نويسنده , , V. and Vargas-Hernandez، نويسنده , , Y.، نويسنده ,

  • Issue Information
    فصلنامه با شماره پیاپی سال 2009
  • Pages
    10
  • From page
    250
  • To page
    259
  • Abstract
    The chemical effects of acoustic cavitation are obtained in sono-reactors built-up from a vessel and an ultrasonic source. In this paper, simulations of an existing sono-reactor are carried out, using a linear acoustics model, accounting for the vibrations of the solid walls. The available frequency range of the generator (19–21 kHz) is systematically scanned. Global quantities are plotted as a function of frequency in order to obtain response curves, exhibiting several resonance peaks. In absence of the precise knowledge of the bubbles size distribution and spatial location, the attenuation coefficient of the wave is taken as a variable, but spatially uniform parameter, and its influence is studied. The concepts of acoustic energy, intensity, active power, and source impedance are recalled, along with the general balance equation for acoustic energy, which is used as a convergence check of the simulations. It is shown that the interface between the liquid and the solid walls cannot be correctly represented by the simple approximations of either infinitely soft, or infinitely hard boundaries. Moreover, the liquid–solid coupling allows the cooling jacket to receive a noticeable part of the input power, although it is not in direct contact with the sonotrode. It may therefore undergo cavitation and this feature opens the perspective to design sono-reactors which avoid direct contact between the working liquid and the sonotrode. Besides, the possibility to shift the main pressure antinode far from the sonotrode area by exciting a resonance of the system is examined.
  • Keywords
    Finite elements , Ultrasound , Fluid–structure interaction , Acoustic cavitation , Standing waves
  • Journal title
    Ultrasonics Sonochemistry
  • Serial Year
    2009
  • Journal title
    Ultrasonics Sonochemistry
  • Record number

    2189320