Title of article
Improvement of Acoustic Doppler Velocimetry in bubbly flow measurements as applied to river characterization for kinetic turbines
Author/Authors
Birjandi، نويسنده , , Amir Hossein and Bibeau، نويسنده , , Eric Louis، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 2011
Pages
11
From page
919
To page
929
Abstract
Acoustic Doppler Velocimetry (ADV) can measure flow velocities in three directions in experimental facilities and field applications. Based on the Doppler shift effect, ADV can accurately resolve the quasi-instantaneous flow field at frequencies of up to approximately 200 Hz. However, this technique is sensitive to operating conditions that can lead to contaminated signals containing large amplitude spikes, a disadvantage of ADV. Aliasing of the Doppler signal creates these spikes. Such a situation occurs when large particles intersect the sampling volume or acoustic waves. For example during the characterization of river velocities, sediments floating near the riverbed cause aliasing from particles, and more importantly, surface entrained air bubbles contaminate the ADV signal. Spikes due to air bubbles not only increase the standard deviation of the velocity, but also corrupt the autocorrelation and power spectra. As some of these spikes appear like velocity fluctuations, developing accurate despiking procedures is an important requirement during post-processing of ADV velocity measurements in bubbly flow applications. A new hybrid method is introduced which has advantages over conventional despiking methods such as the acceleration thresholding method and the phase-space thresholding method when using ADV in bubbly flow. ADV river velocity measurements near kinetic turbines demonstrate the proposed method. This method is applicable to other bubbly flow applications to characterize the liquid phase using ADV.
Keywords
Kinetic turbines , Bubbly flow , Air bubbles , River characterization , Two-phase flow , Turbulence , Renewable energy , Spikes , Acoustic Doppler Velocimetry (ADV)
Journal title
International Journal of Multiphase Flow
Serial Year
2011
Journal title
International Journal of Multiphase Flow
Record number
1410674
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