Experimental investigation of frequency and amplitude of density wave oscillations in vertical upflow boiling

•Experiments investigate Density Wave Oscillations (DWOs) in vertical upflow boiling.•Observed pressure oscillations are characterized relative to frequency and amplitude.•Both frequency and amplitude of pressure oscillations are dominated by mass velocity.•With pressure oscillation amplitude less t...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2018-10, Vol.125, p.1240-1263
Main Authors: O'Neill, Lucas E., Mudawar, Issam, Hasan, Mohammad M., Nahra, Henry K., Balasubramaniam, R., Mackey, Jeffery R.
Format: Article
Language:English
Subjects:
Amplitudes
Binary systems
Boiling
Boundary conditions
Computer simulation
Control systems
Density
Density wave oscillations
Flow boiling
Flow geometry
Flow instabilities
Flow visualization
Frequency and amplitude
Geometry
Heat transfer
Oscillations
Pressure oscillations
Space missions
Two phase flow
Unsteady flow
Variation
Vertical oscillations
Visualization
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Summary:•Experiments investigate Density Wave Oscillations (DWOs) in vertical upflow boiling.•Observed pressure oscillations are characterized relative to frequency and amplitude.•Both frequency and amplitude of pressure oscillations are dominated by mass velocity.•With pressure oscillation amplitude less than 7% of average, DWOs do not pose risks. Historically, study of two-phase flow instabilities has been arguably one of the most challenging endeavors in heat transfer literature due to the wide range of instabilities systems can manifest depending on differences in operating conditions and flow geometry. This study utilizes experimental results for vertical upflow boiling of FC-72 in a rectangular channel with finite inlet quality to investigate Density Wave Oscillations (DWOs) and assess their potential impact on design of two-phase systems for future space missions. High-speed flow visualization image sequences are presented and used to directly relate the cyclical passage of High and Low Density Fronts (HDFs and LDFs) to dominant low-frequency oscillations present in transient pressure signals commonly attributed to DWOs. A methodology is presented to determine frequency and amplitude of DWO induced pressure oscillations, which are then plotted for a wide range of relevant operating conditions. Mass velocity (flow inertia) is seen to be the dominant parameter influencing frequency and amplitude of DWOs. Amplitude of pressure oscillations is at most 7% of the time-averaged pressure level for current operating conditions, meaning there is little risk to space missions. Reconstruction of experimental pressure signals using a waveform defined by frequency and amplitude of DWO induced pressure fluctuations is seen to have only moderate agreement with the original signal due to the oversimplifications of treating DWO induced fluctuations as perfectly sinusoidal in nature, assuming they occur at a constant frequency value, and neglecting other transient flow features. This approach is nonetheless determined to have potential value for use as a boundary condition to introduce DWOs in two-phase flow simulations should a model be capable of accurately predicting frequency and amplitude of oscillation.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2018.04.138