Experimental research on pressure drop fluctuation of two-phase flow in single horizontal mini-channels

Abstract

The pressure drop fluctuation of two-phase flow in single horizontal mini-channels with diameters of 1.2mm, 1.6mm and 2.0mm was experimentally investigated. Degassed water was tested in circular horizontal mini-channels with diameters of 1.2mm, 1.6mm and 2.0mm at liquid mass fluxes of 21.2, 42.4 and 84.8kgm−2s−1 as well as heat fluxes of 0–216kWm−2. The pressure drop and the mini-channel wall temperature profiles as well as the visualization results were recorded. Three basic types of the two-phase flow pressure drop fluctuation were identified based on the characteristic frequency, i.e. the low-frequency fluctuation (f<2.0Hz), the medium-frequency fluctuation (2.0Hz<f<10.0Hz) and the high-frequency fluctuation (f>10.0Hz). Besides, it was found that there existed three types of superimposed-frequency fluctuation. Pressure drop fluctuation maps were presented for three diameter channels, showing the single-phase region, the superimposed-frequency region and the low-frequency fluctuation region. The pressure drop fluctuation region depends on the ratio of the heat flux and the mass flux and the channel diameter. The periodic vapour catapult phenomenon was found during the low-frequency fluctuation, which was inferred to be caused by the bubbly/annular alternating flow pattern transition. It was found that the pressure drop and the wall temperature had the approximate fluctuation period with the periodic vapour catapult process. The medium-frequency fluctuation and the high-frequency fluctuation are related to the passage of the elongated bubbles with different periods. In superimposed medium and high frequency fluctuation, the amplitude of the pressure drop fluctuation is relatively low and no synchronous fluctuation was observed between wall temperature and pressure drop profiles.