The flow regimes associated with a horizontal internal two-phase (liquid-vapor) flow in the presence and absence of the electric field are investigated with the linear stability analysis. The momentum interchange due to the entrainment between the two phases is included in the analysis. The presence of the electric field promotes instability by providing the electrohydrodynamic (EHD) extraction force. Qualitative stability maps for the annular two-phase flow are provided with and without the electric field presence. Onset of the instability is compared with the experimental data and it is shown that the transition between the EHD-enhanced and EHD-suppressed convective boiling heat transfer is located near the annular-to-mist transition region.

Issue Section:
Two-Phase Flow and Heat Transfer
Keywords:
flow instability, two-phase flow, convection, boiling, confined flow, electrohydrodynamics, stratified flow, Electric Fields, Heat Transfer, Instability, Phase Change, Stability, , Two-Phase
Topics:
Flow (Dynamics), Stability, Two-phase flow, Vapors, Pipes, Electrohydrodynamics, Electric fields, Heat transfer, Momentum, Boiling
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