The modelling of pump performance in two-phase flow

Homer, C. J.

January 1986

This work firstly reviews the experimental data for centrifugal pumps operating in steady-state and transient two-phase flow. The pump head and torque become degraded in two-phase pumping operation. This degradation becomes increasingly severe and abrupt as pump specific speed falls, and is chiefly due to the reduced impeller performance. Degradation depends primarily on specific speed and pump geometry, void fraction and flow coefficient. Degradation also depends on flow regime, fluid viscosity, flow rate and system pressure. The evidence suggests that transient pump performance can be accurately predicted by steady-state tests.A pseudo-two-dimensional analysis is then presented of two-phase flow through a centrifugal pump to predict the head and torque performance over the full range of operating conditions. The loss of performance in the impeller in pumping operation is caused by the large slip that develops between the two phases as the gas slows dramatically compared to the liquid, particularly in stratified flow. In these conditions there is little or no pressure recovery by diffusion in the pump casing, with further energy losses at the impeller exit due to flow impact against the casing.The head and torque performance predicted by the model compared favourably with the results from the single-phase and two-phase experimental pump tests. The comparisons cover all 4 quadrants of pump operation over the whole voidage range for a comprehensive range of pump designs and fluid mixtures. A number of recommendations are made to improve two-phase pump performance for industrial applications.

621.69

Pumps in two-phase flow

Experimental study of hydrodynamics in laboratory-scale venturi scrubbers with two different types of liquid injection

Fernandez-Alonso, Diego

January 2000

No description available.

532

Drop size; Two-phase

Stability improvement of the one-dimensional two-fluid model for horizontal two-phase flow with model unification

Abel, Kent C.

25 August 2005

The next generation of nuclear safety analysis computer codes will require detailed modeling of two-phase fluid flow. The most complete and fundamental model used for these calculations is known as the two-fluid model. It is the most accurate of the two-phase models since it considers each phase independently and links the two phases together with six conservation equations. A major drawback is that the current two-fluid model, when area-averaged to create a one-dimensional model, becomes ill-posed as an initial value problem when the gas and liquid velocities are not equal. The importance of this research lies in obtaining a model that overcomes this difficulty. It is desired to develop a modified one-dimensional two-fluid model for horizontal flow that accounts for the pressure difference between the two phases, due to hydrostatic head, with the implementation of a void fraction distribution parameter. With proper improvement of the one-dimensional two-fluid model, the next generation of nuclear safety analysis computer codes will be able to predict, with greater precision, the key safety parameters of an accident scenario. As part of this research, an improved version of the one-dimensional two-fluid model for horizontal flows was developed. The model was developed from a theoretical point of view with the three original distribution parameters simplified down to a single parameter. The model was found to greatly enhance the numerical stability (hyperbolicity) of the solution method. With proper modeling of the phase distribution parameter, a wide range of flow regimes can be modeled. This parameter could also be used in the future to eliminate the more subjective flow regime maps that are currently implemented in today's multiphase computer codes. By incorporating the distribution parameter and eliminating the flow regime maps, a hyperbolic model is formed with smooth transitions between various flow regimes, eliminating the unphysical oscillations that may occur near transition boundaries in today's multiphase computer codes. / Graduation date:2006

Two-phase flow -- Mathematical models

Discontinuous Galerkin finite element methods applied to two-phase, air-water flow problems

Eslinger, Owen John

28 August 2008

Not available / text

Galerkin methods

Two-phase flow

Dynamics of a single flexible cylinder in external axial compressible fluid flow

Ostoja-Starzewski, Martin

January 1980

No description available.

Two-phase flow.

Hydrodynamics.

Cylinders.

Mass transfer in two-phase annular flow

Wu, Der Chang

05 1900

No description available.

Mass transfer

Two-phase flow

Two phase swirling flow in a cylindrical reactor

Nygaard, Thor Isak.

05 1900

No description available.

Chemical reactors

Two-phase flow

Analysis of separated, non-parallel, axisymmetric, annular two-phase flows

Pohner, John A.

08 1900

No description available.

Heat Transmission

Two-phase flow

Moisture fraction measurement for two-phase mist flow

Wartell, Jason David

05 1900

No description available.

Two-phase flow

Moisture Measurement

Interphase transfer processes in cocurrent two phase channel flow

Luo, Danhui

08 1900

No description available.

Two-phase flow

Mass transfer