Jim Bennett scite author profile

The determination of whether a phase is a liquid or a vapor is somewhat arbitrary, particularly when the fluid is in the single-phase region. However, the calculation of multiphase flow in oil industry simulators is dependent upon the labeling of the phases. Key properties in flow modeling, such as relative permeabilities and capillary pressures, are dependent upon which phases are present. Correct labeling of the fluid phases is therefore critical to the success of simulations. Many methods have been proposed for identifying phases. These are reviewed here. Five methods have been selected for detailed comparison, including a new method, based on the thermal expansion coefficient. The results of the comparison and the relative advantages of the methods are discussed.

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Momentum rate probe for use with two-phase flows

Bush

Bennett

Sojka

et al. 1996

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An instrument for measuring the momentum rate of two-phase flows is described, and design and construction details are provided. The device utilizes a conelike body to turn the flow from the axial to the radial direction. The force resulting from the change in momentum rate of the turning flow is measured using a strain-gage-instrumented cantilevered beam. The instrument is applicable to a wide range of flows including nuclear reactor coolant streams, refrigerants in heating-ventilating air-conditioning equipment, impingement cooling of small scale electronic hardware (computer chips are one example), supercritical fuel injection (in Diesel engines, for instance), and consumer product sprays (such as hair-care product sprays produced using effervescent atomizers). The latter application is discussed here. Features of the instrument include sensitivity to a wide range of forces and the ability to damp oscillations of the deflection cone. Instrument sensitivity allows measurement of momentum rates considerably lower (below 0.01 N) than those that could be obtained using previous devices. This feature is a direct result of our use of precision strain gages, capable of sensing strains below 20 μm/m, and the damping of oscillations which can overwhelm the force measurements. Oscillation damping results from a viscous fluid damper whose resistance is easily varied by changing fluids. Data used to calibrate the instrument are presented to demonstrate the effectiveness of the technique. As an example of the instrument’s utility, momentum rate data obtained using it will be valuable in efforts to explain entrainment of surrounding air into effervescent atomizer-produced sprays and also to model the effervescent atomization process.

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Jim Bennett

Correlation of binary interaction coefficients for hydrate inhibition using the Soave-Redlich-Kwong Equation of State and the Huron-Vidal mixing rule

Comparison of Phase Identification Methods Used in Oil Industry Flow Simulations

Momentum rate probe for use with two-phase flows

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