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Studies of Two-Phase Flow Dynamics and Heat Transfer at Reduced Gravity ConditionsThe ability to predict gas-liquid flow patterns is crucial to the design and operation of two-phase flow systems in the microgravity environment. Flow pattern maps have been developed in this study which show the occurrence of flow patterns as a function of gas and liquid superficial velocities as well as tube diameter, liquid viscosity and surface tension. The results have demonstrated that the location of the bubble-slug transition is affected by the tube diameter for air-water systems and by surface tension, suggesting that turbulence-induced bubble fluctuations and coalescence mechanisms play a role in this transition. The location of the slug-annular transition on the flow pattern maps is largely unaffected by tube diameter, liquid viscosity or surface tension in the ranges tested. Void fraction-based transition criteria were developed which separate the flow patterns on the flow pattern maps with reasonable accuracy. Weber number transition criteria also show promise but further work is needed to improve these models. For annular gas-liquid flows of air-water and air- 50 percent glycerine under reduced gravity conditions, the pressure gradient agrees fairly well with a version of the Lockhart-Martinelli correlation but the measured film thickness deviates from published correlations at lower Reynolds numbers. Nusselt numbers, based on a film thickness obtained from standard normal-gravity correlations, follow the relation, Nu = A Re(sup n) Pr(exp l/3), but more experimental data in a reduced gravity environment are needed to increase the confidence in the estimated constants, A and n. In the slug flow regime, experimental pressure gradient does not correlate well with either the Lockhart-Martinelli or a homogeneous formulation, but does correlate nicely with a formulation based on a two-phase Reynolds number. Comparison with ground-based correlations implies that the heat transfer coefficients are lower at reduced gravity than at normal gravity under the same flow conditions. Nusselt numbers can be correlated in a fashion similar to Chu and Jones.
Document ID
19960015900
Acquisition Source
Legacy CDMS
Document Type
Contractor Report (CR)
Authors
Witte, Larry C.
(Houston Univ. TX United States)
Bousman, W. Scott
(Houston Univ. TX United States)
Fore, Larry B.
(Houston Univ. TX United States)
Date Acquired
September 6, 2013
Publication Date
February 1, 1996
Subject Category
Fluid Mechanics And Heat Transfer
Report/Patent Number
E-10136
NAS 1.26:198459
NASA-CR-198459
Accession Number
96N21673
Funding Number(s)
CONTRACT_GRANT: NAG3-510
PROJECT: RTOP 694-03-0A
Distribution Limits
Public
Copyright
Work of the US Gov. Public Use Permitted.
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