Liquid hydrogen line chilldown experiments at high Reynolds numbers. II. Analysis

•We report analysis of the first ever set of liquid hydrogen chilldown tests conducted at high Reynolds numbers.•We also present the first ever flow visualization of liquid hydrogen chilldown tests.•The effect of chilldown method, mass flow rate, and inlet liquid temperature on chilldown is reported...

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Bibliographic Details
Published inInternational journal of heat and mass transfer Vol. 156; p. 119805
Main Authors Hartwig, Jason, Styborski, Jeremy, Stiegemeier, Ben, Chung, J.N., Ramé, Enrique, McQuillen, John
Format Journal Article
LanguageEnglish
Published Oxford Elsevier Ltd 01.08.2020
Elsevier BV
Subjects
Annular flow
Boiling
Chilldown
Cryogenic
Flow mapping
Flow visualization
Fluid dynamics
Fluid flow
Heat transfer coefficients
High Reynolds number
Hydrogen
Liquid hydrogen
Mass flow rate
Research facilities
State (computer science)
Temperature profiles
Two phase flow
Cryogenic
Chilldown
Liquid hydrogen
High Reynolds number
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Summary:•We report analysis of the first ever set of liquid hydrogen chilldown tests conducted at high Reynolds numbers.•We also present the first ever flow visualization of liquid hydrogen chilldown tests.•The effect of chilldown method, mass flow rate, and inlet liquid temperature on chilldown is reported.•LH2 chilldown follows the reverse boiling curve (aka quenching curve). This paper presents in-depth analysis of the recently conducted high Reynolds (Re) number liquid hydrogen (LH2) transfer line chilldown experiments at NASA Glenn Research Center. Vertically upward trickle and pulse flow chilldown tests were conducted over a wide range of LH2 liquid temperatures (20.3 K – 24.2 K) and mass flow rates (0.0012 – 0.036 kg/s) typical of a proposed cryogenic propellant depot. Two-phase flow mapping is used to correlate flow visualization with LH2 stream temperature profiles. Thermodynamic state diagrams, reverse boiling curves, and heat transfer coefficients are used to explain the evolution of the chill down process at various locations. Analysis reveals stark differences in behavior between skin and stream temperature measurements due to annular flow and bubbly flow dominated cooling. Analysis also shows that hydrogen chilldown at high Re numbers promotes better mixing and thus more liquid contact along the wall earlier on, in comparison to chilldown with other fluids like nitrogen where classical inverted annular flow boiling is incurred.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2020.119805