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Neutron attenuation analysis of cryogenic propellants

[+] Author and Article Information
Kishan Bellur

Michigan Technological University, 49931
ksbellur@mtu.edu

Daniel Hussey

National Institute of Standards and Technology, 20899
daniel.hussey@nist.gov

David Jacobson

National Institute of Standards and Technology, 20899
david.jacobson@nist.gov

Jacob Lamana

National Institute of Standards and Technology, 20899
jacob.lamanna@nist.gov

Ezequiel Medici

Michigan Technological University, 49931
efmedici@mtu.edu

James Hermanson

University of Washington, 98195
jherm@aa.washington.edu

Dr. Jeffrey S. Allen

Michigan Technological University, 49931
jstallen@mtu.edu

Chang Kyoung Choi

Michigan Technological University, 49931
cchoi@mtu.edu

1Corresponding author.

J. Heat Transfer 140(3), 030904 (Feb 16, 2018) Paper No: HT-17-1714; doi: 10.1115/1.4039169 History: Received November 28, 2017; Revised December 22, 2017

Abstract

Neutron imaging enables direct visualization of evaporation and condensation of cryogenic propellants in metal containers such as aluminum and stainless steel. CFD models of propellant behaviors inside the large tanks have shown that a thin liquid film is formed along the interior surface, but this had not been verified experimentally. In the present study, neutron imaging is used to study evaporation and condensation rates of liquid methane inside a cylindrical 10 mm, Al 6061 cell. The liquid meniscus is clearly shown, but the spatial resolution is insufficient to directly image thin liquid films that may be on the interior surface. Optical density (neutron attenuation) analysis enables quantitative measurements of these liquid films. An optical density image is formed by removing the background noise and normalizing the liquid image with that of the empty cell. Optical densities are then transformed into a liquid transmission thickness using the Beer-Lambert law. This technique enables measurement of film thicknesses smaller than the spatial resolution of the imaging system. The above graphic shows an optical density image during condensation of methane and the corresponding horizontal scan which suggests that a 11 μm film exists on the wall. The images indicate that methane undergoes film-wise condensation and is perfectly wetting to aluminum.

These experiments were conducted at the NIST Center for Neutron Research in the Neutron Imaging Facility and the relevant work is supported by an Early stage Innovations Grant from NASA's Space Technology Research Grants Program (Grant # NNX14AB05G).

Copyright © 2018 by American Society of Mechanical Engineers
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