An advance in transfer line chilldown heat transfer of cryogenic propellants in microgravity using microfilm coating for enabling deep space exploration-Reference-Cited by-同舟云学术

An advance in transfer line chilldown heat transfer of cryogenic propellants in microgravity using microfilm coating for enabling deep space exploration

Published:2021-06-08 Issue:1 Volume:7 Page:
ISSN:2373-8065
Container-title:npj Microgravity
language:en
Short-container-title:npj Microgravity

Author:

Chung J. N.,Dong Jun,Wang Hao^ORCID,Darr S. R.,Hartwig J. W.

Abstract

AbstractThe extension of human space exploration from a low earth orbit to a high earth orbit, then to Moon, Mars, and possibly asteroids is NASA’s biggest challenge for the new millennium. Integral to this mission is the effective, sufficient, and reliable supply of cryogenic propellant fluids. Therefore, highly energy-efficient thermal-fluid management breakthrough concepts to conserve and minimize the cryogen consumption have become the focus of research and development, especially for the deep space mission to mars. Here we introduce such a concept and demonstrate its feasibility in parabolic flights under a simulated space microgravity condition. We show that by coating the inner surface of a cryogenic propellant transfer pipe with low-thermal conductivity microfilms, the quenching efficiency can be increased up to 176% over that of the traditional bare-surface pipe for the thermal management process of chilling down the transfer pipe. To put this into proper perspective, the much higher efficiency translates into a 65% savings in propellant consumption.

Publisher

Springer Science and Business Media LLC

Subject

Space and Planetary Science,Physics and Astronomy (miscellaneous),Agricultural and Biological Sciences (miscellaneous),Biochemistry, Genetics and Molecular Biology (miscellaneous),Materials Science (miscellaneous),Medicine (miscellaneous)

Link

http://www.nature.com/articles/s41526-021-00149-5.pdf

Reference33 articles.

1. Mars Architecture Steering Group. Human exploration of Mars Design Reference Architecture 5.0. Report No. NASA/SP-2009-566 (ed. Drake, B. G.) (National Aeronautics And Space Administration) (2009).

2. Meyer, M. L. et al. Mastering cryogenic propellants. J. Aerosp. Eng. 26, 343–351 (2013).

3. Motil, S. M., Meyer, M. L. & Tucker, S. P. Cryogenic fluid management technologies for advanced green propulsion systems. AIAA 45th Aerospace Sciences Meeting and Exhibit; NASA/TM-2007-214810, Reno, NV, 8 January (American Institute of Aeronautics and Astronautics, 2007).

4. NASA. NASA Technology Roadmaps, TA 2: In-Space Propulsion Technologies (National Aeronautics and Space Administration, 2015).

5. Shaeffer, R., Hu, H. & Chung, J. N. An experimental study on liquid nitrogen pipe chilldown and heat transfer with pulse flows. Int. J. Heat Mass Transf. 67, 955–966 (2013).

Cited by 18 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Experimental investigations on the flow boiling and heat transfer characteristics during chilldown process in a closed loop chilldown test section;International Journal of Heat and Mass Transfer;2024-11

2. Demonstration of charge-hold-vent (CHV) and no-vent-fill (NVF) in a simulated propellent storage tank during tank-to-tank cryogen transfer in microgravity;npj Microgravity;2024-06-06

3. Development of constitutive relations for predicting film boiling crisis in bare and inner wall coated cryogenic tubes with a low-thermal conductive layer for heat transfer enhancement;International Journal of Heat and Mass Transfer;2024-05

4. Enhancement and optimization of cryogenic metal tube chilldown heat transfer using thin-film coating, I. Effects of flow mass flux and coating layer thickness;International Communications in Heat and Mass Transfer;2024-04

5. Enhancement and optimization of cryogenic metal tube chilldown heat transfer using thin-film coating, II. Chilldown efficiency, flow direction and tube wall thickness;International Communications in Heat and Mass Transfer;2024-04