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Magnetohydrodynamic rnhanced entry system for space transportation (MEESST) as a key building block for low-cost interplanetary missions

Magnetohydrodynamic rnhanced entry system for space transportation (MEESST) as a key building block for low-cost interplanetary missions
Magnetohydrodynamic rnhanced entry system for space transportation (MEESST) as a key building block for low-cost interplanetary missions
Aside from the launch environment, atmospheric re-entry imposes one of the most demanding environments which a spacecraft can experience. The combination of high spacecraft velocity and the presence of atmospheric particles leads to partially ionised gas forming around the vehicle, which significantly inhibits radio communications, and leads to the generation of high thermal loads on the spacecraft surface. Currently, the latter is solved using expensive, heavy, and often expendable thermal protection systems (TPS).The use of electromagnetic fields to exploit Magnetohydrodynamic (MHD) principles has long been considered as an attractive solution for this problem. By displacing the ionised gas away from the spacecraft, the thermal loads can be reduced, while also opening a magnetic window for radio waves, mitigating the blackout phenomenon. The application of this concept has to date not been possible due to the large magnetic fields required, which would necessitate the use of exceptionally massive and power-hungry copper coils. High Temperature Superconductors (HTS) have now reached industrial maturity. HTS coils can now offer the necessary low weight and compactness required for space applications. The MEESST consortium the has been awarded a grant from the EU Horizon 2020 programme for the development and demonstration of a novel HTS-based re-entry system based with its foundation on MHD principles. The project will first harmonize existing numerical codes, and then design, manufacture, and test a HTS magnet. The study shows that the use of MEESST technology can have a positive impact on the cost-effectiveness and available payload of interplanetary missions.
HTS, MEESST, MHD, Reentry, Superconductors
0007-084X
448-453
La Rosa Betancourt, Manuel
a7a00aa4-8935-4bbd-a355-e163032f6919
Collier-Wright, Marcus
741a728d-0521-491f-a24e-53840ae049ea
Bögel, Elias
911eec59-8488-4da0-abf3-244a4b6d9431
Lozano, Jaime Martin
9077b953-cb04-487a-aea8-7a29b65ba504
Lani, Andrea
f33a8683-70cc-4e8c-92b1-54cb70e95272
Herdrich, Georg
c871e6e4-243b-46a8-843f-28c4770e08e3
Thoemel, Jan
412b18cc-4e6b-4966-8259-1bebed0f6fcb
Kim, Min Kwan
18ed9a6f-484f-4a7c-bf24-b630938c1acc
Magin, Thierry
5ea13be7-8647-4015-942f-03cc344b13e7
Schlachter, Sonja
58622825-e602-44d2-be6a-37b2cca91346
Tanchon, Julien
0df1c503-dd35-47a0-a6ed-2a021136987f
Grosse, Veit
45651db5-ac4a-4d5a-bb13-9bcd00c200c0
Casagrande, Angelo
f28586d8-d1b3-4506-a6a5-420747391120
La Rosa Betancourt, Manuel
a7a00aa4-8935-4bbd-a355-e163032f6919
Collier-Wright, Marcus
741a728d-0521-491f-a24e-53840ae049ea
Bögel, Elias
911eec59-8488-4da0-abf3-244a4b6d9431
Lozano, Jaime Martin
9077b953-cb04-487a-aea8-7a29b65ba504
Lani, Andrea
f33a8683-70cc-4e8c-92b1-54cb70e95272
Herdrich, Georg
c871e6e4-243b-46a8-843f-28c4770e08e3
Thoemel, Jan
412b18cc-4e6b-4966-8259-1bebed0f6fcb
Kim, Min Kwan
18ed9a6f-484f-4a7c-bf24-b630938c1acc
Magin, Thierry
5ea13be7-8647-4015-942f-03cc344b13e7
Schlachter, Sonja
58622825-e602-44d2-be6a-37b2cca91346
Tanchon, Julien
0df1c503-dd35-47a0-a6ed-2a021136987f
Grosse, Veit
45651db5-ac4a-4d5a-bb13-9bcd00c200c0
Casagrande, Angelo
f28586d8-d1b3-4506-a6a5-420747391120

La Rosa Betancourt, Manuel, Collier-Wright, Marcus, Bögel, Elias, Lozano, Jaime Martin, Lani, Andrea, Herdrich, Georg, Thoemel, Jan, Kim, Min Kwan, Magin, Thierry, Schlachter, Sonja, Tanchon, Julien, Grosse, Veit and Casagrande, Angelo (2021) Magnetohydrodynamic rnhanced entry system for space transportation (MEESST) as a key building block for low-cost interplanetary missions. JBIS - Journal of the British Interplanetary Society, 74 (12), 448-453.

Record type: Article

Abstract

Aside from the launch environment, atmospheric re-entry imposes one of the most demanding environments which a spacecraft can experience. The combination of high spacecraft velocity and the presence of atmospheric particles leads to partially ionised gas forming around the vehicle, which significantly inhibits radio communications, and leads to the generation of high thermal loads on the spacecraft surface. Currently, the latter is solved using expensive, heavy, and often expendable thermal protection systems (TPS).The use of electromagnetic fields to exploit Magnetohydrodynamic (MHD) principles has long been considered as an attractive solution for this problem. By displacing the ionised gas away from the spacecraft, the thermal loads can be reduced, while also opening a magnetic window for radio waves, mitigating the blackout phenomenon. The application of this concept has to date not been possible due to the large magnetic fields required, which would necessitate the use of exceptionally massive and power-hungry copper coils. High Temperature Superconductors (HTS) have now reached industrial maturity. HTS coils can now offer the necessary low weight and compactness required for space applications. The MEESST consortium the has been awarded a grant from the EU Horizon 2020 programme for the development and demonstration of a novel HTS-based re-entry system based with its foundation on MHD principles. The project will first harmonize existing numerical codes, and then design, manufacture, and test a HTS magnet. The study shows that the use of MEESST technology can have a positive impact on the cost-effectiveness and available payload of interplanetary missions.

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More information

Published date: 1 December 2021
Additional Information: Publisher Copyright: © 2021 British Interplanetary Society. All rights reserved.
Keywords: HTS, MEESST, MHD, Reentry, Superconductors

Identifiers

Local EPrints ID: 498614
URI: http://eprints.soton.ac.uk/id/eprint/498614
ISSN: 0007-084X
PURE UUID: 0b332516-af3f-4d67-9bc4-394de0774c5e
ORCID for Min Kwan Kim: ORCID iD orcid.org/0000-0002-6192-312X

Catalogue record

Date deposited: 24 Feb 2025 17:40
Last modified: 25 Feb 2025 02:47

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Contributors

Author: Manuel La Rosa Betancourt
Author: Marcus Collier-Wright
Author: Elias Bögel
Author: Jaime Martin Lozano
Author: Andrea Lani
Author: Georg Herdrich
Author: Jan Thoemel
Author: Min Kwan Kim ORCID iD
Author: Thierry Magin
Author: Sonja Schlachter
Author: Julien Tanchon
Author: Veit Grosse
Author: Angelo Casagrande

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