Multi-physics simulation study of magnetic shielding on hypersonic vehicles
Multi-physics simulation study of magnetic shielding on hypersonic vehicles
The renewed interest in hypersonic flights due to NASA’s Artemis program has brought fresh attention to the physical challenges of reusable thermal protection systems. The need to enhance the reliability of hypersonic and re-entry vehicles has sharply focused on the limitations of our current comprehension of thermo-chemical non-equilibrium flows and our limited predictive capabilities. This paper presents the work carried out by the University of Southampton and our consortium partners within the MEESST collaboration. This project is currently involved in both numerical and experimental research to develop magnetic shielding techniques for atmospheric re-entry vehicles. These techniques aim to offer additional approaches for mitigating both impinging heat loads and communication blackout. Herein, we present the results of multi-physics simulations conducted with the University of Southampton’s HANSA toolkit, along with comparisons, both experimental and numerical, produced by our consortium partners. These encompass simulations of multiple capsules undergoing atmospheric re-entry and simulations of ground-based experimental campaigns. We give particular attention to the effects of thermo-chemical non-equilibrium and MHD modelling. We illustrate the impacts of various mathematical models on the results obtained, with a strong emphasis on mission-critical parameters such as surface heat fluxes and electron densities. We also present conclusions regarding the implications of these results on magnetic shielding designs. Lastly, we offer an overview of current knowledge gaps in areas crucial to MEESST and lay out plans for future simulations and experiments, both within the MEESST project and beyond.
Greenslade, Thomas J.
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Chinnappan, Arun Kumar
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Kim, Minkwan
18ed9a6f-484f-4a7c-bf24-b630938c1acc
Greenslade, Thomas J.
01c4cc26-f5a1-4166-b2fe-d105e893bb02
Chinnappan, Arun Kumar
8db93823-a84a-4f2e-8fb1-9fa3ab8ac407
Kim, Minkwan
18ed9a6f-484f-4a7c-bf24-b630938c1acc
Greenslade, Thomas J., Chinnappan, Arun Kumar and Kim, Minkwan
(2024)
Multi-physics simulation study of magnetic shielding on hypersonic vehicles.
CEAS Space Journal.
(doi:10.1007/s12567-024-00580-w).
Abstract
The renewed interest in hypersonic flights due to NASA’s Artemis program has brought fresh attention to the physical challenges of reusable thermal protection systems. The need to enhance the reliability of hypersonic and re-entry vehicles has sharply focused on the limitations of our current comprehension of thermo-chemical non-equilibrium flows and our limited predictive capabilities. This paper presents the work carried out by the University of Southampton and our consortium partners within the MEESST collaboration. This project is currently involved in both numerical and experimental research to develop magnetic shielding techniques for atmospheric re-entry vehicles. These techniques aim to offer additional approaches for mitigating both impinging heat loads and communication blackout. Herein, we present the results of multi-physics simulations conducted with the University of Southampton’s HANSA toolkit, along with comparisons, both experimental and numerical, produced by our consortium partners. These encompass simulations of multiple capsules undergoing atmospheric re-entry and simulations of ground-based experimental campaigns. We give particular attention to the effects of thermo-chemical non-equilibrium and MHD modelling. We illustrate the impacts of various mathematical models on the results obtained, with a strong emphasis on mission-critical parameters such as surface heat fluxes and electron densities. We also present conclusions regarding the implications of these results on magnetic shielding designs. Lastly, we offer an overview of current knowledge gaps in areas crucial to MEESST and lay out plans for future simulations and experiments, both within the MEESST project and beyond.
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s12567-024-00580-w
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Accepted/In Press date: 18 November 2024
e-pub ahead of print date: 3 December 2024
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Local EPrints ID: 498620
URI: http://eprints.soton.ac.uk/id/eprint/498620
ISSN: 1868-2510
PURE UUID: 25a33cce-d9bf-428b-b907-88868798dac1
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Date deposited: 24 Feb 2025 17:42
Last modified: 22 Aug 2025 02:09
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Author:
Thomas J. Greenslade
Author:
Arun Kumar Chinnappan
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