Application of probabilistic set-based design exploration on the energy management of a hybrid-electric aircraft
Application of probabilistic set-based design exploration on the energy management of a hybrid-electric aircraft
The energy management strategy of a hybrid-electric aircraft is coupled with the design of the propulsion system itself. A new design space exploration methodology based on Set-Based Design is introduced to analyse the effects of different strategies on the fuel consumption, NOx
and take-off mass. Probabilities are used to evaluate and discard areas of the design space not capable of satisfying the constraints and requirements, saving computational time corresponding to an average of 75%. The study is carried on a 50-seater regional turboprop with a parallel hybrid-electric architecture. The strategies are modelled as piecewise linear functions of the degree of hybridisation and are applied to different mission phases to explore how the strategy complexity and the number of hybridised segments can influence the behaviour of the system. The results indicate that the complexity of the parametrisation does not affect the trade-off between fuel consumption and NOx emissions. On the contrary, a significant trade-off is identified on which phases are hybridised. That is, the least fuel consumption is obtained only by hybridising the longest mission phase, while less NOx emissions are generated if more phases are hybridised. Finally, the maximum take-off mass was investigated as a parameter, and the impact to the trade-off between the objectives was analysed. Three energy management strategies were suggested from these findings, which achieved a reduction to the fuel consumption of up to 10% and a reduction to NOx
emissions of up to 15%.
Spinelli, Andrea
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Enalou, Hossein Balaghi
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Zaghari, Bahareh
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Kipouros, Timoleon
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Laskaridis, Panagiotis
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8 March 2022
Spinelli, Andrea
b873f99d-ffac-4505-a621-04c322e76a1e
Enalou, Hossein Balaghi
68e719e2-504e-426e-a935-8e2eaf72563f
Zaghari, Bahareh
c24b19e7-513a-4395-8400-6b7361fa8774
Kipouros, Timoleon
d8adf7f6-d861-40ef-b48c-a648f5d33a95
Laskaridis, Panagiotis
20b947eb-4679-411c-afa0-c50f1738d9ea
Spinelli, Andrea, Enalou, Hossein Balaghi, Zaghari, Bahareh, Kipouros, Timoleon and Laskaridis, Panagiotis
(2022)
Application of probabilistic set-based design exploration on the energy management of a hybrid-electric aircraft.
Aerospace, 9 (3).
(doi:10.3390/aerospace9030147).
Abstract
The energy management strategy of a hybrid-electric aircraft is coupled with the design of the propulsion system itself. A new design space exploration methodology based on Set-Based Design is introduced to analyse the effects of different strategies on the fuel consumption, NOx
and take-off mass. Probabilities are used to evaluate and discard areas of the design space not capable of satisfying the constraints and requirements, saving computational time corresponding to an average of 75%. The study is carried on a 50-seater regional turboprop with a parallel hybrid-electric architecture. The strategies are modelled as piecewise linear functions of the degree of hybridisation and are applied to different mission phases to explore how the strategy complexity and the number of hybridised segments can influence the behaviour of the system. The results indicate that the complexity of the parametrisation does not affect the trade-off between fuel consumption and NOx emissions. On the contrary, a significant trade-off is identified on which phases are hybridised. That is, the least fuel consumption is obtained only by hybridising the longest mission phase, while less NOx emissions are generated if more phases are hybridised. Finally, the maximum take-off mass was investigated as a parameter, and the impact to the trade-off between the objectives was analysed. Three energy management strategies were suggested from these findings, which achieved a reduction to the fuel consumption of up to 10% and a reduction to NOx
emissions of up to 15%.
Text
aerospace-09-00147
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Accepted/In Press date: 5 March 2022
Published date: 8 March 2022
Identifiers
Local EPrints ID: 494772
URI: http://eprints.soton.ac.uk/id/eprint/494772
ISSN: 2226-4310
PURE UUID: 3570bcdb-4057-449c-a5c5-5a1df4818f21
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Date deposited: 15 Oct 2024 16:44
Last modified: 15 Oct 2024 16:44
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Contributors
Author:
Andrea Spinelli
Author:
Hossein Balaghi Enalou
Author:
Bahareh Zaghari
Author:
Timoleon Kipouros
Author:
Panagiotis Laskaridis
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