Optimization of a hydrogen-based hybrid propulsion system under aircraft performance constraints

This paper addresses the topic of the conceptual design of a regional aircraft with hybrid electric propulsion based on hydrogen fuel cells. It aims at providing an optimization-based method to design a hybrid propulsive system comprising two power sources (jet fuel and hydrogen) for the generation...

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Published in	Chinese journal of aeronautics Vol. 36; no. 5; pp. 41 - 56
Main Authors	PALLADINO, Vincenzo, BARTOLI, Nathalie, POMMIER-BUDINGER, Valérie, BENARD, Emmanuel, SCHMOLLGRUBER, Peter, JORDAN, Arnaud
Format	Journal Article
Language	English
Published	Elsevier Ltd 01.05.2023 ISAE-SUPAERO,Toulouse 31055,France%ONERA/DTIS-Universite de Toulouse,Toulouse 31055,France%ISAE-SUPAERO,Toulouse 31055,France%ATR Aircraft,Blagnac 31712,France ONERA/DTIS-Universite de Toulouse,Toulouse 31055,France ATR Aircraft,Blagnac 31712,France Elsevier
Subjects	Aircraft design Engineering Sciences Hybrid aircraft Hydrogen aircraft Mathematics Physics Propulsion Regional aircraft Hybrid aircraft Propulsion Aircraft design Regional aircraft Hydrogen aircraft CONCEPTION AVION AVION HYDROGENE AVION REGIONAL AVION HYBRIDE
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Abstract	This paper addresses the topic of the conceptual design of a regional aircraft with hybrid electric propulsion based on hydrogen fuel cells. It aims at providing an optimization-based method to design a hybrid propulsive system comprising two power sources (jet fuel and hydrogen) for the generation of the required propulsive power and at studying the impact of fuel cell technologies on the aircraft performances. Indeed, by performing optimizations for two hybrid propulsive systems using either low temperature or high temperature proton-exchange membrane fuel cells, this study provides a preliminary assessment of the impact of the fuel cell operating temperature on the system design and the overall aircraft performance. First, this paper gives a description of the baseline turboprop regional aircraft with a focus on its high speed and low speed flight performances which will serve as requirements for the design of the hybrid aircraft. Then, the hybrid electric architecture and the sizing models of the propulsion system are presented. Finally, optimizations are performed to design two parallel hybrid propulsive systems based on different fuel cells technologies and aimed at minimizing the block fuel per passenger over a mission of 200 n mile. Results show how the proposed methodology and models lead to design two propulsive systems capable of reducing the fuel consumption per passenger by more than 30 % compared to the baseline aircraft. The study also shows that the choice of fuel cell operating temperature has a first-order impact on the total mass of the propulsive system due to the higher cooling requirement of the low temperature fuel cells.
AbstractList	This paper addresses the topic of the conceptual design of a regional aircraft with hybrid electric propulsion based on hydrogen fuel cells. It aims at providing an optimization-based method to design a hybrid propulsive system comprising two power sources (jet fuel and hydrogen) for the generation of the required propulsive power and at studying the impact of fuel cell technologies on the aircraft performances. Indeed, by performing optimizations for two hybrid propulsive systems using either low temperature or high temperature proton-exchange membrane fuel cells, this study provides a preliminary assessment of the impact of the fuel cell operating temperature on the system design and the overall aircraft performance. First, this paper gives a description of the baseline turboprop regional aircraft with a focus on its high speed and low speed flight performances which will serve as requirements for the design of the hybrid aircraft. Then, the hybrid electric architecture and the sizing models of the propulsion system are presented. Finally, optimizations are performed to design two parallel hybrid propulsive systems based on different fuel cells technologies and aimed at minimizing the block fuel per passenger over a mission of 200 n mile. Results show how the proposed methodology and models lead to design two propulsive systems capable of reducing the fuel consumption per passenger by more than 30 % compared to the baseline aircraft. The study also shows that the choice of fuel cell operating temperature has a first-order impact on the total mass of the propulsive system due to the higher cooling requirement of the low temperature fuel cells. This paper addresses the topic of the conceptual design of a regional aircraft with hybrid electric propulsion based on hydrogen fuel cells. It aims at providing an optimization-based method to design a hybrid propulsive system comprising two power sources (jet fuel and hydrogen) for the generation of the required propulsive power and at studying the impact of fuel cell technologies on the aircraft performances. Indeed, by performing optimizations for two hybrid propulsive systems using either low temperature or high temperature proton-exchange membrane fuel cells, this study provides a preliminary assessment of the impact of the fuel cell operating temperature on the system design and the overall aircraft performance. First, this paper gives a description of the baseline turboprop regional aircraft with a focus on its high speed and low speed flight performances which will serve as requirements for the design of the hybrid aircraft. Then, the hybrid electric architecture and the sizing models of the propulsion system are presented. Finally, optimizations are performed to design two parallel hybrid propulsive systems based on different fuel cells technologies and aimed at minimizing the block fuel per passenger over a mission of 200 n mile. Results show how the proposed methodology and models lead to design two propulsive systems capable of reducing the fuel consumption per passenger by more than 30 % compared to the baseline aircraft. The study also shows that the choice of fuel cell operating temperature has a first-order impact on the total mass This paper addresses the topic of the conceptual design of a regional aircraft with hybrid electric propulsion based on hydrogen fuel cells.It aims at providing an optimization-based method to design a hybrid propulsive system comprising two power sources(jet fuel and hydrogen)for the generation of the required propulsive power and at studying the impact of fuel cell technologies on the aircraft performances.Indeed,by performing optimizations for two hybrid propulsive systems using either low temperature or high temperature proton-exchange membrane fuel cells,this study provides a preliminary assessment of the impact of the fuel cell operating temperature on the system design and the overall aircraft performance.First,this paper gives a description of the baseline tur-boprop regional aircraft with a focus on its high speed and low speed flight performances which will serve as requirements for the design of the hybrid aircraft.Then,the hybrid electric architecture and the sizing models of the propulsion system are presented.Finally,optimizations are performed to design two parallel hybrid propulsive systems based on different fuel cells technologies and aimed at minimizing the block fuel per passenger over a mission of 200 n mile.Results show how the pro-posed methodology and models lead to design two propulsive systems capable of reducing the fuel consumption per passenger by more than 30％compared to the baseline aircraft.The study also shows that the choice of fuel cell operating temperature has a first-order impact on the total mass of the propulsive system due to the higher cooling requirement of the low temperature fuel cells.
Author	SCHMOLLGRUBER, Peter BARTOLI, Nathalie POMMIER-BUDINGER, Valérie JORDAN, Arnaud BENARD, Emmanuel PALLADINO, Vincenzo
AuthorAffiliation	ATR Aircraft,Blagnac 31712,France;ONERA/DTIS-Universite de Toulouse,Toulouse 31055,France;ISAE-SUPAERO,Toulouse 31055,France%ONERA/DTIS-Universite de Toulouse,Toulouse 31055,France%ISAE-SUPAERO,Toulouse 31055,France%ATR Aircraft,Blagnac 31712,France
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Author_xml	– sequence: 1 givenname: Vincenzo surname: PALLADINO fullname: PALLADINO, Vincenzo email: vincenzo.palladino@outlook.com organization: ATR Aircraft, Blagnac 31712, France – sequence: 2 givenname: Nathalie surname: BARTOLI fullname: BARTOLI, Nathalie organization: ONERA/DTIS-Université de Toulouse, Toulouse 31055, France – sequence: 3 givenname: Valérie surname: POMMIER-BUDINGER fullname: POMMIER-BUDINGER, Valérie organization: ISAE-SUPAERO, Toulouse 31055, France – sequence: 4 givenname: Emmanuel surname: BENARD fullname: BENARD, Emmanuel organization: ISAE-SUPAERO, Toulouse 31055, France – sequence: 5 givenname: Peter surname: SCHMOLLGRUBER fullname: SCHMOLLGRUBER, Peter organization: ONERA/DTIS-Université de Toulouse, Toulouse 31055, France – sequence: 6 givenname: Arnaud surname: JORDAN fullname: JORDAN, Arnaud organization: ATR Aircraft, Blagnac 31712, France
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Snippet	This paper addresses the topic of the conceptual design of a regional aircraft with hybrid electric propulsion based on hydrogen fuel cells. It aims at... This paper addresses the topic of the conceptual design of a regional aircraft with hybrid electric propulsion based on hydrogen fuel cells.It aims at...
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SubjectTerms	Aircraft design Engineering Sciences Hybrid aircraft Hydrogen aircraft Mathematics Physics Propulsion Regional aircraft
Title	Optimization of a hydrogen-based hybrid propulsion system under aircraft performance constraints
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